/************************************************************************/ /* KEGS: Apple //gs Emulator */ /* Copyright 2002 by Kent Dickey */ /* */ /* This code is covered by the GNU GPL */ /* */ /* The KEGS web page is kegs.sourceforge.net */ /* You may contact the author at: kadickey@alumni.princeton.edu */ /************************************************************************/ const char rcsid_sim65816_c[] = "@(#)$KmKId: sim65816.c,v 1.367 2004-11-22 02:39:26-05 kentd Exp $"; #include #define INCLUDE_RCSID_C #include "defc.h" #undef INCLUDE_RCSID_C #define PC_LOG_LEN (8*1024) char g_argv0_path[256] = "./"; const char *g_kegs_default_paths[] = { "", "./", "${HOME}/", "${HOME}/Library/KEGS/", "${0}/Contents/Resources/", "/usr/local/lib/", "/usr/local/kegs/", "/usr/local/lib/kegs/", "/usr/share/kegs/", "/var/lib/", "/usr/lib/kegs/", "${0}/", 0 }; #define MAX_EVENTS 64 /* All EV_* must be less than 256, since upper bits reserved for other use */ /* e.g., DOC_INT uses upper bits to encode oscillator */ #define EV_60HZ 1 #define EV_STOP 2 #define EV_SCAN_INT 3 #define EV_DOC_INT 4 #define EV_VBL_INT 5 #define EV_SCC 6 #define EV_VID_UPD 7 extern int g_stepping; extern int g_c068_statereg; extern int g_cur_a2_stat; extern int g_c08x_wrdefram; extern int g_c02d_int_crom; extern int g_c035_shadow_reg; extern int g_c036_val_speed; extern int g_c023_val; extern int g_c041_val; extern int g_c046_val; extern int g_zipgs_reg_c059; extern int g_zipgs_reg_c05a; extern int g_zipgs_reg_c05b; extern int g_zipgs_unlock; extern int g_engine_c_mode; extern int defs_instr_start_8; extern int defs_instr_start_16; extern int defs_instr_end_8; extern int defs_instr_end_16; extern int op_routs_start; extern int op_routs_end; Engine_reg engine; extern word32 table8[]; extern word32 table16[]; extern byte doc_ram[]; extern int g_iwm_motor_on; extern int g_fast_disk_emul; extern int g_slow_525_emul_wr; extern int g_c031_disk35; extern int g_config_control_panel; extern int g_audio_enable; extern int g_preferred_rate; void U_STACK_TRACE(); double g_fcycles_stop = 0.0; int halt_sim = 0; int enter_debug = 0; int g_rom_version = -1; int g_user_halt_bad = 0; int g_halt_on_bad_read = 0; int g_ignore_bad_acc = 1; int g_ignore_halts = 1; int g_code_red = 0; int g_code_yellow = 0; int g_use_alib = 0; int g_raw_serial = 1; int g_iw2_emul = 0; int g_serial_out_masking = 0; int g_serial_modem[2] = { 0, 1 }; int g_config_iwm_vbl_count = 0; const char g_kegs_version_str[] = "0.91"; #define START_DCYCS (0.0) double g_last_vbl_dcycs = START_DCYCS; double g_cur_dcycs = START_DCYCS; double g_last_vbl_dadjcycs = 0.0; double g_dadjcycs = 0.0; int g_wait_pending = 0; int g_stp_pending = 0; extern int g_irq_pending; int g_num_irq = 0; int g_num_brk = 0; int g_num_cop = 0; int g_num_enter_engine = 0; int g_io_amt = 0; int g_engine_action = 0; int g_engine_halt_event = 0; int g_engine_scan_int = 0; int g_engine_doc_int = 0; int g_testing = 0; int g_testing_enabled = 0; #define MAX_FATAL_LOGS 20 int g_debug_file_fd = -1; int g_fatal_log = -1; char *g_fatal_log_strs[MAX_FATAL_LOGS]; word32 stop_run_at; int g_25sec_cntr = 0; int g_1sec_cntr = 0; double g_dnatcycs_1sec = 0.0; word32 g_natcycs_lastvbl = 0; int Verbose = 0; int Halt_on = 0; word32 g_mem_size_base = 256*1024; /* size of motherboard memory */ word32 g_mem_size_exp = 8*1024*1024; /* size of expansion RAM card */ word32 g_mem_size_total = 256*1024; /* Total contiguous RAM from 0 */ extern word32 slow_mem_changed[]; byte *g_slow_memory_ptr = 0; byte *g_memory_ptr = 0; byte *g_dummy_memory1_ptr = 0; byte *g_rom_fc_ff_ptr = 0; byte *g_rom_cards_ptr = 0; void *g_memory_alloc_ptr = 0; /* for freeing memory area */ Page_info page_info_rd_wr[2*65536 + PAGE_INFO_PAD_SIZE]; Pc_log g_pc_log_array[PC_LOG_LEN + 2]; Data_log g_data_log_array[PC_LOG_LEN + 2]; Pc_log *g_log_pc_ptr = &(g_pc_log_array[0]); Pc_log *g_log_pc_start_ptr = &(g_pc_log_array[0]); Pc_log *g_log_pc_end_ptr = &(g_pc_log_array[PC_LOG_LEN]); Data_log *g_log_data_ptr = &(g_data_log_array[0]); Data_log *g_log_data_start_ptr = &(g_data_log_array[0]); Data_log *g_log_data_end_ptr = &(g_data_log_array[PC_LOG_LEN]); void show_pc_log() { FILE *pcfile; Pc_log *log_pc_ptr; Data_log *log_data_ptr; double dcycs; double start_dcycs; word32 instr; word32 psr; word32 acc, xreg, yreg; word32 stack, direct; word32 dbank; word32 kpc; int data_wrap; int accsize, xsize; int num; int i; pcfile = fopen("pc_log_out", "w"); if(pcfile == 0) { fprintf(stderr,"fopen failed...errno: %d\n", errno); exit(2); } log_pc_ptr = g_log_pc_ptr; log_data_ptr = g_log_data_ptr; #if 0 fprintf(pcfile, "current pc_log_ptr: %p, start: %p, end: %p\n", log_pc_ptr, log_pc_start_ptr, log_pc_end_ptr); #endif start_dcycs = log_pc_ptr->dcycs; dcycs = start_dcycs; data_wrap = 0; /* find first data entry */ while(data_wrap < 2 && (log_data_ptr->dcycs < dcycs)) { log_data_ptr++; if(log_data_ptr >= g_log_data_end_ptr) { log_data_ptr = g_log_data_start_ptr; data_wrap++; } } fprintf(pcfile, "start_dcycs: %9.2f\n", start_dcycs); for(i = 0; i < PC_LOG_LEN; i++) { dcycs = log_pc_ptr->dcycs; while((data_wrap < 2) && (log_data_ptr->dcycs <= dcycs) && (log_data_ptr->dcycs >= start_dcycs)) { fprintf(pcfile, "DATA set %06x = %06x (%d) %9.2f\n", log_data_ptr->addr, log_data_ptr->val, log_data_ptr->size, log_data_ptr->dcycs - start_dcycs); log_data_ptr++; if(log_data_ptr >= g_log_data_end_ptr) { log_data_ptr = g_log_data_start_ptr; data_wrap++; } } dbank = (log_pc_ptr->dbank_kpc >> 24) & 0xff; kpc = log_pc_ptr->dbank_kpc & 0xffffff; instr = log_pc_ptr->instr; psr = (log_pc_ptr->psr_acc >> 16) & 0xffff;; acc = log_pc_ptr->psr_acc & 0xffff;; xreg = (log_pc_ptr->xreg_yreg >> 16) & 0xffff;; yreg = log_pc_ptr->xreg_yreg & 0xffff;; stack = (log_pc_ptr->stack_direct >> 16) & 0xffff;; direct = log_pc_ptr->stack_direct & 0xffff;; num = log_pc_ptr - g_log_pc_start_ptr; accsize = 2; xsize = 2; if(psr & 0x20) { accsize = 1; } if(psr & 0x10) { xsize = 1; } fprintf(pcfile, "%04x: A:%04x X:%04x Y:%04x P:%03x " "S:%04x D:%04x B:%02x %9.2f ", i, acc, xreg, yreg, psr, stack, direct, dbank, (dcycs-start_dcycs)); do_dis(pcfile, kpc, accsize, xsize, 1, instr); log_pc_ptr++; if(log_pc_ptr >= g_log_pc_end_ptr) { log_pc_ptr = g_log_pc_start_ptr; } } fclose(pcfile); } #define TOOLBOX_LOG_LEN 64 int g_toolbox_log_pos = 0; word32 g_toolbox_log_array[TOOLBOX_LOG_LEN][8]; word32 toolbox_debug_4byte(word32 addr) { word32 part1, part2; /* If addr looks safe, use it */ if(addr > 0xbffc) { return (word32)-1; } part1 = get_memory16_c(addr, 0); part1 = (part1 >> 8) + ((part1 & 0xff) << 8); part2 = get_memory16_c(addr+2, 0); part2 = (part2 >> 8) + ((part2 & 0xff) << 8); return (part1 << 16) + part2; } void toolbox_debug_c(word32 xreg, word32 stack, double *cyc_ptr) { int pos; pos = g_toolbox_log_pos; stack += 9; g_toolbox_log_array[pos][0] = g_last_vbl_dcycs + *cyc_ptr; g_toolbox_log_array[pos][1] = stack+1; g_toolbox_log_array[pos][2] = xreg; g_toolbox_log_array[pos][3] = toolbox_debug_4byte(stack+1); g_toolbox_log_array[pos][4] = toolbox_debug_4byte(stack+5); g_toolbox_log_array[pos][5] = toolbox_debug_4byte(stack+9); g_toolbox_log_array[pos][6] = toolbox_debug_4byte(stack+13); g_toolbox_log_array[pos][7] = toolbox_debug_4byte(stack+17); pos++; if(pos >= TOOLBOX_LOG_LEN) { pos = 0; } g_toolbox_log_pos = pos; } void show_toolbox_log() { int pos; int i; pos = g_toolbox_log_pos; for(i = TOOLBOX_LOG_LEN - 1; i >= 0; i--) { printf("%2d:%2d: %08x %06x %04x: %08x %08x %08x %08x %08x\n", i, pos, g_toolbox_log_array[pos][0], g_toolbox_log_array[pos][1], g_toolbox_log_array[pos][2], g_toolbox_log_array[pos][3], g_toolbox_log_array[pos][4], g_toolbox_log_array[pos][5], g_toolbox_log_array[pos][6], g_toolbox_log_array[pos][7]); pos++; if(pos >= TOOLBOX_LOG_LEN) { pos = 0; } } } #if 0 /* get_memory_c is not used, get_memory_asm is, but this does what the */ /* assembly language would do */ word32 get_memory_c(word32 loc, int diff_cycles) { byte *addr; word32 result; int index; #ifdef CHECK_BREAKPOINTS check_breakpoints_c(loc); #endif index = loc >> 8; result = page_info[index].rd; if(result & BANK_IO_BIT) { return get_memory_io(loc, diff_cycles); } addr = (byte *)((result & 0xffffff00) + (loc & 0xff)); return *addr; } #endif word32 get_memory_io(word32 loc, double *cyc_ptr) { int tmp; if(loc > 0xffffff) { halt_printf("get_memory_io:%08x out of range==halt!\n", loc); return 0; } tmp = loc & 0xfef000; if(tmp == 0xc000 || tmp == 0xe0c000) { return(io_read(loc & 0xfff, cyc_ptr)); } /* Else it's an illegal addr...skip if memory sizing */ if(loc >= g_mem_size_total) { if((loc & 0xfffe) == 0) { #if 0 printf("get_io assuming mem sizing, not halting\n"); #endif return 0; } } /* Skip reads to f80000 and f00000, just return 0 */ if((loc & 0xf70000) == 0xf00000) { return 0; } if((loc & 0xff0000) == 0xef0000) { /* DOC RAM */ return (doc_ram[loc & 0xffff]); } g_code_yellow++; if(g_ignore_bad_acc && !g_user_halt_bad) { /* print no message, just get out. User doesn't want */ /* to be bothered by buggy programs */ return 0; } printf("get_memory_io for addr: %06x\n", loc); printf("stat for addr: %06x = %p\n", loc, GET_PAGE_INFO_RD((loc >> 8) & 0xffff)); set_halt(g_halt_on_bad_read | g_user_halt_bad); return 0; } #if 0 word32 get_memory16_pieces(word32 loc, int diff_cycles) { return(get_memory_c(loc, diff_cycles) + (get_memory_c(loc+1, diff_cycles) << 8)); } word32 get_memory24(word32 loc, int diff_cycles) { return(get_memory_c(loc, diff_cycles) + (get_memory_c(loc+1, diff_cycles) << 8) + (get_memory_c(loc+2, diff_cycles) << 16)); } #endif #if 0 void set_memory(word32 loc, int val, int diff_cycles) { byte *ptr; word32 new_addr; word32 tmp; word32 or_val; int or_pos; int old_slow_val; #ifdef CHECK_BREAKPOINTS check_breakpoints_c(loc); #endif tmp = GET_PAGE_INFO_WR((loc>>8) & 0xffff); if(tmp & BANK_IO) { set_memory_io(loc, val, diff_cycles); return; } if((loc & 0xfef000) == 0xe0c000) { printf("set_memory_special: non-io for addr %08x, %02x, %d\n", loc, val, diff_cycles); halt_printf("tmp: %08x\n", tmp); } ptr = (byte *)(tmp & (~0xff)); new_addr = loc & 0xffff; old_slow_val = val; if(tmp & BANK_SHADOW) { old_slow_val = g_slow_memory_ptr[new_addr]; } else if(tmp & BANK_SHADOW2) { new_addr += 0x10000; old_slow_val = g_slow_memory_ptr[new_addr]; } if(old_slow_val != val) { g_slow_memory_ptr[new_addr] = val; or_pos = (new_addr >> SHIFT_PER_CHANGE) & 0x1f; or_val = DEP1(1, or_pos, 0); if((new_addr >> CHANGE_SHIFT) >= SLOW_MEM_CH_SIZE) { printf("new_addr: %08x\n", new_addr); exit(12); } slow_mem_changed[(new_addr & 0xffff) >> CHANGE_SHIFT] |= or_val; } ptr[loc & 0xff] = val; } #endif void set_memory_io(word32 loc, int val, double *cyc_ptr) { word32 tmp; tmp = loc & 0xfef000; if(tmp == 0xc000 || tmp == 0xe0c000) { io_write(loc, val, cyc_ptr); return; } /* Else it's an illegal addr */ if(loc >= g_mem_size_total) { if((loc & 0xfffe) == 0) { #if 0 printf("set_io assuming mem sizing, not halting\n"); #endif return; } } /* ignore writes to ROM */ if((loc & 0xfc0000) == 0xfc0000) { return; } if((loc & 0xff0000) == 0xef0000) { /* DOC RAM */ doc_ram[loc & 0xffff] = val; return; } if(g_ignore_bad_acc && !g_user_halt_bad) { /* print no message, just get out. User doesn't want */ /* to be bothered by buggy programs */ return; } if((loc & 0xffc000) == 0x00c000) { printf("set_memory %06x = %02x, warning\n", loc, val); return; } halt_printf("set_memory %06x = %02x, stopping\n", loc, val); return; } #if 0 void check_breakpoints_c(word32 loc) { int index; int count; int i; index = (loc & (MAX_BP_INDEX-1)); count = breakpoints[index].count; if(count) { for(i = 0; i < count; i++) { if(loc == breakpoints[index].addrs[i]) { halt_printf("Write hit breakpoint %d!\n", i); } } } } #endif void show_regs_act(Engine_reg *eptr) { int tmp_acc, tmp_x, tmp_y, tmp_psw; int kpc; int direct_page, dbank; int stack; kpc = eptr->kpc; tmp_acc = eptr->acc; direct_page = eptr->direct; dbank = eptr->dbank; stack = eptr->stack; tmp_x = eptr->xreg; tmp_y = eptr->yreg; tmp_psw = eptr->psr; printf(" PC=%02x.%04x A=%04x X=%04x Y=%04x P=%03x", kpc>>16, kpc & 0xffff ,tmp_acc,tmp_x,tmp_y,tmp_psw); printf(" S=%04x D=%04x B=%02x,cyc:%.3f\n", stack, direct_page, dbank, g_cur_dcycs); } void show_regs() { show_regs_act(&engine); } void my_exit(int ret) { end_screen(); printf("exiting\n"); exit(ret); } void do_reset() { g_c068_statereg = 0x08 + 0x04 + 0x01; /* rdrom, lcbank2, intcx */ g_c035_shadow_reg = 0; g_c08x_wrdefram = 1; g_c02d_int_crom = 0; g_c023_val = 0; g_c041_val = 0; engine.psr = (engine.psr | 0x134) & ~(0x08); engine.stack = 0x100 + (engine.stack & 0xff); engine.dbank = 0; engine.direct = 0; engine.xreg &= 0xff; engine.yreg &= 0xff; g_wait_pending = 0; g_stp_pending = 0; video_reset(); adb_reset(); iwm_reset(); scc_reset(); sound_reset(g_cur_dcycs); setup_pageinfo(); change_display_mode(g_cur_dcycs); g_irq_pending = 0; engine.kpc = get_memory16_c(0x00fffc, 0); g_stepping = 0; } #define CHECK(start, var, value, var1, var2) \ var2 = PTR2WORD(&(var)); \ var1 = PTR2WORD((start)); \ if((var2 - var1) != value) { \ printf("CHECK: " #var " is 0x%x, but " #value " is 0x%x\n", \ (var2 - var1), value); \ exit(5); \ } void check_engine_asm_defines() { Fplus fplus; Fplus *fplusptr; Pc_log pclog; Pc_log *pcptr; Engine_reg ereg; Engine_reg *eptr; word32 val1; word32 val2; eptr = &ereg; CHECK(eptr, eptr->fcycles, ENGINE_FCYCLES, val1, val2); CHECK(eptr, eptr->fplus_ptr, ENGINE_FPLUS_PTR, val1, val2); CHECK(eptr, eptr->acc, ENGINE_REG_ACC, val1, val2); CHECK(eptr, eptr->xreg, ENGINE_REG_XREG, val1, val2); CHECK(eptr, eptr->yreg, ENGINE_REG_YREG, val1, val2); CHECK(eptr, eptr->stack, ENGINE_REG_STACK, val1, val2); CHECK(eptr, eptr->dbank, ENGINE_REG_DBANK, val1, val2); CHECK(eptr, eptr->direct, ENGINE_REG_DIRECT, val1, val2); CHECK(eptr, eptr->psr, ENGINE_REG_PSR, val1, val2); CHECK(eptr, eptr->kpc, ENGINE_REG_KPC, val1, val2); pcptr = &pclog; CHECK(pcptr, pcptr->dbank_kpc, LOG_PC_DBANK_KPC, val1, val2); CHECK(pcptr, pcptr->instr, LOG_PC_INSTR, val1, val2); CHECK(pcptr, pcptr->psr_acc, LOG_PC_PSR_ACC, val1, val2); CHECK(pcptr, pcptr->xreg_yreg, LOG_PC_XREG_YREG, val1, val2); CHECK(pcptr, pcptr->stack_direct, LOG_PC_STACK_DIRECT, val1, val2); if(LOG_PC_SIZE != sizeof(pclog)) { printf("LOG_PC_SIZE: %d != sizeof=%d\n", LOG_PC_SIZE, (int)sizeof(pclog)); exit(2); } fplusptr = &fplus; CHECK(fplusptr, fplusptr->plus_1, FPLUS_PLUS_1, val1, val2); CHECK(fplusptr, fplusptr->plus_2, FPLUS_PLUS_2, val1, val2); CHECK(fplusptr, fplusptr->plus_3, FPLUS_PLUS_3, val1, val2); CHECK(fplusptr, fplusptr->plus_x_minus_1, FPLUS_PLUS_X_M1, val1, val2); } byte * memalloc_align(int size, int skip_amt, void **alloc_ptr) { byte *bptr; word32 addr; word32 offset; skip_amt = MAX(256, skip_amt); bptr = calloc(size + skip_amt, 1); if(alloc_ptr) { /* Save allocation address */ *alloc_ptr = bptr; } addr = PTR2WORD(bptr) & 0xff; /* must align bptr to be 256-byte aligned */ /* this code should work even if ptrs are > 32 bits */ offset = ((addr + skip_amt - 1) & (~0xff)) - addr; return (bptr + offset); } void memory_ptr_init() { word32 mem_size; /* This routine may be called several times--each time the ROM file */ /* changes this will be called */ mem_size = MIN(0xdf0000, g_mem_size_base + g_mem_size_exp); g_mem_size_total = mem_size; if(g_memory_alloc_ptr) { free(g_memory_alloc_ptr); g_memory_alloc_ptr = 0; } g_memory_ptr = memalloc_align(mem_size, 256, &g_memory_alloc_ptr); printf("RAM size is 0 - %06x (%.2fMB)\n", mem_size, (double)mem_size/(1024.0*1024.0)); } extern int g_screen_redraw_skip_amt; extern int g_use_shmem; extern int g_use_dhr140; extern int g_use_bw_hires; char g_display_env[512]; int g_force_depth = -1; int g_screen_depth = 8; int kegsmain(int argc, char **argv) { int skip_amt; int diff; int tmp1; int i; /* parse args */ for(i = 1; i < argc; i++) { if(!strcmp("-badrd", argv[i])) { printf("Halting on bad reads\n"); g_halt_on_bad_read = 2; } else if(!strcmp("-noignbadacc", argv[i])) { printf("Not ignoring bad memory accesses\n"); g_ignore_bad_acc = 0; } else if(!strcmp("-noignhalt", argv[i])) { printf("Not ignoring code red halts\n"); g_ignore_halts = 0; } else if(!strcmp("-test", argv[i])) { printf("Allowing testing\n"); g_testing_enabled = 1; } else if(!strcmp("-hpdev", argv[i])) { printf("Using /dev/audio\n"); g_use_alib = 0; } else if(!strcmp("-alib", argv[i])) { printf("Using Aserver audio server\n"); g_use_alib = 1; } else if(!strcmp("-24", argv[i])) { printf("Using 24-bit visual\n"); g_force_depth = 24; } else if(!strcmp("-16", argv[i])) { printf("Using 16-bit visual\n"); g_force_depth = 16; } else if(!strcmp("-15", argv[i])) { printf("Using 15-bit visual\n"); g_force_depth = 15; } else if(!strcmp("-mem", argv[i])) { if((i+1) >= argc) { printf("Missing argument\n"); exit(1); } g_mem_size_exp = strtol(argv[i+1], 0, 0) & 0x00ff0000; printf("Using %d as memory size\n", g_mem_size_exp); i++; } else if(!strcmp("-skip", argv[i])) { if((i+1) >= argc) { printf("Missing argument\n"); exit(1); } skip_amt = strtol(argv[i+1], 0, 0); printf("Using %d as skip_amt\n", skip_amt); g_screen_redraw_skip_amt = skip_amt; i++; } else if(!strcmp("-audio", argv[i])) { if((i+1) >= argc) { printf("Missing argument\n"); exit(1); } tmp1 = strtol(argv[i+1], 0, 0); printf("Using %d as audio enable val\n", tmp1); g_audio_enable = tmp1; i++; } else if(!strcmp("-arate", argv[i])) { if((i+1) >= argc) { printf("Missing argument\n"); exit(1); } tmp1 = strtol(argv[i+1], 0, 0); printf("Using %d as preferred audio rate\n", tmp1); g_preferred_rate = tmp1; i++; } else if(!strcmp("-v", argv[i])) { if((i+1) >= argc) { printf("Missing argument\n"); exit(1); } tmp1 = strtol(argv[i+1], 0, 0); printf("Setting Verbose = 0x%03x\n", tmp1); Verbose = tmp1; i++; #ifndef __NeXT__ } else if(!strcmp("-display", argv[i])) { if((i+1) >= argc) { printf("Missing argument\n"); exit(1); } printf("Using %s as display\n", argv[i+1]); sprintf(g_display_env, "DISPLAY=%s", argv[i+1]); putenv(&g_display_env[0]); i++; #endif } else if(!strcmp("-noshm", argv[i])) { printf("Not using X shared memory\n"); g_use_shmem = 0; } else if(!strcmp("-joystick", argv[i])) { printf("Ignoring -joystick option\n"); } else if(!strcmp("-dhr140", argv[i])) { printf("Using simple dhires color map\n"); g_use_dhr140 = 1; } else if(!strcmp("-bw", argv[i])) { printf("Forcing black-and-white hires modes\n"); g_cur_a2_stat |= ALL_STAT_COLOR_C021; g_use_bw_hires = 1; } else { printf("Bad option: %s\n", argv[i]); exit(3); } } check_engine_asm_defines(); fixed_memory_ptrs_init(); if(sizeof(word32) != 4) { printf("sizeof(word32) = %d, must be 4!\n", (int)sizeof(word32)); exit(1); } if(!g_engine_c_mode) { diff = &defs_instr_end_8 - &defs_instr_start_8; if(diff != 1) { printf("defs_instr_end_8 - start is %d\n",diff); exit(1); } diff = &defs_instr_end_16 - &defs_instr_start_16; if(diff != 1) { printf("defs_instr_end_16 - start is %d\n", diff); exit(1); } diff = &op_routs_end - &op_routs_start; if(diff != 1) { printf("op_routs_end - start is %d\n", diff); exit(1); } } iwm_init(); config_init(); load_roms_init_memory(); init_reg(); clear_halt(); initialize_events(); video_init(); #ifndef _WIN32 //sleep(1); #endif sound_init(); scc_init(); adb_init(); joystick_init(); if(g_rom_version >= 3) { g_c036_val_speed |= 0x40; /* set power-on bit */ } do_reset(); g_stepping = 0; do_go(); /* If we get here, we hit a breakpoint, call debug intfc */ do_debug_intfc(); my_exit(0); return 0; } void load_roms_init_memory() { config_load_roms(); memory_ptr_init(); clk_setup_bram_version(); /* Must be after config_load_roms */ if(g_rom_version >= 3) { g_c036_val_speed |= 0x40; /* set power-on bit */ } else { g_c036_val_speed &= (~0x40); /* clear the bit */ } do_reset(); /* if user booted ROM 01, switches to ROM 03, then switches back */ /* to ROM 01, then the reset routines call to Tool $0102 looks */ /* at uninitialized $e1/15fe and if it is negative it will JMP */ /* through $e1/1688 which ROM 03 left pointing to fc/0199 */ /* So set e1/15fe = 0 */ set_memory16_c(0xe115fe, 0, 0); } void kegs_expand_path(char *out_ptr, const char *in_ptr, int maxlen) { char name_buf[256]; char *tmp_ptr; int name_len; int in_char; int state; out_ptr[0] = 0; name_len = 0; state = 0; /* See if in_ptr has ${} notation, replace with getenv or argv0 */ while(maxlen > 0) { in_char = *in_ptr++; *out_ptr++ = in_char; maxlen--; if(state == 0) { /* No $ seen yet, look for it */ if(in_char == '$') { state = 1; } } else if(state == 1) { /* See if next char is '{' (dummy }) */ if(in_char == '{') { /* add dummy } */ state = 2; name_len = 0; out_ptr -= 2; } else { state = 0; } } else if(state == 2) { /* fill name_buf ... dummy '{' */ out_ptr--; if(in_char == '}') { name_buf[name_len] = 0; /* got token, now look it up */ tmp_ptr = ""; if(!strncmp("0", name_buf, 128)) { /* Replace ${0} with g_argv0_path */ tmp_ptr = &(g_argv0_path[0]); } else { tmp_ptr = getenv(name_buf); if(tmp_ptr == 0) { tmp_ptr = ""; } } strncpy(out_ptr, tmp_ptr, maxlen); out_ptr += strlen(tmp_ptr); maxlen -= strlen(tmp_ptr); state = 0; } else { name_buf[name_len++] = in_char; } } if(in_char == 0) { /* make sure its null terminated */ *out_ptr++ = 0; break; } } } void setup_kegs_file(char *outname, int maxlen, int ok_if_missing, int can_create_file, const char **name_ptr) { char local_path[256]; struct stat stat_buf; const char **path_ptr; const char **cur_name_ptr, **save_path_ptr; int ret; outname[0] = 0; path_ptr = &g_kegs_default_paths[0]; save_path_ptr = path_ptr; while(*path_ptr) { kegs_expand_path(&(local_path[0]), *path_ptr, 250); cur_name_ptr = name_ptr; while(*cur_name_ptr) { strcpy(outname, &(local_path[0])); strncat(outname, *cur_name_ptr, 255-strlen(outname)); if(!ok_if_missing) { printf("Trying '%s'\n", outname); } ret = stat(outname, &stat_buf); if(ret == 0) { /* got it! */ return; } cur_name_ptr++; } path_ptr++; } outname[0] = 0; if(ok_if_missing > 0) { return; } /* couldn't find it, print out all the attempts */ path_ptr = save_path_ptr; fatal_printf("Could not find required file \"%s\" in any of these " "directories:\n", *name_ptr); while(*path_ptr) { fatal_printf(" %s\n", *path_ptr++); } if(can_create_file) { // Ask user if it's OK to create the file x_dialog_create_kegs_conf(*name_ptr); can_create_file = 0; // But clear out the fatal_printfs first clear_fatal_logs(); setup_kegs_file(outname, maxlen, ok_if_missing, can_create_file, name_ptr); // It's one-level of recursion--it cannot loop since we // clear can_create_file. // If it returns, then there was succes and we should get out return; } else if(ok_if_missing) { /* Just show an alert and return if ok_if_missing < 0 */ x_show_alert(0, 0); return; } system("pwd"); my_exit(2); } Event g_event_list[MAX_EVENTS]; Event g_event_free; Event g_event_start; void initialize_events() { int i; for(i = 1; i < MAX_EVENTS; i++) { g_event_list[i-1].next = &g_event_list[i]; } g_event_free.next = &g_event_list[0]; g_event_list[MAX_EVENTS-1].next = 0; g_event_start.next = 0; g_event_start.dcycs = 0.0; add_event_entry(DCYCS_IN_16MS, EV_60HZ); } void check_for_one_event_type(int type) { Event *ptr; int count; int depth; count = 0; depth = 0; ptr = g_event_start.next; while(ptr != 0) { depth++; if(ptr->type == type) { count++; if(count != 1) { halt_printf("in check_for_1, type %d found at " "depth: %d, count: %d, at %f\n", type, depth, count, ptr->dcycs); } } ptr = ptr->next; } } void add_event_entry(double dcycs, int type) { Event *this_event; Event *ptr, *prev_ptr; int tmp_type; int done; this_event = g_event_free.next; if(this_event == 0) { halt_printf("Out of queue entries!\n"); show_all_events(); return; } g_event_free.next = this_event->next; this_event->type = type; tmp_type = type & 0xff; if((dcycs < 0.0) || (dcycs > (g_cur_dcycs + 50*1000*1000.0)) || ((dcycs < g_cur_dcycs) && (tmp_type != EV_SCAN_INT))) { halt_printf("add_event: dcycs: %f, type:%05x, cur_dcycs: %f!\n", dcycs, type, g_cur_dcycs); dcycs = g_cur_dcycs + 1000.0; } ptr = g_event_start.next; if(ptr && (dcycs < ptr->dcycs)) { /* create event before next expected event */ /* do this by setting HALT_EVENT */ set_halt(HALT_EVENT); } prev_ptr = &g_event_start; ptr = g_event_start.next; done = 0; while(!done) { if(ptr == 0) { this_event->next = ptr; this_event->dcycs = dcycs; prev_ptr->next = this_event; return; } else { if(ptr->dcycs < dcycs) { /* step across this guy */ prev_ptr = ptr; ptr = ptr->next; } else { /* go in front of this guy */ this_event->dcycs = dcycs; this_event->next = ptr; prev_ptr->next = this_event; return; } } } } extern int g_doc_saved_ctl; double remove_event_entry(int type) { Event *ptr, *prev_ptr; Event *next_ptr; ptr = g_event_start.next; prev_ptr = &g_event_start; while(ptr != 0) { if((ptr->type & 0xffff) == type) { /* got it, remove it */ next_ptr = ptr->next; prev_ptr->next = next_ptr; /* Add ptr to free list */ ptr->next = g_event_free.next; g_event_free.next = ptr; return ptr->dcycs; } prev_ptr = ptr; ptr = ptr->next; } halt_printf("remove event_entry: %08x, but not found!\n", type); if((type & 0xff) == EV_DOC_INT) { printf("DOC, g_doc_saved_ctl = %02x\n", g_doc_saved_ctl); } #ifdef HPUX U_STACK_TRACE(); #endif show_all_events(); return 0.0; } void add_event_stop(double dcycs) { add_event_entry(dcycs, EV_STOP); } void add_event_doc(double dcycs, int osc) { if(dcycs < g_cur_dcycs) { dcycs = g_cur_dcycs; #if 0 halt_printf("add_event_doc: dcycs: %f, cur_dcycs: %f\n", dcycs, g_cur_dcycs); #endif } add_event_entry(dcycs, EV_DOC_INT + (osc << 8)); } void add_event_scc(double dcycs, int type) { if(dcycs < g_cur_dcycs) { dcycs = g_cur_dcycs; } add_event_entry(dcycs, EV_SCC + (type << 8)); } void add_event_vbl() { double dcycs; dcycs = g_last_vbl_dcycs + (DCYCS_IN_16MS * (192.0/262.0)); add_event_entry(dcycs, EV_VBL_INT); } void add_event_vid_upd(int line) { double dcycs; dcycs = g_last_vbl_dcycs + ((DCYCS_IN_16MS * line) / 262.0); add_event_entry(dcycs, EV_VID_UPD + (line << 8)); } double remove_event_doc(int osc) { return remove_event_entry(EV_DOC_INT + (osc << 8)); } double remove_event_scc(int type) { return remove_event_entry(EV_SCC + (type << 8)); } void show_all_events() { Event *ptr; int count; double dcycs; count = 0; ptr = g_event_start.next; while(ptr != 0) { dcycs = ptr->dcycs; printf("Event: %02x: type: %05x, dcycs: %f (%f)\n", count, ptr->type, dcycs, dcycs - g_cur_dcycs); ptr = ptr->next; count++; } } word32 g_vbl_count = 0; int g_vbl_index_count = 0; double dtime_array[60]; double g_dadjcycs_array[60]; double g_dtime_diff3_array[60]; double g_dtime_this_vbl_array[60]; double g_dtime_exp_array[60]; double g_dtime_pmhz_array[60]; double g_dtime_eff_pmhz_array[60]; int g_limit_speed = 0; double sim_time[60]; double g_sim_sum = 0.0; double g_cur_sim_dtime = 0.0; double g_projected_pmhz = 1.0; double g_zip_pmhz = 8.0; double g_sim_mhz = 100.0; int g_line_ref_amt = 1; int g_video_line_update_interval = 0; Fplus g_recip_projected_pmhz_slow; Fplus g_recip_projected_pmhz_fast; Fplus g_recip_projected_pmhz_zip; Fplus g_recip_projected_pmhz_unl; void show_pmhz() { printf("Pmhz: %f, c036:%02x, limit: %d\n", g_projected_pmhz, g_c036_val_speed, g_limit_speed); } void setup_zip_speeds() { double frecip; double fmhz; int mult; mult = 16 - ((g_zipgs_reg_c05a >> 4) & 0xf); // 16 = full speed, 1 = 1/16th speed fmhz = (8.0 * mult) / 16.0; #if 0 if(mult == 16) { /* increase full speed by 19% to make zipgs freq measuring */ /* programs work correctly */ fmhz = fmhz * 1.19; } #endif frecip = 1.0 / fmhz; g_zip_pmhz = fmhz; g_recip_projected_pmhz_zip.plus_1 = frecip; g_recip_projected_pmhz_zip.plus_2 = 2.0 * frecip; g_recip_projected_pmhz_zip.plus_3 = 3.0 * frecip; if(frecip >= 0.5) { g_recip_projected_pmhz_zip.plus_x_minus_1 = 1.01; } else { g_recip_projected_pmhz_zip.plus_x_minus_1 = 1.01 - frecip; } } void run_prog() { Fplus *fplus_ptr; Event *this_event; Event *db1; double dcycs; double now_dtime; double prev_dtime; double prerun_fcycles; double fspeed_mult; double fcycles_stop; word32 ret; word32 zip_speed_0tof, zip_speed_0tof_new; int zip_en, zip_follow_cps; int type; int motor_on; int iwm_1; int iwm_25; int limit_speed; int apple35_sel; int fast, zip_speed, faster_than_28, unl_speed; int this_type; fflush(stdout); g_cur_sim_dtime = 0.0; g_recip_projected_pmhz_slow.plus_1 = 1.0; g_recip_projected_pmhz_slow.plus_2 = 2.0; g_recip_projected_pmhz_slow.plus_3 = 3.0; g_recip_projected_pmhz_slow.plus_x_minus_1 = 0.9; g_recip_projected_pmhz_fast.plus_1 = (1.0 / 2.5); g_recip_projected_pmhz_fast.plus_2 = (2.0 / 2.5); g_recip_projected_pmhz_fast.plus_3 = (3.0 / 2.5); g_recip_projected_pmhz_fast.plus_x_minus_1 = (1.98 - (1.0/2.5)); zip_speed_0tof = g_zipgs_reg_c05a & 0xf0; setup_zip_speeds(); if(engine.fplus_ptr == 0) { g_recip_projected_pmhz_unl = g_recip_projected_pmhz_slow; } while(1) { fflush(stdout); if(g_config_control_panel) { config_control_panel(); } if(g_irq_pending && !(engine.psr & 0x4)) { irq_printf("taking an irq!\n"); take_irq(0); /* Interrupt! */ } motor_on = g_iwm_motor_on; limit_speed = g_limit_speed; apple35_sel = g_c031_disk35 & 0x40; zip_en = ((g_zipgs_reg_c05b & 0x10) == 0); zip_follow_cps = ((g_zipgs_reg_c059 & 0x8) != 0); zip_speed_0tof_new = g_zipgs_reg_c05a & 0xf0; fast = (g_c036_val_speed & 0x80) || (zip_en && !zip_follow_cps); if(zip_speed_0tof_new != zip_speed_0tof) { zip_speed_0tof = zip_speed_0tof_new; setup_zip_speeds(); } iwm_1 = motor_on && !apple35_sel && (g_c036_val_speed & 0x4) && (g_slow_525_emul_wr || !g_fast_disk_emul); iwm_25 = (motor_on && apple35_sel) && !g_fast_disk_emul; faster_than_28 = fast && (!iwm_1 && !iwm_25) && zip_en && ((limit_speed == 0) || (limit_speed == 3)); zip_speed = faster_than_28 && ((zip_speed_0tof != 0) || (limit_speed == 3) || (g_zipgs_unlock >= 4) ); unl_speed = faster_than_28 && !zip_speed; if(unl_speed) { /* use unlimited speed */ fspeed_mult = g_projected_pmhz; fplus_ptr = &g_recip_projected_pmhz_unl; } else if(zip_speed) { fspeed_mult = g_zip_pmhz; fplus_ptr = &g_recip_projected_pmhz_zip; } else if(fast && !iwm_1 && !(limit_speed == 1)) { fspeed_mult = 2.5; fplus_ptr = &g_recip_projected_pmhz_fast; } else { /* else run slow */ fspeed_mult = 1.0; fplus_ptr = &g_recip_projected_pmhz_slow; } engine.fplus_ptr = fplus_ptr; this_type = g_event_start.next->type; prerun_fcycles = g_cur_dcycs - g_last_vbl_dcycs; engine.fcycles = prerun_fcycles; fcycles_stop = (g_event_start.next->dcycs - g_last_vbl_dcycs) + 0.001; if(g_stepping) { fcycles_stop = prerun_fcycles; } g_fcycles_stop = fcycles_stop; #if 0 printf("Enter engine, fcycs: %f, stop: %f\n", prerun_fcycles, fcycles_stop); printf("g_cur_dcycs: %f, last_vbl_dcyc: %f\n", g_cur_dcycs, g_last_vbl_dcycs); #endif g_num_enter_engine++; prev_dtime = get_dtime(); ret = enter_engine(&engine); now_dtime = get_dtime(); g_cur_sim_dtime += (now_dtime - prev_dtime); dcycs = g_last_vbl_dcycs + (double)(engine.fcycles); g_dadjcycs += (engine.fcycles - prerun_fcycles) * fspeed_mult; #if 0 printf("...back, engine.fcycles: %f, dcycs: %f\n", (double)engine.fcycles, dcycs); #endif g_cur_dcycs = dcycs; if(ret != 0) { g_engine_action++; handle_action(ret); } if(halt_sim == HALT_EVENT) { g_engine_halt_event++; /* if we needed to stop to check for interrupts, */ /* clear halt */ halt_sim = 0; } #if 0 if(!g_testing && run_cycles < -2000000) { halt_printf("run_cycles: %d, cycles: %d\n", run_cycles, cycles); printf("this_type: %05x\n", this_type); printf("duff_cycles: %d\n", duff_cycles); printf("start.next->rel_time: %d, type: %05x\n", g_event_start.next->rel_time, g_event_start.next->type); } #endif this_event = g_event_start.next; while(dcycs >= this_event->dcycs) { /* Pop this guy off of the queue */ g_event_start.next = this_event->next; type = this_event->type; this_event->next = g_event_free.next; g_event_free.next = this_event; switch(type & 0xff) { case EV_60HZ: update_60hz(dcycs, now_dtime); break; case EV_STOP: printf("type: EV_STOP\n"); printf("next: %p, dcycs: %f\n", g_event_start.next, dcycs); db1 = g_event_start.next; halt_printf("next.dcycs: %f\n", db1->dcycs); break; case EV_SCAN_INT: g_engine_scan_int++; irq_printf("type: scan int\n"); do_scan_int(dcycs, type >> 8); break; case EV_DOC_INT: g_engine_doc_int++; doc_handle_event(type >> 8, dcycs); break; case EV_VBL_INT: do_vbl_int(); break; case EV_SCC: do_scc_event(type >> 8, dcycs); break; case EV_VID_UPD: video_update_event_line(type >> 8); break; default: printf("Unknown event: %d!\n", type); exit(3); } this_event = g_event_start.next; } if(g_event_start.next == 0) { halt_printf("ERROR...run_prog, event_start.n=0!\n"); } #if 0 if(!g_testing && g_event_start.next->rel_time > 2000000) { printf("Z:start.next->rel_time: %d, duff_cycles: %d\n", g_event_start.next->rel_time, duff_cycles); halt_printf("Zrun_cycles:%d, cycles:%d\n", run_cycles, cycles); show_all_events(); } #endif if(halt_sim != 0 && halt_sim != HALT_EVENT) { break; } if(g_stepping) { break; } } if(!g_testing) { printf("leaving run_prog, halt_sim:%d\n", halt_sim); } x_auto_repeat_on(0); } void add_irq(word32 irq_mask) { if(g_irq_pending & irq_mask) { /* Already requested, just get out */ return; } g_irq_pending |= irq_mask; set_halt(HALT_EVENT); } void remove_irq(word32 irq_mask) { g_irq_pending = g_irq_pending & (~irq_mask); } void take_irq(int is_it_brk) { word32 new_kpc; word32 va; irq_printf("Taking irq, at: %02x/%04x, psw: %02x, dcycs: %f\n", engine.kpc>>16, engine.kpc & 0xffff, engine.psr, g_cur_dcycs); g_num_irq++; if(g_wait_pending) { /* step over WAI instruction */ engine.kpc++; g_wait_pending = 0; } if(engine.psr & 0x100) { /* Emulation */ set_memory_c(engine.stack, (engine.kpc >> 8) & 0xff, 0); engine.stack = ((engine.stack -1) & 0xff) + 0x100; set_memory_c(engine.stack, engine.kpc & 0xff, 0); engine.stack = ((engine.stack -1) & 0xff) + 0x100; set_memory_c(engine.stack, (engine.psr & 0xef)|(is_it_brk<<4),0); /* Clear B bit in psr on stack */ engine.stack = ((engine.stack -1) & 0xff) + 0x100; va = 0xfffffe; if(g_c035_shadow_reg & 0x40) { /* I/O shadowing off...use ram locs */ va = 0x00fffe; } } else { /* native */ set_memory_c(engine.stack, (engine.kpc >> 16) & 0xff, 0); engine.stack = ((engine.stack -1) & 0xffff); set_memory_c(engine.stack, (engine.kpc >> 8) & 0xff, 0); engine.stack = ((engine.stack -1) & 0xffff); set_memory_c(engine.stack, engine.kpc & 0xff, 0); engine.stack = ((engine.stack -1) & 0xffff); set_memory_c(engine.stack, engine.psr & 0xff, 0); engine.stack = ((engine.stack -1) & 0xffff); if(is_it_brk) { /* break */ va = 0xffffe6; if(g_c035_shadow_reg & 0x40) { va = 0xffe6; } } else { /* irq */ va = 0xffffee; if(g_c035_shadow_reg & 0x40) { va = 0xffee; } } } new_kpc = get_memory_c(va, 0); new_kpc = new_kpc + (get_memory_c(va+1, 0) << 8); engine.psr = ((engine.psr & 0x1f3) | 0x4); engine.kpc = new_kpc; HALT_ON(HALT_ON_IRQ, "Halting on IRQ\n"); } double g_dtime_last_vbl = 0.0; double g_dtime_expected = (1.0/60.0); int g_scan_int_events = 0; void show_dtime_array() { double dfirst_time; double first_total_cycs; int i; int pos; dfirst_time = 0.0; first_total_cycs = 0.0; for(i = 0; i < 60; i++) { pos = (g_vbl_index_count + i) % 60; printf("%2d:%2d dt:%.5f adjc:%9.1f this_vbl:%.6f " "exp:%.5f p:%2.2f ep:%2.2f\n", i, pos, dtime_array[pos] - dfirst_time, g_dadjcycs_array[pos] - first_total_cycs, g_dtime_this_vbl_array[pos], g_dtime_exp_array[pos] - dfirst_time, g_dtime_pmhz_array[pos], g_dtime_eff_pmhz_array[pos]); dfirst_time = dtime_array[pos]; first_total_cycs = g_dadjcycs_array[pos]; } } extern word32 g_cycs_in_40col; extern word32 g_cycs_in_xredraw; extern word32 g_cycs_in_check_input; extern word32 g_cycs_in_refresh_line; extern word32 g_cycs_in_refresh_ximage; extern word32 g_cycs_in_io_read; extern word32 g_cycs_in_sound1; extern word32 g_cycs_in_sound2; extern word32 g_cycs_in_sound3; extern word32 g_cycs_in_sound4; extern word32 g_cycs_in_start_sound; extern word32 g_cycs_in_est_sound; extern word32 g_refresh_bytes_xfer; extern int g_num_snd_plays; extern int g_num_doc_events; extern int g_num_start_sounds; extern int g_num_scan_osc; extern int g_num_recalc_snd_parms; extern float g_fvoices; extern int g_doc_vol; extern int g_a2vid_palette; extern int g_status_refresh_needed; void update_60hz(double dcycs, double dtime_now) { register word32 end_time; char status_buf[1024]; char sim_mhz_buf[128]; char total_mhz_buf[128]; char *sim_mhz_ptr, *total_mhz_ptr; char *code_str1, *code_str2, *sp_str; double eff_pmhz; double planned_dcycs; double predicted_pmhz; double recip_predicted_pmhz; double dtime_this_vbl_sim; double dtime_diff_1sec; double dratio; double dtime_till_expected; double dtime_diff; double dtime_this_vbl; double dadjcycs_this_vbl; double dadj_cycles_1sec; double dtmp1, dtmp2, dtmp3, dtmp4, dtmp5; double dnatcycs_1sec; int tmp; int doit_3_persec; int cur_vbl_index; int prev_vbl_index; g_vbl_count++; /* NOTE: this event is defined to occur before line 0 */ /* It's actually happening at the start of the border for line (-1) */ /* All other timings should be adjusted for this */ irq_printf("vbl_60hz: vbl: %d, dcycs: %f, last_vbl_dcycs: %f\n", g_vbl_count, dcycs, g_last_vbl_dcycs); planned_dcycs = DCYCS_IN_16MS; g_last_vbl_dcycs = g_last_vbl_dcycs + planned_dcycs; add_event_entry(g_last_vbl_dcycs + planned_dcycs, EV_60HZ); check_for_one_event_type(EV_60HZ); cur_vbl_index = g_vbl_index_count; /* figure out dtime spent running SIM, not all the overhead */ dtime_this_vbl_sim = g_cur_sim_dtime; g_cur_sim_dtime = 0.0; g_sim_sum = g_sim_sum - sim_time[cur_vbl_index] + dtime_this_vbl_sim; sim_time[cur_vbl_index] = dtime_this_vbl_sim; dadj_cycles_1sec = g_dadjcycs - g_dadjcycs_array[cur_vbl_index]; /* dtime_diff_1sec is dtime total spent over the last 60 ticks */ dtime_diff_1sec = dtime_now - dtime_array[cur_vbl_index]; dtime_array[cur_vbl_index] = dtime_now; g_dadjcycs_array[cur_vbl_index] = g_dadjcycs; prev_vbl_index = cur_vbl_index; cur_vbl_index = prev_vbl_index + 1; if(cur_vbl_index >= 60) { cur_vbl_index = 0; } g_vbl_index_count = cur_vbl_index; GET_ITIMER(end_time); g_dnatcycs_1sec += (double)(end_time - g_natcycs_lastvbl); g_natcycs_lastvbl = end_time; if(prev_vbl_index == 0) { if(g_sim_sum < (1.0/250.0)) { sim_mhz_ptr = "???"; g_sim_mhz = 250.0; } else { g_sim_mhz = (dadj_cycles_1sec / g_sim_sum) / (1000.0*1000.0); sprintf(sim_mhz_buf, "%6.2f", g_sim_mhz); sim_mhz_ptr = sim_mhz_buf; } if(dtime_diff_1sec < (1.0/250.0)) { total_mhz_ptr = "???"; } else { sprintf(total_mhz_buf, "%6.2f", (dadj_cycles_1sec / dtime_diff_1sec) / (1000000.0)); total_mhz_ptr = total_mhz_buf; } switch(g_limit_speed) { case 1: sp_str = "1Mhz"; break; case 2: sp_str = "2.8Mhz"; break; case 3: sp_str = "8.0Mhz"; break; default: sp_str = "Unlimited"; break; } sprintf(status_buf, "dcycs:%9.1f sim MHz:%s " "Eff MHz:%s, sec:%1.3f vol:%02x pal:%x, Limit:%s", dcycs/(1000.0*1000.0), sim_mhz_ptr, total_mhz_ptr, dtime_diff_1sec, g_doc_vol, g_a2vid_palette, sp_str); video_update_status_line(0, status_buf); if(g_video_line_update_interval == 0) { if(g_sim_mhz > 12.0) { /* just set video line_ref_amt to 1 */ g_line_ref_amt = 1; } else if(g_line_ref_amt == 1 && g_sim_mhz < 4.0) { g_line_ref_amt = 8; } } else { g_line_ref_amt = g_video_line_update_interval; } if(g_dnatcycs_1sec < (1000.0*1000.0)) { /* make it so large that all %'s become 0 */ g_dnatcycs_1sec = 800.0*1000.0*1000.0*1000.0; } dnatcycs_1sec = g_dnatcycs_1sec / 100.0; /* eff mult by 100 */ dtmp2 = (double)(g_cycs_in_check_input) / dnatcycs_1sec; dtmp3 = (double)(g_cycs_in_refresh_line) / dnatcycs_1sec; dtmp4 = (double)(g_cycs_in_refresh_ximage) / dnatcycs_1sec; sprintf(status_buf, "xfer:%08x, %5.1f ref_amt:%d " "ch_in:%4.1f%% ref_l:%4.1f%% ref_x:%4.1f%%", g_refresh_bytes_xfer, g_dnatcycs_1sec/(1000.0*1000.0), g_line_ref_amt, dtmp2, dtmp3, dtmp4); video_update_status_line(1, status_buf); sprintf(status_buf, "Ints:%3d I/O:%4dK BRK:%3d COP:%2d " "Eng:%3d act:%3d hev:%3d esi:%3d edi:%3d", g_num_irq, g_io_amt>>10, g_num_brk, g_num_cop, g_num_enter_engine, g_engine_action, g_engine_halt_event, g_engine_scan_int, g_engine_doc_int); video_update_status_line(2, status_buf); dtmp1 = (double)(g_cycs_in_sound1) / dnatcycs_1sec; dtmp2 = (double)(g_cycs_in_sound2) / dnatcycs_1sec; dtmp3 = (double)(g_cycs_in_sound3) / dnatcycs_1sec; dtmp4 = (double)(g_cycs_in_start_sound) / dnatcycs_1sec; dtmp5 = (double)(g_cycs_in_est_sound) / dnatcycs_1sec; sprintf(status_buf, "snd1:%4.1f%%, 2:%4.1f%%, " "3:%4.1f%%, st:%4.1f%% est:%4.1f%% %4.2f", dtmp1, dtmp2, dtmp3, dtmp4, dtmp5, g_fvoices); video_update_status_line(3, status_buf); code_str1 = ""; code_str2 = ""; if(g_code_yellow) { code_str1 = "Code: Yellow"; code_str2 = "Emulated system state suspect, save work"; } if(g_code_red) { code_str1 = "Code: RED"; code_str2 = "Emulated system state probably corrupt"; } sprintf(status_buf, "snd_plays:%4d, doc_ev:%4d, st_snd:%4d " "snd_parms: %4d %s", g_num_snd_plays, g_num_doc_events, g_num_start_sounds, g_num_recalc_snd_parms, code_str1); video_update_status_line(4, status_buf); draw_iwm_status(5, status_buf); sprintf(status_buf, "KEGS v%-6s " "Press F4 for Config Menu %s", g_kegs_version_str, code_str2); video_update_status_line(6, status_buf); g_status_refresh_needed = 1; g_num_irq = 0; g_num_brk = 0; g_num_cop = 0; g_num_enter_engine = 0; g_io_amt = 0; g_engine_action = 0; g_engine_halt_event = 0; g_engine_scan_int = 0; g_engine_doc_int = 0; g_cycs_in_40col = 0; g_cycs_in_xredraw = 0; g_cycs_in_check_input = 0; g_cycs_in_refresh_line = 0; g_cycs_in_refresh_ximage = 0; g_cycs_in_io_read = 0; g_cycs_in_sound1 = 0; g_cycs_in_sound2 = 0; g_cycs_in_sound3 = 0; g_cycs_in_sound4 = 0; g_cycs_in_start_sound = 0; g_cycs_in_est_sound = 0; g_dnatcycs_1sec = 0.0; g_refresh_bytes_xfer = 0; g_num_snd_plays = 0; g_num_doc_events = 0; g_num_start_sounds = 0; g_num_scan_osc = 0; g_num_recalc_snd_parms = 0; g_fvoices = (float)0.0; } dtime_this_vbl = dtime_now - g_dtime_last_vbl; if(dtime_this_vbl < 0.001) { dtime_this_vbl = 0.001; } g_dtime_last_vbl = dtime_now; dadjcycs_this_vbl = g_dadjcycs - g_last_vbl_dadjcycs; g_last_vbl_dadjcycs = g_dadjcycs; g_dtime_expected += (1.0/60.0); eff_pmhz = ((dadjcycs_this_vbl) / (dtime_this_vbl)) / DCYCS_1_MHZ; /* using eff_pmhz, predict how many cycles can be run by */ /* g_dtime_expected */ dtime_till_expected = g_dtime_expected - dtime_now; dratio = 60.0 * dtime_till_expected; predicted_pmhz = eff_pmhz * dratio; if(! (predicted_pmhz < (1.4 * g_projected_pmhz))) { predicted_pmhz = 1.4 * g_projected_pmhz; } if(! (predicted_pmhz > (0.7 * g_projected_pmhz))) { predicted_pmhz = 0.7 * g_projected_pmhz; } if(!(predicted_pmhz >= 1.0)) { irq_printf("predicted: %f, setting to 1.0\n", predicted_pmhz); predicted_pmhz = 1.0; } if(!(predicted_pmhz < 250.0)) { irq_printf("predicted: %f, setting to 250.0\n", predicted_pmhz); predicted_pmhz = 250.0; } recip_predicted_pmhz = 1.0/predicted_pmhz; g_projected_pmhz = predicted_pmhz; g_recip_projected_pmhz_unl.plus_1 = 1.0*recip_predicted_pmhz; g_recip_projected_pmhz_unl.plus_2 = 2.0*recip_predicted_pmhz; g_recip_projected_pmhz_unl.plus_3 = 3.0*recip_predicted_pmhz; g_recip_projected_pmhz_unl.plus_x_minus_1 = 1.01 - recip_predicted_pmhz; if(dtime_till_expected < -0.125) { /* If we were way off, get back on track */ /* this happens because our sim took much longer than */ /* expected, so we're going to skip some VBL */ irq_printf("adj1: dtexp:%f, dt_new:%f\n", g_dtime_expected, dtime_now); dtime_diff = -dtime_till_expected; irq_printf("dtime_till_exp: %f, dtime_diff: %f, dcycs: %f\n", dtime_till_expected, dtime_diff, dcycs); g_dtime_expected += dtime_diff; } if(dtime_till_expected > (3/60.0)) { /* we're running fast, usleep */ micro_sleep(dtime_till_expected - (1/60.0)); } g_dtime_this_vbl_array[prev_vbl_index] = dtime_this_vbl; g_dtime_exp_array[prev_vbl_index] = g_dtime_expected; g_dtime_pmhz_array[prev_vbl_index] = predicted_pmhz; g_dtime_eff_pmhz_array[prev_vbl_index] = eff_pmhz; if(g_c041_val & C041_EN_VBL_INTS) { add_event_vbl(); } g_25sec_cntr++; if(g_25sec_cntr >= 16) { g_25sec_cntr = 0; if(g_c041_val & C041_EN_25SEC_INTS) { add_irq(IRQ_PENDING_C046_25SEC); g_c046_val |= 0x10; irq_printf("Setting c046 .25 sec int, g_irq_pend:%d\n", g_irq_pending); } } g_1sec_cntr++; if(g_1sec_cntr >= 60) { g_1sec_cntr = 0; tmp = g_c023_val; tmp |= 0x40; /* set 1sec int */ if(tmp & 0x04) { tmp |= 0x80; add_irq(IRQ_PENDING_C023_1SEC); irq_printf("Setting c023 to %02x irq_pend: %d\n", tmp, g_irq_pending); } g_c023_val = tmp; } if(!g_scan_int_events) { check_scan_line_int(dcycs, 0); } doit_3_persec = 0; if(g_config_iwm_vbl_count > 0) { g_config_iwm_vbl_count--; } else { g_config_iwm_vbl_count = 20; doit_3_persec = 1; } iwm_vbl_update(doit_3_persec); config_vbl_update(doit_3_persec); video_update(); sound_update(dcycs); clock_update(); scc_update(dcycs); paddle_update_buttons(); } void do_vbl_int() { if(g_c041_val & C041_EN_VBL_INTS) { g_c046_val |= 0x08; add_irq(IRQ_PENDING_C046_VBL); irq_printf("Setting c046 vbl_int_status to 1, irq_pend: %d\n", g_irq_pending); } } void do_scan_int(double dcycs, int line) { int c023_val; g_scan_int_events = 0; c023_val = g_c023_val; if(c023_val & 0x20) { halt_printf("c023 scan_int and another on line %03x\n", line); } /* make sure scan int is still enabled for this line */ if((g_slow_memory_ptr[0x19d00 + line] & 0x40) && (g_cur_a2_stat & ALL_STAT_SUPER_HIRES)) { /* valid interrupt, do it */ c023_val |= 0xa0; /* vgc_int and scan_int */ if(c023_val & 0x02) { add_irq(IRQ_PENDING_C023_SCAN); irq_printf("Setting c023 to %02x, irq_pend: %d\n", c023_val, g_irq_pending); } g_c023_val = c023_val; HALT_ON(HALT_ON_SCAN_INT, "In do_scan_int\n"); } else { /* scan int bit cleared on scan line control byte */ /* look for next line, if any */ check_scan_line_int(dcycs, line+1); } } void check_scan_line_int(double dcycs, int cur_video_line) { int delay; int start; int line; int i; /* Called during VBL interrupt phase */ if(!(g_cur_a2_stat & ALL_STAT_SUPER_HIRES)) { return; } if(g_c023_val & 0x20) { /* don't check for any more */ return; } start = cur_video_line; if(start < 0) { halt_printf("check_scan_line_int: cur_video_line: %d\n", cur_video_line); start = 0; } for(line = start; line < 200; line++) { i = line; if(i < 0 || i >= 200) { halt_printf("check_new_scan_int:i:%d, line:%d, st:%d\n", i, line, start); i = 0; } if(g_slow_memory_ptr[0x19d00+i] & 0x40) { irq_printf("Adding scan_int for line %d\n", i); delay = (DCYCS_IN_16MS/262.0) * ((double)line); add_event_entry(g_last_vbl_dcycs + delay, EV_SCAN_INT + (line << 8)); g_scan_int_events = 1; check_for_one_event_type(EV_SCAN_INT); break; } } } void check_for_new_scan_int(double dcycs) { int cur_video_line; cur_video_line = get_lines_since_vbl(dcycs) >> 8; check_scan_line_int(dcycs, cur_video_line); } void init_reg() { engine.acc = 0; engine.xreg = 0; engine.yreg = 0; engine.stack = 0x1ff; engine.direct = 0; engine.psr = 0x134; engine.fplus_ptr = 0; } void handle_action(word32 ret) { int type; type = EXTRU(ret,3,4); switch(type) { case RET_BREAK: do_break(ret & 0xff); break; case RET_COP: do_cop(ret & 0xff); break; #if 0 case RET_MVN: do_mvn(ret & 0xffff); break; #endif case RET_C700: do_c700(ret); break; case RET_C70A: do_c70a(ret); break; case RET_C70D: do_c70d(ret); break; #if 0 case RET_ADD_DEC_8: do_add_dec_8(ret); break; case RET_ADD_DEC_16: do_add_dec_16(ret); break; #endif case RET_IRQ: irq_printf("Special fast IRQ response. irq_pending: %x\n", g_irq_pending); break; case RET_WDM: do_wdm(ret & 0xff); break; case RET_STP: do_stp(); break; default: halt_printf("Unknown special action: %08x!\n", ret); } } #if 0 void do_add_dec_8(word32 ret) { halt_printf("do_add_dec_8 called, ret: %08x\n", ret); } void do_add_dec_16(word32 ret) { halt_printf("do_add_dec_16 called, ret: %08x\n", ret); } #endif void do_break(word32 ret) { if(!g_testing) { printf("I think I got a break, second byte: %02x!\n", ret); printf("kpc: %06x\n", engine.kpc); } halt_printf("do_break, kpc: %06x\n", engine.kpc); enter_debug = 1; } void do_cop(word32 ret) { halt_printf("COP instr %02x!\n", ret); fflush(stdout); } #if 0 void do_mvn(word32 banks) { int src_bank, dest_bank; int dest, src; int num; int i; int val; halt_printf("In MVN...just quitting\n"); return; printf("MVN instr with %04x, cycles: %08x\n", banks, engine.cycles); src_bank = banks >> 8; dest_bank = banks & 0xff; printf("psr: %03x\n", engine.psr); if((engine.psr & 0x30) != 0) { halt_printf("MVN in non-native mode unimplemented!\n"); } dest = dest_bank << 16 | engine.yreg; src = src_bank << 16 | engine.xreg; num = engine.acc; printf("Moving %08x+1 bytes from %08x to %08x\n", num, src, dest); for(i = 0; i <= num; i++) { val = get_memory_c(src, 0); set_memory_c(dest, val, 0); src = (src_bank << 16) | ((src + 1) & 0xffff); dest = (dest_bank << 16) | ((dest + 1) & 0xffff); } engine.dbank = dest_bank; engine.acc = 0xffff; engine.yreg = dest & 0xffff; engine.xreg = src & 0xffff; engine.kpc = (engine.kpc + 3); printf("move done. db: %02x, acc: %04x, y: %04x, x: %04x, num: %08x\n", engine.dbank, engine.acc, engine.yreg, engine.xreg, num); } #endif void do_wdm(word32 arg) { switch(arg) { case 0x8d: /* Bouncin Ferno does WDM 8d */ break; default: halt_printf("do_wdm: %02x!\n", arg); } } void do_wai() { halt_printf("do_wai!\n"); } void do_stp() { if(!g_stp_pending) { g_stp_pending = 1; halt_printf("Hit STP instruction at: %06x, press RESET to " "continue\n", engine.kpc); } } void size_fail(int val, word32 v1, word32 v2) { halt_printf("Size failure, val: %08x, %08x %08x\n", val, v1, v2); } int fatal_printf(const char *fmt, ...) { va_list ap; int ret; va_start(ap, fmt); if(g_fatal_log < 0) { g_fatal_log = 0; } ret = kegs_vprintf(fmt, ap); va_end(ap); return ret; } int kegs_vprintf(const char *fmt, va_list ap) { char *bufptr, *buf2ptr; int len; int ret; bufptr = malloc(4096); ret = vsnprintf(bufptr, 4090, fmt, ap); len = strlen(bufptr); if(g_fatal_log >= 0 && g_fatal_log < MAX_FATAL_LOGS) { buf2ptr = malloc(len+1); memcpy(buf2ptr, bufptr, len+1); g_fatal_log_strs[g_fatal_log++] = buf2ptr; } must_write(1, bufptr, len); if(g_debug_file_fd >= 0) { must_write(g_debug_file_fd, bufptr, len); } free(bufptr); return ret; } void must_write(int fd, char *bufptr, int len) { int ret; while(len > 0) { ret = write(fd, bufptr, len); if(ret >= 0) { len -= ret; bufptr += ret; } else if(errno != EAGAIN && errno != EINTR) { return; // just get out } } } void clear_fatal_logs() { int i; for(i = 0; i < g_fatal_log; i++) { free(g_fatal_log_strs[i]); g_fatal_log_strs[i] = 0; } g_fatal_log = -1; } char * kegs_malloc_str(char *in_str) { char *str; int len; len = strlen(in_str) + 1; str = malloc(len); memcpy(str, in_str, len); return str; }