mirror of
https://github.com/forth-ev/VolksForth.git
synced 2024-11-25 10:30:57 +00:00
579 lines
36 KiB
Forth
579 lines
36 KiB
Forth
\ *** Block No. 0 Hexblock 0
|
||
\ 8086 Assembler cas 10nov05
|
||
|
||
The 8086 Assembler was written by Mike Perry.
|
||
To create and assembler language definition, use the defining
|
||
word CODE. It must be terminated with either END-CODE or
|
||
its synonym C;. How the assembler operates is a very
|
||
interesting example of the power of CREATE DOES> Basically
|
||
the instructions are categorized and a defining word is
|
||
created for each category. When the nmemonic for the
|
||
instruction is interpreted, it compiles itself.
|
||
|
||
Adapted for volksFORTH by Klaus Schleisiek
|
||
|
||
No really tested, but
|
||
CODE TEST TOS PUSH 1 # TOS MOV NEXT END-CODE
|
||
works!
|
||
\ *** Block No. 1 Hexblock 1
|
||
\ 8086 Assembler ks cas 10nov05
|
||
Onlyforth
|
||
Vocabulary Assembler
|
||
: octal 8 Base ! ;
|
||
|
||
decimal 1 14 +THRU clear
|
||
|
||
Onlyforth
|
||
|
||
: Code Create [ Assembler ] here dup 2- ! Assembler ;
|
||
|
||
CR .( 8086 Assembler loaded )
|
||
Onlyforth
|
||
|
||
|
||
|
||
\ *** Block No. 2 Hexblock 2
|
||
\ 8086 Assembler ks 19 m<>r 88
|
||
: LABEL CREATE ASSEMBLER ;
|
||
\ 232 CONSTANT DOES-OP
|
||
\ 3 CONSTANT DOES-SIZE
|
||
\ : DOES? ( IP -- IP' F )
|
||
\ DUP DOES-SIZE + SWAP C@ DOES-OP = ;
|
||
ASSEMBLER ALSO DEFINITIONS
|
||
: C; ( -- ) END-CODE ;
|
||
OCTAL
|
||
DEFER C, FORTH ' C, ASSEMBLER IS C,
|
||
DEFER , FORTH ' , ASSEMBLER IS ,
|
||
DEFER HERE FORTH ' HERE ASSEMBLER IS HERE
|
||
DEFER ?>MARK
|
||
DEFER ?>RESOLVE
|
||
DEFER ?<MARK
|
||
DEFER ?<RESOLVE
|
||
\ *** Block No. 3 Hexblock 3
|
||
\ 8086 Assembler Register Definitions ks 19 m<>r 88
|
||
| : REG 11 * SWAP 1000 * OR CONSTANT ;
|
||
| : REGS ( MODE N -- ) SWAP 0 DO DUP I REG LOOP DROP ;
|
||
|
||
10 0 REGS AL CL DL BL AH CH DH BH
|
||
10 1 REGS AX CX DX BX SP BP SI DI
|
||
10 2 REGS [BX+SI] [BX+DI] [BP+SI] [BP+DI] [SI] [DI] [BP] [BX]
|
||
4 2 REGS [SI+BX] [DI+BX] [SI+BP] [DI+BP]
|
||
4 3 REGS ES CS SS DS
|
||
3 4 REGS # #) S#)
|
||
|
||
BP Constant UP [BP] Constant [UP] \ User Pointer
|
||
SI CONSTANT IP [SI] CONSTANT [IP] ( INTERPRETER POINTER )
|
||
DI Constant W [DI] Constant [W] \ WORKING REGISTER
|
||
BX Constant RP [BX] Constant [RP] \ Return Stack Pointer
|
||
DX Constant TOS \ Top Of Stack im Register
|
||
\ *** Block No. 4 Hexblock 4
|
||
\ Addressing Modes ks 19 m<>r 88
|
||
| : MD CREATE 1000 * , DOES> @ SWAP 7000 AND = 0<> ;
|
||
| 0 MD R8? | 1 MD R16? | 2 MD MEM? | 3 MD SEG? | 4 MD #?
|
||
| : REG? ( n -- f ) 7000 AND 2000 < 0<> ;
|
||
| : BIG? ( N -- F ) ABS -200 AND 0<> ;
|
||
| : RLOW ( n1 -- n2 ) 7 AND ;
|
||
| : RMID ( n1 -- n2 ) 70 AND ;
|
||
| VARIABLE SIZE SIZE ON
|
||
: BYTE ( -- ) SIZE OFF ;
|
||
| : OP, ( N OP -- ) OR C, ;
|
||
| : W, ( OP MR -- ) R16? 1 AND OP, ;
|
||
| : SIZE, ( OP -- OP' ) SIZE @ 1 AND OP, ;
|
||
| : ,/C, ( n f -- ) IF , ELSE C, THEN ;
|
||
| : RR, ( MR1 MR2 -- ) RMID SWAP RLOW OR 300 OP, ;
|
||
| VARIABLE LOGICAL
|
||
| : B/L? ( n -- f ) BIG? LOGICAL @ OR ;
|
||
\ *** Block No. 5 Hexblock 5
|
||
\ Addressing ks 19 m<>r 88
|
||
| : MEM, ( DISP MR RMID -- ) OVER #) =
|
||
IF RMID 6 OP, DROP ,
|
||
ELSE RMID OVER RLOW OR -ROT [BP] = OVER 0= AND
|
||
IF SWAP 100 OP, C, ELSE SWAP OVER BIG?
|
||
IF 200 OP, , ELSE OVER 0=
|
||
IF C, DROP ELSE 100 OP, C,
|
||
THEN THEN THEN THEN ;
|
||
| : WMEM, ( DISP MEM REG OP -- ) OVER W, MEM, ;
|
||
| : R/M, ( MR REG -- )
|
||
OVER REG? IF RR, ELSE MEM, THEN ;
|
||
| : WR/SM, ( R/M R OP -- ) 2 PICK DUP REG?
|
||
IF W, RR, ELSE DROP SIZE, MEM, THEN SIZE ON ;
|
||
| VARIABLE INTER
|
||
: FAR ( -- ) INTER ON ;
|
||
| : ?FAR ( n1 -- n2 ) INTER @ IF 10 OR THEN INTER OFF ;
|
||
\ *** Block No. 6 Hexblock 6
|
||
\ Defining Words to Generate Op Codes ks 19 m<>r 88
|
||
| : 1MI CREATE C, DOES> C@ C, ;
|
||
| : 2MI CREATE C, DOES> C@ C, 12 C, ;
|
||
| : 3MI CREATE C, DOES> C@ C, HERE - 1-
|
||
DUP -200 177 uWITHIN NOT ABORT" Branch out of Range" C, ;
|
||
| : 4MI CREATE C, DOES> C@ C, MEM, ;
|
||
| : 5MI CREATE C, DOES> C@ SIZE, SIZE ON ;
|
||
| : 6MI CREATE C, DOES> C@ SWAP W, ;
|
||
| : 7MI CREATE C, DOES> C@ 366 WR/SM, ;
|
||
| : 8MI CREATE C, DOES> C@ SWAP R16? 1 AND OR SWAP # =
|
||
IF C, C, ELSE 10 OR C, THEN ;
|
||
| : 9MI CREATE C, DOES> C@ OVER R16?
|
||
IF 100 OR SWAP RLOW OP, ELSE 376 WR/SM, THEN ;
|
||
| : 10MI CREATE C, DOES> C@ OVER CL =
|
||
IF NIP 322 ELSE 320 THEN WR/SM, ;
|
||
|
||
\ *** Block No. 7 Hexblock 7
|
||
\ Defining Words to Generate Op Codes ks 19 m<>r 88
|
||
| : 11MI CREATE C, C, DOES> OVER #) =
|
||
IF NIP C@ INTER @
|
||
IF 1 AND IF 352 ELSE 232 THEN C, SWAP , , INTER OFF
|
||
ELSE SWAP HERE - 2- SWAP 2DUP 1 AND SWAP BIG? NOT AND
|
||
IF 2 OP, C, ELSE C, 1- , THEN THEN
|
||
ELSE OVER S#) = IF NIP #) SWAP THEN
|
||
377 C, 1+ C@ ?FAR R/M, THEN ;
|
||
| : 12MI CREATE C, C, C, DOES> OVER REG?
|
||
IF C@ SWAP RLOW OP, ELSE 1+ OVER SEG?
|
||
IF C@ RLOW SWAP RMID OP,
|
||
ELSE COUNT SWAP C@ C, MEM,
|
||
THEN THEN ;
|
||
| : 14MI CREATE C, DOES> C@
|
||
DUP ?FAR C, 1 AND 0= IF , THEN ;
|
||
|
||
\ *** Block No. 8 Hexblock 8
|
||
\ Defining Words to Generate Op Codes ks 19 m<>r 88
|
||
| : 13MI CREATE C, C, DOES> COUNT >R C@ LOGICAL ! DUP REG?
|
||
IF OVER REG?
|
||
IF R> OVER W, SWAP RR, ELSE OVER DUP MEM? SWAP #) = OR
|
||
IF R> 2 OR WMEM, ELSE ( # ) NIP DUP RLOW 0= ( ACC? )
|
||
IF R> 4 OR OVER W, R16? ,/C,
|
||
ELSE OVER B/L? OVER R16? 2DUP AND
|
||
-ROT 1 AND SWAP NOT 2 AND OR 200 OP,
|
||
SWAP RLOW 300 OR R> OP, ,/C,
|
||
THEN THEN THEN
|
||
ELSE ( MEM ) ROT DUP REG?
|
||
IF R> WMEM,
|
||
ELSE ( # ) DROP 2 PICK B/L? DUP NOT 2 AND 200 OR SIZE,
|
||
-ROT R> MEM, SIZE @ AND ,/C, SIZE ON
|
||
THEN THEN ;
|
||
|
||
\ *** Block No. 9 Hexblock 9
|
||
\ Instructions ks 19 m<>r 88
|
||
: TEST ( source dest -- ) DUP REG?
|
||
IF OVER REG?
|
||
IF 204 OVER W, SWAP RR, ELSE OVER DUP MEM? SWAP #) = OR
|
||
IF 204 WMEM, ELSE ( # ) NIP DUP RLOW 0= ( ACC? )
|
||
IF 250 OVER W,
|
||
ELSE 366 OVER W, DUP RLOW 300 OP,
|
||
THEN R16? ,/C, THEN THEN
|
||
ELSE ( MEM ) ROT DUP REG?
|
||
IF 204 WMEM,
|
||
ELSE ( # ) DROP 366 SIZE, 0 MEM, SIZE @ ,/C, SIZE ON
|
||
THEN THEN ;
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 10 Hexblock A
|
||
\ Instructions ks 19 m<>r 88
|
||
HEX
|
||
: ESC ( source ext-opcode -- ) RLOW 0D8 OP, R/M, ;
|
||
: INT ( N -- ) 0CD C, C, ;
|
||
: SEG ( SEG -- ) RMID 26 OP, ;
|
||
: XCHG ( MR1 MR2 -- ) DUP REG?
|
||
IF DUP AX =
|
||
IF DROP RLOW 90 OP, ELSE OVER AX =
|
||
IF NIP RLOW 90 OP, ELSE 86 WR/SM, THEN THEN
|
||
ELSE ROT 86 WR/SM, THEN ;
|
||
|
||
: CS: CS SEG ;
|
||
: DS: DS SEG ;
|
||
: ES: ES SEG ;
|
||
: SS: SS SEG ;
|
||
|
||
\ *** Block No. 11 Hexblock B
|
||
\ Instructions ks 19 m<>r 88
|
||
: MOV ( S D -- ) DUP SEG?
|
||
IF 8E C, R/M, ELSE DUP REG?
|
||
IF OVER #) = OVER RLOW 0= AND
|
||
IF A0 SWAP W, DROP , ELSE OVER SEG?
|
||
IF SWAP 8C C, RR, ELSE OVER # =
|
||
IF NIP DUP R16? SWAP RLOW OVER 8 AND OR B0 OP, ,/C,
|
||
ELSE 8A OVER W, R/M, THEN THEN THEN
|
||
ELSE ( MEM ) ROT DUP SEG?
|
||
IF 8C C, MEM, ELSE DUP # =
|
||
IF DROP C6 SIZE, 0 MEM, SIZE @ ,/C,
|
||
ELSE OVER #) = OVER RLOW 0= AND
|
||
IF A2 SWAP W, DROP , ELSE 88 OVER W, R/M,
|
||
THEN THEN THEN THEN THEN SIZE ON ;
|
||
|
||
|
||
\ *** Block No. 12 Hexblock C
|
||
\ Instructions 12Oct83map
|
||
37 1MI AAA D5 2MI AAD D4 2MI AAM 3F 1MI AAS
|
||
0 10 13MI ADC 0 00 13MI ADD 2 20 13MI AND 10 E8 11MI CALL
|
||
98 1MI CBW F8 1MI CLC FC 1MI CLD FA 1MI CLI
|
||
F5 1MI CMC 0 38 13MI CMP A6 5MI CMPS 99 1MI CWD
|
||
27 1MI DAA 2F 1MI DAS 08 9MI DEC 30 7MI DIV
|
||
( ESC ) F4 1MI HLT 38 7MI IDIV 28 7MI IMUL
|
||
E4 8MI IN 00 9MI INC ( INT ) 0CE 1MI INTO
|
||
0CF 1MI IRET 77 3MI JA 73 3MI JAE 72 3MI JB
|
||
76 3MI JBE E3 3MI JCXZ 74 3MI JE 7F 3MI JG
|
||
7D 3MI JGE 7C 3MI JL 7E 3MI JLE 20 E9 11MI JMP
|
||
75 3MI JNE 71 3MI JNO 79 3MI JNS 70 3MI JO
|
||
7A 3MI JPE 7B 3MI JPO 78 3MI JS 9F 1MI LAHF
|
||
C5 4MI LDS 8D 4MI LEA C4 4MI LES F0 1MI LOCK
|
||
0AC 6MI LODS E2 3MI LOOP E1 3MI LOOPE E0 3MI LOOPNE
|
||
|
||
\ *** Block No. 13 Hexblock D
|
||
\ Instructions 12Apr84map
|
||
( MOV ) 0A4 5MI MOVS 20 7MI MUL 18 7MI NEG
|
||
90 1MI NOP 10 7MI NOT 2 08 13MI OR E6 8MI OUT
|
||
8F 07 58 12MI POP 9D 1MI POPF
|
||
0FF 36 50 12MI PUSH 9C 1MI PUSHF
|
||
10 10MI RCL 18 10MI RCR
|
||
F2 1MI REP F2 1MI REPNZ F3 1MI REPZ
|
||
C3 14MI RET 00 10MI ROL 8 10MI ROR 9E 1MI SAHF
|
||
38 10MI SAR 0 18 13MI SBB 0AE 5MI SCAS ( SEG )
|
||
20 10MI SHL 28 10MI SHR F9 1MI STC FD 1MI STD
|
||
FB 1MI STI 0AA 6MI STOS 0 28 13MI SUB ( TEST )
|
||
9B 1MI WAIT ( XCHG ) D7 1MI XLAT 2 30 13MI XOR
|
||
C2 14MI +RET
|
||
|
||
|
||
|
||
\ *** Block No. 14 Hexblock E
|
||
\ Structured Conditionals ks 19 m<>r 88
|
||
: A?>MARK ( -- f addr ) TRUE HERE 0 C, ;
|
||
: A?>RESOLVE ( f addr -- ) HERE OVER 1+ - SWAP C! true ?pairs ;
|
||
: A?<MARK ( -- f addr ) TRUE HERE ;
|
||
: A?<RESOLVE ( f addr -- ) HERE 1+ - C, true ?pairs ;
|
||
' A?>MARK ASSEMBLER IS ?>MARK
|
||
' A?>RESOLVE ASSEMBLER IS ?>RESOLVE
|
||
' A?<MARK ASSEMBLER IS ?<MARK
|
||
' A?<RESOLVE ASSEMBLER IS ?<RESOLVE
|
||
HEX
|
||
75 CONSTANT 0= 74 CONSTANT 0<> 79 CONSTANT 0<
|
||
78 CONSTANT 0>= 7D CONSTANT < 7C CONSTANT >=
|
||
7F CONSTANT <= 7E CONSTANT > 73 CONSTANT U<
|
||
72 CONSTANT U>= 77 CONSTANT U<= 76 CONSTANT U>
|
||
71 CONSTANT OV
|
||
DECIMAL
|
||
\ *** Block No. 15 Hexblock F
|
||
\ Structured Conditionals cas 10nov05
|
||
HEX
|
||
: IF C, ?>MARK ;
|
||
: THEN ?>RESOLVE ;
|
||
: ELSE 0EB IF 2SWAP THEN ;
|
||
: BEGIN ?<MARK ;
|
||
: UNTIL C, ?<RESOLVE ;
|
||
: AGAIN 0EB UNTIL ;
|
||
: WHILE IF ;
|
||
: REPEAT 2SWAP AGAIN THEN ;
|
||
: DO # CX MOV HERE ;
|
||
: Next AX lods AX DI xchg 0 [DI] jmp
|
||
[ Assembler ] here next-link @ , next-link ! ;
|
||
\ volksFORTH uses "inline" Next and a linked list, to find all
|
||
\ existing NEXT for the debugger.
|
||
DECIMAL
|
||
\ *** Block No. 16 Hexblock 10
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 17 Hexblock 11
|
||
\ 8086 Assembler 08OCT83HHL
|
||
LABEL marks the start of a subroutine whose name returns its
|
||
address.
|
||
DOES-OP Is the op code of the call instruction used for DOES> U
|
||
C; A synonym for END-CODE
|
||
|
||
Deferring the definitions of the commas, marks, and resolves
|
||
allows the same assembler to serve for both the system and the
|
||
Meta-Compiler.
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 18 Hexblock 12
|
||
\ 8086 Assembler Register Definitions 12Oct83map
|
||
|
||
On the 8086, register names are cleverly defined constants.
|
||
|
||
The value returned by registers and by modes such as #) contains
|
||
both mode and register information. The instructions use the
|
||
mode information to decide how many arguments exist, and what to
|
||
assemble.
|
||
Like many CPUs, the 8086 uses many 3 bit fields in its opcodes
|
||
This makes octal ( base 8 ) natural for describing the registers
|
||
|
||
|
||
We redefine the Registers that FORTH uses to implement its
|
||
virtual machine.
|
||
|
||
|
||
\ *** Block No. 19 Hexblock 13
|
||
\ Addressing Modes 16Oct83map
|
||
MD defines words which test for various modes.
|
||
R8? R16? MEM? SEG? #? test for mode equal to 0 thru 4.
|
||
REG? tests for any register mode ( 8 or 16 bit).
|
||
BIG? tests offsets size. True if won't fit in one byte.
|
||
RLOW mask off all but low register field.
|
||
RMID mask off all but middle register field.
|
||
SIZE true for 16 bit, false for 8 bit.
|
||
BYTE set size to 8 bit.
|
||
OP, for efficiency. OR two numbers and assemble.
|
||
W, assemble opcode with W field set for size of register.
|
||
SIZE, assemble opcode with W field set for size of data.
|
||
,/C, assemble either 8 or 16 bits.
|
||
RR, assemble register to register instruction.
|
||
LOGICAL true while assembling logical instructions.
|
||
B/L? see 13MI
|
||
\ *** Block No. 20 Hexblock 14
|
||
\ Addressing 16Oct83map
|
||
These words perform most of the addressing mode encoding.
|
||
MEM, handles memory reference modes. It takes a displacement,
|
||
a mode/register, and a register, and encodes and assembles
|
||
them.
|
||
|
||
|
||
WMEM, uses MEM, after packing the register size into the opcode
|
||
R/M, assembles either a register to register or a register to
|
||
or from memory mode.
|
||
WR/SM, assembles either a register mode with size field, or a
|
||
memory mode with size from SIZE. Default is 16 bit. Use BYTE
|
||
for 8 bit size.
|
||
INTER true if inter-segment jump, call, or return.
|
||
FAR sets INTER true. Usage: FAR JMP, FAR CALL, FAR RET.
|
||
?FAR sets far bit, clears flag.
|
||
\ *** Block No. 21 Hexblock 15
|
||
\ Defining Words to Generate Op Codes 12Oct83map
|
||
1MI define one byte constant instructions.
|
||
2MI define ascii adjust instructions.
|
||
3MI define branch instructions, with one byte offset.
|
||
4MI define LDS, LEA, LES instructions.
|
||
5MI define string instructions.
|
||
6MI define more string instructions.
|
||
7MI define multiply and divide instructions.
|
||
8MI define input and output instructions.
|
||
|
||
9MI define increment/decrement instructions.
|
||
|
||
10MI define shift/rotate instructions.
|
||
*NOTE* To allow both 'ax shl' and 'ax cl shl', if the register
|
||
on top of the stack is cl, shift second register by cl. If not,
|
||
shift top ( only) register by one.
|
||
\ *** Block No. 22 Hexblock 16
|
||
\ Defining Words to Generate Op Codes 09Apr84map
|
||
11MI define calls and jumps.
|
||
notice that the first byte stored is E9 for jmp and E8 for call
|
||
so C@ 1 AND is zero for call, 1 for jmp.
|
||
syntax for direct intersegment: address segment #) FAR JMP
|
||
|
||
|
||
|
||
12MI define pushes and pops.
|
||
|
||
|
||
|
||
|
||
14MI defines returns.
|
||
RET FAR RET n +RET n FAR +RET
|
||
|
||
\ *** Block No. 23 Hexblock 17
|
||
\ Defining Words to Generate Op Codes 16Oct83map
|
||
13MI define arithmetic and logical instructions.
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 24 Hexblock 18
|
||
\ Instructions 16Oct83map
|
||
TEST bits in dest
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 25 Hexblock 19
|
||
\ Instructions 16Oct83map
|
||
|
||
ESC
|
||
INT assemble interrupt instruction.
|
||
SEG assemble segment instruction.
|
||
XCHG assemble register swap instruction.
|
||
|
||
|
||
|
||
|
||
|
||
CS: DS: ES: SS: assemble segment over-ride instructions.
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 26 Hexblock 1A
|
||
\ Instructions 12Oct83map
|
||
MOV as usual, the move instruction is the most complicated.
|
||
It allows more addressing modes than any other, each of which
|
||
assembles something more or less unique.
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 27 Hexblock 1B
|
||
\ Instructions 12Oct83map
|
||
Most instructions are defined on these two screens. Mnemonics in
|
||
parentheses are defined earlier or not at all.
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 28 Hexblock 1C
|
||
\ Instructions 12Oct83map
|
||
Most instructions are defined on these two screens. Mnemonics in
|
||
parentheses are defined earlier or not at all.
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 29 Hexblock 1D
|
||
\ Structured Conditionals 16Oct83map
|
||
A?>MARK assembler version of forward mark.
|
||
A?>RESOLVE assembler version of forward resolve.
|
||
A?<MARK assembler version of backward mark.
|
||
A?<RESOLVE assembler version of backward resolve.
|
||
|
||
|
||
|
||
|
||
|
||
These conditional test words leave the opcodes of conditional
|
||
branches to be used by the structured conditional words.
|
||
For example,
|
||
5 # CX CMP 0< IF AX BX ADD ELSE AX BX SUB THEN
|
||
|
||
|
||
\ *** Block No. 30 Hexblock 1E
|
||
\ Structured Conditionals 12Oct83map
|
||
|
||
One of the very best features of FORTH assemblers is the ability
|
||
to use structured conditionals instead of branching to nonsense
|
||
labels.
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 31 Hexblock 1F
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 32 Hexblock 20
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
\ *** Block No. 33 Hexblock 21
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|