Difference between revisions of "Z80"
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| IX, IY (Index Registers) || 16-bit || Used for indexed addressing || Can be split into IXH/IXL, IYH/IYL for 8-bit access | | IX, IY (Index Registers) || 16-bit || Used for indexed addressing || Can be split into IXH/IXL, IYH/IYL for 8-bit access | ||
+ | |- | ||
+ | | IM (Interrupt Mode) || 2-bit || Specifies the interrupt mode (0, 1, or 2) || Controls how interrupts are handled: | ||
+ | * IM 0: External devices provide interrupt vectors. | ||
+ | * IM 1: Fixed vector at 0038h. | ||
+ | * IM 2: Vector provided by I register and external data. | ||
|- | |- | ||
| I (Interrupt Vector) || 8-bit || Holds base address for interrupt mode 2 || Combined with external data to form an interrupt vector | | I (Interrupt Vector) || 8-bit || Holds base address for interrupt mode 2 || Combined with external data to form an interrupt vector |
Revision as of 23:54, 31 August 2024
Microprocessor from Zilog, which is used in the Amstrad CPC Computers. The Z80/Z80A was a very popular microprocessor, used in a great variety of home computers and appliances as far-fetched as satellites. It was even used in the Commodore C128 as a secondary processor in order to achieve CP/M compatibility.
Contents
Description
The Z80 microprocessor is an 8 bit CPU with a 16 bit address bus capable of direct access to 64k of memory space. It has a language of 252 root instructions and with the reserved 4 bytes as prefixes, access to an additional 308 instructions. The Z80 was modelled after the 8080 and contains the seventy-eight 8080 opcodes as a subset to its language.
Programming features include an accumulator and six 8-bit registers that can be paired as three 16-bit registers. In addition to the general registers, a stack pointer, program counter, and two index (memory pointer) registers are provided. While not in the same league as the Intel 80x86 or the Motorola 68000 series, the Z80 is extremely useful for low cost control applications. One of the more useful features of the Z80 is the built-in refresh circuitry for ease of design with DRAMs.
The Z80 comes in a 40 pin DIP package. It has been manufactured in A, B, and C models, differing only in maximum clock speed. It also has been manufactured as a stand-alone microcontroller with various configurations of on-chip RAM and EPROM.
Part numbers used in the Amstrad CPC during its lifetime
The Z80 CPU has been manufactured by others, and various Z80s have been used in the construction of the CPC during its lifetime.
- SGS Z8400AB1
- ST Z8400AB1
- ZILOG Z8400APS
- ZILOG Z0840004PSC
modern incarnatinons
Apart from surplus/new Z80-clones that are quite easy to find, many emulations depend on software implementations of the Z80:
- The T80 is a VHDL implementation of the Z80 and Z80A, finished in 2002 on OpenCores
- arnold uses InkZ80, written in C++ (apart from the author-designed C simulation)
- On OpenCores, there is also a Verilog implementation of the Z80.
Zilog itself offers the eZ80 processor, a new, 50MHz design. Kits now have reached a less-than-prohibitive price range and may be available without a business.
See also
Block Diagram
Manuals
- Official Zilog Z80 CPU user manual (2016)
- Media:Z80 CPU Technical Manual 1977.pdf
- Media:Mostek Z80 Programming Manual.pdf
Weblinks
- Zilog [1]
- Computer Systems based on Z80 Family
- The Z80 processor on Wikipedia
- Z80 documentation from Grimware
- Detailed look at Z80 instruction timings with the help of a Z80 netlist simulation
- Z80 Instruction Set on WikiTI
Registers
Register | Size | Description | Notes |
---|---|---|---|
B, C, D, E, H, L | 8-bit | General-purpose registers | Can form 16-bit pairs: BC, DE, HL |
A (Accumulator) | 8-bit | Main register for arithmetic, logic, and data transfer | Most used register |
F (Flags) | 8-bit |
|
Flags are affected by most operations |
AF', BC', DE', HL' | 16-bit | Alternate register set | Swappable with primary registers for fast context switching |
SP (Stack Pointer) | 16-bit | Points to top of the stack | Used for subroutine calls and interrupt handling |
PC (Program Counter) | 16-bit | Points to the next instruction | Automatically increments as instructions execute |
IX, IY (Index Registers) | 16-bit | Used for indexed addressing | Can be split into IXH/IXL, IYH/IYL for 8-bit access |
IM (Interrupt Mode) | 2-bit | Specifies the interrupt mode (0, 1, or 2) | Controls how interrupts are handled:
|
I (Interrupt Vector) | 8-bit | Holds base address for interrupt mode 2 | Combined with external data to form an interrupt vector |
R (Memory Refresh) | 8-bit | Increments after each instruction fetch to refresh DRAM | Only the lower 7 bits are incremented |
IFF1 | 1-bit | Interrupt enable flag | Set when interrupts are enabled, cleared on disable |
IFF2 | 1-bit | IFF1 buffer | Allows interrupts to be enabled after the instruction following EI |
WZ | 16-bit | Internal temporary register pair | Used for memory and address calculations (not user-accessible) |
Opcodes
Check the end of the document for explanations of abbreviations used below.
Alphabetical list
Mnemonic | Clock | Size | SZHPNC | Opcode | Description | Notes |
ADC A, r | 4 | 1 | *** V0 * | 88 + rb | Add with Carry | A = A + s + CY |
ADC A, N | 7 | 2 | CE XX | |||
ADC A, (HL) | 7 | 1 | 8E | |||
ADC A, (IX + N) | 19 | 3 | DD 8E XX | |||
ADC A, (IY + N) | 19 | 3 | FD 8E XX | |||
ADC HL, BC | 15 | 2 | **? V0 * | ED 4A | Add with Carry | HL = HL + ss + CY |
ADC HL, DE | 15 | 2 | ED 5A | |||
ADC HL, HL | 15 | 2 | ED 6A | |||
ADC HL, SP | 15 | 2 | ED 7A | |||
ADD A, r | 4 | 1 | *** V0 * | 80 + rb | Add (8-bit) | A = A + s |
ADD A, N | 7 | 2 | C6 XX | |||
ADD A, (HL) | 7 | 1 | 86 | |||
ADD A, (IX + N) | 19 | 3 | DD 86 XX | |||
ADD A, (IY + N) | 19 | 3 | FD 86 XX | |||
ADD HL, BC | 11 | 1 | --?- 0 * | 09 | Add (16-bit) | HL = HL + ss |
ADD HL, DE | 11 | 1 | 19 | |||
ADD HL, HL | 11 | 1 | 29 | |||
ADD HL, SP | 11 | 1 | 39 | |||
ADD IX, BC | 15 | 2 | --?- 0 * | DD 09 | Add (IX register) | IX = IX + pp |
ADD IX, DE | 15 | 2 | DD 19 | |||
ADD IX, IX | 15 | 2 | DD 29 | |||
ADD IX, SP | 15 | 2 | DD 39 | |||
ADD IY, BC | 15 | 2 | --?- 0 * | FD 09 | Add (IY register) | IY = IY + rr |
ADD IY, DE | 15 | 2 | FD 19 | |||
ADD IY, IY | 15 | 2 | FD 29 | |||
ADD IY, SP | 15 | 2 | FD 39 | |||
AND r | 4 | 1 | ***P00 | A0+rb | Logical AND | A=A&s |
AND N | 7 | 2 | E6 XX | |||
AND (HL) | 7 | 1 | A6 | |||
AND (IX+N) | 19 | 3 | DD A6 XX | |||
AND (IY+N) | 19 | 3 | FD A6 XX | |||
BIT b,r | 8 | 2 | ?*1?0- | CB 40+8*b+rb | Test Bit | m&{2^b} |
BIT b,(HL) | 12 | 2 | CB 46+8*b | |||
BIT b,(IX+N) | 20 | 4 | DD CB XX 46+8*b | |||
BIT b,(IY+N) | 20 | 4 | FD CB XX 46+8*b | |||
CALL NN | 17 | 3 | ------ | CD XX XX | Unconditional Call | -(SP)=PC,PC=nn |
CALL C,NN | 17/1 | 3 | ------ | DC XX XX | Conditional Call | If Carry = 1 |
CALL NC,NN | 17/1 | 3 | D4 XX XX | If carry = 0 | ||
CALL M,NN | 17/1 | 3 | FC XX XX | If Sign = 1 (negative) | ||
CALL P,NN | 17/1 | 3 | F4 XX XX | If Sign = 0 (positive) | ||
CALL Z,NN | 17/1 | 3 | CC XX XX | If Zero = 1 (ans.=0) | ||
CALL NZ,NN | 17/1 | 3 | C4 XX XX | If Zero = 0 (non-zero) | ||
CALL PE,NN | 17/1 | 3 | EC XX XX | If Parity = 1 (even) | ||
CALL PO,NN | 17/1 | 3 | E4 XX XX | If Parity = 0 (odd) | ||
CCF | 4 | 1 | --?-0* | 3F | Complement Carry Flag | CY=~CY |
CP r | 4 | 1 | ***V1* | B8+rb | Compare | Compare A-s |
CP N | 7 | 2 | FE XX | |||
CP (HL) | 7 | 1 | BE | |||
CP (IX+N) | 19 | 3 | DD BE XX | |||
CP (IY+N) | 19 | 3 | FD BE XX | |||
CPD | 16 | 2 | ****1- | ED A9 | Compare and Decrement | A-(HL),HL=HL-1,BC=BC-1 |
CPDR | 21/1 | 2 | ****1- | ED B9 | Compare, Dec., Repeat | CPD till A=(HL)or BC=0 |
CPI | 16 | 2 | ****1- | ED A1 | Compare and Increment | A-(HL),HL=HL+1,BC=BC-1 |
CPIR | 21/1 | 2 | ****1- | ED B1 | Compare, Inc., Repeat | CPI till A=(HL)or BC=0 |
CPL | 4 | 1 | --1-1- | 2F | Complement | A=~A |
DAA | 4 | 1 | ***P-* | 27 | Decimal Adjust Acc. | A=BCD format (dec.) |
DEC A | 4 | 1 | ***V1- | 3D | Decrement (8-bit) | s=s-1 |
DEC B | 4 | 1 | 05 | |||
DEC C | 4 | 1 | 0D | |||
DEC D | 4 | 1 | 15 | |||
DEC E | 4 | 1 | 1D | |||
DEC H | 4 | 1 | 25 | |||
DEC L | 4 | 2 | 2D | |||
DEC (HL) | 11 | 1 | 35 | (HL)=(HL)-1 | ||
DEC (IX+N) | 23 | 3 | DD 35 XX | (xx-d)=(xx-d)+1 | ||
DEC (IY+N) | 23 | 3 | FD 35 XX | |||
DEC BC | 6 | 1 | ------ | 0B | Decrement (16-bit) | ss=ss-1 |
DEC DE | 6 | 1 | 1B | |||
DEC HL | 6 | 1 | 2B | |||
DEC SP | 6 | 1 | 3B | |||
DEC IX | 10 | 2 | ------ | DD 2B | Decrement | xx=xx-1 |
DEC IY | 10 | 2 | FD 2B | |||
DI | 4 | 1 | ------ | F3 | Disable Interrupts | |
DJNZ $+2 | 13/8 | 1 | ------ | 10 | Dec., Jump Non-Zero | B=B-1 till B=0 |
EI | 4 | 1 | ------ | FB | Enable Interrupts | |
EX (SP),HL | 19 | 1 | ------ | E3 | Exchange | (SP)<->HL |
EX (SP),IX | 23 | 2 | DD E3 | (SP)<->xx | ||
EX (SP),IY | 23 | 2 | FD E3 | |||
EX AF,AF' | 4 | 1 | 08 | AF<->AF' | ||
EX DE,HL | 4 | 1 | EB | DE<->HL | ||
EXX | 4 | 1 | ------ | D9 | Exchange | qq<->qq' (except AF) |
HALT | 4 | 1 | ------ | 76 | Halt | |
IM 0 | 8 | 2 | ------ | ED 46 | Interrupt Mode | (n=0,1,2) |
IM 1 | 8 | 2 | ED 56 | |||
IM 2 | 8 | 2 | ED 5E | |||
IN A,(N) | 11 | 2 | ------ | DB XX | Input | A=(n) |
IN (C) | 12 | 2 | ***P0- | ED 70 | Input* | (Unsupported) |
IN A,(C) | 12 | 2 | ***P0- | ED 78 | Input | r=(C) |
IN B,(C) | 12 | 2 | ED 40 | |||
IN C,(C) | 12 | 2 | ED 48 | |||
IN D,(C) | 12 | 2 | ED 50 | |||
IN E,(C) | 12 | 2 | ED 58 | |||
IN H,(C) | 12 | 2 | ED 60 | |||
IN L,(C) | 12 | 2 | ED 68 | |||
INC A | 4 | 1 | ***V0- | 3C | Increment (8-bit) | r=r+1 |
INC B | 4 | 1 | 04 | |||
INC C | 4 | 1 | 0C | |||
INC D | 4 | 1 | 14 | |||
INC E | 4 | 1 | 1C | |||
INC H | 4 | 1 | 24 | |||
INC L | 4 | 1 | 2C | |||
INC (HL) | 11 | 1 | 34 | (HL)=(HL)+1 | ||
INC (IX+N) | 23 | 3 | DD 34 XX | (xx+d)=(xx+d)+1 | ||
INC (IY+N) | 23 | 3 | FD 34 XX | |||
INC BC | 6 | 1 | ------ | 03 | Increment (16-bit) | ss=ss+1 |
INC DE | 6 | 1 | 13 | |||
INC HL | 6 | 1 | 23 | |||
INC SP | 6 | 1 | 33 | |||
INC IX | 10 | 2 | ------ | DD 23 | Increment | xx=xx+1 |
INC IY | 10 | 2 | FD 23 | |||
IND | 16 | 2 | ?*??1- | ED AA | Input and Decrement | (HL)=(C),HL=HL-1,B=B-1 |
INDR | 21/1 | 2 | ?1??1- | ED BA | Input, Dec., Repeat | IND till B=0 |
INI | 16 | 2 | ?*??1- | ED A2 | Input and Increment | (HL)=(C),HL=HL+1,B=B-1 |
INIR | 21/1 | 2 | ?1??1- | ED B2 | Input, Inc., Repeat | INI till B=0 |
JP NN | 10 | 3 | ------ | C3 XX XX | Unconditional Jump | PC=nn |
JP (HL) | 4 | 1 | E9 | PC=(HL) | ||
JP (IX) | 8 | 2 | DD E9 | PC=(xx) | ||
JP (IY) | 8 | 2 | FD E9 | |||
JP C,$NN | 10/1 | 3 | ------ | DA XX XX | Conditional Jump | If Carry = 1 |
JP NC,$NN | 10/1 | 3 | D2 XX XX | If Carry = 0 | ||
JP M,$NN | 10/1 | 3 | FA XX XX | If Sign = 1 (negative) | ||
JP P,$NN | 10/1 | 3 | F2 XX XX | If Sign = 0 (positive) | ||
JP Z,$NN | 10/1 | 3 | CA XX XX | If Zero = 1 (ans.= 0) | ||
JP NZ,$NN | 10/1 | 3 | C2 XX XX | If Zero = 0 (non-zero) | ||
JP PE,$NN | 10/1 | 3 | EA XX XX | If Parity = 1 (even) | ||
JP PO,$NN | 10/1 | 3 | E2 XX XX | If Parity = 0 (odd) | ||
JR $N+2 | 12 | 2 | ------ | 18 XX | Relative Jump | PC=PC+e |
JR C,$N+2 | 12/7 | 2 | ------ | 38 XX | Cond. Relative Jump | If cc JR(cc=C,NC,NZ,Z) |
JR NC,$N+2 | 12/7 | 2 | 30 XX | |||
JR Z,$N+2 | 12/7 | 2 | 28 XX | |||
JR NZ,$N+2 | 12/7 | 2 | 20 XX | |||
LD I,A | 9 | 2 | ------ | ED 47 | Load* | dst=src |
LD R,A | 9 | 2 | ED 4F | |||
LD A,I | 9 | 2 | **0*0- | ED 57 | Load* | dst=src |
LD A,R | 9 | 2 | ED 5F | |||
LD A,r | 4 | 1 | ------ | 78+rb | Load (8-bit) | dst=src |
LD A,N | 7 | 2 | 3E XX | |||
LD A,(BC) | 7 | 1 | 0A | |||
LD A,(DE) | 7 | 1 | 1A | |||
LD A,(HL) | 7 | 1 | 7E | |||
LD A,(IX+N) | 19 | 3 | DD 7E XX | |||
LD A,(IY+N) | 19 | 3 | FD 7E XX | |||
LD A,(NN) | 13 | 3 | 3A XX XX | |||
LD B,r | 4 | 1 | 40+rb | |||
LD B,N | 7 | 2 | 06 XX | |||
LD B,(HL) | 7 | 1 | 46 | |||
LD B,(IX+N) | 19 | 3 | DD 46 XX | |||
LD B,(IY+N) | 19 | 3 | FD 46 XX | |||
LD C,r | 4 | 1 | 48+rb | |||
LD C,N | 7 | 2 | 0E XX | |||
LD C,(HL) | 7 | 1 | 4E | |||
LD C,(IX+N) | 19 | 3 | DD 4E XX | |||
LD C,(IY+N) | 19 | 3 | FD 4E XX | |||
LD D,r | 4 | 1 | 50+rb | |||
LD D,N | 7 | 2 | 16 XX | |||
LD D,(HL) | 7 | 1 | 56 | |||
LD D,(IX+N) | 19 | 3 | DD 56 XX | |||
LD D,(IY+N) | 19 | 3 | FD 56 XX | |||
LD E,r | 4 | 1 | 58+rb | |||
LD E,N | 7 | 2 | 1E XX | |||
LD E,(HL) | 7 | 1 | 5E | |||
LD E,(IX+N) | 19 | 3 | DD 5E XX | |||
LD E,(IY+N) | 19 | 3 | FD 5E XX | |||
LD H,r | 4 | 1 | 60+rb | |||
LD H,N | 7 | 2 | 26 XX | |||
LD H,(HL) | 7 | 1 | 66 | |||
LD H,(IX+N) | 19 | 3 | DD 66 XX | |||
LD H,(IY+N) | 19 | 3 | FD 66 XX | |||
LD L,r | 4 | 1 | 68+rb | |||
LD L,N | 7 | 2 | 2E XX | |||
LD L,(HL) | 7 | 1 | 6E | |||
LD L,(IX+N) | 19 | 3 | DD 6E XX | |||
LD L,(IY+N) | 19 | 3 | FD 6E XX | |||
LD BC,(NN) | 20 | 4 | ------ | ED 4B XX XX | Load (16-bit) | dst=src |
LD BC,NN | 10 | 3 | 01 XX XX | |||
LD DE,(NN) | 20 | 4 | ED 5B XX XX | |||
LD DE,NN | 10 | 3 | 11 XX XX | |||
LD HL,(NN) | 20 | 3 | 2A XX XX | |||
LD HL,NN | 10 | 3 | 21 XX XX | |||
LD SP,(NN) | 20 | 4 | ED 7B XX XX | |||
LD SP,HL | 6 | 1 | F9 | |||
LD SP,IX | 10 | 2 | DD F9 | |||
LD SP,IY | 10 | 2 | FD F9 | |||
LD SP,NN | 10 | 3 | 31 XX XX | |||
LD IX,(NN) | 20 | 4 | DD 2A XX XX | |||
LD IX,NN | 14 | 4 | DD 21 XX XX | |||
LD IY,(NN) | 20 | 4 | FD 2A XX XX | |||
LD IY,NN | 14 | 4 | FD 21 XX XX | |||
LD (HL),r | 7 | 1 | ------ | 70+rb | Load (Indirect) | dst=src |
LD (HL),N | 10 | 2 | 36 XX | |||
LD (BC),A | 7 | 1 | 02 | |||
LD (DE),A | 7 | 1 | 12 | |||
LD (NN),A | 13 | 3 | 32 XX XX | |||
LD (NN),BC | 20 | 4 | ED 43 XX XX | |||
LD (NN),DE | 20 | 4 | ED 53 XX XX | |||
LD (NN),HL | 16 | 3 | 22 XX XX | |||
LD (NN),IX | 20 | 4 | DD 22 XX XX | |||
LD (NN),IY | 20 | 4 | FD 22 XX XX | |||
LD (NN),SP | 20 | 4 | ED 73 XX XX | |||
LD (IX+N),r | 19 | 3 | DD 70+rb XX | |||
LD (IX+N),N | 19 | 4 | DD 36 XX XX | |||
LD (IY+N),r | 19 | 3 | FD 70+rb XX | |||
LD (IY+N),N | 19 | 4 | FD 36 XX XX | |||
LDD | 16 | 2 | --0*0- | ED A8 | Load and Decrement | (DE)=(HL),HL=HL-1,# |
LDDR | 21/1 | 2 | --000- | ED B8 | Load, Dec., Repeat | LDD till BC=0 |
LDI | 16 | 2 | --0*0- | ED A0 | Load and Increment | (DE)=(HL),HL=HL+1,# |
LDIR | 21/1 | 2 | --000- | ED B0 | Load, Inc., Repeat | LDI till BC=0 |
NEG | 8 | 2 | ***V1* | ED 44 | Negate | A=-A |
NOP | 4 | 1 | ------ | 00 | No Operation | |
OR r | 4 | 1 | ***P00 | B0+rb | Logical inclusive OR | A=Avs |
OR N | 7 | 2 | F6 XX | |||
OR (HL) | 7 | 1 | B6 | |||
OR (IX+N) | 19 | 3 | DD B6 XX | |||
OR (IY+N) | 19 | 3 | FD B6 XX | |||
OUT (N),A | 11 | 2 | ------ | D3 XX | Output | (n)=A |
OUT (C),0 | 12 | 2 | ED 71 | Output* | (Unsupported) | |
OUT (C),A | 12 | 2 | ED 79 | Output | (C)=r | |
OUT (C),B | 12 | 2 | ED 41 | |||
OUT (C),C | 12 | 2 | ED 49 | |||
OUT (C),D | 12 | 2 | ED 51 | |||
OUT (C),E | 12 | 2 | ED 59 | |||
OUT (C),H | 12 | 2 | ED 61 | |||
OUT (C),L | 12 | 2 | ED 69 | |||
OUTD | 16 | 2 | ?*??1- | ED AB | Output and Decrement | (C)=(HL),HL=HL-1,B=B-1 |
OTDR | 21/1 | 2 | ?1??1- | ED BB | Output, Dec., Repeat | OUTD till B=0 |
OUTI | 16 | 2 | ?*??1- | ED A3 | Output and Increment | (C)=(HL),HL=HL+1,B=B-1 |
OTIR | 21/1 | 2 | ?1??1- | ED B3 | Output, Inc., Repeat | OUTI till B=0 |
POP AF | 10 | 1 | ------ | F1 | Pop | qq=(SP)+ |
POP BC | 10 | 1 | C1 | |||
POP DE | 10 | 1 | D1 | |||
POP HL | 10 | 1 | E1 | |||
POP IX | 14 | 2 | ------ | DD E1 | Pop | xx=(SP)+ |
POP IY | 14 | 2 | FD E1 | |||
PUSH AF | 11 | 1 | ------ | F5 | Push | (SP)=qq |
PUSH BC | 11 | 1 | C5 | |||
PUSH DE | 11 | 1 | D5 | |||
PUSH HL | 11 | 1 | E5 | |||
PUSH IX | 15 | 2 | ------ | DD E5 | Push | -(SP)=xx |
PUSH IY | 15 | 2 | ||||
RES b,r | 8 | 2 | ------ | CB 80+8*b+rb | Reset bit | m=m&{~2^b} |
RES b,(HL) | 15 | 2 | CB 86+8*b | |||
RES b,(IX+N) | 23 | 4 | DD CB XX 86+8*b | |||
RES b,(IY+N) | 23 | 4 | FD CB XX 86+8*b | |||
RET | 10 | 1 | ------ | C9 | Return | PC=(SP)+ |
RET C | 11/5 | 1 | D8 | Conditional Return | If Carry = 1 | |
RET NC | 11/5 | 1 | D0 | If Carry = 0 | ||
RET M | 11/5 | 1 | F8 | If Sign = 1 (negative) | ||
RET P | 11/5 | 1 | F0 | If Sign = 0 (positive) | ||
RET Z | 11/5 | 1 | C8 | If Zero = 1 (ans.=0) | ||
RET NZ | 11/5 | 1 | C0 | If Zero = 0 (non-zero) | ||
RET PE | 11/5 | 1 | E8 | If Parity = 1 (even) | ||
RET PO | 11/5 | 1 | E0 | If Parity = 0 (odd) | ||
RET | 10 | 1 | ------ | C9 | Return | PC=(SP)+ |
RET C | 11/5 | 1 | ------ | D8 | Conditional Return | If Carry = 1 |
RET NC | 11/5 | 1 | D0 | If Carry = 0 | ||
RET M | 11/5 | 1 | F8 | If Sign = 1 (negative) | ||
RET P | 11/5 | 1 | F0 | If Sign = 0 (positive) | ||
RET Z | 11/5 | 1 | C8 | If Zero = 1 (ans.=0) | ||
RET NZ | 11/5 | 1 | C0 | If Zero = 0 (non-zero) | ||
RET PE | 11/5 | 1 | E8 | If Parity = 1 (even) | ||
RET PO | 11/5 | 1 | E0 | If Parity = 0 (odd) | ||
RETI | 14 | 2 | ------ | ED 4D | Return from Interrupt | PC=(SP)+ |
RETN | 14 | 2 | ------ | ED 45 | Return from NMI | PC=(SP)+ |
RLA | 4 | 1 | --0-0* | 17 | Rotate Left Acc. | A={CY,A}<- |
RL r | 8 | 2 | **0P0* | CB 10+rb | Rotate Left | m={CY,m}<- |
RL (HL) | 15 | 2 | CB 16 | |||
RL (IX+N) | 23 | 4 | DD CB XX 16 | |||
RL (IY+N) | 23 | 4 | FD CB XX 16 | |||
RLCA | 4 | 1 | --0-0* | 07 | Rotate Left Cir. Acc. | A=A<- |
RLC r | 8 | 2 | **0P0* | CB 00+rb | Rotate Left Circular | m=m<- |
RLC (HL) | 15 | 2 | CB 06 | |||
RLC (IX+N) | 23 | 4 | DD CB XX 06 | |||
RLC (IY+N) | 23 | 4 | FD CB XX 06 | |||
RLD | 18 | 2 | **0P0- | ED 6F | Rotate Left 4 bits | {A,(HL)}={A,(HL)}<- ## |
RRA | 4 | 1 | --0-0* | 1F | Rotate Right Acc. | A=->{CY,A} |
RR r | 8 | 2 | **0P0* | CB 18+rb | Rotate Right | m=->{CY,m} |
RR (HL) | 15 | 2 | CB 1E | |||
RR (IX+N) | 23 | 4 | DD CB XX 1E | |||
RR (IY+N) | 23 | 4 | FD CB XX 1E | |||
RRCA | 4 | 1 | --0-0* | 0F | Rotate Right Cir.Acc. | A=->A |
RRC r | 8 | 2 | **0P0* | CB 08+rb | Rotate Right Circular | m=->m |
RRC (HL) | 15 | 2 | CB 0E | |||
RRC (IX+N) | 23 | 4 | DD CB XX 0E | |||
RRC (IY+N) | 23 | 4 | FD CB XX 0E | |||
RRD | 18 | 2 | **0P0- | ED 67 | Rotate Right 4 bits | {A,(HL)}=->{A,(HL)} ## |
RST 0 | 11 | 1 | ------ | C7 | Restart | (p=0H,8H,10H,...,38H) |
RST 08H | 11 | 1 | CF | |||
RST 10H | 11 | 1 | D7 | |||
RST 18H | 11 | 1 | DF | |||
RST 20H | 11 | 1 | E7 | |||
RST 28H | 11 | 1 | EF | |||
RST 30H | 11 | 1 | F7 | |||
RST 38H | 11 | 1 | FF | |||
SBC r | 4 | 1 | ***V1* | 98+rb | Subtract with Carry | A=A-s-CY |
SBC A,N | 7 | 2 | DE XX | |||
SBC (HL) | 7 | 1 | 9E | |||
SBC A,(IX+N) | 19 | 3 | DD 9E XX | |||
SBC A,(IY+N) | 19 | 3 | FD 9E XX | |||
SBC HL,BC | 15 | 2 | **?V1* | ED 42 | Subtract with Carry | HL=HL-ss-CY |
SBC HL,DE | 15 | 2 | ED 52 | |||
SBC HL,HL | 15 | 2 | ED 62 | |||
SBC HL,SP | 15 | 2 | ED 72 | |||
SCF | 4 | 1 | --0-01 | 37 | Set Carry Flag | CY=1 |
SET b,r | 8 | 2 | ------ | CB C0+8*b+rb | Set bit | m=mv{2^b} |
SET b,(HL) | 15 | 2 | CB C6+8*b | |||
SET b,(IX+N) | 23 | 4 | DD CB XX C6+8*b | |||
SET b,(IY+N) | 23 | 4 | FD CB XX C6+8*b | |||
SLA r | 8 | 2 | **0P0* | CB 20+rb | Shift Left Arithmetic | m=m*2 |
SLA (HL) | 15 | 2 | CB 26 | |||
SLA (IX+N) | 23 | 4 | DD CB XX 26 | |||
SLA (IY+N) | 23 | 4 | FD CB XX 26 | |||
SRA r | 8 | 2 | **0P0* | CB 28+rb | Shift Right Arith. | m=m/2 |
SRA (HL) | 15 | 2 | CB 2E | |||
SRA (IX+N) | 23 | 4 | DD CB XX 2E | |||
SRA (IY+N) | 23 | 4 | FD CB XX 2E | |||
SLL r | 8 | 2 | **0P0* | CB 30+rb | Shift Left Logical* | m={0,m,CY}<-
(SLL Instructions are unsupported) |
SLL (HL) | 15 | 2 | CB 36 | |||
SLL (IX+N) | 23 | 4 | DD CB XX 36 | |||
SLL (IY+N) | 23 | 4 | FD CB XX 36 | |||
SRL r | 8 | 2 | **0P0* | CB 38+rb | Shift Right Logical | m=->{0,m,CY} |
SRL (HL) | 15 | 2 | CB 3E | |||
SRL (IX+N) | 23 | 4 | DD CB XX 3E | |||
SRL (IY+N) | 23 | 4 | FD CB XX 3E | |||
SUB r | 4 | 1 | ***V1* | 90+rb | Subtract | A=A-s |
SUB N | 7 | 2 | D6 XX | |||
SUB (HL) | 7 | 1 | 96 | |||
SUB (IX+N) | 19 | 3 | DD 96 XX | |||
SUB (IY+N) | 19 | 3 | FD 96 XX | |||
XOR r | 4 | 1 | ***P00 | A8+rb | Logical Exclusive OR | A=Axs |
XOR N | 7 | 2 | EE XX | |||
XOR (HL) | 7 | 1 | AE | |||
XOR (IX+N) | 19 | 3 | DD AE XX | |||
XOR (IY+N) | 19 | 3 | FD AE XX |
CPC Timings
Instruction | µs | Size | I/O |
---|---|---|---|
ADC/ADD/SBC/SUB A, (HL) | 2 | 1 | |
ADC/ADD/SBC/SUB A, (IX/IY+d) | 5 | 3 | |
ADC/ADD/SBC/SUB A, A/B/C/D/E/H/L | 1 | 1 | |
ADC/ADD/SBC/SUB A, HX/LX/HY/LY | 2 | 2 | |
ADC/ADD/SBC/SUB A, d | 2 | 2 | |
ADD/SUB HL, BC/DE/HL/SP | 3 | 1 | |
ADD/SUB IX/IY, BC/DE/HL/SP | 4 | 2 | |
AND/OR/XOR A, (HL) | 2 | 1 | |
AND/OR/XOR A, (IX/IY+d) | 5 | 3 | |
AND/OR/XOR A, A/B/C/D/E/H/L | 1 | 1 | |
AND/OR/XOR A, HX/LX/HY/LY | 2 | 2 | |
AND/OR/XOR A, d | 2 | 2 | |
BIT x, (HL) | 3 | 2 | |
BIT x, (IX/IY+d) | 6 | 4 | |
BIT x, A/B/C/D/E/H/L | 2 | 2 | |
CALL cond, aa | 5/3 | 3 | |
CALL aa | 5 | 3 | |
CCF/SCF | 1 | 1 | |
CP A, (HL) | 2 | 1 | |
CP A, (IX/IY+d) | 5 | 3 | |
CP A, A/B/C/D/E/H/L | 1 | 1 | |
CP A, HX/LX/HY/LY | 2 | 2 | |
CP A, d | 2 | 2 | |
CPD/CPI | 4 | 2 | |
CPDR/CPIR | 6/4 | 2 | |
CPL | 1 | 1 | |
DAA | 1 | 1 | |
DEC/INC (HL) | 3 | 1 | |
DEC/INC (IX/IY+d) | 6 | 3 | |
DEC/INC A/B/C/D/E/H/L | 1 | 1 | |
DEC/INC HX/LX/HY/LY | 2 | 2 | |
DEC/INC BC/DE/HL/SP | 2 | 1 | |
DEC/INC IX/IY | 3 | 2 | |
DI/EI | 1 | 1 | |
DJNZ | 4/3 | 2 | |
EX (SP), HL | 6 | 1 | |
EX (SP), IX/IY | 7 | 2 | |
EX AF, AF’ | 1 | 1 | |
EX DE, HL | 1 | 1 | |
EXX | 1 | 1 | |
HALT | 1 | 1 | |
IM m | 2 | 2 | |
IN A/B/C/D/E/H/L, (C) | 4 | 2 | 4 |
IN A, (d) | 3 | 2 | 3 |
IN F | 4 | 2 | 4 |
IND/INI | 5 | 2 | 4 |
INDR/INIR | 6/5 | 2 | 4 |
JP aa | 3 | 3 | |
JP cond, aa | 3 | 3 | |
JP (HL) | 1 | 1 | |
JP (IX/IY) | 2 | 2 | |
JR a | 3 | 2 | |
JR cond, a | 3/2 | 2 | |
LD (BC/DE), A | 2 | 1 | |
LD (HL), A/B/C/D/E/H/L | 2 | 1 | |
LD (HL),d | 3 | 2 | |
LD (IX/IY+d), A/B/C/D/E/H/L | 5 | 3 | |
LD (IX/IY+d), d’ | 6 | 4 | |
LD (aa), A | 4 | 3 | |
LD (aa), BC/DE/SP/IX/IY | 6 | 4 | |
LD (aa), HL | 5 | 3 | |
LD A, (BC/DE) | 2 | 1 | |
LD A/B/C/D/E/H/L, (HL) | 2 | 1 | |
LD A/B/C/D/E/H/L, (IX/IY+d) | 5 | 3 | |
LD A,(aa) | 4 | 3 | |
LD A/B/C/D/E/H/L, A/B/C/D/E/H/L | 1 | 1 | |
LD A/B/C/D/E/H/L, d | 2 | 2 | |
LD HX/LX, A/B/C/D/E/HX/LX | 2 | 3 | |
LD HY/LY, A/B/C/D/E/HY/LY | 2 | 3 | |
LD BC/DE/HL/SP, dd | 3 | 3 | |
LD IX/IY, dd | 4 | 4 | |
LD SP, IX/IY | 3 | 2 | |
LD SP, HL | 2 | 1 | |
LD HX/LX/HY/LY, d | 3 | 3 | |
LD BC/DE/HL/SP/IX/IY, (aa) | 6 | 4 | |
LD HL, (aa) | 5 | 3 | |
LD A, I/R | 3 | 2 | |
LD I/R, A | 3 | 2 | |
LDD/LDI | 5 | 2 | |
LDDR/LDIR | 6/5 | 2 | |
NEG | 2 | 2 | |
NOP | 1 | 1 | |
OUT (C), A/B/C/D/E/H/L | 4 | 2 | 3* |
OUT (C), 0 | 4 | 2 | 3* |
OUT (d), A | 3 | 2 | 3 |
OUTD/OUTI | 5 | 2 | 5 |
OTDR/OTIR | 6/5 | 2 | 5 |
POP AF/BC/DE/HL | 3 | 1 | |
POP IX/IY | 4 | 2 | |
PUSH AF/BC/DE/HL | 4 | 1 | |
PUSH IX/IY | 5 | 2 | |
RES/SET x, (HL) | 4 | 2 | |
RES/SET x, (IX/IY+d) | 7 | 4 | |
RES/SET x, (IX/IY+d), A/B/C/D/E/H/L | 7 | 4 | |
RES/SET x, A/B/C/D/E/H/L | 2 | 2 | |
RET | 3 | 1 | |
RET cond | 4/2 | 1 | |
RETI/RETN | 4 | 2 | |
RL/RLC/RR/RRC/SLA/SLL/SRA/SRL (HL) | 4 | 2 | |
RL/RLC/RR/RRC/SLA/SLL/SRA/SRL (IX/IY+d) | 7 | 4 | |
RL/RLC/RR/RRC/SLA/SLL/SRA/SRL (IX/IY+d), A/B/C/D/E/H/L | 7 | 4 | |
RL/RLC/RR/RRC/SLA/SLL/SRA/SRL A/B/C/D/E/H/L | 2 | 2 | |
RLA/RLCA/RRA/RRCA | 1 | 1 | |
RLD/RRD | 5 | 2 | |
RST 0/08h/10h/18h/20h/28h/30h/38h | 4 | 1 |
Notes:
- x=[0..7], d=[0..ff], m=[0..2], aa=[0..ffff], a=[0..ff]
- * Some exceptions exist
- All instructions containing (IX/IY+d) add 3µs and 2 bytes compared to their (HL) variants
- Contrarily to what the syntax of the instructions JP (HL/IX/IY) suggest, PC will be loaded with the contents of the register itself, not the indexed value. Those instructions should be understood as JP HL/IX/IY
- Despite having different names and opcodes, RETI and RETN are in fact the exact same instruction