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[/] [light8080/] [trunk/] [ucode/] [light8080.m80] - Rev 49

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////////////////////////////////////////////////////////////////////////////////
// LIGHT8080 CORE MICROCODE (V.1 November 1st 2007)
////////////////////////////////////////////////////////////////////////////////
// NOTE: Except for bug fixing, there's no need to tinker with the microcode. 
// Once the microcode table has been generated, this file is is not needed to 
// synthesize or use the core.
////////////////////////////////////////////////////////////////////////////////
//
// ***** FORMAT AND OPERATION:
//
// operation 1 ; operation 2 ; flags
//
// Operation 1 sets up the ALU input registers; operation 2 takes the ALU result
// and writes it back somewhere; and the flags group all other microinstruction 
// control signals.
//  
// For any given microinstruction, operation 2 takes place in the cycle after 
// operation 1. It happens concurrently with the next microinstruction's 
// operation 1, so whenever a register is written to in an operation 2 it will 
// NOT be available for the next microinstruction.
//
// In operation 1, you may load any one of T1 or T2 from the register bank or
// from DI which is simply the unregistered signal data_in.
//  
// In operation 2, you specify the ALU operation and assign the ALU result to 
// the register bank or the register DO, which feeds the signal data_out. 
//  
// You cannot address two different registers from the register bank in 
// operations 1 and 2 (see the design notes on this).
//  
// *** Some other elements found in the microcode source:
//
// labels: must be in a line by themselves, otherwise work like any assembler.
// __code pragmas: used by assembler to automatically generate the decode table.
// __asm pragmas: not used, but can be handy as a reference.
//
//
// ***** FLAGS:
//
// Note: '1st cycle' and '2nd cycle' denote both cycles of the present 
// microinstruction (m.i.); cycle 2 of m.i. N overlaps cycle 1 of m.i. N+1.
//
// #ld_al :   Load AL register with register bank output as read by operation 1.
//            (used in memory and io access). 
// #ld_addr : Load address register (H byte = register bank output as read by 
//            operation 1, L byte = AL). 
//            Activate vma signal for 1st cycle.
// #auxcy :   Use aux carry instead of regular carry for this operation. 
// #setacy :  Set aux carry at the start of 1st cycle (used for ++).
// #end :     Jump to microinstruction address 3 after the present m.i.
// #ret :     Jump to address saved by the last JST or TJSR m.i.
// #rd :      Activate rd signal for the 2nd cycle.
// #wr :      Activate wr signal for the 2nd cycle.
// #fp_r :    This microinstruction updates all PSW flags except for C.
// #fp_c :    This microinstruction updates only the C flag in the PSW.
// #fp_rc :   This microinstruction updates all the flags in the PSW.
// #clrt1 :   Clear T1 at the end of 1st cycle.
// #io :      Activate io signal for 1st cycle.
// #ei :      Set interrupt enable register.
// #di :      Reset interrupt enable register.
// #halt :    Jump to microcode address 0x07 without saving return value.
//
////////////////////////////////////////////////////////////////////////////////

// RESET ucode: from 0 to 2, but uinst at address 0 is never executed
__reset 

NOP           ; NOP                     
NOP           ; _pl = AND                       ;                                                                 // T1 & T2 = 0x00
NOP           ; _ph = AND     ;                                                           // T1 & T2 = 0x00

// FETCH ucode: from 3 to 6 
// (executed in INTA cycles too, with pc increment inhibited to preserve PC)
__fetch

T1 = _pl      ; _pl = ADC     ; #ld_al, #auxcy, #setacy
T1 = _ph      ; _ph = ADC     ; #ld_addr, #rd, #auxcy
NOP           ; NOP           ; #decode

// free uinst slot
NOP           ; NOP           ;

// HALT ucode: address 7
__halt
NOP           ; NOP           ; #halt, #end


// NOTE: ALU single_operand ops work on T1
// ALU 2-operands work with 'A' on T2 (e.g. SUB == T2 - T1)


__code  "01dddsss"
__asm   MOV {d},{s}

T1 = {s}      ; NOP
NOP           ; {d} = T1      ; #end


__code  "01ddd110"
__asm   MOV {d},M 

JSR read_m              ;
NOP           ; {d} = T1      ; #end  


__code  "01110sss"
__asm   MOV M,{s}

T1 = {s}      ; DO = T1
JSR write_m                   // does not return


__code  "00ddd110"
__asm   MVI {d},#imm

JSR read_imm
NOP           ; {d} = T1      ; #end


__code  "00110110"
__asm   MVI M,#imm

JSR read_imm 
JSR write_m


__code  "00pp0001"
__asm   LXI [p]

JSR read_imm
NOP           ; {p}1 = T1
JSR read_imm
NOP           ; {p}0 = T1     ; #end


__code  "00111010"
__asm   LDA addr

JSR read_imm_wz
JSR read_wz 
NOP           ; _a = T1       ; #end


__code  "00110010"
__asm   STA addr

JSR read_imm_wz
T1 = _a       ; DO = T1       ;
JSR write_wz                    //does not return


__code  "00101010"
__asm   LHLD 


JSR read_imm_wz
T1 = _z       ; _z = ADC      ; #ld_al, #auxcy, #setacy // L = (WZ++)
T1 = _w       ; _w = ADC      ; #ld_addr, #rd, #auxcy
T1 = DI       ; _l = T1
JSR read_wz                                             // H = (WZ)
NOP           ; _h = T1       ; #end           


__code  "00100010"
__asm   SHLD 

JSR read_imm_wz
T1 = _l       ; DO = T1
T1 = _z       ; _z = ADC      ; #ld_al, #auxcy, #setacy
T1 = _w       ; _w = ADC      ; #ld_addr, #wr, #auxcy
T1 = _h       ; DO = T1                             
JSR write_wz


__code  "00pp1010"
__asm   LDAX [p]

JSR read_p
NOP           ; _a = T1       ; #end


__code  "00pp0010"
__asm   STAX [p]

T1 = _a       ; DO = T1
JSR write_p


__code  "11101011"
__asm   XCHG

// 16 T cycles vs. 10 for the original 8080...
T1 = _d       ; NOP
NOP           ; _x = T1
T1 = _e       ; NOP
NOP           ; _y = T1
T1 = _h       ; NOP
NOP           ; _d = T1
T1 = _l       ; NOP
NOP           ; _e = T1
T1 = _x       ; NOP
NOP           ; _h = T1
T1 = _y       ; NOP
NOP           ; _l = T1         ; #end


__code  "11000110"
__asm   ADI #imm

JSR read_imm
T2 = _a       ; _a = ADD      ; #end, #fp_rc

__code  "11001110"
__asm   ACI #imm

JSR read_imm
T2 = _a       ; _a = ADC      ; #end, #fp_rc

__code  "11010110"
__asm   SUI #imm

JSR read_imm
T2 = _a       ; _a = SUB      ; #end, #fp_rc

__code  "11011110"
__asm   SBI #imm

JSR read_imm
T2 = _a       ; _a = SBB      ; #end, #fp_rc


__code  "11100110"
__asm   ANI #imm

JSR read_imm
T2 = _a       ; _a = AND      ; #end, #fp_rc

__code  "11101110"
__asm   XRI #imm

JSR read_imm
T2 = _a       ; _a = XRL      ; #end, #fp_rc


__code  "11110110"
__asm   ORI #imm

JSR read_imm
T2 = _a       ; _a = ORL      ; #end, #fp_rc


__code  "11111110"
__asm   CPI #imm

JSR read_imm
T2 = _a       ; DO = SUB      ; #end, #fp_rc



__code  "10000sss"
__asm   ADD {s}

T1 = {s}      ; NOP   
T2 = _a       ; _a = ADD      ; #end, #fp_rc

__code  "10001sss"
__asm   ADC {s}

T1 = {s}      ; NOP   
T2 = _a       ; _a = ADC      ; #end, #fp_rc

__code  "10010sss"
__asm   SUB {s}

T1 = {s}      ; NOP   
T2 = _a       ; _a = SUB      ; #end, #fp_rc

__code  "10011sss"
__asm   SBB {s}

T1 = {s}      ; NOP   
T2 = _a       ; _a = SBB      ; #end, #fp_rc

__code  "10100sss"
__asm   ANA {s}

T1 = {s}      ; NOP   
T2 = _a       ; _a = AND      ; #end, #fp_rc

__code  "10101sss"
__asm   XRA {s}

T1 = {s}      ; NOP   
T2 = _a       ; _a = XRL      ; #end, #fp_rc

__code  "10110sss"
__asm   ORA {s}

T1 = {s}      ; NOP   
T2 = _a       ; _a = ORL      ; #end, #fp_rc

__code  "10111sss"
__asm   CMP {s}

T1 = {s}      ; NOP   
T2 = _a       ; DO = SUB      ; #end, #fp_rc


__code  "10000110"
__asm   ADD M

JSR read_m
T2 = _a       ; _a = ADD      ; #end, #fp_rc

__code  "10001110"
__asm   ADC M

JSR read_m
T2 = _a       ; _a = ADC      ; #end, #fp_rc

__code  "10010110"
__asm   SUB M

JSR read_m
T2 = _a       ; _a = SUB      ; #end, #fp_rc

__code  "10011110"
__asm   SBB M

JSR read_m
T2 = _a       ; _a = SBB      ; #end, #fp_rc

__code  "10100110"
__asm   ANA M

JSR read_m
T2 = _a       ; _a = AND      ; #end, #fp_rc

__code  "10101110"
__asm   XRA M

JSR read_m
T2 = _a       ; _a = XRL      ; #end, #fp_rc

__code  "10110110"
__asm   ORA M

JSR read_m
T2 = _a       ; _a = ORL      ; #end, #fp_rc


__code  "10111110"
__asm   CMP M

JSR read_m
T2 = _a       ; DO = SUB      ; #end, #fp_rc


__code  "00ddd100"
__asm   INR {d}

T1 = {d}      ; {d} = ADC     ; #auxcy, #setacy, #fp_r
NOP           ; NOP           ; #end  // extra line, flag clash


__code  "00110100"
__asm   INR M

JSR read_m
NOP           ; DO = ADC      ; #auxcy, #setacy, #fp_r
JSR write_m


__code  "00ddd101"
__asm   DCR {d}

T2 = {d}      ; {d} = SBB     ; #auxcy, #setacy, #fp_r
NOP           ; NOP           ; #end   // extra line, flag clash


__code  "00110101"
__asm   DCR M

JSR read_m // T1 = _x = (HL); but we need it in T2!
NOP           ; NOP           ; #clrt1 // flag clash
T2 = _x       ; DO = SBB      ; #auxcy, #setacy, #fp_r
JSR write_m


__code  "00pp0011"
__asm   INX [p]

T1 = {p}1     ; {p}1 = ADC      ; #auxcy, #setacy
T1 = {p}0     ; {p}0 = ADC      ; #end, #auxcy 


__code  "00pp1011"
__asm   DCX [p]

T2 = {p}1     ; {p}1 = SBB      ; #auxcy, #setacy  // T2 because SUB -> T2 - T1
T2 = {p}0     ; {p}0 = SBB      ; #end, #auxcy 


__code  "00pp1001"
__asm   DAD [p]

T2 = {p}1     ; NOP
T1 = _l       ; _l = ADD      ; #fp_c // we need this cy
T2 = {p}0     ; NOP           ; 
T1 = _h       ; _h = ADC      ; #end, #fp_c


__code  "00100111"
__asm   DAA

// DAA result is only valid after the 2nd cycle;
T1 = _a       ; DO = DAA        ; //DO value ignored
T1 = _a       ; _a = DAA        ; #end, #fp_rc


__code  "00000111"
__asm   RLC

T1 = _a       ; _a = rla       ; #end, #fp_c


__code  "00001111"
__asm   RRC

T1 = _a       ; _a = rra       ; #end, #fp_c


__code  "00010111"
__asm   RAL

T1 = _a       ; _a = rlca      ; #end, #fp_c


__code  "00011111"
__asm   RAR

T1 = _a       ; _a = rrca      ; #end, #fp_c


__code  "00101111"
__asm   CMA

T1 = _a       ; _a = NOT        ; #end


__code  "00111111"
__asm   CMC

NOP           ; cpc              ; #end, #fp_c


__code  "00110111"
__asm   STC

NOP           ; sec              ; #end, #fp_c


__code  "11000011"
__asm   JMP addr

JSR read_imm_wz
:jmp_addr
T1 = _z       ; NOP 
NOP           ; _pl = T1
T1 = _w       ; NOP 
NOP           ; _ph = T1      ; #end



__code  "00000000"
__asm   NOP

NOP           ; NOP           ; #end


__code  "11ccc010"
__asm   {JZ,JNZ,JC,JNC,JPO,JPE,JP,JM} addr

JSR read_imm_wz
TJSR jmp_addr           // TJSR does the JSR or does #end the instruction.


__code  "11001101"
__asm   CALL addr

//:call_addr
JSR read_imm_wz
:call_addr //@@
T1 = _ph      ; DO = T1         ; #clrt1
JSR push
T1 = _pl      ; DO = T1         ; #clrt1
JSR push
T1 = _z       ; NOP
NOP           ; _pl = T1
T1 = _w       ; NOP
NOP           ; _ph = T1        ; #end



__code  "11ccc100"
__asm   {CZ,CNZ,CC,CNC,CPO,CPE,CP,CM} addr

JSR read_imm_wz     // skip next 2 bytes
TJSR call_addr      // TJSR does the JSR or does #end the instruction.            


__code  "11001001"
__asm   RET

:ret
JSR pop
NOP           ; _pl = T1
JSR pop
NOP           ; _ph = T1        ; #end


__code  "11ccc000"
__asm   {RZ,RNZ,RC,RNC,RPO,RPE,RP,RM}


TJSR ret      // TJSR does the JSR or does #end the instruction.



__code  "11nnn111"
__asm   {RST 0h,RST 8h,RST 10h,RST 18h,RST 20h,RST 28h,RST 30h,RST 38h}

T1 = _ph      ; DO = T1       ; #clrt1
JSR push
T1 = _pl      ; DO = T1       ; #clrt1
JSR push
NOP           ; _pl = rst     ; #clrt1
NOP           ; _ph = AND     ; #end  // T1 & T2 = 0, because T2=0
// No extra cycle needed, _ph is not used in the next microinstruction

__code  "11101001"
__asm   PCHL

T1 = _l       ; NOP
NOP           ; _pl = T1
T1 = _h       ; NOP
NOP           ; _ph = T1        ; #end


__code  "11pp0101"  //Except for PUSH PSW
__asm   PUSH [p]

T1 = {p}0     ; DO = T1         ; #clrt1  // H first...
JSR push 
T1 = {p}1     ; DO = T1         ; #clrt1  // ...L last
JSR push 
NOP           ; NOP             ; #end


__code  "11110101"
__asm   PUSH PSW

T1 = _a       ; DO = T1         ; #clrt1
JSR push      
NOP           ; DO = PSW        ; #clrt1
JSR push 
NOP           ; NOP             ; #end


__code  "11pp0001"  //Except for POP PSW
__asm   POP [p]

JSR pop
NOP           ; {p}1 = T1
JSR pop
NOP           ; {p}0 = T1       ; #end


__code  "11110001"
__asm   POP PSW

JSR pop
NOP           ; _f = T1         ; #fp_rc //F<-(SP); F f-fs load automatically
JSR pop
NOP           ; _a = T1         ; #end


__code  "11100011"
__asm   XTHL

JSR pop
NOP           ; _z = T1
JSR pop
NOP           ; _w = T1         
T1 = _h       ; DO = T1         ; #clrt1
JSR push 
T1 = _l       ; DO = T1         ; #clrt1
JSR push 
T1 = _z       ; NOP
NOP           ; _l = T1
T1 = _w       ; NOP
NOP           ; _h = T1         ; #end


__code  "11111001"
__asm   SPHL

T1 = _l       ; NOP
NOP           ; _sl = T1
T1 = _h       ; NOP
NOP           ; _sh = T1           ; #end


__code  "11111011"
__asm   EI

NOP           ; NOP                ; #ei, #end


__code  "11110011"
__asm   DI

NOP           ; NOP                ; #di, #end


__code  "11011011"
__asm   IN port

NOP           ; _w = T1             // _w = 0
JSR read_imm                        // T1 = port
NOP           ; _z = T1             // #ld_al reads from mux...
NOP           ; NOP
T1 = _z       ; NOP           ; #ld_al
T1 = _w       ; NOP           ; #ld_addr, #rd, #io
T1 = DI       ; _a = T1       ; #end


// Can be reduced to 11 states by removing 1st uinst
// Then, _b might be put on high addr byte as in the original...
__code  "11010011"
__asm   OUT port


NOP           ; _w = T1             // _w = 0, put on high byte of io address
JSR read_imm                        // T1 = port
NOP           ; _z = T1             // #ld_al reads from mux...
T1 = _a       ; DO = T1
T1 = _z       ; NOP           ; #ld_al
T1 = _w       ; NOP           ; #ld_addr, #wr, #io
NOP           ; NOP           ; #end


__code  "01110110"
__asm   HLT
//TODO doc: #halt has to be in the same cycle as #end
NOP           ; NOP           ; #halt, #end




//********************************************

// T1 = (HL)

:read_m

T1 = _l       ; NOP           ; #ld_al
T1 = _h       ; NOP           ; #ld_addr, #rd
T1 = DI       ; _x = T1       ; #ret

// (HL) = DO, does not return
// TODO extra uinst is for wait state, which is not implemented

:write_m

T1 = _l       ; NOP           ; #ld_al
T1 = _h       ; NOP           ; #ld_addr, #wr
NOP           ; NOP           ; #end


// T1 = (PC++), DO = T1
// T2 must be 0 on entry
:read_imm

T1 = _pl      ; _pl = ADC     ; #ld_al, #auxcy, #setacy
T1 = _ph      ; _ph = ADC     ; #ld_addr, #rd, #auxcy
T1 = DI       ; DO = T1       ; #ret


// T1 = (WZ)

:read_wz

T1 = _z       ; NOP           ; #ld_al
T1 = _w       ; NOP           ; #ld_addr, #rd
T1 = DI       ; NOP           ; #ret


// (WZ) = DO, does not return
// TODO extra uinst is for wait state, which is not implemented

:write_wz

T1 = _z       ; NOP           ; #ld_al
T1 = _w       ; NOP           ; #ld_addr, #wr
NOP           ; NOP           ; #end

// T1 = (RP)

:read_p

T1 = {p}1     ; NOP           ; #ld_al
T1 = {p}0     ; NOP           ; #ld_addr, #rd
T1 = DI       ; NOP           ; #ret


// (RP) = DO, does not return
// TODO extra uinst is for wait state, which is not implemented

:write_p

T1 = {p}1     ; NOP           ; #ld_al
T1 = {p}0     ; NOP           ; #ld_addr, #wr
NOP           ; NOP           ; #end

// WZ = imm16

:read_imm_wz

T1 = _pl      ; _pl = ADC     ; #ld_al, #auxcy, #setacy
T1 = _ph      ; _ph = ADC     ; #ld_addr, #rd, #auxcy
T1 = DI       ; _z = T1      
T1 = _pl      ; _pl = ADC     ; #ld_al, #auxcy, #setacy
T1 = _ph      ; _ph = ADC     ; #ld_addr, #rd, #auxcy
T1 = DI       ; _w = T1       ; #ret

// push DO
// no wait cycle! 

:push
T2 = _sl      ; _sl = SBB     ; #auxcy, #setacy 
T2 = _sh      ; _sh = SBB     ; #auxcy 
T1 = _sl                        ; NOP                                           ; #ld_al
T1 = _sh                        ; NOP                                           ; #ld_addr, #wr,
NOP           ; NOP           ; #ret   // extra line, flag clash


// POP T1

:pop
T1 = _sl      ; _sl = ADC     ; #ld_al, #auxcy, #setacy
T1 = _sh      ; _sh = ADC     ; #ld_addr, #rd, #auxcy
T1 = DI       ; NOP                                       ; #ret        // extra line, flag clash


// End of file

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