/* * Sony CXD8530AQ/CXD8530BQ/CXD8530CQ/CXD8661R * * PSX CPU emulator for the MAME project written by smf * Thanks to Farfetch'd for information on the delay slot bug * * The PSX CPU is a custom r3000a with a built in * geometry transform engine, no mmu & no data cache. * * There is a stall circuit for load delays, but * it doesn't work if the load occurs in a branch * delay slot. * */ #include "ui.h" #include "debugger.h" #include "psx.h" #include "osd_cpu.h" #define LOG_BIOSCALL ( 0 ) #define EXC_INT ( 0 ) #define EXC_ADEL ( 4 ) #define EXC_ADES ( 5 ) #define EXC_SYS ( 8 ) #define EXC_BP ( 9 ) #define EXC_RI ( 10 ) #define EXC_CPU ( 11 ) #define EXC_OVF ( 12 ) #define CP0_RANDOM ( 1 ) #define CP0_BADVADDR ( 8 ) #define CP0_SR ( 12 ) #define CP0_CAUSE ( 13 ) #define CP0_EPC ( 14 ) #define CP0_PRID ( 15 ) #define SR_IEC ( 1L << 0 ) #define SR_KUC ( 1L << 1 ) #define SR_ISC ( 1L << 16 ) #define SR_SWC ( 1L << 17 ) #define SR_TS ( 1L << 21 ) #define SR_BEV ( 1L << 22 ) #define SR_RE ( 1L << 25 ) #define SR_CU0 ( 1L << 28 ) #define SR_CU1 ( 1L << 29 ) #define SR_CU2 ( 1L << 30 ) #define SR_CU3 ( 1L << 31 ) #define CAUSE_EXC ( 31L << 2 ) #define CAUSE_IP ( 255L << 8 ) #define CAUSE_IP2 ( 1L << 10 ) #define CAUSE_IP3 ( 1L << 11 ) #define CAUSE_IP4 ( 1L << 12 ) #define CAUSE_IP5 ( 1L << 13 ) #define CAUSE_IP6 ( 1L << 14 ) #define CAUSE_IP7 ( 1L << 15 ) #define CAUSE_CE ( 3L << 28 ) #define CAUSE_CE0 ( 0L << 28 ) #define CAUSE_CE1 ( 1L << 28 ) #define CAUSE_CE2 ( 2L << 28 ) #define CAUSE_BD ( 1L << 31 ) static const char *delayn[] = { "pc", "at", "v0", "v1", "a0", "a1", "a2", "a3", "t0", "t1", "t2", "t3", "t4", "t5", "t6", "t7", "s0", "s1", "s2", "s3", "s4", "s5", "s6", "s7", "t8", "t9", "k0", "k1", "gp", "sp", "fp", "ra", "pc" }; #define REGPC ( 32 ) typedef struct { UINT32 op; UINT32 pc; UINT32 delayv; UINT32 delayr; UINT32 hi; UINT32 lo; UINT32 r[ 32 ]; UINT32 cp0r[ 32 ]; PAIR cp2cr[ 32 ]; PAIR cp2dr[ 32 ]; int (*irq_callback)(int irqline); } mips_cpu_context; static mips_cpu_context mipscpu; static int mips_ICount = 0; static UINT32 mips_mtc0_writemask[]= { 0xffffffff, /* INDEX */ 0x00000000, /* RANDOM */ 0xffffff00, /* ENTRYLO */ 0x00000000, 0xffe00000, /* CONTEXT */ 0x00000000, 0x00000000, 0x00000000, 0x00000000, /* BADVADDR */ 0x00000000, 0xffffffc0, /* ENTRYHI */ 0x00000000, 0xf27fff3f, /* SR */ 0x00000300, /* CAUSE */ 0x00000000, /* EPC */ 0x00000000, /* PRID */ 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000 }; #if 0 void GTELOG(const char *a,...) { va_list va; char s_text[ 1024 ]; va_start( va, a ); vsprintf( s_text, a, va ); va_end( va ); logerror( "%08x: GTE: %08x %s\n", mipscpu.pc, INS_COFUN( mipscpu.op ), s_text ); } #else INLINE void GTELOG(const char *a, ...) {} #endif static UINT32 getcp2dr( int n_reg ); static void setcp2dr( int n_reg, UINT32 n_value ); static UINT32 getcp2cr( int n_reg ); static void setcp2cr( int n_reg, UINT32 n_value ); static void docop2( int gteop ); static void mips_exception( int exception ); static void mips_stop( void ) { DEBUGGER_BREAK; CALL_MAME_DEBUG; } #if LOG_BIOSCALL static const struct { int address; int operation; const char *prototype; } bioscalls[] = { { 0xa0, 0x00, "int open(const char *name, int mode)" }, { 0xa0, 0x01, "int lseek(int fd, int offset, int whence)" }, { 0xa0, 0x02, "int read(int fd, void *buf, int nbytes)" }, { 0xa0, 0x03, "int write(int fd, void *buf, int nbytes)" }, { 0xa0, 0x04, "int close(int fd)" }, { 0xa0, 0x05, "int ioctl(int fd, int cmd, int arg)" }, { 0xa0, 0x06, "void exit(int code)" }, { 0xa0, 0x07, "sys_a0_07()" }, { 0xa0, 0x08, "char getc(int fd)" }, { 0xa0, 0x09, "void putc(char c, int fd)" }, { 0xa0, 0x0a, "todigit()" }, { 0xa0, 0x0b, "double atof(const char *s)" }, { 0xa0, 0x0c, "long strtoul(const char *s, char **ptr, int base)" }, { 0xa0, 0x0d, "unsigned long strtol(const char *s, char **ptr, int base)" }, { 0xa0, 0x0e, "int abs(int val)" }, { 0xa0, 0x0f, "long labs(long lval)" }, { 0xa0, 0x10, "long atoi(const char *s)" }, { 0xa0, 0x11, "int atol(const char *s)" }, { 0xa0, 0x12, "atob()" }, { 0xa0, 0x13, "int setjmp(jmp_buf *ctx)" }, { 0xa0, 0x14, "void longjmp(jmp_buf *ctx, int value)" }, { 0xa0, 0x15, "char *strcat(char *dst, const char *src)" }, { 0xa0, 0x16, "char *strncat(char *dst, const char *src, size_t n)" }, { 0xa0, 0x17, "int strcmp(const char *dst, const char *src)" }, { 0xa0, 0x18, "int strncmp(const char *dst, const char *src, size_t n)" }, { 0xa0, 0x19, "char *strcpy(char *dst, const char *src)" }, { 0xa0, 0x1a, "char *strncpy(char *dst, const char *src, size_t n)" }, { 0xa0, 0x1b, "size_t strlen(const char *s)" }, { 0xa0, 0x1c, "int index(const char *s, int c)" }, { 0xa0, 0x1d, "int rindex(const char *s, int c)" }, { 0xa0, 0x1e, "char *strchr(const char *s, int c)" }, { 0xa0, 0x1f, "char *strrchr(const char *s, int c)" }, { 0xa0, 0x20, "char *strpbrk(const char *dst, const char *src)" }, { 0xa0, 0x21, "size_t strspn(const char *s, const char *set)" }, { 0xa0, 0x22, "size_t strcspn(const char *s, const char *set)" }, { 0xa0, 0x23, "char *strtok(char *s, const char *set)" }, { 0xa0, 0x24, "char *strstr(const char *s, const char *set)" }, { 0xa0, 0x25, "int toupper(int c)" }, { 0xa0, 0x26, "int tolower(int c)" }, { 0xa0, 0x27, "void bcopy(const void *src, void *dst, size_t len)" }, { 0xa0, 0x28, "void bzero(void *ptr, size_t len)" }, { 0xa0, 0x29, "int bcmp(const void *ptr1, const void *ptr2, int len)" }, { 0xa0, 0x2a, "void *memcpy(void *dst, const void *src, size_t n)" }, { 0xa0, 0x2b, "void *memset(void *dst, char c, size_t n)" }, { 0xa0, 0x2c, "void *memmove(void *dst, const void *src, size_t n)" }, { 0xa0, 0x2d, "int memcmp(const void *dst, const void *src, size_t n)" }, { 0xa0, 0x2e, "void *memchr(const void *s, int c, size_t n)" }, { 0xa0, 0x2f, "int rand()" }, { 0xa0, 0x30, "void srand(unsigned int seed)" }, { 0xa0, 0x31, "void qsort(void *base, int nel, int width, int (*cmp)(void *, void *))" }, { 0xa0, 0x32, "double strtod(const char *s, char **endptr)" }, { 0xa0, 0x33, "void *malloc(int size)" }, { 0xa0, 0x34, "void free(void *buf)" }, { 0xa0, 0x35, "void *lsearch(void *key, void *base, int belp, int width, int (*cmp)(void *, void *))" }, { 0xa0, 0x36, "void *bsearch(void *key, void *base, int nel, int size, int (*cmp)(void *, void *))" }, { 0xa0, 0x37, "void *calloc(int size, int n)" }, { 0xa0, 0x38, "void *realloc(void *buf, int n)" }, { 0xa0, 0x39, "InitHeap(void *block, int size)" }, { 0xa0, 0x3a, "void _exit(int code)" }, { 0xa0, 0x3b, "char getchar(void)" }, { 0xa0, 0x3c, "void putchar(char c)" }, { 0xa0, 0x3d, "char *gets(char *s)" }, { 0xa0, 0x3e, "void puts(const char *s)" }, { 0xa0, 0x3f, "int printf(const char *fmt, ...)" }, { 0xa0, 0x40, "sys_a0_40()" }, { 0xa0, 0x41, "int LoadTest(const char *name, struct EXEC *header)" }, { 0xa0, 0x42, "int Load(const char *name, struct EXEC *header)" }, { 0xa0, 0x43, "int Exec(struct EXEC *header, int argc, char **argv)" }, { 0xa0, 0x44, "void FlushCache()" }, { 0xa0, 0x45, "void InstallInterruptHandler()" }, { 0xa0, 0x46, "GPU_dw(int x, int y, int w, int h, long *data)" }, { 0xa0, 0x47, "mem2vram(int x, int y, int w, int h, long *data)" }, { 0xa0, 0x48, "SendGPU(int status)" }, { 0xa0, 0x49, "GPU_cw(long cw)" }, { 0xa0, 0x4a, "GPU_cwb(long *pkt, int len)" }, { 0xa0, 0x4b, "SendPackets(void *ptr)" }, { 0xa0, 0x4c, "sys_a0_4c()" }, { 0xa0, 0x4d, "int GetGPUStatus()" }, { 0xa0, 0x4e, "GPU_sync()" }, { 0xa0, 0x4f, "sys_a0_4f()" }, { 0xa0, 0x50, "sys_a0_50()" }, { 0xa0, 0x51, "int LoadExec(const char *name, int, int)" }, { 0xa0, 0x52, "GetSysSp()" }, { 0xa0, 0x53, "sys_a0_53()" }, { 0xa0, 0x54, "_96_init()" }, { 0xa0, 0x55, "_bu_init()" }, { 0xa0, 0x56, "_96_remove()" }, { 0xa0, 0x57, "sys_a0_57()" }, { 0xa0, 0x58, "sys_a0_58()" }, { 0xa0, 0x59, "sys_a0_59()" }, { 0xa0, 0x5a, "sys_a0_5a()" }, { 0xa0, 0x5b, "dev_tty_init()" }, { 0xa0, 0x5c, "dev_tty_open()" }, { 0xa0, 0x5d, "dev_tty_5d()" }, { 0xa0, 0x5e, "dev_tty_ioctl()" }, { 0xa0, 0x5f, "dev_cd_open()" }, { 0xa0, 0x60, "dev_cd_read()" }, { 0xa0, 0x61, "dev_cd_close()" }, { 0xa0, 0x62, "dev_cd_firstfile()" }, { 0xa0, 0x63, "dev_cd_nextfile()" }, { 0xa0, 0x64, "dev_cd_chdir()" }, { 0xa0, 0x65, "dev_card_open()" }, { 0xa0, 0x66, "dev_card_read()" }, { 0xa0, 0x67, "dev_card_write()" }, { 0xa0, 0x68, "dev_card_close()" }, { 0xa0, 0x69, "dev_card_firstfile()" }, { 0xa0, 0x6a, "dev_card_nextfile()" }, { 0xa0, 0x6b, "dev_card_erase()" }, { 0xa0, 0x6c, "dev_card_undelete()" }, { 0xa0, 0x6d, "dev_card_format()" }, { 0xa0, 0x6e, "dev_card_rename()" }, { 0xa0, 0x6f, "dev_card_6f()" }, { 0xa0, 0x70, "_bu_init()" }, { 0xa0, 0x71, "_96_init()" }, { 0xa0, 0x72, "_96_remove()" }, { 0xa0, 0x73, "sys_a0_73()" }, { 0xa0, 0x74, "sys_a0_74()" }, { 0xa0, 0x75, "sys_a0_75()" }, { 0xa0, 0x76, "sys_a0_76()" }, { 0xa0, 0x77, "sys_a0_77()" }, { 0xa0, 0x78, "_96_CdSeekL()" }, { 0xa0, 0x79, "sys_a0_79()" }, { 0xa0, 0x7a, "sys_a0_7a()" }, { 0xa0, 0x7b, "sys_a0_7b()" }, { 0xa0, 0x7c, "_96_CdGetStatus()" }, { 0xa0, 0x7d, "sys_a0_7d()" }, { 0xa0, 0x7e, "_96_CdRead()" }, { 0xa0, 0x7f, "sys_a0_7f()" }, { 0xa0, 0x80, "sys_a0_80()" }, { 0xa0, 0x81, "sys_a0_81()" }, { 0xa0, 0x82, "sys_a0_82()" }, { 0xa0, 0x83, "sys_a0_83()" }, { 0xa0, 0x84, "sys_a0_84()" }, { 0xa0, 0x85, "_96_CdStop()" }, { 0xa0, 0x84, "sys_a0_84()" }, { 0xa0, 0x85, "sys_a0_85()" }, { 0xa0, 0x86, "sys_a0_86()" }, { 0xa0, 0x87, "sys_a0_87()" }, { 0xa0, 0x88, "sys_a0_88()" }, { 0xa0, 0x89, "sys_a0_89()" }, { 0xa0, 0x8a, "sys_a0_8a()" }, { 0xa0, 0x8b, "sys_a0_8b()" }, { 0xa0, 0x8c, "sys_a0_8c()" }, { 0xa0, 0x8d, "sys_a0_8d()" }, { 0xa0, 0x8e, "sys_a0_8e()" }, { 0xa0, 0x8f, "sys_a0_8f()" }, { 0xa0, 0x90, "sys_a0_90()" }, { 0xa0, 0x91, "sys_a0_91()" }, { 0xa0, 0x92, "sys_a0_92()" }, { 0xa0, 0x93, "sys_a0_93()" }, { 0xa0, 0x94, "sys_a0_94()" }, { 0xa0, 0x95, "sys_a0_95()" }, { 0xa0, 0x96, "AddCDROMDevice()" }, { 0xa0, 0x97, "AddMemCardDevice()" }, { 0xa0, 0x98, "DisableKernelIORedirection()" }, { 0xa0, 0x99, "EnableKernelIORedirection()" }, { 0xa0, 0x9a, "sys_a0_9a()" }, { 0xa0, 0x9b, "sys_a0_9b()" }, { 0xa0, 0x9c, "void SetConf(int Event, int TCB, int Stack)" }, { 0xa0, 0x9d, "void GetConf(int *Event, int *TCB, int *Stack)" }, { 0xa0, 0x9e, "sys_a0_9e()" }, { 0xa0, 0x9f, "void SetMem(int size)" }, { 0xa0, 0xa0, "_boot()" }, { 0xa0, 0xa1, "SystemError()" }, { 0xa0, 0xa2, "EnqueueCdIntr()" }, { 0xa0, 0xa3, "DequeueCdIntr()" }, { 0xa0, 0xa4, "sys_a0_a4()" }, { 0xa0, 0xa5, "ReadSector(int count, int sector, void *buffer)" }, { 0xa0, 0xa6, "get_cd_status()" }, { 0xa0, 0xa7, "bufs_cb_0()" }, { 0xa0, 0xa8, "bufs_cb_1()" }, { 0xa0, 0xa9, "bufs_cb_2()" }, { 0xa0, 0xaa, "bufs_cb_3()" }, { 0xa0, 0xab, "_card_info()" }, { 0xa0, 0xac, "_card_load()" }, { 0xa0, 0xad, "_card_auto()" }, { 0xa0, 0xae, "bufs_cb_4()" }, { 0xa0, 0xaf, "sys_a0_af()" }, { 0xa0, 0xb0, "sys_a0_b0()" }, { 0xa0, 0xb1, "sys_a0_b1()" }, { 0xa0, 0xb2, "do_a_long_jmp()" }, { 0xa0, 0xb3, "sys_a0_b3()" }, { 0xa0, 0xb4, "GetKernelInfo(int sub_function)" }, { 0xb0, 0x00, "SysMalloc()" }, { 0xb0, 0x01, "sys_b0_01()" }, { 0xb0, 0x02, "sys_b0_02()" }, { 0xb0, 0x03, "sys_b0_03()" }, { 0xb0, 0x04, "sys_b0_04()" }, { 0xb0, 0x05, "sys_b0_05()" }, { 0xb0, 0x06, "sys_b0_06()" }, { 0xb0, 0x07, "void DeliverEvent(u_long class, u_long event)" }, { 0xb0, 0x08, "long OpenEvent(u_long class, long spec, long mode, long (*func)())" }, { 0xb0, 0x09, "long CloseEvent(long event)" }, { 0xb0, 0x0a, "long WaitEvent(long event)" }, { 0xb0, 0x0b, "long TestEvent(long event)" }, { 0xb0, 0x0c, "long EnableEvent(long event)" }, { 0xb0, 0x0d, "long DisableEvent(long event)" }, { 0xb0, 0x0e, "OpenTh()" }, { 0xb0, 0x0f, "CloseTh()" }, { 0xb0, 0x10, "ChangeTh()" }, { 0xb0, 0x11, "sys_b0_11()" }, { 0xb0, 0x12, "int InitPAD(char *buf1, int len1, char *buf2, int len2)" }, { 0xb0, 0x13, "int StartPAD(void)" }, { 0xb0, 0x14, "int StopPAD(void)" }, { 0xb0, 0x15, "PAD_init(u_long nazo, u_long *pad_buf)" }, { 0xb0, 0x16, "u_long PAD_dr()" }, { 0xb0, 0x17, "void ReturnFromException(void)" }, { 0xb0, 0x18, "ResetEntryInt()" }, { 0xb0, 0x19, "HookEntryInt()" }, { 0xb0, 0x1a, "sys_b0_1a()" }, { 0xb0, 0x1b, "sys_b0_1b()" }, { 0xb0, 0x1c, "sys_b0_1c()" }, { 0xb0, 0x1d, "sys_b0_1d()" }, { 0xb0, 0x1e, "sys_b0_1e()" }, { 0xb0, 0x1f, "sys_b0_1f()" }, { 0xb0, 0x20, "UnDeliverEvent(int class, int event)" }, { 0xb0, 0x21, "sys_b0_21()" }, { 0xb0, 0x22, "sys_b0_22()" }, { 0xb0, 0x23, "sys_b0_23()" }, { 0xb0, 0x24, "sys_b0_24()" }, { 0xb0, 0x25, "sys_b0_25()" }, { 0xb0, 0x26, "sys_b0_26()" }, { 0xb0, 0x27, "sys_b0_27()" }, { 0xb0, 0x28, "sys_b0_28()" }, { 0xb0, 0x29, "sys_b0_29()" }, { 0xb0, 0x2a, "sys_b0_2a()" }, { 0xb0, 0x2b, "sys_b0_2b()" }, { 0xb0, 0x2c, "sys_b0_2c()" }, { 0xb0, 0x2d, "sys_b0_2d()" }, { 0xb0, 0x2e, "sys_b0_2e()" }, { 0xb0, 0x2f, "sys_b0_2f()" }, { 0xb0, 0x2f, "sys_b0_30()" }, { 0xb0, 0x31, "sys_b0_31()" }, { 0xb0, 0x32, "int open(const char *name, int access)" }, { 0xb0, 0x33, "int lseek(int fd, long pos, int seektype)" }, { 0xb0, 0x34, "int read(int fd, void *buf, int nbytes)" }, { 0xb0, 0x35, "int write(int fd, void *buf, int nbytes)" }, { 0xb0, 0x36, "close(int fd)" }, { 0xb0, 0x37, "int ioctl(int fd, int cmd, int arg)" }, { 0xb0, 0x38, "exit(int exitcode)" }, { 0xb0, 0x39, "sys_b0_39()" }, { 0xb0, 0x3a, "char getc(int fd)" }, { 0xb0, 0x3b, "putc(int fd, char ch)" }, { 0xb0, 0x3c, "char getchar(void)" }, { 0xb0, 0x3d, "putchar(char ch)" }, { 0xb0, 0x3e, "char *gets(char *s)" }, { 0xb0, 0x3f, "puts(const char *s)" }, { 0xb0, 0x40, "int cd(const char *path)" }, { 0xb0, 0x41, "int format(const char *fs)" }, { 0xb0, 0x42, "struct DIRENTRY* firstfile(const char *name, struct DIRENTRY *dir)" }, { 0xb0, 0x43, "struct DIRENTRY* nextfile(struct DIRENTRY *dir)" }, { 0xb0, 0x44, "int rename(const char *oldname, const char *newname)" }, { 0xb0, 0x45, "int delete(const char *name)" }, { 0xb0, 0x46, "undelete()" }, { 0xb0, 0x47, "AddDevice()" }, { 0xb0, 0x48, "RemoveDevice()" }, { 0xb0, 0x49, "PrintInstalledDevices()" }, { 0xb0, 0x4a, "InitCARD()" }, { 0xb0, 0x4b, "StartCARD()" }, { 0xb0, 0x4c, "StopCARD()" }, { 0xb0, 0x4d, "sys_b0_4d()" }, { 0xb0, 0x4e, "_card_write()" }, { 0xb0, 0x4f, "_card_read()" }, { 0xb0, 0x50, "_new_card()" }, { 0xb0, 0x51, "void *Krom2RawAdd(int code)" }, { 0xb0, 0x52, "sys_b0_52()" }, { 0xb0, 0x53, "sys_b0_53()" }, { 0xb0, 0x54, "long _get_errno(void)" }, { 0xb0, 0x55, "long _get_error(long fd)" }, { 0xb0, 0x56, "GetC0Table()" }, { 0xb0, 0x57, "GetB0Table()" }, { 0xb0, 0x58, "_card_chan()" }, { 0xb0, 0x59, "sys_b0_59()" }, { 0xb0, 0x5a, "sys_b0_5a()" }, { 0xb0, 0x5b, "ChangeClearPAD(int, int)" }, { 0xb0, 0x5c, "_card_status()" }, { 0xb0, 0x5d, "_card_wait()" }, { 0xc0, 0x00, "InitRCnt()" }, { 0xc0, 0x01, "InitException()" }, { 0xc0, 0x02, "SysEnqIntRP(int index, long *queue)" }, { 0xc0, 0x03, "SysDeqIntRP(int index, long *queue)" }, { 0xc0, 0x04, "int get_free_EvCB_slot(void)" }, { 0xc0, 0x05, "get_free_TCB_slot()" }, { 0xc0, 0x06, "ExceptionHandler()" }, { 0xc0, 0x07, "InstallExceptionHandlers()" }, { 0xc0, 0x08, "SysInitMemory()" }, { 0xc0, 0x09, "SysInitKMem()" }, { 0xc0, 0x0a, "ChangeClearRCnt()" }, { 0xc0, 0x0b, "SystemError()" }, { 0xc0, 0x0c, "InitDefInt()" }, { 0xc0, 0x0d, "sys_c0_0d()" }, { 0xc0, 0x0e, "sys_c0_0e()" }, { 0xc0, 0x0f, "sys_c0_0f()" }, { 0xc0, 0x10, "sys_c0_10()" }, { 0xc0, 0x11, "sys_c0_11()" }, { 0xc0, 0x12, "InstallDevices()" }, { 0xc0, 0x13, "FlushStdInOutPut()" }, { 0xc0, 0x14, "sys_c0_14()" }, { 0xc0, 0x15, "_cdevinput()" }, { 0xc0, 0x16, "_cdevscan()" }, { 0xc0, 0x17, "char _circgetc(struct device_buf *circ)" }, { 0xc0, 0x18, "_circputc(char c, struct device_buf *circ)" }, { 0xc0, 0x19, "ioabort(const char *str)" }, { 0xc0, 0x1a, "sys_c0_1a()" }, { 0xc0, 0x1b, "KernelRedirect(int flag)" }, { 0xc0, 0x1c, "PatchA0Table()" }, { 0x00, 0x00, NULL } }; static UINT32 log_bioscall_parameter( int parm ) { if( parm < 4 ) { return activecpu_get_reg( MIPS_R4 + parm ); } else { return program_read_dword_32le( activecpu_get_reg( MIPS_R29 ) + ( parm * 4 ) ); } } static const char *log_bioscall_string( int parm ) { int pos; UINT32 address; static char string[ 1024 ]; address = log_bioscall_parameter( parm ); if( address == 0 ) { return "NULL"; } pos = 0; string[ pos++ ] = '\"'; for( ;; ) { UINT8 c = program_read_byte_32le( address ); if( c == 0 ) { break; } else if( c == '\t' ) { string[ pos++ ] = '\\'; string[ pos++ ] = 't'; } else if( c == '\r' ) { string[ pos++ ] = '\\'; string[ pos++ ] = 'r'; } else if( c == '\n' ) { string[ pos++ ] = '\\'; string[ pos++ ] = 'n'; } else if( c < 32 || c > 127 ) { string[ pos++ ] = '\\'; string[ pos++ ] = ( ( c / 64 ) % 8 ) + '0'; string[ pos++ ] = ( ( c / 8 ) % 8 ) + '0'; string[ pos++ ] = ( ( c / 1 ) % 8 ) + '0'; } else { string[ pos++ ] = c; } address++; } string[ pos++ ] = '\"'; string[ pos++ ] = 0; return string; } static const char *log_bioscall_hex( int parm ) { static char string[ 1024 ]; sprintf( string, "0x%08x", log_bioscall_parameter( parm ) ); return string; } static const char *log_bioscall_char( int parm ) { int c; static char string[ 1024 ]; c = log_bioscall_parameter( parm ); if( c < 32 || c > 127 ) { sprintf( string, "0x%02x", c ); } else { sprintf( string, "'%c'", c ); } return string; } static void log_bioscall( void ) { int address = activecpu_get_reg( MIPS_PC ) - 0x04; if( address == 0xa0 || address == 0xb0 || address == 0xc0 ) { char buf[ 1024 ]; int operation = activecpu_get_reg( MIPS_R9 ) & 0xff; int bioscall = 0; if( ( address == 0xa0 && operation == 0x3c ) || ( address == 0xb0 && operation == 0x3d ) ) { putchar( log_bioscall_parameter( 0 ) ); } if( ( address == 0xa0 && operation == 0x03 ) || ( address == 0xb0 && operation == 0x35 ) ) { int fd = log_bioscall_parameter( 0 ); int buf = log_bioscall_parameter( 1 ); int nbytes = log_bioscall_parameter( 2 ); if( fd == 1 ) { while( nbytes > 0 ) { UINT8 c = program_read_byte_32le( buf ); putchar( c ); nbytes--; buf++; } } } while( bioscalls[ bioscall ].prototype != NULL && ( bioscalls[ bioscall ].address != address || bioscalls[ bioscall ].operation != operation ) ) { bioscall++; } if( bioscalls[ bioscall ].prototype != NULL ) { const char *prototype = bioscalls[ bioscall ].prototype; const char *parmstart = NULL; int parm = 0; int parmlen = -1; int brackets = 0; int pos = 0; while( *( prototype ) != 0 ) { int ch = *( prototype ); switch( ch ) { case '(': brackets++; prototype++; if( brackets == 1 ) { buf[ pos++ ] = ch; parmstart = prototype; } break; case ')': if( brackets == 1 ) { parmlen = prototype - parmstart; } prototype++; brackets--; break; case ',': if( brackets == 1 ) { parmlen = prototype - parmstart; } prototype++; break; default: if( brackets == 0 ) { buf[ pos++ ] = ch; } prototype++; break; } if( parmlen >= 0 ) { while( parmlen > 0 && parmstart[ 0 ] == ' ' ) { parmstart++; parmlen--; } while( parmlen > 0 && parmstart[ parmlen - 1 ] == ' ' ) { parmlen--; } if( parmlen == 0 || ( parmlen == 4 && memcmp( parmstart, "void", 4 ) == 0 ) ) { parm = -1; } else if( parmlen == 3 && memcmp( parmstart, "...", 3 ) == 0 ) { if( parm > 0 ) { UINT32 format = log_bioscall_parameter( parm - 1 ); const char *parmstr = NULL; int percent = 0; for( ;; ) { UINT8 c = program_read_byte_32le( format ); if( c == 0 ) { break; } if( percent == 0 ) { if( c == '%' ) { percent = 1; } } else { if( c == '%' ) { percent = 0; } else if( c == '*' ) { parmstr = log_bioscall_hex( parm ); } else if( c == 's' ) { parmstr = log_bioscall_string( parm ); percent = 0; } else if( c == 'c' ) { parmstr = log_bioscall_char( parm ); percent = 0; } else if( c != '-' && c != '.' && c != 'l' && ( c < '0' || c > '9' ) ) { parmstr = log_bioscall_hex( parm ); percent = 0; } } if( parmstr != NULL ) { if( parm > 0 ) { buf[ pos++ ] = ','; } buf[ pos++ ] = ' '; strcpy( &buf[ pos ], parmstr ); pos += strlen( parmstr ); parmstr = NULL; parm++; } format++; } } } else if( parmlen > 0 ) { const char *parmstr; int typelen = parmlen; while( typelen > 0 && parmstart[ typelen - 1 ] != ' ' && parmstart[ typelen - 1 ] != '*' ) { typelen--; } if( typelen == 5 && memcmp( parmstart, "char ", 5 ) == 0 ) { parmstr = log_bioscall_char( parm ); } else if( typelen == 12 && memcmp( parmstart, "const char *", 12 ) == 0 ) { parmstr = log_bioscall_string( parm ); } else { parmstr = log_bioscall_hex( parm ); } if( parm > 0 ) { buf[ pos++ ] = ','; } buf[ pos++ ] = ' '; strcpy( &buf[ pos ], parmstr ); pos += strlen( parmstr ); } parmlen = -1; parm++; if( ch == ',' ) { parmstart = prototype; } else { if( parm > 0 ) { buf[ pos++ ] = ' '; } buf[ pos++ ] = ch; } } } buf[ pos ] = 0; } else { sprintf( buf, "unknown_%02x_%02x", address, operation ); } logerror( "%08x: bioscall %s\n", (unsigned int)activecpu_get_reg( MIPS_R31 ) - 8, buf ); } } static void log_syscall( void ) { char buf[ 1024 ]; int operation = activecpu_get_reg( MIPS_R4 ); switch( operation ) { case 0: strcpy( buf, "void Exception()" ); break; case 1: strcpy( buf, "void EnterCriticalSection()" ); break; case 2: strcpy( buf, "void ExitCriticalSection()" ); break; default: sprintf( buf, "unknown_%02x", operation ); break; } logerror( "%08x: syscall %s\n", (unsigned int)activecpu_get_reg( MIPS_R31 ) - 8, buf ); } #endif INLINE void mips_set_cp0r( int reg, UINT32 value ) { mipscpu.cp0r[ reg ] = value; if( reg == CP0_SR || reg == CP0_CAUSE ) { if( ( mipscpu.cp0r[ CP0_SR ] & SR_IEC ) != 0 && ( mipscpu.cp0r[ CP0_SR ] & mipscpu.cp0r[ CP0_CAUSE ] & CAUSE_IP ) != 0 ) { mips_exception( EXC_INT ); } else if( mipscpu.delayr != REGPC && ( mipscpu.pc & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 3 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, mipscpu.pc ); } } } INLINE void mips_commit_delayed_load( void ) { if( mipscpu.delayr != 0 ) { mipscpu.r[ mipscpu.delayr ] = mipscpu.delayv; mipscpu.delayr = 0; mipscpu.delayv = 0; } } INLINE void mips_delayed_branch( UINT32 n_adr ) { if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 3 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else if( mipscpu.delayr == REGPC ) { mipscpu.pc = mipscpu.delayv; change_pc( mipscpu.delayv ); mipscpu.delayv = n_adr; } else { mips_commit_delayed_load(); mipscpu.delayr = REGPC; mipscpu.delayv = n_adr; mipscpu.pc += 4; } } INLINE void mips_set_pc( unsigned val ) { mipscpu.pc = val; change_pc( val ); mipscpu.delayr = 0; mipscpu.delayv = 0; } INLINE void mips_advance_pc( void ) { if( mipscpu.delayr == REGPC ) { mips_set_pc( mipscpu.delayv ); } else { mips_commit_delayed_load(); mipscpu.pc += 4; } } INLINE void mips_load( UINT32 n_r, UINT32 n_v ) { mips_advance_pc(); if( n_r != 0 ) { mipscpu.r[ n_r ] = n_v; } } INLINE void mips_delayed_load( UINT32 n_r, UINT32 n_v ) { if( mipscpu.delayr == REGPC ) { mips_set_pc( mipscpu.delayv ); mipscpu.delayr = n_r; mipscpu.delayv = n_v; } else { mips_commit_delayed_load(); mipscpu.pc += 4; if( n_r != 0 ) { mipscpu.r[ n_r ] = n_v; } } } static void mips_exception( int exception ) { mips_set_cp0r( CP0_SR, ( mipscpu.cp0r[ CP0_SR ] & ~0x3f ) | ( ( mipscpu.cp0r[ CP0_SR ] << 2 ) & 0x3f ) ); if( mipscpu.delayr == REGPC ) { mips_set_cp0r( CP0_EPC, mipscpu.pc - 4 ); mips_set_cp0r( CP0_CAUSE, ( mipscpu.cp0r[ CP0_CAUSE ] & ~CAUSE_EXC ) | CAUSE_BD | ( exception << 2 ) ); } else { mips_commit_delayed_load(); mips_set_cp0r( CP0_EPC, mipscpu.pc ); mips_set_cp0r( CP0_CAUSE, ( mipscpu.cp0r[ CP0_CAUSE ] & ~( CAUSE_EXC | CAUSE_BD ) ) | ( exception << 2 ) ); } if( mipscpu.cp0r[ CP0_SR ] & SR_BEV ) { mips_set_pc( 0xbfc00180 ); } else { mips_set_pc( 0x80000080 ); } } static void mips_init( int index, int clock, const void *config, int (*irqcallback)(int) ) { mipscpu.irq_callback = irqcallback; state_save_register_item( "psxcpu", index, mipscpu.op ); state_save_register_item( "psxcpu", index, mipscpu.pc ); state_save_register_item( "psxcpu", index, mipscpu.delayv ); state_save_register_item( "psxcpu", index, mipscpu.delayr ); state_save_register_item( "psxcpu", index, mipscpu.hi ); state_save_register_item( "psxcpu", index, mipscpu.lo ); state_save_register_item_array( "psxcpu", index, mipscpu.r ); state_save_register_item_array( "psxcpu", index, mipscpu.cp0r ); state_save_register_item_array( "psxcpu", index, mipscpu.cp2cr ); state_save_register_item_array( "psxcpu", index, mipscpu.cp2dr ); } static void mips_reset( void ) { mips_set_cp0r( CP0_SR, ( mipscpu.cp0r[ CP0_SR ] & ~( SR_TS | SR_SWC | SR_KUC | SR_IEC ) ) | SR_BEV ); mips_set_cp0r( CP0_RANDOM, 63 ); /* todo: */ mips_set_cp0r( CP0_PRID, 0x00000200 ); /* todo: */ mips_set_pc( 0xbfc00000 ); } static void mips_exit( void ) { } static int mips_execute( int cycles ) { UINT32 n_res; mips_ICount = cycles; do { #if LOG_BIOSCALL log_bioscall(); #endif CALL_MAME_DEBUG; mipscpu.op = cpu_readop32( mipscpu.pc ); switch( INS_OP( mipscpu.op ) ) { case OP_SPECIAL: switch( INS_FUNCT( mipscpu.op ) ) { case FUNCT_SLL: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RT( mipscpu.op ) ] << INS_SHAMT( mipscpu.op ) ); break; case FUNCT_SRL: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RT( mipscpu.op ) ] >> INS_SHAMT( mipscpu.op ) ); break; case FUNCT_SRA: mips_load( INS_RD( mipscpu.op ), (INT32)mipscpu.r[ INS_RT( mipscpu.op ) ] >> INS_SHAMT( mipscpu.op ) ); break; case FUNCT_SLLV: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RT( mipscpu.op ) ] << ( mipscpu.r[ INS_RS( mipscpu.op ) ] & 31 ) ); break; case FUNCT_SRLV: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RT( mipscpu.op ) ] >> ( mipscpu.r[ INS_RS( mipscpu.op ) ] & 31 ) ); break; case FUNCT_SRAV: mips_load( INS_RD( mipscpu.op ), (INT32)mipscpu.r[ INS_RT( mipscpu.op ) ] >> ( mipscpu.r[ INS_RS( mipscpu.op ) ] & 31 ) ); break; case FUNCT_JR: if( INS_RD( mipscpu.op ) != 0 ) { mips_exception( EXC_RI ); } else { mips_delayed_branch( mipscpu.r[ INS_RS( mipscpu.op ) ] ); } break; case FUNCT_JALR: n_res = mipscpu.pc + 8; mips_delayed_branch( mipscpu.r[ INS_RS( mipscpu.op ) ] ); if( INS_RD( mipscpu.op ) != 0 ) { mipscpu.r[ INS_RD( mipscpu.op ) ] = n_res; } break; case FUNCT_SYSCALL: #if LOG_BIOSCALL log_syscall(); #endif mips_exception( EXC_SYS ); break; case FUNCT_BREAK: mips_exception( EXC_BP ); break; case FUNCT_MFHI: mips_load( INS_RD( mipscpu.op ), mipscpu.hi ); break; case FUNCT_MTHI: if( INS_RD( mipscpu.op ) != 0 ) { mips_exception( EXC_RI ); } else { mips_advance_pc(); mipscpu.hi = mipscpu.r[ INS_RS( mipscpu.op ) ]; } break; case FUNCT_MFLO: mips_load( INS_RD( mipscpu.op ), mipscpu.lo ); break; case FUNCT_MTLO: if( INS_RD( mipscpu.op ) != 0 ) { mips_exception( EXC_RI ); } else { mips_advance_pc(); mipscpu.lo = mipscpu.r[ INS_RS( mipscpu.op ) ]; } break; case FUNCT_MULT: if( INS_RD( mipscpu.op ) != 0 ) { mips_exception( EXC_RI ); } else { INT64 n_res64; n_res64 = MUL_64_32_32( (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ], (INT32)mipscpu.r[ INS_RT( mipscpu.op ) ] ); mips_advance_pc(); mipscpu.lo = LO32_32_64( n_res64 ); mipscpu.hi = HI32_32_64( n_res64 ); } break; case FUNCT_MULTU: if( INS_RD( mipscpu.op ) != 0 ) { mips_exception( EXC_RI ); } else { UINT64 n_res64; n_res64 = MUL_U64_U32_U32( mipscpu.r[ INS_RS( mipscpu.op ) ], mipscpu.r[ INS_RT( mipscpu.op ) ] ); mips_advance_pc(); mipscpu.lo = LO32_U32_U64( n_res64 ); mipscpu.hi = HI32_U32_U64( n_res64 ); } break; case FUNCT_DIV: if( INS_RD( mipscpu.op ) != 0 ) { mips_exception( EXC_RI ); } else { UINT32 n_div; UINT32 n_mod; if( mipscpu.r[ INS_RT( mipscpu.op ) ] != 0 ) { n_div = (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] / (INT32)mipscpu.r[ INS_RT( mipscpu.op ) ]; n_mod = (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] % (INT32)mipscpu.r[ INS_RT( mipscpu.op ) ]; mips_advance_pc(); mipscpu.lo = n_div; mipscpu.hi = n_mod; } else { mips_advance_pc(); } } break; case FUNCT_DIVU: if( INS_RD( mipscpu.op ) != 0 ) { mips_exception( EXC_RI ); } else { UINT32 n_div; UINT32 n_mod; if( mipscpu.r[ INS_RT( mipscpu.op ) ] != 0 ) { n_div = mipscpu.r[ INS_RS( mipscpu.op ) ] / mipscpu.r[ INS_RT( mipscpu.op ) ]; n_mod = mipscpu.r[ INS_RS( mipscpu.op ) ] % mipscpu.r[ INS_RT( mipscpu.op ) ]; mips_advance_pc(); mipscpu.lo = n_div; mipscpu.hi = n_mod; } else { mips_advance_pc(); } } break; case FUNCT_ADD: { n_res = mipscpu.r[ INS_RS( mipscpu.op ) ] + mipscpu.r[ INS_RT( mipscpu.op ) ]; if( (INT32)( ~( mipscpu.r[ INS_RS( mipscpu.op ) ] ^ mipscpu.r[ INS_RT( mipscpu.op ) ] ) & ( mipscpu.r[ INS_RS( mipscpu.op ) ] ^ n_res ) ) < 0 ) { mips_exception( EXC_OVF ); } else { mips_load( INS_RD( mipscpu.op ), n_res ); } } break; case FUNCT_ADDU: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] + mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case FUNCT_SUB: n_res = mipscpu.r[ INS_RS( mipscpu.op ) ] - mipscpu.r[ INS_RT( mipscpu.op ) ]; if( (INT32)( ( mipscpu.r[ INS_RS( mipscpu.op ) ] ^ mipscpu.r[ INS_RT( mipscpu.op ) ] ) & ( mipscpu.r[ INS_RS( mipscpu.op ) ] ^ n_res ) ) < 0 ) { mips_exception( EXC_OVF ); } else { mips_load( INS_RD( mipscpu.op ), n_res ); } break; case FUNCT_SUBU: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] - mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case FUNCT_AND: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] & mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case FUNCT_OR: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] | mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case FUNCT_XOR: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] ^ mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case FUNCT_NOR: mips_load( INS_RD( mipscpu.op ), ~( mipscpu.r[ INS_RS( mipscpu.op ) ] | mipscpu.r[ INS_RT( mipscpu.op ) ] ) ); break; case FUNCT_SLT: mips_load( INS_RD( mipscpu.op ), (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] < (INT32)mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case FUNCT_SLTU: mips_load( INS_RD( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] < mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; default: mips_exception( EXC_RI ); break; } break; case OP_REGIMM: switch( INS_RT( mipscpu.op ) ) { case RT_BLTZ: if( (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] < 0 ) { mips_delayed_branch( mipscpu.pc + 4 + ( MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) << 2 ) ); } else { mips_advance_pc(); } break; case RT_BGEZ: if( (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] >= 0 ) { mips_delayed_branch( mipscpu.pc + 4 + ( MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) << 2 ) ); } else { mips_advance_pc(); } break; case RT_BLTZAL: n_res = mipscpu.pc + 8; if( (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] < 0 ) { mips_delayed_branch( mipscpu.pc + 4 + ( MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) << 2 ) ); } else { mips_advance_pc(); } mipscpu.r[ 31 ] = n_res; break; case RT_BGEZAL: n_res = mipscpu.pc + 8; if( (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] >= 0 ) { mips_delayed_branch( mipscpu.pc + 4 + ( MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) << 2 ) ); } else { mips_advance_pc(); } mipscpu.r[ 31 ] = n_res; break; } break; case OP_J: mips_delayed_branch( ( ( mipscpu.pc + 4 ) & 0xf0000000 ) + ( INS_TARGET( mipscpu.op ) << 2 ) ); break; case OP_JAL: n_res = mipscpu.pc + 8; mips_delayed_branch( ( ( mipscpu.pc + 4 ) & 0xf0000000 ) + ( INS_TARGET( mipscpu.op ) << 2 ) ); mipscpu.r[ 31 ] = n_res; break; case OP_BEQ: if( mipscpu.r[ INS_RS( mipscpu.op ) ] == mipscpu.r[ INS_RT( mipscpu.op ) ] ) { mips_delayed_branch( mipscpu.pc + 4 + ( MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) << 2 ) ); } else { mips_advance_pc(); } break; case OP_BNE: if( mipscpu.r[ INS_RS( mipscpu.op ) ] != mipscpu.r[ INS_RT( mipscpu.op ) ] ) { mips_delayed_branch( mipscpu.pc + 4 + ( MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) << 2 ) ); } else { mips_advance_pc(); } break; case OP_BLEZ: if( INS_RT( mipscpu.op ) != 0 ) { mips_exception( EXC_RI ); } else if( (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] <= 0 ) { mips_delayed_branch( mipscpu.pc + 4 + ( MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) << 2 ) ); } else { mips_advance_pc(); } break; case OP_BGTZ: if( INS_RT( mipscpu.op ) != 0 ) { mips_exception( EXC_RI ); } else if( (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] > 0 ) { mips_delayed_branch( mipscpu.pc + 4 + ( MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) << 2 ) ); } else { mips_advance_pc(); } break; case OP_ADDI: { UINT32 n_imm; n_imm = MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); n_res = mipscpu.r[ INS_RS( mipscpu.op ) ] + n_imm; if( (INT32)( ~( mipscpu.r[ INS_RS( mipscpu.op ) ] ^ n_imm ) & ( mipscpu.r[ INS_RS( mipscpu.op ) ] ^ n_res ) ) < 0 ) { mips_exception( EXC_OVF ); } else { mips_load( INS_RT( mipscpu.op ), n_res ); } } break; case OP_ADDIU: mips_load( INS_RT( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) ); break; case OP_SLTI: mips_load( INS_RT( mipscpu.op ), (INT32)mipscpu.r[ INS_RS( mipscpu.op ) ] < MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) ); break; case OP_SLTIU: mips_load( INS_RT( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] < (UINT32)MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ) ); break; case OP_ANDI: mips_load( INS_RT( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] & INS_IMMEDIATE( mipscpu.op ) ); break; case OP_ORI: mips_load( INS_RT( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] | INS_IMMEDIATE( mipscpu.op ) ); break; case OP_XORI: mips_load( INS_RT( mipscpu.op ), mipscpu.r[ INS_RS( mipscpu.op ) ] ^ INS_IMMEDIATE( mipscpu.op ) ); break; case OP_LUI: mips_load( INS_RT( mipscpu.op ), INS_IMMEDIATE( mipscpu.op ) << 16 ); break; case OP_COP0: if( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) != 0 && ( mipscpu.cp0r[ CP0_SR ] & SR_CU0 ) == 0 ) { mips_exception( EXC_CPU ); mips_set_cp0r( CP0_CAUSE, ( mipscpu.cp0r[ CP0_CAUSE ] & ~CAUSE_CE ) | CAUSE_CE0 ); } else { switch( INS_RS( mipscpu.op ) ) { case RS_MFC: mips_delayed_load( INS_RT( mipscpu.op ), mipscpu.cp0r[ INS_RD( mipscpu.op ) ] ); break; case RS_CFC: /* todo: */ logerror( "%08x: COP0 CFC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case RS_MTC: n_res = ( mipscpu.cp0r[ INS_RD( mipscpu.op ) ] & ~mips_mtc0_writemask[ INS_RD( mipscpu.op ) ] ) | ( mipscpu.r[ INS_RT( mipscpu.op ) ] & mips_mtc0_writemask[ INS_RD( mipscpu.op ) ] ); mips_advance_pc(); mips_set_cp0r( INS_RD( mipscpu.op ), n_res ); break; case RS_CTC: /* todo: */ logerror( "%08x: COP0 CTC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case RS_BC: switch( INS_RT( mipscpu.op ) ) { case RT_BCF: /* todo: */ logerror( "%08x: COP0 BCF not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case RT_BCT: /* todo: */ logerror( "%08x: COP0 BCT not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; default: /* todo: */ logerror( "%08x: COP0 unknown command %08x\n", mipscpu.pc, mipscpu.op ); mips_stop(); mips_advance_pc(); break; } break; default: switch( INS_CO( mipscpu.op ) ) { case 1: switch( INS_CF( mipscpu.op ) ) { case CF_RFE: mips_advance_pc(); mips_set_cp0r( CP0_SR, ( mipscpu.cp0r[ CP0_SR ] & ~0xf ) | ( ( mipscpu.cp0r[ CP0_SR ] >> 2 ) & 0xf ) ); break; default: /* todo: */ logerror( "%08x: COP0 unknown command %08x\n", mipscpu.pc, mipscpu.op ); mips_stop(); mips_advance_pc(); break; } break; default: /* todo: */ logerror( "%08x: COP0 unknown command %08x\n", mipscpu.pc, mipscpu.op ); mips_stop(); mips_advance_pc(); break; } break; } } break; case OP_COP1: if( ( mipscpu.cp0r[ CP0_SR ] & SR_CU1 ) == 0 ) { mips_exception( EXC_CPU ); mips_set_cp0r( CP0_CAUSE, ( mipscpu.cp0r[ CP0_CAUSE ] & ~CAUSE_CE ) | CAUSE_CE1 ); } else { switch( INS_RS( mipscpu.op ) ) { case RS_MFC: /* todo: */ logerror( "%08x: COP1 BCT not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case RS_CFC: /* todo: */ logerror( "%08x: COP1 CFC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case RS_MTC: /* todo: */ logerror( "%08x: COP1 MTC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case RS_CTC: /* todo: */ logerror( "%08x: COP1 CTC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case RS_BC: switch( INS_RT( mipscpu.op ) ) { case RT_BCF: /* todo: */ logerror( "%08x: COP1 BCF not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case RT_BCT: /* todo: */ logerror( "%08x: COP1 BCT not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; default: /* todo: */ logerror( "%08x: COP1 unknown command %08x\n", mipscpu.pc, mipscpu.op ); mips_stop(); mips_advance_pc(); break; } break; default: switch( INS_CO( mipscpu.op ) ) { case 1: /* todo: */ logerror( "%08x: COP1 unknown command %08x\n", mipscpu.pc, mipscpu.op ); mips_stop(); mips_advance_pc(); break; default: /* todo: */ logerror( "%08x: COP1 unknown command %08x\n", mipscpu.pc, mipscpu.op ); mips_stop(); mips_advance_pc(); break; } break; } } break; case OP_COP2: if( ( mipscpu.cp0r[ CP0_SR ] & SR_CU2 ) == 0 ) { mips_exception( EXC_CPU ); mips_set_cp0r( CP0_CAUSE, ( mipscpu.cp0r[ CP0_CAUSE ] & ~CAUSE_CE ) | CAUSE_CE2 ); } else { switch( INS_RS( mipscpu.op ) ) { case RS_MFC: mips_delayed_load( INS_RT( mipscpu.op ), getcp2dr( INS_RD( mipscpu.op ) ) ); break; case RS_CFC: mips_delayed_load( INS_RT( mipscpu.op ), getcp2cr( INS_RD( mipscpu.op ) ) ); break; case RS_MTC: setcp2dr( INS_RD( mipscpu.op ), mipscpu.r[ INS_RT( mipscpu.op ) ] ); mips_advance_pc(); break; case RS_CTC: setcp2cr( INS_RD( mipscpu.op ), mipscpu.r[ INS_RT( mipscpu.op ) ] ); mips_advance_pc(); break; case RS_BC: switch( INS_RT( mipscpu.op ) ) { case RT_BCF: /* todo: */ logerror( "%08x: COP2 BCF not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case RT_BCT: /* todo: */ logerror( "%08x: COP2 BCT not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; default: /* todo: */ logerror( "%08x: COP2 unknown command %08x\n", mipscpu.pc, mipscpu.op ); mips_stop(); mips_advance_pc(); break; } break; default: switch( INS_CO( mipscpu.op ) ) { case 1: docop2( INS_COFUN( mipscpu.op ) ); mips_advance_pc(); break; default: /* todo: */ logerror( "%08x: COP2 unknown command %08x\n", mipscpu.pc, mipscpu.op ); mips_stop(); mips_advance_pc(); break; } break; } } break; case OP_LB: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: LB SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { mips_delayed_load( INS_RT( mipscpu.op ), MIPS_BYTE_EXTEND( program_read_byte_32le( n_adr ^ 3 ) ) ); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { mips_delayed_load( INS_RT( mipscpu.op ), MIPS_BYTE_EXTEND( program_read_byte_32le( n_adr ) ) ); } } break; case OP_LH: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: LH SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 1 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { mips_delayed_load( INS_RT( mipscpu.op ), MIPS_WORD_EXTEND( program_read_word_32le( n_adr ^ 2 ) ) ); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 1 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { mips_delayed_load( INS_RT( mipscpu.op ), MIPS_WORD_EXTEND( program_read_word_32le( n_adr ) ) ); } } break; case OP_LWL: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: LWL SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { switch( n_adr & 3 ) { case 0: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0x00ffffff ) | ( (UINT32)program_read_byte_32le( n_adr + 3 ) << 24 ); break; case 1: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0x0000ffff ) | ( (UINT32)program_read_word_32le( n_adr + 1 ) << 16 ); break; case 2: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0x000000ff ) | ( (UINT32)program_read_byte_32le( n_adr - 1 ) << 8 ) | ( (UINT32)program_read_word_32le( n_adr ) << 16 ); break; default: n_res = program_read_dword_32le( n_adr - 3 ); break; } mips_delayed_load( INS_RT( mipscpu.op ), n_res ); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { switch( n_adr & 3 ) { case 0: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0x00ffffff ) | ( (UINT32)program_read_byte_32le( n_adr ) << 24 ); break; case 1: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0x0000ffff ) | ( (UINT32)program_read_word_32le( n_adr - 1 ) << 16 ); break; case 2: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0x000000ff ) | ( (UINT32)program_read_word_32le( n_adr - 2 ) << 8 ) | ( (UINT32)program_read_byte_32le( n_adr ) << 24 ); break; default: n_res = program_read_dword_32le( n_adr - 3 ); break; } mips_delayed_load( INS_RT( mipscpu.op ), n_res ); } } break; case OP_LW: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: LW SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 3 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { mips_delayed_load( INS_RT( mipscpu.op ), program_read_dword_32le( n_adr ) ); } } break; case OP_LBU: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: LBU SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { mips_delayed_load( INS_RT( mipscpu.op ), program_read_byte_32le( n_adr ^ 3 ) ); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { mips_delayed_load( INS_RT( mipscpu.op ), program_read_byte_32le( n_adr ) ); } } break; case OP_LHU: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: LHU SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 1 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { mips_delayed_load( INS_RT( mipscpu.op ), program_read_word_32le( n_adr ^ 2 ) ); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 1 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { mips_delayed_load( INS_RT( mipscpu.op ), program_read_word_32le( n_adr ) ); } } break; case OP_LWR: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: LWR SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { switch( n_adr & 3 ) { case 3: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0xffffff00 ) | program_read_byte_32le( n_adr - 3 ); break; case 2: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0xffff0000 ) | program_read_word_32le( n_adr - 2 ); break; case 1: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0xff000000 ) | program_read_word_32le( n_adr - 1 ) | ( (UINT32)program_read_byte_32le( n_adr + 1 ) << 16 ); break; default: n_res = program_read_dword_32le( n_adr ); break; } mips_delayed_load( INS_RT( mipscpu.op ), n_res ); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { switch( n_adr & 3 ) { case 3: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0xffffff00 ) | program_read_byte_32le( n_adr ); break; case 2: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0xffff0000 ) | program_read_word_32le( n_adr ); break; case 1: n_res = ( mipscpu.r[ INS_RT( mipscpu.op ) ] & 0xff000000 ) | program_read_byte_32le( n_adr ) | ( (UINT32)program_read_word_32le( n_adr + 1 ) << 8 ); break; default: n_res = program_read_dword_32le( n_adr ); break; } mips_delayed_load( INS_RT( mipscpu.op ), n_res ); } } break; case OP_SB: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: SB SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { program_write_byte_32le( n_adr ^ 3, mipscpu.r[ INS_RT( mipscpu.op ) ] ); mips_advance_pc(); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { program_write_byte_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] ); mips_advance_pc(); } } break; case OP_SH: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: SH SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 1 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { program_write_word_32le( n_adr ^ 2, mipscpu.r[ INS_RT( mipscpu.op ) ] ); mips_advance_pc(); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 1 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { program_write_word_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] ); mips_advance_pc(); } } break; case OP_SWL: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: SWL SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { switch( n_adr & 3 ) { case 0: program_write_byte_32le( n_adr + 3, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 24 ); break; case 1: program_write_word_32le( n_adr + 1, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 16 ); break; case 2: program_write_byte_32le( n_adr - 1, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 8 ); program_write_word_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 16 ); break; case 3: program_write_dword_32le( n_adr - 3, mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; } mips_advance_pc(); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { switch( n_adr & 3 ) { case 0: program_write_byte_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 24 ); break; case 1: program_write_word_32le( n_adr - 1, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 16 ); break; case 2: program_write_word_32le( n_adr - 2, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 8 ); program_write_byte_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 24 ); break; case 3: program_write_dword_32le( n_adr - 3, mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; } mips_advance_pc(); } } break; case OP_SW: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ /* used by bootstrap logerror( "%08x: SW SR_ISC not supported\n", mipscpu.pc ); mips_stop(); */ mips_advance_pc(); } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 3 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { program_write_dword_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] ); mips_advance_pc(); } } break; case OP_SWR: if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: SWR SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else if( ( mipscpu.cp0r[ CP0_SR ] & ( SR_RE | SR_KUC ) ) == ( SR_RE | SR_KUC ) ) { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { switch( n_adr & 3 ) { case 0: program_write_dword_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case 1: program_write_word_32le( n_adr - 1, mipscpu.r[ INS_RT( mipscpu.op ) ] ); program_write_byte_32le( n_adr + 1, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 16 ); break; case 2: program_write_word_32le( n_adr - 2, mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case 3: program_write_byte_32le( n_adr - 3, mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; } mips_advance_pc(); } } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { switch( n_adr & 3 ) { case 0: program_write_dword_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case 1: program_write_byte_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] ); program_write_word_32le( n_adr + 1, mipscpu.r[ INS_RT( mipscpu.op ) ] >> 8 ); break; case 2: program_write_word_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; case 3: program_write_byte_32le( n_adr, mipscpu.r[ INS_RT( mipscpu.op ) ] ); break; } mips_advance_pc(); } } break; case OP_LWC1: /* todo: */ logerror( "%08x: COP1 LWC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case OP_LWC2: if( ( mipscpu.cp0r[ CP0_SR ] & SR_CU2 ) == 0 ) { mips_exception( EXC_CPU ); mips_set_cp0r( CP0_CAUSE, ( mipscpu.cp0r[ CP0_CAUSE ] & ~CAUSE_CE ) | CAUSE_CE2 ); } else if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: LWC2 SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 3 ) ) != 0 ) { mips_exception( EXC_ADEL ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { /* todo: delay? */ setcp2dr( INS_RT( mipscpu.op ), program_read_dword_32le( n_adr ) ); mips_advance_pc(); } } break; case OP_SWC1: /* todo: */ logerror( "%08x: COP1 SWC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); break; case OP_SWC2: if( ( mipscpu.cp0r[ CP0_SR ] & SR_CU2 ) == 0 ) { mips_exception( EXC_CPU ); mips_set_cp0r( CP0_CAUSE, ( mipscpu.cp0r[ CP0_CAUSE ] & ~CAUSE_CE ) | CAUSE_CE2 ); } else if( ( mipscpu.cp0r[ CP0_SR ] & SR_ISC ) != 0 ) { /* todo: */ logerror( "%08x: SWC2 SR_ISC not supported\n", mipscpu.pc ); mips_stop(); mips_advance_pc(); } else { UINT32 n_adr; n_adr = mipscpu.r[ INS_RS( mipscpu.op ) ] + MIPS_WORD_EXTEND( INS_IMMEDIATE( mipscpu.op ) ); if( ( n_adr & ( ( ( mipscpu.cp0r[ CP0_SR ] & SR_KUC ) << 30 ) | 3 ) ) != 0 ) { mips_exception( EXC_ADES ); mips_set_cp0r( CP0_BADVADDR, n_adr ); } else { program_write_dword_32le( n_adr, getcp2dr( INS_RT( mipscpu.op ) ) ); mips_advance_pc(); } } break; default: logerror( "%08x: unknown opcode %08x\n", mipscpu.pc, mipscpu.op ); mips_stop(); mips_exception( EXC_RI ); break; } mips_ICount--; } while( mips_ICount > 0 ); return cycles - mips_ICount; } static void mips_get_context( void *dst ) { if( dst ) { *(mips_cpu_context *)dst = mipscpu; } } static void mips_set_context( void *src ) { if( src ) { mipscpu = *(mips_cpu_context *)src; change_pc( mipscpu.pc ); } } static void set_irq_line( int irqline, int state ) { UINT32 ip; switch( irqline ) { case MIPS_IRQ0: ip = CAUSE_IP2; break; case MIPS_IRQ1: ip = CAUSE_IP3; break; case MIPS_IRQ2: ip = CAUSE_IP4; break; case MIPS_IRQ3: ip = CAUSE_IP5; break; case MIPS_IRQ4: ip = CAUSE_IP6; break; case MIPS_IRQ5: ip = CAUSE_IP7; break; default: return; } switch( state ) { case CLEAR_LINE: mips_set_cp0r( CP0_CAUSE, mipscpu.cp0r[ CP0_CAUSE ] & ~ip ); break; case ASSERT_LINE: mips_set_cp0r( CP0_CAUSE, mipscpu.cp0r[ CP0_CAUSE ] |= ip ); if( mipscpu.irq_callback ) { /* HOLD_LINE interrupts are not supported by the architecture. By acknowledging the interupt here they are treated like PULSE_LINE interrupts, so if the interrupt isn't enabled it will be ignored. There is also a problem with PULSE_LINE interrupts as the interrupt pending bits aren't latched the emulated code won't know what caused the interrupt. */ (*mipscpu.irq_callback)( irqline ); } break; } } /**************************************************************************** * Return a formatted string for a register ****************************************************************************/ #ifdef MAME_DEBUG static offs_t mips_dasm(char *buffer, offs_t pc, const UINT8 *oprom, const UINT8 *opram) { return DasmMIPS( buffer, pc, opram ); } #endif /* MAME_DEBUG */ /* preliminary gte code */ #define VXY0 ( mipscpu.cp2dr[ 0 ].d ) #define VX0 ( mipscpu.cp2dr[ 0 ].w.l ) #define VY0 ( mipscpu.cp2dr[ 0 ].w.h ) #define VZ0 ( mipscpu.cp2dr[ 1 ].w.l ) #define VXY1 ( mipscpu.cp2dr[ 2 ].d ) #define VX1 ( mipscpu.cp2dr[ 2 ].w.l ) #define VY1 ( mipscpu.cp2dr[ 2 ].w.h ) #define VZ1 ( mipscpu.cp2dr[ 3 ].w.l ) #define VXY2 ( mipscpu.cp2dr[ 4 ].d ) #define VX2 ( mipscpu.cp2dr[ 4 ].w.l ) #define VY2 ( mipscpu.cp2dr[ 4 ].w.h ) #define VZ2 ( mipscpu.cp2dr[ 5 ].w.l ) #define RGB ( mipscpu.cp2dr[ 6 ].d ) #define R ( mipscpu.cp2dr[ 6 ].b.l ) #define G ( mipscpu.cp2dr[ 6 ].b.h ) #define B ( mipscpu.cp2dr[ 6 ].b.h2 ) #define CODE ( mipscpu.cp2dr[ 6 ].b.h3 ) #define OTZ ( mipscpu.cp2dr[ 7 ].w.l ) #define IR0 ( mipscpu.cp2dr[ 8 ].d ) #define IR1 ( mipscpu.cp2dr[ 9 ].d ) #define IR2 ( mipscpu.cp2dr[ 10 ].d ) #define IR3 ( mipscpu.cp2dr[ 11 ].d ) #define SXY0 ( mipscpu.cp2dr[ 12 ].d ) #define SX0 ( mipscpu.cp2dr[ 12 ].w.l ) #define SY0 ( mipscpu.cp2dr[ 12 ].w.h ) #define SXY1 ( mipscpu.cp2dr[ 13 ].d ) #define SX1 ( mipscpu.cp2dr[ 13 ].w.l ) #define SY1 ( mipscpu.cp2dr[ 13 ].w.h ) #define SXY2 ( mipscpu.cp2dr[ 14 ].d ) #define SX2 ( mipscpu.cp2dr[ 14 ].w.l ) #define SY2 ( mipscpu.cp2dr[ 14 ].w.h ) #define SXYP ( mipscpu.cp2dr[ 15 ].d ) #define SXP ( mipscpu.cp2dr[ 15 ].w.l ) #define SYP ( mipscpu.cp2dr[ 15 ].w.h ) #define SZ0 ( mipscpu.cp2dr[ 16 ].w.l ) #define SZ1 ( mipscpu.cp2dr[ 17 ].w.l ) #define SZ2 ( mipscpu.cp2dr[ 18 ].w.l ) #define SZ3 ( mipscpu.cp2dr[ 19 ].w.l ) #define RGB0 ( mipscpu.cp2dr[ 20 ].d ) #define R0 ( mipscpu.cp2dr[ 20 ].b.l ) #define G0 ( mipscpu.cp2dr[ 20 ].b.h ) #define B0 ( mipscpu.cp2dr[ 20 ].b.h2 ) #define CD0 ( mipscpu.cp2dr[ 20 ].b.h3 ) #define RGB1 ( mipscpu.cp2dr[ 21 ].d ) #define R1 ( mipscpu.cp2dr[ 21 ].b.l ) #define G1 ( mipscpu.cp2dr[ 21 ].b.h ) #define B1 ( mipscpu.cp2dr[ 21 ].b.h2 ) #define CD1 ( mipscpu.cp2dr[ 21 ].b.h3 ) #define RGB2 ( mipscpu.cp2dr[ 22 ].d ) #define R2 ( mipscpu.cp2dr[ 22 ].b.l ) #define G2 ( mipscpu.cp2dr[ 22 ].b.h ) #define B2 ( mipscpu.cp2dr[ 22 ].b.h2 ) #define CD2 ( mipscpu.cp2dr[ 22 ].b.h3 ) #define RES1 ( mipscpu.cp2dr[ 23 ].d ) #define MAC0 ( mipscpu.cp2dr[ 24 ].d ) #define MAC1 ( mipscpu.cp2dr[ 25 ].d ) #define MAC2 ( mipscpu.cp2dr[ 26 ].d ) #define MAC3 ( mipscpu.cp2dr[ 27 ].d ) #define IRGB ( mipscpu.cp2dr[ 28 ].d ) #define ORGB ( mipscpu.cp2dr[ 29 ].d ) #define LZCS ( mipscpu.cp2dr[ 30 ].d ) #define LZCR ( mipscpu.cp2dr[ 31 ].d ) #define D1 ( mipscpu.cp2cr[ 0 ].d ) #define R11 ( mipscpu.cp2cr[ 0 ].w.l ) #define R12 ( mipscpu.cp2cr[ 0 ].w.h ) #define R13 ( mipscpu.cp2cr[ 1 ].w.l ) #define R21 ( mipscpu.cp2cr[ 1 ].w.h ) #define D2 ( mipscpu.cp2cr[ 2 ].d ) #define R22 ( mipscpu.cp2cr[ 2 ].w.l ) #define R23 ( mipscpu.cp2cr[ 2 ].w.h ) #define R31 ( mipscpu.cp2cr[ 3 ].w.l ) #define R32 ( mipscpu.cp2cr[ 3 ].w.h ) #define D3 ( mipscpu.cp2cr[ 4 ].d ) #define R33 ( mipscpu.cp2cr[ 4 ].w.l ) #define TRX ( mipscpu.cp2cr[ 5 ].d ) #define TRY ( mipscpu.cp2cr[ 6 ].d ) #define TRZ ( mipscpu.cp2cr[ 7 ].d ) #define L11 ( mipscpu.cp2cr[ 8 ].w.l ) #define L12 ( mipscpu.cp2cr[ 8 ].w.h ) #define L13 ( mipscpu.cp2cr[ 9 ].w.l ) #define L21 ( mipscpu.cp2cr[ 9 ].w.h ) #define L22 ( mipscpu.cp2cr[ 10 ].w.l ) #define L23 ( mipscpu.cp2cr[ 10 ].w.h ) #define L31 ( mipscpu.cp2cr[ 11 ].w.l ) #define L32 ( mipscpu.cp2cr[ 11 ].w.h ) #define L33 ( mipscpu.cp2cr[ 12 ].w.l ) #define RBK ( mipscpu.cp2cr[ 13 ].d ) #define GBK ( mipscpu.cp2cr[ 14 ].d ) #define BBK ( mipscpu.cp2cr[ 15 ].d ) #define LR1 ( mipscpu.cp2cr[ 16 ].w.l ) #define LR2 ( mipscpu.cp2cr[ 16 ].w.h ) #define LR3 ( mipscpu.cp2cr[ 17 ].w.l ) #define LG1 ( mipscpu.cp2cr[ 17 ].w.h ) #define LG2 ( mipscpu.cp2cr[ 18 ].w.l ) #define LG3 ( mipscpu.cp2cr[ 18 ].w.h ) #define LB1 ( mipscpu.cp2cr[ 19 ].w.l ) #define LB2 ( mipscpu.cp2cr[ 19 ].w.h ) #define LB3 ( mipscpu.cp2cr[ 20 ].w.l ) #define RFC ( mipscpu.cp2cr[ 21 ].d ) #define GFC ( mipscpu.cp2cr[ 22 ].d ) #define BFC ( mipscpu.cp2cr[ 23 ].d ) #define OFX ( mipscpu.cp2cr[ 24 ].d ) #define OFY ( mipscpu.cp2cr[ 25 ].d ) #define H ( mipscpu.cp2cr[ 26 ].w.l ) #define DQA ( mipscpu.cp2cr[ 27 ].w.l ) #define DQB ( mipscpu.cp2cr[ 28 ].d ) #define ZSF3 ( mipscpu.cp2cr[ 29 ].w.l ) #define ZSF4 ( mipscpu.cp2cr[ 30 ].w.l ) #define FLAG ( mipscpu.cp2cr[ 31 ].d ) static UINT32 getcp2dr( int n_reg ) { if( n_reg == 1 || n_reg == 3 || n_reg == 5 || n_reg == 8 || n_reg == 9 || n_reg == 10 || n_reg == 11 ) { mipscpu.cp2dr[ n_reg ].d = (INT32)(INT16)mipscpu.cp2dr[ n_reg ].d; } else if( n_reg == 17 || n_reg == 18 || n_reg == 19 ) { mipscpu.cp2dr[ n_reg ].d = (UINT32)(UINT16)mipscpu.cp2dr[ n_reg ].d; } else if( n_reg == 29 ) { ORGB = ( ( IR1 >> 7 ) & 0x1f ) | ( ( IR2 >> 2 ) & 0x3e0 ) | ( ( IR3 << 3 ) & 0x7c00 ); } GTELOG( "get CP2DR%u=%08x", n_reg, mipscpu.cp2dr[ n_reg ].d ); return mipscpu.cp2dr[ n_reg ].d; } static void setcp2dr( int n_reg, UINT32 n_value ) { GTELOG( "set CP2DR%u=%08x", n_reg, n_value ); mipscpu.cp2dr[ n_reg ].d = n_value; if( n_reg == 15 ) { SXY0 = SXY1; SXY1 = SXY2; SXY2 = SXYP; } else if( n_reg == 28 ) { IR1 = ( IRGB & 0x1f ) << 4; IR2 = ( IRGB & 0x3e0 ) >> 1; IR3 = ( IRGB & 0x7c00 ) >> 6; } else if( n_reg == 30 ) { UINT32 n_lzcs = LZCS; UINT32 n_lzcr = 0; if( ( n_lzcs & 0x80000000 ) == 0 ) { n_lzcs = ~n_lzcs; } while( ( n_lzcs & 0x80000000 ) != 0 ) { n_lzcr++; n_lzcs <<= 1; } LZCR = n_lzcr; } } static UINT32 getcp2cr( int n_reg ) { GTELOG( "get CP2CR%u=%08x", n_reg, mipscpu.cp2cr[ n_reg ].d ); return mipscpu.cp2cr[ n_reg ].d; } static void setcp2cr( int n_reg, UINT32 n_value ) { GTELOG( "set CP2CR%u=%08x", n_reg, n_value ); mipscpu.cp2cr[ n_reg ].d = n_value; } INLINE INT32 LIM( INT32 n_value, INT32 n_max, INT32 n_min, UINT32 n_flag ) { if( n_value > n_max ) { FLAG |= n_flag; return n_max; } else if( n_value < n_min ) { FLAG |= n_flag; return n_min; } return n_value; } INLINE INT64 BOUNDS( INT64 n_value, INT64 n_max, int n_maxflag, INT64 n_min, int n_minflag ) { if( n_value > n_max ) { FLAG |= 1 << n_maxflag; } else if( n_value < n_min ) { FLAG |= 1 << n_minflag; } return n_value; } #define A1( a ) BOUNDS( ( a ), 0x7fffffff, 30, -(INT64)0x80000000, 27 ) #define A2( a ) BOUNDS( ( a ), 0x7fffffff, 29, -(INT64)0x80000000, 26 ) #define A3( a ) BOUNDS( ( a ), 0x7fffffff, 28, -(INT64)0x80000000, 25 ) #define Lm_B1( a, l ) LIM( ( a ), 0x7fff, -0x8000 * !l, ( 1 << 31 ) | ( 1 << 24 ) ) #define Lm_B2( a, l ) LIM( ( a ), 0x7fff, -0x8000 * !l, ( 1 << 31 ) | ( 1 << 23 ) ) #define Lm_B3( a, l ) LIM( ( a ), 0x7fff, -0x8000 * !l, ( 1 << 31 ) | ( 1 << 22 ) ) #define Lm_C1( a ) LIM( ( a ), 0x00ff, 0x0000, ( 1 << 21 ) ) #define Lm_C2( a ) LIM( ( a ), 0x00ff, 0x0000, ( 1 << 20 ) ) #define Lm_C3( a ) LIM( ( a ), 0x00ff, 0x0000, ( 1 << 19 ) ) #define Lm_D( a ) LIM( ( a ), 0xffff, 0x0000, ( 1 << 31 ) | ( 1 << 18 ) ) INLINE UINT32 Lm_E( UINT32 n_z ) { if( n_z <= H / 2 ) { n_z = H / 2; FLAG |= ( 1 << 31 ) | ( 1 << 17 ); } if( n_z == 0 ) { n_z = 1; } return n_z; } #define F( a ) BOUNDS( ( a ), 0x7fffffff, ( 1 << 31 ) | ( 1 << 16 ), -(INT64)0x80000000, ( 1 << 31 ) | ( 1 << 15 ) ) #define Lm_G1( a ) LIM( ( a ), 0x3ff, -0x400, ( 1 << 31 ) | ( 1 << 14 ) ) #define Lm_G2( a ) LIM( ( a ), 0x3ff, -0x400, ( 1 << 31 ) | ( 1 << 13 ) ) #define Lm_H( a ) LIM( ( a ), 0xfff, 0x000, ( 1 << 12 ) ) static void docop2( int gteop ) { int n_sf; int n_v; int n_lm; int n_pass; UINT16 n_v1; UINT16 n_v2; UINT16 n_v3; const UINT16 **p_n_mx; const UINT32 **p_n_cv; static const UINT16 n_zm = 0; static const UINT32 n_zc = 0; static const UINT16 *p_n_vx[] = { &VX0, &VX1, &VX2 }; static const UINT16 *p_n_vy[] = { &VY0, &VY1, &VY2 }; static const UINT16 *p_n_vz[] = { &VZ0, &VZ1, &VZ2 }; static const UINT16 *p_n_rm[] = { &R11, &R12, &R13, &R21, &R22, &R23, &R31, &R32, &R33 }; static const UINT16 *p_n_lm[] = { &L11, &L12, &L13, &L21, &L22, &L23, &L31, &L32, &L33 }; static const UINT16 *p_n_cm[] = { &LR1, &LR2, &LR3, &LG1, &LG2, &LG3, &LB1, &LB2, &LB3 }; static const UINT16 *p_n_zm[] = { &n_zm, &n_zm, &n_zm, &n_zm, &n_zm, &n_zm, &n_zm, &n_zm, &n_zm }; static const UINT16 **p_p_n_mx[] = { p_n_rm, p_n_lm, p_n_cm, p_n_zm }; static const UINT32 *p_n_tr[] = { &TRX, &TRY, &TRZ }; static const UINT32 *p_n_bk[] = { &RBK, &GBK, &BBK }; static const UINT32 *p_n_fc[] = { &RFC, &GFC, &BFC }; static const UINT32 *p_n_zc[] = { &n_zc, &n_zc, &n_zc }; static const UINT32 **p_p_n_cv[] = { p_n_tr, p_n_bk, p_n_fc, p_n_zc }; switch( GTE_FUNCT( gteop ) ) { case 0x01: if( gteop == 0x0180001 ) { GTELOG( "RTPS" ); FLAG = 0; MAC1 = A1( ( ( (INT64)(INT32)TRX << 12 ) + ( (INT16)R11 * (INT16)VX0 ) + ( (INT16)R12 * (INT16)VY0 ) + ( (INT16)R13 * (INT16)VZ0 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)(INT32)TRY << 12 ) + ( (INT16)R21 * (INT16)VX0 ) + ( (INT16)R22 * (INT16)VY0 ) + ( (INT16)R23 * (INT16)VZ0 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)(INT32)TRZ << 12 ) + ( (INT16)R31 * (INT16)VX0 ) + ( (INT16)R32 * (INT16)VY0 ) + ( (INT16)R33 * (INT16)VZ0 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 0 ); IR2 = Lm_B2( (INT32)MAC2, 0 ); IR3 = Lm_B3( (INT32)MAC3, 0 ); SZ0 = SZ1; SZ1 = SZ2; SZ2 = SZ3; SZ3 = Lm_D( (INT32)MAC3 ); SXY0 = SXY1; SXY1 = SXY2; SX2 = Lm_G1( F( (INT64)(INT32)OFX + ( (INT64)(INT16)IR1 * ( ( (UINT32)H << 16 ) / Lm_E( SZ3 ) ) ) ) >> 16 ); SY2 = Lm_G2( F( (INT64)(INT32)OFY + ( (INT64)(INT16)IR2 * ( ( (UINT32)H << 16 ) / Lm_E( SZ3 ) ) ) ) >> 16 ); MAC0 = F( (INT64)(INT32)DQB + ( (INT64)(INT16)DQA * ( ( (UINT32)H << 16 ) / Lm_E( SZ3 ) ) ) ); IR0 = Lm_H( (INT32)MAC0 >> 12 ); return; } break; case 0x06: if( gteop == 0x0400006 || gteop == 0x1400006 || gteop == 0x0155cc6 ) { GTELOG( "NCLIP" ); FLAG = 0; MAC0 = F( ( (INT64)(INT16)SX0 * (INT16)SY1 ) + ( (INT16)SX1 * (INT16)SY2 ) + ( (INT16)SX2 * (INT16)SY0 ) - ( (INT16)SX0 * (INT16)SY2 ) - ( (INT16)SX1 * (INT16)SY0 ) - ( (INT16)SX2 * (INT16)SY1 ) ); return; } break; case 0x0c: if( GTE_OP( gteop ) == 0x17 ) { GTELOG( "OP" ); n_sf = 12 * GTE_SF( gteop ); FLAG = 0; MAC1 = A1( ( ( (INT64)(INT32)D2 * (INT16)IR3 ) - ( (INT64)(INT32)D3 * (INT16)IR2 ) ) >> n_sf ); MAC2 = A2( ( ( (INT64)(INT32)D3 * (INT16)IR1 ) - ( (INT64)(INT32)D1 * (INT16)IR3 ) ) >> n_sf ); MAC3 = A3( ( ( (INT64)(INT32)D1 * (INT16)IR2 ) - ( (INT64)(INT32)D2 * (INT16)IR1 ) ) >> n_sf ); IR1 = Lm_B1( (INT32)MAC1, 0 ); IR2 = Lm_B2( (INT32)MAC2, 0 ); IR3 = Lm_B3( (INT32)MAC3, 0 ); return; } break; case 0x10: if( gteop == 0x0780010 ) { GTELOG( "DPCS" ); FLAG = 0; MAC1 = A1( ( ( (INT64)R << 16 ) + ( (INT64)(INT16)IR0 * ( Lm_B1( (INT32)RFC - ( R << 4 ), 0 ) ) ) ) >> 12 ); MAC2 = A2( ( ( (INT64)G << 16 ) + ( (INT64)(INT16)IR0 * ( Lm_B1( (INT32)GFC - ( G << 4 ), 0 ) ) ) ) >> 12 ); MAC3 = A3( ( ( (INT64)B << 16 ) + ( (INT64)(INT16)IR0 * ( Lm_B1( (INT32)BFC - ( B << 4 ), 0 ) ) ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 0 ); IR2 = Lm_B2( (INT32)MAC2, 0 ); IR3 = Lm_B3( (INT32)MAC3, 0 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); return; } break; case 0x11: if( gteop == 0x0980011 ) { GTELOG( "INTPL" ); FLAG = 0; MAC1 = A1( ( ( (INT64)(INT16)IR1 << 12 ) + ( (INT64)(INT16)IR0 * ( Lm_B1( (INT32)RFC - (INT16)IR1, 0 ) ) ) ) >> 12 ); MAC2 = A2( ( ( (INT64)(INT16)IR2 << 12 ) + ( (INT64)(INT16)IR0 * ( Lm_B1( (INT32)GFC - (INT16)IR2, 0 ) ) ) ) >> 12 ); MAC3 = A3( ( ( (INT64)(INT16)IR3 << 12 ) + ( (INT64)(INT16)IR0 * ( Lm_B1( (INT32)BFC - (INT16)IR3, 0 ) ) ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 0 ); IR2 = Lm_B2( (INT32)MAC2, 0 ); IR3 = Lm_B3( (INT32)MAC3, 0 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 ); return; } break; case 0x12: if( GTE_OP( gteop ) == 0x04 ) { GTELOG( "MVMVA" ); n_sf = 12 * GTE_SF( gteop ); p_n_mx = p_p_n_mx[ GTE_MX( gteop ) ]; n_v = GTE_V( gteop ); if( n_v < 3 ) { n_v1 = *p_n_vx[ n_v ]; n_v2 = *p_n_vy[ n_v ]; n_v3 = *p_n_vz[ n_v ]; } else { n_v1 = IR1; n_v2 = IR2; n_v3 = IR3; } p_n_cv = p_p_n_cv[ GTE_CV( gteop ) ]; n_lm = GTE_LM( gteop ); FLAG = 0; MAC1 = A1( ( ( (INT64)(INT32)*p_n_cv[ 0 ] << 12 ) + ( (INT16)*p_n_mx[ 0 ] * (INT16)n_v1 ) + ( (INT16)*p_n_mx[ 1 ] * (INT16)n_v2 ) + ( (INT16)*p_n_mx[ 2 ] * (INT16)n_v3 ) ) >> n_sf ); MAC2 = A2( ( ( (INT64)(INT32)*p_n_cv[ 1 ] << 12 ) + ( (INT16)*p_n_mx[ 3 ] * (INT16)n_v1 ) + ( (INT16)*p_n_mx[ 4 ] * (INT16)n_v2 ) + ( (INT16)*p_n_mx[ 5 ] * (INT16)n_v3 ) ) >> n_sf ); MAC3 = A3( ( ( (INT64)(INT32)*p_n_cv[ 2 ] << 12 ) + ( (INT16)*p_n_mx[ 6 ] * (INT16)n_v1 ) + ( (INT16)*p_n_mx[ 7 ] * (INT16)n_v2 ) + ( (INT16)*p_n_mx[ 8 ] * (INT16)n_v3 ) ) >> n_sf ); IR1 = Lm_B1( (INT32)MAC1, n_lm ); IR2 = Lm_B2( (INT32)MAC2, n_lm ); IR3 = Lm_B3( (INT32)MAC3, n_lm ); return; } break; case 0x13: if( gteop == 0x0e80413 ) { GTELOG( "NCDS" ); FLAG = 0; MAC1 = A1( ( ( (INT64)(INT16)L11 * (INT16)VX0 ) + ( (INT16)L12 * (INT16)VY0 ) + ( (INT16)L13 * (INT16)VZ0 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)(INT16)L21 * (INT16)VX0 ) + ( (INT16)L22 * (INT16)VY0 ) + ( (INT16)L23 * (INT16)VZ0 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)(INT16)L31 * (INT16)VX0 ) + ( (INT16)L32 * (INT16)VY0 ) + ( (INT16)L33 * (INT16)VZ0 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( ( (INT64)RBK << 12 ) + ( (INT16)LR1 * (INT16)IR1 ) + ( (INT16)LR2 * (INT16)IR2 ) + ( (INT16)LR3 * (INT16)IR3 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)GBK << 12 ) + ( (INT16)LG1 * (INT16)IR1 ) + ( (INT16)LG2 * (INT16)IR2 ) + ( (INT16)LG3 * (INT16)IR3 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)BBK << 12 ) + ( (INT16)LB1 * (INT16)IR1 ) + ( (INT16)LB2 * (INT16)IR2 ) + ( (INT16)LB3 * (INT16)IR3 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( ( ( (INT64)R << 4 ) * (INT16)IR1 ) + ( (INT16)IR0 * Lm_B1( (INT32)RFC - ( ( R * (INT16)IR1 ) >> 8 ), 0 ) ) ) >> 12 ); MAC2 = A2( ( ( ( (INT64)G << 4 ) * (INT16)IR2 ) + ( (INT16)IR0 * Lm_B2( (INT32)GFC - ( ( G * (INT16)IR2 ) >> 8 ), 0 ) ) ) >> 12 ); MAC3 = A3( ( ( ( (INT64)B << 4 ) * (INT16)IR3 ) + ( (INT16)IR0 * Lm_B3( (INT32)BFC - ( ( B * (INT16)IR3 ) >> 8 ), 0 ) ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); return; } break; case 0x14: if( gteop == 0x1280414 ) { GTELOG( "CDP" ); FLAG = 0; MAC1 = A1( ( ( (INT64)RBK << 12 ) + ( (INT16)LR1 * (INT16)IR1 ) + ( (INT16)LR2 * (INT16)IR2 ) + ( (INT16)LR3 * (INT16)IR3 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)GBK << 12 ) + ( (INT16)LG1 * (INT16)IR1 ) + ( (INT16)LG2 * (INT16)IR2 ) + ( (INT16)LG3 * (INT16)IR3 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)BBK << 12 ) + ( (INT16)LB1 * (INT16)IR1 ) + ( (INT16)LB2 * (INT16)IR2 ) + ( (INT16)LB3 * (INT16)IR3 ) ) >> 12 ); IR1 = Lm_B1( MAC1, 1 ); IR2 = Lm_B2( MAC2, 1 ); IR3 = Lm_B3( MAC3, 1 ); MAC1 = A1( ( ( ( (INT64)R << 4 ) * (INT16)IR1 ) + ( (INT16)IR0 * Lm_B1( (INT32)RFC - ( ( R * (INT16)IR1 ) >> 8 ), 0 ) ) ) >> 12 ); MAC2 = A2( ( ( ( (INT64)G << 4 ) * (INT16)IR2 ) + ( (INT16)IR0 * Lm_B2( (INT32)GFC - ( ( G * (INT16)IR2 ) >> 8 ), 0 ) ) ) >> 12 ); MAC3 = A3( ( ( ( (INT64)B << 4 ) * (INT16)IR3 ) + ( (INT16)IR0 * Lm_B3( (INT32)BFC - ( ( B * (INT16)IR3 ) >> 8 ), 0 ) ) ) >> 12 ); IR1 = Lm_B1( MAC1, 1 ); IR2 = Lm_B2( MAC2, 1 ); IR3 = Lm_B3( MAC3, 1 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); return; } break; case 0x16: if( gteop == 0x0f80416 ) { GTELOG( "NCDT" ); FLAG = 0; for( n_v = 0; n_v < 3; n_v++ ) { MAC1 = A1( ( ( (INT64)(INT16)L11 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)L12 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)L13 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); MAC2 = A2( ( ( (INT64)(INT16)L21 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)L22 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)L23 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); MAC3 = A3( ( ( (INT64)(INT16)L31 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)L32 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)L33 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( ( (INT64)RBK << 12 ) + ( (INT16)LR1 * (INT16)IR1 ) + ( (INT16)LR2 * (INT16)IR2 ) + ( (INT16)LR3 * (INT16)IR3 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)GBK << 12 ) + ( (INT16)LG1 * (INT16)IR1 ) + ( (INT16)LG2 * (INT16)IR2 ) + ( (INT16)LG3 * (INT16)IR3 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)BBK << 12 ) + ( (INT16)LB1 * (INT16)IR1 ) + ( (INT16)LB2 * (INT16)IR2 ) + ( (INT16)LB3 * (INT16)IR3 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( ( ( (INT64)R << 4 ) * (INT16)IR1 ) + ( (INT16)IR0 * Lm_B1( (INT32)RFC - ( ( R * (INT16)IR1 ) >> 8 ), 0 ) ) ) >> 12 ); MAC2 = A2( ( ( ( (INT64)G << 4 ) * (INT16)IR2 ) + ( (INT16)IR0 * Lm_B2( (INT32)GFC - ( ( G * (INT16)IR2 ) >> 8 ), 0 ) ) ) >> 12 ); MAC3 = A3( ( ( ( (INT64)B << 4 ) * (INT16)IR3 ) + ( (INT16)IR0 * Lm_B3( (INT32)BFC - ( ( B * (INT16)IR3 ) >> 8 ), 0 ) ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); } return; } break; case 0x1b: if( gteop == 0x108041b ) { GTELOG( "NCCS" ); FLAG = 0; MAC1 = A1( ( ( (INT64)(INT16)L11 * (INT16)VX0 ) + ( (INT16)L12 * (INT16)VY0 ) + ( (INT16)L13 * (INT16)VZ0 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)(INT16)L21 * (INT16)VX0 ) + ( (INT16)L22 * (INT16)VY0 ) + ( (INT16)L23 * (INT16)VZ0 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)(INT16)L31 * (INT16)VX0 ) + ( (INT16)L32 * (INT16)VY0 ) + ( (INT16)L33 * (INT16)VZ0 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( ( (INT64)RBK << 12 ) + ( (INT16)LR1 * (INT16)IR1 ) + ( (INT16)LR2 * (INT16)IR2 ) + ( (INT16)LR3 * (INT16)IR3 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)GBK << 12 ) + ( (INT16)LG1 * (INT16)IR1 ) + ( (INT16)LG2 * (INT16)IR2 ) + ( (INT16)LG3 * (INT16)IR3 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)BBK << 12 ) + ( (INT16)LB1 * (INT16)IR1 ) + ( (INT16)LB2 * (INT16)IR2 ) + ( (INT16)LB3 * (INT16)IR3 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( (INT64)R * (INT16)IR1 ) >> 8 ); MAC2 = A2( ( (INT64)G * (INT16)IR2 ) >> 8 ); MAC3 = A3( ( (INT64)B * (INT16)IR3 ) >> 8 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); return; } break; case 0x1c: if( gteop == 0x138041c ) { GTELOG( "CC" ); FLAG = 0; MAC1 = A1( ( ( (INT64)RBK << 12 ) + ( (INT16)LR1 * (INT16)IR1 ) + ( (INT16)LR2 * (INT16)IR2 ) + ( (INT16)LR3 * (INT16)IR3 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)GBK << 12 ) + ( (INT16)LG1 * (INT16)IR1 ) + ( (INT16)LG2 * (INT16)IR2 ) + ( (INT16)LG3 * (INT16)IR3 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)BBK << 12 ) + ( (INT16)LB1 * (INT16)IR1 ) + ( (INT16)LB2 * (INT16)IR2 ) + ( (INT16)LB3 * (INT16)IR3 ) ) >> 12 ); IR1 = Lm_B1( MAC1, 1 ); IR2 = Lm_B2( MAC2, 1 ); IR3 = Lm_B3( MAC3, 1 ); MAC1 = A1( ( (INT64)R * (INT16)IR1 ) >> 8 ); MAC2 = A2( ( (INT64)G * (INT16)IR2 ) >> 8 ); MAC3 = A3( ( (INT64)B * (INT16)IR3 ) >> 8 ); IR1 = Lm_B1( MAC1, 1 ); IR2 = Lm_B2( MAC2, 1 ); IR3 = Lm_B3( MAC3, 1 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); return; } break; case 0x1e: if( gteop == 0x0c8041e ) { GTELOG( "NCS" ); FLAG = 0; MAC1 = A1( ( ( (INT64)(INT16)L11 * (INT16)VX0 ) + ( (INT16)L12 * (INT16)VY0 ) + ( (INT16)L13 * (INT16)VZ0 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)(INT16)L21 * (INT16)VX0 ) + ( (INT16)L22 * (INT16)VY0 ) + ( (INT16)L23 * (INT16)VZ0 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)(INT16)L31 * (INT16)VX0 ) + ( (INT16)L32 * (INT16)VY0 ) + ( (INT16)L33 * (INT16)VZ0 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( ( (INT64)RBK << 12 ) + ( (INT16)LR1 * (INT16)IR1 ) + ( (INT16)LR2 * (INT16)IR2 ) + ( (INT16)LR3 * (INT16)IR3 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)GBK << 12 ) + ( (INT16)LG1 * (INT16)IR1 ) + ( (INT16)LG2 * (INT16)IR2 ) + ( (INT16)LG3 * (INT16)IR3 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)BBK << 12 ) + ( (INT16)LB1 * (INT16)IR1 ) + ( (INT16)LB2 * (INT16)IR2 ) + ( (INT16)LB3 * (INT16)IR3 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); return; } break; case 0x20: if( gteop == 0x0d80420 ) { GTELOG( "NCT" ); FLAG = 0; for( n_v = 0; n_v < 3; n_v++ ) { MAC1 = A1( ( ( (INT64)(INT16)L11 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)L12 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)L13 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); MAC2 = A2( ( ( (INT64)(INT16)L21 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)L22 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)L23 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); MAC3 = A3( ( ( (INT64)(INT16)L31 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)L32 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)L33 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( ( (INT64)RBK << 12 ) + ( (INT16)LR1 * (INT16)IR1 ) + ( (INT16)LR2 * (INT16)IR2 ) + ( (INT16)LR3 * (INT16)IR3 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)GBK << 12 ) + ( (INT16)LG1 * (INT16)IR1 ) + ( (INT16)LG2 * (INT16)IR2 ) + ( (INT16)LG3 * (INT16)IR3 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)BBK << 12 ) + ( (INT16)LB1 * (INT16)IR1 ) + ( (INT16)LB2 * (INT16)IR2 ) + ( (INT16)LB3 * (INT16)IR3 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); } return; } break; case 0x28: if( GTE_OP( gteop ) == 0x0a && GTE_LM( gteop ) == 1 ) { GTELOG( "SQR" ); n_sf = 12 * GTE_SF( gteop ); FLAG = 0; MAC1 = A1( ( (INT64)(INT16)IR1 * (INT16)IR1 ) >> n_sf ); MAC2 = A2( ( (INT64)(INT16)IR2 * (INT16)IR2 ) >> n_sf ); MAC3 = A3( ( (INT64)(INT16)IR3 * (INT16)IR3 ) >> n_sf ); IR1 = Lm_B1( MAC1, 1 ); IR2 = Lm_B2( MAC2, 1 ); IR3 = Lm_B3( MAC3, 1 ); return; } break; // DCPL 0x29 case 0x2a: if( gteop == 0x0f8002a ) { GTELOG( "DPCT" ); FLAG = 0; for( n_pass = 0; n_pass < 3; n_pass++ ) { MAC1 = A1( ( ( (INT64)R0 << 16 ) + ( (INT64)(INT16)IR0 * ( Lm_B1( (INT32)RFC - ( R0 << 4 ), 0 ) ) ) ) >> 12 ); MAC2 = A2( ( ( (INT64)G0 << 16 ) + ( (INT64)(INT16)IR0 * ( Lm_B1( (INT32)GFC - ( G0 << 4 ), 0 ) ) ) ) >> 12 ); MAC3 = A3( ( ( (INT64)B0 << 16 ) + ( (INT64)(INT16)IR0 * ( Lm_B1( (INT32)BFC - ( B0 << 4 ), 0 ) ) ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 0 ); IR2 = Lm_B2( (INT32)MAC2, 0 ); IR3 = Lm_B3( (INT32)MAC3, 0 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); } return; } break; case 0x2d: if( gteop == 0x158002d ) { GTELOG( "AVSZ3" ); FLAG = 0; MAC0 = F( ( (INT64)(INT16)ZSF3 * SZ1 ) + ( (INT16)ZSF3 * SZ2 ) + ( (INT16)ZSF3 * SZ3 ) ); OTZ = Lm_D( (INT32)MAC0 >> 12 ); return; } break; case 0x2e: if( gteop == 0x168002e ) { GTELOG( "AVSZ4" ); FLAG = 0; MAC0 = F( ( (INT64)(INT16)ZSF4 * SZ0 ) + ( (INT16)ZSF4 * SZ1 ) + ( (INT16)ZSF4 * SZ2 ) + ( (INT16)ZSF4 * SZ3 ) ); OTZ = Lm_D( (INT32)MAC0 >> 12 ); return; } break; case 0x30: if( gteop == 0x0280030 ) { GTELOG( "RTPT" ); FLAG = 0; for( n_v = 0; n_v < 3; n_v++ ) { MAC1 = A1( ( ( (INT64)(INT32)TRX << 12 ) + ( (INT16)R11 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)R12 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)R13 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); MAC2 = A2( ( ( (INT64)(INT32)TRY << 12 ) + ( (INT16)R21 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)R22 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)R23 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); MAC3 = A3( ( ( (INT64)(INT32)TRZ << 12 ) + ( (INT16)R31 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)R32 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)R33 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 0 ); IR2 = Lm_B2( (INT32)MAC2, 0 ); IR3 = Lm_B3( (INT32)MAC3, 0 ); SZ0 = SZ1; SZ1 = SZ2; SZ2 = SZ3; SZ3 = Lm_D( (INT32)MAC3 ); SXY0 = SXY1; SXY1 = SXY2; SX2 = Lm_G1( F( ( (INT64)(INT32)OFX + ( (INT64)(INT16)IR1 * ( ( (UINT32)H << 16 ) / Lm_E( SZ3 ) ) ) ) >> 16 ) ); SY2 = Lm_G2( F( ( (INT64)(INT32)OFY + ( (INT64)(INT16)IR2 * ( ( (UINT32)H << 16 ) / Lm_E( SZ3 ) ) ) ) >> 16 ) ); MAC0 = F( (INT64)(INT32)DQB + ( (INT64)(INT16)DQA * ( ( (UINT32)H << 16 ) / Lm_E( SZ3 ) ) ) ); IR0 = Lm_H( (INT32)MAC0 >> 12 ); } return; } break; case 0x3d: if( GTE_OP( gteop ) == 0x09 || GTE_OP( gteop ) == 0x19 ) { GTELOG( "GPF" ); n_sf = 12 * GTE_SF( gteop ); FLAG = 0; MAC1 = A1( ( (INT64)(INT16)IR0 * (INT16)IR1 ) >> n_sf ); MAC2 = A2( ( (INT64)(INT16)IR0 * (INT16)IR2 ) >> n_sf ); MAC3 = A3( ( (INT64)(INT16)IR0 * (INT16)IR3 ) >> n_sf ); IR1 = Lm_B1( (INT32)MAC1, 0 ); IR2 = Lm_B2( (INT32)MAC2, 0 ); IR3 = Lm_B3( (INT32)MAC3, 0 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); return; } break; case 0x3e: if( GTE_OP( gteop ) == 0x1a ) { GTELOG( "GPL" ); n_sf = 12 * GTE_SF( gteop ); FLAG = 0; MAC1 = A1( ( ( (INT64)(INT32)MAC1 << n_sf ) + ( (INT16)IR0 * (INT16)IR1 ) ) >> n_sf ); MAC2 = A2( ( ( (INT64)(INT32)MAC2 << n_sf ) + ( (INT16)IR0 * (INT16)IR2 ) ) >> n_sf ); MAC3 = A3( ( ( (INT64)(INT32)MAC3 << n_sf ) + ( (INT16)IR0 * (INT16)IR3 ) ) >> n_sf ); IR1 = Lm_B1( (INT32)MAC1, 0 ); IR2 = Lm_B2( (INT32)MAC2, 0 ); IR3 = Lm_B3( (INT32)MAC3, 0 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); return; } break; case 0x3f: if( gteop == 0x108043f || gteop == 0x118043f ) { GTELOG( "NCCT" ); FLAG = 0; for( n_v = 0; n_v < 3; n_v++ ) { MAC1 = A1( ( ( (INT64)(INT16)L11 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)L12 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)L13 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); MAC2 = A2( ( ( (INT64)(INT16)L21 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)L22 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)L23 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); MAC3 = A3( ( ( (INT64)(INT16)L31 * (INT16)*p_n_vx[ n_v ] ) + ( (INT16)L32 * (INT16)*p_n_vy[ n_v ] ) + ( (INT16)L33 * (INT16)*p_n_vz[ n_v ] ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( ( (INT64)RBK << 12 ) + ( (INT16)LR1 * (INT16)IR1 ) + ( (INT16)LR2 * (INT16)IR2 ) + ( (INT16)LR3 * (INT16)IR3 ) ) >> 12 ); MAC2 = A2( ( ( (INT64)GBK << 12 ) + ( (INT16)LG1 * (INT16)IR1 ) + ( (INT16)LG2 * (INT16)IR2 ) + ( (INT16)LG3 * (INT16)IR3 ) ) >> 12 ); MAC3 = A3( ( ( (INT64)BBK << 12 ) + ( (INT16)LB1 * (INT16)IR1 ) + ( (INT16)LB2 * (INT16)IR2 ) + ( (INT16)LB3 * (INT16)IR3 ) ) >> 12 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); MAC1 = A1( ( (INT64)R * (INT16)IR1 ) >> 8 ); MAC2 = A2( ( (INT64)G * (INT16)IR2 ) >> 8 ); MAC3 = A3( ( (INT64)B * (INT16)IR3 ) >> 8 ); IR1 = Lm_B1( (INT32)MAC1, 1 ); IR2 = Lm_B2( (INT32)MAC2, 1 ); IR3 = Lm_B3( (INT32)MAC3, 1 ); CD0 = CD1; CD1 = CD2; CD2 = CODE; R0 = R1; R1 = R2; R2 = Lm_C1( (INT32)MAC1 >> 4 ); G0 = G1; G1 = G2; G2 = Lm_C2( (INT32)MAC2 >> 4 ); B0 = B1; B1 = B2; B2 = Lm_C3( (INT32)MAC3 >> 4 ); } return; } break; } ui_popup_time( 1, "unknown GTE op %08x", gteop ); logerror( "%08x: unknown GTE op %08x\n", mipscpu.pc, gteop ); mips_stop(); } /************************************************************************** * Generic set_info **************************************************************************/ static void mips_set_info(UINT32 state, cpuinfo *info) { switch (state) { /* --- the following bits of info are set as 64-bit signed integers --- */ case CPUINFO_INT_INPUT_STATE + MIPS_IRQ0: set_irq_line(MIPS_IRQ0, info->i); break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ1: set_irq_line(MIPS_IRQ1, info->i); break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ2: set_irq_line(MIPS_IRQ2, info->i); break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ3: set_irq_line(MIPS_IRQ3, info->i); break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ4: set_irq_line(MIPS_IRQ4, info->i); break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ5: set_irq_line(MIPS_IRQ5, info->i); break; case CPUINFO_INT_PC: mips_set_pc( info->i ); break; case CPUINFO_INT_REGISTER + MIPS_PC: mips_set_pc( info->i ); break; case CPUINFO_INT_SP: /* no stack */ break; case CPUINFO_INT_REGISTER + MIPS_DELAYV: mipscpu.delayv = info->i; break; case CPUINFO_INT_REGISTER + MIPS_DELAYR: if( info->i <= REGPC ) mipscpu.delayr = info->i; break; case CPUINFO_INT_REGISTER + MIPS_HI: mipscpu.hi = info->i; break; case CPUINFO_INT_REGISTER + MIPS_LO: mipscpu.lo = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R0: mipscpu.r[ 0 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R1: mipscpu.r[ 1 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R2: mipscpu.r[ 2 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R3: mipscpu.r[ 3 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R4: mipscpu.r[ 4 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R5: mipscpu.r[ 5 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R6: mipscpu.r[ 6 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R7: mipscpu.r[ 7 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R8: mipscpu.r[ 8 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R9: mipscpu.r[ 9 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R10: mipscpu.r[ 10 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R11: mipscpu.r[ 11 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R12: mipscpu.r[ 12 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R13: mipscpu.r[ 13 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R14: mipscpu.r[ 14 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R15: mipscpu.r[ 15 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R16: mipscpu.r[ 16 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R17: mipscpu.r[ 17 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R18: mipscpu.r[ 18 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R19: mipscpu.r[ 19 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R20: mipscpu.r[ 20 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R21: mipscpu.r[ 21 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R22: mipscpu.r[ 22 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R23: mipscpu.r[ 23 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R24: mipscpu.r[ 24 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R25: mipscpu.r[ 25 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R26: mipscpu.r[ 26 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R27: mipscpu.r[ 27 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R28: mipscpu.r[ 28 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R29: mipscpu.r[ 29 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R30: mipscpu.r[ 30 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_R31: mipscpu.r[ 31 ] = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP0R0: mips_set_cp0r( 0, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R1: mips_set_cp0r( 1, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R2: mips_set_cp0r( 2, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R3: mips_set_cp0r( 3, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R4: mips_set_cp0r( 4, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R5: mips_set_cp0r( 5, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R6: mips_set_cp0r( 6, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R7: mips_set_cp0r( 7, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R8: mips_set_cp0r( 8, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R9: mips_set_cp0r( 9, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R10: mips_set_cp0r( 10, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R11: mips_set_cp0r( 11, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R12: mips_set_cp0r( 12, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R13: mips_set_cp0r( 13, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R14: mips_set_cp0r( 14, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R15: mips_set_cp0r( 15, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R16: mips_set_cp0r( 16, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R17: mips_set_cp0r( 17, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R18: mips_set_cp0r( 18, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R19: mips_set_cp0r( 19, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R20: mips_set_cp0r( 20, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R21: mips_set_cp0r( 21, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R22: mips_set_cp0r( 22, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R23: mips_set_cp0r( 23, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R24: mips_set_cp0r( 24, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R25: mips_set_cp0r( 25, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R26: mips_set_cp0r( 26, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R27: mips_set_cp0r( 27, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R28: mips_set_cp0r( 28, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R29: mips_set_cp0r( 29, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R30: mips_set_cp0r( 30, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP0R31: mips_set_cp0r( 31, info->i ); break; case CPUINFO_INT_REGISTER + MIPS_CP2DR0: mipscpu.cp2dr[ 0 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR1: mipscpu.cp2dr[ 1 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR2: mipscpu.cp2dr[ 2 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR3: mipscpu.cp2dr[ 3 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR4: mipscpu.cp2dr[ 4 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR5: mipscpu.cp2dr[ 5 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR6: mipscpu.cp2dr[ 6 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR7: mipscpu.cp2dr[ 7 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR8: mipscpu.cp2dr[ 8 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR9: mipscpu.cp2dr[ 9 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR10: mipscpu.cp2dr[ 10 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR11: mipscpu.cp2dr[ 11 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR12: mipscpu.cp2dr[ 12 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR13: mipscpu.cp2dr[ 13 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR14: mipscpu.cp2dr[ 14 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR15: mipscpu.cp2dr[ 15 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR16: mipscpu.cp2dr[ 16 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR17: mipscpu.cp2dr[ 17 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR18: mipscpu.cp2dr[ 18 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR19: mipscpu.cp2dr[ 19 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR20: mipscpu.cp2dr[ 20 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR21: mipscpu.cp2dr[ 21 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR22: mipscpu.cp2dr[ 22 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR23: mipscpu.cp2dr[ 23 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR24: mipscpu.cp2dr[ 24 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR25: mipscpu.cp2dr[ 25 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR26: mipscpu.cp2dr[ 26 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR27: mipscpu.cp2dr[ 27 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR28: mipscpu.cp2dr[ 28 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR29: mipscpu.cp2dr[ 29 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR30: mipscpu.cp2dr[ 30 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR31: mipscpu.cp2dr[ 31 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR0: mipscpu.cp2cr[ 0 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR1: mipscpu.cp2cr[ 1 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR2: mipscpu.cp2cr[ 2 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR3: mipscpu.cp2cr[ 3 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR4: mipscpu.cp2cr[ 4 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR5: mipscpu.cp2cr[ 5 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR6: mipscpu.cp2cr[ 6 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR7: mipscpu.cp2cr[ 7 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR8: mipscpu.cp2cr[ 8 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR9: mipscpu.cp2cr[ 9 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR10: mipscpu.cp2cr[ 10 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR11: mipscpu.cp2cr[ 11 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR12: mipscpu.cp2cr[ 12 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR13: mipscpu.cp2cr[ 13 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR14: mipscpu.cp2cr[ 14 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR15: mipscpu.cp2cr[ 15 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR16: mipscpu.cp2cr[ 16 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR17: mipscpu.cp2cr[ 17 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR18: mipscpu.cp2cr[ 18 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR19: mipscpu.cp2cr[ 19 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR20: mipscpu.cp2cr[ 20 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR21: mipscpu.cp2cr[ 21 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR22: mipscpu.cp2cr[ 22 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR23: mipscpu.cp2cr[ 23 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR24: mipscpu.cp2cr[ 24 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR25: mipscpu.cp2cr[ 25 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR26: mipscpu.cp2cr[ 26 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR27: mipscpu.cp2cr[ 27 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR28: mipscpu.cp2cr[ 28 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR29: mipscpu.cp2cr[ 29 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR30: mipscpu.cp2cr[ 30 ].d = info->i; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR31: mipscpu.cp2cr[ 31 ].d = info->i; break; } } /************************************************************************** * Generic get_info **************************************************************************/ static void mips_get_info(UINT32 state, cpuinfo *info) { switch (state) { /* --- the following bits of info are returned as 64-bit signed integers --- */ case CPUINFO_INT_CONTEXT_SIZE: info->i = sizeof(mipscpu); break; case CPUINFO_INT_INPUT_LINES: info->i = 6; break; case CPUINFO_INT_DEFAULT_IRQ_VECTOR: info->i = 0; break; case CPUINFO_INT_ENDIANNESS: info->i = CPU_IS_LE; break; case CPUINFO_INT_CLOCK_DIVIDER: info->i = 1; break; case CPUINFO_INT_MIN_INSTRUCTION_BYTES: info->i = 4; break; case CPUINFO_INT_MAX_INSTRUCTION_BYTES: info->i = 4; break; case CPUINFO_INT_MIN_CYCLES: info->i = 1; break; case CPUINFO_INT_MAX_CYCLES: info->i = 40; break; case CPUINFO_INT_DATABUS_WIDTH + ADDRESS_SPACE_PROGRAM: info->i = 32; break; case CPUINFO_INT_ADDRBUS_WIDTH + ADDRESS_SPACE_PROGRAM: info->i = 32; break; case CPUINFO_INT_ADDRBUS_SHIFT + ADDRESS_SPACE_PROGRAM: info->i = 0; break; case CPUINFO_INT_DATABUS_WIDTH + ADDRESS_SPACE_DATA: info->i = 0; break; case CPUINFO_INT_ADDRBUS_WIDTH + ADDRESS_SPACE_DATA: info->i = 0; break; case CPUINFO_INT_ADDRBUS_SHIFT + ADDRESS_SPACE_DATA: info->i = 0; break; case CPUINFO_INT_DATABUS_WIDTH + ADDRESS_SPACE_IO: info->i = 0; break; case CPUINFO_INT_ADDRBUS_WIDTH + ADDRESS_SPACE_IO: info->i = 0; break; case CPUINFO_INT_ADDRBUS_SHIFT + ADDRESS_SPACE_IO: info->i = 0; break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ0: info->i = (mipscpu.cp0r[ CP0_CAUSE ] & 0x400) ? ASSERT_LINE : CLEAR_LINE; break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ1: info->i = (mipscpu.cp0r[ CP0_CAUSE ] & 0x800) ? ASSERT_LINE : CLEAR_LINE; break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ2: info->i = (mipscpu.cp0r[ CP0_CAUSE ] & 0x1000) ? ASSERT_LINE : CLEAR_LINE; break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ3: info->i = (mipscpu.cp0r[ CP0_CAUSE ] & 0x2000) ? ASSERT_LINE : CLEAR_LINE; break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ4: info->i = (mipscpu.cp0r[ CP0_CAUSE ] & 0x4000) ? ASSERT_LINE : CLEAR_LINE; break; case CPUINFO_INT_INPUT_STATE + MIPS_IRQ5: info->i = (mipscpu.cp0r[ CP0_CAUSE ] & 0x8000) ? ASSERT_LINE : CLEAR_LINE; break; case CPUINFO_INT_PREVIOUSPC: /* not implemented */ break; case CPUINFO_INT_PC: info->i = mipscpu.pc; break; case CPUINFO_INT_REGISTER + MIPS_PC: info->i = mipscpu.pc; break; case CPUINFO_INT_SP: /* because there is no hardware stack and the pipeline causes the cpu to execute the instruction after a subroutine call before the subroutine is executed there is little chance of cmd_step_over() in mamedbg.c working. */ info->i = 0; break; case CPUINFO_INT_REGISTER + MIPS_DELAYV: info->i = mipscpu.delayv; break; case CPUINFO_INT_REGISTER + MIPS_DELAYR: info->i = mipscpu.delayr; break; case CPUINFO_INT_REGISTER + MIPS_HI: info->i = mipscpu.hi; break; case CPUINFO_INT_REGISTER + MIPS_LO: info->i = mipscpu.lo; break; case CPUINFO_INT_REGISTER + MIPS_R0: info->i = mipscpu.r[ 0 ]; break; case CPUINFO_INT_REGISTER + MIPS_R1: info->i = mipscpu.r[ 1 ]; break; case CPUINFO_INT_REGISTER + MIPS_R2: info->i = mipscpu.r[ 2 ]; break; case CPUINFO_INT_REGISTER + MIPS_R3: info->i = mipscpu.r[ 3 ]; break; case CPUINFO_INT_REGISTER + MIPS_R4: info->i = mipscpu.r[ 4 ]; break; case CPUINFO_INT_REGISTER + MIPS_R5: info->i = mipscpu.r[ 5 ]; break; case CPUINFO_INT_REGISTER + MIPS_R6: info->i = mipscpu.r[ 6 ]; break; case CPUINFO_INT_REGISTER + MIPS_R7: info->i = mipscpu.r[ 7 ]; break; case CPUINFO_INT_REGISTER + MIPS_R8: info->i = mipscpu.r[ 8 ]; break; case CPUINFO_INT_REGISTER + MIPS_R9: info->i = mipscpu.r[ 9 ]; break; case CPUINFO_INT_REGISTER + MIPS_R10: info->i = mipscpu.r[ 10 ]; break; case CPUINFO_INT_REGISTER + MIPS_R11: info->i = mipscpu.r[ 11 ]; break; case CPUINFO_INT_REGISTER + MIPS_R12: info->i = mipscpu.r[ 12 ]; break; case CPUINFO_INT_REGISTER + MIPS_R13: info->i = mipscpu.r[ 13 ]; break; case CPUINFO_INT_REGISTER + MIPS_R14: info->i = mipscpu.r[ 14 ]; break; case CPUINFO_INT_REGISTER + MIPS_R15: info->i = mipscpu.r[ 15 ]; break; case CPUINFO_INT_REGISTER + MIPS_R16: info->i = mipscpu.r[ 16 ]; break; case CPUINFO_INT_REGISTER + MIPS_R17: info->i = mipscpu.r[ 17 ]; break; case CPUINFO_INT_REGISTER + MIPS_R18: info->i = mipscpu.r[ 18 ]; break; case CPUINFO_INT_REGISTER + MIPS_R19: info->i = mipscpu.r[ 19 ]; break; case CPUINFO_INT_REGISTER + MIPS_R20: info->i = mipscpu.r[ 20 ]; break; case CPUINFO_INT_REGISTER + MIPS_R21: info->i = mipscpu.r[ 21 ]; break; case CPUINFO_INT_REGISTER + MIPS_R22: info->i = mipscpu.r[ 22 ]; break; case CPUINFO_INT_REGISTER + MIPS_R23: info->i = mipscpu.r[ 23 ]; break; case CPUINFO_INT_REGISTER + MIPS_R24: info->i = mipscpu.r[ 24 ]; break; case CPUINFO_INT_REGISTER + MIPS_R25: info->i = mipscpu.r[ 25 ]; break; case CPUINFO_INT_REGISTER + MIPS_R26: info->i = mipscpu.r[ 26 ]; break; case CPUINFO_INT_REGISTER + MIPS_R27: info->i = mipscpu.r[ 27 ]; break; case CPUINFO_INT_REGISTER + MIPS_R28: info->i = mipscpu.r[ 28 ]; break; case CPUINFO_INT_REGISTER + MIPS_R29: info->i = mipscpu.r[ 29 ]; break; case CPUINFO_INT_REGISTER + MIPS_R30: info->i = mipscpu.r[ 30 ]; break; case CPUINFO_INT_REGISTER + MIPS_R31: info->i = mipscpu.r[ 31 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R0: info->i = mipscpu.cp0r[ 0 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R1: info->i = mipscpu.cp0r[ 1 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R2: info->i = mipscpu.cp0r[ 2 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R3: info->i = mipscpu.cp0r[ 3 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R4: info->i = mipscpu.cp0r[ 4 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R5: info->i = mipscpu.cp0r[ 5 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R6: info->i = mipscpu.cp0r[ 6 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R7: info->i = mipscpu.cp0r[ 7 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R8: info->i = mipscpu.cp0r[ 8 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R9: info->i = mipscpu.cp0r[ 9 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R10: info->i = mipscpu.cp0r[ 10 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R11: info->i = mipscpu.cp0r[ 11 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R12: info->i = mipscpu.cp0r[ 12 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R13: info->i = mipscpu.cp0r[ 13 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R14: info->i = mipscpu.cp0r[ 14 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R15: info->i = mipscpu.cp0r[ 15 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R16: info->i = mipscpu.cp0r[ 16 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R17: info->i = mipscpu.cp0r[ 17 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R18: info->i = mipscpu.cp0r[ 18 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R19: info->i = mipscpu.cp0r[ 19 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R20: info->i = mipscpu.cp0r[ 20 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R21: info->i = mipscpu.cp0r[ 21 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R22: info->i = mipscpu.cp0r[ 22 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R23: info->i = mipscpu.cp0r[ 23 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R24: info->i = mipscpu.cp0r[ 24 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R25: info->i = mipscpu.cp0r[ 25 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R26: info->i = mipscpu.cp0r[ 26 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R27: info->i = mipscpu.cp0r[ 27 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R28: info->i = mipscpu.cp0r[ 28 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R29: info->i = mipscpu.cp0r[ 29 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R30: info->i = mipscpu.cp0r[ 30 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP0R31: info->i = mipscpu.cp0r[ 31 ]; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR0: info->i = mipscpu.cp2dr[ 0 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR1: info->i = mipscpu.cp2dr[ 1 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR2: info->i = mipscpu.cp2dr[ 2 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR3: info->i = mipscpu.cp2dr[ 3 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR4: info->i = mipscpu.cp2dr[ 4 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR5: info->i = mipscpu.cp2dr[ 5 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR6: info->i = mipscpu.cp2dr[ 6 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR7: info->i = mipscpu.cp2dr[ 7 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR8: info->i = mipscpu.cp2dr[ 8 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR9: info->i = mipscpu.cp2dr[ 9 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR10: info->i = mipscpu.cp2dr[ 10 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR11: info->i = mipscpu.cp2dr[ 11 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR12: info->i = mipscpu.cp2dr[ 12 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR13: info->i = mipscpu.cp2dr[ 13 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR14: info->i = mipscpu.cp2dr[ 14 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR15: info->i = mipscpu.cp2dr[ 15 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR16: info->i = mipscpu.cp2dr[ 16 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR17: info->i = mipscpu.cp2dr[ 17 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR18: info->i = mipscpu.cp2dr[ 18 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR19: info->i = mipscpu.cp2dr[ 19 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR20: info->i = mipscpu.cp2dr[ 20 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR21: info->i = mipscpu.cp2dr[ 21 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR22: info->i = mipscpu.cp2dr[ 22 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR23: info->i = mipscpu.cp2dr[ 23 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR24: info->i = mipscpu.cp2dr[ 24 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR25: info->i = mipscpu.cp2dr[ 25 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR26: info->i = mipscpu.cp2dr[ 26 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR27: info->i = mipscpu.cp2dr[ 27 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR28: info->i = mipscpu.cp2dr[ 28 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR29: info->i = mipscpu.cp2dr[ 29 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR30: info->i = mipscpu.cp2dr[ 30 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2DR31: info->i = mipscpu.cp2dr[ 31 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR0: info->i = mipscpu.cp2cr[ 0 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR1: info->i = mipscpu.cp2cr[ 1 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR2: info->i = mipscpu.cp2cr[ 2 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR3: info->i = mipscpu.cp2cr[ 3 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR4: info->i = mipscpu.cp2cr[ 4 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR5: info->i = mipscpu.cp2cr[ 5 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR6: info->i = mipscpu.cp2cr[ 6 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR7: info->i = mipscpu.cp2cr[ 7 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR8: info->i = mipscpu.cp2cr[ 8 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR9: info->i = mipscpu.cp2cr[ 9 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR10: info->i = mipscpu.cp2cr[ 10 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR11: info->i = mipscpu.cp2cr[ 11 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR12: info->i = mipscpu.cp2cr[ 12 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR13: info->i = mipscpu.cp2cr[ 13 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR14: info->i = mipscpu.cp2cr[ 14 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR15: info->i = mipscpu.cp2cr[ 15 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR16: info->i = mipscpu.cp2cr[ 16 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR17: info->i = mipscpu.cp2cr[ 17 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR18: info->i = mipscpu.cp2cr[ 18 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR19: info->i = mipscpu.cp2cr[ 19 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR20: info->i = mipscpu.cp2cr[ 20 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR21: info->i = mipscpu.cp2cr[ 21 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR22: info->i = mipscpu.cp2cr[ 22 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR23: info->i = mipscpu.cp2cr[ 23 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR24: info->i = mipscpu.cp2cr[ 24 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR25: info->i = mipscpu.cp2cr[ 25 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR26: info->i = mipscpu.cp2cr[ 26 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR27: info->i = mipscpu.cp2cr[ 27 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR28: info->i = mipscpu.cp2cr[ 28 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR29: info->i = mipscpu.cp2cr[ 29 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR30: info->i = mipscpu.cp2cr[ 30 ].d; break; case CPUINFO_INT_REGISTER + MIPS_CP2CR31: info->i = mipscpu.cp2cr[ 31 ].d; break; /* --- the following bits of info are returned as pointers to data or functions --- */ case CPUINFO_PTR_SET_INFO: info->setinfo = mips_set_info; break; case CPUINFO_PTR_GET_CONTEXT: info->getcontext = mips_get_context; break; case CPUINFO_PTR_SET_CONTEXT: info->setcontext = mips_set_context; break; case CPUINFO_PTR_INIT: info->init = mips_init; break; case CPUINFO_PTR_RESET: info->reset = mips_reset; break; case CPUINFO_PTR_EXIT: info->exit = mips_exit; break; case CPUINFO_PTR_EXECUTE: info->execute = mips_execute; break; case CPUINFO_PTR_BURN: info->burn = NULL; break; #ifdef MAME_DEBUG case CPUINFO_PTR_DISASSEMBLE: info->disassemble = mips_dasm; break; #endif /* MAME_DEBUG */ case CPUINFO_PTR_INSTRUCTION_COUNTER: info->icount = &mips_ICount; break; /* --- the following bits of info are returned as NULL-terminated strings --- */ case CPUINFO_STR_NAME: strcpy(info->s, "PSX CPU"); break; case CPUINFO_STR_CORE_FAMILY: strcpy(info->s, "mipscpu"); break; case CPUINFO_STR_CORE_VERSION: strcpy(info->s, "1.5"); break; case CPUINFO_STR_CORE_FILE: strcpy(info->s, __FILE__); break; case CPUINFO_STR_CORE_CREDITS: strcpy(info->s, "Copyright 2005 smf"); break; case CPUINFO_STR_FLAGS: strcpy(info->s, " "); break; case CPUINFO_STR_REGISTER + MIPS_PC: sprintf( info->s, "pc :%08x", mipscpu.pc ); break; case CPUINFO_STR_REGISTER + MIPS_DELAYV: sprintf( info->s, "delay :%08x", mipscpu.delayv ); break; case CPUINFO_STR_REGISTER + MIPS_DELAYR: sprintf( info->s, "delay %s:%02x", delayn[ mipscpu.delayr ], mipscpu.delayr ); break; case CPUINFO_STR_REGISTER + MIPS_HI: sprintf( info->s, "hi :%08x", mipscpu.hi ); break; case CPUINFO_STR_REGISTER + MIPS_LO: sprintf( info->s, "lo :%08x", mipscpu.lo ); break; case CPUINFO_STR_REGISTER + MIPS_R0: sprintf( info->s, "zero :%08x", mipscpu.r[ 0 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R1: sprintf( info->s, "at :%08x", mipscpu.r[ 1 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R2: sprintf( info->s, "v0 :%08x", mipscpu.r[ 2 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R3: sprintf( info->s, "v1 :%08x", mipscpu.r[ 3 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R4: sprintf( info->s, "a0 :%08x", mipscpu.r[ 4 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R5: sprintf( info->s, "a1 :%08x", mipscpu.r[ 5 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R6: sprintf( info->s, "a2 :%08x", mipscpu.r[ 6 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R7: sprintf( info->s, "a3 :%08x", mipscpu.r[ 7 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R8: sprintf( info->s, "t0 :%08x", mipscpu.r[ 8 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R9: sprintf( info->s, "t1 :%08x", mipscpu.r[ 9 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R10: sprintf( info->s, "t2 :%08x", mipscpu.r[ 10 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R11: sprintf( info->s, "t3 :%08x", mipscpu.r[ 11 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R12: sprintf( info->s, "t4 :%08x", mipscpu.r[ 12 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R13: sprintf( info->s, "t5 :%08x", mipscpu.r[ 13 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R14: sprintf( info->s, "t6 :%08x", mipscpu.r[ 14 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R15: sprintf( info->s, "t7 :%08x", mipscpu.r[ 15 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R16: sprintf( info->s, "s0 :%08x", mipscpu.r[ 16 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R17: sprintf( info->s, "s1 :%08x", mipscpu.r[ 17 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R18: sprintf( info->s, "s2 :%08x", mipscpu.r[ 18 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R19: sprintf( info->s, "s3 :%08x", mipscpu.r[ 19 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R20: sprintf( info->s, "s4 :%08x", mipscpu.r[ 20 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R21: sprintf( info->s, "s5 :%08x", mipscpu.r[ 21 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R22: sprintf( info->s, "s6 :%08x", mipscpu.r[ 22 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R23: sprintf( info->s, "s7 :%08x", mipscpu.r[ 23 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R24: sprintf( info->s, "t8 :%08x", mipscpu.r[ 24 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R25: sprintf( info->s, "t9 :%08x", mipscpu.r[ 25 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R26: sprintf( info->s, "k0 :%08x", mipscpu.r[ 26 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R27: sprintf( info->s, "k1 :%08x", mipscpu.r[ 27 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R28: sprintf( info->s, "gp :%08x", mipscpu.r[ 28 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R29: sprintf( info->s, "sp :%08x", mipscpu.r[ 29 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R30: sprintf( info->s, "fp :%08x", mipscpu.r[ 30 ] ); break; case CPUINFO_STR_REGISTER + MIPS_R31: sprintf( info->s, "ra :%08x", mipscpu.r[ 31 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R0: sprintf( info->s, "Index :%08x", mipscpu.cp0r[ 0 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R1: sprintf( info->s, "Random :%08x", mipscpu.cp0r[ 1 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R2: sprintf( info->s, "EntryLo :%08x", mipscpu.cp0r[ 2 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R3: sprintf( info->s, "cp0r3 :%08x", mipscpu.cp0r[ 3 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R4: sprintf( info->s, "Context :%08x", mipscpu.cp0r[ 4 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R5: sprintf( info->s, "cp0r5 :%08x", mipscpu.cp0r[ 5 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R6: sprintf( info->s, "cp0r6 :%08x", mipscpu.cp0r[ 6 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R7: sprintf( info->s, "cp0r7 :%08x", mipscpu.cp0r[ 7 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R8: sprintf( info->s, "BadVAddr:%08x", mipscpu.cp0r[ 8 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R9: sprintf( info->s, "cp0r9 :%08x", mipscpu.cp0r[ 9 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R10: sprintf( info->s, "EntryHi :%08x", mipscpu.cp0r[ 10 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R11: sprintf( info->s, "cp0r11 :%08x", mipscpu.cp0r[ 11 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R12: sprintf( info->s, "SR :%08x", mipscpu.cp0r[ 12 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R13: sprintf( info->s, "Cause :%08x", mipscpu.cp0r[ 13 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R14: sprintf( info->s, "EPC :%08x", mipscpu.cp0r[ 14 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R15: sprintf( info->s, "PRId :%08x", mipscpu.cp0r[ 15 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R16: sprintf( info->s, "cp0r16 :%08x", mipscpu.cp0r[ 16 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R17: sprintf( info->s, "cp0r17 :%08x", mipscpu.cp0r[ 17 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R18: sprintf( info->s, "cp0r18 :%08x", mipscpu.cp0r[ 18 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R19: sprintf( info->s, "cp0r19 :%08x", mipscpu.cp0r[ 19 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R20: sprintf( info->s, "cp0r20 :%08x", mipscpu.cp0r[ 20 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R21: sprintf( info->s, "cp0r21 :%08x", mipscpu.cp0r[ 21 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R22: sprintf( info->s, "cp0r22 :%08x", mipscpu.cp0r[ 22 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R23: sprintf( info->s, "cp0r23 :%08x", mipscpu.cp0r[ 23 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R24: sprintf( info->s, "cp0r24 :%08x", mipscpu.cp0r[ 24 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R25: sprintf( info->s, "cp0r25 :%08x", mipscpu.cp0r[ 25 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R26: sprintf( info->s, "cp0r26 :%08x", mipscpu.cp0r[ 26 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R27: sprintf( info->s, "cp0r27 :%08x", mipscpu.cp0r[ 27 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R28: sprintf( info->s, "cp0r28 :%08x", mipscpu.cp0r[ 28 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R29: sprintf( info->s, "cp0r29 :%08x", mipscpu.cp0r[ 29 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R30: sprintf( info->s, "cp0r30 :%08x", mipscpu.cp0r[ 30 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP0R31: sprintf( info->s, "cp0r31 :%08x", mipscpu.cp0r[ 31 ] ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR0: sprintf( info->s, "vxy0 :%08x", mipscpu.cp2dr[ 0 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR1: sprintf( info->s, "vz0 :%08x", mipscpu.cp2dr[ 1 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR2: sprintf( info->s, "vxy1 :%08x", mipscpu.cp2dr[ 2 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR3: sprintf( info->s, "vz1 :%08x", mipscpu.cp2dr[ 3 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR4: sprintf( info->s, "vxy2 :%08x", mipscpu.cp2dr[ 4 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR5: sprintf( info->s, "vz2 :%08x", mipscpu.cp2dr[ 5 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR6: sprintf( info->s, "rgb :%08x", mipscpu.cp2dr[ 6 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR7: sprintf( info->s, "otz :%08x", mipscpu.cp2dr[ 7 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR8: sprintf( info->s, "ir0 :%08x", mipscpu.cp2dr[ 8 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR9: sprintf( info->s, "ir1 :%08x", mipscpu.cp2dr[ 9 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR10: sprintf( info->s, "ir2 :%08x", mipscpu.cp2dr[ 10 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR11: sprintf( info->s, "ir3 :%08x", mipscpu.cp2dr[ 11 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR12: sprintf( info->s, "sxy0 :%08x", mipscpu.cp2dr[ 12 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR13: sprintf( info->s, "sxy1 :%08x", mipscpu.cp2dr[ 13 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR14: sprintf( info->s, "sxy2 :%08x", mipscpu.cp2dr[ 14 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR15: sprintf( info->s, "sxyp :%08x", mipscpu.cp2dr[ 15 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR16: sprintf( info->s, "sz0 :%08x", mipscpu.cp2dr[ 16 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR17: sprintf( info->s, "sz1 :%08x", mipscpu.cp2dr[ 17 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR18: sprintf( info->s, "sz2 :%08x", mipscpu.cp2dr[ 18 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR19: sprintf( info->s, "sz3 :%08x", mipscpu.cp2dr[ 19 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR20: sprintf( info->s, "rgb0 :%08x", mipscpu.cp2dr[ 20 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR21: sprintf( info->s, "rgb1 :%08x", mipscpu.cp2dr[ 21 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR22: sprintf( info->s, "rgb2 :%08x", mipscpu.cp2dr[ 22 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR23: sprintf( info->s, "res1 :%08x", mipscpu.cp2dr[ 23 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR24: sprintf( info->s, "mac0 :%08x", mipscpu.cp2dr[ 24 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR25: sprintf( info->s, "mac1 :%08x", mipscpu.cp2dr[ 25 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR26: sprintf( info->s, "mac2 :%08x", mipscpu.cp2dr[ 26 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR27: sprintf( info->s, "mac3 :%08x", mipscpu.cp2dr[ 27 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR28: sprintf( info->s, "irgb :%08x", mipscpu.cp2dr[ 28 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR29: sprintf( info->s, "orgb :%08x", mipscpu.cp2dr[ 29 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR30: sprintf( info->s, "lzcs :%08x", mipscpu.cp2dr[ 30 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2DR31: sprintf( info->s, "lzcr :%08x", mipscpu.cp2dr[ 31 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR0: sprintf( info->s, "r11r12 :%08x", mipscpu.cp2cr[ 0 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR1: sprintf( info->s, "r13r21 :%08x", mipscpu.cp2cr[ 1 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR2: sprintf( info->s, "r22r23 :%08x", mipscpu.cp2cr[ 2 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR3: sprintf( info->s, "r31r32 :%08x", mipscpu.cp2cr[ 3 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR4: sprintf( info->s, "r33 :%08x", mipscpu.cp2cr[ 4 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR5: sprintf( info->s, "trx :%08x", mipscpu.cp2cr[ 5 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR6: sprintf( info->s, "try :%08x", mipscpu.cp2cr[ 6 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR7: sprintf( info->s, "trz :%08x", mipscpu.cp2cr[ 7 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR8: sprintf( info->s, "l11l12 :%08x", mipscpu.cp2cr[ 8 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR9: sprintf( info->s, "l13l21 :%08x", mipscpu.cp2cr[ 9 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR10: sprintf( info->s, "l22l23 :%08x", mipscpu.cp2cr[ 10 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR11: sprintf( info->s, "l31l32 :%08x", mipscpu.cp2cr[ 11 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR12: sprintf( info->s, "l33 :%08x", mipscpu.cp2cr[ 12 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR13: sprintf( info->s, "rbk :%08x", mipscpu.cp2cr[ 13 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR14: sprintf( info->s, "gbk :%08x", mipscpu.cp2cr[ 14 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR15: sprintf( info->s, "bbk :%08x", mipscpu.cp2cr[ 15 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR16: sprintf( info->s, "lr1lr2 :%08x", mipscpu.cp2cr[ 16 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR17: sprintf( info->s, "lr31g1 :%08x", mipscpu.cp2cr[ 17 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR18: sprintf( info->s, "lg2lg3 :%08x", mipscpu.cp2cr[ 18 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR19: sprintf( info->s, "lb1lb2 :%08x", mipscpu.cp2cr[ 19 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR20: sprintf( info->s, "lb3 :%08x", mipscpu.cp2cr[ 20 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR21: sprintf( info->s, "rfc :%08x", mipscpu.cp2cr[ 21 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR22: sprintf( info->s, "gfc :%08x", mipscpu.cp2cr[ 22 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR23: sprintf( info->s, "bfc :%08x", mipscpu.cp2cr[ 23 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR24: sprintf( info->s, "ofx :%08x", mipscpu.cp2cr[ 24 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR25: sprintf( info->s, "ofy :%08x", mipscpu.cp2cr[ 25 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR26: sprintf( info->s, "h :%08x", mipscpu.cp2cr[ 26 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR27: sprintf( info->s, "dqa :%08x", mipscpu.cp2cr[ 27 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR28: sprintf( info->s, "dqb :%08x", mipscpu.cp2cr[ 28 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR29: sprintf( info->s, "zsf3 :%08x", mipscpu.cp2cr[ 29 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR30: sprintf( info->s, "zsf4 :%08x", mipscpu.cp2cr[ 30 ].d ); break; case CPUINFO_STR_REGISTER + MIPS_CP2CR31: sprintf( info->s, "flag :%08x", mipscpu.cp2cr[ 31 ].d ); break; } } #if (HAS_PSXCPU) /************************************************************************** * CPU-specific set_info **************************************************************************/ void psxcpu_get_info(UINT32 state, cpuinfo *info) { switch (state) { /* --- the following bits of info are returned as NULL-terminated strings --- */ case CPUINFO_STR_NAME: strcpy(info->s, "PSX CPU"); break; default: mips_get_info(state, info); break; } } #endif