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204 lines
7.6 KiB
Plaintext
204 lines
7.6 KiB
Plaintext
Collapse OS' Forth implementation notes
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*** EXECUTION MODEL
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After having read a line through readln, we want to interpret it. As a general
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rule, we go like this:
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1. read single word from line
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2. Can we find the word in dict?
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3. If yes, execute that word, goto 1
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4. Is it a number?
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5. If yes, push that number to PS, goto 1
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6. Error: undefined word.
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*** EXECUTING A WORD
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At it's core, executing a word is pushing the wordref on PS and calling EXECUTE.
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Then, we let the word do its things. Some words are special, but most of them
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are of the compiledWord type, and that's their execution that we describe here.
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First of all, at all time during execution, the Interpreter Pointer (IP) points
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to the wordref we're executing next.
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When we execute a compiledWord, the first thing we do is push IP to the Return
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Stack (RS). Therefore, RS' top of stack will contain a wordref to execute next,
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after we EXIT.
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At the end of every compiledWord is an EXIT. This pops RS, sets IP to it, and
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continues.
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*** Stack management
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The Parameter stack (PS) is maintained by SP and the Return stack (RS) is
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maintained by IX. This allows us to generally use push and pop freely because PS
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is the most frequently used. However, this causes a problem with routine calls:
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because in Forth, the stack isn't balanced within each call, our return offset,
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when placed by a CALL, messes everything up. This is one of the reasons why we
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need stack management routines below. IX always points to RS' Top Of Stack (TOS)
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This return stack contain "Interpreter pointers", that is a pointer to the
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address of a word, as seen in a compiled list of words.
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*** Dictionary
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A dictionary entry has this structure:
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- Xb name. Arbitrary long number of character (but can't be bigger than
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input buffer, of course). not null-terminated
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- 2b prev offset
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- 1b size + IMMEDIATE flag
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- 2b code pointer
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- Parameter field (PF)
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The prev offset is the number of bytes between the prev field and the previous
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word's code pointer.
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The size + flag indicate the size of the name field, with the 7th bit being the
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IMMEDIATE flag.
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The code pointer point to "word routines". These routines expect to be called
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with IY pointing to the PF. They themselves are expected to end by jumping to
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the address at (IP). They will usually do so with "jp next".
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That's for "regular" words (words that are part of the dict chain). There are
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also "special words", for example NUMBER, LIT, FBR, that have a slightly
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different structure. They're also a pointer to an executable, but as for the
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other fields, the only one they have is the "flags" field.
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*** System variables
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There are some core variables in the core system that are referred to directly
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by their address in memory throughout the code. The place where they live is
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configurable by the RAMSTART constant in conf.fs, but their relative offset is
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not. In fact, they're mostly referred to directly as their numerical offset
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along with a comment indicating what this offset refers to.
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This system is a bit fragile because every time we change those offsets, we
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have to be careful to adjust all system variables offsets, but thankfully,
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there aren't many system variables. Here's a list of them:
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RAMSTART INITIAL_SP
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+02 CURRENT
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+04 HERE
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+06 IP
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+08 FLAGS
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+0a PARSEPTR
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+0c CINPTR
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+0e WORDBUF
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+2e BOOT C< PTR
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+4e INTJUMP
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+51 CURRENTPTR
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+53 readln's variables
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+55 adev's variables
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+57 blk's variables
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+59 z80a's variables
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+5b FUTURE USES
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+70 DRIVERS
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+80 RAMEND
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INITIAL_SP holds the initial Stack Pointer value so that we know where to reset
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it on ABORT
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CURRENT points to the last dict entry.
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HERE points to current write offset.
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IP is the Interpreter Pointer
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FLAGS holds global flags. Only used for prompt output control for now.
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PARSEPTR holds routine address called on (parse)
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CINPTR holds routine address called on C<
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WORDBUF is the buffer used by WORD
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BOOT C< PTR is used when Forth boots from in-memory source. See "Initialization
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sequence" below.
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INTJUMP All RST offsets (well, not *all* at this moment, I still have to free
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those slots...) in boot binaries are made to jump to this address. If you use
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one of those slots for an interrupt, write a jump to the appropriate offset in
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that RAM location.
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CURRENTPTR points to current CURRENT. The Forth CURRENT word doesn't return
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RAM+2 directly, but rather the value at this address. Most of the time, it
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points to RAM+2, but sometimes, when maintaining alternative dicts (during
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cross compilation for example), it can point elsewhere.
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FUTURE USES section is unused for now.
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DRIVERS section is reserved for recipe-specific drivers. Here is a list of
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known usages:
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* 0x70-0x78: ACIA buffer pointers in RC2014 recipes.
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*** Word routines
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This is the description of all word routine you can encounter in this Forth
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implementation. That is, a wordref will always point to a memory offset
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containing one of these numbers.
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0x17: nativeWord. This words PFA contains native binary code and is jumped to
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directly.
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0x0e: compiledWord. This word's PFA contains an atom list and its execution is
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described in "EXECUTION MODEL" above.
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0x0b: cellWord. This word is usually followed by a 2-byte value in its PFA.
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Upon execution, the *address* of the PFA is pushed to PS.
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0x2b: doesWord. This word is created by "DOES>" and is followed by a 2-byte
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value as well as the adress where "DOES>" was compiled. At that address is an
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atom list exactly like in a compiled word. Upon execution, after having pushed
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its cell addr to PSP, it execute its reference exactly like a compiledWord.
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0x20: numberWord. No word is actually compiled with this routine, but atoms are.
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Atoms with a reference to the number words routine are followed, *in the atom
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list*, of a 2-byte number. Upon execution, that number is fetched and IP is
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avdanced by an extra 2 bytes.
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0x24: addrWord. Exactly like a numberWord, except that it is treated
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differently by meta-tools.
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0x22: litWord. Similar to a number word, except that instead of being followed
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by a 2 byte number, it is followed by a null-terminated string. Upon execution,
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the address of that null-terminated string is pushed on the PSP and IP is
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advanced to the address following the null.
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*** Initialization sequence
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On boot, we jump to the "main" routine in boot.fs which does very few things.
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1. Set SP to 0x10000-6
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2. Sets HERE to RAMEND (RAMSTART+0x80).
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3. Sets CURRENT to value of LATEST field in stable ABI.
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4. Look for the word "BOOT" and calls it.
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In a normal system, BOOT is in icore and does a few things:
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1. Find "(parse)" and set "(parse*)" to it.
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2. Find "(c<)" a set CINPTR to it (what C< calls).
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3. Write LATEST in SYSTEM SCRATCHPAD ( see below )
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4. Find "INIT". If found, execute. Otherwise, execute "INTERPRET"
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On a bare system (only boot+icore), this sequence will result in "(parse)"
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reading only decimals and (c<) reading characters from memory starting from
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CURRENT (this is why we put CURRENT in SYSTEM SCRATCHPAD, it tracks current
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pos ).
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This means that you can put initialization code in source form right into your
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binary, right after your last compiled dict entry and it's going to be executed
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as such until you set a new (c<).
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Note that there is no EMIT in a bare system. You have to take care of supplying
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one before your load core.fs and its higher levels.
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In the "/emul" binaries, "HERE" is readjusted to "CURRENT @" so that we don't
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have to relocate compiled dicts. Note that in this context, the initialization
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code is fighting for space with HERE: New entries to the dict will overwrite
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that code! Also, because we're barebone, we can't have comments. This can lead
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to peculiar code in this area where we try to "waste" space in initialization
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code.
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