/* MikMod sound library (c) 1998, 1999, 2000, 2001, 2002 Miodrag Vallat and others - see file AUTHORS for complete list. This library is free software; you can redistribute it and/or modify it under the terms of the GNU Library 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 Library General Public License for more details. You should have received a copy of the GNU Library General Public License along with this library; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /*============================================================================== $Id: load_mod.c,v 1.3 2005/04/07 19:57:38 realtech Exp $ Generic MOD loader (Protracker, StarTracker, FastTracker, etc) ==============================================================================*/ #ifdef HAVE_CONFIG_H #include "config.h" #endif #ifdef HAVE_UNISTD_H #include #endif #include #include #ifdef HAVE_MEMORY_H #include #endif #include #include "mikmod_internals.h" #ifdef SUNOS extern int fprintf(FILE *, const char *, ...); #endif /*========== Module structure */ typedef struct MSAMPINFO { CHAR samplename[23]; /* 22 in module, 23 in memory */ UWORD length; UBYTE finetune; UBYTE volume; UWORD reppos; UWORD replen; } MSAMPINFO; typedef struct MODULEHEADER { CHAR songname[21]; /* the songname.. 20 in module, 21 in memory */ MSAMPINFO samples[31]; /* all sampleinfo */ UBYTE songlength; /* number of patterns used */ UBYTE magic1; /* should be 127 */ UBYTE positions[128]; /* which pattern to play at pos */ UBYTE magic2[4]; /* string "M.K." or "FLT4" or "FLT8" */ } MODULEHEADER; typedef struct MODTYPE { CHAR id[5]; UBYTE channels; CHAR *name; } MODTYPE; typedef struct MODNOTE { UBYTE a, b, c, d; } MODNOTE; /*========== Loader variables */ #define MODULEHEADERSIZE 0x438 static CHAR protracker[] = "Protracker"; static CHAR startrekker[] = "Startrekker"; static CHAR fasttracker[] = "Fasttracker"; static CHAR oktalyser[] = "Oktalyser"; static CHAR oktalyzer[] = "Oktalyzer"; static CHAR taketracker[] = "TakeTracker"; static CHAR orpheus[] = "Imago Orpheus (MOD format)"; static MODULEHEADER *mh = NULL; static MODNOTE *patbuf = NULL; static int modtype, trekker; /*========== Loader code */ /* given the module ID, determine the number of channels and the tracker description ; also alters modtype */ static int MOD_CheckType(UBYTE *id, UBYTE *numchn, CHAR **descr) { modtype = trekker = 0; /* Protracker and variants */ if ((!memcmp(id, "M.K.", 4)) || (!memcmp(id, "M!K!", 4))) { *descr = protracker; modtype = 0; *numchn = 4; return 1; } /* Star Tracker */ if (((!memcmp(id, "FLT", 3)) || (!memcmp(id, "EXO", 3))) && (isdigit(id[3]))) { *descr = startrekker; modtype = trekker = 1; *numchn = id[3] - '0'; if (*numchn == 4 || *numchn == 8) return 1; #ifdef MIKMOD_DEBUG else fprintf(stderr, "\rUnknown FLT%d module type\n", *numchn); #endif return 0; } /* Oktalyzer (Amiga) */ if (!memcmp(id, "OKTA", 4)) { *descr = oktalyzer; modtype = 1; *numchn = 8; return 1; } /* Oktalyser (Atari) */ if (!memcmp(id, "CD81", 4)) { *descr = oktalyser; modtype = 1; *numchn = 8; return 1; } /* Fasttracker */ if ((!memcmp(id + 1, "CHN", 3)) && (isdigit(id[0]))) { *descr = fasttracker; modtype = 1; *numchn = id[0] - '0'; return 1; } /* Fasttracker or Taketracker */ if (((!memcmp(id + 2, "CH", 2)) || (!memcmp(id + 2, "CN", 2))) && (isdigit(id[0])) && (isdigit(id[1]))) { if (id[3] == 'H') { *descr = fasttracker; modtype = 2; /* this can also be Imago Orpheus */ } else { *descr = taketracker; modtype = 1; } *numchn = (id[0] - '0') * 10 + (id[1] - '0'); return 1; } return 0; } static int MOD_Test(void) { UBYTE id[4], numchn; CHAR *descr; _mm_fseek(modreader, MODULEHEADERSIZE, SEEK_SET); if (!_mm_read_UBYTES(id, 4, modreader)) return 0; if (MOD_CheckType(id, &numchn, &descr)) return 1; return 0; } static int MOD_Init(void) { if (!(mh = (MODULEHEADER *)MikMod_malloc(sizeof(MODULEHEADER)))) return 0; return 1; } static void MOD_Cleanup(void) { MikMod_free(mh); MikMod_free(patbuf); } /* Old (amiga) noteinfo: _____byte 1_____ byte2_ _____byte 3_____ byte4_ / \ / \ / \ / \ 0000 0000-00000000 0000 0000-00000000 Upper four 12 bits for Lower four Effect command. bits of sam- note period. bits of sam- ple number. ple number. */ static UBYTE ConvertNote(MODNOTE *n, UBYTE lasteffect) { UBYTE instrument, effect, effdat, note; UWORD period; UBYTE lastnote = 0; /* extract the various information from the 4 bytes that make up a note */ instrument = (n->a & 0x10) | (n->c >> 4); period = (((UWORD)n->a & 0xf) << 8) + n->b; effect = n->c & 0xf; effdat = n->d; /* Convert the period to a note number */ note = 0; if (period) { for (note = 0; note < 7 * OCTAVE; note++) if (period >= npertab[note]) break; if (note == 7 * OCTAVE) note = 0; else note++; } if (instrument) { /* if instrument does not exist, note cut */ if ((instrument > 31) || (!mh->samples[instrument - 1].length)) { UniPTEffect(0xc, 0); if (effect == 0xc) effect = effdat = 0; } else { /* Protracker handling */ if (!modtype) { /* if we had a note, then change instrument... */ if (note) UniInstrument(instrument - 1); /* ...otherwise, only adjust volume... */ else { /* ...unless an effect was specified, which forces a new note to be played */ if (effect || effdat) { UniInstrument(instrument - 1); note = lastnote; } else UniPTEffect(0xc, mh->samples[instrument - 1].volume & 0x7f); } } else { /* Fasttracker handling */ UniInstrument(instrument - 1); if (!note) note = lastnote; } } } if (note) { UniNote(note + 2 * OCTAVE - 1); lastnote = note; } /* Convert pattern jump from Dec to Hex */ if (effect == 0xd) effdat = (((effdat & 0xf0) >> 4) * 10) + (effdat & 0xf); /* Volume slide, up has priority */ if ((effect == 0xa) && (effdat & 0xf) && (effdat & 0xf0)) effdat &= 0xf0; /* Handle ``heavy'' volumes correctly */ if ((effect == 0xc) && (effdat > 0x40)) effdat = 0x40; /* An isolated 100, 200 or 300 effect should be ignored (no "standalone" porta memory in mod files). However, a sequence such as 1XX, 100, 100, 100 is fine. */ if ((!effdat) && ((effect == 1)||(effect == 2)||(effect ==3)) && (lasteffect < 0x10) && (effect != lasteffect)) effect = 0; UniPTEffect(effect, effdat); if (effect == 8) of.flags |= UF_PANNING; return effect; } static UBYTE *ConvertTrack(MODNOTE *n, int numchn) { int t; UBYTE lasteffect = 0x10; /* non existant effect */ UniReset(); for (t = 0; t < 64; t++) { lasteffect = ConvertNote(n,lasteffect); UniNewline(); n += numchn; } return UniDup(); } /* Loads all patterns of a modfile and converts them into the 3 byte format. */ static int ML_LoadPatterns(void) { int t, s, tracks = 0; if (!AllocPatterns()) return 0; if (!AllocTracks()) return 0; /* Allocate temporary buffer for loading and converting the patterns */ if (!(patbuf = (MODNOTE *)MikMod_calloc(64U * of.numchn, sizeof(MODNOTE)))) return 0; if (trekker && of.numchn == 8) { /* Startrekker module dual pattern */ for (t = 0; t < of.numpat; t++) { for (s = 0; s < (64U * 4); s++) { patbuf[s].a = _mm_read_UBYTE(modreader); patbuf[s].b = _mm_read_UBYTE(modreader); patbuf[s].c = _mm_read_UBYTE(modreader); patbuf[s].d = _mm_read_UBYTE(modreader); } for (s = 0; s < 4; s++) if (!(of.tracks[tracks++] = ConvertTrack(patbuf + s, 4))) return 0; for (s = 0; s < (64U * 4); s++) { patbuf[s].a = _mm_read_UBYTE(modreader); patbuf[s].b = _mm_read_UBYTE(modreader); patbuf[s].c = _mm_read_UBYTE(modreader); patbuf[s].d = _mm_read_UBYTE(modreader); } for (s = 0; s < 4; s++) if (!(of.tracks[tracks++] = ConvertTrack(patbuf + s, 4))) return 0; } } else { /* Generic module pattern */ for (t = 0; t < of.numpat; t++) { /* Load the pattern into the temp buffer and convert it */ for (s = 0; s < (64U * of.numchn); s++) { patbuf[s].a = _mm_read_UBYTE(modreader); patbuf[s].b = _mm_read_UBYTE(modreader); patbuf[s].c = _mm_read_UBYTE(modreader); patbuf[s].d = _mm_read_UBYTE(modreader); } for (s = 0; s < of.numchn; s++) if (!(of.tracks[tracks++] = ConvertTrack(patbuf + s, of.numchn))) return 0; } } return 1; } static int MOD_Load(int curious) { int t, scan; SAMPLE *q; MSAMPINFO *s; CHAR *descr; /* try to read module header */ _mm_read_string((CHAR *)mh->songname, 20, modreader); mh->songname[20] = 0; /* just in case */ for (t = 0; t < 31; t++) { s = &mh->samples[t]; _mm_read_string(s->samplename, 22, modreader); s->samplename[22] = 0; /* just in case */ s->length = _mm_read_M_UWORD(modreader); s->finetune = _mm_read_UBYTE(modreader); s->volume = _mm_read_UBYTE(modreader); s->reppos = _mm_read_M_UWORD(modreader); s->replen = _mm_read_M_UWORD(modreader); } mh->songlength = _mm_read_UBYTE(modreader); /* this fixes mods which declare more than 128 positions. * eg: beatwave.mod */ if (mh->songlength > 128) { mh->songlength = 128; } mh->magic1 = _mm_read_UBYTE(modreader); _mm_read_UBYTES(mh->positions, 128, modreader); _mm_read_UBYTES(mh->magic2, 4, modreader); if (_mm_eof(modreader)) { _mm_errno = MMERR_LOADING_HEADER; return 0; } /* set module variables */ of.initspeed = 6; of.inittempo = 125; if (!(MOD_CheckType(mh->magic2, &of.numchn, &descr))) { _mm_errno = MMERR_NOT_A_MODULE; return 0; } if (trekker && of.numchn == 8) for (t = 0; t < 128; t++) /* if module pretends to be FLT8, yet the order table contains odd numbers, chances are it's a lying FLT4... */ if (mh->positions[t] & 1) { of.numchn = 4; break; } if (trekker && of.numchn == 8) for (t = 0; t < 128; t++) mh->positions[t] >>= 1; of.songname = DupStr(mh->songname, 21, 1); of.numpos = mh->songlength; of.reppos = 0; /* Count the number of patterns */ of.numpat = 0; for (t = 0; t < of.numpos; t++) if (mh->positions[t] > of.numpat) of.numpat = mh->positions[t]; /* since some old modules embed extra patterns, we have to check the whole list to get the samples' file offsets right - however we can find garbage here, so check carefully */ scan = 1; for (t = of.numpos; t < 128; t++) if (mh->positions[t] >= 0x80) scan = 0; if (scan) for (t = of.numpos; t < 128; t++) { if (mh->positions[t] > of.numpat) of.numpat = mh->positions[t]; if ((curious) && (mh->positions[t])) of.numpos = t + 1; } of.numpat++; of.numtrk = of.numpat * of.numchn; if (!AllocPositions(of.numpos)) return 0; for (t = 0; t < of.numpos; t++) of.positions[t] = mh->positions[t]; /* Finally, init the sampleinfo structures */ of.numins = of.numsmp = 31; if (!AllocSamples()) return 0; s = mh->samples; q = of.samples; for (t = 0; t < of.numins; t++) { /* convert the samplename */ q->samplename = DupStr(s->samplename, 23, 1); /* init the sampleinfo variables and convert the size pointers */ q->speed = finetune[s->finetune & 0xf]; q->volume = s->volume & 0x7f; q->loopstart = (ULONG)s->reppos << 1; q->loopend = q->loopstart + ((ULONG)s->replen << 1); q->length = (ULONG)s->length << 1; q->flags = SF_SIGNED; /* Imago Orpheus creates MODs with 16 bit samples, check */ if ((modtype == 2) && (s->volume & 0x80)) { q->flags |= SF_16BITS; descr = orpheus; } if (s->replen > 2) q->flags |= SF_LOOP; s++; q++; } of.modtype = StrDup(descr); if (!ML_LoadPatterns()) return 0; return 1; } static CHAR *MOD_LoadTitle(void) { CHAR s[21]; _mm_fseek(modreader, 0, SEEK_SET); if (!_mm_read_UBYTES(s, 20, modreader)) return NULL; s[20] = 0; /* just in case */ return (DupStr(s, 21, 1)); } /*========== Loader information */ MIKMODAPI MLOADER load_mod = { NULL, "Standard module", "MOD (31 instruments)", MOD_Init, MOD_Test, MOD_Load, MOD_Cleanup, MOD_LoadTitle }; /* ex:set ts=4: */