kolibrios-gitea/programs/emulator/dgen-sdl-1.33/cz80/cz80.inc

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/********************************************************************************/
/* */
/* CZ80 macro file */
/* C Z80 emulator version 0.91 */
/* Copyright 2004-2005 Stephane Dallongeville */
/* */
/********************************************************************************/
#if CZ80_USE_JUMPTABLE
#define _SSOP(A,B) A##B
#define OP(A) _SSOP(OP,A)
#define OPCB(A) _SSOP(OPCB,A)
#define OPED(A) _SSOP(OPED,A)
#define OPXY(A) _SSOP(OPXY,A)
#define OPXYCB(A) _SSOP(OPXYCB,A)
#else
#define OP(A) case A
#define OPCB(A) case A
#define OPED(A) case A
#define OPXY(A) case A
#define OPXYCB(A) case A
#endif
#define GET_BYTE \
(((uint8_t *)CPU->BasePC)[PC])
#define GET_BYTE_S \
(((int8_t *)CPU->BasePC)[PC])
#define GET_WORD \
(((uint8_t *)CPU->BasePC)[PC] | \
(((uint8_t *)CPU->BasePC)[((PC + 1) & 0xffff)] << 8))
#define FETCH_BYTE \
(((uint8_t *)CPU->BasePC)[PC++])
#define FETCH_BYTE_S \
(((int8_t *)CPU->BasePC)[PC++])
#define FETCH_WORD(A) \
A = GET_WORD; \
PC += 2;
#if CZ80_SIZE_OPT
#define RET(A) \
CCnt -= A; \
goto Cz80_Exec_Check;
#else
#define RET(A) \
if ((CCnt -= A) <= 0) goto Cz80_Exec_End; \
goto Cz80_Exec;
#endif
#define SET_PC(A) \
CPU->BasePC = (uintptr_t) CPU->Fetch[(A) >> CZ80_FETCH_SFT]; \
PC = ((A) & 0xffff);
#define PRE_IO \
CPU->CycleIO = CCnt;
#define POST_IO \
CCnt = CPU->CycleIO;
#define READ_BYTE(A, D) \
D = CPU->Read_Byte(CPU->ctx, (A));
#if CZ80_USE_WORD_HANDLER
#define READ_WORD(A, D) \
D = CPU->Read_Word(CPU->ctx, (A));
#define READ_WORD_LE(A, D) READ_WORD(A, D)
#elif CZ80_LITTLE_ENDIAN
#define READ_WORD(A, D) \
D = CPU->Read_Byte(CPU->ctx, (A)) | (CPU->Read_Byte(CPU->ctx, ((A) + 1)) << 8);
#define READ_WORD_LE(A, D) READ_WORD(A, D)
#else
#define READ_WORD(A, D) \
D = (CPU->Read_Byte(CPU->ctx, (A)) << 8) | CPU->Read_Byte(CPU->ctx, ((A) + 1));
#define READ_WORD_LE(A, D) \
D = CPU->Read_Byte(CPU->ctx, (A)) | (CPU->Read_Byte(CPU->ctx, ((A) + 1)) << 8);
#endif
#define READSX_BYTE(A, D) \
D = CPU->Read_Byte(CPU->ctx, (A));
#define WRITE_BYTE(A, D) \
CPU->Write_Byte(CPU->ctx, (A), (D));
#if CZ80_USE_WORD_HANDLER
#define WRITE_WORD(A, D) \
CPU->Write_Word(CPU->ctx, (A), (D));
#define WRITE_WORD_LE(A, D) WRITE_WORD(A, D);
#elif CZ80_LITTLE_ENDIAN
#define WRITE_WORD(A, D) \
CPU->Write_Byte(CPU->ctx, (A), (D)); \
CPU->Write_Byte(CPU->ctx, ((A) + 1), ((D) >> 8));
#define WRITE_WORD_LE(A, D) WRITE_WORD(A, D);
#else
#define WRITE_WORD(A, D) \
CPU->Write_Byte(CPU->ctx, (A), ((D) >> 8)); \
CPU->Write_Byte(CPU->ctx, ((A) + 1), (D));
#define WRITE_WORD_LE(A, D) \
CPU->Write_Byte(CPU->ctx, (A), (D)); \
CPU->Write_Byte(CPU->ctx, ((A) + 1), ((D) >> 8));
#endif
#define PUSH_16(A) \
{ \
uint16_t sp; \
\
zSP -= 2; \
sp = zSP; \
WRITE_WORD_LE(sp, A); \
}
#define POP_16(A) \
{ \
uint16_t sp; \
\
sp = zSP; \
READ_WORD_LE(sp, A);\
zSP = sp + 2; \
}
#define IN(A, D) \
D = CPU->IN_Port(CPU->ctx, (A));
#define OUT(A, D) \
CPU->OUT_Port(CPU->ctx, (A), (D));
#define CHECK_INT \
if (CPU->Status & (zIFF1 | CZ80_HAS_NMI)) \
{ \
uint16_t newPC; \
\
if (CPU->Status & CZ80_HAS_NMI) \
{ \
/* NMI */ \
CPU->Status &= ~(CZ80_HALTED | CZ80_HAS_NMI); \
zIFF1 = 0; \
newPC = 0x66; \
} \
else \
{ \
/* MI */ \
CPU->Status &= ~(CZ80_HALTED | CZ80_HAS_INT); \
zIFF= 0; \
\
if (zIM == 1) newPC = 0x38; \
else \
{ \
uint16_t adr; \
\
Opcode = CPU->Interrupt_Ack(CPU->ctx, CPU->IntVect) & 0xFF; \
if (zIM == 0) goto Cz80_Exec_IM0; \
\
adr = Opcode | (zI << 8); \
READ_WORD(adr, newPC) \
CCnt -= 8; \
} \
} \
\
{ \
uint16_t src = PC; \
\
PUSH_16(src) \
SET_PC(newPC) \
CCnt -= 11; \
} \
}