Added missing Blas1 single fp {saxpy, caxpy, cdot, crot(refactored version of srot),isamax ,isamin, icamax, icamin},

Fixed idamin,icamin choosing the first occurance index of equal minimals

kernel/power/isamin.c

@@ -0,0 +1,288 @@
+/***************************************************************************
+Copyright (c) 2013-2019, The OpenBLAS Project
+All rights reserved.
+Redistribution and use in source and binary forms, with or without
+modification, are permitted provided that the following conditions are
+met:
+1. Redistributions of source code must retain the above copyright
+notice, this list of conditions and the following disclaimer.
+2. Redistributions in binary form must reproduce the above copyright
+notice, this list of conditions and the following disclaimer in
+the documentation and/or other materials provided with the
+distribution.
+3. Neither the name of the OpenBLAS project nor the names of
+its contributors may be used to endorse or promote products
+derived from this software without specific prior written permission.
+THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
+ARE DISCLAIMED. IN NO EVENT SHALL THE OPENBLAS PROJECT OR CONTRIBUTORS BE
+LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
+DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
+SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
+CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
+OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE
+USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
+ *****************************************************************************/
+#include "common.h"
+#include <math.h>
+#include <altivec.h>
+#if defined(DOUBLE)
+    #define ABS fabs
+#else
+    #define ABS fabsf
+#endif
+/**
+ * Find  minimum index 
+ * Warning: requirements n>0  and n % 64 == 0
+ * @param n     
+ * @param x     pointer to the vector
+ * @param minf  (out) minimum absolute value .( only for output )
+ * @return  index 
+ */
+static BLASLONG siamin_kernel_64(BLASLONG n, FLOAT *x, FLOAT *minf) {
+    BLASLONG index;
+    BLASLONG i=0;
+    register __vector unsigned int static_index0 = {0,1,2,3};
+    register __vector unsigned int temp0 = {4,4,4, 4}; //temporary vector register
+    register __vector unsigned int temp1=  temp0<<1;  //{8,8,8,8}
+    register __vector unsigned int static_index1=static_index0 +temp0;//{4,5,6,7};
+    register __vector unsigned int static_index2=static_index0 +temp1;//{8,9,10,11};
+    register __vector unsigned int static_index3=static_index1 +temp1; //{12,13,14,15};
+    temp0=vec_xor(temp0,temp0);
+    temp1=temp1 <<1 ; //{16,16,16,16}
+    register __vector unsigned int quadruple_indices=static_index0;//{0,1,2,3};
+    register __vector float * v_ptrx=(__vector float *)x;
+    register __vector float quadruple_values=vec_abs(v_ptrx[0]);
+    for(; i<n; i+=64){
+       //absolute temporary vectors
+       register __vector float v0=vec_abs(v_ptrx[0]);
+       register __vector float v1=vec_abs(v_ptrx[1]);
+       register __vector float v2=vec_abs(v_ptrx[2]);
+       register __vector float v3=vec_abs(v_ptrx[3]);
+       register __vector float v4=vec_abs(v_ptrx[4]);
+       register __vector float v5=vec_abs(v_ptrx[5]);
+       register __vector float v6=vec_abs(v_ptrx[6]);       
+       register __vector float v7=vec_abs(v_ptrx[7]);
+       //cmp quadruple pairs
+       register __vector bool int r1=vec_cmpgt(v0,v1);
+       register __vector bool int r2=vec_cmpgt(v2,v3);
+       register __vector bool int r3=vec_cmpgt(v4,v5);
+       register __vector bool int r4=vec_cmpgt(v6,v7);
+              
+       //select
+       register __vector unsigned int ind0_first= vec_sel(static_index0,static_index1,r1);
+       register __vector float vf0= vec_sel(v0,v1,r1);
+
+       register __vector unsigned int ind1= vec_sel(static_index2,static_index3,r2);
+       register __vector float vf1= vec_sel(v2,v3,r2);
+
+       register __vector unsigned int ind2= vec_sel(static_index0,static_index1,r3);
+       v0=vec_sel(v4,v5,r3);
+
+       register __vector unsigned int ind3= vec_sel(static_index2,static_index3,r4);
+       v1=vec_sel(v6,v7,r4);
+
+       // cmp selected
+       r1=vec_cmpgt(vf0,vf1);
+       r2=vec_cmpgt(v0,v1);
+
+       v_ptrx+=8;
+       //select from above 
+       ind0_first= vec_sel(ind0_first,ind1,r1);
+       vf0= vec_sel(vf0,vf1,r1) ;
+
+       ind2= vec_sel(ind2,ind3,r2);
+       vf1= vec_sel(v0,v1,r2);
+
+       //second indices actually should be within [16,31] so ind2+16
+       ind2 +=temp1;
+       
+       //final cmp and select index and value for the first 32 values
+       r1=vec_cmpgt(vf0,vf1);
+       ind0_first = vec_sel(ind0_first,ind2,r1);
+       vf0= vec_sel(vf0,vf1,r1);
+ 
+       ind0_first+=temp0; //get absolute index
+       
+       temp0+=temp1;
+       temp0+=temp1; //temp0+32
+       //second part of 32
+       // absolute temporary vectors
+       v0=vec_abs(v_ptrx[0]);
+       v1=vec_abs(v_ptrx[1]);
+       v2=vec_abs(v_ptrx[2]);
+       v3=vec_abs(v_ptrx[3]);
+       v4=vec_abs(v_ptrx[4]);
+       v5=vec_abs(v_ptrx[5]);
+       v6=vec_abs(v_ptrx[6]);       
+       v7=vec_abs(v_ptrx[7]);
+       //cmp quadruple pairs
+       r1=vec_cmpgt(v0,v1);
+       r2=vec_cmpgt(v2,v3);
+       r3=vec_cmpgt(v4,v5);
+       r4=vec_cmpgt(v6,v7);
+       //select
+       register __vector unsigned int ind0_second= vec_sel(static_index0,static_index1,r1);
+       register __vector float vv0= vec_sel(v0,v1,r1);
+
+       ind1= vec_sel(static_index2,static_index3,r2);
+       register __vector float vv1= vec_sel(v2,v3,r2);
+
+       ind2= vec_sel(static_index0,static_index1,r3);
+       v0=vec_sel(v4,v5,r3);
+
+       ind3= vec_sel(static_index2,static_index3,r4);
+       v1=vec_sel(v6,v7,r4);
+
+       // cmp selected
+       r1=vec_cmpgt(vv0,vv1);
+       r2=vec_cmpgt(v0,v1);
+
+       v_ptrx+=8;
+       //select from above 
+       ind0_second= vec_sel(ind0_second,ind1,r1);
+       vv0= vec_sel(vv0,vv1,r1) ;
+
+       ind2= vec_sel(ind2,ind3,r2);
+       vv1= vec_sel(v0,v1,r2) ;  
+
+       //second indices actually should be within [16,31] so ind2+16
+       ind2 +=temp1;
+       
+       //final cmp and select index and value for the second 32 values
+       r1=vec_cmpgt(vv0,vv1);
+       ind0_second = vec_sel(ind0_second,ind2,r1);
+       vv0= vec_sel(vv0,vv1,r1);
+
+       ind0_second+=temp0; //get absolute index
+        
+       //find final quadruple from 64 elements
+       r2=vec_cmpgt(vf0,vv0);
+       ind2 = vec_sel( ind0_first,ind0_second,r2);
+       vv0= vec_sel(vf0,vv0,r2);       
+             
+       //compare with old quadruple and update 
+       r3=vec_cmpgt( quadruple_values,vv0);
+       quadruple_indices = vec_sel( quadruple_indices,ind2,r3);
+       quadruple_values= vec_sel(quadruple_values,vv0,r3);      
+            
+       temp0+=temp1;
+       temp0+=temp1; //temp0+32
+       
+      
+    }
+
+    //now we have to chose from 4 values and 4 different indices
+    // we will compare pairwise if pairs are exactly the same we will choose minimum between index
+    // otherwise we will assign index of the minimum value
+    float a1,a2,a3,a4;
+    unsigned int i1,i2,i3,i4;
+    a1=vec_extract(quadruple_values,0);
+    a2=vec_extract(quadruple_values,1);
+    a3=vec_extract(quadruple_values,2);
+    a4=vec_extract(quadruple_values,3);
+    i1=vec_extract(quadruple_indices,0);
+    i2=vec_extract(quadruple_indices,1);
+    i3=vec_extract(quadruple_indices,2);
+    i4=vec_extract(quadruple_indices,3);
+    if(a1==a2){
+       index=i1>i2?i2:i1;
+    }else if(a2<a1){
+      index=i2;
+      a1=a2;
+    }else{
+       index= i1;
+    }
+
+    if(a4==a3){
+      i1=i3>i4?i4:i3;
+    }else if(a4<a3){
+      i1=i4;
+      a3=a4;
+    }else{
+       i1= i3;
+    }
+
+    if(a1==a3){
+      index=i1>index?index:i1;
+       *minf=a1; 
+    }else if(a3<a1){
+       index=i1;
+       *minf=a3;
+    }else{ 
+        *minf=a1;
+    }
+    return index;
+
+}
+
+
+
+
+BLASLONG CNAME(BLASLONG n, FLOAT *x, BLASLONG inc_x) {
+    BLASLONG i = 0;
+    BLASLONG j = 0; 
+    BLASLONG min = 0;
+    FLOAT minf = 0.0;
+    
+    if (n <= 0 || inc_x <= 0) return (min);
+    minf = ABS(x[0]); //index's not incremented
+    if (inc_x == 1) {
+
+        BLASLONG n1 = n & -64;
+        if (n1 > 0) {
+
+            min = siamin_kernel_64(n1, x, &minf);
+            i = n1;
+        }
+
+        while (i < n) {
+            if (ABS(x[i]) < minf) {
+                min = i;
+                minf = ABS(x[i]);
+            }
+            i++;
+        }
+        return (min + 1);
+
+    } else {
+
+        BLASLONG n1 = n & -4;
+        while (j < n1) {
+
+            if (ABS(x[i]) < minf) {
+                min = j;
+                minf = ABS(x[i]);
+            }
+            if (ABS(x[i + inc_x]) < minf) {
+                min = j + 1;
+                minf = ABS(x[i + inc_x]);
+            }
+            if (ABS(x[i + 2 * inc_x]) < minf) {
+                min = j + 2;
+                minf = ABS(x[i + 2 * inc_x]);
+            }
+            if (ABS(x[i + 3 * inc_x]) < minf) {
+                min = j + 3;
+                minf = ABS(x[i + 3 * inc_x]);
+            }
+
+            i += inc_x * 4;
+
+            j += 4;
+
+        }
+
+
+        while (j < n) {
+            if (ABS(x[i]) < minf) {
+                min = j;
+                minf = ABS(x[i]);
+            }
+            i += inc_x;
+            j++;
+        }
+        return (min + 1);
+    }
+}