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view playercode/load_s3m.c @ 4:5d614bcc4287
Initial entry of mikmod into the CVS tree.
| author | darius |
|---|---|
| date | Fri, 23 Jan 1998 16:05:08 +0000 |
| parents | |
| children |
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/* Name: LOAD_S3M.C Description: Screamtracker (S3M) module loader Portability: All systems - all compilers (hopefully) If this module is found to not be portable to any particular platform, please contact Jake Stine at dracoirs@epix.net (see MIKMOD.TXT for more information on contacting the author). */ #include <string.h> #include "mikmod.h" /************************************************************************** **************************************************************************/ typedef struct S3MNOTE { UBYTE note,ins,vol,cmd,inf; } S3MNOTE; typedef S3MNOTE S3MTRACK[64]; // Raw S3M header struct: typedef struct S3MHEADER { CHAR songname[28]; UBYTE t1a; UBYTE type; UBYTE unused1[2]; UWORD ordnum; UWORD insnum; UWORD patnum; UWORD flags; UWORD tracker; UWORD fileformat; CHAR scrm[4]; UBYTE mastervol; UBYTE initspeed; UBYTE inittempo; UBYTE mastermult; UBYTE ultraclick; UBYTE pantable; UBYTE unused2[8]; UWORD special; UBYTE channels[32]; } S3MHEADER; // Raw S3M sampleinfo struct: typedef struct S3MSAMPLE { UBYTE type; CHAR filename[12]; UBYTE memsegh; UWORD memsegl; ULONG length; ULONG loopbeg; ULONG loopend; UBYTE volume; UBYTE dsk; UBYTE pack; UBYTE flags; ULONG c2spd; UBYTE unused[12]; CHAR sampname[28]; CHAR scrs[4]; } S3MSAMPLE; /************************************************************************** **************************************************************************/ extern UBYTE *poslookup; // S3M/IT fix - removing blank patterns needs a // lookup table to fix position-jump commands extern SBYTE remap[64]; // for removing empty channels static S3MNOTE *s3mbuf = NULL; // pointer to a complete S3M pattern static S3MHEADER *mh = NULL; static UWORD *paraptr = NULL; // parapointer array (see S3M docs) CHAR S3M_Version[] = "Screamtracker 3.xx"; BOOL S3M_Test(void) { UBYTE id[4]; _mm_fseek(modfp,0x2c,SEEK_SET); if(!_mm_read_UBYTES(id,4,modfp)) return 0; if(!memcmp(id,"SCRM",4)) return 1; return 0; } BOOL S3M_Init(void) { if(!(s3mbuf = (S3MNOTE *)_mm_malloc(16*64*sizeof(S3MNOTE)))) return 0; if(!(mh = (S3MHEADER *)_mm_calloc(1,sizeof(S3MHEADER)))) return 0; if(!(poslookup = (UBYTE *)_mm_malloc(sizeof(UBYTE)*128))) return 0; return 1; } void S3M_Cleanup(void) { if(s3mbuf!=NULL) free(s3mbuf); if(paraptr!=NULL) free(paraptr); if(poslookup!=NULL) free(poslookup); if(mh!=NULL) free(mh); paraptr = NULL; s3mbuf = NULL; poslookup = NULL; mh = NULL; } BOOL S3M_GetNumChannels(void) // Because so many s3m files have 16 channels as the set number used, but really // only use far less (usually 8 to 12 still), I had to make this function, // which determines the number of channels that are actually USED by a pattern. // // For every channel that's used, it sets the appropriate array entry of the // global varialbe 'isused' // // NOTE: You must first seek to the file location of the pattern before calling // this procedure. // Returns 1 on fail. { int row=0,flag,ch; while(row<64) { flag = _mm_read_UBYTE(modfp); if(feof(modfp)) { _mm_errno = MMERR_LOADING_PATTERN; return 1; } if(flag) { ch = flag&31; if(mh->channels[ch] < 16) remap[ch] = 0; if(flag&32) { _mm_read_UBYTE(modfp); _mm_read_UBYTE(modfp); } if(flag&64) _mm_read_UBYTE(modfp); if(flag&128) { _mm_read_UBYTE(modfp); _mm_read_UBYTE(modfp); } } else row++; } return 0; } BOOL S3M_ReadPattern(void) { int row=0,flag,ch; S3MNOTE *n; S3MNOTE dummy; // clear pattern data memset(s3mbuf,255,16*64*sizeof(S3MNOTE)); while(row<64) { flag = _mm_read_UBYTE(modfp); if(flag==EOF) { _mm_errno = MMERR_LOADING_PATTERN; return 0; } if(flag) { ch = remap[flag&31]; if(ch != -1) n = &s3mbuf[(64U*ch)+row]; else n = &dummy; if(flag&32) { n->note = _mm_read_UBYTE(modfp); n->ins = _mm_read_UBYTE(modfp); } if(flag&64) n->vol = _mm_read_UBYTE(modfp); if(flag&128) { n->cmd = _mm_read_UBYTE(modfp); n->inf = _mm_read_UBYTE(modfp); } } else row++; } return 1; } void S3MIT_ProcessCmd(UBYTE cmd, UBYTE inf, BOOL oldeffect); UBYTE *S3M_ConvertTrack(S3MNOTE *tr) { int t; UBYTE note,ins,vol; UniReset(); for(t=0; t<64; t++) { note = tr[t].note; ins = tr[t].ins; vol = tr[t].vol; if(ins!=0 && ins!=255) UniInstrument(ins-1); if(note!=255) { if(note==254) UniPTEffect(0xc,0); // <- note off command else UniNote(((note>>4)*12)+(note&0xf)); // <- normal note } if(vol<255) UniPTEffect(0xc,vol); S3MIT_ProcessCmd(tr[t].cmd,tr[t].inf,1); UniNewline(); } return UniDup(); } BOOL S3M_Load(void) { int t,u,track = 0; SAMPLE *q; UBYTE pan[32]; // try to read module header _mm_read_string(mh->songname,28,modfp); mh->t1a =_mm_read_UBYTE(modfp); mh->type =_mm_read_UBYTE(modfp); _mm_read_UBYTES(mh->unused1,2,modfp); mh->ordnum =_mm_read_I_UWORD(modfp); mh->insnum =_mm_read_I_UWORD(modfp); mh->patnum =_mm_read_I_UWORD(modfp); mh->flags =_mm_read_I_UWORD(modfp); mh->tracker =_mm_read_I_UWORD(modfp); mh->fileformat =_mm_read_I_UWORD(modfp); _mm_read_string(mh->scrm,4,modfp); mh->mastervol =_mm_read_UBYTE(modfp); mh->initspeed =_mm_read_UBYTE(modfp); mh->inittempo =_mm_read_UBYTE(modfp); mh->mastermult =_mm_read_UBYTE(modfp); mh->ultraclick =_mm_read_UBYTE(modfp); mh->pantable =_mm_read_UBYTE(modfp); _mm_read_UBYTES(mh->unused2,8,modfp); mh->special =_mm_read_I_UWORD(modfp); _mm_read_UBYTES(mh->channels,32,modfp); if(feof(modfp)) { _mm_errno = MMERR_LOADING_HEADER; return 0; } // set module variables of.modtype = strdup(S3M_Version); of.modtype[14] = ((mh->tracker >> 8) &0xf) + 0x30; of.modtype[16] = ((mh->tracker >> 4)&0xf) + 0x30; of.modtype[17] = ((mh->tracker)&0xf) + 0x30; of.songname = DupStr(mh->songname,28); of.numpat = mh->patnum; of.reppos = 0; of.numins = of.numsmp = mh->insnum; of.initspeed = mh->initspeed; of.inittempo = mh->inittempo; of.initvolume = mh->mastervol<<1; // read the order data if(!AllocPositions(mh->ordnum)) return 0; for(t=0; t<mh->ordnum; t++) of.positions[t] = _mm_read_UBYTE(modfp); of.numpos = 0; for(t=0; t<mh->ordnum; t++) { of.positions[of.numpos] = of.positions[t]; poslookup[t] = of.numpos; // bug fix for FREAKY S3Ms if(of.positions[t]<254) of.numpos++; } if((paraptr=(UWORD *)_mm_malloc((of.numins+of.numpat)*sizeof(UWORD)))==NULL) return 0; // read the instrument+pattern parapointers _mm_read_I_UWORDS(paraptr,of.numins+of.numpat,modfp); if(mh->pantable==252) { // read the panning table (ST 3.2 addition. See below for further // portions of channel panning [past reampper]). _mm_read_UBYTES(pan,32,modfp); } // now is a good time to check if the header was too short :) if(feof(modfp)) { _mm_errno = MMERR_LOADING_HEADER; return 0; } // ============================================== // Load those darned Samples! (no insts in ST3) if(!AllocSamples()) return 0; q = of.samples; for(t=0; t<of.numins; t++) { S3MSAMPLE s; // seek to instrument position _mm_fseek(modfp,((long)paraptr[t])<<4,SEEK_SET); // and load sample info s.type =_mm_read_UBYTE(modfp); _mm_read_string(s.filename,12,modfp); s.memsegh =_mm_read_UBYTE(modfp); s.memsegl =_mm_read_I_UWORD(modfp); s.length =_mm_read_I_ULONG(modfp); s.loopbeg =_mm_read_I_ULONG(modfp); s.loopend =_mm_read_I_ULONG(modfp); s.volume =_mm_read_UBYTE(modfp); s.dsk =_mm_read_UBYTE(modfp); s.pack =_mm_read_UBYTE(modfp); s.flags =_mm_read_UBYTE(modfp); s.c2spd =_mm_read_I_ULONG(modfp); _mm_read_UBYTES(s.unused,12,modfp); _mm_read_string(s.sampname,28,modfp); _mm_read_string(s.scrs,4,modfp); if(feof(modfp)) { _mm_errno = MMERR_LOADING_SAMPLEINFO; return 0; } q->samplename = DupStr(s.sampname,28); q->speed = s.c2spd; q->length = s.length; q->loopstart = s.loopbeg; q->loopend = s.loopend; q->volume = s.volume; q->seekpos = (((long)s.memsegh)<<16|s.memsegl)<<4; if(s.flags&1) q->flags |= SF_LOOP; if(s.flags&4) q->flags |= SF_16BITS; if(mh->fileformat==1) q->flags |= SF_SIGNED; // DON'T load sample if it doesn't have the SCRS tag if(memcmp(s.scrs,"SCRS",4)!=0) q->length = 0; q++; } // ==================================== // Determine the number of channels actually used. (what ever happened // to the concept of a single "numchn" variable, eh?! of.numchn = 0; memset(remap,-1,32*sizeof(UBYTE)); for(t=0; t<of.numpat; t++) { // seek to pattern position ( + 2 skip pattern length ) _mm_fseek(modfp,(long)((paraptr[of.numins+t])<<4)+2,SEEK_SET); if(S3M_GetNumChannels()) return 0; } // build the remap array for(t=0; t<32; t++) { if(remap[t]==0) { remap[t] = of.numchn; of.numchn++; } } // ============================================================ // set panning positions AFTER building remap chart! for(t=0; t<32; t++) { if((mh->channels[t]<16) && (remap[t]!=-1)) { if(mh->channels[t]<8) of.panning[remap[t]] = 0x20; // 0x30 = std s3m val else of.panning[remap[t]] = 0xd0; // 0xc0 = std s3m val } } if(mh->pantable==252) { // set panning positions according to panning table (new for st3.2) for(t=0; t<32; t++) { if((pan[t]&0x20) && (mh->channels[t]<16) && (remap[t]!=-1)) of.panning[remap[t]] = (pan[t]&0xf)<<4; } } // ============================== // Load the pattern info now! of.numtrk = of.numpat*of.numchn; if(!AllocTracks()) return 0; if(!AllocPatterns()) return 0; for(t=0; t<of.numpat; t++) { // seek to pattern position ( + 2 skip pattern length ) _mm_fseek(modfp,(((long)paraptr[of.numins+t])<<4)+2,SEEK_SET); if(!S3M_ReadPattern()) return 0; for(u=0; u<of.numchn; u++) if(!(of.tracks[track++]=S3M_ConvertTrack(&s3mbuf[u*64]))) return 0; } return 1; } CHAR *S3M_LoadTitle(void) { CHAR s[28]; _mm_fseek(modfp,0,SEEK_SET); if(!fread(s,28,1,modfp)) return NULL; return(DupStr(s,28)); } MLOADER load_s3m = { NULL, "S3M", "S3M loader v0.3", S3M_Init, S3M_Test, S3M_Load, S3M_Cleanup, S3M_LoadTitle };