GNU Radio 3.6.5 C++ API

volk_32fc_s32fc_multiply_32fc_a.h

Go to the documentation of this file.
00001 #ifndef INCLUDED_volk_32fc_s32fc_multiply_32fc_a_H
00002 #define INCLUDED_volk_32fc_s32fc_multiply_32fc_a_H
00003 
00004 #include <inttypes.h>
00005 #include <stdio.h>
00006 #include <volk/volk_complex.h>
00007 #include <float.h>
00008 
00009 #ifdef LV_HAVE_SSE3
00010 #include <pmmintrin.h>
00011   /*!
00012     \brief Multiplies the two input complex vectors and stores their results in the third vector
00013     \param cVector The vector where the results will be stored
00014     \param aVector One of the vectors to be multiplied
00015     \param bVector One of the vectors to be multiplied
00016     \param num_points The number of complex values in aVector and bVector to be multiplied together and stored into cVector
00017   */
00018 static inline void volk_32fc_s32fc_multiply_32fc_a_sse3(lv_32fc_t* cVector, const lv_32fc_t* aVector, const lv_32fc_t scalar, unsigned int num_points){
00019   unsigned int number = 0;
00020     const unsigned int halfPoints = num_points / 2;
00021 
00022     __m128 x, yl, yh, z, tmp1, tmp2;
00023     lv_32fc_t* c = cVector;
00024     const lv_32fc_t* a = aVector;
00025 
00026     // Set up constant scalar vector
00027     yl = _mm_set_ps1(lv_creal(scalar));
00028     yh = _mm_set_ps1(lv_cimag(scalar));
00029 
00030     for(;number < halfPoints; number++){
00031 
00032       x = _mm_load_ps((float*)a); // Load the ar + ai, br + bi as ar,ai,br,bi
00033 
00034       tmp1 = _mm_mul_ps(x,yl); // tmp1 = ar*cr,ai*cr,br*dr,bi*dr
00035 
00036       x = _mm_shuffle_ps(x,x,0xB1); // Re-arrange x to be ai,ar,bi,br
00037 
00038       tmp2 = _mm_mul_ps(x,yh); // tmp2 = ai*ci,ar*ci,bi*di,br*di
00039 
00040       z = _mm_addsub_ps(tmp1,tmp2); // ar*cr-ai*ci, ai*cr+ar*ci, br*dr-bi*di, bi*dr+br*di
00041 
00042       _mm_store_ps((float*)c,z); // Store the results back into the C container
00043 
00044       a += 2;
00045       c += 2;
00046     }
00047 
00048     if((num_points % 2) != 0) {
00049       *c = (*a) * scalar;
00050     }
00051 }
00052 #endif /* LV_HAVE_SSE */
00053 
00054 
00055 #ifdef LV_HAVE_GENERIC
00056   /*!
00057     \brief Multiplies the two input complex vectors and stores their results in the third vector
00058     \param cVector The vector where the results will be stored
00059     \param aVector One of the vectors to be multiplied
00060     \param bVector One of the vectors to be multiplied
00061     \param num_points The number of complex values in aVector and bVector to be multiplied together and stored into cVector
00062   */
00063 static inline void volk_32fc_s32fc_multiply_32fc_a_generic(lv_32fc_t* cVector, const lv_32fc_t* aVector, const lv_32fc_t scalar, unsigned int num_points){
00064     lv_32fc_t* cPtr = cVector;
00065     const lv_32fc_t* aPtr = aVector;
00066     unsigned int number = num_points;
00067 
00068     // unwrap loop
00069     while (number >= 8){
00070       *cPtr++ = (*aPtr++) * scalar;
00071       *cPtr++ = (*aPtr++) * scalar;
00072       *cPtr++ = (*aPtr++) * scalar;
00073       *cPtr++ = (*aPtr++) * scalar;
00074       *cPtr++ = (*aPtr++) * scalar;
00075       *cPtr++ = (*aPtr++) * scalar;
00076       *cPtr++ = (*aPtr++) * scalar;
00077       *cPtr++ = (*aPtr++) * scalar;
00078       number -= 8;
00079     }
00080 
00081     // clean up any remaining
00082     while (number-- > 0)
00083       *cPtr++ = *aPtr++ * scalar;
00084 }
00085 #endif /* LV_HAVE_GENERIC */
00086 
00087 
00088 
00089 
00090 
00091 #endif /* INCLUDED_volk_32fc_x2_multiply_32fc_a_H */