/* * This source code is public domain. * * Authors: Olivier Lapicque , * Adam Goode (endian and char fixes for PPC) */ ////////////////////////////////////////////// // PTM PolyTracker module loader // ////////////////////////////////////////////// #include "stdafx.h" #include "sndfile.h" //#pragma warning(disable:4244) #pragma pack(1) typedef struct PTMFILEHEADER { CHAR songname[28]; // name of song, asciiz string CHAR eof; // 26 BYTE version_lo; // 03 version of file, currently 0203h BYTE version_hi; // 02 BYTE reserved1; // reserved, set to 0 WORD norders; // number of orders (0..256) WORD nsamples; // number of instruments (1..255) WORD npatterns; // number of patterns (1..128) WORD nchannels; // number of channels (voices) used (1..32) WORD fileflags; // set to 0 WORD reserved2; // reserved, set to 0 DWORD ptmf_id; // song identification, 'PTMF' or 0x464d5450 BYTE reserved3[16]; // reserved, set to 0 BYTE chnpan[32]; // channel panning settings, 0..15, 0 = left, 7 = middle, 15 = right BYTE orders[256]; // order list, valid entries 0..nOrders-1 WORD patseg[128]; // pattern offsets (*16) } PTMFILEHEADER, *LPPTMFILEHEADER; #define SIZEOF_PTMFILEHEADER 608 typedef struct PTMSAMPLE { BYTE sampletype; // sample type (bit array) CHAR filename[12]; // name of external sample file BYTE volume; // default volume WORD nC4Spd; // C4 speed WORD sampleseg; // sample segment (used internally) WORD fileofs[2]; // offset of sample data WORD length[2]; // sample size (in bytes) WORD loopbeg[2]; // start of loop WORD loopend[2]; // end of loop WORD gusdata[8]; char samplename[28]; // name of sample, asciiz // changed from CHAR DWORD ptms_id; // sample identification, 'PTMS' or 0x534d5450 } PTMSAMPLE; #define SIZEOF_PTMSAMPLE 80 #pragma pack() BOOL CSoundFile::ReadPTM(const BYTE *lpStream, DWORD dwMemLength) //--------------------------------------------------------------- { PTMFILEHEADER pfh = *(LPPTMFILEHEADER)lpStream; DWORD dwMemPos; UINT nOrders; pfh.norders = bswapLE16(pfh.norders); pfh.nsamples = bswapLE16(pfh.nsamples); pfh.npatterns = bswapLE16(pfh.npatterns); pfh.nchannels = bswapLE16(pfh.nchannels); pfh.fileflags = bswapLE16(pfh.fileflags); pfh.reserved2 = bswapLE16(pfh.reserved2); pfh.ptmf_id = bswapLE32(pfh.ptmf_id); for (UINT j=0; j<128; j++) { pfh.patseg[j] = bswapLE16(pfh.patseg[j]); } if ((!lpStream) || (dwMemLength < 1024)) return FALSE; if ((pfh.ptmf_id != 0x464d5450) || (!pfh.nchannels) || (pfh.nchannels > 32) || (pfh.norders > 256) || (!pfh.norders) || (!pfh.nsamples) || (pfh.nsamples > 255) || (!pfh.npatterns) || (pfh.npatterns > 128) || (SIZEOF_PTMFILEHEADER+pfh.nsamples*SIZEOF_PTMSAMPLE >= (int)dwMemLength)) return FALSE; memcpy(m_szNames[0], pfh.songname, 28); m_szNames[0][28] = 0; m_nType = MOD_TYPE_PTM; m_nChannels = pfh.nchannels; m_nSamples = (pfh.nsamples < MAX_SAMPLES) ? pfh.nsamples : MAX_SAMPLES-1; dwMemPos = SIZEOF_PTMFILEHEADER; nOrders = (pfh.norders < MAX_ORDERS) ? pfh.norders : MAX_ORDERS-1; memcpy(Order, pfh.orders, nOrders); for (UINT ipan=0; ipansamplename, 28); memcpy(pins->name, psmp->filename, 12); pins->name[12] = 0; pins->nGlobalVol = 64; pins->nPan = 128; pins->nVolume = psmp->volume << 2; pins->nC4Speed = bswapLE16(psmp->nC4Spd) << 1; pins->uFlags = 0; if ((psmp->sampletype & 3) == 1) { UINT smpflg = RS_PCM8D; DWORD samplepos = (psmp->fileofs[1] << 16) + psmp->fileofs[0]; pins->nLength = bswapLE32(*(LPDWORD)(psmp->length)); pins->nLoopStart = bswapLE32(*(LPDWORD)(psmp->loopbeg)); pins->nLoopEnd = bswapLE32(*(LPDWORD)(psmp->loopend)); samplepos = bswapLE32(samplepos); if (psmp->sampletype & 4) pins->uFlags |= CHN_LOOP; if (psmp->sampletype & 8) pins->uFlags |= CHN_PINGPONGLOOP; if (psmp->sampletype & 16) { pins->uFlags |= CHN_16BIT; pins->nLength >>= 1; pins->nLoopStart >>= 1; pins->nLoopEnd >>= 1; smpflg = RS_PTM8DTO16; } if ((pins->nLength) && (samplepos) && (samplepos < dwMemLength)) { ReadSample(pins, smpflg, (LPSTR)(lpStream+samplepos), dwMemLength-samplepos); } } } // Reading Patterns for (UINT ipat=0; ipat= dwMemLength)) continue; PatternSize[ipat] = 64; if ((Patterns[ipat] = AllocatePattern(64, m_nChannels)) == NULL) break; // MODCOMMAND *m = Patterns[ipat]; for (UINT row=0; ((row < 64) && (dwMemPos < dwMemLength)); ) { UINT b = lpStream[dwMemPos++]; if (dwMemPos >= dwMemLength) break; if (b) { UINT nChn = b & 0x1F; if (b & 0x20) { if (dwMemPos + 2 > dwMemLength) break; m[nChn].note = lpStream[dwMemPos++]; m[nChn].instr = lpStream[dwMemPos++]; } if (b & 0x40) { if (dwMemPos + 2 > dwMemLength) break; m[nChn].command = lpStream[dwMemPos++]; m[nChn].param = lpStream[dwMemPos++]; if ((m[nChn].command == 0x0E) && ((m[nChn].param & 0xF0) == 0x80)) { m[nChn].command = CMD_S3MCMDEX; } else if (m[nChn].command < 0x10) { ConvertModCommand(&m[nChn]); } else { switch(m[nChn].command) { case 16: m[nChn].command = CMD_GLOBALVOLUME; break; case 17: m[nChn].command = CMD_RETRIG; break; case 18: m[nChn].command = CMD_FINEVIBRATO; break; default: m[nChn].command = 0; } } } if (b & 0x80) { if (dwMemPos >= dwMemLength) break; m[nChn].volcmd = VOLCMD_VOLUME; m[nChn].vol = lpStream[dwMemPos++]; } } else { row++; m += m_nChannels; } } } return TRUE; }