# Algorithm smbPitchShift (Pascal)

I looked for a long time this algorithm in Pascal and not found, I found it only in C++, it was frustrating. Then I decided to translate the C++ code for Pascal, however there were some problems that I am not able to solve. it appeared an error message "Floating point overflow". I would like help to make this code work!

``````var
WFX: pWaveFormatEx;

{** Algoritmo Pitch Shift **}
gInFIFO, gOutFIFO, gLastPhase, gSumPhase, gOutputAccum: Array Of Extended;
gAnaMagn, gAnaFreq, gSynFreq, gSynMagn, gFFTworksp: Array Of Extended;

Const
MAX_FRAME_LENGTH = 8192;

implementation

{\$R *.dfm}

procedure smbFft(fftBuffer: PExtended; fftFrameSize, sign: Integer);
var
p1, p2, p1r, p1i, p2r, p2i: PExtended;
wr, wi, arg, temp: EXTENDED;
tr, ti, ur, ui: EXTENDED;
i, bitm, j, le, le2, k: Integer;
begin
i:= 2;
WHILE (i < 2*fftFrameSize-2) DO                                                //for (i = 2; i < 2*fftFrameSize-2; i += 2) {
BEGIN
bitm:= 2;
j:= 0;
WHILE (bitm < (2 * fftFrameSize)) DO                                       //for (bitm = 2, j = 0; bitm < 2*fftFrameSize; bitm <<= 1) {
BEGIN
if ((i and bitm) <> 0) then                                            //if (i & bitm) j++;
inc(j);
//
j:= j shl 1;                                                           //j <<= 1;
bitm:= bitm shl 1;                                                     //bitm <<= 1
END;
//
if (i < j) then
begin
p1:= fftBuffer;                                                        //^
Inc(p1, i);                                                            //p1 = fftBuffer+i;
p2:= fftBuffer;                                                        //^
Inc(p2, j);                                                            //p2 = fftBuffer+j;
temp:= p1^;                                                            //temp = *p1;
inc(p1, 1);                                                            //*(p1++)
p1:= p2;                                                               //p1 = *p2;
inc(p2, 1);                                                            //*(p2++)
p2^:= temp;                                                            //p2 = temp;
temp:= p1^;                                                            //temp = *p1;
p1:= p2;                                                               //*p1 = *p2;
p2^:= temp;                                                            //*p2 = temp;
end;
INC(I, 2);
END;
//
le:= 2;
k:= 0;
WHILE (k < (ln(fftFrameSize)/ln(2.0)+0.5)) DO                                  //for (k = 0, le = 2; k < (long)(log(fftFrameSize)/log(2.)+.5); k++) {
BEGIN
le:= le shl 1;                                                             //le <<= 1;
le2:= le shr 1;                                                            //le2 = le>>1;
ur:= 1.0;                                                                  //ur = 1.0;
ui:= 0.0;                                                                  //ui = 0.0;
arg:= PI / (le2 shr 1);                                                    //arg = M_PI / (le2>>1);
wr:= cos(arg);                                                             //wr = cos(arg);
wi:= sign * sin(arg);                                                      //wi = sign*sin(arg);
j:=0;
WHILE (j < le2) DO                                                         //for (j = 0; j < le2; j += 2) {
BEGIN
p1r:= fftBuffer;                                                       //^
INC(p1r, j);                                                           //p1r = fftBuffer+j;
p1i:= p1r;                                                             //^
INC(p1i, 1);                                                           //p1i = p1r+1;
p2r:= p1r;                                                             //^
INC(p2r, le2);                                                         //p2r = p1r+le2;
p2i:= p2r;                                                             //^
INC(p2i, 1);                                                           //p2i = p2r+1;
i:= j;
WHILE (i < 2*fftFrameSize) DO                                          //for (i = j; i < 2*fftFrameSize; i += le) {
BEGIN
tr:= p2r^ * ur - p2i^ * ui;                                        //tr = *p2r * ur - *p2i * ui;
ti:= p2r^ * ui + p2i^ * ur;                                        //ti = *p2r * ui + *p2i * ur;
p2r^:= p1r^ - tr;                                                  //*p2r = *p1r - tr;
p2i^:= p1i^ - ti;                                                  //*p2i = *p1i - ti;
p1r^:= p1r^ + tr;                                                  //*p1r += tr;
p1i^:= p1i^ + ti;                                                  //*p1i += ti;
INC(p1r, le);                                                      //p1r += le;
INC(p1i, le);                                                      //p1i += le;
INC(p2r, le);                                                      //p2r += le;
INC(p2i, le);                                                      //p2i += le;
INC(i, le);
END;
//
tr:= ur * wr - ui * wi;                                                //tr = ur*wr - ui*wi;
ui:= ur * wi + ui * wr;                                                //ui = ur*wi + ui*wr;
ur:= tr;                                                               //ur = tr;
INC(J, 2);
END;
inc(k);
END;
end;

Procedure smbPitchShift(pitchShift: Double; numSampsToProcess, fftFrameSize, osamp, sampleRate: Integer;  indata, outdata: PExtended);

function atan2 (y, x : Extended) : Extended; Assembler;
asm
fld [y]
fld [x]
fpatan
end;
var magn, phase, tmp, window, xreal, imag: Extended;
freqPerBin, expct, CC: Extended;
i, k, qpd, index, inFifoLatency, stepSize, fftFrameSize2: Integer;
gRover: Integer;
TmpData: PExtended;
begin
gRover:= 0;
{* set up some handy variables *}
fftFrameSize2:= Round(fftFrameSize / 2);                                       //fftFrameSize2 = fftFrameSize/2;
stepSize:= Round(fftFrameSize / osamp);                                        //stepSize = fftFrameSize/osamp;
freqPerBin:= sampleRate / fftFrameSize;                                        //freqPerBin = sampleRate/(double)fftFrameSize;
expct:= 2.0 * PI * stepSize / fftFrameSize;                                    //expct = 2.*M_PI*(double)stepSize/(double)fftFrameSize;
inFifoLatency:= fftFrameSize - stepSize;                                       //inFifoLatency = fftFrameSize-stepSize;
if (gRover = 0) then gRover:= inFifoLatency;                                   //if (gRover == false) gRover = inFifoLatency;
//
{* main processing loop *}
for i:=0 to numSampsToProcess-1 do                                             //for (i = 0; i < numSampsToProcess; i++){
begin
{* As long as we have not yet collected enough data just read in *}
TmpData:= indata;                                                          //^
inc(TmpData, i);                                                           // [i]
gInFIFO[gRover]:= TmpData^;                                                //gInFIFO[gRover] = indata[i];
TmpData:= outdata;                                                         //^
inc(TmpData, i);                                                           // [i]
TmpData^:= gOutFIFO[gRover - inFifoLatency];                               //outdata[i] = gOutFIFO[gRover-inFifoLatency];
Inc(gRover);                                                               //gRover++;
{* now we have enough data for processing *}
if (gRover >= fftFrameSize) then                                         //if (gRover >= fftFrameSize) {
begin
gRover:= inFifoLatency;                                              //gRover = inFifoLatency;
{* do windowing and re,im interleave *}
for k:=0 to fftFrameSize-1 do                                        //for (k = 0; k < fftFrameSize;k+
begin
window:= -0.5 * Cos(2.0 * PI * k / fftFrameSize) + 0.5;          //window = -.5*cos(2.*M_PI*(double)k/(double)fftFrameSize)+.5;
gFFTworksp[2 * k]:= gInFIFO[k] * window;                         //gFFTworksp[2*k] = gInFIFO[k] * window;
gFFTworksp[2 * k + 1]:= 0.0;                                     //gFFTworksp[2 * k + 1]:= 0.0F;
end;
{****************** ANALYSIS ********************}
{* do transform *}
SmbFft(Ptr(DWORD(gFFTworksp)), fftFrameSize, -1);                    //smbFft(gFFTworksp, fftFrameSize, -1);
{* this is the analysis step *}
for k:= 0 to fftFrameSize2 do                                        //for (k = 0; k <= fftFrameSize2; k++) {
begin
{* de-interlace FFT buffer *}
xreal:= gFFTworksp[2 * k];                                       //real = gFFTworksp[2*k];
imag:= gFFTworksp[2 * k + 1];                                    //imag = gFFTworksp[2*k+1];
{* compute magnitude and phase *}
magn:= 2.0 * Sqrt(xreal * xreal + imag * imag);                  //magn = 2.*sqrt(real*real + imag*imag);
phase:= Atan2(imag, xreal);                                      //phase = atan2(imag,real);
{* compute phase difference *}
tmp:= phase - gLastPhase[k];                                     //tmp = phase - gLastPhase[k];
gLastPhase[k]:= phase;                                           //gLastPhase[k] = phase;
{* subtract expected phase difference *}
tmp:= tmp - k * expct;                                           //tmp -= (double)k*expct;
{* map delta phase into +/- Pi interval *}
qpd:= Round(tmp / PI);                                           //qpd = tmp/M_PI;
if (qpd >= 0) then
qpd:= qpd + qpd and 1                                          // if (qpd >= 0) qpd += qpd&1;
else
qpd:= qpd - qpd and 1;                                         // else qpd -= qpd&1;
//
tmp:= tmp - (PI * qpd);                                          //tmp -= M_PI*(double)qpd;
{* get deviation from bin frequency from the +/- Pi interval *}
tmp:= osamp * tmp / (2.0 * PI);                                  //tmp = osamp*tmp/(2.*M_PI);
{* compute the k-th partials' true frequency *}
tmp:= k * freqPerBin + tmp * freqPerBin;                         //tmp = (double)k*freqPerBin + tmp*freqPerBin;
{* store magnitude and true frequency in analysis arrays *}
gAnaMagn[k]:= magn;                                              //gAnaMagn[k] = magn;
gAnaFreq[k]:= tmp;                                               //gAnaFreq[k] = tmp;
end;
{****************** PROCESSING ********************}
{* this does the actual pitch shifting *}
for k:=0 to fftFrameSize2 do                                         //for (k = 0; k <= fftFrameSize2; k++) {
begin
index:= Round(k * pitchShift);                                   //index = (long)(k*pitchShift);
if (index <= fftFrameSize2) then                                 //if (index <= fftFrameSize2) {
begin
IF K >= LENGTH(gSynFreq) THEN
SetLength(gSynFreq , LENGTH(gSynFreq)+1);                  //memset(gSynFreq, 0, fftFrameSize*sizeof(float));
IF K >= LENGTH(gSynMagn) THEN
SetLength(gSynMagn , LENGTH(gSynMagn)+1);                  //memset(gSynMagn, 0, fftFrameSize*sizeof(float));
//
gSynMagn[index]:= gSynMagn[index] + gAnaMagn[k];             //gSynMagn[index] += gAnaMagn[k];
gSynFreq[index]:= gAnaFreq[k] * pitchShift;                  //gSynFreq[index] = gAnaFreq[k] * pitchShift;
end;
end;
{****************** SYNTHESIS ********************}
{* this is the synthesis step *}
for k:=0 to fftFrameSize2 do                                         //for (k = 0; k <= fftFrameSize2; k++) {
begin
{* get magnitude and true frequency from synthesis arrays *}
magn:= gSynMagn[k];                                              // magn = gSynMagn[k];
tmp:= gSynFreq[k];                                               //tmp = gSynFreq[k]
{* subtract bin mid frequency *}
tmp:= tmp - (k * freqPerBin);                                    //tmp -= (double)k*freqPerBin;
{* get bin deviation from freq deviation *}
tmp:= tmp / freqPerBin;                                          //tmp /= freqPerBin;
{* take osamp into account *}
tmp:= 2.0 * PI * tmp / osamp;                                    //tmp = 2.*M_PI*tmp/osamp;
tmp:= tmp + (k * expct);                                         //tmp += (double)k*expct;
{* accumulate delta phase to get bin phase *}
gSumPhase[k]:= gSumPhase[k] + tmp;                               //gSumPhase[k] += tmp;
phase:= gSumPhase[k];                                            //phase = gSumPhase[k];
{* get real and imag part and re-interleave *}
gFFTworksp[2 * k]:= (magn * Cos(phase));                         //gFFTworksp[2*k] = magn*cos(phase);
gFFTworksp[2 * k + 1]:= (magn * Sin(phase));                     //gFFTworksp[2*k+1] = magn*sin(phase);
end;
{* zero negative frequencies *}
k:= fftFrameSize + 2;
WHILE (k < 2 * fftFrameSize) DO                                      //for (k = fftFrameSize+2; k < 2*fftFrameSize; k++)
BEGIN
gFFTworksp[k]:= 0.0;                                             //gFFTworksp[k] = 0.0F;
inc(k);
END;
{* do inverse transform *}
SmbFft(Ptr(DWORD(gFFTworksp)), fftFrameSize, 1);                     //smbFft(gFFTworksp, fftFrameSize, 1);
{* do windowing and add to output accumulator *}
for k:=0 to fftFrameSize-1 do                                        // for(k=0; k < fftFrameSize; k++) {
begin
window:= -0.5 * Cos(2.0 * PI * k / fftFrameSize) + 0.5;          //window = -.5*cos(2.*M_PI*(double)k/(double)fftFrameSize)+.5;
gOutputAccum[k]:= gOutputAccum[k] + (2.0 * window * gFFTworksp[2 * k] / (fftFrameSize2 * osamp));
end;                                                               //gOutputAccum[k] += 2.*window*gFFTworksp[2*k]/(fftFrameSize2*osamp);
//
for k:=0 to stepSize-1 do gOutFIFO[k]:= gOutputAccum[k];             //for (k = 0; k < stepSize; k++) gOutFIFO[k] = gOutputAccum[k];
{* shift accumulator *}
//
TmpData:= PTR(DWORD(gOutputAccum));                                  //^
Inc(TmpData, StepSize);                                              //gOutputAccum + stepSize
MoveMemory(TmpData, PTR(DWORD(gOutputAccum)), fftFrameSize * sizeof(Extended));
//memmove(gOutputAccum, gOutputAccum + stepSize, fftFrameSize * sizeof(float));
//
{* move input FIFO *}
for k:=0 to inFifoLatency-1 do                                       //for (k = 0; k < inFifoLatency; k++)
gInFIFO[k]:= gInFIFO[k + stepSize];                                //gInFIFO[k] = gInFIFO[k+stepSize];
end;
end;
end;

procedure TWavAnalize.FormCreate(Sender: TObject);
begin
{** algoritimo pitchshift **}
SetLength(gInFIFO ,MAX_FRAME_LENGTH);
SetLength(gOutFIFO ,MAX_FRAME_LENGTH);
SetLength(gSynFreq ,MAX_FRAME_LENGTH);
SetLength(gSynMagn ,MAX_FRAME_LENGTH);
SetLength(gAnaFreq ,MAX_FRAME_LENGTH);
SetLength(gAnaMagn ,MAX_FRAME_LENGTH);
SetLength(gFFTworksp ,2 * MAX_FRAME_LENGTH);
SetLength(gLastPhase , Round(MAX_FRAME_LENGTH / 2) + 1);
SetLength(gSumPhase , Round(MAX_FRAME_LENGTH / 2) + 1);
SetLength(gOutputAccum , 2 * MAX_FRAME_LENGTH);
{** algoritimo pitchshift **}
end;

procedure TWavAnalize.Button8Click(Sender: TObject);
VAR T: TMEMORYSTREAM;
DSize, DataOffset, i: cARDINAL;
AIN, AOUT: ARRAY OF EXTENDED;
begin
T:= TMEMORYSTREAM.CREATE;
GetStreamWaveAudioInfo(T, WFX, DSize, DataOffset);
T.Position:= DataOffset;
SETLENGTH(AIN, DSIZE);
SETLENGTH(AOUT, DSIZE);
smbPitchShift(0.5, DSize, 2048, 10, WFX.nSamplesPerSec, Ptr(DWORD(AIN)), Ptr(DWORD(AOUT)));
T.Clear;
T.WRITE(AOUT[0], LENGTH(AOUT));
``````
• Welcome to StackOverflow. Please edit your question to format the code correctly. Use the button with the '{}' image on the toolbar or Ctrl+K to format it once it's pasted in. You can preview your post below where it's being entered by just looking at that area of the browser window. I was going to try and fix it for you, but it's too much of a mess (and missing part at the end) for me to do so. If people can't read it, they can't help you. – Ken White Aug 31 '11 at 1:29
• FWIW, in C and C++ on Win32 and Win64, float means Single, not Extended. There is no need to use Extended in the code. – Rudy Velthuis Aug 31 '11 at 2:42
• Why don't you use the SoundTouch DLL as I told you in one of your other questions about pitch shifting? – Rudy Velthuis Aug 31 '11 at 7:12
• please don't use extended, that is for sure a mistake – David Heffernan Aug 31 '11 at 7:15
• translate float to single, double to double. Since you have both codes you can insert diagnostics output to see where they differ. You are clearly very competent, I think you can crack this yourself. – David Heffernan Aug 31 '11 at 7:24

OK, I usually don't do this, but I also have an interest in having a Delphi version of the code, so I translated it. Try my translation and see if that works for you.

FWIW, also take a look at the Dirac3LE library by the same author. That is a much more professional library (PSOLA, not WSOLA), available for Windows, Linux, Mac, iPhone, etc. Just tried the Mac version and it sounds good.

• @Ville: Thanks. It is not my first. <g> – Rudy Velthuis Aug 31 '11 at 18:11
• FWIW, does anyone know a code site where such code can be posted permanently? I made the .pas file downloadable from my website, but it should not stay there. – Rudy Velthuis Aug 31 '11 at 22:36
• OK, I found pastebin.com and edited the URL to point there now. – Rudy Velthuis Aug 31 '11 at 22:52

Note the HINTS that Delphi generates when compiling the code.

For instance I get: "[DCC Hint] Unit1.pas(65): H2077 Value assigned to 'p1' never used" on this line:

``````p1:= p2;                                                               //*p1 = *p2;
``````

Because it should really be:

``````p1^ := p2^;
``````

Also if you add this line at the top of your unit:

``````{\$POINTERMATH ON}
``````

you can do C-style pointer arithmetic so you don't have to use the TmpData workaround. So this:

``````TmpData:= indata;
inc(TmpData, i);
gInFIFO[gRover]:= TmpData^;
``````

Can be simplified into this:

``````gInFIFO[gRover]:= InData[i];
``````