Merge branch 'next' of git+ssh://github.com/gnss-sdr/gnss-sdr into next

# Please enter a commit message to explain why this merge is necessary, # especially if it merges an updated upstream into a topic branch. # # Lines starting with '#' will be ignored, and an empty message aborts # the commit.
2024-12-14 20:20:35 +00:00 · 2016-01-28 18:10:21 +01:00 · 2016-01-28 18:10:21 +01:00 · 2014149e17
commit 2014149e17
parent b270d1ca61 d2898c40ce
3 changed files with 273 additions and 23 deletions
--- a/src/algorithms/libs/volk_gnsssdr_module/volk_gnsssdr/README.md
+++ b/src/algorithms/libs/volk_gnsssdr_module/volk_gnsssdr/README.md
@ -14,6 +14,12 @@ This library is automatically built and installed along with GNSS-SDR if it is n
 However, you can install and use VOLK_GNSSSDR kernels as you use VOLK's, independently from GNSS-SDR.
 First, make sure that the required dependencies are installed in you machine:
 ~~~~~~ 
 $ sudo apt-get install git subversion cmake python-cheetah libboost-dev libbbost-filesystem
 ~~~~~~ 
 In order to build and install the library, go to the base folder of the source code and do:
 ~~~~~~ 
--- a/src/algorithms/libs/volk_gnsssdr_module/volk_gnsssdr/kernels/volk_gnsssdr/volk_gnsssdr_16ic_rotatorpuppet_16ic.h
+++ b/src/algorithms/libs/volk_gnsssdr_module/volk_gnsssdr/kernels/volk_gnsssdr/volk_gnsssdr_16ic_rotatorpuppet_16ic.h
@ -4,26 +4,70 @@
 #include <volk_gnsssdr/volk_gnsssdr_complex.h>
 #include "volk_gnsssdr/volk_gnsssdr_16ic_s32fc_x2_rotator_16ic.h"
 #include <math.h>
 #ifdef LV_HAVE_GENERIC
 static inline void volk_gnsssdr_16ic_rotatorpuppet_16ic_generic(lv_16sc_t* outVector, const lv_16sc_t* inVector, unsigned int num_points)
 {
-    lv_32fc_t phase[1] = {lv_cmake(.3, 0.95393)};
+	// phases must be normalized. Phase rotator expects a complex exponential input!
-    const lv_32fc_t phase_inc = lv_cmake(.1, 0.01);
+	float rem_carrier_phase_in_rad=0.345;
-    volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_generic(outVector, inVector, phase_inc, phase, num_points);
+	float phase_step_rad = 0.123;
    lv_32fc_t phase[1];
    phase[0]=lv_cmake(cos(rem_carrier_phase_in_rad), -sin(rem_carrier_phase_in_rad));
    lv_32fc_t phase_inc[1];
    phase_inc[0]=lv_cmake(cos(phase_step_rad), -sin(phase_step_rad));
    volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_generic(outVector, inVector, phase_inc[0], phase, num_points);
 }
 #endif /* LV_HAVE_GENERIC */
 #ifdef LV_HAVE_SSE2
 static inline void volk_gnsssdr_16ic_rotatorpuppet_16ic_a_sse2(lv_16sc_t* outVector, const lv_16sc_t* inVector, unsigned int num_points)
 {
 	// phases must be normalized. Phase rotator expects a complex exponential input!
 	float rem_carrier_phase_in_rad=0.345;
 	float phase_step_rad = 0.123;
    lv_32fc_t phase[1];
    phase[0]=lv_cmake(cos(rem_carrier_phase_in_rad), -sin(rem_carrier_phase_in_rad));
    lv_32fc_t phase_inc[1];
    phase_inc[0]=lv_cmake(cos(phase_step_rad), -sin(phase_step_rad));
    volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_a_sse2(outVector, inVector, phase_inc[0], phase, num_points);
 }
 #endif /* LV_HAVE_SSE2 */
 #ifdef LV_HAVE_SSE2
 static inline void volk_gnsssdr_16ic_rotatorpuppet_16ic_u_sse2(lv_16sc_t* outVector, const lv_16sc_t* inVector, unsigned int num_points)
 {
 	// phases must be normalized. Phase rotator expects a complex exponential input!
 	float rem_carrier_phase_in_rad=0.345;
 	float phase_step_rad = 0.123;
    lv_32fc_t phase[1];
    phase[0]=lv_cmake(cos(rem_carrier_phase_in_rad), -sin(rem_carrier_phase_in_rad));
    lv_32fc_t phase_inc[1];
    phase_inc[0]=lv_cmake(cos(phase_step_rad), -sin(phase_step_rad));
    volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_u_sse2(outVector, inVector, phase_inc[0], phase, num_points);
 }
 #endif /* LV_HAVE_SSE2 */
 #ifdef LV_HAVE_NEON
 static inline void volk_gnsssdr_16ic_rotatorpuppet_16ic_neon(lv_16sc_t* outVector, const lv_16sc_t* inVector, unsigned int num_points)
 {
-    lv_32fc_t phase[1] = {lv_cmake(.3, 0.95393)};
+	// phases must be normalized. Phase rotator expects a complex exponential input!
-    const lv_32fc_t phase_inc = lv_cmake(.1, 0.01);
+	float rem_carrier_phase_in_rad=0.345;
-    volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_neon(outVector, inVector, phase_inc, phase, num_points);
+	float phase_step_rad = 0.123;
    lv_32fc_t phase[1];
    phase[0]=lv_cmake(cos(rem_carrier_phase_in_rad), -sin(rem_carrier_phase_in_rad));
    lv_32fc_t phase_inc[1];
    phase_inc[0]=lv_cmake(cos(phase_step_rad), -sin(phase_step_rad));
    volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_neon(outVector, inVector, phase_inc[0], phase, num_points);
 }
 #endif /* LV_HAVE_NEON */
--- a/src/algorithms/libs/volk_gnsssdr_module/volk_gnsssdr/kernels/volk_gnsssdr/volk_gnsssdr_16ic_s32fc_x2_rotator_16ic.h
+++ b/src/algorithms/libs/volk_gnsssdr_module/volk_gnsssdr/kernels/volk_gnsssdr/volk_gnsssdr_16ic_s32fc_x2_rotator_16ic.h
@ -38,6 +38,7 @@
 #include <volk_gnsssdr/volk_gnsssdr_complex.h>
 #include <math.h>
 #include <stdio.h>
 #define ROTATOR_RELOAD 512
@ -47,55 +48,254 @@ static inline void volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_generic(lv_16sc_t* ou
 {
    unsigned int i = 0;
    int j = 0;
    lv_16sc_t tmp16;
    lv_32fc_t tmp32;
    for(i = 0; i < (unsigned int)(num_points / ROTATOR_RELOAD); ++i)
        {
            for(j = 0; j < ROTATOR_RELOAD; ++j)
                {
-                    *outVector++ = *inVector++ * (*phase);
+                    tmp16 = *inVector++;
                    tmp32 = lv_cmake((float)lv_creal(tmp16), (float)lv_cimag(tmp16)) * (*phase);
                    *outVector++ = lv_cmake((int16_t)rintf(lv_creal(tmp32)), (int16_t)rintf(lv_cimag(tmp32)));
                    (*phase) *= phase_inc;
                    tmp32=(*phase);
                    //printf("[%i][%i] phase fc: %f,%f  \n",i,j,lv_creal(tmp32),lv_cimag(tmp32));
                }
 #ifdef __cplusplus
            (*phase) /= std::abs((*phase));
 #else
            //(*phase) /= cabsf((*phase));
            (*phase) /= hypotf(lv_creal(*phase), lv_cimag(*phase));
 #endif
        }
    for(i = 0; i < num_points % ROTATOR_RELOAD; ++i)
        {
-            *outVector++ = *inVector++ * (*phase);
+           tmp16 = *inVector++;
           tmp32 = lv_cmake((float)lv_creal(tmp16), (float)lv_cimag(tmp16)) * (*phase);
            *outVector++ = lv_cmake((int16_t)rintf(lv_creal(tmp32)), (int16_t)rintf(lv_cimag(tmp32)));
            (*phase) *= phase_inc;
        }
 }
 #endif /* LV_HAVE_GENERIC */
 #ifdef LV_HAVE_SSE2
 #include <emmintrin.h>
 static inline void volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_a_sse2(lv_16sc_t* outVector, const lv_16sc_t* inVector, const lv_32fc_t phase_inc, lv_32fc_t* phase, unsigned int num_points)
 {
 	   const unsigned int sse_iters = num_points / 4;
 	    __m128i a,b,c, c_sr, mask_imag, mask_real, real, imag, imag1,imag2, b_sl, a_sl, result;
 	    mask_imag = _mm_set_epi8(255, 255, 0, 0, 255, 255, 0, 0, 255, 255, 0, 0, 255, 255, 0, 0);
 	    mask_real = _mm_set_epi8(0, 0, 255, 255, 0, 0, 255, 255, 0, 0, 255, 255, 0, 0, 255, 255);
 	    const lv_16sc_t* _in_a = inVector;
 	    __attribute__((aligned(32))) lv_32fc_t four_phase_rotations_32fc[4];
 	    // debug
 	    //__attribute__((aligned(16))) lv_16sc_t four_phase_rotations_16sc[4];
        // specify how many bits are used in the rotation (2^(N-1)) (it WILL increase the output signal range!)
 	    __attribute__((aligned(32))) float rotator_amplitude_float[4] = { 4.0f, 4.0f, 4.0f, 4.0f };
 	    __m128 _rotator_amplitude_reg = _mm_load_ps(rotator_amplitude_float);
 	    //const lv_16sc_t* _in_b = in_b;
 	    lv_16sc_t* _out = outVector;
 	    __m128 fc_reg1, fc_reg2;
 	    __m128i sc_reg1, sc_reg2; // is __m128i defined in xmmintrin.h?
 	    for(unsigned int number = 0; number < sse_iters; number++)
 	        {
 	            //std::complex<T> memory structure: real part -> reinterpret_cast<cv T*>(a)[2*i]
 	            //imaginery part -> reinterpret_cast<cv T*>(a)[2*i + 1]
 	            // a[127:0]=[a3.i,a3.r,a2.i,a2.r,a1.i,a1.r,a0.i,a0.r]
 	            a = _mm_load_si128((__m128i*)_in_a); //load (2 byte imag, 2 byte real) x 4 into 128 bits reg
 	            //b = _mm_loadu_si128((__m128i*)_in_b);
 	            // compute next four 16ic complex exponential values for phase rotation
 	            // compute next four float complex rotations
 	            four_phase_rotations_32fc[0]=*phase;
                (*phase) *= phase_inc;
                four_phase_rotations_32fc[1]=*phase;
                (*phase) *= phase_inc;
                four_phase_rotations_32fc[2]=*phase;
                (*phase) *= phase_inc;
                four_phase_rotations_32fc[3]=*phase;
                (*phase) *= phase_inc;
                //convert the rotations to integers
                fc_reg1 = _mm_load_ps((float*)&four_phase_rotations_32fc[0]);
                // disable next line for 1 bit rotation (equivalent to a square wave NCO)
                fc_reg1 = _mm_mul_ps (fc_reg1, _rotator_amplitude_reg);
                fc_reg2 = _mm_load_ps((float*)&four_phase_rotations_32fc[2]);
                sc_reg1 = _mm_cvtps_epi32(fc_reg1);
                sc_reg2 = _mm_cvtps_epi32(fc_reg2);
                b = _mm_packs_epi32(sc_reg1, sc_reg2);
                // debug
 	            //_mm_store_si128((__m128i*)four_phase_rotations_16sc, b);
                //printf("phase fc: %f,%f phase sc: %i,%i \n",lv_creal(four_phase_rotations_32fc[0]),lv_cimag(four_phase_rotations_32fc[0]),lv_creal(four_phase_rotations_16sc[0]),lv_cimag(four_phase_rotations_16sc[0]));
                // multiply the input vector times the rotations
 	            c = _mm_mullo_epi16 (a, b); // a3.i*b3.i, a3.r*b3.r, ....
 	            c_sr = _mm_srli_si128 (c, 2); // Shift a right by imm8 bytes while shifting in zeros, and store the results in dst.
 	            real = _mm_subs_epi16 (c, c_sr);
 	            real = _mm_and_si128 (real, mask_real); // a3.r*b3.r-a3.i*b3.i , 0,  a3.r*b3.r- a3.i*b3.i
 	            b_sl = _mm_slli_si128(b, 2); // b3.r, b2.i ....
 	            a_sl = _mm_slli_si128(a, 2); // a3.r, a2.i ....
 	            imag1 = _mm_mullo_epi16(a, b_sl); // a3.i*b3.r, ....
 	            imag2 = _mm_mullo_epi16(b, a_sl); // b3.i*a3.r, ....
 	            imag = _mm_adds_epi16(imag1, imag2);
 	            imag = _mm_and_si128 (imag, mask_imag); // a3.i*b3.r+b3.i*a3.r, 0, ...
 	            result = _mm_or_si128 (real, imag);
 	            // normalize the rotations
 	            // TODO
 	            // store results
 	            _mm_store_si128((__m128i*)_out, result);
 	            _in_a += 4;
 	            _out += 4;
 	        }
 	    for (unsigned int i = sse_iters * 4; i < num_points; ++i)
 	        {
 				*_out++ = *_in_a++ * (*phase);
 				(*phase) *= phase_inc;
 	        }
 }
 #endif /* LV_HAVE_SSE2 */
 #ifdef LV_HAVE_SSE2
 #include <emmintrin.h>
 static inline void volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_u_sse2(lv_16sc_t* outVector, const lv_16sc_t* inVector, const lv_32fc_t phase_inc, lv_32fc_t* phase, unsigned int num_points)
 {
 	   const unsigned int sse_iters = num_points / 4;
 	    __m128i a,b,c, c_sr, mask_imag, mask_real, real, imag, imag1,imag2, b_sl, a_sl, result;
 	    mask_imag = _mm_set_epi8(255, 255, 0, 0, 255, 255, 0, 0, 255, 255, 0, 0, 255, 255, 0, 0);
 	    mask_real = _mm_set_epi8(0, 0, 255, 255, 0, 0, 255, 255, 0, 0, 255, 255, 0, 0, 255, 255);
 	    const lv_16sc_t* _in_a = inVector;
 	    __attribute__((aligned(32))) lv_32fc_t four_phase_rotations_32fc[4];
 	    // debug
 	    //__attribute__((aligned(16))) lv_16sc_t four_phase_rotations_16sc[4];
        // specify how many bits are used in the rotation (2^(N-1)) (it WILL increase the output signal range!)
 	    __attribute__((aligned(32))) float rotator_amplitude_float[4] = { 4.0f, 4.0f, 4.0f, 4.0f };
 	    __m128 _rotator_amplitude_reg = _mm_load_ps(rotator_amplitude_float);
 	    //const lv_16sc_t* _in_b = in_b;
 	    lv_16sc_t* _out = outVector;
 	    __m128 fc_reg1, fc_reg2;
 	    __m128i sc_reg1, sc_reg2; // is __m128i defined in xmmintrin.h?
 	    for(unsigned int number = 0; number < sse_iters; number++)
 	        {
 	            //std::complex<T> memory structure: real part -> reinterpret_cast<cv T*>(a)[2*i]
 	            //imaginery part -> reinterpret_cast<cv T*>(a)[2*i + 1]
 	            // a[127:0]=[a3.i,a3.r,a2.i,a2.r,a1.i,a1.r,a0.i,a0.r]
 	            a = _mm_loadu_si128((__m128i*)_in_a); //load (2 byte imag, 2 byte real) x 4 into 128 bits reg
 	            //b = _mm_loadu_si128((__m128i*)_in_b);
 	            // compute next four 16ic complex exponential values for phase rotation
 	            // compute next four float complex rotations
 	            four_phase_rotations_32fc[0]=*phase;
                (*phase) *= phase_inc;
                four_phase_rotations_32fc[1]=*phase;
                (*phase) *= phase_inc;
                four_phase_rotations_32fc[2]=*phase;
                (*phase) *= phase_inc;
                four_phase_rotations_32fc[3]=*phase;
                (*phase) *= phase_inc;
                //convert the rotations to integers
                fc_reg1 = _mm_load_ps((float*)&four_phase_rotations_32fc[0]);
                // disable next line for 1 bit rotation (equivalent to a square wave NCO)
                fc_reg1 = _mm_mul_ps (fc_reg1, _rotator_amplitude_reg);
                fc_reg2 = _mm_load_ps((float*)&four_phase_rotations_32fc[2]);
                sc_reg1 = _mm_cvtps_epi32(fc_reg1);
                sc_reg2 = _mm_cvtps_epi32(fc_reg2);
                b = _mm_packs_epi32(sc_reg1, sc_reg2);
                // debug
 	            //_mm_store_si128((__m128i*)four_phase_rotations_16sc, b);
                //printf("phase fc: %f,%f phase sc: %i,%i \n",lv_creal(four_phase_rotations_32fc[0]),lv_cimag(four_phase_rotations_32fc[0]),lv_creal(four_phase_rotations_16sc[0]),lv_cimag(four_phase_rotations_16sc[0]));
                // multiply the input vector times the rotations
 	            c = _mm_mullo_epi16 (a, b); // a3.i*b3.i, a3.r*b3.r, ....
 	            c_sr = _mm_srli_si128 (c, 2); // Shift a right by imm8 bytes while shifting in zeros, and store the results in dst.
 	            real = _mm_subs_epi16 (c, c_sr);
 	            real = _mm_and_si128 (real, mask_real); // a3.r*b3.r-a3.i*b3.i , 0,  a3.r*b3.r- a3.i*b3.i
 	            b_sl = _mm_slli_si128(b, 2); // b3.r, b2.i ....
 	            a_sl = _mm_slli_si128(a, 2); // a3.r, a2.i ....
 	            imag1 = _mm_mullo_epi16(a, b_sl); // a3.i*b3.r, ....
 	            imag2 = _mm_mullo_epi16(b, a_sl); // b3.i*a3.r, ....
 	            imag = _mm_adds_epi16(imag1, imag2);
 	            imag = _mm_and_si128 (imag, mask_imag); // a3.i*b3.r+b3.i*a3.r, 0, ...
 	            result = _mm_or_si128 (real, imag);
 	            // normalize the rotations
 	            // TODO
 	            // store results
 	            _mm_storeu_si128((__m128i*)_out, result);
 	            _in_a += 4;
 	            _out += 4;
 	        }
 	    for (unsigned int i = sse_iters * 4; i < num_points; ++i)
 	        {
 				*_out++ = *_in_a++ * (*phase);
 				(*phase) *= phase_inc;
 	        }
 }
 #endif /* LV_HAVE_SSE2 */
 #ifdef LV_HAVE_NEON
 #include <arm.neon.h>
 static inline void volk_gnsssdr_16ic_s32fc_x2_rotator_16ic_neon(lv_16sc_t* outVector, const lv_16sc_t* inVector, const lv_32fc_t phase_inc, lv_32fc_t* phase, unsigned int num_points)
 {
    unsigned int i = 0;
    int j = 0;
    lv_16sc_t tmp16;
    lv_32fc_t tmp32;
    for(i = 0; i < (unsigned int)(num_points / ROTATOR_RELOAD); ++i)
        {
            for(j = 0; j < ROTATOR_RELOAD; ++j)
                {
-                    *outVector++ = *inVector++ * (*phase);
+                    tmp16 = *inVector++;
                    tmp32 = lv_cmake((float)lv_creal(tmp16), (float)lv_cimag(tmp16)) * (*phase);
                    *outVector++ = lv_cmake((int16_t)rintf(lv_creal(tmp32)), (int16_t)rintf(lv_cimag(tmp32)));
                    (*phase) *= phase_inc;
                    tmp32=(*phase);
                    printf("[%i][%i] phase fc: %f,%f  \n",i,j,lv_creal(tmp32),lv_cimag(tmp32));
                }
 #ifdef __cplusplus
            (*phase) /= std::abs((*phase));
 #else
            //(*phase) /= cabsf((*phase));
            (*phase) /= hypotf(lv_creal(*phase), lv_cimag(*phase));
 #endif
        }
    for(i = 0; i < num_points % ROTATOR_RELOAD; ++i)
        {
-            *outVector++ = *inVector++ * (*phase);
+           tmp16 = *inVector++;
           tmp32 = lv_cmake((float)lv_creal(tmp16), (float)lv_cimag(tmp16)) * (*phase);
            *outVector++ = lv_cmake((int16_t)rintf(lv_creal(tmp32)), (int16_t)rintf(lv_cimag(tmp32)));
            (*phase) *= phase_inc;
        }
 }
 #endif /* LV_HAVE_NEON */