/* 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. */ /*============================================================================== $Id$ Oktalyzer (OKT) module loader ==============================================================================*/ /* Written by UFO based on the file description compiled by Harald Zappe */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #ifdef HAVE_UNISTD_H #include #endif #include #ifdef HAVE_MEMORY_H #include #endif #include #include "mikmod_internals.h" #ifdef SUNOS extern int fprintf(FILE *, const char *, ...); #endif /*========== Module blocks */ /* sample information */ typedef struct OKTSAMPLE { CHAR sampname[20]; ULONG len; UWORD loopbeg; UWORD looplen; UBYTE volume; } OKTSAMPLE; typedef struct OKTNOTE { UBYTE note, ins, eff, dat; } OKTNOTE; /*========== Loader variables */ static OKTNOTE *okttrk = NULL; /*========== Loader code */ static int OKT_Test(void) { CHAR id[8]; if (!_mm_read_UBYTES(id, 8, modreader)) return 0; if (!memcmp(id, "OKTASONG", 8)) return 1; return 0; } /* Pattern analysis routine. Effects not implemented (yet) : (in decimal) 11 Arpeggio 4: Change note every 50Hz tick between N,H,N,L 12 Arpeggio 5: Change note every 50Hz tick between H,H,N N = normal note being played in this channel (1-36) L = normal note number minus upper four bits of 'data'. H = normal note number plus lower four bits of 'data'. 13 Decrease note number by 'data' once per tick. 17 Increase note number by 'data' once per tick. 21 Decrease note number by 'data' once per line. 30 Increase note number by 'data' once per line. */ static UBYTE *OKT_ConvertTrack(UBYTE patrows) { int t; UBYTE ins, note, eff, dat; UniReset(); for (t = 0; t < patrows; t++) { note = okttrk[t].note; ins = okttrk[t].ins; eff = okttrk[t].eff; dat = okttrk[t].dat; if (note) { UniNote(note + 3 * OCTAVE - 1); UniInstrument(ins); } if (eff) switch (eff) { case 1: /* Porta Up */ UniPTEffect(0x1, dat); break; case 2: /* Portamento Down */ UniPTEffect(0x2, dat); break; /* case 9: what is this? */ case 10: /* Arpeggio 3 */ case 11: /* Arpeggio 4 */ case 12: /* Arpeggio 5 */ UniWriteByte(UNI_OKTARP); UniWriteByte(eff + 3 - 10); UniWriteByte(dat); break; case 15: /* Amiga filter toggle, ignored */ break; case 25: /* Pattern Jump */ dat = (dat >> 4) * 10 + (dat & 0x0f); UniPTEffect(0xb, dat); break; case 27: /* Release - similar to Keyoff */ UniWriteByte(UNI_KEYOFF); break; case 28: /* Set Tempo */ UniPTEffect(0xf, dat & 0x0f); break; case 31: /* volume Control */ if (dat <= 0x40) UniPTEffect(0xc, dat); else if (dat <= 0x50) UniEffect(UNI_XMEFFECTA, (dat - 0x40)); /* fast fade out */ else if (dat <= 0x60) UniEffect(UNI_XMEFFECTA, (dat - 0x50) << 4); /* fast fade in */ else if (dat <= 0x70) UniEffect(UNI_XMEFFECTEB, (dat - 0x60)); /* slow fade out */ else if (dat <= 0x80) UniEffect(UNI_XMEFFECTEA, (dat - 0x70)); /* slow fade in */ break; #ifdef MIKMOD_DEBUG default: fprintf(stderr, "\rUnimplemented effect (%02d,%02x)\n", eff, dat); #endif } UniNewline(); } return UniDup(); } /* Read "channel modes" i.e. channel number and panning information */ static void OKT_doCMOD(void) { /* amiga channel panning table */ UBYTE amigapan[4] = { 0x00, 0xff, 0xff, 0x00 }; int t; of.numchn = 0; of.flags |= UF_PANNING; for (t = 0; t < 4; t++) if (_mm_read_M_UWORD(modreader)) { /* two channels tied to the same Amiga hardware voice */ of.panning[of.numchn++] = amigapan[t]; of.panning[of.numchn++] = amigapan[t]; } else /* one channel tied to the Amiga hardware voice */ of.panning[of.numchn++] = amigapan[t]; } /* Read sample information */ static int OKT_doSAMP(int len) { int t; SAMPLE *q; OKTSAMPLE s; of.numins = of.numsmp = (len / 0x20); if (!AllocSamples()) return 0; for (t = 0, q = of.samples; t < of.numins; t++, q++) { _mm_read_UBYTES(s.sampname, 20, modreader); s.len = _mm_read_M_ULONG(modreader); s.loopbeg = _mm_read_M_UWORD(modreader) * 2; s.looplen = _mm_read_M_UWORD(modreader) * 2; _mm_skip_BYTE(modreader); s.volume = _mm_read_UBYTE(modreader); _mm_read_M_UWORD(modreader); if (_mm_eof(modreader)) { _mm_errno = MMERR_LOADING_SAMPLEINFO; return 0; } if (!s.len) q->seekpos = q->length = q->loopstart = q->loopend = q->flags = 0; else { s.len--; /* sanity checks */ if (s.loopbeg > s.len) s.loopbeg = s.len; if (s.loopbeg + s.looplen > s.len) s.looplen = s.len - s.loopbeg; if (s.looplen < 2) s.looplen = 0; q->length = s.len; q->loopstart = s.loopbeg; q->loopend = s.looplen + q->loopstart; q->volume = s.volume; q->flags = SF_SIGNED; if (s.looplen) q->flags |= SF_LOOP; } q->samplename = DupStr(s.sampname, 20, 1); q->speed = 8287; } return 1; } /* Read speed information */ static void OKT_doSPEE(void) { int tempo = _mm_read_M_UWORD(modreader); of.initspeed = tempo; } /* Read song length information */ static void OKT_doSLEN(void) { of.numpat = _mm_read_M_UWORD(modreader); } /* Read pattern length information */ static void OKT_doPLEN(void) { of.numpos = _mm_read_M_UWORD(modreader); } /* Read order table */ static int OKT_doPATT(void) { int t; if (!of.numpos || !AllocPositions(of.numpos)) return 0; for (t = 0; t < 128; t++) if (t < of.numpos) of.positions[t] = _mm_read_UBYTE(modreader); else break; return 1; } static int OKT_doPBOD(int patnum) { char *patbuf; int rows, i; int u; if (!patnum) { of.numtrk = of.numpat * of.numchn; if (!AllocTracks() || !AllocPatterns()) return 0; } /* Read pattern */ of.pattrows[patnum] = rows = _mm_read_M_UWORD(modreader); if (!(okttrk = (OKTNOTE *) MikMod_calloc(rows, sizeof(OKTNOTE))) || !(patbuf = (char *)MikMod_calloc(rows * of.numchn, sizeof(OKTNOTE)))) return 0; _mm_read_UBYTES(patbuf, rows * of.numchn * sizeof(OKTNOTE), modreader); if (_mm_eof(modreader)) { _mm_errno = MMERR_LOADING_PATTERN; return 0; } for (i = 0; i < of.numchn; i++) { for (u = 0; u < rows; u++) { okttrk[u].note = patbuf[(u * of.numchn + i) * sizeof(OKTNOTE)]; okttrk[u].ins = patbuf[(u * of.numchn + i) * sizeof(OKTNOTE) + 1]; okttrk[u].eff = patbuf[(u * of.numchn + i) * sizeof(OKTNOTE) + 2]; okttrk[u].dat = patbuf[(u * of.numchn + i) * sizeof(OKTNOTE) + 3]; } if (!(of.tracks[patnum * of.numchn + i] = OKT_ConvertTrack(rows))) return 0; } MikMod_free(patbuf); MikMod_free(okttrk); okttrk = NULL; return 1; } static void OKT_doSBOD(int insnum) { of.samples[insnum].seekpos = _mm_ftell(modreader); } static int OKT_Load(int curious) { UBYTE id[4]; ULONG len; ULONG fp; int seen_cmod = 0, seen_samp = 0, seen_slen = 0, seen_plen = 0, seen_patt = 0, seen_spee = 0; int patnum = 0, insnum = 0; (void)curious; /* skip OKTALYZER header */ _mm_fseek(modreader, 8, SEEK_SET); of.songname = MikMod_strdup(""); of.modtype = MikMod_strdup("Amiga Oktalyzer"); of.numpos = of.reppos = 0; /* default values */ of.initspeed = 6; of.inittempo = 125; while (1) { /* read block header */ _mm_read_UBYTES(id, 4, modreader); len = _mm_read_M_ULONG(modreader); if (_mm_eof(modreader)) break; fp = _mm_ftell(modreader); if (!memcmp(id, "CMOD", 4)) { if (!seen_cmod) { OKT_doCMOD(); seen_cmod = 1; } else { _mm_errno = MMERR_LOADING_HEADER; return 0; } } else if (!memcmp(id, "SAMP", 4)) { if (!seen_samp && OKT_doSAMP(len)) seen_samp = 1; else { _mm_errno = MMERR_LOADING_HEADER; return 0; } } else if (!memcmp(id, "SPEE", 4)) { if (!seen_spee) { OKT_doSPEE(); seen_spee = 1; } else { _mm_errno = MMERR_LOADING_HEADER; return 0; } } else if (!memcmp(id, "SLEN", 4)) { if (!seen_slen) { OKT_doSLEN(); seen_slen = 1; } else { _mm_errno = MMERR_LOADING_HEADER; return 0; } } else if (!memcmp(id, "PLEN", 4)) { if (!seen_plen) { OKT_doPLEN(); seen_plen = 1; } else { _mm_errno = MMERR_LOADING_HEADER; return 0; } } else if (!memcmp(id, "PATT", 4)) { if (!seen_plen) { _mm_errno = MMERR_LOADING_HEADER; return 0; } if (!seen_patt && OKT_doPATT()) seen_patt = 1; else { _mm_errno = MMERR_LOADING_HEADER; return 0; } } else if (!memcmp(id,"PBOD", 4)) { /* need to know numpat and numchn */ if (!seen_slen || !seen_cmod || (patnum >= of.numpat)) { _mm_errno = MMERR_LOADING_HEADER; return 0; } if (!OKT_doPBOD(patnum++)) { _mm_errno = MMERR_LOADING_PATTERN; return 0; } } else if (!memcmp(id,"SBOD",4)) { /* need to know numsmp */ if (!seen_samp) { _mm_errno = MMERR_LOADING_HEADER; return 0; } while ((insnum < of.numins) && !of.samples[insnum].length) insnum++; if (insnum >= of.numins) { _mm_errno = MMERR_LOADING_HEADER; return 0; } OKT_doSBOD(insnum++); } /* goto next block start position */ _mm_fseek(modreader, fp + len, SEEK_SET); } if (!seen_cmod || !seen_samp || !seen_patt || !seen_slen || !seen_plen || (patnum != of.numpat)) { _mm_errno = MMERR_LOADING_HEADER; return 0; } return 1; } static CHAR *OKT_LoadTitle(void) { return MikMod_strdup(""); } /*========== Loader information */ MIKMODAPI MLOADER load_okt = { NULL, "OKT", "OKT (Amiga Oktalyzer)", NULL, OKT_Test, OKT_Load, NULL, OKT_LoadTitle }; /* ex:set ts=4: */