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adea75e50a
I'm pretty happy about how lightweight the implementation turns out to be.
279 lines
8.1 KiB
Plaintext
279 lines
8.1 KiB
Plaintext
# Assembling Z80 binaries
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(All assembers in Collapse OS follow the same basic principles.
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There are sections, below, for each supported architectures, but
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you should read this first section first to be familiar with
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those common, basic principles)
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Words in the Z80 assembler, loaded with "5 LOAD" allow you to
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assemble z80 binaries. Being Forth words, opcode assembly is a
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bit different than with a typical assembler. For example, what
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would traditionally be "ld a, b" would become "A B LDrr,".
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Those opcode words, of which there is a complete list below, end
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with "," to indicate that their effect is to write (,) the cor-
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responding opcode.
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The "argtype" suffix after each mnemonic is needed because the
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assembler doesn't auto-detect the op's form based on arguments.
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It has to be explicitly specified. "r" is for 8-bit registers,
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"d" for 16-bit ones, "i" for immediate, "c" is for conditions.
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Be aware that "SP" and "AF" refer to the same value: some 16-
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bit ops can affect SP, others, AF. If you use the wrong argu-
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ment on the wrong op, you will affect the wrong register.
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Mnemonics having only a single form, such as PUSH and POP,
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don't have argtype suffixes.
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In addition to opcode words, some variables are also defined by
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this program:
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BIN( is the addr at which the compiled binary will live. It is
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often 0.
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ORG is H@ offset at which we begin spitting binary. Used to
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compute PC. To have a proper PC, call "H@ ORG !" at the
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beginning of your assembly process. PC is H@ - ORG + BIN(.
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Labels are a convenient way of managing relative jump
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calculations. Backward labels are easy. It is only a matter or
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recording "HERE" and do subtractions. Forward labels record the
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place where we should write the offset, and then when we get to
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that point later on, the label records the offset there.
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To avoid using dict memory in compilation targets, we
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pre-declare label variables here, which means we have a limited
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number of it. We have 4: L1, L2, L3, L4.
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# Flow
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There are 2 label types: backward and forward. For each type,
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there are two actions: set and write. Setting a label is
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declaring where it is. Words for this are BSET and FSET. It has
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to be performed at the label's destination. Writing a label is
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writing its offset difference to the binary result. It has to be
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done right after a relative jump operation. Word for this are
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BWR and FWR. Yes, those words are only for relative jumps.
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For backward labels, set happens before write. For forward
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labels, write happen before set. The write operation writes a
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dummy placeholder, and then the set operation writes the offset
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at that placeholder's address.
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Variable actions are expected to be called with labels in
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front of them. Examples:
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L1 BSET NOP, JR, L1 BWR ( backward jump )
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JR, L1 FWR NOP, L1 FSET ( forward jump )
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If you look at the code for those words, you'll notice a mys-
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terious "1-". z80 relative jumps receives "e-2", that is, the
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offset that *counts the 2 bytes of the jump itself*. Because we
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set the label *after* the jump OP1 itself, that's 1 byte that is
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taken care of. We still need to adjust by another byte before
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writing the offset.
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Can you use labels with JP, and CALL,? Yes, but only backwards
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jumps, and in that case, you use the label's value directly.
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Example: L2 @ CALL,
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# Structured flow
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z80a also has words that behave similarly to IF..THEN and
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BEGIN..UNTIL.
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On the IF side, we have IFZ, IFNZ, IFC, IFNC, and THEN,. When
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the opposite condition is met, a relative jump is made to
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THEN,'s PC. For example, if you have IFZ, a jump is made when
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Z is unset.
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On the BEGIN,..AGAIN, side, it's a bit different. You start
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with your BEGIN, instruction, and then later you issue a
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JRxx, instr followed by AGAIN,. Exactly like you would do
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with a label.
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On top of that, you have the very nice BREAK, instruction,
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which must also be preceded by a JRxx, and will jump to the
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PC following the next AGAIN,. Examples:
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IFZ, NOP, THEN,
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BEGIN, NOP, JR, AGAIN, ( unconditional )
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BEGIN, NOP, JRZ, AGAIN, ( conditional )
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BEGIN, NOP, JRZ, BREAK, JR, AGAIN, ( break off the loop )
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# Z80 Instructions list
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Letters in [] brackets indicate "argtype" variants. When the
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bracket starts with ",", it means that a "plain" mnemonic is
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available. For example, "RET," and "RETc," exist.
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Note that assemblers in Collapse OS are incomplete and opcode
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words were implemented in a "just-in-time" fashion, when needed.
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r => A B C D E H L (HL)
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d => BC DE HL AF/SP
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c => CNZ CZ CNC CC CPO CPE CP CM
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LD [rr, ri, di, (i)HL, HL(i), d(i), (i)d, rIXY, IXYr,
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(DE)A, A(DE), (i)A, A(i)]
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ADD [r, i, HLd, IXd, IXIX, IYd, IYIY]
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ADC [r, HLd]
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CP [r, i, (IXY+)]
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SBC [r, HLd]
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SUB [r, i]
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INC [r, d, (IXY+)]
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DEC [r, d, (IXY+)]
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AND [r, i]
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OR [r, i]
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XOR [r, i]
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OUT [iA, (C)r]
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IN [Ai, r(C)]
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JP [i, (HL), (IX), (IY)]
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JR [, Z, NZ, C, NC]
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PUSH POP
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SET RES BIT
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RL RLC SLA RLA RLCA
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RR RRC SRL RRA RRCA
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CALL RST DJNZ
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DI EI EXDEHL EXX HALT
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NOP RET [,c] RETI RETN SCF
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Macros:
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SUBHLd PUSH [0,1,Z,A] HLZ DEZ
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LDDE(HL) OUT [HL,DE]
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# 8086 assembler
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Load with "30 LOAD". As with the Z80 assembler, it is incom-
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plete.
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Mnemonics are followed by argument types. For example, MOVri,
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moves 8-bit immediate to 8-bit register.
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'r' = 8-bit register 'x' = 16-bit register
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'i' = 8-bit immediate 'I' = 16-bit immediate
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's' = SREG register
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Mnemonics that only have one signature (for example INT,) don't
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have operands letters.
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For jumps, it's special. 's' is SHORT, 'n' is NEAR, 'f' is FAR.
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# 8086 Instructions list
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r -> AL BL CL DL AH BH CH DX
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x -> AX BX CX DX SP BP SI DI
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s -> ES CS SS DS
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[] -> [SI] [DI] [BP] [BX] [BX+SI] [BX+DI] [BP+SI] [BP+DI]
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RET CLI STI HLT CLD STD NOP CBW REPZ REPNZ
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LODSB LODSW CMPSB SMPSW MOVSB MOVSW SCASB SCASW STOSB STOSW
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CALL J[Z,NZ,C,NC] JMP[s,n,r,f]
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INC[r,x,[w],[b],[w]+,[b]+]
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DEC[r,x,[w],[b],[w]+,[b]+]
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POP[x,[w],[w]+]
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PUSH[x,[w],[w]+,s]
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MUL[r,x]
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DIV[r,x]
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XOR[rr,xx]
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OR[rr,xx]
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AND[rr,xx,ALi,AXI]
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ADD[rr,xx,ALi,AXI,xi]
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SUB[rr,xx,ALi,AXI,xi]
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INT
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CMP[rr,xx,r[],x[],r[]+,x[]+]
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MOV[rr,xx,r[],x[],[]r,[]x,r[]+,x[]+,[]+r,[]+x,ri,xI,sx,rm,xm
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mr,mx]
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("1" means "shift by 1", "CL" means "shift by CL")
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ROL[r1,x1,rCL,xCL]
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ROR[r1,x1,rCL,xCL]
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SHL[r1,x1,rCL,xCL]
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SHR[r1,x1,rCL,xCL]
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# AVR assembler
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Load with "50 LOAD". As with the Z80 assembler, it is incom-
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plete.
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All mnemonics in AVR have a single signature. Therefore, we
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don't need any "argtype" suffixes.
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Registers are referred to with consts R0-R31. There is
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X, Y, Z, X+, Y+, Z+, X-, Y-, Z- for appropriate ops (LD, ST).
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XL, XH, YL, YH, ZL, ZH are simple aliases to R26-R31.
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Branching works differently. Instead of expecting a byte to be
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written after the naked op, branching words expect a displace-
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ment argument.
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This is because there's bitwise ORing involved in the creation
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of the final opcode, which makes z80a's approach impractical.
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This makes labelling a bit different too. Instead of expecting
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label words after the naked branching op, we rather have label
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words expecting branching wordref as an argument. Examples:
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L2 ' BRTS FLBL! ( branch forward to L2 )
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L1 ' RJMP LBL, ( branch backward to L1 )
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# Model-specific constants
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Model-specific constants must be loaded separately. Here is a
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list of units:
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- ATMega328P: B65-B66
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Those units contain register constants such as PORTB, DDRB, etc.
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Unlike many moder assemblers, they do not include bit constants.
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Here's an example use:
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DDRB 5 SBI,
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PORTB 5 CBI,
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R16 TIFR0 IN,
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R16 0 ( TOV0 ) SBRS,
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# AVR instructions list
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OPRd (B53)
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ASR COM DEC INC LAC LAS LAT LSR NEG POP PUSH
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ROR SWAP XCH
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OPRdRr (B54)
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ADC ADD AND CP CPC CPSE EOR MOV MUL OR SBC
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SUB
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OPRdA (B54)
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IN OUT
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OPRdK (B55)
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ANDI CPI LDI ORI SBCI SBR SUBI
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OPAb (B55)
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CBI SBI SBIC SBIS
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OPNA (B56)
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BREAK CL[C,H,I,N,S,T,V,Z] SE[C,H,I,N,S,T,V,Z] EIJMP ICALL
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EICALL IJMP NOP RET RETI SLEEP WDR
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OPb (B57)
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BCLR BSET
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OPRdb (B57)
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BLD BST SBRC SBRS
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Special (B57,B60)
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CLR TST LSL LD ST
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Flow (B58)
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RJMP RCALL
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BR[BC,BS,CC,CS,EQ,NE,GE,HC,HS,ID,IE,LO,LT,MI,PL,SH,TC,TS,VC,VS]
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Flow macros (B61)
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LBL! LBL, SKIP, TO, FLBL, FLBL! BEGIN, AGAIN? AGAIN, IF, THEN,
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