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|
/*
* vim: ai ts=4 sts=4 sw=4 cinoptions=>4 expandtab
*/
#define _GNU_SOURCE
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <err.h>
#include <sys/types.h>
#include <sys/time.h>
#include <time.h>
#include <string.h>
#include <unistd.h>
#ifdef HAVE_AVX512
#include <stdint.h>
#include <immintrin.h>
#endif
#ifdef MULTITHREADED
#include <pthread.h>
#include <semaphore.h>
#endif
#ifdef NUMA
#include <numaif.h>
#include <numa.h>
#endif
/* how many runs to average by default */
#define DEFAULT_NR_LOOPS 40
/* we have 4 tests at the moment */
#define MAX_TESTS 5
/* default block size for test 2, in bytes */
#define DEFAULT_BLOCK_SIZE 262144
/* test types */
#define TEST_MEMCPY 0
#define TEST_PLAIN 1
#define TEST_MCBLOCK 2
#define TEST_AVX512 3
#define TEST_READ_PLAIN 4
/* version number */
#define VERSION "1.5+smaug"
/*
* MBW memory bandwidth benchmark
*
* 2006, 2012 Andras.Horvath@gmail.com
* 2013 j.m.slocum@gmail.com
* (Special thanks to Stephen Pasich)
*
* http://github.com/raas/mbw
*
* compile with:
* gcc -O -o mbw mbw.c
*
* run with eg.:
*
* ./mbw 300
*
* or './mbw -h' for help
*
* watch out for swap usage (or turn off swap)
*/
#ifdef MULTITHREADED
unsigned long num_threads = 1;
volatile unsigned int done = 0;
pthread_t *threads;
sem_t start_sem, stop_sem, sync_sem;
#endif
long *arr_a, *arr_b; /* the two arrays to be copied from/to */
unsigned long long arr_size=0; /* array size (elements in array) */
unsigned int test_type;
/* fixed memcpy block size for -t2 */
unsigned long long block_size=DEFAULT_BLOCK_SIZE;
#ifdef NUMA
void* mp_pages[1];
int mp_status[1];
int mp_nodes[1];
int numa_node_a = -1;
int numa_node_b = -1;
int numa_node_cpu = -1;
struct bitmask* bitmask_a = NULL;
struct bitmask* bitmask_b = NULL;
#endif
#ifdef HAVE_AVX512
/**
* AVX512 implementation taken from
* <https://lore.kernel.org/all/1453086314-30158-4-git-send-email-zhihong.wang@intel.com/>
*/
/**
* Copy 16 bytes from one location to another,
* locations should not overlap.
*/
static inline void
rte_mov16(uint8_t *dst, const uint8_t *src)
{
__m128i xmm0;
xmm0 = _mm_loadu_si128((const __m128i *)src);
_mm_storeu_si128((__m128i *)dst, xmm0);
}
/**
* Copy 32 bytes from one location to another,
* locations should not overlap.
*/
static inline void
rte_mov32(uint8_t *dst, const uint8_t *src)
{
__m256i ymm0;
ymm0 = _mm256_loadu_si256((const __m256i *)src);
_mm256_storeu_si256((__m256i *)dst, ymm0);
}
/**
* Copy 64 bytes from one location to another,
* locations should not overlap.
*/
static inline void
rte_mov64(uint8_t *dst, const uint8_t *src)
{
__m512i zmm0;
zmm0 = _mm512_loadu_si512((const void *)src);
_mm512_storeu_si512((void *)dst, zmm0);
}
/**
* Copy 128 bytes from one location to another,
* locations should not overlap.
*/
static inline void
rte_mov128(uint8_t *dst, const uint8_t *src)
{
rte_mov64(dst + 0 * 64, src + 0 * 64);
rte_mov64(dst + 1 * 64, src + 1 * 64);
}
/**
* Copy 256 bytes from one location to another,
* locations should not overlap.
*/
static inline void
rte_mov256(uint8_t *dst, const uint8_t *src)
{
rte_mov64(dst + 0 * 64, src + 0 * 64);
rte_mov64(dst + 1 * 64, src + 1 * 64);
rte_mov64(dst + 2 * 64, src + 2 * 64);
rte_mov64(dst + 3 * 64, src + 3 * 64);
}
/**
* Copy 128-byte blocks from one location to another,
* locations should not overlap.
*/
static inline void
rte_mov128blocks(uint8_t *dst, const uint8_t *src, size_t n)
{
__m512i zmm0, zmm1;
while (n >= 128) {
zmm0 = _mm512_loadu_si512((const void *)(src + 0 * 64));
n -= 128;
zmm1 = _mm512_loadu_si512((const void *)(src + 1 * 64));
src = src + 128;
_mm512_storeu_si512((void *)(dst + 0 * 64), zmm0);
_mm512_storeu_si512((void *)(dst + 1 * 64), zmm1);
dst = dst + 128;
}
}
/**
* Copy 512-byte blocks from one location to another,
* locations should not overlap.
*/
static inline void
rte_mov512blocks(uint8_t *dst, const uint8_t *src, size_t n)
{
__m512i zmm0, zmm1, zmm2, zmm3, zmm4, zmm5, zmm6, zmm7;
while (n >= 512) {
zmm0 = _mm512_loadu_si512((const void *)(src + 0 * 64));
n -= 512;
zmm1 = _mm512_loadu_si512((const void *)(src + 1 * 64));
zmm2 = _mm512_loadu_si512((const void *)(src + 2 * 64));
zmm3 = _mm512_loadu_si512((const void *)(src + 3 * 64));
zmm4 = _mm512_loadu_si512((const void *)(src + 4 * 64));
zmm5 = _mm512_loadu_si512((const void *)(src + 5 * 64));
zmm6 = _mm512_loadu_si512((const void *)(src + 6 * 64));
zmm7 = _mm512_loadu_si512((const void *)(src + 7 * 64));
src = src + 512;
_mm512_storeu_si512((void *)(dst + 0 * 64), zmm0);
_mm512_storeu_si512((void *)(dst + 1 * 64), zmm1);
_mm512_storeu_si512((void *)(dst + 2 * 64), zmm2);
_mm512_storeu_si512((void *)(dst + 3 * 64), zmm3);
_mm512_storeu_si512((void *)(dst + 4 * 64), zmm4);
_mm512_storeu_si512((void *)(dst + 5 * 64), zmm5);
_mm512_storeu_si512((void *)(dst + 6 * 64), zmm6);
_mm512_storeu_si512((void *)(dst + 7 * 64), zmm7);
dst = dst + 512;
}
}
static inline void *
rte_memcpy(void *dst, const void *src, size_t n)
{
uintptr_t dstu = (uintptr_t)dst;
uintptr_t srcu = (uintptr_t)src;
void *ret = dst;
size_t dstofss;
size_t bits;
/**
* Copy less than 16 bytes
*/
if (n < 16) {
if (n & 0x01) {
*(uint8_t *)dstu = *(const uint8_t *)srcu;
srcu = (uintptr_t)((const uint8_t *)srcu + 1);
dstu = (uintptr_t)((uint8_t *)dstu + 1);
}
if (n & 0x02) {
*(uint16_t *)dstu = *(const uint16_t *)srcu;
srcu = (uintptr_t)((const uint16_t *)srcu + 1);
dstu = (uintptr_t)((uint16_t *)dstu + 1);
}
if (n & 0x04) {
*(uint32_t *)dstu = *(const uint32_t *)srcu;
srcu = (uintptr_t)((const uint32_t *)srcu + 1);
dstu = (uintptr_t)((uint32_t *)dstu + 1);
}
if (n & 0x08)
*(uint64_t *)dstu = *(const uint64_t *)srcu;
return ret;
}
/**
* Fast way when copy size doesn't exceed 512 bytes
*/
if (n <= 32) {
rte_mov16((uint8_t *)dst, (const uint8_t *)src);
rte_mov16((uint8_t *)dst - 16 + n,
(const uint8_t *)src - 16 + n);
return ret;
}
if (n <= 64) {
rte_mov32((uint8_t *)dst, (const uint8_t *)src);
rte_mov32((uint8_t *)dst - 32 + n,
(const uint8_t *)src - 32 + n);
return ret;
}
if (n <= 512) {
if (n >= 256) {
n -= 256;
rte_mov256((uint8_t *)dst, (const uint8_t *)src);
src = (const uint8_t *)src + 256;
dst = (uint8_t *)dst + 256;
}
if (n >= 128) {
n -= 128;
rte_mov128((uint8_t *)dst, (const uint8_t *)src);
src = (const uint8_t *)src + 128;
dst = (uint8_t *)dst + 128;
}
COPY_BLOCK_128_BACK63:
if (n > 64) {
rte_mov64((uint8_t *)dst, (const uint8_t *)src);
rte_mov64((uint8_t *)dst - 64 + n,
(const uint8_t *)src - 64 + n);
return ret;
}
if (n > 0)
rte_mov64((uint8_t *)dst - 64 + n,
(const uint8_t *)src - 64 + n);
return ret;
}
/**
* Make store aligned when copy size exceeds 512 bytes
*/
dstofss = ((uintptr_t)dst & 0x3F);
if (dstofss > 0) {
dstofss = 64 - dstofss;
n -= dstofss;
rte_mov64((uint8_t *)dst, (const uint8_t *)src);
src = (const uint8_t *)src + dstofss;
dst = (uint8_t *)dst + dstofss;
}
/**
* Copy 512-byte blocks.
* Use copy block function for better instruction order control,
* which is important when load is unaligned.
*/
rte_mov512blocks((uint8_t *)dst, (const uint8_t *)src, n);
bits = n;
n = n & 511;
bits -= n;
src = (const uint8_t *)src + bits;
dst = (uint8_t *)dst + bits;
/**
* Copy 128-byte blocks.
* Use copy block function for better instruction order control,
* which is important when load is unaligned.
*/
if (n >= 128) {
rte_mov128blocks((uint8_t *)dst, (const uint8_t *)src, n);
bits = n;
n = n & 127;
bits -= n;
src = (const uint8_t *)src + bits;
dst = (uint8_t *)dst + bits;
}
/**
* Copy whatever left
*/
goto COPY_BLOCK_128_BACK63;
}
#endif
void usage()
{
printf("mbw memory benchmark v%s, https://github.com/raas/mbw\n", VERSION);
printf("Usage: mbw [options] array_size_in_MiB\n");
printf("Options:\n");
printf(" -n: number of runs per test (0 to run forever)\n");
printf(" -a: Don't display average\n");
printf(" -t%d: memcpy test\n", TEST_MEMCPY);
printf(" -t%d: plain (b[i]=a[i] style) test\n", TEST_PLAIN);
printf(" -t%d: memcpy test with fixed block size\n", TEST_MCBLOCK);
#ifdef HAVE_AVX512
printf(" -t%d: AVX512 copy test\n", TEST_AVX512);
#endif
printf(" -t%d: plain read test\n", TEST_READ_PLAIN);
printf(" -b <size>: block size in bytes for -t2 (default: %d)\n", DEFAULT_BLOCK_SIZE);
printf(" -q: quiet (print statistics only)\n");
#ifdef NUMA
printf(" -a <node>: allocate source array on NUMA node\n");
printf(" -b <node>: allocate target array on NUMA node\n");
printf(" -c <node>: schedule task/threads on NUME node\n");
#endif
printf("(will then use two arrays, watch out for swapping)\n");
printf("'Bandwidth' is amount of data copied over the time this operation took.\n");
printf("\nThe default is to run all tests available.\n");
}
/* ------------------------------------------------------ */
/* allocate a test array and fill it with data
* so as to force Linux to _really_ allocate it */
long *make_array()
{
unsigned long long t;
unsigned int long_size=sizeof(long);
long *a;
#ifdef HAVE_AVX512
a=aligned_alloc(64, arr_size * long_size);
#else
a=calloc(arr_size, long_size);
#endif
if(NULL==a) {
perror("Error allocating memory");
exit(1);
}
/* make sure both arrays are allocated, fill with pattern */
for(t=0; t<arr_size; t++) {
a[t]=0xaa;
}
return a;
}
#ifdef MULTITHREADED
void *thread_worker(void *arg)
{
unsigned long thread_id = (unsigned long)arg;
unsigned int long_size=sizeof(long);
unsigned long long array_bytes=arr_size*long_size;
unsigned long long t;
unsigned long long const plain_start = thread_id * (arr_size / num_threads);
unsigned long long const plain_stop = (thread_id + 1) * (arr_size / num_threads);
while (!done) {
if (sem_wait(&start_sem) != 0) {
err(1, "sem_wait(start_sem)");
}
if (done) {
return NULL;
}
if(test_type==TEST_MEMCPY) { /* memcpy test */
memcpy(arr_b + (thread_id * (arr_size / num_threads)), arr_a + (thread_id * (arr_size / num_threads)), array_bytes / num_threads);
} else if(test_type==TEST_MCBLOCK) { /* memcpy block test */
char* src = (char*)(arr_a + (thread_id * (arr_size / num_threads)));
char* dst = (char*)(arr_b + (thread_id * (arr_size / num_threads)));
for (t=array_bytes / num_threads; t >= block_size; t-=block_size, src+=block_size){
dst=(char *) memcpy(dst, src, block_size) + block_size;
}
if(t) {
dst=(char *) memcpy(dst, src, t) + t;
}
} else if(test_type==TEST_PLAIN) { /* plain test */
for(t=plain_start; t<plain_stop; t++) {
arr_b[t]=arr_a[t];
}
#ifdef HAVE_AVX512
} else if(test_type==TEST_AVX512) {
rte_memcpy(arr_b, arr_a, array_bytes);
#endif // HAVE_AVX512
} else if(test_type==TEST_READ_PLAIN) {
long tmp = 0;
for(t=plain_start; t<plain_stop; t++) {
tmp ^= arr_a[t];
}
arr_b[plain_stop-1] = tmp;
}
if (sem_post(&stop_sem) != 0) {
err(1, "sem_post(stop_sem)");
}
if (sem_wait(&sync_sem) != 0) {
err(1, "sem_wait(sync_sem)");
}
}
return NULL;
}
void start_threads()
{
for (unsigned int i = 0 ; i < num_threads; i++) {
sem_post(&start_sem);
}
}
void await_threads()
{
for (unsigned int i = 0 ; i < num_threads; i++) {
sem_wait(&stop_sem);
}
}
void sync_threads()
{
for (unsigned int i = 0 ; i < num_threads; i++) {
sem_post(&sync_sem);
}
}
#endif
/* actual benchmark */
/* arr_size: number of type 'long' elements in test arrays
* long_size: sizeof(long) cached
* test_type: 0=use memcpy, 1=use plain copy loop (whatever GCC thinks best)
*
* return value: elapsed time in seconds
*/
double worker()
{
struct timespec starttime, endtime;
double te;
/* array size in bytes */
#ifdef MULTITHREADED
clock_gettime(CLOCK_MONOTONIC, &starttime);
start_threads();
await_threads();
clock_gettime(CLOCK_MONOTONIC, &endtime);
sync_threads();
#else
unsigned int long_size=sizeof(long);
unsigned long long array_bytes=arr_size*long_size;
unsigned long long t;
if(test_type==TEST_MEMCPY) { /* memcpy test */
clock_gettime(CLOCK_MONOTONIC, &starttime);
memcpy(arr_b, arr_a, array_bytes);
clock_gettime(CLOCK_MONOTONIC, &endtime);
} else if(test_type==TEST_MCBLOCK) { /* memcpy block test */
char* src = (char*)arr_a;
char* dst = (char*)arr_b;
clock_gettime(CLOCK_MONOTONIC, &starttime);
for (t=array_bytes; t >= block_size; t-=block_size, src+=block_size){
dst=(char *) memcpy(dst, src, block_size) + block_size;
}
if(t) {
dst=(char *) memcpy(dst, src, t) + t;
}
clock_gettime(CLOCK_MONOTONIC, &endtime);
} else if(test_type==TEST_PLAIN) { /* plain test */
clock_gettime(CLOCK_MONOTONIC, &starttime);
for(t=0; t<arr_size; t++) {
arr_b[t]=arr_a[t];
}
clock_gettime(CLOCK_MONOTONIC, &endtime);
#ifdef HAVE_AVX512
} else if(test_type==TEST_AVX512) {
clock_gettime(CLOCK_MONOTONIC, &starttime);
rte_memcpy(arr_b, arr_a, array_bytes);
clock_gettime(CLOCK_MONOTONIC, &endtime);
#endif // HAVE_AVX512
} else if(test_type==TEST_READ_PLAIN) {
long tmp = 0;
clock_gettime(CLOCK_MONOTONIC, &starttime);
for(t=0; t<arr_size; t++) {
tmp ^= arr_a[t];
}
clock_gettime(CLOCK_MONOTONIC, &endtime);
arr_b[arr_size-1] = tmp;
}
#endif // MULTITHREADED
te=((double)(endtime.tv_sec*1000000000-starttime.tv_sec*1000000000+endtime.tv_nsec-starttime.tv_nsec))/1000000000;
return te;
}
/* ------------------------------------------------------ */
/* pretty print worker's output in human-readable terms */
/* te: elapsed time in seconds
* mt: amount of transferred data in MiB
* test_type: see 'worker' above
*
* return value: -
*/
void printout(double te, double mt)
{
switch(test_type) {
case TEST_MEMCPY:
printf("e_method=MEMCPY ");
break;
case TEST_PLAIN:
printf("e_method=PLAIN ");
break;
case TEST_MCBLOCK:
printf("e_method=MCBLOCK ");
break;
}
printf("| data_MiB=%f time_s=%f throughput_MiBps=%f\n", mt, te, mt/te);
return;
}
/* ------------------------------------------------------ */
int main(int argc, char **argv)
{
unsigned int long_size=0;
double te, te_sum; /* time elapsed */
unsigned int i;
int o; /* getopt options */
unsigned long testno;
/* options */
/* how many runs to average? */
unsigned int nr_loops=DEFAULT_NR_LOOPS;
/* what tests to run (-t x) */
int tests[MAX_TESTS];
double mt=0; /* MiBytes transferred == array size in MiB */
int quiet=0; /* suppress extra messages */
tests[0]=0;
tests[1]=0;
tests[2]=0;
tests[3]=0;
while((o=getopt(argc, argv, "ha:b:c:qn:N:t:B:")) != EOF) {
switch(o) {
case 'h':
usage();
exit(1);
break;
#ifdef NUMA
case 'a': /* NUMA node */
bitmask_a = numa_parse_nodestring(optarg);
break;
case 'b': /* NUMA node */
bitmask_b = numa_parse_nodestring(optarg);
break;
case 'c': /* NUMA node */
numa_node_cpu = strtoul(optarg, (char **)NULL, 10);
break;
#endif
case 'n': /* no. loops */
nr_loops=strtoul(optarg, (char **)NULL, 10);
break;
#ifdef MULTITHREADED
case 'N': /* no. threads */
num_threads=strtoul(optarg, (char **)NULL, 10);
break;
#endif
case 't': /* test to run */
testno=strtoul(optarg, (char **)NULL, 10);
if(testno>MAX_TESTS-1) {
printf("Error: test number must be between 0 and %d\n", MAX_TESTS-1);
exit(1);
}
tests[testno]=1;
break;
case 'B': /* block size in bytes*/
block_size=strtoull(optarg, (char **)NULL, 10);
if(0>=block_size) {
printf("Error: what block size do you mean?\n");
exit(1);
}
break;
case 'q': /* quiet */
quiet=1;
break;
default:
break;
}
}
/* default is to run all tests if no specific tests were requested */
if( (tests[0]+tests[1]+tests[2]+tests[3]+tests[4]) == 0) {
tests[0]=1;
tests[1]=1;
tests[2]=1;
}
if( nr_loops==0 && ((tests[0]+tests[1]+tests[2]+tests[3]+tests[4]) != 1) ) {
printf("Error: nr_loops can be zero if only one test selected!\n");
exit(1);
}
if(optind<argc) {
mt=strtoul(argv[optind++], (char **)NULL, 10);
} else {
printf("Error: no array size given!\n");
exit(1);
}
if(0>=mt) {
printf("Error: array size wrong!\n");
exit(1);
}
/* ------------------------------------------------------ */
long_size=sizeof(long); /* the size of long on this platform */
arr_size=1024*1024/long_size*mt; /* how many longs then in one array? */
if(arr_size*long_size < block_size) {
printf("Error: array size larger than block size (%llu bytes)!\n", block_size);
exit(1);
}
if(!quiet) {
printf("Long uses %d bytes. ", long_size);
printf("Allocating 2*%lld elements = %lld bytes of memory.\n", arr_size, 2*arr_size*long_size);
if(tests[2]) {
printf("Using %lld bytes as blocks for memcpy block copy test.\n", block_size);
}
}
#ifdef NUMA
struct bitmask *bitmask_all = numa_allocate_nodemask();
numa_bitmask_setall(bitmask_all);
if (bitmask_a) {
numa_set_membind(bitmask_a);
numa_free_nodemask(bitmask_a);
}
#endif
arr_a=make_array();
#ifdef NUMA
if (bitmask_b) {
numa_set_membind(bitmask_b);
numa_free_nodemask(bitmask_b);
}
#endif
arr_b=make_array();
#ifdef NUMA
numa_set_membind(bitmask_all);
numa_free_nodemask(bitmask_all);
#endif
#ifdef NUMA
mp_pages[0] = arr_a;
if (move_pages(0, 1, mp_pages, NULL, mp_status, 0) == -1) {
perror("move_pages(arr_a)");
}
else if (mp_status[0] < 0) {
printf("move_pages error: %d", mp_status[0]);
}
else {
numa_node_a = mp_status[0];
}
mp_pages[0] = arr_b;
if (move_pages(0, 1, mp_pages, NULL, mp_status, 0) == -1) {
perror("move_pages(arr_b)");
}
else if (mp_status[0] < 0) {
printf("move_pages error: %d", mp_status[0]);
}
else {
numa_node_b = mp_status[0];
}
if (numa_node_cpu != -1) {
if (numa_run_on_node(numa_node_cpu) == -1) {
perror("numa_run_on_node");
numa_node_cpu = -1;
}
}
#endif
/* ------------------------------------------------------ */
if(!quiet) {
printf("Getting down to business... Doing %d runs per test.\n", nr_loops);
}
#ifdef MULTITHREADED
if (sem_init(&start_sem, 0, 0) != 0) {
err(1, "sem_init");
}
if (sem_init(&stop_sem, 0, 0) != 0) {
err(1, "sem_init");
}
if (sem_init(&sync_sem, 0, 0) != 0) {
err(1, "sem_init");
}
threads = calloc(num_threads, sizeof(pthread_t));
for (i=0; i < num_threads; i++) {
if (pthread_create(&threads[i], NULL, thread_worker, (void*)(unsigned long)i) != 0) {
err(1, "pthread_create");
}
}
#endif
/* run all tests requested, the proper number of times */
for(test_type=0; test_type<MAX_TESTS; test_type++) {
te_sum=0;
if(tests[test_type]) {
for (i=0; nr_loops==0 || i<nr_loops; i++) {
te=worker();
te_sum+=te;
if (test_type == TEST_MEMCPY) {
printf("[::] memcpy");
} else if (test_type == TEST_PLAIN) {
printf("[::] copy");
} else if (test_type == TEST_MCBLOCK) {
printf("[::] mcblock");
} else if (test_type == TEST_AVX512) {
printf("[::] copy-avx512");
} else if (test_type == TEST_READ_PLAIN) {
printf("[::] read");
}
printf(" | block_size_B=%llu array_size_B=%llu ", block_size, arr_size*long_size);
#ifdef MULTITHREADED
printf("n_threads=%ld ", num_threads);
#else
printf("n_threads=1 ");
#endif
#ifdef NUMA
printf("from_numa_node=%d to_numa_node=%d cpu_numa_node=%d numa_distance_ram_ram=%d numa_distance_ram_cpu=%d numa_distance_cpu_ram=%d ", numa_node_a, numa_node_b, numa_node_cpu, numa_distance(numa_node_a, numa_node_b), numa_distance(numa_node_a, numa_node_cpu), numa_distance(numa_node_cpu, numa_node_b));
#else
printf("from_numa_node=X to_numa_node=X cpu_numa_node=X numa_distance_ram_ram=X numa_distance_ram_cpu=X numa_distance_cpu_ram=X ");
#endif
printout(te, mt);
}
}
}
#ifdef MULTITHREADED
done = 1;
start_threads();
for (i=0; i < num_threads; i++) {
if (pthread_join(threads[i], NULL) != 0) {
err(1, "pthread_join");
}
}
#endif
free(arr_a);
free(arr_b);
return 0;
}
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