/* * This program is free software; you can redistribute it and 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. * * Authors: Olivier Lapicque , * Adam Goode (endian and char fixes for PPC) */ #include "stdafx.h" #include "sndfile.h" //////////////////////////////////////////////////////// // FastTracker II XM file support #ifdef WIN32 #pragma warning(disable:4244) #endif #pragma pack(1) typedef struct tagXMFILEHEADER { DWORD size; WORD norder; WORD restartpos; WORD channels; WORD patterns; WORD instruments; WORD flags; WORD speed; WORD tempo; BYTE order[256]; } Q_PACKED XMFILEHEADER; typedef struct tagXMINSTRUMENTHEADER { DWORD size; CHAR name[22]; BYTE type; BYTE samples; BYTE samplesh; } Q_PACKED XMINSTRUMENTHEADER; typedef struct tagXMSAMPLEHEADER { DWORD shsize; BYTE snum[96]; WORD venv[24]; WORD penv[24]; BYTE vnum, pnum; BYTE vsustain, vloops, vloope, psustain, ploops, ploope; BYTE vtype, ptype; BYTE vibtype, vibsweep, vibdepth, vibrate; WORD volfade; WORD res; BYTE reserved1[20]; } Q_PACKED XMSAMPLEHEADER; typedef struct tagXMSAMPLESTRUCT { DWORD samplen; DWORD loopstart; DWORD looplen; BYTE vol; signed char finetune; BYTE type; BYTE pan; signed char relnote; BYTE res; char name[22]; } Q_PACKED XMSAMPLESTRUCT; typedef struct tagXMPATTERNHEADER { DWORD size; BYTE packing; WORD rows; WORD packsize; } Q_PACKED XMPATTERNHEADER; #pragma pack() BOOL CSoundFile::ReadXM(const BYTE *lpStream, DWORD dwMemLength) //-------------------------------------------------------------- { XMSAMPLEHEADER xmsh; XMSAMPLESTRUCT xmss; DWORD dwMemPos, dwHdrSize; WORD norders=0, restartpos=0, channels=0, patterns=0, instruments=0; WORD xmflags=0, deftempo=125, defspeed=6; BOOL InstUsed[256]; BYTE channels_used[MAX_CHANNELS]; BYTE pattern_map[256]; BOOL samples_used[MAX_SAMPLES]; UINT unused_samples; m_nChannels = 0; if ((!lpStream) || (dwMemLength < 0x200)) return FALSE; if (strnicmp((LPCSTR)lpStream, "Extended Module", 15)) return FALSE; memcpy(m_szNames[0], lpStream+17, 20); dwHdrSize = bswapLE32(*((DWORD *)(lpStream+60))); norders = bswapLE16(*((WORD *)(lpStream+64))); if ((!norders) || (norders > MAX_ORDERS)) return FALSE; restartpos = bswapLE16(*((WORD *)(lpStream+66))); channels = bswapLE16(*((WORD *)(lpStream+68))); if ((!channels) || (channels > 64)) return FALSE; m_nType = MOD_TYPE_XM; m_nMinPeriod = 27; m_nMaxPeriod = 54784; m_nChannels = channels; if (restartpos < norders) m_nRestartPos = restartpos; patterns = bswapLE16(*((WORD *)(lpStream+70))); if (patterns > 256) patterns = 256; instruments = bswapLE16(*((WORD *)(lpStream+72))); if (instruments >= MAX_INSTRUMENTS) instruments = MAX_INSTRUMENTS-1; m_nInstruments = instruments; m_nSamples = 0; memcpy(&xmflags, lpStream+74, 2); xmflags = bswapLE16(xmflags); if (xmflags & 1) m_dwSongFlags |= SONG_LINEARSLIDES; if (xmflags & 0x1000) m_dwSongFlags |= SONG_EXFILTERRANGE; defspeed = bswapLE16(*((WORD *)(lpStream+76))); deftempo = bswapLE16(*((WORD *)(lpStream+78))); if ((deftempo >= 32) && (deftempo < 256)) m_nDefaultTempo = deftempo; if ((defspeed > 0) && (defspeed < 40)) m_nDefaultSpeed = defspeed; memcpy(Order, lpStream+80, norders); memset(InstUsed, 0, sizeof(InstUsed)); if (patterns > MAX_PATTERNS) { UINT i, j; for (i=0; i= dwMemLength) return TRUE; // Reading patterns memset(channels_used, 0, sizeof(channels_used)); for (UINT ipat=0; ipatsize); /* while ((dwMemPos + dwSize >= dwMemLength) || (dwSize & 0xFFFFFF00)) { if (dwMemPos + 4 >= dwMemLength) break; dwMemPos++; dwSize = bswapLE32(*((DWORD *)(lpStream+dwMemPos))); } */ //rows = bswapLE16(*((WORD *)(lpStream+dwMemPos+5))); rows = bswapLE16(patternHeader->rows); if ((!rows) || (rows > 256)) rows = 64; //packsize = bswapLE16(*((WORD *)(lpStream+dwMemPos+7))); packsize = bswapLE16(patternHeader->packsize); if (dwMemPos + dwSize + 4 > dwMemLength) return TRUE; dwMemPos += dwSize; if (dwMemPos + packsize + 4 > dwMemLength) return TRUE; MODCOMMAND *p; if (ipatmap < MAX_PATTERNS) { PatternSize[ipatmap] = rows; if ((Patterns[ipatmap] = AllocatePattern(rows, m_nChannels)) == NULL) return TRUE; if (!packsize) continue; p = Patterns[ipatmap]; } else p = NULL; const BYTE *src = lpStream+dwMemPos; UINT j=0; for (UINT row=0; rownote = src[j++]; if (b & 2) p->instr = src[j++]; if (b & 4) vol = src[j++]; if (b & 8) p->command = src[j++]; if (b & 16) p->param = src[j++]; } else { p->note = b; p->instr = src[j++]; vol = src[j++]; p->command = src[j++]; p->param = src[j++]; } if (p->note == 97) p->note = 0xFF; else if ((p->note) && (p->note < 97)) p->note += 12; if (p->note) channels_used[chn] = 1; if (p->command | p->param) ConvertModCommand(p); if (p->instr == 0xff) p->instr = 0; if (p->instr) InstUsed[p->instr] = TRUE; if ((vol >= 0x10) && (vol <= 0x50)) { p->volcmd = VOLCMD_VOLUME; p->vol = vol - 0x10; } else if (vol >= 0x60) { UINT v = vol & 0xF0; vol &= 0x0F; p->vol = vol; switch(v) { // 60-6F: Volume Slide Down case 0x60: p->volcmd = VOLCMD_VOLSLIDEDOWN; break; // 70-7F: Volume Slide Up: case 0x70: p->volcmd = VOLCMD_VOLSLIDEUP; break; // 80-8F: Fine Volume Slide Down case 0x80: p->volcmd = VOLCMD_FINEVOLDOWN; break; // 90-9F: Fine Volume Slide Up case 0x90: p->volcmd = VOLCMD_FINEVOLUP; break; // A0-AF: Set Vibrato Speed case 0xA0: p->volcmd = VOLCMD_VIBRATOSPEED; break; // B0-BF: Vibrato case 0xB0: p->volcmd = VOLCMD_VIBRATO; break; // C0-CF: Set Panning case 0xC0: p->volcmd = VOLCMD_PANNING; p->vol = (vol << 2) + 2; break; // D0-DF: Panning Slide Left case 0xD0: p->volcmd = VOLCMD_PANSLIDELEFT; break; // E0-EF: Panning Slide Right case 0xE0: p->volcmd = VOLCMD_PANSLIDERIGHT; break; // F0-FF: Tone Portamento case 0xF0: p->volcmd = VOLCMD_TONEPORTAMENTO; break; } } p++; } else if (j < packsize) { BYTE b = src[j++]; if (b & 0x80) { if (b & 1) j++; if (b & 2) j++; if (b & 4) j++; if (b & 8) j++; if (b & 16) j++; } else j += 4; } else break; } } dwMemPos += packsize; } /* // Wrong offset check while (dwMemPos + 4 < dwMemLength) { DWORD d = bswapLE32(*((DWORD *)(lpStream+dwMemPos))); if (d < 0x300) break; dwMemPos++; } */ memset(samples_used, 0, sizeof(samples_used)); unused_samples = 0; // Reading instruments for (UINT iIns=1; iIns<=instruments; iIns++) { XMINSTRUMENTHEADER *pih; BYTE flags[32]; DWORD samplesize[32]; UINT samplemap[32]; WORD nsamples; if (dwMemPos + sizeof(XMINSTRUMENTHEADER) >= dwMemLength) return TRUE; pih = (XMINSTRUMENTHEADER *)(lpStream+dwMemPos); if (dwMemPos + bswapLE32(pih->size) > dwMemLength) return TRUE; if ((Headers[iIns] = new INSTRUMENTHEADER) == NULL) continue; memset(Headers[iIns], 0, sizeof(INSTRUMENTHEADER)); memcpy(Headers[iIns]->name, pih->name, 22); if ((nsamples = pih->samples) > 0) { if (dwMemPos + sizeof(XMSAMPLEHEADER) > dwMemLength) return TRUE; memcpy(&xmsh, lpStream+dwMemPos+sizeof(XMINSTRUMENTHEADER), sizeof(XMSAMPLEHEADER)); xmsh.shsize = bswapLE32(xmsh.shsize); for (int i = 0; i < 24; ++i) { xmsh.venv[i] = bswapLE16(xmsh.venv[i]); xmsh.penv[i] = bswapLE16(xmsh.penv[i]); } xmsh.volfade = bswapLE16(xmsh.volfade); xmsh.res = bswapLE16(xmsh.res); dwMemPos += bswapLE32(pih->size); } else { if (bswapLE32(pih->size)) dwMemPos += bswapLE32(pih->size); else dwMemPos += sizeof(XMINSTRUMENTHEADER); continue; } memset(samplemap, 0, sizeof(samplemap)); if (nsamples > 32) return TRUE; UINT newsamples = m_nSamples; for (UINT nmap=0; nmap= MAX_SAMPLES) { n = m_nSamples; while (n > 0) { if (!Ins[n].pSample) { for (UINT xmapchk=0; xmapchk < nmap; xmapchk++) { if (samplemap[xmapchk] == n) goto alreadymapped; } for (UINT clrs=1; clrsKeyboard[ks] == n) pks->Keyboard[ks] = 0; } } break; } alreadymapped: n--; } #ifndef FASTSOUNDLIB // Damn! more than 200 samples: look for duplicates if (!n) { if (!unused_samples) { unused_samples = DetectUnusedSamples(samples_used); if (!unused_samples) unused_samples = 0xFFFF; } if ((unused_samples) && (unused_samples != 0xFFFF)) { for (UINT iext=m_nSamples; iext>=1; iext--) if (!samples_used[iext]) { unused_samples--; samples_used[iext] = TRUE; DestroySample(iext); n = iext; for (UINT mapchk=0; mapchkKeyboard[ks] == n) pks->Keyboard[ks] = 0; } } memset(&Ins[n], 0, sizeof(Ins[0])); break; } } } #endif // FASTSOUNDLIB } if (newsamples < n) newsamples = n; samplemap[nmap] = n; } m_nSamples = newsamples; // Reading Volume Envelope INSTRUMENTHEADER *penv = Headers[iIns]; penv->nMidiProgram = pih->type; penv->nFadeOut = xmsh.volfade; penv->nPan = 128; penv->nPPC = 5*12; if (xmsh.vtype & 1) penv->dwFlags |= ENV_VOLUME; if (xmsh.vtype & 2) penv->dwFlags |= ENV_VOLSUSTAIN; if (xmsh.vtype & 4) penv->dwFlags |= ENV_VOLLOOP; if (xmsh.ptype & 1) penv->dwFlags |= ENV_PANNING; if (xmsh.ptype & 2) penv->dwFlags |= ENV_PANSUSTAIN; if (xmsh.ptype & 4) penv->dwFlags |= ENV_PANLOOP; if (xmsh.vnum > 12) xmsh.vnum = 12; if (xmsh.pnum > 12) xmsh.pnum = 12; penv->nVolEnv = xmsh.vnum; if (!xmsh.vnum) penv->dwFlags &= ~ENV_VOLUME; if (!xmsh.pnum) penv->dwFlags &= ~ENV_PANNING; penv->nPanEnv = xmsh.pnum; penv->nVolSustainBegin = penv->nVolSustainEnd = xmsh.vsustain; if (xmsh.vsustain >= 12) penv->dwFlags &= ~ENV_VOLSUSTAIN; penv->nVolLoopStart = xmsh.vloops; penv->nVolLoopEnd = xmsh.vloope; if (penv->nVolLoopEnd >= 12) penv->nVolLoopEnd = 0; if (penv->nVolLoopStart >= penv->nVolLoopEnd) penv->dwFlags &= ~ENV_VOLLOOP; penv->nPanSustainBegin = penv->nPanSustainEnd = xmsh.psustain; if (xmsh.psustain >= 12) penv->dwFlags &= ~ENV_PANSUSTAIN; penv->nPanLoopStart = xmsh.ploops; penv->nPanLoopEnd = xmsh.ploope; if (penv->nPanLoopEnd >= 12) penv->nPanLoopEnd = 0; if (penv->nPanLoopStart >= penv->nPanLoopEnd) penv->dwFlags &= ~ENV_PANLOOP; penv->nGlobalVol = 64; for (UINT ienv=0; ienv<12; ienv++) { penv->VolPoints[ienv] = (WORD)xmsh.venv[ienv*2]; penv->VolEnv[ienv] = (BYTE)xmsh.venv[ienv*2+1]; penv->PanPoints[ienv] = (WORD)xmsh.penv[ienv*2]; penv->PanEnv[ienv] = (BYTE)xmsh.penv[ienv*2+1]; if (ienv) { if (penv->VolPoints[ienv] < penv->VolPoints[ienv-1]) { penv->VolPoints[ienv] &= 0xFF; penv->VolPoints[ienv] += penv->VolPoints[ienv-1] & 0xFF00; if (penv->VolPoints[ienv] < penv->VolPoints[ienv-1]) penv->VolPoints[ienv] += 0x100; } if (penv->PanPoints[ienv] < penv->PanPoints[ienv-1]) { penv->PanPoints[ienv] &= 0xFF; penv->PanPoints[ienv] += penv->PanPoints[ienv-1] & 0xFF00; if (penv->PanPoints[ienv] < penv->PanPoints[ienv-1]) penv->PanPoints[ienv] += 0x100; } } } for (UINT j=0; j<96; j++) { penv->NoteMap[j+12] = j+1+12; if (xmsh.snum[j] < nsamples) penv->Keyboard[j+12] = samplemap[xmsh.snum[j]]; } // Reading samples for (UINT ins=0; ins dwMemLength) || (dwMemPos + xmsh.shsize > dwMemLength)) return TRUE; memcpy(&xmss, lpStream+dwMemPos, sizeof(xmss)); xmss.samplen = bswapLE32(xmss.samplen); xmss.loopstart = bswapLE32(xmss.loopstart); xmss.looplen = bswapLE32(xmss.looplen); dwMemPos += xmsh.shsize; flags[ins] = (xmss.type & 0x10) ? RS_PCM16D : RS_PCM8D; if (xmss.type & 0x20) flags[ins] = (xmss.type & 0x10) ? RS_STPCM16D : RS_STPCM8D; samplesize[ins] = xmss.samplen; if (!samplemap[ins]) continue; if (xmss.type & 0x10) { xmss.looplen >>= 1; xmss.loopstart >>= 1; xmss.samplen >>= 1; } if (xmss.type & 0x20) { xmss.looplen >>= 1; xmss.loopstart >>= 1; xmss.samplen >>= 1; } if (xmss.samplen > MAX_SAMPLE_LENGTH) xmss.samplen = MAX_SAMPLE_LENGTH; if (xmss.loopstart >= xmss.samplen) xmss.type &= ~3; xmss.looplen += xmss.loopstart; if (xmss.looplen > xmss.samplen) xmss.looplen = xmss.samplen; if (!xmss.looplen) xmss.type &= ~3; UINT imapsmp = samplemap[ins]; memcpy(m_szNames[imapsmp], xmss.name, 22); m_szNames[imapsmp][22] = 0; MODINSTRUMENT *pins = &Ins[imapsmp]; pins->nLength = (xmss.samplen > MAX_SAMPLE_LENGTH) ? MAX_SAMPLE_LENGTH : xmss.samplen; pins->nLoopStart = xmss.loopstart; pins->nLoopEnd = xmss.looplen; if (pins->nLoopEnd > pins->nLength) pins->nLoopEnd = pins->nLength; if (pins->nLoopStart >= pins->nLoopEnd) { pins->nLoopStart = pins->nLoopEnd = 0; } if (xmss.type & 3) pins->uFlags |= CHN_LOOP; if (xmss.type & 2) pins->uFlags |= CHN_PINGPONGLOOP; pins->nVolume = xmss.vol << 2; if (pins->nVolume > 256) pins->nVolume = 256; pins->nGlobalVol = 64; if ((xmss.res == 0xAD) && (!(xmss.type & 0x30))) { flags[ins] = RS_ADPCM4; samplesize[ins] = (samplesize[ins]+1)/2 + 16; } pins->nFineTune = xmss.finetune; pins->RelativeTone = (int)xmss.relnote; pins->nPan = xmss.pan; pins->uFlags |= CHN_PANNING; pins->nVibType = xmsh.vibtype; pins->nVibSweep = xmsh.vibsweep; pins->nVibDepth = xmsh.vibdepth; pins->nVibRate = xmsh.vibrate; memcpy(pins->name, xmss.name, 22); pins->name[21] = 0; } #if 0 if ((xmsh.reserved2 > nsamples) && (xmsh.reserved2 <= 16)) { dwMemPos += (((UINT)xmsh.reserved2) - nsamples) * xmsh.shsize; } #endif for (UINT ismpd=0; ismpd= dwMemLength) break; } } // Read song comments: "TEXT" if ((dwMemPos + 8 < dwMemLength) && (bswapLE32(*((DWORD *)(lpStream+dwMemPos))) == 0x74786574)) { UINT len = *((DWORD *)(lpStream+dwMemPos+4)); dwMemPos += 8; if ((dwMemPos + len <= dwMemLength) && (len < 16384)) { m_lpszSongComments = new char[len+1]; if (m_lpszSongComments) { memcpy(m_lpszSongComments, lpStream+dwMemPos, len); m_lpszSongComments[len] = 0; } dwMemPos += len; } } // Read midi config: "MIDI" if ((dwMemPos + 8 < dwMemLength) && (bswapLE32(*((DWORD *)(lpStream+dwMemPos))) == 0x4944494D)) { UINT len = *((DWORD *)(lpStream+dwMemPos+4)); dwMemPos += 8; if (len == sizeof(MODMIDICFG)) { memcpy(&m_MidiCfg, lpStream+dwMemPos, len); m_dwSongFlags |= SONG_EMBEDMIDICFG; } } // Read pattern names: "PNAM" if ((dwMemPos + 8 < dwMemLength) && (bswapLE32(*((DWORD *)(lpStream+dwMemPos))) == 0x4d414e50)) { UINT len = *((DWORD *)(lpStream+dwMemPos+4)); dwMemPos += 8; if ((dwMemPos + len <= dwMemLength) && (len <= MAX_PATTERNS*MAX_PATTERNNAME) && (len >= MAX_PATTERNNAME)) { m_lpszPatternNames = new char[len]; if (m_lpszPatternNames) { m_nPatternNames = len / MAX_PATTERNNAME; memcpy(m_lpszPatternNames, lpStream+dwMemPos, len); } dwMemPos += len; } } // Read channel names: "CNAM" if ((dwMemPos + 8 < dwMemLength) && (bswapLE32(*((DWORD *)(lpStream+dwMemPos))) == 0x4d414e43)) { UINT len = *((DWORD *)(lpStream+dwMemPos+4)); dwMemPos += 8; if ((dwMemPos + len <= dwMemLength) && (len <= MAX_BASECHANNELS*MAX_CHANNELNAME)) { UINT n = len / MAX_CHANNELNAME; for (UINT i=0; i= header.patterns) && (Order[i] < MAX_PATTERNS)) header.patterns = Order[i]+1; } header.instruments = m_nInstruments; if (!header.instruments) header.instruments = m_nSamples; header.flags = (m_dwSongFlags & SONG_LINEARSLIDES) ? 0x01 : 0x00; if (m_dwSongFlags & SONG_EXFILTERRANGE) header.flags |= 0x1000; header.tempo = m_nDefaultTempo; header.speed = m_nDefaultSpeed; memcpy(header.order, Order, header.norder); fwrite(&header, 1, sizeof(header), f); // Writing patterns for (i=0; i> 8); for (UINT j=m_nChannels*PatternSize[i]; j; j--,p++) { UINT note = p->note; UINT param = ModSaveCommand(p, TRUE); UINT command = param >> 8; param &= 0xFF; if (note >= 0xFE) note = 97; else if ((note <= 12) || (note > 96+12)) note = 0; else note -= 12; UINT vol = 0; if (p->volcmd) { UINT volcmd = p->volcmd; switch(volcmd) { case VOLCMD_VOLUME: vol = 0x10 + p->vol; break; case VOLCMD_VOLSLIDEDOWN: vol = 0x60 + (p->vol & 0x0F); break; case VOLCMD_VOLSLIDEUP: vol = 0x70 + (p->vol & 0x0F); break; case VOLCMD_FINEVOLDOWN: vol = 0x80 + (p->vol & 0x0F); break; case VOLCMD_FINEVOLUP: vol = 0x90 + (p->vol & 0x0F); break; case VOLCMD_VIBRATOSPEED: vol = 0xA0 + (p->vol & 0x0F); break; case VOLCMD_VIBRATO: vol = 0xB0 + (p->vol & 0x0F); break; case VOLCMD_PANNING: vol = 0xC0 + (p->vol >> 2); if (vol > 0xCF) vol = 0xCF; break; case VOLCMD_PANSLIDELEFT: vol = 0xD0 + (p->vol & 0x0F); break; case VOLCMD_PANSLIDERIGHT: vol = 0xE0 + (p->vol & 0x0F); break; case VOLCMD_TONEPORTAMENTO: vol = 0xF0 + (p->vol & 0x0F); break; } } if ((note) && (p->instr) && (vol > 0x0F) && (command) && (param)) { s[len++] = note; s[len++] = p->instr; s[len++] = vol; s[len++] = command; s[len++] = param; } else { BYTE b = 0x80; if (note) b |= 0x01; if (p->instr) b |= 0x02; if (vol >= 0x10) b |= 0x04; if (command) b |= 0x08; if (param) b |= 0x10; s[len++] = b; if (b & 1) s[len++] = note; if (b & 2) s[len++] = p->instr; if (b & 4) s[len++] = vol; if (b & 8) s[len++] = command; if (b & 16) s[len++] = param; } if (len > sizeof(s) - 5) break; } xmph[7] = (BYTE)(len & 0xFF); xmph[8] = (BYTE)(len >> 8); fwrite(xmph, 1, 9, f); fwrite(s, 1, len, f); } else { memset(&xmph, 0, sizeof(xmph)); xmph[0] = 9; xmph[5] = (BYTE)(PatternSize[i] & 0xFF); xmph[6] = (BYTE)(PatternSize[i] >> 8); fwrite(xmph, 1, 9, f); } // Writing instruments for (i=1; i<=header.instruments; i++) { MODINSTRUMENT *pins; BYTE flags[32]; memset(&xmih, 0, sizeof(xmih)); memset(&xmsh, 0, sizeof(xmsh)); xmih.size = sizeof(xmih) + sizeof(xmsh); memcpy(xmih.name, m_szNames[i], 22); xmih.type = 0; xmih.samples = 0; if (m_nInstruments) { INSTRUMENTHEADER *penv = Headers[i]; if (penv) { memcpy(xmih.name, penv->name, 22); xmih.type = penv->nMidiProgram; xmsh.volfade = penv->nFadeOut; xmsh.vnum = (BYTE)penv->nVolEnv; xmsh.pnum = (BYTE)penv->nPanEnv; if (xmsh.vnum > 12) xmsh.vnum = 12; if (xmsh.pnum > 12) xmsh.pnum = 12; for (UINT ienv=0; ienv<12; ienv++) { xmsh.venv[ienv*2] = penv->VolPoints[ienv]; xmsh.venv[ienv*2+1] = penv->VolEnv[ienv]; xmsh.penv[ienv*2] = penv->PanPoints[ienv]; xmsh.penv[ienv*2+1] = penv->PanEnv[ienv]; } if (penv->dwFlags & ENV_VOLUME) xmsh.vtype |= 1; if (penv->dwFlags & ENV_VOLSUSTAIN) xmsh.vtype |= 2; if (penv->dwFlags & ENV_VOLLOOP) xmsh.vtype |= 4; if (penv->dwFlags & ENV_PANNING) xmsh.ptype |= 1; if (penv->dwFlags & ENV_PANSUSTAIN) xmsh.ptype |= 2; if (penv->dwFlags & ENV_PANLOOP) xmsh.ptype |= 4; xmsh.vsustain = (BYTE)penv->nVolSustainBegin; xmsh.vloops = (BYTE)penv->nVolLoopStart; xmsh.vloope = (BYTE)penv->nVolLoopEnd; xmsh.psustain = (BYTE)penv->nPanSustainBegin; xmsh.ploops = (BYTE)penv->nPanLoopStart; xmsh.ploope = (BYTE)penv->nPanLoopEnd; for (UINT j=0; j<96; j++) if (penv->Keyboard[j+12]) { UINT k; for (k=0; kKeyboard[j+12]) break; if (k == xmih.samples) { smptable[xmih.samples++] = penv->Keyboard[j+12]; } if (xmih.samples >= 32) break; xmsh.snum[j] = k; } // xmsh.reserved2 = xmih.samples; } } else { xmih.samples = 1; // xmsh.reserved2 = 1; smptable[0] = i; } xmsh.shsize = (xmih.samples) ? 40 : 0; fwrite(&xmih, 1, sizeof(xmih), f); if (smptable[0]) { MODINSTRUMENT *pvib = &Ins[smptable[0]]; xmsh.vibtype = pvib->nVibType; xmsh.vibsweep = pvib->nVibSweep; xmsh.vibdepth = pvib->nVibDepth; xmsh.vibrate = pvib->nVibRate; } fwrite(&xmsh, 1, xmih.size - sizeof(xmih), f); if (!xmih.samples) continue; for (UINT ins=0; insnLength; xmss.loopstart = pins->nLoopStart; xmss.looplen = pins->nLoopEnd - pins->nLoopStart; xmss.vol = pins->nVolume / 4; xmss.finetune = (char)pins->nFineTune; xmss.type = 0; if (pins->uFlags & CHN_LOOP) xmss.type = (pins->uFlags & CHN_PINGPONGLOOP) ? 2 : 1; flags[ins] = RS_PCM8D; #ifndef NO_PACKING if (nPacking) { if ((!(pins->uFlags & (CHN_16BIT|CHN_STEREO))) && (CanPackSample(pins->pSample, pins->nLength, nPacking))) { flags[ins] = RS_ADPCM4; xmss.res = 0xAD; } } else #endif { if (pins->uFlags & CHN_16BIT) { flags[ins] = RS_PCM16D; xmss.type |= 0x10; xmss.looplen *= 2; xmss.loopstart *= 2; xmss.samplen *= 2; } if (pins->uFlags & CHN_STEREO) { flags[ins] = (pins->uFlags & CHN_16BIT) ? RS_STPCM16D : RS_STPCM8D; xmss.type |= 0x20; xmss.looplen *= 2; xmss.loopstart *= 2; xmss.samplen *= 2; } } xmss.pan = 255; if (pins->nPan < 256) xmss.pan = (BYTE)pins->nPan; xmss.relnote = (signed char)pins->RelativeTone; fwrite(&xmss, 1, xmsh.shsize, f); } for (UINT ismpd=0; ismpdpSample) { #ifndef NO_PACKING if ((flags[ismpd] == RS_ADPCM4) && (xmih.samples>1)) CanPackSample(pins->pSample, pins->nLength, nPacking); #endif // NO_PACKING WriteSample(f, pins, flags[ismpd]); } } } // Writing song comments if ((m_lpszSongComments) && (m_lpszSongComments[0])) { DWORD d = 0x74786574; fwrite(&d, 1, 4, f); d = strlen(m_lpszSongComments); fwrite(&d, 1, 4, f); fwrite(m_lpszSongComments, 1, d, f); } // Writing midi cfg if (m_dwSongFlags & SONG_EMBEDMIDICFG) { DWORD d = 0x4944494D; fwrite(&d, 1, 4, f); d = sizeof(MODMIDICFG); fwrite(&d, 1, 4, f); fwrite(&m_MidiCfg, 1, sizeof(MODMIDICFG), f); } // Writing Pattern Names if ((m_nPatternNames) && (m_lpszPatternNames)) { DWORD dwLen = m_nPatternNames * MAX_PATTERNNAME; while ((dwLen >= MAX_PATTERNNAME) && (!m_lpszPatternNames[dwLen-MAX_PATTERNNAME])) dwLen -= MAX_PATTERNNAME; if (dwLen >= MAX_PATTERNNAME) { DWORD d = 0x4d414e50; fwrite(&d, 1, 4, f); fwrite(&dwLen, 1, 4, f); fwrite(m_lpszPatternNames, 1, dwLen, f); } } // Writing Channel Names { UINT nChnNames = 0; for (UINT inam=0; inam