/*************************************************************************** xa.c - description ------------------- begin : Wed May 15 2002 copyright : (C) 2002 by Pete Bernert email : BlackDove@addcom.de ***************************************************************************/ /*************************************************************************** * * * This program is free software; you can redistribute it and/or 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. See also the license.txt file for * * additional informations. * * * ***************************************************************************/ //*************************************************************************// // History of changes: // // 2003/02/18 - kode54 // - added gaussian interpolation // // 2002/05/15 - Pete // - generic cleanup for the Peops release // //*************************************************************************// #include "stdafx.h" #define _IN_XA // will be included from spu.c #ifdef _IN_SPU //////////////////////////////////////////////////////////////////////// // XA GLOBALS //////////////////////////////////////////////////////////////////////// xa_decode_t * xapGlobal=0; unsigned long * XAFeed = NULL; unsigned long * XAPlay = NULL; unsigned long * XAStart = NULL; unsigned long * XAEnd = NULL; unsigned long XARepeat = 0; unsigned long XALastVal = 0; int iLeftXAVol = 32767; int iRightXAVol = 32767; static int gauss_ptr = 0; static int gauss_window[8] = {0, 0, 0, 0, 0, 0, 0, 0}; #define gvall0 gauss_window[gauss_ptr] #define gvall(x) gauss_window[(gauss_ptr+x)&3] #define gvalr0 gauss_window[4+gauss_ptr] #define gvalr(x) gauss_window[4+((gauss_ptr+x)&3)] //////////////////////////////////////////////////////////////////////// // MIX XA //////////////////////////////////////////////////////////////////////// INLINE void MixXA(void) { int ns; for(ns=0;ns>16)&0xffff)) * iRightXAVol)/32767; } if(XAPlay==XAFeed && XARepeat) { XARepeat--; for(;ns>16)&0xffff)) * iRightXAVol)/32767; } } } //////////////////////////////////////////////////////////////////////// // FEED XA //////////////////////////////////////////////////////////////////////// INLINE void FeedXA(xa_decode_t *xap) { int sinc,spos,i,iSize,iPlace,vl,vr; if(!bSPUIsOpen) return; xapGlobal = xap; // store info for save states XARepeat = 100; // set up repeat iSize=((44100*xap->nsamples)/xap->freq); // get size if(!iSize) return; // none? bye if(XAFeed=10) { if(!dwFPS) dwFPS=1; dw1=1000000/dwFPS; if(dw1>=(dwL1-100) && dw1<=(dwL1+100)) dw1=dwL1; else dwL1=dw1; dw2=(xap->freq*100/xap->nsamples); if((!dw1)||((dw2+100)>=dw1)) iLastSize=0; else { iLastSize=iSize*dw2/dw1; if(iLastSize>iPlace) iLastSize=iPlace; iSize=iLastSize; } iFPSCnt=0;dwFPS=0; } else { if(iLastSize) iSize=iLastSize; } } //----------------------------------------------------// spos=0x10000L; sinc = (xap->nsamples << 16) / iSize; // calc freq by num / size if(xap->stereo) { unsigned long * pS=(unsigned long *)xap->pcm; unsigned long l=0; if(iXAPitch) { long l1,l2;short s; for(i=0;i=0x10000L) { l = *pS++; gauss_window[gauss_ptr] = (short)LOWORD(l); gauss_window[4+gauss_ptr] = (short)HIWORD(l); gauss_ptr = (gauss_ptr+1) & 3; spos -= 0x10000L; } vl = (spos >> 6) & ~3; vr=(gauss[vl]*gvall0)&~2047; vr+=(gauss[vl+1]*gvall(1))&~2047; vr+=(gauss[vl+2]*gvall(2))&~2047; vr+=(gauss[vl+3]*gvall(3))&~2047; l= (vr >> 11) & 0xffff; vr=(gauss[vl]*gvalr0)&~2047; vr+=(gauss[vl+1]*gvalr(1))&~2047; vr+=(gauss[vl+2]*gvalr(2))&~2047; vr+=(gauss[vl+3]*gvalr(3))&~2047; l |= vr << 5; } else { while(spos>=0x10000L) { l = *pS++; spos -= 0x10000L; } } s=(short)LOWORD(l); l1=s; l1=(l1*iPlace)/iSize; if(l1<-32767) l1=-32767; if(l1> 32767) l1=32767; s=(short)HIWORD(l); l2=s; l2=(l2*iPlace)/iSize; if(l2<-32767) l2=-32767; if(l2> 32767) l2=32767; l=(l1&0xffff)|(l2<<16); *XAFeed++=l; if(XAFeed==XAEnd) XAFeed=XAStart; if(XAFeed==XAPlay) { if(XAPlay!=XAStart) XAFeed=XAPlay-1; break; } spos += sinc; } } else { for(i=0;i=0x10000L) { l = *pS++; gauss_window[gauss_ptr] = (short)LOWORD(l); gauss_window[4+gauss_ptr] = (short)HIWORD(l); gauss_ptr = (gauss_ptr+1) & 3; spos -= 0x10000L; } vl = (spos >> 6) & ~3; vr=(gauss[vl]*gvall0)&~2047; vr+=(gauss[vl+1]*gvall(1))&~2047; vr+=(gauss[vl+2]*gvall(2))&~2047; vr+=(gauss[vl+3]*gvall(3))&~2047; l= (vr >> 11) & 0xffff; vr=(gauss[vl]*gvalr0)&~2047; vr+=(gauss[vl+1]*gvalr(1))&~2047; vr+=(gauss[vl+2]*gvalr(2))&~2047; vr+=(gauss[vl+3]*gvalr(3))&~2047; l |= vr << 5; } else { while(spos>=0x10000L) { l = *pS++; spos -= 0x10000L; } } *XAFeed++=l; if(XAFeed==XAEnd) XAFeed=XAStart; if(XAFeed==XAPlay) { if(XAPlay!=XAStart) XAFeed=XAPlay-1; break; } spos += sinc; } } } else { unsigned short * pS=(unsigned short *)xap->pcm; unsigned long l;short s=0; if(iXAPitch) { long l1; for(i=0;i=0x10000L) { gauss_window[gauss_ptr] = (short)*pS++; gauss_ptr = (gauss_ptr+1) & 3; spos -= 0x10000L; } vl = (spos >> 6) & ~3; vr=(gauss[vl]*gvall0)&~2047; vr+=(gauss[vl+1]*gvall(1))&~2047; vr+=(gauss[vl+2]*gvall(2))&~2047; vr+=(gauss[vl+3]*gvall(3))&~2047; l1=s= vr >> 11; l1 &= 0xffff; } else { while(spos>=0x10000L) { s = *pS++; spos -= 0x10000L; } l1=s; } l1=(l1*iPlace)/iSize; if(l1<-32767) l1=-32767; if(l1> 32767) l1=32767; l=(l1&0xffff)|(l1<<16); *XAFeed++=l; if(XAFeed==XAEnd) XAFeed=XAStart; if(XAFeed==XAPlay) { if(XAPlay!=XAStart) XAFeed=XAPlay-1; break; } spos += sinc; } } else { for(i=0;i=0x10000L) { gauss_window[gauss_ptr] = (short)*pS++; gauss_ptr = (gauss_ptr+1) & 3; spos -= 0x10000L; } vl = (spos >> 6) & ~3; vr=(gauss[vl]*gvall0)&~2047; vr+=(gauss[vl+1]*gvall(1))&~2047; vr+=(gauss[vl+2]*gvall(2))&~2047; vr+=(gauss[vl+3]*gvall(3))&~2047; l=s= vr >> 11; l &= 0xffff; } else { while(spos>=0x10000L) { s = *pS++; spos -= 0x10000L; } l=s; } *XAFeed++=(l|(l<<16)); if(XAFeed==XAEnd) XAFeed=XAStart; if(XAFeed==XAPlay) { if(XAPlay!=XAStart) XAFeed=XAPlay-1; break; } spos += sinc; } } } } #endif