Révision 300 ETSN/MyDFT_7.py

MyDFT_7.py (revision 300)
11 11 
    Y=np.zeros(size).astype(np.float32)
12 12 
    for i in range(size):
13 13 
        for j in range(size):
14 
            X[i]=X[i]+x[j]*cos(2.*pi*i*j/size)-y[j]*sin(2.*pi*i*j/size)
15 
            Y[i]=Y[i]+x[j]*sin(2.*pi*i*j/size)+y[j]*cos(2.*pi*i*j/size)
14 
            X[i]=X[i]+x[j]*cos(2.*pi*i*j/size)+y[j]*sin(2.*pi*i*j/size)
15 
            Y[i]=Y[i]-x[j]*sin(2.*pi*i*j/size)+y[j]*cos(2.*pi*i*j/size)
16 16 
    return(X,Y)
17 17 

  		





  18
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# Numpy Discrete Fourier Transform


  		





  ......




  22
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    Y=np.zeros(size).astype(np.float32)


  		





  23
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    nj=np.multiply(2.0*np.pi/size,np.arange(size)).astype(np.float32)


  		





  24
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    for i in range(size):


  		





  25
  
  
    
        X[i]=np.sum(np.subtract(np.multiply(np.cos(i*nj),x),np.multiply(np.sin(i*nj),y)))


  		





  26
  
  
    
        Y[i]=np.sum(np.add(np.multiply(np.sin(i*nj),x),np.multiply(np.cos(i*nj),y)))


  		





  
  25
  
    
        X[i]=np.sum(np.add(np.multiply(np.cos(i*nj),x),np.multiply(np.sin(i*nj),y)))


  		





  
  26
  
    
        Y[i]=np.sum(np.subtract(np.multiply(np.cos(i*nj),y),np.multiply(np.sin(i*nj),x)))


  		





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    return(X,Y)


  		





  28
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# Numba Discrete Fourier Transform


  		





  ......




  35
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    Y=np.zeros(size).astype(np.float32)


  		





  36
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    nj=np.multiply(2.0*np.pi/size,np.arange(size)).astype(np.float32)


  		





  37
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    for i in numba.prange(size):


  		





  38
  
  
    
        X[i]=np.sum(np.subtract(np.multiply(np.cos(i*nj),x),np.multiply(np.sin(i*nj),y)))


  		





  39
  
  
    
        Y[i]=np.sum(np.add(np.multiply(np.sin(i*nj),x),np.multiply(np.cos(i*nj),y)))


  		





  
  38
  
    
        X[i]=np.sum(np.add(np.multiply(np.cos(i*nj),x),np.multiply(np.sin(i*nj),y)))


  		





  
  39
  
    
        Y[i]=np.sum(np.subtract(np.multiply(np.cos(i*nj),y),np.multiply(np.sin(i*nj),x)))


  		





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    return(X,Y)


  		





  41
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# OpenCL complete operation


  		





  ......




  85
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  float A=0.,B=0.;


  		





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  for (uint i=0; i<size;i++) 


  		





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  {


  		





  88
  
  
    
     A+=a_g[i]*cos(2.*PI*(float)(gid*i)/(float)size)-b_g[i]*sin(2.*PI*(float)(gid*i)/(float)size);


  		





  89
  
  
    
     B+=a_g[i]*sin(2.*PI*(float)(gid*i)/(float)size)+b_g[i]*cos(2.*PI*(float)(gid*i)/(float)size);


  		





  
  88
  
    
     A+=a_g[i]*cos(2.*PI*(float)(gid*i)/(float)size)+b_g[i]*sin(2.*PI*(float)(gid*i)/(float)size);


  		





  
  89
  
    
     B+=-a_g[i]*sin(2.*PI*(float)(gid*i)/(float)size)+b_g[i]*cos(2.*PI*(float)(gid*i)/(float)size);


  		





  90
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  }


  		





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  A_g[gid]=A;


  		





  92
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  B_g[gid]=B;


  		





  ......




  154
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  float A=0.,B=0.;


  		





  155
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  for (uint i=0; i<size;i++) 


  		





  156
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  {


  		





  157
  
  
    
     A+=a_g[i]*cos(2.*PI*(float)(gid*i)/(float)size)-b_g[i]*sin(2.*PI*(float)(gid*i)/(float)size);


  		





  158
  
  
    
     B+=a_g[i]*sin(2.*PI*(float)(gid*i)/(float)size)+b_g[i]*cos(2.*PI*(float)(gid*i)/(float)size);


  		





  
  157
  
    
     A+=a_g[i]*cos(2.*PI*(float)(gid*i)/(float)size)+b_g[i]*sin(2.*PI*(float)(gid*i)/(float)size);


  		





  
  158
  
    
     B+=-a_g[i]*sin(2.*PI*(float)(gid*i)/(float)size)+b_g[i]*cos(2.*PI*(float)(gid*i)/(float)size);


  		





  159
  159
  
    
  }


  		





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  A_g[gid]=A;


  		





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  B_g[gid]=B;


  		












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