unit URecord;
interface
uses Classes, Math, SysUtils, {DXSounds, Wave, }UMusic, UIni, BASS;
type
TSound = class
BufferNew: TMemoryStream; // buffer for newest sample
BufferArray: array[1..4096] of smallint; // (Signal) newest 4096 samples
BufferLong: array of TMemoryStream; // full buffer
Num: integer;
n: integer; // length of Signal to analyze
// Spectrum: array[1..8192] of single; // sound buffer from above as FFT
// Spektogram: array[0..100] of TSpekt; // FFT(t)
// pitch detection
SzczytJest: boolean; // czy jest szczyt
Szczyt: integer; // pozycja szczytu na osi poziomej
TonDokl: real; // ton aktualnego szczytu
Ton: integer; // ton bez ulamka
TonGamy: integer; // ton w gamie. wartosci: 0-11
Skala: real; // skala FFT
// procedures
procedure ProcessNewBuffer;
procedure AnalizujBufor; // use to analyze sound from buffers to get new pitch
procedure AnalizujByAutocorrelation; // we call it to analyze sound by checking Autocorrelation
function AnalyzeAutocorrelationFreq(Freq: real): real; // use this to check one frequency by Autocorrelation
end;
TSoundCardInput = record
Name: string;
end;
TSoundCard = record
// here can be the soundcard information - whole database from which user will select recording source
Description: string;
Input: array of TSoundCardInput;
InputSeleceted: integer;
// bass record
BassRecordStream: hStream;
end;
TRecord = class
SoundCard: array of TSoundCard;
constructor Create;
end;
smallintarray = array [0..maxInt shr 1-1] of smallInt;
psmallintarray = ^smallintarray;
// procedures - bass record
function GetMicrophone(handle: HSTREAM; buffer: Pointer; len: DWORD; user: DWORD): boolean; stdcall;
var
Sound: array of TSound;
SoundCard: array of TSoundCard;
Poz: integer;
Recording: TRecord;
implementation
uses UMain, ULog;
procedure TSound.ProcessNewBuffer;
var
S: integer;
L: integer;
A: integer;
begin
// process BufferArray
S := 0;
L := BufferNew.Size div 2;
if L > n then begin
S := L - n;
L := n;
end;
// copy to array
for A := L+1 to n do
BufferArray[A-L] := BufferArray[A];
BufferNew.Seek(2*S, soBeginning);
BufferNew.ReadBuffer(BufferArray[1+n-L], 2*L);
// process BufferLong
if Ini.SavePlayback = 1 then begin
BufferNew.Seek(0, soBeginning);
BufferLong[0].CopyFrom(BufferNew, BufferNew.Size);
end;
end;
procedure TSound.AnalizujBufor;
begin
AnalizujByAutocorrelation;
end;
procedure TSound.AnalizujByAutocorrelation;
var
T: integer; // tone
F: real; // freq
Wages: array[0..35] of real; // wages
MaxT: integer; // max tone
MaxW: real; // max wage
V: real; // volume
MaxV: real; // max volume
S: integer; // Signal
Threshold: real; // threshold
begin
// Log.LogAnalyze('[Analyze by Autocorrelation]');
SzczytJest := false;
// find maximum volume of first 1024 words of signal
MaxV := 0;
for S := 1 to 1024 do begin // 0.5.2: fix. was from 0 to 1023
// Log.LogDebug('1');
// Log.LogDebug(IntTostr(S));
V := Abs(BufferArray[S]) / $10000;
// Log.LogDebug('2');
// Log.LogDebug(IntTostr(S) + ': ' + FloatToStr(V) + ', MaxV='+floattostr(maxv)+', buf='+inttostr(length(BufferArray)));
if V > MaxV then MaxV := V;
// Log.LogDebug('3');
// Log.LogDebug(IntTostr(S) + ': ' + FloatToStr(V) + ', MaxV='+floattostr(maxv)+', buf='+inttostr(length(BufferArray)));
end;
// prepare to analyze
MaxW := 0;
MaxT := 0;
// analyze all 12 halftones
for T := 0 to 35 do begin // to 11, then 23, now 35 (for Whitney and my high voice)
F := 130.81*Power(1.05946309436, T)/2; // let's analyze below 130.81
Wages[T] := AnalyzeAutocorrelationFreq(F);
if Wages[T] > MaxW then begin // this frequency has better wage
MaxW := Wages[T];
MaxT := T;
end;
end; // for T
Threshold := 0.1;
case Ini.Threshold of
0: Threshold := 0.05;
1: Threshold := 0.1;
2: Threshold := 0.15;
3: Threshold := 0.2;
end;
//Log.LogDebug('Sound -> AnalyzeByAutocorrelation: MaxV='+floattostr(maxv)+', Threshold='+floattostr(threshold));
if MaxV >= Threshold then begin // found acceptable volume // 0.1
SzczytJest := true;
TonGamy := MaxT mod 12;
Ton := MaxT mod 12;
end;
// Log.LogAnalyze('--> Weight: ')
// Log.LogAnalyze('--> Selected: ' + BoolToStr(SzczytJest, true) +
// ', TonGamy: ' + IntToStr(Ton) +
// ', MaxV: ' + FloatToStr(MaxV));
// Log.LogAnalyze('');
end;
function TSound.AnalyzeAutocorrelationFreq(Freq: real): real; // result medium difference
var
Count: real;
Src: integer;
Dst: integer;
Move: integer;
Il: integer; // how many counts were done
begin
// we use Signal as source
Count := 0;
Il := 0;
Src := 1;
Move := Round(44100/Freq);
Dst := Src + Move;
// ver 1 - sample 1 and compare n-times
{ while (Src <= Move) do begin // process by moving Src by one
while (Dst < n) do begin // process up to n (4KB) of Signal
Count := Count + Abs(Signal[Src] - Signal[Dst]) / $10000;
Inc(Dst, Move);
Inc(Il);
end;
Inc(Src);
Dst := Src + Move;
end;}
// ver 2 - compare in vertical
while (Dst < n) do begin // process up to n (4KB) of Signal
Count := Count + Abs(BufferArray[Src] - BufferArray[Dst]) / $10000;
Inc(Src);
Inc(Dst);
Inc(Il);
end;
Result := 1 - Count / Il;
end;
function GetMicrophone(handle: HSTREAM; buffer: Pointer; len: DWORD; user: DWORD): boolean; stdcall;
var
L: integer;
S: integer;
PB: pbytearray;
PSI: psmallintarray;
I: integer;
Skip: integer;
P1: integer;
P2: integer;
Boost: byte;
begin
// Log.LogDebug('Record -> GetMicrophone: len='+inttstr(len));
// set boost
case Ini.MicBoost of
0: Boost := 1;
1: Boost := 2;
2: Boost := 4;
3: Boost := 8;
else Boost := 1;
end;
// boost buffer
L := Len div 2; // number of samples
PSI := Buffer;
for S := 0 to L-1 do begin
I := PSI^[S] * Boost;
if I > 32767 then I := 32767; // 0.5.0: limit
if I < -32768 then I := -32768; // 0.5.0: limit
PSI^[S] := I;
end;
// decode user
P1 := (user and 255) - 1;
P2 := (user div 256) - 1;
// Log.LogDebug('Record -> GetMicrophone: P1='+inttostr(p1)+', P2='+inttostr(p2));
// 2 players USB mic, left channel
if P1 >= 0 then begin
L := Len div 4; // number of samples
PB := Buffer;
// Log.LogDebug('Record -> GetMicrophone -> Sound[P1].BufferNew.Clear');
Sound[P1].BufferNew.Clear; // 0.5.2: problem on exiting
for S := 1 to L do begin
Sound[P1].BufferNew.Write(PB[(S-1)*4], 2);
end;
Sound[P1].ProcessNewBuffer;
end;
// 2 players USB mic, right channel
// if Ini.Debug = 0 then Skip := 2
// else Skip := 0;
Skip := 2;
if P2 >= 0 then begin
L := Len div 4; // number of samples
PB := Buffer;
Sound[P2].BufferNew.Clear;
for S := 1 to L do begin
Sound[P2].BufferNew.Write(PB[Skip + (S-1)*4], 2);
end;
Sound[P2].ProcessNewBuffer;
end;
// Log.LogDebug('Record -> GetMicrophone -> Finish');
Result := true;
end;
constructor TRecord.Create;
var
Info: BASS_DEVICEINFO;
SC: integer; // soundcard
SCI: integer; // soundcard input
Descr: string;
InputName: string;
Flags: integer;
No: integer;
Proceed: boolean;
function isDuplicate(Desc: String): Boolean;
var
I: Integer;
begin
Result := False;
//Check for Soundcard with same Description
For I := 0 to SC-1 do
begin
if (SoundCard[I].Description = Desc) then
begin
Result := True;
Break;
end;
end;
end;
// mic: array[0..15] of integer;
begin
// checks for recording devices and puts them into array;
SetLength(SoundCard, 0);
BASS_RecordFree;
SC := 0;
//Descr := BASS_RecordGetDeviceDescription(SC);
Proceed := BASS_RecordGetDeviceInfo(SC, &Info);
Descr := Info.name;
while {(Descr <> '')} Proceed and not (info.flags and BASS_DEVICE_ENABLED=0) do
begin
//If there is another SoundCard with the Same ID, Search an available Name
if (IsDuplicate(Descr)) then
begin
No:= 1; //Count of SoundCards with same Name
Repeat
Inc(No)
Until not IsDuplicate(Descr + ' (' + InttoStr(No) + ')');
//Set Description
Descr := Descr + ' (' + InttoStr(No) + ')';
end;
SetLength(SoundCard, SC+1);
// Log.LogError('Device #' + IntToStr(SC+1) + ': ' + Descr);
SoundCard[SC].Description := Descr;
// check for recording inputs
// mic[device] := -1; // default to no change
SCI := 0;
BASS_RecordInit(SC);
Flags := BASS_RecordGetInput(SCI, PSingle(nil)^);
InputName := BASS_RecordGetInputName(SCI);
// Log.LogError('Input #' + IntToStr(SCI) + ' (' + IntToStr(Flags) + '): ' + InputName);
SetLength(SoundCard[SC].Input, 1);
SoundCard[SC].Input[SCI].Name := InputName;
// process each input
while (Flags <> -1) and (Flags and BASS_INPUT_OFF<>0) do
begin
if SCI >= 1 then
begin
SetLength(SoundCard[SC].Input, SCI+1);
InputName := BASS_RecordGetInputName(SCI);
SoundCard[SC].Input[SCI].Name := InputName;
// Log.LogError('Input #' + IntToStr(SCI) + ' (' + IntToStr(Flags) + '): ' + InputName);
end;
{ if (flags and BASS_INPUT_TYPE_MASK) = BASS_INPUT_TYPE_MIC then begin
mic[device] := input; // auto set microphone
end;}
Inc(SCI);
Flags := BASS_RecordGetInput(SCI, PSingle(nil)^);
end;
{ if mic[device] <> -1 then begin
Log.LogAnalyze('Found the mic at input ' + IntToStr(Mic[device]))
end else begin
Log.LogAnalyze('Mic not found');
mic[device] := 0; // setting to the first one (for kxproject)
end;
SoundCard[SC].InputSeleceted := Mic[Device];}
BASS_RecordFree;
Inc(SC);
//Descr := BASS_RecordGetDeviceDescription(SC);
Proceed := BASS_RecordGetDeviceInfo(SC, &Info);
Descr := Info.name;
end; // while
end;
end.