;tree { search-key 2 max-key-len 1 } ;assembler { pass 1 state 1 token 2 scope-len 1 scope 80 heap 2 addr 2 subtree 2 vartmp 2 } %HCF { #0000 DIV } %SHORT_FLAG { #20 } %RETURN_FLAG { #40 } ( devices ) |0100 ;System { vector 2 pad 6 r 2 g 2 b 2 } |0110 ;Console { vector 2 pad 6 char 1 byte 1 short 2 string 2 } |0120 ;Screen { vector 2 width 2 height 2 pad 2 x 2 y 2 addr 2 color 1 } |0130 ;Audio { wave 2 envelope 2 pad 4 volume 1 pitch 1 play 1 value 2 delay 2 finish 1 } |0140 ;Controller { vector 2 button 1 key 1 } |0160 ;Mouse { vector 2 x 2 y 2 state 1 chord 1 } |0170 ;File { vector 2 pad 6 name 2 length 2 load 3 save 2 } |01a0 ;DateTime { year 2 month 1 day 1 hour 1 minute 1 second 1 dotw 1 doty 2 isdst 1 refresh 1 } ( vectors ) |0200 ^RESET JMP @RESET ,assembler-heap-start =assembler.heap #0070 =assembler.addr ,$read-filename =File.name #1000 =File.length #f000 =File.load #f000 #1000 ^assemble-chunk JSR HCF $read-filename [ etc/assembler-test.usm 00 ] @assemble-chunk ( ptr* len* -- 00 if EOF found in chunk OR assembled-up-to-ptr* 01 if reached end of chunk ) OVR2 ADD2 STH2 #0001 SUB2 $per-token DUP2 STH2 $loop #0001 ADD2 DUP2 PEK2 #20 GTH ^$loop JNZ DUP2 OVR2r STH2r LTS2 ^$valid JNZ SWP2r POP2r POP2 STH2r #0001 ADD2 #01 JMP2r $valid DUP2 PEK2 #00 OVR2 POK2 STH2r #0001 ADD2 ^assemble-token JSR ^$per-token JNZ POP2 POP2r #00 JMP2r @assemble-macro ( macro-ptr* -- ) DUP2 ,strlen JSR2 DUP2 #0000 EQU2 ^$end JNZ OVR2 ^assemble-token JSR ADD2 #0001 ADD2 ^assemble-macro JMP $end POP2 POP2 JMP2r @assemble-token ( string-ptr* -- ) ( get location of tree ) DUP2 ,state-machine-pointers #00 ~assembler.state ,highest-bit JSR2 #0004 MUL2 ADD2 DUP2 STH2 ( see if first char is recognised ) SWP2 #01 ,traverse-tree JSR2 ^$not-found JNZ ( skip first character of token ) SWP2 #0001 ADD2 =assembler.token ( tail call handling function defined in tree ) POP2r JMP2 $not-found ( not interested in incoming-ptr ) POP2 =assembler.token ( tail call default handling function defined in state-machine-pointers ) LIT2r [ 0002 ] ADD2r LDR2r JMP2r @parse-hex-length ( string-ptr* -- value 01 if one or two hex digits OR 00 otherwise ) DUP2 #0001 ADD2 PEK2 ^parse-hex-string-try-two JNZ PEK2 ^parse-hex-digit JSR DUP #04 SFT ^parse-hex-string-fail1 JNZ #01 JMP2r @parse-hex-string ( string-ptr* -- value* 02 if four hex digits OR value 01 if two hex digits OR 00 otherwise ) DUP2 #0004 ADD2 PEK2 #00 EQU ^$try-four JNZ $try-two DUP2 #0002 ADD2 PEK2 ^$fail2 JNZ $known-two DUP2 PEK2 ^parse-hex-digit JSR DUP #04 SFT ^$fail3 JNZ ROT ROT #0001 ADD2 PEK2 ^parse-hex-digit JSR DUP #04 SFT ^$fail2 JNZ SWP #40 SFT ORA #01 JMP2r $fail3 POP $fail2 POP $fail1 POP #00 JMP2r $try-four DUP2 #0002 ADD2 ^$known-two JSR ^$maybe-four JNZ ^$try-two JMP $maybe-four ROT ROT ^$known-two JSR ^$four JNZ ^$fail1 JMP $four SWP #02 JMP2r @parse-hex-digit ( charcode -- 00-0f if valid hex -- 10-ff otherwise ) DUP #3a LTH ^$digit JNZ DUP #60 GTH ^$lowercase JNZ DUP #40 GTH ^$uppercase JNZ JMP2r $digit ( #30 is #00 ) #30 SUB JMP2r $lowercase ( #61 is #0a ) #57 SUB JMP2r $uppercase ( #41 is #0a ) #37 SUB JMP2r @find-opcode ( name* -- byte 00 if valid opcode name OR 01 if not found ) ,opcodes-tree SWP2 #03 ^traverse-tree JSR ^$nomatch JNZ ,opcodes-asm SUB2 #0007 DIV2 SWP JMP2r $nomatch DUP2 EQU2 JMP2r @traverse-tree ( tree-ptr* search-key* max-key-len -- binary-ptr* 00 if key matched OR incoming-ptr* 01 if key not found ) =tree.max-key-len =tree.search-key $loop DUP2 LDR2 #0000 NEQ2 ^$valid-node JNZ #01 JMP2r $valid-node LDR2 DUP2 STH2 #0004 ADD2 ^strcmp-tree JSR DUP ^$nomatch JNZ POP2r JMP2r $nomatch #07 SFT #02 MUL #00 SWP STH2r ADD2 ^$loop JMP @strcmp-tree ( node-key* -- order if strings differ OR after-node-key* 00 if strings match ) ~tree.search-key STH2 ~tree.max-key-len $loop ( node-key* key-len in wst, search-key* in rst ) DUP ^$keep-going JNZ ( exhausted key-len, match found ) POP2r JMP2r $keep-going #01 OVR2 PEK2 DUP2r PEK2r STHr DUP2 ORA ^$not-end JNZ ( end of C strings, match found ) POP2r POP ROT POP SWP ADD2 #00 JMP2r $not-end SUB DUP ^$nomatch JNZ POP SUB LIT2r [ 0001 ] ADD2r STH LIT2 [ 0001 ] ADD2 STHr ^$loop JMP $nomatch STH POP2 POP2 STHr POP2r JMP2r @highest-bit ( n -- 00 if n is 00 OR 01 if n is 01 OR 02 if n is 02..03 OR 03 if n is 04..07 OR 04 if n is 08..0f .. OR 08 if n is 80..ff ) DUP #00 NEQ JMP JMP2r DUP #01 SFT ORA DUP #02 SFT ORA DUP #04 SFT ORA #1d MUL #05 SFT #00 SWP ,$lookup ADD2 PEK2 JMP2r $lookup [ 01 06 02 07 05 04 03 08 ] @memcpy ( src-ptr* dest-ptr* length* -- after-dest-ptr* ) SWP2 STH2 $loop DUP2 ORA ^$keep-going JNZ POP2 POP2 STH2r JMP2r $keep-going #0001 SUB2 SWP2 DUP2 PEK2 DUP2r STH2r POK2 #0001 ADD2 SWP2 LIT2r [ 0001 ] ADD2r ^$loop JMP @strcpy ( src-ptr* dest-ptr* -- after-dest-ptr* ) OVR2 ^strlen JSR #0001 ADD2 ^memcpy JMP @strlen ( string-ptr* -- length* ) DUP2 #0001 SUB2 $loop #0001 ADD2 DUP2 PEK2 ^$loop JNZ SWP2 SUB2 JMP2r @append-heap ( string-ptr* -- after-string-ptr* ) ~assembler.heap ,strcpy JSR2 DUP2 =assembler.heap JMP2r @append-tree ( string-ptr* incoming-ptr* -- binary-data* ) ~assembler.heap SWP2 STR2 ,$zero-pointers ~assembler.heap #0004 ^memcpy JSR =assembler.heap ^append-heap JSR JMP2r $zero-pointers [ 0000 0000 ] @add-label ( label-flags string-ptr* tree-ptr* -- ) OVR2 #ff ,traverse-tree JSR2 ^$new-label JNZ ( label already exists, check the flags and addr value ) SWP2 POP2 DUP2 #0001 ADD2 LDR2 ~assembler.addr EQU2 ^$addr-okay JNZ ( FIXME address is different to previous run, or label defined twice ) $addr-okay PEK2 EQU ^$type-okay JNZ ( FIXME node type is different to before ) $type-okay JMP2r $new-label ^append-tree JSR ( ~assembler.heap SWP2 STR2 ,$zero-pointers ~assembler.heap #0004 ^memcpy JSR =assembler.heap ~assembler.heap ,strcpy JSR2 ) DUP2 STH2 POK2 STH2r DUP2 #0001 ADD2 ~assembler.addr SWP2 STR2 #0003 ADD2 =assembler.heap JMP2r @lookup-label ( string-ptr* -- address* node-type if found OR false-address* 00 if not found ) ( FIXME deal with dotted labels ) DUP2 ,label-tree SWP2 #ff ,traverse-tree JSR2 ^$not-found JNZ SWP2 POP2 DUP2 #0001 ADD2 LDR2 SWP2 PEK2 JMP2r $not-found POP2 ( FIXME complain about missing label ) POP2 ( false-address is out of reach for JMP ) ~assembler.addr #8765 ADD2 #00 JMP2r @write-byte ( byte -- ) ( FIXME ) =Console.byte ~assembler.addr #0001 ADD2 =assembler.addr JMP2r @write-short ( short -- ) ( FIXME ) =Console.short ~assembler.addr #0002 ADD2 =assembler.addr JMP2r @label-tree .l-root @macro-tree [ 0000 ] @opcodes ( The code for this section is automatically generated, and needs to be regenerated when the opcode list in src/assembler.c is updated. After editing src/assembler.c, run "lua etc/assembler-trees.lua" and this file will be edited automatically. This is the first example of a binary tree in this code, so let's explore them in general. The format of a tree node in memory is: left-node* right-node* node-key-cstring binary-data and the general algorithm is to compare the key you're looking for against node-key-cstring, and move to the node pointed to by left-node* or right-node* if the keys don't match. If your key sorts earlier than use left-node*, otherwise go to right-node*. When you find a node that matches your key, traverse-bintree gives you a pointer to the binary-data straight after the node-key-cstring. This data can contain anything you want: fixed length fields, executable code... in this case of this opcode tree, we store nothing. traverse-bintree is passed the maximum length of node-key-cstring, not including the zero, so the zero can be omitted if the string is at that maximum length. If the key isn't present in the tree, you'll eventually get to a node where the left-node* or right-node* pointer you'll need to follow is null (0000). traverse-bintree will give you the location of that pointer, so if you want to insert another node, you can write it to the heap and overwrite the pointer with the new node's location. This approach works even if the tree is completely empty and the pointer you've provided to the root node is null, since that pointer gets updated to point to the first node without needing any special logic. The ordering of nodes in memory is totally arbitrary, so for pre- prepared trees like this one we can have our own meaning for the order of the nodes. By ordering the opcodes by their byte value, we can find the byte by subtracting $asm from the binary-data pointer and dividing by seven (the size of each node). By multiplying the byte value by seven and adding to $disasm, we get the opcode name when disassembling too. ) $tree .$op-lth ( opcode tree ) $start $op-brk .$op-add .$op-dup $disasm [ BRK ] $asm $op-nop .$op-mul .$op-ovr [ NOP ] $op-lit [ 0000 ] [ 0000 ] [ LIT ] $op-pop [ 0000 ] [ 0000 ] [ POP ] $op-dup .$op-div .$op-eor [ DUP ] $op-swp [ 0000 ] [ 0000 ] [ SWP ] $op-ovr .$op-ora .$op-pek [ OVR ] $op-rot .$op-pop .$op-sft [ ROT ] $op-equ .$op-brk .$op-jnz [ EQU ] $op-neq [ 0000 ] [ 0000 ] [ NEQ ] $op-gth [ 0000 ] [ 0000 ] [ GTH ] $op-lth .$op-equ .$op-pok [ LTH ] $op-gts .$op-gth .$op-jmp [ GTS ] $op-lts [ 0000 ] [ 0000 ] [ LTS ] [ 0000 ] [ 0000 ] [ ??? ] [ 0000 ] [ 0000 ] [ ??? ] $op-pek [ 0000 ] [ 0000 ] [ PEK ] $op-pok .$op-nop .$op-sth [ POK ] $op-ldr .$op-jsr .$op-lit [ LDR ] $op-str [ 0000 ] [ 0000 ] [ STR ] $op-jmp [ 0000 ] [ 0000 ] [ JMP ] $op-jnz .$op-gts .$op-ldr [ JNZ ] $op-jsr [ 0000 ] [ 0000 ] [ JSR ] $op-sth .$op-rot .$op-sub [ STH ] $op-add [ 0000 ] .$op-and [ ADD ] $op-sub .$op-str .$op-swp [ SUB ] $op-mul .$op-lts .$op-neq [ MUL ] $op-div [ 0000 ] [ 0000 ] [ DIV ] $op-and [ 0000 ] [ 0000 ] [ AND ] $op-ora [ 0000 ] [ 0000 ] [ ORA ] $op-eor [ 0000 ] [ 0000 ] [ EOR ] $op-sft [ 0000 ] [ 0000 ] [ SFT ] @state-machine-pointers ( normal mode 00 ) .normal-root .normal-main ( macro definition 01 ) .macro-root .macro-main ( macro definition, contents ignored 02 ) .macro-root .ignore ( variable definition, expect field size 04 ) .variable-nul .variable-size ( variable definition, expect field name 08 ) .variable-root .variable-name ( reserved for future use 10 ) [ 0000 ] .ignore ( literal data 20 ) .normal-] .data-main ( reserved for future use 40 ) [ 0000 ] .ignore ( comment 80 ) .normal-) .ignore ( Next up, we have the tree of code corresponding to each token's first character. Here we do have a binary payload, which is the code to run when the assembler considers the token. Some special assembler modes have their own trees. Since comments have a very simple tree that only understands the end of comments, we reuse the terminal branch of the main tree as the root of the comment tree. ) ( Left and right parentheses start and end comment sections. They use the highest bit in assembler state, so they receive highest priority: it doesn't matter what other bits are set, a comment's a comment. ) @normal-( [ 0000 ] .normal-) [ 28 ] ~assembler.state #80 ORA =assembler.state JMP2r @normal-) [ 0000 ] [ 0000 ] [ 29 ] ~assembler.state #7f AND =assembler.state JMP2r ( Ampersands introduce global labels, and define the scope for any local labels that follow. ) @normal-@ [ 0000 ] [ 0000 ] [ 40 ] #00 ~assembler.token ,label-tree ,add-label JSR2 $scope ~assembler.token ,assembler.scope ,strcpy JSR2 DUP2 ,assembler.scope SUB2 =assembler.scope-len POP #0001 SUB2 #2d SWP POK POP JMP2r ( Dollar signs introduce local labels, which use the scope defined above. ) @normal-$ .normal-" .normal-, [ 24 ] ~assembler.token ,assembler.scope ~assembler.scope-len ADD ,strcpy JSR2 POP2 #00 ,assembler.scope ,label-tree ,add-label JMP2 ( tail call ) ( Hash signs followed by two or four hex digits write a literal. ) @normal-# [ 0000 ] [ 0000 ] [ 23 ] ~assembler.token ,parse-hex-string JSR2 DUP ^$valid JNZ ( FIXME complain about invalid hex literal ) POP JMP2r $valid DUP #01 SUB SHORT_FLAG MUL ( short flag for opcode ) ,opcodes-op-lit ,opcodes-start SUB2 #07 DIV ADD ADD ,write-byte JSR2 $value #02 EQU ^$short JNZ ,write-byte JMP2 ( tail call ) $short ,write-short JMP2 ( tail call ) ( Left and right square brackets start and end literal data sections. ) @normal-[ .normal-@ .normal-] [ 5b ] ~assembler.state #20 ORA =assembler.state JMP2r @normal-] [ 0000 ] [ 0000 ] [ 5d ] ( this is spurious, but ignore it anyway ) JMP2r @data-] .normal-( [ 0000 ] [ 5d ] ~assembler.state #df AND =assembler.state JMP2r @data-root @data-nul [ 0000 ] .data-] [ 00 ] JMP2r @data-main ~assembler.token ,parse-hex-string JSR2 DUP ^normal-#-value JNZ POP ~assembler.token $loop DUP2 PEK2 DUP ^$keep-going JNZ POP POP2 JMP2r $keep-going ,write-byte JSR2 #0001 ADD2 ^$loop JMP ( A pipe moves the current address to the hex value given. ) @normal-| .normal-{ .normal-} [ 7c ] ~assembler.token ,parse-hex-string JSR2 DUP #02 EQU ^$valid JNZ #00 EQU JMP POP ( FIXME complain about invalid hex literal ) JMP2r $valid POP DUP2 ~assembler.addr LTH2 ^$backwards JNZ ( FIXME add zeroes when writing ) =assembler.addr JMP2r $backwards ( FIXME complain about going backwards ) POP2 JMP2r ( Commas and dots write the label address - the comma precedes this with a LIT2 opcode. ) @normal-, .normal-% .normal-dot [ 2c ] ,opcodes-op-lit ,opcodes-start SUB2 #07 DIV SHORT_FLAG ADD ,write-byte JSR2 POP ^normal-dot-main JMP @normal-dot [ 0000 ] .normal-; [ 2e ] $main ~assembler.token ,lookup-label JSR2 POP ( don't care about node type ) ,write-short JMP2 ( tail call ) ( Caret writes LIT, followed by the label address as an offset. ) @normal-^ .normal-[ .normal-| [ 5e ] ,opcodes-op-lit ,opcodes-start SUB2 #07 DIV ,write-byte JSR2 POP ~assembler.token ,lookup-label JSR2 POP ( don't care about node type ) ~assembler.addr SUB2 DUP2 #ff79 GTH2 ^$okay JNZ DUP2 #0080 LTH2 ^$okay JNZ ( FIXME complain about jump being too far ) $okay ,write-byte JSR2 POP JMP2r ( Tilde and equals are the load and store helpers respectively. If the target is in the zero page, use LDR/PEK or STR/POK opcodes, otherwise use LDR2/PEK2 or STR2/POK2 opcodes. ) @normal-~ [ 0000 ] [ 0000 ] [ 7e ] LIT2r .opcodes-op-ldr LIT2r .opcodes-op-pek ^normal-=-main JMP @normal-root @normal-= .normal-$ .normal-^ [ 3d ] LIT2r .opcodes-op-str LIT2r .opcodes-op-pok $main ~assembler.token ,lookup-label JSR2 DUP #03 AND ^$valid JNZ ( FIXME complain about helper not being usable ) POP2 JMP2r $valid #02 AND ^$two-byte JNZ SWP2r $two-byte POP2r LIT2r .opcodes-start SUB2r LITr [ 07 ] DIVr OVR #00 EQU ^$byte-mode JNZ ,write-short SHORT_FLAG ^$end JMP $byte-mode SWP POP ,write-byte #00 $end ,opcodes-op-lit ,opcodes-start SUB2 #07 DIV ADD ADD ,write-byte JSR2 JSR2 STHr ,write-byte JSR2 POPr JMP2r ( Semicolons introduce variables. The variable name is added to the label tree as usual, but all of the subfields are collected into their own tree pointed to in the variable name's binary data. ) @normal-; [ 0000 ] [ 0000 ] [ 3b ] #80 ~assembler.token ,label-tree ,add-label JSR2 ~assembler.heap #0000 OVR2 STR2 DUP2 =assembler.subtree #0002 ADD2 =assembler.heap ~assembler.state #0c ORA =assembler.state JMP2r @variable-root @variable-{ .variable-nul .variable-} [ 7b ] JMP2r @variable-nul [ 0000 ] .normal-( [ 00 ] JMP2r @variable-} [ 0000 ] [ 0000 ] [ 7d ] ~assembler.state #f3 AND =assembler.state JMP2r @variable-name #00 ~assembler.token ~assembler.subtree ,add-label JSR2 ~assembler.heap #0003 SUB2 =assembler.vartmp ~assembler.state #f7 AND =assembler.state JMP2r @variable-size ~assembler.token ,parse-hex-length JSR2 ^$valid JNZ ( FIXME complain about invalid size ) JMP2r $valid DUP #02 GTH ^$end JNZ DUP ~assembler.vartmp POK2 ^$end JMP $loop #00 ,write-byte JSR2 #01 SUB $end DUP ^$loop JNZ POP ~assembler.state #0c ORA =assembler.state JMP2r ( Percent signs introduce macros. The macro name is added to the macro tree, and all the arguments are collected into a list that follows the label's binary data. ) @normal-% [ 0000 ] .normal-( [ 25 ] ,macro-tree ~assembler.token #ff ,traverse-tree JSR2 ^$new-macro JNZ ( macro already exists, we assume defined in a previous pass we totally ignore the contents ) POP2 ~assembler.state #02 ORA =assembler.state JMP2r $new-macro ~assembler.token SWP2 ,append-tree JSR2 POP2 ~assembler.state #01 ORA =assembler.state JMP2r @macro-root @macro-{ .macro-nul .macro-} [ 7b ] JMP2r @macro-} [ 0000 ] [ 0000 ] [ 7d ] ~assembler.heap DUP2 #00 ROT ROT POK2 #0001 ADD2 =assembler.heap ~assembler.state #fc AND =assembler.state JMP2r @macro-nul [ 0000 ] .normal-( [ 00 ] JMP2r @macro-main ~assembler.token ,append-heap JSR2 POP2 JMP2r @normal-" .normal-nul .normal-# [ 22 ] ( FIXME NYI ) JMP2r @normal-{ [ 0000 ] [ 0000 ] [ 7b ] ( these are spurious, but ignore them anyway ) JMP2r @normal-} [ 0000 ] .normal-~ [ 7d ] ( these are spurious, but ignore them anyway ) JMP2r @normal-nul [ 0000 ] [ 0000 ] [ 00 ] @ignore JMP2r @normal-main ~assembler.token ,opcodes-tree OVR2 #03 ,traverse-tree JSR2 ^$not-opcode JNZ ,opcodes-asm SUB2 #0007 DIV2 SWP2 #0003 ADD2 $flags DUP2 PEK2 DUP #00 EQU ^$end-flags JNZ DUP #32 NEQ ^$not-two JNZ POP SWP2 SHORT_FLAG ORA SWP2 #0001 ADD2 ^$flags JMP $not-two DUP #72 NEQ ^$not-r JNZ POP SWP2 RETURN_FLAG ORA SWP2 #0001 ADD2 ^$flags JMP $not-r POP POP2 ~assembler.token SWP2 ^$not-opcode JMP $end-flags POP POP2 ,write-byte JSR2 POP JMP2r $not-opcode POP2 ,macro-tree SWP2 #ff ,traverse-tree JSR2 ^$not-macro JNZ ,assemble-macro JMP2 ( tail call ) $not-macro ( FIXME complain about bad opcode / nonexistent macro ) POP2 JMP2r ( Here's the big set of trees relating to labels. Starting from l-root, all the devices are stored here, perhaps some helper functions in the future, too. left-node* right-node* node-key-cstring binary-data The node-keys are terminated with NUL since, unlike the opcodes and first characters, the keys are variable length. The binary-data is either three or five bytes long: flags value* [ subtree-pointer* ] The flags byte is divided up into bits: bit 0-1: 00 means store / load helpers cannot be used, 01 means the helpers use POK / PEK, 02 means the helpers use STR / LDR, 03 is invalid; bits 2-6 are reserved; and bit 7: 80 means there is a subtree. If there is a subtree, it is searched when the reference contains a dot. ) @l-Audio [ 0000 ] [ 0000 ] [ Audio 00 ] [ 80 ] .Audio .l-Audio-root @l-Audio-delay [ 0000 ] [ 0000 ] [ delay 00 ] [ 02 ] .Audio.delay @l-Audio-envelope .l-Audio-delay .l-Audio-finish [ envelope 00 ] [ 02 ] .Audio.envelope @l-Audio-finish [ 0000 ] [ 0000 ] [ finish 00 ] [ 01 ] .Audio.finish @l-Audio-root @l-Audio-pitch .l-Audio-envelope .l-Audio-value [ pitch 00 ] [ 01 ] .Audio.pitch @l-Audio-play [ 0000 ] [ 0000 ] [ play 00 ] [ 01 ] .Audio.play @l-Audio-value .l-Audio-play .l-Audio-volume [ value 00 ] [ 02 ] .Audio.value @l-Audio-volume [ 0000 ] .l-Audio-wave [ volume 00 ] [ 01 ] .Audio.volume @l-Audio-wave [ 0000 ] [ 0000 ] [ wave 00 ] [ 02 ] .Audio.wave @l-Console .l-Audio .l-Controller [ Console 00 ] [ 80 ] .Console .l-Console-root @l-Console-byte [ 0000 ] .l-Console-char [ byte 00 ] [ 01 ] .Console.byte @l-Console-char [ 0000 ] [ 0000 ] [ char 00 ] [ 01 ] .Console.char @l-Console-root @l-Console-short .l-Console-byte .l-Console-string [ short 00 ] [ 02 ] .Console.short @l-Console-string [ 0000 ] .l-Console-vector [ string 00 ] [ 02 ] .Console.string @l-Console-vector [ 0000 ] [ 0000 ] [ vector 00 ] [ 02 ] .Console.vector @l-Controller [ 0000 ] [ 0000 ] [ Controller 00 ] [ 80 ] .Controller .l-Controller-root @l-Controller-button [ 0000 ] [ 0000 ] [ button 00 ] [ 01 ] .Controller.button @l-Controller-root @l-Controller-key .l-Controller-button .l-Controller-vector [ key 00 ] [ 01 ] .Controller.key @l-Controller-vector [ 0000 ] [ 0000 ] [ vector 00 ] [ 02 ] .Controller.vector @l-root @l-DateTime .l-Console .l-Mouse [ DateTime 00 ] [ 80 ] .DateTime .l-DateTime-root @l-DateTime-day [ 0000 ] [ 0000 ] [ day 00 ] [ 01 ] .DateTime.day @l-DateTime-dotw .l-DateTime-day .l-DateTime-doty [ dotw 00 ] [ 01 ] .DateTime.dotw @l-DateTime-doty [ 0000 ] .l-DateTime-hour [ doty 00 ] [ 02 ] .DateTime.doty @l-DateTime-hour [ 0000 ] [ 0000 ] [ hour 00 ] [ 01 ] .DateTime.hour @l-DateTime-root @l-DateTime-isdst .l-DateTime-dotw .l-DateTime-refresh [ isdst 00 ] [ 01 ] .DateTime.isdst @l-DateTime-minute [ 0000 ] .l-DateTime-month [ minute 00 ] [ 01 ] .DateTime.minute @l-DateTime-month [ 0000 ] [ 0000 ] [ month 00 ] [ 01 ] .DateTime.month @l-DateTime-refresh .l-DateTime-minute .l-DateTime-second [ refresh 00 ] [ 01 ] .DateTime.refresh @l-DateTime-second [ 0000 ] .l-DateTime-year [ second 00 ] [ 01 ] .DateTime.second @l-DateTime-year [ 0000 ] [ 0000 ] [ year 00 ] [ 02 ] .DateTime.year @l-File [ 0000 ] [ 0000 ] [ File 00 ] [ 80 ] .File .l-File-root @l-File-length [ 0000 ] .l-File-load [ length 00 ] [ 02 ] .File.length @l-File-load [ 0000 ] [ 0000 ] [ load 00 ] [ 00 ] .File.load @l-File-root @l-File-name .l-File-length .l-File-save [ name 00 ] [ 02 ] .File.name @l-File-save [ 0000 ] .l-File-vector [ save 00 ] [ 02 ] .File.save @l-File-vector [ 0000 ] [ 0000 ] [ vector 00 ] [ 02 ] .File.vector @l-Mouse .l-File .l-Screen [ Mouse 00 ] [ 80 ] .Mouse .l-Mouse-root @l-Mouse-chord [ 0000 ] .l-Mouse-state [ chord 00 ] [ 01 ] .Mouse.chord @l-Mouse-state [ 0000 ] [ 0000 ] [ state 00 ] [ 01 ] .Mouse.state @l-Mouse-root @l-Mouse-vector .l-Mouse-chord .l-Mouse-x [ vector 00 ] [ 02 ] .Mouse.vector @l-Mouse-x [ 0000 ] .l-Mouse-y [ x 00 ] [ 02 ] .Mouse.x @l-Mouse-y [ 0000 ] [ 0000 ] [ y 00 ] [ 02 ] .Mouse.y @l-Screen [ 0000 ] .l-System [ Screen 00 ] [ 80 ] .Screen .l-Screen-root @l-Screen-addr [ 0000 ] [ 0000 ] [ addr 00 ] [ 02 ] .Screen.addr @l-Screen-color .l-Screen-addr .l-Screen-height [ color 00 ] [ 01 ] .Screen.color @l-Screen-height [ 0000 ] [ 0000 ] [ height 00 ] [ 02 ] .Screen.height @l-Screen-root @l-Screen-vector .l-Screen-color .l-Screen-x [ vector 00 ] [ 02 ] .Screen.vector @l-Screen-width [ 0000 ] [ 0000 ] [ width 00 ] [ 02 ] .Screen.width @l-Screen-x .l-Screen-width .l-Screen-y [ x 00 ] [ 02 ] .Screen.x @l-Screen-y [ 0000 ] [ 0000 ] [ y 00 ] [ 02 ] .Screen.y @l-System [ 0000 ] [ 0000 ] [ System 00 ] [ 80 ] .System .l-System-root @l-System-b [ 0000 ] [ 0000 ] [ b 00 ] [ 02 ] .System.b @l-System-root @l-System-g .l-System-b .l-System-r [ g 00 ] [ 02 ] .System.g @l-System-r [ 0000 ] .l-System-vector [ r 00 ] [ 02 ] .System.r @l-System-vector [ 0000 ] [ 0000 ] [ vector 00 ] [ 02 ] .System.vector @assembler-heap-start