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98ca338aba
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c968995ec0
@ -191,10 +191,4 @@ the instruction after the "foo" label would be "rjmp foo+1". In zasm, it's
|
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"rjmp foo+2". If your expression results in an odd number, the low bit of your
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number will be ignored.
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Limitations:
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* `CALL` and `JMP` only support 16-bit numbers, not 22-bit ones.
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* `BRLO` and `BRSH` are not there. Use `BRCS` and `BRCC` instead.
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* No `high()` and `low()`. Use `&0xff` and `}8`.
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[libz80]: https://github.com/ggambetta/libz80
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|
@ -31,19 +31,14 @@ instrNames:
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.equ I_BRBS 16
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.db "BRBS", 0
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.db "BRBC", 0
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.equ I_LD 18
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.db "LD", 0
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.db "ST", 0
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; Rd(5) + Rr(5) (from here, instrTbl8)
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.equ I_ADC 20
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.equ I_ADC 18
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.db "ADC", 0
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.db "ADD", 0
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.db "AND", 0
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.db "ASR", 0
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.db "BCLR", 0
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.db "BLD", 0
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.db "BREAK", 0
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.db "BSET", 0
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.db "BST", 0
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.db "CLC", 0
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.db "CLH", 0
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@ -69,7 +64,6 @@ instrNames:
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.db "LAC", 0
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.db "LAS", 0
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.db "LAT", 0
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.db "LSL", 0
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.db "LSR", 0
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.db "MOV", 0
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.db "MUL", 0
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@ -89,7 +83,6 @@ instrNames:
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.db "SEH", 0
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.db "SEI", 0
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.db "SEN", 0
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.db "SER", 0
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.db "SES", 0
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.db "SET", 0
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.db "SEV", 0
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@ -97,33 +90,22 @@ instrNames:
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.db "SLEEP", 0
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.db "SUB", 0
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.db "SWAP", 0
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.db "TST", 0
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.db "WDR", 0
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.db "XCH", 0
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.equ I_ANDI 84
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.equ I_ANDI 77
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.db "ANDI", 0
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.db "CBR", 0
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.db "CPI", 0
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.db "LDI", 0
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.db "ORI", 0
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.db "SBCI", 0
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.db "SBR", 0
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.db "SUBI", 0
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.equ I_RCALL 92
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.equ I_RCALL 84
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.db "RCALL", 0
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.db "RJMP", 0
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.equ I_CBI 94
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.equ I_CBI 86
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.db "CBI", 0
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.db "SBI", 0
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.db "SBIC", 0
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.db "SBIS", 0
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; 32-bit
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; ZASM limitation: CALL and JMP constants are 22-bit. In ZASM, we limit
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; ourselves to 16-bit. Supporting 22-bit would incur a prohibitive complexity
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; cost. As they say, 64K words ought to be enough for anybody.
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.equ I_CALL 98
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.db "CALL", 0
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.db "JMP", 0
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.db 0xff
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; Instruction table
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@ -145,7 +127,6 @@ instrNames:
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; allow this kind of syntactic sugar with minimal complexity.
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;
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; Bit 6: Second arg is a copy of the first
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; Bit 5: Second arg is inverted (complement)
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; In the same order as in instrNames
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instrTbl:
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@ -156,10 +137,8 @@ instrTbl:
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.db 0x02, 0b00001100, 0x00 ; ADD Rd, Rr
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.db 0x02, 0b00100000, 0x00 ; AND Rd, Rr
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.db 0x01, 0b10010100, 0b00000101 ; ASR Rd
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.db 0x0b, 0b10010100, 0b10001000 ; BCLR s, k
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.db 0x05, 0b11111000, 0x00 ; BLD Rd, b
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.db 0x00, 0b10010101, 0b10011000 ; BREAK
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.db 0x0b, 0b10010100, 0b00001000 ; BSET s, k
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.db 0x05, 0b11111010, 0x00 ; BST Rd, b
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.db 0x00, 0b10010100, 0b10001000 ; CLC
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.db 0x00, 0b10010100, 0b11011000 ; CLH
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@ -185,12 +164,11 @@ instrTbl:
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.db 0x01, 0b10010010, 0b00000110 ; LAC Rd
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.db 0x01, 0b10010010, 0b00000101 ; LAS Rd
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.db 0x01, 0b10010010, 0b00000111 ; LAT Rd
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.db 0x41, 0b00001100, 0x00 ; LSL Rd
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.db 0x01, 0b10010100, 0b00000110 ; LSR Rd
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.db 0x00, 0b00000000, 0b00000000 ; NOP
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.db 0x02, 0b00101100, 0x00 ; MOV Rd, Rr
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.db 0x02, 0b10011100, 0x00 ; MUL Rd, Rr
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.db 0x01, 0b10010100, 0b00000001 ; NEG Rd
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.db 0x00, 0b00000000, 0b00000000 ; NOP
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.db 0x02, 0b00101000, 0x00 ; OR Rd, Rr
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.db 0x87, 0b10111000, 0x00 ; OUT A, Rr (Bit 7)
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.db 0x01, 0b10010000, 0b00001111 ; POP Rd
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@ -205,7 +183,6 @@ instrTbl:
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.db 0x00, 0b10010100, 0b01011000 ; SEH
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.db 0x00, 0b10010100, 0b01111000 ; SEI
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.db 0x00, 0b10010100, 0b00101000 ; SEN
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.db 0x0a, 0b11101111, 0b00001111 ; SER Rd
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.db 0x00, 0b10010100, 0b01001000 ; SES
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.db 0x00, 0b10010100, 0b01101000 ; SET
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.db 0x00, 0b10010100, 0b00111000 ; SEV
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@ -213,29 +190,22 @@ instrTbl:
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.db 0x00, 0b10010101, 0b10001000 ; SLEEP
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.db 0x02, 0b00011000, 0x00 ; SUB Rd, Rr
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.db 0x01, 0b10010100, 0b00000010 ; SWAP Rd
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.db 0x41, 0b00100000, 0x00 ; TST Rd (Bit 6)
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.db 0x00, 0b10010101, 0b10101000 ; WDR
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.db 0x01, 0b10010010, 0b00000100 ; XCH Rd
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; Rd(4) + K(8): XXXXKKKK ddddKKKK
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.db 0x04, 0b01110000, 0x00 ; ANDI Rd, K
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.db 0x24, 0b01110000, 0x00 ; CBR Rd, K (Bit 5)
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.db 0x04, 0b00110000, 0x00 ; CPI Rd, K
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.db 0x04, 0b11100000, 0x00 ; LDI Rd, K
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.db 0x04, 0b01100000, 0x00 ; ORI Rd, K
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.db 0x04, 0b01000000, 0x00 ; SBCI Rd, K
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.db 0x04, 0b01100000, 0x00 ; SBR Rd, K
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.db 0x04, 0b01010000, 0x00 ; SUBI Rd, K
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.db 0x04, 0b01110000, 0x00 ; ANDI
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.db 0x04, 0b00110000, 0x00 ; CPI
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.db 0x04, 0b11100000, 0x00 ; LDI
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.db 0x04, 0b01100000, 0x00 ; ORI
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.db 0x04, 0b01000000, 0x00 ; SBCI
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.db 0x04, 0b01100000, 0x00 ; SBR
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.db 0x04, 0b01010000, 0x00 ; SUBI
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; k(12): XXXXkkkk kkkkkkkk
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.db 0x08, 0b11010000, 0x00 ; RCALL k
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.db 0x08, 0b11000000, 0x00 ; RJMP k
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; A(5) + bit: XXXXXXXX AAAAAbbb
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.db 0x09, 0b10011000, 0x00 ; CBI A, b
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.db 0x09, 0b10011010, 0x00 ; SBI A, b
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.db 0x09, 0b10011001, 0x00 ; SBIC A, b
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.db 0x09, 0b10011011, 0x00 ; SBIS A, b
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; k(16) (well, k(22)...)
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.db 0x08, 0b10010100, 0b00001110 ; CALL k
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.db 0x08, 0b10010100, 0b00001100 ; JMP k
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; Same signature as getInstID in instr.asm
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; Reads string in (HL) and returns the corresponding ID (I_*) in A. Sets Z if
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@ -283,11 +253,8 @@ parseInstruction:
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ld bc, 0
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ld e, a ; Let's keep that instrID somewhere safe
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; First, let's fetch our table row
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cp I_LD
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jp c, .BR ; BR is special, no table row
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jp z, .LD ; LD is special
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cp I_ADC
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jp c, .ST ; ST is special
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jp c, .BR ; BR is special, no table row
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; *** Step 2: parse arguments
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sub I_ADC ; Adjust index for table
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@ -300,7 +267,7 @@ parseInstruction:
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push hl \ pop ix ; IX is now our tblrow
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ld hl, 0
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or a
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jp z, .spit ; No arg? spit right away
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jr z, .spit ; No arg? spit right away
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and 0xf ; lower nibble
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dec a ; argspec index is 1-based
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ld hl, argSpecs
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@ -323,8 +290,6 @@ parseInstruction:
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call nz, .swapHL ; Bit 7 set, swap H and L again!
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bit 6, (ix)
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call nz, .cpHintoL ; Bit 6 set, copy H into L
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bit 5, (ix)
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call nz, .invL ; Bit 5 set, invert L
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ld a, e ; InstrID
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cp I_ANDI
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jr c, .spitRegular
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@ -332,18 +297,12 @@ parseInstruction:
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jr c, .spitRdK8
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cp I_CBI
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jr c, .spitk12
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cp I_CALL
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jr c, .spitA5Bit
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; Spit k(16)
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call .spit ; spit 16-bit const upcode
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; divide HL by 2 (PC deals with words, not bytes)
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srl h \ rr l
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; spit 16-bit K, LSB first
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ld a, l
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call ioPutB
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; spit A(5) + bit
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ld a, h
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jp ioPutB
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rla \ rla \ rla
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or l
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ld c, a
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jr .spit
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.spitRegular:
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; Regular process which places H and L, ORring it with upcode. Works
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; in most cases.
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@ -360,8 +319,6 @@ parseInstruction:
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.spitk12:
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; k(12) in HL
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; We're doing the same dance as in _readk7. See comments there.
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call zasmIsFirstPass
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jr z, .spit
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ld de, 0xfff
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add hl, de
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jp c, unsetZ ; Carry? number is way too high.
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@ -382,12 +339,6 @@ parseInstruction:
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and 0xf
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ld b, a
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jr .spit
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.spitA5Bit:
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ld a, h
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sla a \ rla \ rla
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or l
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ld c, a
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jr .spit
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.spit:
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; LSB is spit *before* MSB
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@ -454,40 +405,6 @@ parseInstruction:
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; bit in H, k in L.
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jr .spitBR2
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.LD:
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ld h, 'R'
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ld l, 'z'
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call _parseArgs
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ret nz
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ld d, 0b10000000
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jr .LDST
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.ST:
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ld h, 'z'
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ld l, 'R'
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call _parseArgs
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ret nz
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ld d, 0b10000010
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call .swapHL
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; continue to .LDST
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.LDST:
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; Rd in H, Z in L, base upcode in D
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call .placeRd
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; We're spitting LSB first, so let's compose it.
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ld a, l
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and 0b00001111
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or c
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call ioPutB
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; Now, MSB's bit 4 is L's bit 4. How convenient!
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ld a, l
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and 0b00010000
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or d
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or b
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; MSB composed!
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call ioPutB
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cp a ; ensure Z
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ret
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; local routines
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; place number in H in BC at position .......d dddd....
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; BC is assumed to be 0
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@ -524,12 +441,6 @@ parseInstruction:
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ld l, h
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ret
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.invL:
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ld a, l
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cpl
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ld l, a
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ret
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; Argspecs: two bytes describing the arguments that are accepted. Possible
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; values:
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;
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@ -542,9 +453,6 @@ parseInstruction:
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; 'D' - A double-length number which will fill whole HL.
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; 'R' - an r5 value: r0-r31
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; 'r' - an r4 value: r16-r31
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; 'z' - an indirect register (X, Y or Z), with our without post-inc/pre-dec
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; indicator. This will result in a 5-bit number, from which we can place
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; bits 3:0 to upcode's 3:0 and bit 4 at upcode's 12 in LD and ST.
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;
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||||
; All arguments accept expressions, even 'r' ones: in 'r' args, we start by
|
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; looking if the arg starts with 'r' or 'R'. If yes, it's a simple 'rXX' value,
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@ -560,8 +468,6 @@ argSpecs:
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.db 'R', 'A' ; Rd(5) + A(6)
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.db 'D', 0 ; K(12)
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.db 'a', 'b' ; A(5) + bit
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.db 'r', 0 ; Rd(4)
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.db 'b', 0 ; bit
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; Parse arguments from I/O according to specs in HL
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; H for first spec, L for second spec
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@ -622,8 +528,6 @@ _parseArgs:
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jr z, _readK8
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cp 'D'
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jr z, _readDouble
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cp 'z'
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jp z, _readz
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ret ; something's wrong
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||||
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_readBit:
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@ -659,10 +563,6 @@ _readk7:
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push ix
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call parseExpr
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jr nz, .end
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; If we're in first pass, stop now. The value of HL doesn't matter and
|
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; truncation checks might falsely fail.
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call zasmIsFirstPass
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jr z, .end
|
||||
; IX contains an absolute value. Turn this into a -64/+63 relative
|
||||
; value by subtracting PC from it. However, before we do that, let's
|
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; add 0x7f to it, which we'll remove later. This will simplify bounds
|
||||
@ -753,63 +653,4 @@ _readExpr:
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pop ix
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||||
ret
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||||
|
||||
; Parse one of the following: X, Y, Z, X+, Y+, Z+, -X, -Y, -Z.
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||||
; For each of those values, return a 5-bit value than can then be interleaved
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; with LD or ST upcodes.
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_readz:
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call strlen
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cp 3
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jp nc, unsetZ ; string too long
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||||
; Let's load first char in A and second in A'. This will free HL
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ld a, (hl)
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||||
ex af, af'
|
||||
inc hl
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||||
ld a, (hl) ; Good, HL is now free
|
||||
ld hl, .tblStraight
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||||
or a
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||||
jr z, .parseXYZ ; Second char null? We have a single char
|
||||
; Maybe +
|
||||
cp '+'
|
||||
jr nz, .skip
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||||
; We have a +
|
||||
ld hl, .tblInc
|
||||
jr .parseXYZ
|
||||
.skip:
|
||||
; Maybe a -
|
||||
ex af, af'
|
||||
cp '-'
|
||||
ret nz ; we have nothing
|
||||
; We have a -
|
||||
ld hl, .tblDec
|
||||
; continue to .parseXYZ
|
||||
.parseXYZ:
|
||||
; We have X, Y or Z in A'
|
||||
ex af, af'
|
||||
call upcase
|
||||
; Now, let's place HL
|
||||
cp 'X'
|
||||
jr z, .fetch
|
||||
inc hl
|
||||
cp 'Y'
|
||||
jr z, .fetch
|
||||
inc hl
|
||||
cp 'Z'
|
||||
ret nz ; error
|
||||
.fetch:
|
||||
ld a, (hl)
|
||||
; Z already set from earlier cp
|
||||
ret
|
||||
|
||||
.tblStraight:
|
||||
.db 0b11100 ; X
|
||||
.db 0b01000 ; Y
|
||||
.db 0b00000 ; Z
|
||||
.tblInc:
|
||||
.db 0b11101 ; X+
|
||||
.db 0b11001 ; Y+
|
||||
.db 0b10001 ; Z+
|
||||
.tblDec:
|
||||
.db 0b11110 ; -X
|
||||
.db 0b11010 ; -Y
|
||||
.db 0b10010 ; -Z
|
||||
|
||||
|
@ -21,8 +21,8 @@ IJMP, NOP, RET, RETI, SEC, SEH, SEI, SEN, SES, SET, SEV, SEZ, SLEEP, SPM*, WDR
|
||||
|
||||
XXXX XXXd dddd XXXX
|
||||
|
||||
ASR, COM, DEC, ELPM*, INC, LAC, LAS, LAT, LD*, LPM*, LSL*, LSR, NEG, POP, PUSH,
|
||||
ROR, ST*, SWAP, XCH
|
||||
ASR, COM, DEC, ELPM*, INC, LAC, LAS, LAT, LD*, LPM*, LSR, NEG, POP, PUSH, ROR,
|
||||
ST*, SWAP, XCH
|
||||
|
||||
## Rd(5) + Rr(5)
|
||||
|
||||
|
@ -1,3 +1,4 @@
|
||||
; TODO: implement instructions that are commented out
|
||||
; REGISTER USAGE
|
||||
;
|
||||
; R1: overflow counter
|
||||
|
@ -1,343 +0,0 @@
|
||||
; This is a copy of my seg7multiplex main program, translated for zasm.
|
||||
; The output of zasm was verified against avra's.
|
||||
|
||||
; 7-segments multiplexer for an ATtiny45
|
||||
;
|
||||
; Register usage
|
||||
; R0: Digit on AFF1 (rightmost, QH on the SR)
|
||||
; R1: Digit on AFF2 (QG on the SR)
|
||||
; R2: Digit on AFF3 (QF on the SR)
|
||||
; R3: Digit on AFF4 (leftmost, QE on the SR)
|
||||
; R5: always zero
|
||||
; R6: generic tmp value
|
||||
; R16: generic tmp value
|
||||
; R18: value to send to the SR. cleared at every SENDSR call
|
||||
; in input mode, holds the input buffer
|
||||
; R30: (low Z) current digit being refreshed. cycles from 0 to 3
|
||||
;
|
||||
; Flags on GPIOs
|
||||
; GPIOR0 - bit 0: Whether we need to refresh the display
|
||||
; GPIOR0 - bit 1: Set when INT_INT0 has received a new bit
|
||||
; GPIOR0 - bit 2: The value of the new bit received
|
||||
; GPIOR0 - bit 4: input mode enabled
|
||||
|
||||
; Notes on register usage
|
||||
; R0 - R3: 4 low bits are for digit, 5th bit is for dot. other bits are unused.
|
||||
;
|
||||
; Notes on AFF1-4
|
||||
; They are reversed (depending on how you see things...). They read right to
|
||||
; left. That means that AFF1 is least significant, AFF4 is most.
|
||||
;
|
||||
; Input mode counter
|
||||
; When in input mode, TIMER0_OVF, instead of setting the refresh flag, increases
|
||||
; the counter. When it reaches 3, we timeout and consider input invalid.
|
||||
;
|
||||
; Input procedure
|
||||
;
|
||||
; Input starts at INT_INT0. What it does there is very simple: is sets up a flag
|
||||
; telling it received something and conditionally sets another flag with the
|
||||
; value of the received bit.
|
||||
;
|
||||
; While we do that, we have the input loop eagerly checking for that flag. When
|
||||
; it triggers, it records the bit in R18. The way it does so is that it inits
|
||||
; R18 at 1 (not 0), then for every bit, it left shifts R18, then adds the new
|
||||
; bit. When the 6th bit of R18 is set, it means we have every bit we need, we
|
||||
; can flush it into Z.
|
||||
|
||||
; Z points directly to R3, then R2, then R1, then R0. Because display refresh
|
||||
; is disabled during input, it won't result in weird displays, and because
|
||||
; partial numbers result in error display, then partial result won't lead to
|
||||
; weird displays, just error displays.
|
||||
;
|
||||
; When input mode begins, we change Z to point to R3 (the first digit we
|
||||
; receive) and we decrease the Z pointer after every digit we receive. When we
|
||||
; receive the last bit of the last digit and that we see that R30 is 0, we know
|
||||
; that the next (and last) digit is the checksum.
|
||||
|
||||
.inc "avr.h"
|
||||
.inc "tn254585.h"
|
||||
.inc "tn45.h"
|
||||
|
||||
; pins
|
||||
.equ RCLK 0 ; on PORTB
|
||||
.equ SRCLK 3 ; on PORTB
|
||||
.equ SER_DP 4 ; on PORTB
|
||||
.equ INSER 1 ; on PORTB
|
||||
|
||||
; Let's begin!
|
||||
|
||||
.org 0x0000
|
||||
RJMP MAIN
|
||||
RJMP INT_INT0
|
||||
RETI ; PCINT0
|
||||
RETI ; TIMER1_COMPA
|
||||
RETI ; TIMER1_OVF
|
||||
RJMP INT_TIMER0_OVF
|
||||
|
||||
MAIN:
|
||||
LDI R16, RAMEND&0xff
|
||||
OUT SPL, R16
|
||||
LDI R16, RAMEND}8
|
||||
OUT SPH, R16
|
||||
|
||||
SBI DDRB, RCLK
|
||||
SBI DDRB, SRCLK
|
||||
SBI DDRB, SER_DP
|
||||
|
||||
; we generally keep SER_DP high to avoid lighting DP
|
||||
SBI PORTB, SER_DP
|
||||
|
||||
; target delay: 600us. At 1Mhz, that's 75 ticks with a 1/8 prescaler.
|
||||
LDI R16, 0x02 ; CS01, 1/8 prescaler
|
||||
OUT TCCR0B, R16
|
||||
LDI R16, 0xb5 ; TOP - 75 ticks
|
||||
OUT TCNT0, R16
|
||||
|
||||
; Enable TIMER0_OVF
|
||||
IN R16, TIMSK
|
||||
ORI R16, 0x02 ; TOIE0
|
||||
OUT TIMSK, R16
|
||||
|
||||
; Generate interrupt on rising edge of INT0
|
||||
IN R16, MCUCR
|
||||
ORI R16, 0b00000011 ; ISC00 + ISC01
|
||||
OUT MCUCR, R16
|
||||
IN R16, GIMSK
|
||||
ORI R16, 0b01000000 ; INT0
|
||||
OUT GIMSK, R16
|
||||
|
||||
; we never use indirect addresses above 0xff through Z and never use
|
||||
; R31 in other situations. We can set it once and forget about it.
|
||||
CLR R31 ; high Z
|
||||
|
||||
; put 4321 in R2-5
|
||||
CLR R30 ; low Z
|
||||
LDI R16, 0x04
|
||||
ST Z+, R16 ; 4
|
||||
DEC R16
|
||||
ST Z+, R16 ; 3
|
||||
DEC R16
|
||||
ST Z+, R16 ; 2
|
||||
DEC R16
|
||||
ORI R16, 0b00010000 ; DP
|
||||
ST Z, R16 ; 1
|
||||
CLR R30 ; replace Z to 0
|
||||
|
||||
SEI
|
||||
|
||||
LOOP:
|
||||
RCALL INPT_CHK ; verify that we shouldn't enter input mode
|
||||
SBIC GPIOR0, 0 ; refesh flag cleared? skip next
|
||||
RCALL RDISP
|
||||
RJMP LOOP
|
||||
|
||||
; ***** DISPLAY *****
|
||||
|
||||
; refresh display with current number
|
||||
RDISP:
|
||||
; First things first: setup the timer for the next time
|
||||
LDI R16, 0xb5 ; TOP - 75 ticks
|
||||
OUT TCNT0, R16
|
||||
CBI GPIOR0, 0 ; Also, clear the refresh flag
|
||||
|
||||
; Let's begin with the display selector. We select one display at once
|
||||
; (not ready for multi-display refresh operations yet). Let's decode our
|
||||
; binary value from R30 into R16.
|
||||
MOV R6, R30
|
||||
INC R6 ; we need values 1-4, not 0-3
|
||||
LDI R16, 0x01
|
||||
RDISP1:
|
||||
DEC R6
|
||||
BREQ RDISP2 ; == 0? we're finished
|
||||
LSL R16
|
||||
RJMP RDISP1
|
||||
|
||||
; select a digit to display
|
||||
; we do so in a clever way: our registers just happen to be in SRAM
|
||||
; locations 0x00, 0x01, 0x02 and 0x03. Handy eh!
|
||||
RDISP2:
|
||||
LD R18, Z+ ; Indirect load of Z into R18 then increment
|
||||
CPI R30, 4
|
||||
BRCS RDISP3 ; lower than 4 ? don't reset
|
||||
CLR R30 ; not lower than 4? reset
|
||||
|
||||
; in the next step, we're going to join R18 and R16 together, but
|
||||
; before we do, we have one thing to process: R18's 5th bit. If it's
|
||||
; high, it means that DP is highlighted. We have to store this
|
||||
; information in R6 and use it later. Also, we have to clear the higher
|
||||
; bits of R18.
|
||||
RDISP3:
|
||||
SBRC R18, 4 ; 5th bit cleared? skip next
|
||||
INC R6 ; if set, then set R6 as well
|
||||
ANDI R18, 0xf ; clear higher bits
|
||||
|
||||
; Now we have our display selector in R16 and our digit to display in
|
||||
; R18. We want it all in R18.
|
||||
SWAP R18 ; digit goes in high "nibble"
|
||||
OR R18, R16
|
||||
|
||||
; While we send value to the shift register, SER_DP will change.
|
||||
; Because we want to avoid falsely lighting DP, we need to disable
|
||||
; output (disable OE) while that happens. This is why we set RCLK,
|
||||
; which is wired to OE too, HIGH (OE disabled) at the beginning of
|
||||
; the SR operation.
|
||||
;
|
||||
; Because RCLK was low before, this triggers a "buffer clock" on
|
||||
; the SR, but it doesn't matter because the value that was there
|
||||
; before has just been invalidated.
|
||||
SBI PORTB, RCLK ; high
|
||||
RCALL SENDSR
|
||||
; Flush out the buffer with RCLK
|
||||
CBI PORTB, RCLK ; OE enabled, but SR buffer isn't flushed
|
||||
NOP
|
||||
SBI PORTB, RCLK ; SR buffer flushed, OE disabled
|
||||
NOP
|
||||
CBI PORTB, RCLK ; OE enabled
|
||||
|
||||
; We're finished! Oh no wait, one last thing: should we highlight DP?
|
||||
; If we should, then we should keep SER_DP low rather than high for this
|
||||
; SR round.
|
||||
SBI PORTB, SER_DP ; SER_DP generally kept high
|
||||
SBRC R6, 0 ; R6 is cleared? skip DP set
|
||||
CBI PORTB, SER_DP ; SER_DP low highlight DP
|
||||
|
||||
RET ; finished for real this time!
|
||||
|
||||
; send R18 to shift register.
|
||||
; We send highest bits first so that QH is the MSB and QA is the LSB
|
||||
; low bits (QD - QA) control display's power
|
||||
; high bits (QH - QE) select the glyph
|
||||
SENDSR:
|
||||
LDI R16, 8 ; we will loop 8 times
|
||||
CBI PORTB, SER_DP ; low
|
||||
SBRC R18, 7 ; if latest bit isn't cleared, set SER_DP high
|
||||
SBI PORTB, SER_DP ; high
|
||||
RCALL TOGCP
|
||||
LSL R18 ; shift our data left
|
||||
DEC R16
|
||||
BRNE SENDSR+2 ; not zero yet? loop! (+2 to avoid reset)
|
||||
RET
|
||||
|
||||
; toggle SRCLK, waiting 1us between pin changes
|
||||
TOGCP:
|
||||
CBI PORTB, SRCLK ; low
|
||||
NOP ; At 1Mhz, this is enough for 1us
|
||||
SBI PORTB, SRCLK ; high
|
||||
RET
|
||||
|
||||
; ***** INPUT MODE *****
|
||||
|
||||
; check whether we should enter input mode and enter it if needed
|
||||
INPT_CHK:
|
||||
SBIS GPIOR0, 1 ; did we just trigger INT_INT0?
|
||||
RET ; no? return
|
||||
; yes? continue in input mode
|
||||
|
||||
; Initialize input mode and start the loop
|
||||
INPT_BEGIN:
|
||||
SBI GPIOR0, 4 ; enable input mode
|
||||
CBI GPIOR0, 1 ; The first trigger was an empty one
|
||||
|
||||
; At 1/8 prescaler, a "full" counter overflow is 2048us. That sounds
|
||||
; about right for an input timeout. So we co the easy route and simply
|
||||
; clear TCNT0 whenever we want to reset the timer
|
||||
OUT TCNT0, R5 ; R5 == 0
|
||||
CBI GPIOR0, 0 ; clear refresh flag in case it was just set
|
||||
LDI R30, 0x04 ; make Z point on R3+1 (we use pre-decrement)
|
||||
LDI R18, 0x01 ; initialize input buffer
|
||||
|
||||
; loop in input mode. When in input mode, we don't refresh the display, we use
|
||||
; all our processing power to process input.
|
||||
INPT_LOOP:
|
||||
RCALL INPT_READ
|
||||
|
||||
; Check whether we've reached timeout
|
||||
SBIC GPIOR0, 0 ; refesh flag cleared? skip next
|
||||
RCALL INPT_TIMEOUT
|
||||
|
||||
SBIC GPIOR0, 4 ; input mode cleared? skip next, to INPT_END
|
||||
RJMP INPT_LOOP ; not cleared? loop
|
||||
|
||||
INPT_END:
|
||||
; We received all our date or reached timeout. let's go back in normal
|
||||
; mode.
|
||||
CLR R30 ; Ensure Z isn't out of bounds
|
||||
SBI GPIOR0, 0 ; set refresh flag so we start refreshing now
|
||||
RET
|
||||
|
||||
; Read, if needed, the last received bit
|
||||
INPT_READ:
|
||||
SBIS GPIOR0, 1
|
||||
RET ; flag cleared? nothing to do
|
||||
|
||||
; Flag is set, we have to read
|
||||
CBI GPIOR0, 1 ; unset flag
|
||||
LSL R18
|
||||
SBIC GPIOR0, 2 ; data flag cleared? skip next
|
||||
INC R18
|
||||
|
||||
; Now, let's check if we have our 5 digits
|
||||
SBRC R18, 5 ; 6th bit cleared? nothing to do
|
||||
RCALL INPT_PUSH
|
||||
|
||||
OUT TCNT0, R5 ; clear timeout counter
|
||||
|
||||
RET
|
||||
|
||||
; Push the digit currently in R18 in Z and reset R18.
|
||||
INPT_PUSH:
|
||||
ANDI R18, 0b00011111 ; Remove 6th bit flag
|
||||
|
||||
TST R30 ; is R30 zero?
|
||||
BREQ INPT_CHECKSUM ; yes? it means we're at checksum phase.
|
||||
|
||||
; Otherwise, its a regular digit push
|
||||
ST -Z, R18
|
||||
LDI R18, 0x01
|
||||
RET
|
||||
|
||||
INPT_CHECKSUM:
|
||||
CBI GPIOR0, 4 ; clear input mode, whether we error or not
|
||||
MOV R16, R0
|
||||
ADD R16, R1
|
||||
ADD R16, R2
|
||||
ADD R16, R3
|
||||
; only consider the first 5 bits of the checksum since we can't receive
|
||||
; more. Otherwise, we couldn't possibly validate a value like 9999
|
||||
ANDI R16, 0b00011111
|
||||
CP R16, R18
|
||||
BRNE INPT_ERROR
|
||||
RET
|
||||
|
||||
INPT_TIMEOUT:
|
||||
CBI GPIOR0, 4 ; timeout reached, clear input flag
|
||||
; continue to INPT_ERROR
|
||||
|
||||
INPT_ERROR:
|
||||
LDI R16, 0x0c ; some weird digit
|
||||
MOV R0, R16
|
||||
MOV R1, R16
|
||||
MOV R2, R16
|
||||
MOV R3, R16
|
||||
RET
|
||||
|
||||
; ***** INTERRUPTS *****
|
||||
|
||||
; Record received bit
|
||||
; The main loop has to be fast enough to process that bit before we receive the
|
||||
; next one!
|
||||
; no SREG fiddling because no SREG-modifying instruction
|
||||
INT_INT0:
|
||||
CBI GPIOR0, 2 ; clear received data
|
||||
SBIC PINB, INSER ; INSER clear? skip next
|
||||
SBI GPIOR0, 2 ; INSER set? record this
|
||||
SBI GPIOR0, 1 ; indicate that we've received a bit
|
||||
RETI
|
||||
|
||||
; Set refresh flag whenever timer0 overflows
|
||||
; no SREG fiddling because no SREG-modifying instruction
|
||||
INT_TIMER0_OVF:
|
||||
SBI GPIOR0, 0
|
||||
RETI
|
||||
|
||||
|
Binary file not shown.
@ -14,13 +14,3 @@ rcall baz
|
||||
baz:
|
||||
out 0x2e, r12
|
||||
in r0, 0x9
|
||||
cbr r31, 0xff
|
||||
sbis 22, 5
|
||||
ser r19
|
||||
bset 4
|
||||
bclr 7
|
||||
call foo
|
||||
jmp bar
|
||||
mov r6, r30
|
||||
lsl r3
|
||||
tst r12
|
||||
|
Binary file not shown.
@ -1,18 +0,0 @@
|
||||
ld r0, X
|
||||
ld r1, Y
|
||||
ld r2, Z
|
||||
ld r3, X+
|
||||
ld r4, Y+
|
||||
ld r5, Z+
|
||||
ld r6, -X
|
||||
ld r7, -Y
|
||||
ld r8, -Z
|
||||
st X, r9
|
||||
st Y, r10
|
||||
st Z, r11
|
||||
st X+, r12
|
||||
st Y+, r13
|
||||
st Z+, r14
|
||||
st -X, r15
|
||||
st -Y, r16
|
||||
st -Z, r17
|
@ -1,2 +0,0 @@
|
||||
<0C>€ €=<3D>I<EFBFBD>Q<EFBFBD>n<EFBFBD>z<EFBFBD>‚<EFBFBD>ś’¨‚°‚Í’Ů’á’ţ’
|
||||
““
|
Loading…
Reference in New Issue
Block a user