+++ /dev/null
-//**************************************************************************
-// Multi-threaded Matrix Multiply benchmark
-//--------------------------------------------------------------------------
-// TA : Christopher Celio
-// Student:
-//
-//
-// This benchmark multiplies two 2-D arrays together and writes the results to
-// a third vector. The input data (and reference data) should be generated
-// using the matmul_gendata.pl perl script and dumped to a file named
-// dataset.h.
-
-
-// print out arrays, etc.
-//#define DEBUG
-
-//--------------------------------------------------------------------------
-// Includes
-
-#include <string.h>
-#include <stdlib.h>
-#include <stdio.h>
-
-
-//--------------------------------------------------------------------------
-// Input/Reference Data
-
-typedef float data_t;
-#include "dataset.h"
-
-
-//--------------------------------------------------------------------------
-// Basic Utilities and Multi-thread Support
-
-__thread unsigned long coreid;
-unsigned long ncores;
-
-#include "util.h"
-
-#define stringify_1(s) #s
-#define stringify(s) stringify_1(s)
-#define stats(code) do { \
- unsigned long _c = -rdcycle(), _i = -rdinstret(); \
- code; \
- _c += rdcycle(), _i += rdinstret(); \
- if (coreid == 0) \
- printf("%s: %ld cycles, %ld.%ld cycles/iter, %ld.%ld CPI\n", \
- stringify(code), _c, _c/DIM_SIZE/DIM_SIZE/DIM_SIZE, 10*_c/DIM_SIZE/DIM_SIZE/DIM_SIZE%10, _c/_i, 10*_c/_i%10); \
- } while(0)
-
-
-//--------------------------------------------------------------------------
-// Helper functions
-
-void printArrayMT( char name[], int n, data_t arr[] )
-{
- int i;
- if (coreid != 0)
- return;
-
- printf( " %10s :", name );
- for ( i = 0; i < n; i++ )
- printf( " %3ld ", (long) arr[i] );
- printf( "\n" );
-}
-
-void __attribute__((noinline)) verifyMT(size_t n, const data_t* test, const data_t* correct)
-{
- if (coreid != 0)
- return;
-
- size_t i;
- for (i = 0; i < n; i++)
- {
- if (test[i] != correct[i])
- {
- printf("FAILED test[%d]= %3ld, correct[%d]= %3ld\n",
- i, (long)test[i], i, (long)correct[i]);
- exit(-1);
- }
- }
-
- return;
-}
-
-//--------------------------------------------------------------------------
-// matmul function
-
-// single-thread, naive version
-void __attribute__((noinline)) matmul_naive(const int lda, const data_t A[], const data_t B[], data_t C[] )
-{
- int i, j, k;
-
- if (coreid > 0)
- return;
-
- for ( i = 0; i < lda; i++ )
- for ( j = 0; j < lda; j++ )
- {
- for ( k = 0; k < lda; k++ )
- {
- C[i + j*lda] += A[j*lda + k] * B[k*lda + i];
- }
- }
-
-}
-
-
-
-void __attribute__((noinline)) matmul(const int lda, const data_t A[], const data_t B[], data_t C[] )
-{
-
- // ***************************** //
- // **** ADD YOUR CODE HERE ***** //
- // ***************************** //
- //
- // feel free to make a separate function for MI and MSI versions.
- int i, j, k;
- int space=lda/ncores;
- int max= space*coreid+space;
- static data_t B1[32*32];
- if (coreid==ncores-1){
- for (i=0; i<lda*lda/2;i++)
- {
- B1[i]=B[i];
- }
- }
- else{
- for (i=lda*lda/2;i<lda*lda;i++)
- B1[i]=B[i];
- }
- data_t temp=0;
- data_t temp1=0;
- data_t temp2=0;
- data_t temp3=0;
- data_t tempB=0;
-
- data_t temp_1=0;
- data_t temp1_1=0;
- data_t temp2_1=0;
- data_t temp3_1=0;
- data_t tempB_1=0;
-
- data_t temp_2=0;
- data_t temp1_2=0;
- data_t temp2_2=0;
- data_t temp3_2=0;
- data_t tempB_2=0;
-
- data_t temp_3=0;
- data_t temp1_3=0;
- data_t temp2_3=0;
- data_t temp3_3=0;
- data_t tempB_3=0;
- barrier(nc);
- if (coreid!=ncores-1){
- for (i=space*coreid;i<max/4*4;i+=4)
- {
- for(j=0;j<lda/4*4;j+=4)
- {
- temp=C[j+i*lda];
- temp1=C[j+(i+1)*lda];
- temp2=C[j+(i+2)*lda];
- temp3=C[j+(i+3)*lda];
- temp_1=C[j+1+i*lda];
- temp1_1=C[j+1+(i+1)*lda];
- temp2_1=C[j+1+(i+2)*lda];
- temp3_1=C[j+1+(i+3)*lda];
- temp_2=C[j+2+i*lda];
- temp1_2=C[j+2+(i+1)*lda];
- temp2_2=C[j+2+(i+2)*lda];
- temp3_2=C[j+2+(i+3)*lda];
- temp_3=C[j+3+i*lda];
- temp1_3=C[j+3+(i+1)*lda];
- temp2_3=C[j+3+(i+2)*lda];
- temp3_3=C[j+3+(i+3)*lda];
- for (k=0;k<lda;k++)
- {
- tempB=B[j+k*lda];
- temp+=A[k+i*lda]*tempB;
- temp1+=A[k+(i+1)*lda]*tempB;
- temp2+=A[k+(i+2)*lda]*tempB;
- temp3+=A[k+(i+3)*lda]*tempB;
-
- tempB_1=B[j+1+k*lda];
- temp_1+=A[k+i*lda]*tempB_1;
- temp1_1+=A[k+(i+1)*lda]*tempB_1;
- temp2_1+=A[k+(i+2)*lda]*tempB_1;
- temp3_1+=A[k+(i+3)*lda]*tempB_1;
-
- tempB_2=B[j+2+k*lda];
- temp_2+=A[k+i*lda]*tempB_2;
- temp1_2+=A[k+(i+1)*lda]*tempB_2;
- temp2_2+=A[k+(i+2)*lda]*tempB_2;
- temp3_2+=A[k+(i+3)*lda]*tempB_2;
-
- tempB_3=B[j+3+k*lda];
- temp_3+=A[k+i*lda]*tempB_3;
- temp1_3+=A[k+(i+1)*lda]*tempB_3;
- temp2_3+=A[k+(i+2)*lda]*tempB_3;
- temp3_3+=A[k+(i+3)*lda]*tempB_3;
- }
- C[j+i*lda]=temp;
- C[j+(i+1)*lda]=temp1;
- C[j+(i+2)*lda]=temp2;
- C[j+(i+3)*lda]=temp3;
-
- C[j+1+i*lda]=temp_1;
- C[j+1+(i+1)*lda]=temp1_1;
- C[j+1+(i+2)*lda]=temp2_1;
- C[j+1+(i+3)*lda]=temp3_1;
-
- C[j+2+i*lda]=temp_2;
- C[j+2+(i+1)*lda]=temp1_2;
- C[j+2+(i+2)*lda]=temp2_2;
- C[j+2+(i+3)*lda]=temp3_2;
-
- C[j+3+i*lda]=temp_3;
- C[j+3+(i+1)*lda]=temp1_3;
- C[j+3+(i+2)*lda]=temp2_3;
- C[j+3+(i+3)*lda]=temp3_3;
-
- }
- }
- }
- else{
- for (i=space*coreid;i<lda/4*4;i+=4)
- {
- for(j=0;j<lda/4*4;j+=4)
- {
- temp=C[j+i*lda];
- temp1=C[j+(i+1)*lda];
- temp2=C[j+(i+2)*lda];
- temp3=C[j+(i+3)*lda];
- temp_1=C[j+1+i*lda];
- temp1_1=C[j+1+(i+1)*lda];
- temp2_1=C[j+1+(i+2)*lda];
- temp3_1=C[j+1+(i+3)*lda];
- temp_2=C[j+2+i*lda];
- temp1_2=C[j+2+(i+1)*lda];
- temp2_2=C[j+2+(i+2)*lda];
- temp3_2=C[j+2+(i+3)*lda];
- temp_3=C[j+3+i*lda];
- temp1_3=C[j+3+(i+1)*lda];
- temp2_3=C[j+3+(i+2)*lda];
- temp3_3=C[j+3+(i+3)*lda];
- for (k=0;k<lda;k++)
- {
- tempB=B1[j+k*lda];
- temp+=A[k+i*lda]*tempB;
- temp1+=A[k+(i+1)*lda]*tempB;
- temp2+=A[k+(i+2)*lda]*tempB;
- temp3+=A[k+(i+3)*lda]*tempB;
-
- tempB_1=B1[j+1+k*lda];
- temp_1+=A[k+i*lda]*tempB_1;
- temp1_1+=A[k+(i+1)*lda]*tempB_1;
- temp2_1+=A[k+(i+2)*lda]*tempB_1;
- temp3_1+=A[k+(i+3)*lda]*tempB_1;
-
- tempB_2=B1[j+2+k*lda];
- temp_2+=A[k+i*lda]*tempB_2;
- temp1_2+=A[k+(i+1)*lda]*tempB_2;
- temp2_2+=A[k+(i+2)*lda]*tempB_2;
- temp3_2+=A[k+(i+3)*lda]*tempB_2;
-
- tempB_3=B1[j+3+k*lda];
- temp_3+=A[k+i*lda]*tempB_3;
- temp1_3+=A[k+(i+1)*lda]*tempB_3;
- temp2_3+=A[k+(i+2)*lda]*tempB_3;
- temp3_3+=A[k+(i+3)*lda]*tempB_3;
- }
- C[j+i*lda]=temp;
- C[j+(i+1)*lda]=temp1;
- C[j+(i+2)*lda]=temp2;
- C[j+(i+3)*lda]=temp3;
-
- C[j+1+i*lda]=temp_1;
- C[j+1+(i+1)*lda]=temp1_1;
- C[j+1+(i+2)*lda]=temp2_1;
- C[j+1+(i+3)*lda]=temp3_1;
-
- C[j+2+i*lda]=temp_2;
- C[j+2+(i+1)*lda]=temp1_2;
- C[j+2+(i+2)*lda]=temp2_2;
- C[j+2+(i+3)*lda]=temp3_2;
-
- C[j+3+i*lda]=temp_3;
- C[j+3+(i+1)*lda]=temp1_3;
- C[j+3+(i+2)*lda]=temp2_3;
- C[j+3+(i+3)*lda]=temp3_3;
-
- }
- }
- }
-
-
-
-
-}
-
-//--------------------------------------------------------------------------
-// Main
-//
-// all threads start executing thread_entry(). Use their "coreid" to
-// differentiate between threads (each thread is running on a separate core).
-
-void thread_entry(int cid, int nc)
-{
- coreid = cid;
- ncores = nc;
-
- // static allocates data in the binary, which is visible to both threads
- static data_t results_data[ARRAY_SIZE];
-
-
-// // Execute the provided, naive matmul
-// barrier(nc);
-// stats(matmul_naive(DIM_SIZE, input1_data, input2_data, results_data); barrier(nc));
-//
-//
-// // verify
-// verifyMT(ARRAY_SIZE, results_data, verify_data);
-//
-// // clear results from the first trial
-// size_t i;
-// if (coreid == 0)
-// for (i=0; i < ARRAY_SIZE; i++)
-// results_data[i] = 0;
-// barrier(nc);
-
-
- // Execute your faster matmul
- barrier(nc);
- stats(matmul(DIM_SIZE, input1_data, input2_data, results_data); barrier(nc));
-
-#ifdef DEBUG
- printArrayMT("results:", ARRAY_SIZE, results_data);
- printArrayMT("verify :", ARRAY_SIZE, verify_data);
-#endif
-
- // verify
- verifyMT(ARRAY_SIZE, results_data, verify_data);
- barrier(nc);
-
- exit(0);
-}
-
projects / riscv-tests.git / blobdiff