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jonesforth.S
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@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
@
@ Jones' Forth port for ARM EABI
@ Copyright (C) 2013 M2IHP'13 class, see AUTHORS for the full list of
@ contributors.
@
@ Original x86 and forth code: Richard W.M. Jones <[email protected]>
@
@ The extensive comments from Jones' x86 version have been removed. You should
@ check them out, they are really detailed, well written and pedagogical.
@
@ The DIVMOD routine is taken from the ARM Software Development Toolkit User
@ Guide 2.50.
@
@ This program is free software: you can redistribute it and/or modify it under
@ the terms of the GNU Lesser General Public License as published by the Free
@ Software Foundation, either version 3 of the License, or (at your option) any
@ later version.
@
@ This program is distributed in the hope that it will be useful, but WITHOUT
@ ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
@ FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more
@ details.
@
@ You should have received a copy of the GNU Lesser General Public License
@ along with this program. If not, see <http://www.gnu.org/licenses/>.
@
@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
.set JONES_VERSION,47
#include <asm/unistd.h>
@ Reserve three special registers:
@ DSP (r13) points to the top of the data stack
@ RSP (r11) points to the top of the return stack
@ IP (r10) points to the next forth word that will be executed
#define DSP r13
#define RSP r11
#define IP r10
@ Define stdin, stdout, stderr file descriptors numbers
.set stdin, 0
.set stdout, 1
.set stderr, 2
@ Implement NEXT, which:
@ 1. finds the address of the forth word to execute by
@ dereferencing the IP
@ 2. increment IP
@ 3. executes the forth word
.macro NEXT
ldr r0, [IP], #4
ldr r1, [r0]
bx r1
.endm
@ Define macros to push and pop from the data
@ and return stacks
.macro PUSHRSP reg
str \reg, [RSP, #-4]!
.endm
.macro POPRSP reg
ldr \reg, [RSP], #4
.endm
.macro push reg
str \reg, [DSP, #-4]!
.endm
.macro pop reg
ldr \reg, [DSP], #4
.endm
@ DOCOL is the assembly subroutine that is called
@ at the start of every forth word execution.
@ It saves the old IP on the return stack, and
@ makes IP point to the first codeword.
@ Then it calls NEXT to start interpreting the word.
.text
.align 2
DOCOL:
PUSHRSP IP
add IP, r0, #4
NEXT
@ _start is the program entry point
.text
.align 2
.global _start
_start:
ldr r0, =var_S0
str DSP, [r0] @ Save the original stack position in var_S0
ldr RSP, =return_stack_top @ Set the initial return stack position
bl set_up_data_segment @ Set up the data segment
ldr IP, =cold_start @ Make the IP point to cold_start
NEXT @ Start the interpreter
@ Allocate a data segment to define new words and data
@ structures
.set INITIAL_DATA_SEGMENT_SIZE,65536
.text
.align 2
set_up_data_segment:
mov r1, #0
mov r7, #__NR_brk
swi 0 @ Call brk(0) to get value of Program Break
ldr r1, =var_HERE
str r0, [r1] @ Initialize HERE to point at the beginning
@ of data segment
add r0, #INITIAL_DATA_SEGMENT_SIZE
swi 0 @ Allocate Memory
bx lr @ Return
@ cold_start is used to bootstrap the interpreter, the first word executed
@ is QUIT
.section .rodata
cold_start:
.int QUIT
@@ Now we define a set of helper macros that are syntactic sugar
@@ to ease the declaration of Forth words, Native words, Forth variables
@@ and Forth constants.
@ define the word flags
.set F_IMMED,0x80
.set F_HIDDEN,0x20
.set F_LENMASK,0x1f
@ link is used to chain the words in the dictionary as they are defined
.set link,0
@ defword macro helps defining new forth words in assembly
.macro defword name, namelen, flags=0, label
.section .rodata
.align 2
.global name_\label
name_\label :
.int link @ link
.set link,name_\label
.byte \flags+\namelen @ flags + length byte
.ascii "\name" @ the name
.align 2 @ padding to next 4 byte boundary
.global \label
\label :
.int DOCOL @ codeword - the interpreter
@ list of word pointers follow
.endm
@ defcode macro helps defining new native words in assembly
.macro defcode name, namelen, flags=0, label
.section .rodata
.align 2
.globl name_\label
name_\label :
.int link @ link
.set link,name_\label
.byte \flags+\namelen @ flags + length byte
.ascii "\name" @ the name
.align 2 @ padding to next 4 byte boundary
.global \label
\label :
.int code_\label @ codeword
.text
.global code_\label
code_\label : @ assembler code follows
.endm
@ defvar macro helps defining Forth variables in assembly
.macro defvar name, namelen, flags=0, label, initial=0
defcode \name,\namelen,\flags,\label
ldr r0, =var_\name
push r0
NEXT
.data
.align 2
var_\name :
.int \initial
.endm
@defconst macro helps defining Forth constants in assembly
.macro defconst name, namelen, flags=0, label, value
defcode \name,\namelen,\flags,\label
ldr r0, =\value
push r0
NEXT
.endm
@ EXIT is the last codeword of a forth word.
@ It restores the IP and returns to the caller using NEXT.
@ (See DOCOL)
defcode "EXIT",4,,EXIT
POPRSP IP
NEXT
@ DIVMOD computes the unsigned integer division and remainder
@ The implementation is based upon the algorithm extracted from 'ARM Software
@ Development Toolkit User Guide v2.50' published by ARM in 1997-1998
@ The algorithm is split in two steps: search the biggest divisor b^(2^n)
@ lesser than a and then subtract it and all b^(2^i) (for i from 0 to n)
@ to a.
@ ( a b -- r q ) where a = q * b + r
defcode "/MOD",4,,DIVMOD
pop r1 @ Get b
pop r0 @ Get a
mov r3, r1 @ Put b in tmp
cmp r3, r0, LSR #1
1: movls r3, r3, LSL #1 @ Double tmp
cmp r3, r0, LSR #1
bls 1b @ Jump until 2 * tmp > a
mov r2, #0 @ Initialize q
2: cmp r0, r3 @ If a - tmp > 0
subcs r0, r0, r3 @ a <= a - tmp
adc r2, r2, r2 @ Increment q
mov r3, r3, LSR #1 @ Halve tmp
cmp r3, r1 @ Jump until tmp < b
bhs 2b
push r0 @ Put r
push r2 @ Put q
NEXT
@ Alternative to DIVMOD: signed implementation using Euclidean division.
defcode "S/MOD",5,,SDIVMOD
@ Denominator
pop r2
@ Numerator
pop r1
bl _DIVMOD
@ Remainder
push r1
@ Quotient
push r0
NEXT
_DIVMOD:
@ Division by 0.
cmp r2, #0
beq 4f
@ r0 will store the quotient at the end.
mov r0, #0
@ r3 will be 1 if numerator and denominator have the same
@ sign, -1 otherwise.
@ r4 will be 1 if the numerator is positive, -1 otherwise.
mov r3, #1
mov r4, #1
rsblt r3, r3, #0 @ r3 = -r3 if negative denominator
rsblt r2, r2, #0 @ denominator = abs(denominator)
cmp r1, #0
rsblt r4, r4, #0 @ r4 = sign(numerator)
rsblt r3, r3, #0 @ r3 = -r3 if negative numerator
rsblt r1, r1, #0 @ numerator = abs(numerator)
cmp r3, #-1
beq 2f
1: @ Case where denominator and numerator have the same sign.
cmp r1, r2
blt 3f
11:
add r0, r0, #1
sub r1, r1, r2
cmp r1, r2
bge 11b
b 3f
2: @ Case where denominator and numerator have different sign.
cmp r1, #0
beq 3f
21:
sub r0, r0, #1
sub r1, r1, r2
cmp r1, #0
bgt 21b
3:
@ If numerator and denominator were negative:
@ remainder = -remainder
cmp r4, #-1
rsbeq r1, r1, #0
b 5f
4: @ Error, division by 0.
# Display error message on stderr.
mov r0, #stderr
ldr r1, =div0msg
mov r2, #div0msgend-div0msg
mov r7, #__NR_write
swi 0
5:
bx lr
.section .rodata
div0msg: .ascii "Division by 0!\n"
div0msgend:
@ DROP ( a -- ) drops the top element of the stack
defcode "DROP",4,,DROP
pop r0 @( )
NEXT
@ SWAP ( a b -- b a ) swaps the two top elements
defcode "SWAP",4,,SWAP
@ ( a b -- )
pop r0 @ ( a ) , r0 = b
pop r1 @ ( ) , r0 = b, r1 = a
push r0 @ ( b ) , r0 = b, r1 = a
push r1 @ ( b a ) , r0 = b, r1 = a
NEXT
@ DUP ( a -- a a ) duplicates the top element
defcode "DUP",3,,DUP
@ ( a -- )
pop r0 @ ( ) , r0 = a
push r0 @ ( a ) , r0 = a
push r0 @ ( a a ) , r0 = a
NEXT
@ OVER ( a b c -- a b c b ) pushes the second element on top
defcode "OVER",4,,OVER
@ ( a b c) r0 = b we take the element at DSP + 4
@ and since DSP is the top of the stack we will load
@ the second element of the stack in r0
ldr r0, [DSP, #4]
push r0 @ ( a b c b )
NEXT
@ ROT ( a b c -- b c a) rotation
defcode "ROT",3,,ROT
pop r0 @ ( a b ) r0 = c
pop r1 @ ( a ) r1 = b
pop r2 @ ( ) r2 = a
push r1 @ ( b )
push r0 @ ( b c )
push r2 @ ( b c a )
NEXT
@ -ROT ( a b c -- c a b ) backwards rotation
defcode "-ROT",4,,NROT
pop r0 @ ( a b ) r0 = c
pop r1 @ ( a ) r1 = b
pop r2 @ ( ) r2 = a
push r0 @ ( c )
push r2 @ ( c a )
push r1 @ ( c a b )
NEXT
@ ?DUP ( 0 -- 0 | a -- a a ) duplicates if non-zero
defcode "?DUP", 4,,QDUP
@ (x --)
ldr r0, [DSP] @ r0 = x
cmp r0, #0 @ test if x==0
beq 1f @ if x==0 we jump to 1
push r0 @ ( a a ) it's now duplicated
1: NEXT @ ( a a / 0 )
@ 1+ ( a | a+1 ) increments the top element
defcode "1+",2,,INCR
pop r0
add r0,r0,#1
push r0
NEXT
@ 1- ( a | a-1 ) decrements the top element
defcode "1-",2,,DECR
pop r0
sub r0,r0,#1
push r0
NEXT
@ 4+ ( a | a+4 ) increments by 4 the top element
defcode "4+",2,,INCR4
pop r0
add r0,r0,#4
push r0
NEXT
@ 4- ( a | a-4 ) decrements by 4 the top element
defcode "4-",2,,DECR4
pop r0
sub r0,r0,#4
push r0
NEXT
@ + ( a b | a+b)
defcode "+",1,,ADD
pop r0
pop r1
add r0,r0,r1
push r0
NEXT
@ + ( a b | a-b)
defcode "-",1,,SUB
pop r1
pop r0
sub r0,r0,r1
push r0
NEXT
@ + ( a b | a*b)
defcode "*",1,,MUL
pop r0
pop r1
mul r2,r0,r1
push r2
NEXT
@ = ( a b | p ) where p is 1 when a and b are equal (0 otherwise)
defcode "=",1,,EQU
pop r1
pop r0
cmp r0, r1
moveq r0, #1
movne r0, #0
push r0
NEXT
@ <> ( a b | p) where p = a <> b
defcode "<>",2,,NEQU
pop r1
pop r0
cmp r0, r1
movne r0, #1
moveq r0, #0
push r0
NEXT
@ < ( a b | p) where p = a < b
defcode "<",1,,LT
pop r1
pop r0
cmp r0, r1
movlt r0, #1
movge r0, #0
push r0
NEXT
@ < ( a b | p) where p = a < b
defcode ">",1,,GT
pop r1
pop r0
cmp r0, r1
movgt r0, #1
movle r0, #0
push r0
NEXT
@ <= ( a b | p) where p = a <= b
defcode "<=",2,,LE
pop r1
pop r0
cmp r0, r1
movle r0, #1
movgt r0, #0
push r0
NEXT
@ >= ( a b | p) where p = a >= b
defcode ">=",2,,GE
pop r1
pop r0
cmp r0, r1
movge r0, #1
movlt r0, #0
push r0
NEXT
@ AND ( a b | a&b) bitwise and
defcode "AND",3,,AND
pop r0
pop r1
and r0, r1, r0
push r0
NEXT
@ OR ( a b | a|b) bitwise or
defcode "OR",2,,OR
pop r0
pop r1
orr r0, r1, r0
push r0
NEXT
@ XOR ( a b | a^b) bitwise xor
defcode "XOR",3,,XOR
pop r0
pop r1
eor r0, r1, r0
push r0
NEXT
@ INVERT ( a | ~a ) bitwise not
defcode "INVERT",6,,INVERT
pop r0
mvn r0, r0
push r0
NEXT
@ LIT is used to compile literals in forth word.
@ When LIT is executed it pushes the literal (which is the next codeword)
@ into the stack and skips it (since the literal is not executable).
defcode "LIT", 3,, LIT
ldr r1, [IP], #4
push r1
NEXT
@ ! ( value address -- ) write value at address
defcode "!",1,,STORE
pop r0
pop r1
str r1, [r0]
NEXT
@ @ ( address -- value ) reads value from address
defcode "@",1,,FETCH
pop r1
ldr r0, [r1]
push r0
NEXT
@ C! and @! are the same for bytes
defcode "C!",2,,STOREBYTE
pop r0
pop r1
strb r1, [r0]
NEXT
defcode "C@",2,,FETCHBYTE
pop r0
mov r1, #0
ldrb r1, [r0]
push r1
NEXT
@ CMOVE ( source dest length -- ) copies a chunk of length bytes from source
@ address to dest address
defcode "CMOVE",5,,CMOVE
pop r0
pop r1
pop r2
1:
cmp r0, #0 @ while length > 0
ldrgtb r3, [r2], #1 @ read character from source
strgtb r3, [r1], #1 @ and write it to dest (increment both pointers)
subgt r0, r0, #1 @ decrement length
bgt 1b
NEXT
@ Define some variables and constants needed by the Forth interpreter
defvar "STATE",5,,STATE
defvar "HERE",4,,HERE
defvar "LATEST",6,,LATEST,name_SYSCALL0 @ must point to the last word
@ defined in assembly, SYSCALL0
defvar "S0",2,,SZ
defvar "BASE",4,,BASE,10
defconst "VERSION",7,,VERSION,JONES_VERSION
defconst "R0",2,,RZ,return_stack_top
defconst "DOCOL",5,,__DOCOL,DOCOL
defconst "F_IMMED",7,,__F_IMMED,F_IMMED
defconst "F_HIDDEN",8,,__F_HIDDEN,F_HIDDEN
defconst "F_LENMASK",9,,__F_LENMASK,F_LENMASK
defconst "SYS_EXIT",8,,SYS_EXIT,__NR_exit
defconst "SYS_OPEN",8,,SYS_OPEN,__NR_open
defconst "SYS_CLOSE",9,,SYS_CLOSE,__NR_close
defconst "SYS_READ",8,,SYS_READ,__NR_read
defconst "SYS_WRITE",9,,SYS_WRITE,__NR_write
defconst "SYS_CREAT",9,,SYS_CREAT,__NR_creat
defconst "SYS_BRK",7,,SYS_BRK,__NR_brk
defconst "O_RDONLY",8,,__O_RDONLY,0
defconst "O_WRONLY",8,,__O_WRONLY,1
defconst "O_RDWR",6,,__O_RDWR,2
defconst "O_CREAT",7,,__O_CREAT,0100
defconst "O_EXCL",6,,__O_EXCL,0200
defconst "O_TRUNC",7,,__O_TRUNC,01000
defconst "O_APPEND",8,,__O_APPEND,02000
defconst "O_NONBLOCK",10,,__O_NONBLOCK,04000
@ >R ( a -- ) move the top element from the data stack to the return stack
defcode ">R",2,,TOR
pop r0
PUSHRSP r0
NEXT
@ R> ( -- a ) move the top element from the return stack to the data stack
defcode "R>",2,,FROMR
POPRSP r0
push r0
NEXT
@ RDROP drops the top element from the return stack
defcode "RDROP",5,,RDROP
add RSP,RSP,#4
NEXT
@ RSP@, RSP!, DSP@, DSP! manipulate the return and data stack pointers
defcode "RSP@",4,,RSPFETCH
push RSP
NEXT
defcode "RSP!",4,,RSPSTORE
pop RSP
NEXT
defcode "DSP@",4,,DSPFETCH
mov r0, DSP
push r0
NEXT
defcode "DSP!",4,,DSPSTORE
pop r0
mov r0, DSP
NEXT
@ KEY ( -- c ) Reads a key from the user
@ the implementation uses a cached buffer that is
@ refilled, when empty, with a read syscall.
defcode "KEY",3,,KEY
bl _KEY @ Call _KEY
push r0 @ push the return value on the stack
NEXT
_KEY:
ldr r3, =currkey @ Load the address of currkey
ldr r1, [r3] @ Get the value of currkey
ldr r3, =bufftop @ Load the address of bufftop
ldr r2, [r3] @ Get the value of bufftop
cmp r2, r1
ble 1f @ if bufftop <= currkey
ldrb r0, [r1] @ load the first byte of currkey
ldr r3, =currkey
add r1, #1 @ Increments CURRKEY
str r1, [r3]
bx lr @ return
1:
ldr r3, =currkey
mov r0, #0 @ 1st arg: STDIN
ldr r1, =buffer @ 2nd arg : buffer add
str r1, [r3] @ CURRKEY := BUFFER
mov r2, #BUFFER_SIZE @ 3rd arg : buffer sz
mov r7, #__NR_read @ read syscall flag
swi 0 @ call
cmp r0, #0
ble 2f @ if errors goto 2
add r1,r0 @ Set bufftop at the end of the word
ldr r4, =bufftop
str r1, [r4] @ update bufftop
b _KEY
2: @ read syscall returned with an error
mov r0, #0
mov r7, #__NR_exit @ exit(0)
swi 0
@ buffer for KEY
.data
.align 2
currkey:
.int buffer
bufftop:
.int buffer
@ EMIT ( c -- ) outputs character c to stdout
defcode "EMIT",4,,EMIT
pop r0
bl _EMIT
NEXT
_EMIT:
ldr r2, =emit_scratch
str r0, [r2] @ write character to memory
mov r1, r2
mov r2, #1 @ write 1 byte
mov r0, #stdout @ write on standard output
mov r7, #__NR_write @ write syscall flag
swi 0 @ write syscall
bx lr
.data
emit_scratch:
.space 1
@ WORD ( -- addr length ) reads next word from stdin
@ skips spaces and comments, limited to 32 characters
defcode "WORD",4,,WORD
bl _WORD
push r0 @ adress
push r1 @ length
NEXT
_WORD:
stmfd sp!, {r6,lr} @ preserve r6 and lr
1:
bl _KEY @ read a character
cmp r0, #'\\'
beq 3f @ skip comments until end of line
cmp r0, #' '
ble 1b @ skip blank character
ldr r6, =word_buffer
2:
strb r0, [r6], #1 @ store character in word buffer
bl _KEY @ read more characters until a space is found
cmp r0, #' '
bgt 2b
ldr r0, =word_buffer @ r0, address of word
sub r1, r6, r0 @ r1, length of word
ldmfd sp!, {r6,lr} @ restore r6 and lr
bx lr
3:
bl _KEY @ skip all characters until end of line
cmp r0, #'\n'
bne 3b
b 1b
@ word_buffer for WORD
.data
word_buffer:
.space 32
@ NUMBER ( addr length -- n e ) converts string to number
@ n is the parsed number
@ e is the number of unparsed characters
defcode "NUMBER",6,,NUMBER
pop r1
pop r0
bl _NUMBER
push r0
push r1
NEXT
_NUMBER:
stmfd sp!, {r4-r6, lr}
@ Save address of the string.
mov r2, r0
@ r0 will store the result after conversion.
mov r0, #0
@ Check if length is positive, otherwise this is an error.
cmp r1, #0
ble 5f
@ Load current base.
ldr r3, =var_BASE
ldr r3, [r3]
@ Load first character and increment pointer.
ldrb r4, [r2], #1
@ Check trailing '-'.
mov r5, #0
cmp r4, #45 @ 45 in '-' en ASCII
@ Number is positive.
bne 2f
@ Number is negative.
mov r5, #1
sub r1, r1, #1
@ Check if we have more than just '-' in the string.
cmp r1, #0
@ No, proceed with conversion.
bgt 1f
@ Error.
mov r1, #1
b 5f
1:
@ number *= BASE
@ Arithmetic shift right.
@ On ARM we need to use an additional register for MUL.
mul r6, r0, r3
mov r0, r6
@ Load the next character.
ldrb r4, [r2], #1
2:
@ Convert the character into a digit.
sub r4, r4, #48 @ r4 = r4 - '0'
cmp r4, #0
blt 4f @ End, < 0
cmp r4, #9
ble 3f @ chiffre compris entre 0 et 9
@ Test if hexadecimal character.
sub r4, r4, #17 @ 17 = 'A' - '0'
cmp r4, #0
blt 4f @ End, < 'A'
add r4, r4, #10
3:
@ Compare to the current base.
cmp r4, r3
bge 4f @ End, > BASE
@ Everything is fine.
@ Add the digit to the result.
add r0, r0, r4
sub r1, r1, #1
@ Continue processing while there are still characters to read.
cmp r1, #0
bgt 1b
4:
@ Negate result if we had a '-'.
cmp r5, #1
rsbeq r0, r0, #0
5:
@ Back to the caller.
ldmfd sp!, {r4-r6, pc}
@ FIND ( addr length -- dictionary_address )
@ Tries to find a word in the dictionary and returns its address.
@ If the word is not found, NULL is returned.
defcode "FIND",4,,FIND
pop r1 @length
pop r0 @addr
bl _FIND
push r0
NEXT
_FIND:
stmfd sp!, {r5,r6,r8,r9} @ save callee save registers
ldr r2, =var_LATEST
ldr r3, [r2] @ get the last defined word address
1:
cmp r3, #0 @ did we check all the words ?
beq 4f @ then exit
ldrb r2, [r3, #4] @ read the length field
and r2, r2, #(F_HIDDEN|F_LENMASK) @ keep only length + hidden bits
cmp r2, r1 @ do the lengths match ?
@ (note that if a word is hidden,
@ the test will be always negative)
bne 3f @ branch if they do not match
@ Now we compare strings characters
mov r5, r0 @ r5 contains searched string
mov r6, r3 @ r6 contains dict string
add r6, r6, #5 @ (we skip link and length fields)
@ r2 contains the length
2:
ldrb r8, [r5], #1 @ compare character per character
ldrb r9, [r6], #1
cmp r8,r9
bne 3f @ if they do not match, branch to 3
subs r2,r2,#1 @ decrement length
bne 2b @ loop
@ here, strings are equal
b 4f @ branch to 4
3:
ldr r3, [r3] @ Mismatch, follow link to the next
b 1b @ dictionary word
4:
mov r0, r3 @ move result to r0
ldmfd sp!, {r5,r6,r8,r9} @ restore callee save registers
bx lr
@ >CFA ( dictionary_address -- executable_address )
@ Transformat a dictionary address into a code field address
defcode ">CFA",4,,TCFA
pop r0
bl _TCFA
push r0
NEXT
_TCFA:
add r0,r0,#4 @ skip link field
ldrb r1, [r0], #1 @ load and skip the length field
and r1,r1,#F_LENMASK @ keep only the length
add r0,r0,r1 @ skip the name field
add r0,r0,#3 @ find the next 4-byte boundary
and r0,r0,#~3
bx lr
@ >DFA ( dictionary_address -- data_field_address )
@ Return the address of the first data field
defword ">DFA",4,,TDFA
.int TCFA
.int INCR4
.int EXIT
@ CREATE ( address length -- ) Creates a new dictionary entry
@ in the data segment.
@ CREATE ( address length -- ) Creates a new dictionary entry
@ in the data segment.
defcode "CREATE",6,,CREATE
pop r1 @ length of the word to insert into the dictionnary
pop r0 @ address of the word to insert into the dictionnary
ldr r2,=var_HERE
ldr r3,[r2] @ load into r3 and r8 the location of the header
mov r8,r3
ldr r4,=var_LATEST
ldr r5,[r4] @ load into r5 the link pointer
str r5,[r3] @ store link here -> last
add r3,r3,#4 @ skip link adress
strb r1,[r3] @ store the length of the word