/* ScummVM - Graphic Adventure Engine * * ScummVM is the legal property of its developers, whose names * are too numerous to list here. Please refer to the COPYRIGHT * file distributed with this source distribution. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * */ #include "glk/magnetic/magnetic_defs.h" #include "glk/magnetic/magnetic.h" #include "common/file.h" #include "common/textconsole.h" namespace Glk { namespace Magnetic { const char *const no_hints = "[Hints are not available.]\n"; const char *const not_supported = "[This function is not supported.]\n"; const char *const undo_ok = "\n[Previous turn undone.]"; const char *const undo_fail = "\n[You can't \"undo\" what hasn't been done!]"; #define ms_fatal error #if defined(LOGEMU) || defined(LOGGFX) || defined(LOGHNT) FILE *dbg_log; #ifndef LOG_FILE #error LOG_FILE must be defined to be the name of the log file. #endif #endif #ifdef LOGEMU void out(char *format, ...) { va_list a; va_start(a, format); vfprintf(dbg_log, format, a); va_end(a); } #endif #if defined(LOGGFX) || defined(LOGHNT) void out2(char *format, ...) { va_list a; va_start(a, format); vfprintf(dbg_log, format, a); va_end(a); fflush(dbg_log); } #endif /* Convert virtual pointer to effective pointer */ type8 *Magnetic::effective(type32 ptr) { if ((version < 4) && (mem_size == 0x10000)) return &(code[ptr & 0xffff]); if (ptr >= mem_size) { ms_fatal("Outside memory experience"); return code; } return &(code[ptr]); } void Magnetic::write_l(type8 *ptr, type32 val) { ptr[3] = (type8) val; val >>= 8; ptr[2] = (type8) val; val >>= 8; ptr[1] = (type8) val; val >>= 8; ptr[0] = (type8) val; } void Magnetic::write_w(type8 *ptr, type16 val) { ptr[1] = (type8) val; val >>= 8; ptr[0] = (type8) val; } type32 Magnetic::rand_emu() { rseed = 1103515245L * rseed + 12345L; return rseed & 0x7fffffffL; } void Magnetic::ms_freemem() { if (code) free(code); if (string) free(string); if (string2) free(string2); if (string3) free(string3); if (dict) free(dict); if (undo[0]) free(undo[0]); if (undo[1]) free(undo[1]); if (restart) free(restart); code = string = string2 = string3 = dict = undo[0] = undo[1] = restart = 0; if (gfx_data) free(gfx_data); if (gfx_buf) free(gfx_buf); if (gfx2_hdr) free(gfx2_hdr); if (gfx2_buf) free(gfx2_buf); delete gfx_fp; gfx_data = gfx_buf = gfx2_hdr = gfx2_buf = nullptr; gfx2_name = 0; gfx_fp = nullptr; gfx_ver = 0; gfxtable = table_dist = 0; #ifndef NO_ANIMATION pos_table_size = 0; command_index = 0; anim_repeat = 0; pos_table_index = -1; pos_table_max = -1; #endif lastchar = 0; if (hints) free(hints); if (hint_contents) free(hint_contents); hints = 0; hint_contents = 0; if (snd_hdr) free(snd_hdr); if (snd_buf) free(snd_buf); snd_hdr = nullptr; snd_hsize = 0; snd_buf = nullptr; } type8 Magnetic::init_gfx1(type8 *header) { #ifdef SAVEMEM type32 i; #endif if (!(gfx_buf = (type8 *)malloc(MAX_PICTURE_SIZE))) { delete gfx_fp; gfx_fp = nullptr; return 1; } #ifdef SAVEMEM if (!(gfx_data = (type8 *)malloc(128))) { #else if (!(gfx_data = (type8 *)malloc(read_l(header + 4) - 8))) { #endif free(gfx_buf); delete gfx_fp; gfx_buf = nullptr; gfx_fp = nullptr; return 1; } #ifdef SAVEMEM if (!fp.read(gfx_data, 128, 1, gfx_fp)) { #else if (gfx_fp->read(gfx_data, read_l(header + 4)) != read_l(header + 4)) { #endif free(gfx_data); free(gfx_buf); delete gfx_fp; gfx_data = gfx_buf = nullptr; gfx_fp = nullptr; return 1; } #ifdef SAVEMEM for (i = 0; i < 128; i += 4) if (!read_l(gfx_data + i)) write_l(gfx_data + i, read_l(header + 4)); #else delete gfx_fp; gfx_fp = nullptr; #endif gfx_ver = 1; return 2; } type8 Magnetic::init_gfx2(type8 *header) { if (!(gfx_buf = (type8 *)malloc(MAX_PICTURE_SIZE))) { delete gfx_fp; gfx_fp = nullptr; return 1; } gfx2_hsize = read_w(header + 4); if (!(gfx2_hdr = (type8 *)malloc(gfx2_hsize))) { free(gfx_buf); delete gfx_fp; gfx_buf = nullptr; gfx_fp = nullptr; return 1; } gfx_fp->seek(6); if (gfx_fp->read(gfx2_hdr, gfx2_hsize) != gfx2_hsize) { free(gfx_buf); free(gfx2_hdr); delete gfx_fp; gfx_buf = nullptr; gfx2_hdr = 0; gfx_fp = nullptr; return 1; } gfx_ver = 2; return 2; } type8 Magnetic::init_snd(type8 *header) { if (!(snd_buf = (type8 *)malloc(MAX_MUSIC_SIZE))) { delete snd_fp; snd_fp = nullptr; return 1; } snd_hsize = read_w(header + 4); if (!(snd_hdr = (type8 *)malloc(snd_hsize))) { free(snd_buf); delete snd_fp; snd_buf = nullptr; snd_fp = nullptr; return 1; } snd_fp->seek(6); if (snd_fp->read(snd_hdr, snd_hsize) != snd_hsize) { free(snd_buf); free(snd_hdr); delete snd_fp; snd_buf = nullptr; snd_hdr = nullptr; snd_fp = nullptr; return 1; } return 2; } type8 Magnetic::ms_init(const char *name, const char *gfxname, const char *hntname, const char *sndname) { Common::File fp; type8 header[42], header2[8], header3[4]; type32 i, dict_size, string2_size, code_size, dec; #if defined(LOGEMU) || defined(LOGGFX) || defined(LOGHNT) dbg_log = fopen(LOG_FILE, "wt"); #endif ms_stop(); if (!name) { if (!restart) return 0; else { memcpy(code, restart, undo_size); undo_stat[0] = undo_stat[1] = 0; ms_showpic(0, 0); } } else { undo_stat[0] = undo_stat[1] = 0; if (!fp.open(name)) return 0; if ((fp.read(header, 42) != 42) || (read_l(header) != 0x4d615363)) return 0; if (read_l(header + 8) != 42) return 0; ms_freemem(); version = header[13]; code_size = read_l(header + 14); string_size = read_l(header + 18); string2_size = read_l(header + 22); dict_size = read_l(header + 26); undo_size = read_l(header + 34); undo_pc = read_l(header + 38); if ((version < 4) && (code_size < 65536)) mem_size = 65536; else mem_size = code_size; /* Some C libraries don't like malloc(0), so make sure that undo_size is always positive. */ if (undo_size == 0) undo_size = 8; sd = (type8)((dict_size != 0L) ? 1 : 0); /* if (sd) => separate dict */ if (!(code = (type8 *)malloc(mem_size)) || !(string2 = (type8 *)malloc(string2_size)) || !(restart = (type8 *)malloc(undo_size)) || (sd && !(dict = (type8 *)malloc(dict_size)))) { ms_freemem(); fp.close(); return 0; } if (string_size > MAX_STRING_SIZE) { if (!(string = (type8 *)malloc(MAX_STRING_SIZE)) || !(string3 = (type8 *)malloc(string_size - MAX_STRING_SIZE))) { ms_freemem(); fp.close(); return 0; } } else { if (!(string = (type8 *)malloc(string_size))) { ms_freemem(); fp.close(); return 0; } } if (!(undo[0] = (type8 *)malloc(undo_size)) || !(undo[1] = (type8 *)malloc(undo_size))) { ms_freemem(); fp.close(); return 0; } if (fp.read(code, code_size) != code_size) { ms_freemem(); fp.close(); return 0; } memcpy(restart, code, undo_size); /* fast restarts */ if (string_size > MAX_STRING_SIZE) { if (fp.read(string, MAX_STRING_SIZE) != MAX_STRING_SIZE) { ms_freemem(); fp.close(); return 0; } if (fp.read(string3, string_size - MAX_STRING_SIZE) != string_size - MAX_STRING_SIZE) { ms_freemem(); fp.close(); return 0; } } else { if (fp.read(string, string_size) != string_size) { ms_freemem(); fp.close(); return 0; } } if (fp.read(string2, string2_size) != string2_size) { ms_freemem(); fp.close(); return 0; } if (sd && fp.read(dict, dict_size) != dict_size) { ms_freemem(); fp.close(); return 0; } dec = read_l(header + 30); if (dec >= string_size) decode_table = string2 + dec - string_size; else { if (dec >= MAX_STRING_SIZE) decode_table = string3 + dec - MAX_STRING_SIZE; else decode_table = string + dec; } fp.close(); } for (i = 0; i < 8; i++) dreg[i] = areg[i] = 0; write_reg(8 + 7, 2, 0xfffe); /* Stack-pointer, -2 due to MS-DOS segments */ pc = 0; zflag = nflag = cflag = vflag = 0; i_count = 0; running = 1; if (!name) return (type8)(gfx_buf ? 2 : 1); /* Restarted */ if (version == 4) { /* Try loading a hint file */ Common::File hnt_fp; if (hntname && hnt_fp.open(hntname)) { if ((hnt_fp.read(&header3, 4) == 4) && (read_l(header3) == 0x4D614874)) { type8 buf[8]; type16 j, blkcnt, elcnt, ntype, elsize, conidx; /* Allocate memory for hints */ hints = (ms_hint *)malloc(MAX_HINTS * sizeof(struct ms_hint)); hint_contents = (type8 *)malloc(MAX_HCONTENTS); if ((hints != 0) && (hint_contents != 0)) { /* Read number of blocks */ if (hnt_fp.read(&buf, 2) != 2 && !hnt_fp.eos()) return 0; blkcnt = read_w2(buf); #ifdef LOGHNT out2("Blocks: %d\n", blkcnt); #endif conidx = 0; for (i = 0; i < blkcnt; i++) { #ifdef LOGHNT out2("\nBlock No. %d\n", i); #endif /* Read number of elements */ if (hnt_fp.read(&buf, 2) != 2 && !hnt_fp.eos()) return 0; elcnt = read_w2(buf); #ifdef LOGHNT out2("Elements: %d\n", elcnt); #endif hints[i].elcount = elcnt; /* Read node type */ if (hnt_fp.read(&buf, 2) != 2 && !hnt_fp.eos()) return 0; ntype = read_w2(buf); #ifdef LOGHNT if (ntype == 1) out2("Type: Node\n"); else out2("Type: Leaf\n"); #endif hints[i].nodetype = ntype; hints[i].content = (const char *)hint_contents + conidx; #ifdef LOGHNT out2("Elements:\n"); #endif for (j = 0; j < elcnt; j++) { if (hnt_fp.read(&buf, 2) != 2 && !hnt_fp.eos()) return 0; elsize = read_w2(buf); if (hnt_fp.read(hint_contents + conidx, elsize) != elsize && !hnt_fp.eos()) return 0; hint_contents[conidx + elsize - 1] = '\0'; #ifdef LOGHNT out2("%s\n", hint_contents + conidx); #endif conidx += elsize; } /* Do we need a jump table? */ if (ntype == 1) { #ifdef LOGHNT out2("Jump to block:\n"); #endif for (j = 0; j < elcnt; j++) { if (hnt_fp.read(&buf, 2) != 2 && !hnt_fp.eos()) return 0; hints[i].links[j] = read_w2(buf); #ifdef LOGHNT out2("%d\n", hints[i].links[j]); #endif } } /* Read the parent block */ if (hnt_fp.read(&buf, 2) != 2 && !hnt_fp.eos()) return 0; hints[i].parent = read_w2(buf); #ifdef LOGHNT out2("Parent: %d\n", hints[i].parent); #endif } } else { if (hints) free(hints); if (hint_contents) free(hint_contents); hints = 0; hint_contents = 0; } } hnt_fp.close(); } /* Try loading a music file */ snd_fp = new Common::File(); if (sndname && snd_fp->open(sndname)) { if (snd_fp->read(&header2, 8) != 8) { delete snd_fp; snd_fp = nullptr; } else { if (read_l(header2) == 0x4D615364) { /* MaSd */ init_snd(header2); #ifdef LOGSND out2("Sound file loaded.\n"); #endif } } } else { delete snd_fp; snd_fp = nullptr; } } if (!gfxname) return 1; gfx_fp = new Common::File(); if (!gfx_fp->open(gfxname) || gfx_fp->read(&header2, 8) != 8) { delete gfx_fp; gfx_fp = nullptr; return 1; } if (version < 4 && read_l(header2) == 0x4D615069) /* MaPi */ return init_gfx1(header2); else if (version == 4 && read_l(header2) == 0x4D615032) /* MaP2 */ return init_gfx2(header2); delete gfx_fp; gfx_fp = nullptr; return 1; } type8 Magnetic::is_blank(type16 line, type16 width) { type32s i; for (i = line * width; i < (line + 1) * width; i++) if (gfx_buf[i]) return 0; return 1; } type8 *Magnetic::ms_extract1(type8 pic, type16 *w, type16 *h, type16 *pal) { type8 *decodeTable, *data, bit, val, *buf; type16 tablesize, count; type32 i, j, upsize, offset; offset = read_l(gfx_data + 4 * pic); #ifdef SAVEMEM type32 datasize; if (fseek(gfx_fp, offset, SEEK_SET) < 0) return 0; datasize = read_l(gfx_data + 4 * (pic + 1)) - offset; if (!(buf = (type8 *)malloc(datasize))) return 0; if (fp.read(buf, 1, datasize, gfx_fp) != datasize) return 0; #else buf = gfx_data + offset - 8; #endif for (i = 0; i < 16; i++) pal[i] = read_w(buf + 0x1c + 2 * i); w[0] = (type16)(read_w(buf + 4) - read_w(buf + 2)); h[0] = read_w(buf + 6); tablesize = read_w(buf + 0x3c); //datasize = read_l(buf + 0x3e); decodeTable = buf + 0x42; data = decodeTable + tablesize * 2 + 2; upsize = h[0] * w[0]; for (i = 0, j = 0, count = 0, val = 0, bit = 7; i < upsize; i++, count--) { if (!count) { count = tablesize; while (count < 0x80) { if (data[j] & (1 << bit)) count = decodeTable[2 * count]; else count = decodeTable[2 * count + 1]; if (!bit) j++; bit = (type8)(bit ? bit - 1 : 7); } count &= 0x7f; if (count >= 0x10) count -= 0x10; else { val = (type8)count; count = 1; } } gfx_buf[i] = val; } for (j = w[0]; j < upsize; j++) gfx_buf[j] ^= gfx_buf[j - w[0]]; #ifdef SAVEMEM free(buf); #endif for (; h[0] > 0 && is_blank((type16)(h[0] - 1), w[0]); h[0]--); for (i = 0; h[0] > 0 && is_blank((type16)i, w[0]); h[0]--, i++); return gfx_buf + i * w[0]; } type16s Magnetic::find_name_in_header(const char *name, type8 upper) { type16s header_pos = 0; char pic_name[8]; type8 i; for (i = 0; i < 8; i++) pic_name[i] = 0; strncpy(pic_name, name, 6); if (upper) { for (i = 0; i < 8; i++) pic_name[i] = (char)toupper(pic_name[i]); } while (header_pos < gfx2_hsize) { const char *hname = (const char *)(gfx2_hdr + header_pos); if (strncmp(hname, pic_name, 6) == 0) return header_pos; header_pos += 16; } return -1; } void Magnetic::extract_frame(struct picture *pic) { type32 i, x, y, bit_x, mask, ywb, yw, value, values[4]; if (pic->width * pic->height > MAX_PICTURE_SIZE) { ms_fatal("picture too large"); return; } for (y = 0; y < pic->height; y++) { ywb = y * pic->wbytes; yw = y * pic->width; for (x = 0; x < pic->width; x++) { if ((x % 8) == 0) { for (i = 0; i < 4; i++) values[i] = pic->data[ywb + (x / 8) + (pic->plane_step * i)]; } bit_x = 7 - (x & 7); mask = 1 << bit_x; value = ((values[0] & mask) >> bit_x) << 0 | ((values[1] & mask) >> bit_x) << 1 | ((values[2] & mask) >> bit_x) << 2 | ((values[3] & mask) >> bit_x) << 3; value &= 15; gfx_buf[yw + x] = (type8)value; } } } type8 *Magnetic::ms_extract2(const char *name, type16 *w, type16 *h, type16 *pal, type8 *is_anim) { struct picture main_pic; type32 offset = 0, length = 0, i; type16s header_pos = -1; #ifndef NO_ANIMATION type8 *anim_data; type32 j; #endif if (is_anim != 0) *is_anim = 0; gfx2_name = name; #ifndef NO_ANIMATION pos_table_size = 0; #endif #ifdef NO_ANIMATION /* Find the uppercase (no animation) version of the picture first. */ header_pos = find_name_in_header(name, 1); #endif if (header_pos < 0) header_pos = find_name_in_header(name, 0); if (header_pos < 0) return 0; offset = read_l(gfx2_hdr + header_pos + 8); length = read_l(gfx2_hdr + header_pos + 12); if (offset != 0) { if (gfx2_buf) { free(gfx2_buf); gfx2_buf = nullptr; } gfx2_buf = (type8 *)malloc(length); if (!gfx2_buf) return 0; if (!gfx_fp->seek(offset)) { free(gfx2_buf); gfx2_buf = nullptr; return 0; } if (gfx_fp->read(gfx2_buf, length) != length) { free(gfx2_buf); gfx2_buf = nullptr; return 0; } for (i = 0; i < 16; i++) pal[i] = read_w2(gfx2_buf + 4 + (2 * i)); main_pic.data = gfx2_buf + 48; main_pic.data_size = read_l2(gfx2_buf + 38); main_pic.width = read_w2(gfx2_buf + 42); main_pic.height = read_w2(gfx2_buf + 44); main_pic.wbytes = (type16)(main_pic.data_size / main_pic.height); main_pic.plane_step = (type16)(main_pic.wbytes / 4); main_pic.mask = (type8 *)0; extract_frame(&main_pic); *w = main_pic.width; *h = main_pic.height; #ifndef NO_ANIMATION /* Check for an animation */ anim_data = gfx2_buf + 48 + main_pic.data_size; if ((anim_data[0] != 0xD0) || (anim_data[1] != 0x5E)) { type8 *current; type16 frame_count; type16 value1, value2; if (is_anim != 0) *is_anim = 1; current = anim_data + 6; frame_count = read_w2(anim_data + 2); if (frame_count > MAX_ANIMS) { ms_fatal("animation frame array too short"); return 0; } /* Loop through each animation frame */ for (i = 0; i < frame_count; i++) { anim_frame_table[i].data = current + 10; anim_frame_table[i].data_size = read_l2(current); anim_frame_table[i].width = read_w2(current + 4); anim_frame_table[i].height = read_w2(current + 6); anim_frame_table[i].wbytes = (type16)(anim_frame_table[i].data_size / anim_frame_table[i].height); anim_frame_table[i].plane_step = (type16)(anim_frame_table[i].wbytes / 4); anim_frame_table[i].mask = (type8 *)0; current += anim_frame_table[i].data_size + 12; value1 = read_w2(current - 2); value2 = read_w2(current); /* Get the mask */ if ((value1 == anim_frame_table[i].width) && (value2 == anim_frame_table[i].height)) { type16 skip; anim_frame_table[i].mask = (type8 *)(current + 4); skip = read_w2(current + 2); current += skip + 6; } } /* Get the positioning tables */ pos_table_size = read_w2(current - 2); if (pos_table_size > MAX_POSITIONS) { ms_fatal("animation position array too short"); return 0; } #ifdef LOGGFX_EXT out2("POSITION TABLE DUMP\n"); #endif for (i = 0; i < pos_table_size; i++) { pos_table_count[i] = read_w2(current + 2); current += 4; if (pos_table_count[i] > MAX_ANIMS) { ms_fatal("animation position array too short"); return 0; } for (j = 0; j < pos_table_count[i]; j++) { pos_table[i][j].x = read_w2(current); pos_table[i][j].y = read_w2(current + 2); pos_table[i][j].number = read_w2(current + 4) - 1; current += 8; #ifdef LOGGFX_EXT out2("Position entry: Table: %d Entry: %d X: %d Y: %d Frame: %d\n", i, j, pos_table[i][j].x, pos_table[i][j].y, pos_table[i][j].number); #endif } } /* Get the command sequence table */ //command_count = read_w2(current); command_table = current + 2; for (i = 0; i < MAX_POSITIONS; i++) { anim_table[i].flag = -1; anim_table[i].count = -1; } command_index = 0; anim_repeat = 0; pos_table_index = -1; pos_table_max = -1; } #endif return gfx_buf; } return 0; } type8 *Magnetic::ms_extract(type32 pic, type16 *w, type16 *h, type16 *pal, type8 *is_anim) { if (is_anim) *is_anim = 0; if (gfx_buf) { switch (gfx_ver) { case 1: return ms_extract1((type8)pic, w, h, pal); case 2: return ms_extract2((const char *)(code + pic), w, h, pal, is_anim); default: break; } } return 0; } type8 Magnetic::ms_animate(struct ms_position **positions, type16 *count) { #ifndef NO_ANIMATION type8 got_anim = 0; type16 i, j, ttable; if ((gfx_buf == 0) || (gfx2_buf == 0) || (gfx_ver != 2)) return 0; if ((pos_table_size == 0) || (command_index < 0)) return 0; *count = 0; *positions = (struct ms_position *)0; while (got_anim == 0) { if (pos_table_max >= 0) { if (pos_table_index < pos_table_max) { for (i = 0; i < pos_table_size; i++) { if (anim_table[i].flag > -1) { if (*count >= MAX_FRAMES) { ms_fatal("returned animation array too short"); return 0; } pos_array[*count] = pos_table[i][anim_table[i].flag]; #ifdef LOGGFX_EXT out2("Adding frame %d to buffer\n", pos_array[*count].number); #endif (*count)++; if (anim_table[i].flag < (pos_table_count[i] - 1)) anim_table[i].flag++; if (anim_table[i].count > 0) anim_table[i].count--; else anim_table[i].flag = -1; } } if (*count > 0) { *positions = pos_array; got_anim = 1; } pos_table_index++; } } if (got_anim == 0) { type8 command = command_table[command_index]; command_index++; pos_table_max = -1; pos_table_index = -1; switch (command) { case 0x00: command_index = -1; return 0; case 0x01: #ifdef LOGGFX_EXT out2("Load Frame Table: %d Start at: %d Count: %d\n", command_table[command_index], command_table[command_index + 1], command_table[command_index + 2]); #endif ttable = command_table[command_index]; command_index++; if (ttable - 1 >= MAX_POSITIONS) { ms_fatal("animation table too short"); return 0; } anim_table[ttable - 1].flag = (type16s)(command_table[command_index] - 1); command_index++; anim_table[ttable - 1].count = (type16s)(command_table[command_index] - 1); command_index++; /* Workaround for Wonderland "catter" animation */ if (v4_id == 0) { if (strcmp(gfx2_name, "catter") == 0) { if (command_index == 96) anim_table[ttable - 1].count = 9; if (command_index == 108) anim_table[ttable - 1].flag = -1; if (command_index == 156) anim_table[ttable - 1].flag = -1; } } break; case 0x02: #ifdef LOGGFX_EXT out2("Animate: %d\n", command_table[command_index]); #endif pos_table_max = command_table[command_index]; pos_table_index = 0; command_index++; break; case 0x03: #ifdef LOGGFX_EXT out2("Stop/Repeat Param: %d\n", command_table[command_index]); command_index = -1; return 0; #else if (v4_id == 0) { command_index = -1; return 0; } else { command_index = 0; anim_repeat = 1; pos_table_index = -1; pos_table_max = -1; for (j = 0; j < MAX_POSITIONS; j++) { anim_table[j].flag = -1; anim_table[j].count = -1; } } break; #endif case 0x04: #ifdef LOGGFX_EXT out2("Unknown Command: %d Prop1: %d Prop2: %d WARNING:not parsed\n", command, command_table[command_index], command_table[command_index + 1]); #endif command_index += 3; return 0; case 0x05: ttable = next_table; command_index++; anim_table[ttable - 1].flag = 0; anim_table[ttable - 1].count = command_table[command_index]; pos_table_max = command_table[command_index]; pos_table_index = 0; command_index++; command_index++; next_table++; break; default: ms_fatal("unknown animation command"); command_index = -1; return 0; } } } #ifdef LOGGFX_EXT out2("ms_animate() returning %d frames\n", *count); #endif return got_anim; #else return 0; #endif } type8 *Magnetic::ms_get_anim_frame(type16s number, type16 *width, type16 *height, type8 **mask) { #ifndef NO_ANIMATION if (number >= 0) { extract_frame(anim_frame_table + number); *width = anim_frame_table[number].width; *height = anim_frame_table[number].height; *mask = anim_frame_table[number].mask; return gfx_buf; } #endif return 0; } type8 Magnetic::ms_anim_is_repeating() const { #ifndef NO_ANIMATION return anim_repeat; #else return 0; #endif } type16s Magnetic::find_name_in_sndheader(const char *name) { type16s header_pos = 0; while (header_pos < snd_hsize) { const char *hname = (const char *)(snd_hdr + header_pos); if (strcmp(hname, name) == 0) return header_pos; header_pos += 18; } return -1; } type8 *Magnetic::sound_extract(const char *name, type32 *length, type16 *tempo) { type32 offset = 0; type16s header_pos = -1; if (header_pos < 0) header_pos = find_name_in_sndheader(name); if (header_pos < 0) return 0; *tempo = read_w(snd_hdr + header_pos + 8); offset = read_l(snd_hdr + header_pos + 10); *length = read_l(snd_hdr + header_pos + 14); if (offset != 0) { if (!snd_buf) return 0; if (!snd_fp->seek(offset) || snd_fp->read(snd_buf, *length) != *length) return 0; return snd_buf; } return nullptr; } void Magnetic::save_undo() { type8 *tmp, i; type32 tmp32; tmp = undo[0]; /* swap buffers */ undo[0] = undo[1]; undo[1] = tmp; for (i = 0; i < 18; i++) { tmp32 = undo_regs[0][i]; undo_regs[0][i] = undo_regs[1][i]; undo_regs[1][i] = tmp32; } memcpy(undo[1], code, undo_size); for (i = 0; i < 8; i++) { undo_regs[1][i] = dreg[i]; undo_regs[1][8 + i] = areg[i]; } undo_regs[1][16] = i_count; undo_regs[1][17] = pc; /* status flags intentionally omitted */ undo_stat[0] = undo_stat[1]; undo_stat[1] = 1; } type8 Magnetic::ms_undo() { type8 i; ms_flush(); if (!undo_stat[0]) return 0; undo_stat[0] = undo_stat[1] = 0; memcpy(code, undo[0], undo_size); for (i = 0; i < 8; i++) { dreg[i] = undo_regs[0][i]; areg[i] = undo_regs[0][8 + i]; } i_count = undo_regs[0][16]; pc = undo_regs[0][17]; /* status flags intentionally omitted */ return 1; } #ifdef LOGEMU void Magnetic::log_status() { int j; fprintf(dbg_log, "\nD0:"); for (j = 0; j < 8; j++) fprintf(dbg_log, " %8.8x", read_reg(j, 3)); fprintf(dbg_log, "\nA0:"); for (j = 0; j < 8; j++) fprintf(dbg_log, " %8.8x", read_reg(8 + j, 3)); fprintf(dbg_log, "\nPC=%5.5x (%8.8x) ZCNV=%d%d%d%d - %d instructions\n\n", pc, code, zflag & 1, cflag & 1, nflag & 1, vflag & 1, i_count); } #endif void Magnetic::ms_status() { int j; Common::String s = "D0:"; for (j = 0; j < 8; j++) s += Common::String::format(" %8.8lx", (long) read_reg(j, 3)); s += "\nA0:"; for (j = 0; j < 8; j++) s += Common::String::format(" %8.8lx", (long) read_reg(8 + j, 3)); s += Common::String::format("\nPC=%5.5lx ZCNV=%d%d%d%d - %ld instructions\n", (long) pc, zflag & 1, cflag & 1, nflag & 1, vflag & 1, (long) i_count); warning("%s", s.c_str()); } type8 *Magnetic::reg_align(type8 *ptr, type8 size) { if (size == 1) ptr += 2; if (size == 0) ptr += 3; return ptr; } type32 Magnetic::read_reg(int i, int s) { type8 *ptr; if (i > 15) { ms_fatal("invalid register in read_reg"); return 0; } if (i < 8) ptr = (type8 *) & dreg[i]; else ptr = (type8 *) & areg[i - 8]; switch (s) { case 0: return reg_align(ptr, 0)[0]; case 1: return read_w(reg_align(ptr, 1)); default: return read_l(ptr); } } void Magnetic::write_reg(int i, int s, type32 val) { type8 *ptr; if (i > 15) { ms_fatal("invalid register in write_reg"); return; } if (i < 8) ptr = (type8 *) & dreg[i]; else ptr = (type8 *) & areg[i - 8]; switch (s) { case 0: reg_align(ptr, 0)[0] = (type8)val; break; case 1: write_w(reg_align(ptr, 1), (type16)val); break; default: write_l(ptr, val); break; } } void Magnetic::char_out(type8 c) { static type8 big = 0, period = 0, pipe = 0; if (c == 0xff) { big = 1; return; } c &= 0x7f; if (read_reg(3, 0)) { if (c == 0x5f || c == 0x40) c = 0x20; if ((c >= 'a') && (c <= 'z')) c &= 0xdf; if (version < 4) ms_statuschar(c); return; } if (c == 0x5e) c = 0x0a; if (c == 0x40) { if (read_reg(2, 0)) return; else c = 0x73; } if (version < 3 && c == 0x7e) { lastchar = 0x7e; c = 0x0a; } if (((c > 0x40) && (c < 0x5b)) || ((c > 0x60) && (c < 0x7b))) { if (big) { c &= 0xdf; big = 0; } if (period) char_out(0x20); } period = 0; if (version < 4) { if ((c == 0x2e) || (c == 0x3f) || (c == 0x21) || (c == 0x0a)) big = 1; else if (c == 0x22) big = 0; } else { if ((c == 0x20) && (lastchar == 0x0a)) return; if ((c == 0x2e) || (c == 0x3f) || (c == 0x21) || (c == 0x0a)) big = 1; else if (c == 0x22) big = 0; } if (((c == 0x20) || (c == 0x0a)) && (c == lastchar)) return; if (version < 3) { if (pipe) { pipe = 0; return; } if (c == 0x7c) { pipe = 1; return; } } else { if (c == 0x7e) { c = 0x0a; if (lastchar != 0x0a) char_out(0x0a); } } lastchar = c; if (c == 0x5f) c = 0x20; if ((c == 0x2e) || (c == 0x2c) || (c == 0x3b) || (c == 0x3a) || (c == 0x21) || (c == 0x3f)) period = 1; ms_putchar(c); } void Magnetic::set_info(type8 b) { regnr = (type8)(b & 0x07); admode = (type8)((b >> 3) & 0x07); opsize = (type8)(b >> 6); } void Magnetic::read_word() { type8 *epc; epc = effective(pc); byte1 = epc[0]; byte2 = epc[1]; pc += 2; } void Magnetic::set_arg1() { type8 tmp[2], l1c; is_reversible = 1; switch (admode) { case 0: arg1 = reg_align((type8 *) & dreg[regnr], opsize); /* Dx */ is_reversible = 0; #ifdef LOGEMU out(" d%.1d", regnr); #endif break; case 1: arg1 = reg_align((type8 *) & areg[regnr], opsize); /* Ax */ is_reversible = 0; #ifdef LOGEMU out(" a%.1d", regnr); #endif break; case 2: arg1i = read_reg(8 + regnr, 2); /* (Ax) */ #ifdef LOGEMU out(" (a%.1d)", regnr); #endif break; case 3: arg1i = read_reg(8 + regnr, 2); /* (Ax)+ */ write_reg(8 + regnr, 2, read_reg(8 + regnr, 2) + (1 << opsize)); #ifdef LOGEMU out(" (a%.1d)+", regnr); #endif break; case 4: write_reg(8 + regnr, 2, read_reg(8 + regnr, 2) - (1 << opsize)); arg1i = read_reg(8 + regnr, 2); /* -(Ax) */ #ifdef LOGEMU out(" -(a%.1d)", regnr); #endif break; case 5: { type16s i = (type16s) read_w(effective(pc)); arg1i = read_reg(8 + regnr, 2) + i; pc += 2; /* offset.w(Ax) */ #ifdef LOGEMU out(" %X(a%.1d)", i, regnr); #endif } break; case 6: tmp[0] = byte1; tmp[1] = byte2; read_word(); /* offset.b(Ax, Dx/Ax) [1d1c] */ #ifdef LOGEMU out(" %.2X(a%.1d,", (int) byte2, regnr); #endif arg1i = read_reg(regnr + 8, 2) + (type8s) byte2; #ifdef LOGEMU if ((byte1 >> 4) > 8) out("a%.1d", (byte1 >> 4) - 8); else out("d%.1d", byte1 >> 4); #endif if (byte1 & 0x08) { #ifdef LOGEMU out(".l)"); #endif arg1i += (type32s) read_reg((byte1 >> 4), 2); } else { #ifdef LOGEMU out(".w)"); #endif arg1i += (type16s) read_reg((byte1 >> 4), 1); } byte1 = tmp[0]; byte2 = tmp[1]; break; case 7: /* specials */ switch (regnr) { case 0: arg1i = read_w(effective(pc)); /* $xxxx.W */ pc += 2; #ifdef LOGEMU out(" %.4X.w", arg1i); #endif break; case 1: arg1i = read_l(effective(pc)); /* $xxxx */ pc += 4; #ifdef LOGEMU out(" %.4X", arg1i); #endif break; case 2: arg1i = (type16s) read_w(effective(pc)) + pc; /* $xxxx(PC) */ pc += 2; #ifdef LOGEMU out(" %.4X(pc)", arg1i); #endif break; case 3: l1c = effective(pc)[0]; /* $xx(PC,A/Dx) */ #ifdef LOGEMU out(" ???2", arg1i); #endif if (l1c & 0x08) arg1i = pc + (type32s) read_reg((l1c >> 4), 2); else arg1i = pc + (type16s) read_reg((l1c >> 4), 1); l1c = effective(pc)[1]; pc += 2; arg1i += (type8s) l1c; break; case 4: arg1i = pc; /* #$xxxx */ if (opsize == 0) arg1i += 1; pc += 2; if (opsize == 2) pc += 2; #ifdef LOGEMU out(" #%.4X", arg1i); #endif break; } break; } if (is_reversible) arg1 = effective(arg1i); } void Magnetic::set_arg2_nosize(int use_dx, type8 b) { if (use_dx) arg2 = (type8 *) dreg; else arg2 = (type8 *) areg; arg2 += (b & 0x0e) << 1; } void Magnetic::set_arg2(int use_dx, type8 b) { set_arg2_nosize(use_dx, b); arg2 = reg_align(arg2, opsize); } void Magnetic::swap_args() { type8 *tmp; tmp = arg1; arg1 = arg2; arg2 = tmp; } void Magnetic::push(type32 c) { write_reg(15, 2, read_reg(15, 2) - 4); write_l(effective(read_reg(15, 2)), c); } type32 Magnetic::pop() { type32 c; c = read_l(effective(read_reg(15, 2))); write_reg(15, 2, read_reg(15, 2) + 4); return c; } void Magnetic::get_arg() { #ifdef LOGEMU out(" %.4X", pc); #endif set_info(byte2); arg2 = effective(pc); pc += 2; if (opsize == 2) pc += 2; if (opsize == 0) arg2 += 1; set_arg1(); } void Magnetic::set_flags() { type16 i; type32 j; zflag = nflag = 0; switch (opsize) { case 0: if (arg1[0] > 127) nflag = 0xff; if (arg1[0] == 0) zflag = 0xff; break; case 1: i = read_w(arg1); if (i == 0) zflag = 0xff; if ((i >> 15) > 0) nflag = 0xff; break; case 2: j = read_l(arg1); if (j == 0) zflag = 0xff; if ((j >> 31) > 0) nflag = 0xff; break; } } int Magnetic::condition(type8 b) { switch (b & 0x0f) { case 0: return 0xff; case 1: return 0x00; case 2: return (zflag | cflag) ^ 0xff; case 3: return (zflag | cflag); case 4: return cflag ^ 0xff; case 5: return cflag; case 6: return zflag ^ 0xff; case 7: return zflag; case 8: return vflag ^ 0xff; case 9: return vflag; case 10: case 12: return nflag ^ 0xff; case 11: case 13: return nflag; case 14: return (zflag | nflag) ^ 0xff; case 15: return (zflag | nflag); } return 0x00; } void Magnetic::branch(type8 b) { if (b == 0) pc += (type16s) read_w(effective(pc)); else pc += (type8s) b; #ifdef LOGEMU out(" %.4X", pc); #endif } void Magnetic::do_add(type8 adda) { if (adda) { if (opsize == 0) write_l(arg1, read_l(arg1) + (type8s) arg2[0]); if (opsize == 1) write_l(arg1, read_l(arg1) + (type16s) read_w(arg2)); if (opsize == 2) write_l(arg1, read_l(arg1) + (type32s) read_l(arg2)); } else { cflag = 0; if (opsize == 0) { arg1[0] += arg2[0]; if (arg2[0] > arg1[0]) cflag = 0xff; } if (opsize == 1) { write_w(arg1, (type16)(read_w(arg1) + read_w(arg2))); if (read_w(arg2) > read_w(arg1)) cflag = 0xff; } if (opsize == 2) { write_l(arg1, read_l(arg1) + read_l(arg2)); if (read_l(arg2) > read_l(arg1)) cflag = 0xff; } if (version < 3 || !quick_flag) { /* Corruption onwards */ vflag = 0; set_flags(); } } } void Magnetic::do_sub(type8 suba) { if (suba) { if (opsize == 0) write_l(arg1, read_l(arg1) - (type8s) arg2[0]); if (opsize == 1) write_l(arg1, read_l(arg1) - (type16s) read_w(arg2)); if (opsize == 2) write_l(arg1, read_l(arg1) - (type32s) read_l(arg2)); } else { cflag = 0; if (opsize == 0) { if (arg2[0] > arg1[0]) cflag = 0xff; arg1[0] -= arg2[0]; } if (opsize == 1) { if (read_w(arg2) > read_w(arg1)) cflag = 0xff; write_w(arg1, (type16)(read_w(arg1) - read_w(arg2))); } if (opsize == 2) { if (read_l(arg2) > read_l(arg1)) cflag = 0xff; write_l(arg1, read_l(arg1) - read_l(arg2)); } if (version < 3 || !quick_flag) { /* Corruption onwards */ vflag = 0; set_flags(); } } } void Magnetic::do_eor() { if (opsize == 0) arg1[0] ^= arg2[0]; if (opsize == 1) write_w(arg1, (type16)(read_w(arg1) ^ read_w(arg2))); if (opsize == 2) write_l(arg1, read_l(arg1) ^ read_l(arg2)); cflag = vflag = 0; set_flags(); } void Magnetic::do_and() { if (opsize == 0) arg1[0] &= arg2[0]; if (opsize == 1) write_w(arg1, (type16)(read_w(arg1) & read_w(arg2))); if (opsize == 2) write_l(arg1, read_l(arg1) & read_l(arg2)); cflag = vflag = 0; set_flags(); } void Magnetic::do_or() { if (opsize == 0) arg1[0] |= arg2[0]; if (opsize == 1) write_w(arg1, (type16)(read_w(arg1) | read_w(arg2))); if (opsize == 2) write_l(arg1, read_l(arg1) | read_l(arg2)); cflag = vflag = 0; set_flags(); /* [1c2b] */ } void Magnetic::do_cmp() { type8 *tmp; tmp = arg1; tmparg[0] = arg1[0]; tmparg[1] = arg1[1]; tmparg[2] = arg1[2]; tmparg[3] = arg1[3]; arg1 = tmparg; quick_flag = 0; do_sub(0); arg1 = tmp; } void Magnetic::do_move() { if (opsize == 0) arg1[0] = arg2[0]; if (opsize == 1) write_w(arg1, read_w(arg2)); if (opsize == 2) write_l(arg1, read_l(arg2)); if (version < 2 || admode != 1) { /* Jinxter: no flags if destination Ax */ cflag = vflag = 0; set_flags(); } } type8 Magnetic::do_btst(type8 a) { a &= admode ? 0x7 : 0x1f; while (admode == 0 && a >= 8) { a -= 8; arg1 -= 1; } zflag = 0; if ((arg1[0] & (1 << a)) == 0) zflag = 0xff; return a; } void Magnetic::do_bop(type8 b, type8 a) { #ifdef LOGEMU out("bop (%.2x,%.2x) ", (int) b, (int) a); #endif b = b & 0xc0; a = do_btst(a); #ifdef LOGEMU if (b == 0x00) out("no bop???"); #endif if (b == 0x40) { arg1[0] ^= (1 << a); /* bchg */ #ifdef LOGEMU out("bchg"); #endif } if (b == 0x80) { arg1[0] &= ((1 << a) ^ 0xff); /* bclr */ #ifdef LOGEMU out("bclr"); #endif } if (b == 0xc0) { arg1[0] |= (1 << a); /* bset */ #ifdef LOGEMU out("bset"); #endif } } void Magnetic::check_btst() { #ifdef LOGEMU out("btst"); #endif set_info((type8)(byte2 & 0x3f)); set_arg1(); set_arg2(1, byte1); do_bop(byte2, arg2[0]); } void Magnetic::check_lea() { #ifdef LOGEMU out("lea"); #endif if ((byte2 & 0xc0) == 0xc0) { set_info(byte2); opsize = 2; set_arg1(); set_arg2(0, byte1); write_w(arg2, 0); if (is_reversible) write_l(arg2, arg1i); else ms_fatal("illegal addressing mode for LEA"); } else { ms_fatal("unimplemented instruction CHK"); } } void Magnetic::check_movem() { type8 l1c; #ifdef LOGEMU out("movem"); #endif set_info((type8)(byte2 - 0x40)); read_word(); for (l1c = 0; l1c < 8; l1c++) { if (byte2 & 1 << l1c) { set_arg1(); if (opsize == 2) write_l(arg1, read_reg(15 - l1c, 2)); if (opsize == 1) write_w(arg1, (type16)read_reg(15 - l1c, 1)); } } for (l1c = 0; l1c < 8; l1c++) { if (byte1 & 1 << l1c) { set_arg1(); if (opsize == 2) write_l(arg1, read_reg(7 - l1c, 2)); if (opsize == 1) write_w(arg1, (type16)read_reg(7 - l1c, 1)); } } } void Magnetic::check_movem2() { type8 l1c; #ifdef LOGEMU out("movem (2)"); #endif set_info((type8)(byte2 - 0x40)); read_word(); for (l1c = 0; l1c < 8; l1c++) { if (byte2 & 1 << l1c) { set_arg1(); if (opsize == 2) write_reg(l1c, 2, read_l(arg1)); if (opsize == 1) write_reg(l1c, 1, read_w(arg1)); } } for (l1c = 0; l1c < 8; l1c++) { if (byte1 & 1 << l1c) { set_arg1(); if (opsize == 2) write_reg(8 + l1c, 2, read_l(arg1)); if (opsize == 1) write_reg(8 + l1c, 1, read_w(arg1)); } } } void Magnetic::dict_lookup() { type16 dtab, doff, output, output_bak, bank, word, output2; type16 tmp16, i, obj_adj, adjlist, adjlist_bak; type8 c, c2, c3, flag, matchlen, longest, flag2; type8 restartFlag = 0, accept = 0; /* dtab=A5.W ;dict_table offset output=output_bak=A2.W ;output A5.W=A6.W ;input word doff=A3.W ;lookup offset (doff) adjlist=A0.W ;adjlist */ dtab = (type16)read_reg(8 + 5, 1); /* used by version>0 */ output = (type16)read_reg(8 + 2, 1); write_reg(8 + 5, 1, read_reg(8 + 6, 1)); doff = (type16)read_reg(8 + 3, 1); adjlist = (type16)read_reg(8 + 0, 1); bank = (type16)read_reg(6, 0); /* l2d */ flag = 0; /* l2c */ word = 0; /* l26 */ matchlen = 0; /* l2e */ longest = 0; /* 30e2 */ write_reg(0, 1, 0); /* apostroph */ while ((c = sd ? dict[doff] : effective(doff)[0]) != 0x81) { if (c >= 0x80) { if (c == 0x82) { flag = matchlen = 0; word = 0; write_reg(8 + 6, 1, read_reg(8 + 5, 1)); bank++; doff++; continue; } c3 = c; c &= 0x5f; c2 = effective(read_reg(8 + 6, 1))[0] & 0x5f; if (c2 == c) { write_reg(8 + 6, 1, read_reg(8 + 6, 1) + 1); c = effective(read_reg(8 + 6, 1))[0]; if ((!c) || (c == 0x20) || (c == 0x27) || (!version && (matchlen > 6))) { if (c == 0x27) { write_reg(8 + 6, 1, read_reg(8 + 6, 1) + 1); write_reg(0, 1, 0x200 + effective(read_reg(8 + 6, 1))[0]); } if ((version < 4) || (c3 != 0xa0)) accept = 1; } else restartFlag = 1; } else if (!version && matchlen > 6 && !c2) accept = 1; else restartFlag = 1; } else { c &= 0x5f; c2 = effective(read_reg(8 + 6, 1))[0] & 0x5f; if ((c2 == c && c) || (version && !c2 && (c == 0x5f))) { if (version && !c2 && (c == 0x5f)) flag = 0x80; matchlen++; write_reg(8 + 6, 1, read_reg(8 + 6, 1) + 1); doff++; } else if (!version && matchlen > 6 && !c2) accept = 1; else restartFlag = 1; } if (accept) { effective(read_reg(8 + 2, 1))[0] = (version) ? flag : 0; effective(read_reg(8 + 2, 1))[1] = (type8)bank; write_w(effective(read_reg(8 + 2, 1) + 2), word); write_reg(8 + 2, 1, read_reg(8 + 2, 1) + 4); if (matchlen >= longest) longest = matchlen; restartFlag = 1; accept = 0; } if (restartFlag) { write_reg(8 + 6, 1, read_reg(8 + 5, 1)); flag = matchlen = 0; word++; if (sd) while (dict[doff++] < 0x80); else while (effective(doff++)[0] < 0x80); restartFlag = 0; } } write_w(effective(read_reg(8 + 2, 1)), 0xffff); if (version) { /* version > 0 */ output_bak = output; /* check synonyms */ while ((c = effective(output)[1]) != 0xff) { if (c == 0x0b) { if (sd) tmp16 = read_w(&dict[dtab + read_w(effective(output + 2)) * 2]); else tmp16 = read_w(effective(dtab + read_w(effective(output + 2)) * 2)); effective(output)[1] = tmp16 & 0x1f; write_w(effective(output + 2), (type16)(tmp16 >> 5)); } output += 4; } output = output_bak; } /* l22 = output2, l1e = adjlist, l20 = obj_adj, l26 = word, l2f = c2 */ /* l1c = adjlist_bak, 333C = i, l2d = bank, l2c = flag, l30e3 = flag2 */ write_reg(1, 1, 0); /* D1.W=0 [32B5] */ flag2 = 0; output_bak = output; output2 = output; while ((bank = effective(output2)[1]) != 0xff) { obj_adj = (type16)read_reg(8 + 1, 1); /* A1.W - obj_adj, ie. adjs for this word */ write_reg(1, 0, 0); /* D1.B=0 */ flag = effective(output2)[0]; /* flag */ word = read_w(effective(output2 + 2)); /* wordnumber */ output2 += 4; /* next match */ if ((read_w(effective(obj_adj))) && (bank == 6)) { /* Any adjectives? */ if ((i = word) != 0) { /* Find list of valid adjs */ do { while (effective(adjlist++)[0]); } while (--i > 0); } adjlist_bak = adjlist; do { adjlist = adjlist_bak; c2 = effective(obj_adj)[1]; /* given adjective */ if ((tmp16 = read_w(effective(obj_adj))) != 0) { obj_adj += 2; while ((c = effective(adjlist++)[0]) && (c - 3 != c2)); if (c - 3 != c2) write_reg(1, 0, 1); /* invalid adjective */ } } while (tmp16 && !read_reg(1, 0)); adjlist = (type16)read_reg(8 + 0, 1); } if (!read_reg(1, 0)) { /* invalid_flag */ flag2 |= flag; effective(output)[0] = flag2; effective(output)[1] = (type8)bank; write_w(effective(output + 2), word); output += 4; } } write_reg(8 + 2, 1, output); output = output_bak; if (flag2 & 0x80) { tmp16 = output; output -= 4; do { output += 4; c = effective(output)[0]; } while (!(c & 0x80)); write_l(effective(tmp16), read_l(effective(output)) & 0x7fffffff); write_reg(8 + 2, 2, tmp16 + 4); if (longest > 1) { write_reg(8 + 5, 1, read_reg(8 + 5, 1) + longest - 2); } } write_reg(8 + 6, 1, read_reg(8 + 5, 1) + 1); } void Magnetic::do_findprop() { type16 tmp; if ((version > 2) && ((read_reg(0, 1) & 0x3fff) > fp_size)) { tmp = (type16)(((fp_size - (read_reg(0, 1) & 0x3fff)) ^ 0xffff) << 1); tmp += fp_tab; tmp = read_w(effective(tmp)); } else { if (version < 2) write_reg(0, 2, read_reg(0, 2) & 0x7fff); else write_reg(0, 1, read_reg(0, 1) & 0x7fff); tmp = (type16)read_reg(0, 1); } tmp &= 0x3fff; write_reg(8 + 0, 2, tmp * 14 + properties); } void Magnetic::write_string() { static type32 offset_bak; static type8 mask_bak; type8 c, b, mask; type16 ptr; type32 offset; if (!cflag) { /* new string */ ptr = (type16)read_reg(0, 1); if (!ptr) offset = 0; else { offset = read_w(&decode_table[0x100 + 2 * ptr]); if (read_w(&decode_table[0x100])) { if (ptr >= read_w(&decode_table[0x100])) offset += string_size; } } mask = 1; } else { offset = offset_bak; mask = mask_bak; } do { c = 0; while (c < 0x80) { if (offset >= string_size) b = string2[offset - string_size]; else { if (offset >= MAX_STRING_SIZE) b = string3[offset - MAX_STRING_SIZE]; else b = string[offset]; } if (b & mask) c = decode_table[0x80 + c]; else c = decode_table[c]; mask <<= 1; if (!mask) { mask = 1; offset++; } } c &= 0x7f; if (c && ((c != 0x40) || (lastchar != 0x20))) char_out(c); } while (c && ((c != 0x40) || (lastchar != 0x20))); cflag = c ? 0xff : 0; if (c) { offset_bak = offset; mask_bak = mask; } } void Magnetic::output_number(type16 number) { type16 tens = number / 10; if (tens > 0) ms_putchar('0' + tens); number -= (tens * 10); ms_putchar('0' + number); } type16 Magnetic::output_text(const char *text) { type16 i; for (i = 0; text[i] != 0; i++) ms_putchar(text[i]); return i; } type16s Magnetic::hint_input() { type8 c1, c2, c3; output_text(">>"); ms_flush(); do { c1 = ms_getchar(0); } while (c1 == '\n'); if (c1 == 1) return -1; /* New game loaded, abort hints */ c2 = ms_getchar(0); if (c2 == 1) return -1; /* Get and discard any remaining characters */ c3 = c2; while (c3 != '\n') { c3 = ms_getchar(0); if (c3 == 1) return -1; } ms_putchar('\n'); if ((c1 >= '0') && (c1 <= '9')) { type16 number = c1 - '0'; if ((c2 >= '0') && (c2 <= '9')) { number *= 10; number += c2 - '0'; } return number; } if ((c1 >= 'A') && (c1 <= 'Z')) c1 = 'a' + (c1 - 'A'); if ((c1 >= 'a') && (c1 <= 'z')) { switch (c1) { case 'e': return -2; /* End hints */ case 'n': return -3; /* Next hint */ case 'p': return -4; /* Show parent hint list */ } } return 0; } type16 Magnetic::show_hints_text(ms_hint *hintsData, type16 index) { type16 i = 0, j = 0; type16s input; ms_hint *hint = hintsData + index; while (1) { switch (hint->nodetype) { case 1: /* folders */ output_text("Hint categories:\n"); for (i = 0, j = 0; i < hint->elcount; i++) { output_number(i + 1); output_text(". "); j += output_text(hint->content + j) + 1; ms_putchar('\n'); } output_text("Enter hint category number, "); if (hint->parent != 0xffff) output_text("P for the parent hint menu, "); output_text("or E to end hintsData.\n"); input = hint_input(); switch (input) { case -1: /* A new game is being loaded */ return 1; case -2: /* End hintsData */ return 1; case -4: /* Show parent hint list */ if (hint->parent != 0xffff) return 0; // fallthrough default: if ((input > 0) && (input <= hint->elcount)) { if (show_hints_text(hintsData, hint->links[input - 1]) == 1) return 1; } break; } break; case 2: /* hintsData */ if (i < hint->elcount) { output_number(i + 1); output_text(". "); j += output_text(hint->content + j) + 1; if (i == hint->elcount - 1) { output_text("\nNo more hintsData.\n"); return 0; /* Last hint */ } else { output_text("\nEnter N for the next hint, "); output_text("P for the parent hint menu, "); output_text("or E to end hintsData.\n"); } input = hint_input(); switch (input) { case -1: /* A new game is being loaded */ return 1; case -2: /* End hintsData */ return 1; case -3: i++; break; case -4: /* Show parent hint list */ return 0; } } else return 0; break; } } return 0; } void Magnetic::do_line_a() { type8 l1c; char *str; type16 ptr, ptr2, tmp16, dtype; type32 a1reg, tmp32; #ifdef LOGGFX /* if (((byte2-0xdd) == 4) || ((byte2-0xdd) == 13)) out2("--> %d\n",byte2-0xdd); else out2("LINE A %d\n",byte2-0xdd); */ #endif if ((byte2 < 0xdd) || (version < 4 && byte2 < 0xe4) || (version < 2 && byte2 < 0xed)) { ms_flush(); /* flush output-buffer */ rand_emu(); /* Increase game randomness */ l1c = ms_getchar(1); /* 0 means UNDO */ if (l1c == 1) return; if (l1c) write_reg(1, 2, l1c); /* d1=getkey() */ else { if ((l1c = ms_undo()) != 0) output_text(undo_ok); else output_text(undo_fail); if (!l1c) write_reg(1, 2, '\n'); } } else switch (byte2 - 0xdd) { case 0: /* A0DD - Won't probably be needed at all */ break; case 1: /* A0DE */ write_reg(1, 0, 1); /* Should remove the manual check */ break; case 2: /* A0DF */ a1reg = (type32)read_reg(9, 2); dtype = (code + a1reg + 2)[0]; switch (dtype) { case 7: /* Picture */ #ifdef LOGGFX out2("PICTURE IS %s\n", code + a1reg + 3); #endif /* gfx mode = normal, df is not called if graphics are off */ ms_showpic(a1reg + 3, 2); break; case 10: /* Open window commands */ switch ((code + a1reg + 3)[0]) { case 4: /* Help/Hints */ if (hints != 0) { if (ms_showhints(hints) == 0) show_hints_text(hints, 0); } else output_text(no_hints); break; case 0: /* Carried items */ case 1: /* Room items */ case 2: /* Map */ case 3: /* Compass */ output_text(not_supported); break; } break; case 13: /* Music */ switch ((code + a1reg + 3)[0]) { case 0: /* stop music */ ms_playmusic(0, 0, 0); break; default: /* play music */ #ifdef LOGSND out2("MUSIC IS %s\n", code + a1reg + 3); #endif { type32 length = 0; type16 tempo = 0; type8 *midi = sound_extract((const char *)(code + a1reg + 3), &length, &tempo); if (midi != NULL) ms_playmusic(midi, length, tempo); } break; } break; } break; case 3: /* A0E0 */ /* printf("A0E0 stubbed\n"); */ break; case 4: /* A0E1 Read from keyboard to (A1), status in D1 (0 for ok) */ ms_flush(); rand_emu(); tmp32 = read_reg(8 + 1, 2); str = (char *)effective(tmp32); tmp16 = 0; do { if (!(l1c = ms_getchar(1))) { if (g_vm->shouldQuit()) return; if ((l1c = ms_undo()) != 0) output_text(undo_ok); else output_text(undo_fail); if (!l1c) { tmp16 = 0; str[tmp16++] = '\n'; l1c = '\n'; output_text("\n>"); } else { ms_putchar('\n'); return; } } else { if (l1c == 1) return; str[tmp16++] = l1c; #ifdef LOGGFX out2("%c", l1c); #endif } } while (l1c != '\n' && tmp16 < 256); write_reg(8 + 1, 2, tmp32 + tmp16 - 1); if (tmp16 != 256 && tmp16 != 1) write_reg(1, 1, 0); else write_reg(1, 1, 1); break; case 5: /* A0E2 */ /* printf("A0E2 stubbed\n"); */ break; case 6: /* A0E3 */ if (read_reg(1, 2) == 0) { if ((version < 4) || (read_reg(6, 2) == 0)) ms_showpic(0, 0); } /* printf("\nMoves: %u\n",read_reg(0,1)); */ break; case 7: /* A0E4 sp+=4, RTS */ write_reg(8 + 7, 1, read_reg(8 + 7, 1) + 4); pc = pop(); break; case 8: /* A0E5 set z, RTS */ case 9: /* A0E6 clear z, RTS */ pc = pop(); zflag = (byte2 == 0xe5) ? 0xff : 0; break; case 10: /* A0E7 set z */ zflag = 0xff; break; case 11: /* A0E8 clear z */ zflag = 0; break; case 12: /* A0E9 [3083 - j] */ ptr = (type16)read_reg(8 + 0, 1); ptr2 = (type16)read_reg(8 + 1, 1); do { l1c = dict[ptr2++]; effective(ptr++)[0] = l1c; } while ((l1c & 0x80) == 0); write_reg(8 + 0, 1, ptr); write_reg(8 + 1, 1, ptr2); break; case 13: /* A0EA A1=write_dictword(A1,D1=output_mode) */ ptr = (type16)read_reg(8 + 1, 1); tmp32 = read_reg(3, 0); write_reg(3, 0, read_reg(1, 0)); do { l1c = dict[ptr++]; char_out(l1c); } while (l1c < 0x80); write_reg(8 + 1, 1, ptr); write_reg(3, 0, tmp32); break; case 14: /* A0EB [3037 - j] */ dict[read_reg(8 + 1, 1)] = (type8)read_reg(1, 0); break; case 15: /* A0EC */ write_reg(1, 0, dict[read_reg(8 + 1, 1)]); break; case 16: ms_stop(); /* infinite loop A0ED */ break; case 17: if (!ms_init(nullptr, nullptr, nullptr, nullptr)) ms_stop(); /* restart game ie. pc, sp etc. A0EE */ break; case 18: /* printer A0EF */ break; case 19: ms_showpic(read_reg(0, 0), (type8)read_reg(1, 0)); /* Do_picture(D0) A0F0 */ break; case 20: ptr = (type16)read_reg(8 + 1, 1); /* A1=nth_string(A1,D0) A0F1 */ tmp32 = read_reg(0, 1); while (tmp32-- > 0) { while (effective(ptr++)[0]); } write_reg(8 + 1, 1, ptr); break; case 21: /* [2a43] A0F2 */ cflag = 0; write_reg(0, 1, read_reg(2, 1)); do_findprop(); ptr = (type16)read_reg(8 + 0, 1); while (read_reg(2, 1) > 0) { if (read_w(effective(ptr + 12)) & 0x3fff) { cflag = 0xff; break; } if (read_reg(2, 1) == (read_reg(4, 1) & 0x7fff)) { cflag = 0xff; break; } ptr -= 0x0e; write_reg(2, 1, read_reg(2, 1) - 1); } break; case 22: char_out((type8)read_reg(1, 0)); /* A0F3 */ break; case 23: /* D7=Save_(filename A0) D1 bytes starting from A1 A0F4 */ str = (version < 4) ? (char *)effective(read_reg(8 + 0, 1)) : nullptr; write_reg(7, 0, ms_save_file(str, effective(read_reg(8 + 1, 1)), (type16)read_reg(1, 1))); break; case 24: /* D7=Load_(filename A0) D1 bytes starting from A1 A0F5 */ str = (version < 4) ? (char *)effective(read_reg(8 + 0, 1)) : nullptr; write_reg(7, 0, ms_load_file(str, effective(read_reg(8 + 1, 1)), (type16)read_reg(1, 1))); break; case 25: /* D1=Random(0..D1-1) [3748] A0F6 */ l1c = (type8)read_reg(1, 0); write_reg(1, 1, rand_emu() % (l1c ? l1c : 1)); break; case 26: /* D0=Random(0..255) [3742] A0F7 */ tmp16 = (type16)rand_emu(); write_reg(0, 0, tmp16 + (tmp16 >> 8)); break; case 27: /* write string [D0] [2999] A0F8 */ write_string(); break; case 28: /* Z,D0=Get_inventory_item(D0) [2a9e] A0F9 */ zflag = 0; ptr = (type16)read_reg(0, 1); do { write_reg(0, 1, ptr); do { do_findprop(); ptr2 = (type16)read_reg(8 + 0, 1); /* object properties */ if ((effective(ptr2)[5]) & 1) break; /* is_described or so */ l1c = effective(ptr2)[6]; /* some_flags */ tmp16 = read_w(effective(ptr2 + 8)); /* parent_object */ if (!l1c) { /* ordinary object? */ if (!tmp16) zflag = 0xff; /* return if parent()=player */ break; /* otherwise try next */ } if (l1c & 0xcc) break; /* skip worn, bodypart, room, hidden */ if (tmp16 == 0) { /* return if parent()=player? */ zflag = 0xff; break; } write_reg(0, 1, tmp16); /* else look at parent() */ } while (1); ptr--; } while ((!zflag) && ptr); write_reg(0, 1, ptr + 1); break; case 29: /* [2b18] A0FA */ ptr = (type16)read_reg(8, 1); do { if (read_reg(5, 0)) { l1c = ((type32)((read_w(effective(ptr)) & 0x3fff)) == read_reg(2, 1)); } else { l1c = (effective(ptr)[0] == read_reg(2, 0)); } if (read_reg(3, 1) == read_reg(4, 1)) { cflag = 0; write_reg(8, 1, ptr); } else { write_reg(3, 1, read_reg(3, 1) + 1); ptr += 0x0e; if (l1c) { cflag = 0xff; write_reg(8, 1, ptr); } } } while ((!l1c) && (read_reg(3, 1) != read_reg(4, 1))); break; case 30: /* [2bd1] A0FB */ ptr = (type16)read_reg(8 + 1, 1); do { if (dict) while (dict[ptr++] < 0x80); else while (effective(ptr++)[0] < 0x80); write_reg(2, 1, read_reg(2, 1) - 1); } while (read_reg(2, 1)); write_reg(8 + 1, 1, ptr); break; case 31: /* [2c3b] A0FC */ ptr = (type16)read_reg(8 + 0, 1); ptr2 = (type16)read_reg(8 + 1, 1); do { if (dict) while (dict[ptr++] < 0x80); else while (effective(ptr++)[0] < 0x80); while (effective(ptr2++)[0]); write_reg(0, 1, read_reg(0, 1) - 1); } while (read_reg(0, 1)); write_reg(8 + 0, 1, ptr); write_reg(8 + 1, 1, ptr2); break; case 32: /* Set properties pointer from A0 [2b7b] A0FD */ properties = (type16)read_reg(8 + 0, 1); if (version > 0) fl_sub = (type16)read_reg(8 + 3, 1); if (version > 1) { fl_tab = (type16)read_reg(8 + 5, 1); fl_size = (type16)read_reg(7, 1) + 1; /* A3 [routine], A5 [table] and D7 [table-size] */ } if (version > 2) { fp_tab = (type16)read_reg(8 + 6, 1); fp_size = (type16)read_reg(6, 1); } break; case 33: /* A0FE */ do_findprop(); break; case 34: /* Dictionary_lookup A0FF */ dict_lookup(); break; } } type8 Magnetic::ms_rungame() { type8 l1c; type16 ptr; type32 tmp32; #ifdef LOGEMU static int stat = 0; #endif if (!running) return running; if (pc == undo_pc) save_undo(); #ifdef LOGEMU if (pc == 0x0000) stat = 0; if (stat) { log_status(); fflush(dbg_log); } fprintf(dbg_log, "%.8X: ", pc); #endif i_count++; read_word(); switch (byte1 >> 1) { /* 00-0F */ case 0x00: if (byte1 == 0x00) { if (byte2 == 0x3c || byte2 == 0x7c) { /* OR immediate to CCR (30D9) */ read_word(); #ifdef LOGEMU out("or_ccr #%.2x", byte2); #endif if (byte2 & 0x01) cflag = 0xff; if (byte2 & 0x02) vflag = 0xff; if (byte2 & 0x04) zflag = 0xff; if (byte2 & 0x08) nflag = 0xff; } else { /* OR [27df] */ #ifdef LOGEMU out("or"); #endif get_arg(); do_or(); } } else check_btst(); break; case 0x01: if (byte1 == 0x02) { if (byte2 == 0x3c || byte2 == 0x7c) { /* AND immediate to CCR */ read_word(); #ifdef LOGEMU out("and_ccr #%.2x", byte2); #endif if (!(byte2 & 0x01)) cflag = 0; if (!(byte2 & 0x02)) vflag = 0; if (!(byte2 & 0x04)) zflag = 0; if (!(byte2 & 0x08)) nflag = 0; } else { /* AND */ #ifdef LOGEMU out("and"); #endif get_arg(); do_and(); } } else check_btst(); break; case 0x02: if (byte1 == 0x04) { /* SUB */ #ifdef LOGEMU out("sub"); #endif get_arg(); do_sub(0); } else check_btst(); break; case 0x03: if (byte1 == 0x06) { /* ADD */ #ifdef LOGEMU out("addi"); #endif get_arg(); do_add(0); } else check_btst(); break; case 0x04: if (byte1 == 0x08) { /* bit operations (immediate) */ set_info((type8)(byte2 & 0x3f)); l1c = (effective(pc))[1]; pc += 2; set_arg1(); do_bop(byte2, l1c); } else check_btst(); break; case 0x05: if (byte1 == 0x0a) { if (byte2 == 0x3c || byte2 == 0x7c) { /* EOR immediate to CCR */ read_word(); #ifdef LOGEMU out("eor_ccr #%.2X", byte2); #endif if (byte2 & 0x01) cflag ^= 0xff; if (byte2 & 0x02) vflag ^= 0xff; if (byte2 & 0x04) zflag ^= 0xff; if (byte2 & 0x08) nflag ^= 0xff; } else { /* EOR */ #ifdef LOGEMU out("eor"); #endif get_arg(); do_eor(); } } else check_btst(); break; case 0x06: if (byte1 == 0x0c) { /* CMP */ #ifdef LOGEMU out("cmp"); #endif get_arg(); do_cmp(); } else check_btst(); break; case 0x07: check_btst(); break; /* 10-1F [3327] MOVE.B */ case 0x08: case 0x09: case 0x0a: case 0x0b: case 0x0c: case 0x0d: case 0x0e: case 0x0f: #ifdef LOGEMU out("move.b"); #endif set_info((type8)(byte2 & 0x3f)); set_arg1(); swap_args(); l1c = (byte1 >> 1 & 0x07) | (byte2 >> 3 & 0x18) | (byte1 << 5 & 0x20); set_info(l1c); set_arg1(); do_move(); break; /* 20-2F [32d1] MOVE.L */ case 0x10: case 0x11: case 0x12: case 0x13: case 0x14: case 0x15: case 0x16: case 0x17: #ifdef LOGEMU out("move.l"); #endif set_info((type8)((byte2 & 0x3f) | 0x80)); set_arg1(); swap_args(); l1c = (byte1 >> 1 & 0x07) | (byte2 >> 3 & 0x18) | (byte1 << 5 & 0x20); set_info((type8)(l1c | 0x80)); set_arg1(); do_move(); break; /* 30-3F [3327] MOVE.W */ case 0x18: case 0x19: case 0x1a: case 0x1b: case 0x1c: case 0x1d: case 0x1e: case 0x1f: #ifdef LOGEMU out("move.w"); #endif set_info((type8)((byte2 & 0x3f) | 0x40)); set_arg1(); swap_args(); l1c = (byte1 >> 1 & 0x07) | (byte2 >> 3 & 0x18) | (byte1 << 5 & 0x20); set_info((type8)(l1c | 0x40)); set_arg1(); do_move(); break; /* 40-4F various commands */ case 0x20: if (byte1 == 0x40) { /* [31d5] */ ms_fatal("unimplemented instructions NEGX and MOVE SR,xx"); } else check_lea(); break; case 0x21: if (byte1 == 0x42) { /* [3188] */ if ((byte2 & 0xc0) == 0xc0) { ms_fatal("unimplemented instruction MOVE CCR,xx"); } else { /* CLR */ #ifdef LOGEMU out("clr"); #endif set_info(byte2); set_arg1(); if (opsize == 0) arg1[0] = 0; if (opsize == 1) write_w(arg1, 0); if (opsize == 2) write_l(arg1, 0); nflag = cflag = 0; zflag = 0xff; } } else check_lea(); break; case 0x22: if (byte1 == 0x44) { /* [31a0] */ if ((byte2 & 0xc0) == 0xc0) { /* MOVE to CCR */ #ifdef LOGEMU out("move_ccr"); #endif zflag = nflag = cflag = vflag = 0; set_info((type8)(byte2 & 0x7f)); set_arg1(); byte2 = arg1[1]; if (byte2 & 0x01) cflag = 0xff; if (byte2 & 0x02) vflag = 0xff; if (byte2 & 0x04) zflag = 0xff; if (byte2 & 0x08) nflag = 0xff; } else { #ifdef LOGEMU out("neg"); #endif set_info(byte2); /* NEG */ set_arg1(); cflag = 0xff; if (opsize == 0) { arg1[0] = (-arg1[0]); cflag = arg1[0] ? 0xff : 0; } if (opsize == 1) { write_w(arg1, (type16)(-1 * read_w(arg1))); cflag = read_w(arg1) ? 0xff : 0; } if (opsize == 2) { write_l(arg1, -1 * read_l(arg1)); cflag = read_l(arg1) ? 0xff : 0; } vflag = 0; set_flags(); } } else check_lea(); break; case 0x23: if (byte1 == 0x46) { if ((byte2 & 0xc0) == 0xc0) { ms_fatal("unimplemented instruction MOVE xx,SR"); } else { #ifdef LOGEMU out("not"); #endif set_info(byte2); /* NOT */ set_arg1(); tmparg[0] = tmparg[1] = tmparg[2] = tmparg[3] = 0xff; arg2 = tmparg; do_eor(); } } else check_lea(); break; case 0x24: if (byte1 == 0x48) { if ((byte2 & 0xf8) == 0x40) { #ifdef LOGEMU out("swap"); #endif opsize = 2; /* SWAP */ admode = 0; regnr = byte2 & 0x07; set_arg1(); tmp32 = read_w(arg1); write_w(arg1, read_w(arg1 + 2)); write_w(arg1 + 2, (type16)tmp32); set_flags(); } else if ((byte2 & 0xf8) == 0x80) { #ifdef LOGEMU out("ext.w"); #endif opsize = 1; /* EXT.W */ admode = 0; regnr = byte2 & 0x07; set_arg1(); if (arg1[1] > 0x7f) arg1[0] = 0xff; else arg1[0] = 0; set_flags(); } else if ((byte2 & 0xf8) == 0xc0) { #ifdef LOGEMU out("ext.l"); #endif opsize = 2; /* EXT.L */ admode = 0; regnr = byte2 & 0x07; set_arg1(); if (read_w(arg1 + 2) > 0x7fff) write_w(arg1, 0xffff); else write_w(arg1, 0); set_flags(); } else if ((byte2 & 0xc0) == 0x40) { #ifdef LOGEMU out("pea"); #endif set_info((type8)((byte2 & 0x3f) | 0x80)); /* PEA */ set_arg1(); if (is_reversible) push(arg1i); else ms_fatal("illegal addressing mode for PEA"); } else { check_movem(); /* MOVEM */ } } else check_lea(); break; case 0x25: if (byte1 == 0x4a) { /* [3219] TST */ if ((byte2 & 0xc0) == 0xc0) { ms_fatal("unimplemented instruction TAS"); } else { #ifdef LOGEMU out("tst"); #endif set_info(byte2); set_arg1(); cflag = vflag = 0; set_flags(); } } else check_lea(); break; case 0x26: if (byte1 == 0x4c) check_movem2(); /* [3350] MOVEM.L (Ax)+,A/Dx */ else check_lea(); /* LEA */ break; case 0x27: if (byte1 == 0x4e) { /* [3290] */ if (byte2 == 0x75) { /* RTS */ #ifdef LOGEMU out("rts\n"); #endif pc = pop(); } else if (byte2 == 0x71) { /* NOP */ #ifdef LOGEMU out("nop"); #endif } else if ((byte2 & 0xc0) == 0xc0) { /* indir JMP */ #ifdef LOGEMU out("jmp"); #endif set_info((type8)(byte2 | 0xc0)); set_arg1(); if (is_reversible) pc = arg1i; else ms_fatal("illegal addressing mode for JMP"); } else if ((byte2 & 0xc0) == 0x80) { #ifdef LOGEMU out("jsr"); #endif set_info((type8)(byte2 | 0xc0)); /* indir JSR */ set_arg1(); push(pc); if (is_reversible) pc = arg1i; else ms_fatal("illegal addressing mode for JSR"); } else { ms_fatal("unimplemented instructions 0x4EXX"); } } else check_lea(); /* LEA */ break; /* 50-5F [2ed5] ADDQ/SUBQ/Scc/DBcc */ case 0x28: case 0x29: case 0x2a: case 0x2b: case 0x2c: case 0x2d: case 0x2e: case 0x2f: if ((byte2 & 0xc0) == 0xc0) { set_info((type8)(byte2 & 0x3f)); set_arg1(); if (admode == 1) { /* DBcc */ #ifdef LOGEMU out("dbcc"); #endif if (condition(byte1) == 0) { arg1 = (arg1 - (type8 *) areg) + (type8 *) dreg - 1; write_w(arg1, (type16)(read_w(arg1) - 1)); if (read_w(arg1) != 0xffff) branch(0); else pc += 2; } else pc += 2; } else { /* Scc */ #ifdef LOGEMU out("scc"); #endif arg1[0] = condition(byte1) ? 0xff : 0; } } else { set_info(byte2); set_arg1(); quick_flag = (admode == 1) ? 0xff : 0; l1c = byte1 >> 1 & 0x07; tmparg[0] = tmparg[1] = tmparg[2] = 0; tmparg[3] = l1c ? l1c : 8; arg2 = reg_align(tmparg, opsize); { #ifdef LOGEMU type32s outnum = 0; switch (opsize) { case 0: outnum = (type8s) arg2[0]; break; case 1: outnum = (type16s) read_w(arg2); break; case 2: outnum = (type32s) read_l(arg2); break; } #endif if ((byte1 & 0x01) == 1) { #ifdef LOGEMU out("subq #%.8X", outnum); #endif do_sub(0); /* SUBQ */ } else { #ifdef LOGEMU out("addq #%.8X", outnum); #endif do_add(0); /* ADDQ */ } } } break; /* 60-6F [26ba] Bcc */ case 0x30: if (byte1 == 0x61) { /* BRA, BSR */ #ifdef LOGEMU out("bsr"); #endif if (byte2 == 0) push(pc + 2); else push(pc); } #ifdef LOGEMU else out("bra"); #endif if ((byte1 == 0x60) && (byte2 == 0xfe)) { ms_flush(); /* flush stdout */ ms_stop(); /* infinite loop - just exit */ } branch(byte2); break; case 0x31: case 0x32: case 0x33: case 0x34: case 0x35: case 0x36: case 0x37: if (condition(byte1) == 0) { #ifdef LOGEMU out("beq.s"); #endif if (byte2 == 0) pc += 2; } else { #ifdef LOGEMU out("bra"); #endif branch(byte2); } break; /* 70-7F [260a] MOVEQ */ case 0x38: case 0x39: case 0x3a: case 0x3b: case 0x3c: case 0x3d: case 0x3e: case 0x3f: #ifdef LOGEMU out("moveq"); #endif arg1 = (type8 *) & dreg[byte1 >> 1 & 0x07]; if (byte2 > 127) nflag = arg1[0] = arg1[1] = arg1[2] = 0xff; else nflag = arg1[0] = arg1[1] = arg1[2] = 0; arg1[3] = byte2; zflag = byte2 ? 0 : 0xff; break; /* 80-8F [2f36] */ case 0x40: case 0x41: case 0x42: case 0x43: case 0x44: case 0x45: case 0x46: case 0x47: if ((byte2 & 0xc0) == 0xc0) { ms_fatal("unimplemented instructions DIVS and DIVU"); } else if (((byte2 & 0xf0) == 0) && ((byte1 & 0x01) != 0)) { ms_fatal("unimplemented instruction SBCD"); } else { #ifdef LOGEMU out("or?"); #endif set_info(byte2); set_arg1(); set_arg2(1, byte1); if ((byte1 & 0x01) == 0) swap_args(); do_or(); } break; /* 90-9F [3005] SUB */ case 0x48: case 0x49: case 0x4a: case 0x4b: case 0x4c: case 0x4d: case 0x4e: case 0x4f: #ifdef LOGEMU out("sub"); #endif quick_flag = 0; if ((byte2 & 0xc0) == 0xc0) { if ((byte1 & 0x01) == 1) set_info((type8)(byte2 & 0xbf)); else set_info((type8)(byte2 & 0x7f)); set_arg1(); set_arg2_nosize(0, byte1); swap_args(); do_sub(1); } else { set_info(byte2); set_arg1(); set_arg2(1, byte1); if ((byte1 & 0x01) == 0) swap_args(); do_sub(0); } break; /* A0-AF various special commands [LINE_A] */ case 0x50: case 0x56: case 0x57: /* [2521] */ do_line_a(); #ifdef LOGEMU out("LINE_A A0%.2X", byte2); #endif break; case 0x51: #ifdef LOGEMU out("rts\n"); #endif pc = pop(); /* RTS */ break; case 0x52: #ifdef LOGEMU out("bsr"); #endif if (byte2 == 0) push(pc + 2); /* BSR */ else push(pc); branch(byte2); break; case 0x53: if ((byte2 & 0xc0) == 0xc0) { /* TST [321d] */ ms_fatal("unimplemented instructions LINE_A #$6C0-#$6FF"); } else { #ifdef LOGEMU out("tst"); #endif set_info(byte2); set_arg1(); cflag = vflag = 0; set_flags(); } break; case 0x54: check_movem(); break; case 0x55: check_movem2(); break; /* B0-BF [2fe4] */ case 0x58: case 0x59: case 0x5a: case 0x5b: case 0x5c: case 0x5d: case 0x5e: case 0x5f: if ((byte2 & 0xc0) == 0xc0) { #ifdef LOGEMU out("cmp"); #endif if ((byte1 & 0x01) == 1) set_info((type8)(byte2 & 0xbf)); else set_info((type8)(byte2 & 0x7f)); set_arg1(); set_arg2(0, byte1); swap_args(); do_cmp(); /* CMP */ } else { if ((byte1 & 0x01) == 0) { #ifdef LOGEMU out("cmp"); #endif set_info(byte2); set_arg1(); set_arg2(1, byte1); swap_args(); do_cmp(); /* CMP */ } else { #ifdef LOGEMU out("eor"); #endif set_info(byte2); set_arg1(); set_arg2(1, byte1); do_eor(); /* EOR */ } } break; /* C0-CF [2f52] EXG, AND */ case 0x60: case 0x61: case 0x62: case 0x63: case 0x64: case 0x65: case 0x66: case 0x67: if ((byte1 & 0x01) == 0) { if ((byte2 & 0xc0) == 0xc0) { ms_fatal("unimplemented instruction MULU"); } else { /* AND */ #ifdef LOGEMU out("and"); #endif set_info(byte2); set_arg1(); set_arg2(1, byte1); if ((byte1 & 0x01) == 0) swap_args(); do_and(); } } else { if ((byte2 & 0xf8) == 0x40) { #ifdef LOGEMU out("exg (dx)"); #endif opsize = 2; /* EXG Dx,Dx */ set_arg2(1, (type8)(byte2 << 1)); swap_args(); set_arg2(1, byte1); tmp32 = read_l(arg1); write_l(arg1, read_l(arg2)); write_l(arg2, tmp32); } else if ((byte2 & 0xf8) == 0x48) { opsize = 2; /* EXG Ax,Ax */ #ifdef LOGEMU out("exg (ax)"); #endif set_arg2(0, (type8)(byte2 << 1)); swap_args(); set_arg2(0, byte1); tmp32 = read_l(arg1); write_l(arg1, read_l(arg2)); write_l(arg2, tmp32); } else if ((byte2 & 0xf8) == 0x88) { opsize = 2; /* EXG Dx,Ax */ #ifdef LOGEMU out("exg (dx,ax)"); #endif set_arg2(0, (type8)(byte2 << 1)); swap_args(); set_arg2(1, byte1); tmp32 = read_l(arg1); write_l(arg1, read_l(arg2)); write_l(arg2, tmp32); } else { if ((byte2 & 0xc0) == 0xc0) { ms_fatal("unimplemented instruction MULS"); } else { set_info(byte2); set_arg1(); set_arg2(1, byte1); if ((byte1 & 0x01) == 0) swap_args(); do_and(); } } } break; /* D0-DF [2fc8] ADD */ case 0x68: case 0x69: case 0x6a: case 0x6b: case 0x6c: case 0x6d: case 0x6e: case 0x6f: #ifdef LOGEMU out("add"); #endif quick_flag = 0; if ((byte2 & 0xc0) == 0xc0) { if ((byte1 & 0x01) == 1) set_info((type8)(byte2 & 0xbf)); else set_info((type8)(byte2 & 0x7f)); set_arg1(); set_arg2_nosize(0, byte1); swap_args(); do_add(1); } else { set_info(byte2); set_arg1(); set_arg2(1, byte1); if ((byte1 & 0x01) == 0) swap_args(); do_add(0); } break; /* E0-EF [3479] LSR ASL ROR ROL */ case 0x70: case 0x71: case 0x72: case 0x73: case 0x74: case 0x75: case 0x76: case 0x77: #ifdef LOGEMU out("lsr,asl,ror,rol"); #endif if ((byte2 & 0xc0) == 0xc0) { set_info((type8)(byte2 & 0xbf)); /* OP Dx */ set_arg1(); l1c = 1; /* steps=1 */ byte2 = (byte1 >> 1) & 0x03; } else { set_info((type8)(byte2 & 0xc7)); set_arg1(); if ((byte2 & 0x20) == 0) { /* immediate */ l1c = (byte1 >> 1) & 0x07; if (l1c == 0) l1c = 8; } else { l1c = (type8)read_reg(byte1 >> 1 & 0x07, 0); } byte2 = (byte2 >> 3) & 0x03; } if ((byte1 & 0x01) == 0) { /* right */ while (l1c-- > 0) { if (opsize == 0) { cflag = arg1[0] & 0x01 ? 0xff : 0; arg1[0] >>= 1; if (cflag && (byte2 == 3)) arg1[0] |= 0x80; } if (opsize == 1) { cflag = read_w(arg1) & 0x01 ? 0xff : 0; write_w(arg1, (type16)(read_w(arg1) >> 1)); if (cflag && (byte2 == 3)) write_w(arg1, (type16)(read_w(arg1) | ((type16) 1 << 15))); } if (opsize == 2) { cflag = read_l(arg1) & 0x01 ? 0xff : 0; write_l(arg1, read_l(arg1) >> 1); if (cflag && (byte2 == 3)) write_l(arg1, read_l(arg1) | ((type32) 1 << 31)); } } } else { /* left */ while (l1c-- > 0) { if (opsize == 0) { cflag = arg1[0] & 0x80 ? 0xff : 0; /* [3527] */ arg1[0] <<= 1; if (cflag && (byte2 == 3)) arg1[0] |= 0x01; } if (opsize == 1) { cflag = read_w(arg1) & ((type16) 1 << 15) ? 0xff : 0; write_w(arg1, (type16)(read_w(arg1) << 1)); if (cflag && (byte2 == 3)) write_w(arg1, (type16)(read_w(arg1) | 0x01)); } if (opsize == 2) { cflag = read_l(arg1) & ((type32) 1 << 31) ? 0xff : 0; write_l(arg1, read_l(arg1) << 1); if (cflag && (byte2 == 3)) write_l(arg1, read_l(arg1) | 0x01); } } } set_flags(); break; /* F0-FF [24f3] LINE_F */ case 0x78: case 0x79: case 0x7a: case 0x7b: case 0x7c: case 0x7d: case 0x7e: case 0x7f: if (version == 0) { /* hardcoded jump */ char_out(l1c = (type8)read_reg(1, 0)); } else if (version == 1) { /* single programmable shortcut */ push(pc); pc = fl_sub; } else { /* programmable shortcuts from table */ #ifdef LOGEMU out("LINK: %.2X,%.2X", byte1, byte2); #endif ptr = (byte1 & 7) << 8 | byte2; if (ptr >= fl_size) { if ((byte1 & 8) == 0) push(pc); ptr = byte1 << 8 | byte2 | 0x0800; ptr = fl_tab + 2 * (ptr ^ 0xffff); pc = (type32) ptr + (type16s) read_w(effective(ptr)); } else { push(pc); pc = fl_sub; } } break; default: ms_fatal("Constants aren't and variables don't"); break; } #ifdef LOGEMU fprintf(dbg_log, "\n"); #endif return running; } } // End of namespace Magnetic } // End of namespace Glk