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A ~C! override can, if it wants, go put an error code in there, which ~AT28 does. This way, after a copy or xcomp process directly to EEPROM, one can verify whether all bytes were successfully written by checking whether "~C!ERR C@" is zero.
265 lines
9.5 KiB
Plaintext
265 lines
9.5 KiB
Plaintext
# Implementation notes
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# Execution model
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After having read a line through readln, we want to interpret
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it. As a general 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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# What is a word?
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A word is a place in memory having a particular structure. Its
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first byte is a "word type" byte (see below), followed by a
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structure that depends on the word type. This structure is
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generally refered to as the Parameter Field (PF).
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# Stack management
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In all supported arches, The Parameter Stack and Return Stack
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tops are tracked by a registered assigned to this purpose. For
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example, in z80, it's SP and IX that do that. The value in those
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registers are referred to as PS Pointer (PSP) and RS Pointer
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(RSP).
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Those stacks are contiguous and grow in opposite directions. PS
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grows "down", RS grows "up".
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Stack underflow and overflow: In each native word involving
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PS popping, we check whether the stack is big enough. If it's
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not we go in "uflw" (underflow) error condition, then abort.
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This means that if you implement a native word that involves
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popping from PS, you are expected to call chkPS, for under-
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flow situations.
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We don't check RS for underflow because the cost of the check
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is significant and its usefulness is dubious: if RS isn't
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tightly in control, we're screwed anyways, and that, well
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before we reach underflow.
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Overflow condition happen when RSP and PSP meet somewhere in
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the middle. That check is made at each "next" call.
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# Dictionary entry
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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
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bigger than input buffer, of course). not null-terminated
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- 2b prev offset
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- 1b name size + IMMEDIATE flag (7th bit)
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- 1b entry type
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- Parameter field (PF)
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The prev offset is the number of bytes between the prev field
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and the previous word's entry type.
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The size + flag indicate the size of the name field, with the
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7th bit being the IMMEDIATE flag.
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The entry type is simply a number corresponding to a type which
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will determine how the word will be executed. See "Word types"
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below.
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The vast majority of the time, a dictionary entry refers to a
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word. However, sometimes, it refers to something else. A "hook
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word" (see bootstrap.txt) is such an example.
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# Word types
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There are 6 word types in Collapse OS. Whenever you have a
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wordref, it's pointing to a byte with numbers 0 to 5. This
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number is the word type and the word's behavior depends on it.
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0: native. This words PFA contains native binary code and is
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jumped to directly.
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1: compiled. This word's PFA contains a list of wordrefs and its
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execution is described in "Executing a compiled word" below.
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2: cell. This word is usually followed by a 2-byte value in its
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PFA. Upon execution, the address of the PFA is pushed to PS.
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3: DOES>. This word is created by "DOES>" and is followed
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by a 2-bytes value as well as the address where "DOES>" was
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compiled. At that address is an wordref list exactly like in a
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compiled word. Upon execution, after having pushed its cell
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addr to PSP, it executes its reference exactly like a
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compiled word.
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4: alias. See usage.txt. PFA is like a cell, but instead of
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pushing it to PS, we execute it.
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5: ialias. Same as alias, but with an added indirection.
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# Executing a compiled word
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At its core, executing a word is pushing the wordref on PS and
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calling EXECUTE. Then, we let the word do its things. Some
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words are special, but most of them are of the "compiled"
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type, and that's their execution that we describe here.
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First of all, at all time during execution, the Interpreter
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Pointer (IP) points to the wordref we're executing next.
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When we execute a compiled word, the first thing we do is push
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IP to the Return Stack (RS). Therefore, RS' top of stack will
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contain a wordref to execute next, after we EXIT.
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At the end of every compiled word is an EXIT. This pops RS, sets
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IP to it, and continues.
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A compiled word is simply a list of wordrefs, but not all those
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wordrefs are 2 bytes in length. Some wordrefs are special. For
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example, a reference to (n) will be followed by an extra 2 bytes
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number. It's the responsibility of the (n) word to advance IP
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by 2 extra bytes.
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To be clear: It's not (n)'s word type that is special, it's a
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regular "native" word. It's the compilation of the (n) type,
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done in LITN, that is special. We manually compile a number
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constant at compilation time, which is what is expected in (n)'s
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implementation. Similar special things happen in (s), (br),
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(?br) and (loop).
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For example, the word defined by ": FOO 42 EMIT ;" would have
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an 8 bytes PF: a 2b ref to (n), 2b with 0x002a, a 2b ref to EMIT
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and then a 2b ref to EXIT.
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When executing this word, we first set IP to PF+2, then exec
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PF+0, that is, the (n) reference. (n), when executing, reads IP,
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pushes that value to PS, then advances IP by 2. This means that
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when we return to the "next" routine, IP points to PF+4, which
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next will execute. Before executing, IP is increased by 2, but
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it's the "not-increased" value (PF+4) that is executed, that is,
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EMIT. EMIT does its thing, doesn't touch IP, then returns to
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"next". We're still at PF+6, which then points to EXIT. EXIT
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pops RS into IP, which is the value that IP had before FOO was
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called. The "next" dance continues...
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# System variables
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There are some core variables in the core system that are
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referred to directly by their address in memory throughout the
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code. The place where they live is configurable by the SYSVARS
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constant in xcomp unit, but their relative offset is not. In
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fact, they're mostly referred to directly as their numerical
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offset along with a comment indicating what this offset refers
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to.
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This system is a bit fragile because every time we change those
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offsets, we have to be careful to adjust all system variables
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offsets, but thankfully, there aren't many system variables.
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Here's a list of them:
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SYSVARS FUTURE USES +3c BLK(*
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+02 CURRENT +3e ~C!*
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+04 HERE +41 ~C!ERR
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+06 C<? +42 FUTURE USES
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+08 C<* override +43 FUTURE USES
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+0a NL ialias +51 CURRENTPTR
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+0c C<* +53 EMIT ialias
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+0e WORDBUF +55 KEY ialias
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+2e BOOT C< PTR +57 FUTURE USES
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+30 IN>
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+32 IN(* +70 DRIVERS
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+34 BLK@* +80 RAMEND
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+36 BLK!*
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+38 BLK>
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+3a BLKDTY
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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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C<* holds routine address called on C<. If the C<* override
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at 0x08 is nonzero, this routine is called instead.
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IN> is the current position in IN(, which is the input buffer.
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IN(* is a pointer to the input buffer, allocated at runtime.
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CURRENTPTR points to current CURRENT. The Forth CURRENT word
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doesn't return RAM+2 directly, but rather the value at this
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address. Most of the time, it points to RAM+2, but sometimes,
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when maintaining alternative dicts (during cross compilation
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for example), it can point elsewhere.
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BLK* "Disk blocks" in usage.txt.
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~C!* if nonzero, contains a jump to assembly code that overrides
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the routine that writes a byte to memory and then returns.
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Register usage is arch-dependent, see boot code for details.
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~C!ERR: When an error happens during ~C! write overrides, sets
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this byte to a nonzero value. Otherwise, stays at zero. Has to
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be reset to zero manually after an error.
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DRIVERS section is reserved for recipe-specific drivers.
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FUTURE USES section is unused for now.
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# Initialization sequence
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(this describes the z80 boot sequence, but other arches have
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a very similar sequence, and, of course, once we enter Forth
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territory, identical)
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On boot, we jump to the "main" routine in B289 which does
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very few things.
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1. Set SP to PS_ADDR and IX to RS_ADDR.
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2. Set CURRENT to value of LATEST field in stable ABI.
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3. Set HERE to HERESTART const if defined, to CURRENT other-
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wise.
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4. Initialize ~C! and ~C!ERR to 0.
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5. Execute the word referred to by 0x04 (BOOT) in stable ABI.
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In a normal system, BOOT is in core words at B396 and does a
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few things:
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1. Initialize a few core variables:
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CURRENT* -> CURRENT (RAM+02)
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BOOT C< PTR -> LATEST
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C<* override -> 0
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2. Initialized ialiases in this way:
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EMIT -> (emit)
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KEY -> (key)
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NL -> CRLF
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3. Set "C<*", the word that C< calls, to (boot<).
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4. Call INTERPRET which interprets boot source code until
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ASCII EOT (4) is met. This usually initializes drivers.
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5. Initialize rdln buffer, _sys entry (for EMPTY), prints
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"CollapseOS" and then calls (main).
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6. (main) interprets from rdln input (usually from KEY) until
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EOT is met, then calls BYE.
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If, for some reason, you need to override an ialias at some
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point, you de-override it by re-setting it to the address of
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the word specified at step 2.
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# Stable ABI
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The Stable ABI lives at the beginning of the binary and prov-
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ides a way for Collapse OS code to access values that would
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otherwise be difficult to access. Here's the complete list of
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these references:
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04 BOOT addr 06 (uflw) addr 08 LATEST
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13 (oflw) addr 1a next addr
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BOOT, (uflw) and (oflw) exist because they are referred to
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before those words are defined (in core words). LATEST is a
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critical part of the initialization sequence.
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All Collapse OS binaries, regardless of architecture, have
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those values at those offsets of them. Some binaries are built
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to run at offset different than zero. This stable ABI lives at
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that offset, not 0.
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