Syntax C/C++ | #include <VFmath.h>
void VF_divV( fVector Z, fVector X, fVector Y, ui size );
void VFs_divV( fVector Z, fVector X, fVector Y, ui size, float C );
void VFx_divV( fVector Z, fVector X, fVector Y, ui size, float A, float B );
void VCF_divV( cfVector Z, cfVector X, cfVector Y, ui size );
void VCF_divReV( cfVector Z, cfVector X, fVector Y, ui size );
void VCFx_divV( cfVector Z, cfVector X, cfVector Y, ui size, fComplex A, fComplex B );
void VCFx_divReV( cfVector Z, cfVector X, fVector Y, ui size, fComplex A, fComplex B ); |
C++ VecObj | #include <OptiVec.h>
void vector<T>::divV( const vector<T>& X, const vector<T>& Y );
void vector<T>::s_divV( const vector<T>& X, const vector<T>& Y, const T& C );
void vector<T>::x_divV( const vector<T>& X, const vector<T>& Y, const T& A, const T& B );
void vector<complex<T>>::divV( const vector<complex<T>>& X, const vector<complex<T>>& Y );
void vector<complex<T>>::divReV( const vector<complex<T>>& X, const vector<T>& Y );
void vector<complex<T>>::x_divV( const vector<complex<T>>& X, const vector<complex<T>>& Y, complex<T> A, complex<T> B );
void vector<complex<T>>::x_divReV( const vector<complex<T>>& X, const vector<T>& Y, complex<T> A, complex<T> B ); |
Pascal/Delphi | uses VFmath;
procedure VF_divV( Z, X, Y:fVector; size:UIntSize );
procedure VFs_divV( Z, X, Y:fVector; size:UIntSize; C:Single );
procedure VFx_divV( Z, X, Y:fVector; size:UIntSize; A, B:Single );
procedure VCF_divV( Z, X, Y:cfVector; size:UIntSize );
procedure VCF_divReV( Z, X:cfVector; Y:fVector; size:UIntSize );
procedure VCFx_divV( Z, X, Y:cfVector; size:UIntSize; A, B:fComplex );
procedure VCFx_divrReV( Z, X:cfVector; Y:fVector; size:UIntSize; A, B:fComplex ); |
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CUDA-Funktion C/C++ | #include <cudaVFmath.h>
#include <cudaVCFmath.h>
int cudaVF_divV( fVector d_Z, fVector d_X, fVector d_Y,ui size );
int cudaVFs_divV( fVector d_Z, fVector d_X, fVector d_Y, ui size, float C );
int cusdVFs_divV( fVector d_Z, fVector d_X, fVector d_Y, ui size, float *d_C );
int cudaVFx_divV( fVector d_Z, fVector d_X, fVector d_Y, ui size, float A, float B );
int cusdVFx_divV( fVector d_Z, fVector d_X, fVector d_Y, ui size, float *d_A, float *d_B );
int cudaVCF_divReV( cfVector d_Z, cfVector d_X, fVector d_Y, ui size );
int cudaVCFx_divReV( cfVector d_Z, cfVector d_X, fVector d_Y, ui size, fComplex A, fComplex B );
int cusdVCFx_divReV( cfVector d_Z, cfVector d_X, fVector d_Y, ui size, fComplex *d_A, fComplex *d_B );
void VFcu_divV( fVector h_Z, fVector h_X, fVector h_Y,ui size );
void VFscu_divV( fVector h_Z, fVector h_X, fVector h_Y, ui size, float C );
void VFxcu_divV( fVector h_Z, fVector h_X, fVector h_Y, ui size, float A, float B );
void VCFcu_divReV( cfVector h_Z, cfVector h_X, fVector h_Y, ui size );
void VCFxcu_divV( cfVector h_Z, cfVector h_X, cfVector h_Y, ui size, fComplex A, fComplex B );
void VCFxcu_divReV( cfVector h_Z, cfVector h_X, fVector h_Y, ui size, fComplex A, fComplex B );
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CUDA-Funktion Pascal/Delphi | uses VFmath, VCFmath;
function cudaVF_divV( d_Z, d_X, d_Y:fVector; size:UIntSize ): IntBool;
function cudaVFs_divV( d_Z, d_X, d_Y:fVector; size:UIntSize; C:Single ): IntBool;
function cusdVFs_divV( d_Z, d_X, d_Y:fVector; size:UIntSize; d_C:PSingle ): IntBool;
function cudaVFx_divV( d_Z, d_X, d_Y:fVector; size:UIntSize; A, B:Single ): IntBool;
function cusdVFx_divV( d_Z, d_X, d_Y:fVector; size:UIntSize; d_A, d_B:PSingle ): IntBool;
function cudaVCF_divReV( d_Z, d_X:cfVector; d_Y:fVector; size:UIntSize ): IntBool;
function cudaVCFx_divReV( d_Z, d_X:cfVector; d_Y:fVector; size:UIntSize; A, B:fComplex ): IntBool;
function cusdVCFx_divReV( d_Z, d_X:cfVector; d_Y:fVector; size:UIntSize; d_A, d_B:PfComplex ): IntBool;
procedure VFcu_divV( h_Z, h_X, h_Y:fVector; size:UIntSize );
procedure VFscu_divV( h_Z, h_X, h_Y:fVector; size:UIntSize; C:Single );
procedure VFxcu_divV( h_Z, h_X, h_Y:fVector; size:UIntSize; A, B:Single );
procedure VCFcu_divReV( h_Z, h_X:cfVector; h_Y:fVector; size:UIntSize );
procedure VCFxcu_divReV( h_Z, h_X:cfVector; h_Y:fVector; size:UIntSize; A, B:fComplex );
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