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test_simple.c
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test_simple.c
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/*
* File: test_simple.c
* Author: Vasileios Trigonakis <vasileios.trigonakis@epfl.ch>
* Description:
* test_simple.c is part of ASCYLIB
*
* Copyright (c) 2014 Vasileios Trigonakis <vasileios.trigonakis@epfl.ch>,
* Tudor David <tudor.david@epfl.ch>
* Distributed Programming Lab (LPD), EPFL
*
* ASCYLIB is free software: you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation, version 2
* of the License.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
*/
#include <assert.h>
#include <getopt.h>
#include <limits.h>
#include <pthread.h>
#include <signal.h>
#include <stdlib.h>
#include <stdio.h>
#include <sys/time.h>
#include <time.h>
#include <stdlib.h>
#include <stdio.h>
#include <errno.h>
#include <string.h>
#include <sched.h>
#include <inttypes.h>
#include <sys/time.h>
#include <unistd.h>
#include <malloc.h>
#include "utils.h"
#include "atomic_ops.h"
#include "rapl_read.h"
#ifdef __sparc__
# include <sys/types.h>
# include <sys/processor.h>
# include <sys/procset.h>
#endif
#include "intset.h"
/* ################################################################### *
* Definition of macros: per data structure
* ################################################################### */
#define DS_CONTAINS(s,k,t) queue_contains(s, k)
#define DS_ADD(s,k,t) queue_add(s, k, t)
#define DS_REMOVE(s) queue_remove(s)
#define DS_SIZE(s) queue_size(s)
#define DS_NEW() queue_new()
#define DS_TYPE queue_t
#define DS_NODE queue_node_t
/* ################################################################### *
* GLOBALS
* ################################################################### */
RETRY_STATS_VARS_GLOBAL;
size_t initial = DEFAULT_INITIAL;
size_t range = DEFAULT_RANGE;
size_t update = 100;
size_t load_factor;
size_t num_threads = DEFAULT_NB_THREADS;
size_t duration = DEFAULT_DURATION;
size_t print_vals_num = 100;
size_t pf_vals_num = 1023;
size_t put, put_explicit = false;
double update_rate, put_rate, get_rate;
size_t size_after = 0;
int seed = 0;
__thread unsigned long * seeds;
uint32_t rand_max;
#define rand_min 1
static volatile int stop;
TEST_VARS_GLOBAL;
volatile ticks *putting_succ;
volatile ticks *putting_fail;
volatile ticks *getting_succ;
volatile ticks *getting_fail;
volatile ticks *removing_succ;
volatile ticks *removing_fail;
volatile ticks *putting_count;
volatile ticks *putting_count_succ;
volatile ticks *getting_count;
volatile ticks *getting_count_succ;
volatile ticks *removing_count;
volatile ticks *removing_count_succ;
volatile ticks *total;
/* ################################################################### *
* LOCALS
* ################################################################### */
#ifdef DEBUG
extern __thread uint32_t put_num_restarts;
extern __thread uint32_t put_num_failed_expand;
extern __thread uint32_t put_num_failed_on_new;
#endif
barrier_t barrier, barrier_global;
typedef struct thread_data
{
uint32_t id;
DS_TYPE* set;
} thread_data_t;
void*
test(void* thread)
{
thread_data_t* td = (thread_data_t*) thread;
uint32_t ID = td->id;
set_cpu(ID);
ssalloc_init();
DS_TYPE* set = td->set;
THREAD_INIT(ID);
PF_INIT(3, SSPFD_NUM_ENTRIES, ID);
#if defined(COMPUTE_LATENCY)
volatile ticks my_putting_succ = 0;
volatile ticks my_putting_fail = 0;
volatile ticks my_getting_succ = 0;
volatile ticks my_getting_fail = 0;
volatile ticks my_removing_succ = 0;
volatile ticks my_removing_fail = 0;
#endif
uint64_t my_putting_count = 0;
uint64_t my_getting_count = 0;
uint64_t my_removing_count = 0;
uint64_t my_putting_count_succ = 0;
uint64_t my_getting_count_succ = 0;
uint64_t my_removing_count_succ = 0;
#if defined(COMPUTE_LATENCY) && PFD_TYPE == 0
volatile ticks start_acq, end_acq;
volatile ticks correction = getticks_correction_calc();
#endif
seeds = seed_rand();
#if GC == 1
alloc = (ssmem_allocator_t*) malloc(sizeof(ssmem_allocator_t));
assert(alloc != NULL);
ssmem_alloc_init_fs_size(alloc, SSMEM_DEFAULT_MEM_SIZE, SSMEM_GC_FREE_SET_SIZE, ID);
#endif
RR_INIT(phys_id);
barrier_cross(&barrier);
uint64_t key;
int c = 0;
uint32_t scale_rem = (uint32_t) (update_rate * UINT_MAX);
uint32_t scale_put = (uint32_t) (put_rate * UINT_MAX);
int i;
uint32_t num_elems_thread = (uint32_t) (initial / num_threads);
int32_t missing = (uint32_t) initial - (num_elems_thread * num_threads);
if (ID < missing)
{
num_elems_thread++;
}
#if INITIALIZE_FROM_ONE == 1
num_elems_thread = (ID == 0) * initial;
#endif
for(i = 0; i < num_elems_thread; i++)
{
key = (my_random(&(seeds[0]), &(seeds[1]), &(seeds[2])) % (rand_max + 1)) + rand_min;
if(DS_ADD(set, key, key) == false)
{
i--;
}
}
MEM_BARRIER;
barrier_cross(&barrier);
if (!ID)
{
printf("#BEFORE size is: %zu\n", (size_t) DS_SIZE(set));
}
RETRY_STATS_ZERO();
barrier_cross(&barrier_global);
RR_START_SIMPLE();
while (stop == 0)
{
TEST_LOOP_ONLY_UPDATES();
}
barrier_cross(&barrier);
RR_STOP_SIMPLE();
if (!ID)
{
size_after = DS_SIZE(set);
printf("#AFTER size is: %zu\n", size_after);
}
barrier_cross(&barrier);
#if defined(COMPUTE_LATENCY)
putting_succ[ID] += my_putting_succ;
putting_fail[ID] += my_putting_fail;
getting_succ[ID] += my_getting_succ;
getting_fail[ID] += my_getting_fail;
removing_succ[ID] += my_removing_succ;
removing_fail[ID] += my_removing_fail;
#endif
putting_count[ID] += my_putting_count;
getting_count[ID] += my_getting_count;
removing_count[ID]+= my_removing_count;
putting_count_succ[ID] += my_putting_count_succ;
getting_count_succ[ID] += my_getting_count_succ;
removing_count_succ[ID]+= my_removing_count_succ;
EXEC_IN_DEC_ID_ORDER(ID, num_threads)
{
print_latency_stats(ID, SSPFD_NUM_ENTRIES, print_vals_num);
RETRY_STATS_SHARE();
}
EXEC_IN_DEC_ID_ORDER_END(&barrier);
SSPFDTERM();
#if GC == 1
ssmem_term();
free(alloc);
#endif
THREAD_END();
pthread_exit(NULL);
}
int
main(int argc, char **argv)
{
set_cpu(0);
ssalloc_init();
seeds = seed_rand();
struct option long_options[] = {
// These options don't set a flag
{"help", no_argument, NULL, 'h'},
{"duration", required_argument, NULL, 'd'},
{"initial-size", required_argument, NULL, 'i'},
{"num-threads", required_argument, NULL, 'n'},
{"range", required_argument, NULL, 'r'},
{"update-rate", required_argument, NULL, 'u'},
{"num-buckets", required_argument, NULL, 'b'},
{"print-vals", required_argument, NULL, 'v'},
{"vals-pf", required_argument, NULL, 'f'},
{NULL, 0, NULL, 0}
};
int i, c;
while(1)
{
i = 0;
c = getopt_long(argc, argv, "hAf:d:i:n:r:s:u:m:a:l:p:b:v:f:", long_options, &i);
if(c == -1)
break;
if(c == 0 && long_options[i].flag == 0)
c = long_options[i].val;
switch(c)
{
case 0:
/* Flag is automatically set */
break;
case 'h':
printf("ASCYLIB -- stress test "
"\n"
"\n"
"Usage:\n"
" %s [options...]\n"
"\n"
"Options:\n"
" -h, --help\n"
" Print this message\n"
" -d, --duration <int>\n"
" Test duration in milliseconds\n"
" -i, --initial-size <int>\n"
" Number of elements to insert before test\n"
" -n, --num-threads <int>\n"
" Number of threads\n"
" -r, --range <int>\n"
" Range of integer values inserted in set\n"
" -u, --update-rate <int>\n"
" Percentage of update transactions\n"
" -p, --put-rate <int>\n"
" Percentage of put update transactions (should be less than percentage of updates)\n"
" -b, --num-buckets <int>\n"
" Number of initial buckets (stronger than -l)\n"
" -v, --print-vals <int>\n"
" When using detailed profiling, how many values to print.\n"
" -f, --val-pf <int>\n"
" When using detailed profiling, how many values to keep track of.\n"
, argv[0]);
exit(0);
case 'd':
duration = atoi(optarg);
break;
case 'i':
initial = atoi(optarg);
break;
case 'n':
num_threads = atoi(optarg);
break;
case 'r':
range = atol(optarg);
break;
case 'u':
update = atoi(optarg);
break;
case 'p':
put_explicit = 1;
put = atoi(optarg);
break;
case 'l':
load_factor = atoi(optarg);
break;
case 'v':
print_vals_num = atoi(optarg);
break;
case 'f':
pf_vals_num = pow2roundup(atoi(optarg)) - 1;
break;
case '?':
default:
printf("Use -h or --help for help\n");
exit(1);
}
}
if (!is_power_of_two(initial))
{
size_t initial_pow2 = pow2roundup(initial);
printf("** rounding up initial (to make it power of 2): old: %zu / new: %zu\n", initial, initial_pow2);
initial = initial_pow2;
}
if (range < initial)
{
range = 2 * initial;
}
printf("## Initial: %zu / Range: %zu / ", initial, range);
printf("OPTIK algorithm\n");
double kb = initial * sizeof(DS_NODE) / 1024.0;
double mb = kb / 1024.0;
printf("Sizeof initial: %.2f KB = %.2f MB\n", kb, mb);
if (!is_power_of_two(range))
{
size_t range_pow2 = pow2roundup(range);
printf("** rounding up range (to make it power of 2): old: %zu / new: %zu\n", range, range_pow2);
range = range_pow2;
}
if (put > update)
{
put = update;
}
update_rate = update / 100.0;
if (put_explicit)
{
put_rate = put / 100.0;
}
else
{
put_rate = update_rate / 2;
}
get_rate = 1 - update_rate;
/* printf("num_threads = %u\n", num_threads); */
/* printf("cap: = %u\n", num_buckets); */
/* printf("num elem = %u\n", num_elements); */
/* printf("filing rate= %f\n", filling_rate); */
/* printf("update = %f (putting = %f)\n", update_rate, put_rate); */
rand_max = range - 1;
struct timeval start, end;
struct timespec timeout;
timeout.tv_sec = duration / 1000;
timeout.tv_nsec = (duration % 1000) * 1000000;
stop = 0;
DS_TYPE* set = DS_NEW();
assert(set != NULL);
/* Initializes the local data */
putting_succ = (ticks *) calloc(num_threads , sizeof(ticks));
putting_fail = (ticks *) calloc(num_threads , sizeof(ticks));
getting_succ = (ticks *) calloc(num_threads , sizeof(ticks));
getting_fail = (ticks *) calloc(num_threads , sizeof(ticks));
removing_succ = (ticks *) calloc(num_threads , sizeof(ticks));
removing_fail = (ticks *) calloc(num_threads , sizeof(ticks));
putting_count = (ticks *) calloc(num_threads , sizeof(ticks));
putting_count_succ = (ticks *) calloc(num_threads , sizeof(ticks));
getting_count = (ticks *) calloc(num_threads , sizeof(ticks));
getting_count_succ = (ticks *) calloc(num_threads , sizeof(ticks));
removing_count = (ticks *) calloc(num_threads , sizeof(ticks));
removing_count_succ = (ticks *) calloc(num_threads , sizeof(ticks));
pthread_t threads[num_threads];
pthread_attr_t attr;
int rc;
void *status;
barrier_init(&barrier_global, num_threads + 1);
barrier_init(&barrier, num_threads);
/* Initialize and set thread detached attribute */
pthread_attr_init(&attr);
pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE);
thread_data_t* tds = (thread_data_t*) malloc(num_threads * sizeof(thread_data_t));
long t;
for(t = 0; t < num_threads; t++)
{
tds[t].id = t;
tds[t].set = set;
rc = pthread_create(&threads[t], &attr, test, tds + t);
if (rc)
{
printf("ERROR; return code from pthread_create() is %d\n", rc);
exit(-1);
}
}
/* Free attribute and wait for the other threads */
pthread_attr_destroy(&attr);
barrier_cross(&barrier_global);
gettimeofday(&start, NULL);
nanosleep(&timeout, NULL);
stop = 1;
gettimeofday(&end, NULL);
duration = (end.tv_sec * 1000 + end.tv_usec / 1000) - (start.tv_sec * 1000 + start.tv_usec / 1000);
for(t = 0; t < num_threads; t++)
{
rc = pthread_join(threads[t], &status);
if (rc)
{
printf("ERROR; return code from pthread_join() is %d\n", rc);
exit(-1);
}
}
free(tds);
volatile ticks putting_suc_total = 0;
volatile ticks putting_fal_total = 0;
volatile ticks getting_suc_total = 0;
volatile ticks getting_fal_total = 0;
volatile ticks removing_suc_total = 0;
volatile ticks removing_fal_total = 0;
volatile uint64_t putting_count_total = 0;
volatile uint64_t putting_count_total_succ = 0;
volatile uint64_t getting_count_total = 0;
volatile uint64_t getting_count_total_succ = 0;
volatile uint64_t removing_count_total = 0;
volatile uint64_t removing_count_total_succ = 0;
for(t=0; t < num_threads; t++)
{
PRINT_OPS_PER_THREAD();
putting_suc_total += putting_succ[t];
putting_fal_total += putting_fail[t];
getting_suc_total += getting_succ[t];
getting_fal_total += getting_fail[t];
removing_suc_total += removing_succ[t];
removing_fal_total += removing_fail[t];
putting_count_total += putting_count[t];
putting_count_total_succ += putting_count_succ[t];
getting_count_total += getting_count[t];
getting_count_total_succ += getting_count_succ[t];
removing_count_total += removing_count[t];
removing_count_total_succ += removing_count_succ[t];
}
#if defined(COMPUTE_LATENCY)
printf("#thread srch_suc srch_fal insr_suc insr_fal remv_suc remv_fal ## latency (in cycles) \n"); fflush(stdout);
long unsigned get_suc = (getting_count_total_succ) ? getting_suc_total / getting_count_total_succ : 0;
long unsigned get_fal = (getting_count_total - getting_count_total_succ) ? getting_fal_total / (getting_count_total - getting_count_total_succ) : 0;
long unsigned put_suc = putting_count_total_succ ? putting_suc_total / putting_count_total_succ : 0;
long unsigned put_fal = (putting_count_total - putting_count_total_succ) ? putting_fal_total / (putting_count_total - putting_count_total_succ) : 0;
long unsigned rem_suc = removing_count_total_succ ? removing_suc_total / removing_count_total_succ : 0;
long unsigned rem_fal = (removing_count_total - removing_count_total_succ) ? removing_fal_total / (removing_count_total - removing_count_total_succ) : 0;
printf("%-7zu %-8lu %-8lu %-8lu %-8lu %-8lu %-8lu\n", num_threads, get_suc, get_fal, put_suc, put_fal, rem_suc, rem_fal);
#endif
#define LLU long long unsigned int
int UNUSED pr = (int) (putting_count_total_succ - removing_count_total_succ);
if (size_after != (initial + pr))
{
printf("// WRONG size. %zu + %d != %zu\n", initial, pr, size_after);
assert(size_after == (initial + pr));
}
printf(" : %-10s | %-10s | %-11s | %-11s | %s\n", "total", "success", "succ %", "total %", "effective %");
uint64_t total = putting_count_total + getting_count_total + removing_count_total;
double putting_perc = 100.0 * (1 - ((double)(total - putting_count_total) / total));
double putting_perc_succ = (1 - (double) (putting_count_total - putting_count_total_succ) / putting_count_total) * 100;
double getting_perc = 100.0 * (1 - ((double)(total - getting_count_total) / total));
double getting_perc_succ = (1 - (double) (getting_count_total - getting_count_total_succ) / getting_count_total) * 100;
double removing_perc = 100.0 * (1 - ((double)(total - removing_count_total) / total));
double removing_perc_succ = (1 - (double) (removing_count_total - removing_count_total_succ) / removing_count_total) * 100;
printf("srch: %-10llu | %-10llu | %10.1f%% | %10.1f%% | \n", (LLU) getting_count_total,
(LLU) getting_count_total_succ, getting_perc_succ, getting_perc);
printf("insr: %-10llu | %-10llu | %10.1f%% | %10.1f%% | %10.1f%%\n", (LLU) putting_count_total,
(LLU) putting_count_total_succ, putting_perc_succ, putting_perc, (putting_perc * putting_perc_succ) / 100);
printf("rems: %-10llu | %-10llu | %10.1f%% | %10.1f%% | %10.1f%%\n", (LLU) removing_count_total,
(LLU) removing_count_total_succ, removing_perc_succ, removing_perc, (removing_perc * removing_perc_succ) / 100);
double throughput = (putting_count_total + getting_count_total + removing_count_total) * 1000.0 / duration;
printf("#txs %zu\t(%-10.0f\n", num_threads, throughput);
printf("#Mops %.3f\n", throughput / 1e6);
RR_PRINT_UNPROTECTED(RAPL_PRINT_POW);
RR_PRINT_CORRECTED();
RETRY_STATS_PRINT(total, putting_count_total, removing_count_total, putting_count_total_succ + removing_count_total_succ);
LATENCY_DISTRIBUTION_PRINT();
pthread_exit(NULL);
return 0;
}