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openmpi/orte/test/system/threads.c
Ralph Castain 93cf3c7203 Update OPAL and ORTE for thread safety
(I swear, if I look this over one more time, I'll puke)

Signed-off-by: Ralph Castain <rhc@open-mpi.org>
2017-06-06 12:30:57 -07:00

336 строки
8.6 KiB
C

/*
* Test program for memory consistency in a thread shifting design
*
*
* Run:
* ./threads ITERATIONS [MODE]
* ./threads 9000000 3
*
* Example:
* ./threads 9000000 0 --> Will fail, no memory barriers
* ./threads 9000000 1 --> Will fail, no WMB
* ./threads 9000000 2 --> Will fail, no RMB
* ./threads 9000000 3 --> Success
* ./threads 9000000 4 --> Success
* ./threads 9000000 5 --> N/A
*/
#include <stdio.h>
#include <stdlib.h>
#include <stdbool.h>
#include <string.h>
#include <pthread.h>
#include <stdint.h>
#include <hwloc.h>
#include <sys/time.h>
#include "opal/sys/atomic.h"
// Max value for an int16_t
#define MAX_VAL 32767
typedef struct {
int type;
union {
bool flag;
int integer;
int8_t int8;
int16_t int16;
int32_t int32;
int64_t int64;
//char padding[1];
} data;
} my_value_t;
// Structure to handoff work to the peer thread
typedef struct {
volatile bool working;
void *ptr; // Note that adding a volatile here has no effect
} thread_handoff_t;
// Shared object to handoff work
thread_handoff_t handoff;
// Indicates if the test has finished
bool time_to_stop = false;
// Progress reporting
#define PERC_INC 10.0
double perc_report_after = PERC_INC;
double perc_current = 0.0;
// Memory barrier modes
#define MB_MODE_NONE 0x0
#define MB_MODE_RMB 0x1
#define MB_MODE_WMB 0x2
#define MB_MODE_MB 0x4
#define MB_MODE_XMB 0x8
#define MB_MODE_ALL (MB_MODE_RMB | MB_MODE_WMB)
int mb_mode = MB_MODE_ALL;
// Shared hwloc topology (so we only have to read it once)
static hwloc_topology_t topo;
// Which object we are binding to
// 4 - sockets with 5 cores each
// 20 - cores with 8 PUs each
//#define OBJ_TYPE HWLOC_OBJ_SOCKET
#define OBJ_TYPE HWLOC_OBJ_CORE
/*
* Some basic timing support
*/
double acc_time, start_time, stop_time, delta;
static double get_ts_gettimeofday(void) {
double ret;
struct timeval tv;
gettimeofday(&tv, NULL);
ret = tv.tv_sec;
ret += (double)tv.tv_usec / 1000000.0;
return ret;
}
/*
* Bind either the main or support thread far away from each other
*/
void bind_me_to(bool main_thread);
/*
* Support thread to do the memory allocation and xfer
*/
void *value_xfer_thread(void *arg);
/*
* Main thread
*/
int main(int argc, char **argv) {
pthread_t support_thread;
int rc, i, max_iters = 10, cur_iter;
my_value_t *val = NULL;
int mode;
/*
* Parse command line arguments
*/
if( argc > 1 ) {
max_iters = atoi(argv[1]);
}
if( argc > 2 ) {
mode = atoi(argv[2]);
if( 0 > mode || mode > 5 ) {
printf("Error: Invalid mode %d\n"
"\tNone = 0\n"
"\tRMB = 1\n"
"\tWMB = 2\n"
"\tBoth = 3\n"
"\tMB Only = 4\n",
"\tXMB Only = 5\n",
mode);
exit(-1);
}
}
else {
mode = 3;
}
switch(mode) {
case 0:
mb_mode = MB_MODE_NONE;
break;
case 1:
mb_mode = MB_MODE_RMB;
break;
case 2:
mb_mode = MB_MODE_WMB;
break;
case 3:
mb_mode = MB_MODE_ALL;
break;
case 4:
mb_mode = MB_MODE_MB;
break;
case 5:
mb_mode = MB_MODE_XMB;
break;
}
// Load hwloc topology
hwloc_topology_init(&topo);
hwloc_topology_load(topo);
// Display banner
printf("---------------------------\n");
printf("Iterations: %10d\n", max_iters);
printf("Mode R MB : %10s\n", (mb_mode & MB_MODE_RMB ? "Enabled" : "Disabled") );
printf("Mode W MB : %10s\n", (mb_mode & MB_MODE_WMB ? "Enabled" : "Disabled") );
printf("Mode - MB : %10s\n", (mb_mode & MB_MODE_MB ? "Enabled" : "Disabled") );
printf("Mode X MB : %10s\n", (mb_mode & MB_MODE_XMB ? "Enabled" : "Disabled") );
printf("---------------------------\n");
bind_me_to(true);
handoff.working = false;
/*
* Launch supporting thread
*/
rc = pthread_create(&support_thread, NULL, value_xfer_thread, NULL);
if( 0 != rc ) {
printf("Error: Failed to create a thread! %d\n", rc);
exit(-1);
}
/*
* Main work loop
*/
acc_time = 0.0;
for(cur_iter = 0; cur_iter < max_iters; ++cur_iter) {
perc_current = (cur_iter / ((double)max_iters)) * 100.0;
if( perc_current > perc_report_after ) {
delta = (acc_time / cur_iter) * 1000000;
printf("%6.1f %% complete : Iteration %10d / %10d : %6.1f usec / iter\n",
perc_current, cur_iter+1, max_iters, delta);
perc_report_after += PERC_INC;
}
start_time = get_ts_gettimeofday();
// Initialize values
val = NULL;
handoff.ptr = &val;
if( mb_mode & MB_MODE_RMB ) {
opal_atomic_rmb();
}
if( mb_mode & MB_MODE_MB ) {
opal_atomic_mb();
}
handoff.working = true;
// Wait for work to finish
while( handoff.working ) {
usleep(1);
}
if( mb_mode & MB_MODE_WMB ) {
opal_atomic_wmb();
}
if( mb_mode & MB_MODE_MB ) {
opal_atomic_mb();
}
// Inspect values for correctness
if( NULL == val ) {
printf("[%10d / %10d] Error: val = %s\n", cur_iter+1, max_iters,
(NULL == val ? "NULL" : "Valid") );
exit(-1);
}
else if( 999 != val->type ) {
printf("[%10d / %10d] Error: val->type = %d\n", cur_iter+1, max_iters, val->type);
exit(-1);
}
else if( (cur_iter+1)%MAX_VAL != val->data.int16 ) {
printf("[%10d / %10d] Error: val->data.int16 = %d\n", cur_iter+1, max_iters, val->data.int16);
exit(-1);
}
stop_time = get_ts_gettimeofday();
acc_time += (stop_time - start_time);
// Yes, this is a memory leak!
// I need to make sure that the supporting thread is not reusing a
// previous storage location when it calls malloc. This is to emulate
// a program that calls malloc after the value was acquired, possibly
// reusing this memory location.
//free(val);
val = NULL;
}
delta = (acc_time / max_iters) * 1000000;
/*
* All done - Cleanup
*/
time_to_stop = true;
rc = pthread_join(support_thread, NULL);
if( 0 != rc ) {
printf("Error: Failed to join a thread! %d\n", rc);
exit(-1);
}
hwloc_topology_destroy(topo);
printf("Success - %6.1f usec / iter\n", delta);
return 0;
}
void *value_xfer_thread(void *arg) {
my_value_t **val = NULL;
static int var = 0;
// Bind this thread away from the main thread
bind_me_to(false);
while( !time_to_stop ) {
if( handoff.working ) {
// Make sure I have the right pointer
if( mb_mode & MB_MODE_WMB ) {
opal_atomic_wmb();
}
if( mb_mode & MB_MODE_MB ) {
opal_atomic_mb();
}
// Allocate and set the value
val = (my_value_t**)handoff.ptr;
(*val) = malloc(sizeof(my_value_t));
(*val)->type = 999;
(*val)->data.int16 = (++var)%MAX_VAL;
// Make sure main thread can see the value
// See 'Examples' -> 'Global thread flag' discussion here:
// https://www.ibm.com/developerworks/systems/articles/powerpc.html
if( mb_mode & MB_MODE_RMB ) {
opal_atomic_rmb();
}
if( mb_mode & MB_MODE_MB ) {
opal_atomic_mb();
}
// Release main thread
handoff.working = false;
}
else {
// wait for work
usleep(1);
}
}
pthread_exit(NULL);
}
void bind_me_to(bool main_thread) {
int num_objs;
hwloc_cpuset_t set;
char *buffer = NULL;
hwloc_obj_t obj;
num_objs = hwloc_get_nbobjs_by_type(topo, OBJ_TYPE);
if( main_thread ) {
obj = hwloc_get_obj_by_type(topo, OBJ_TYPE, 0);
}
else {
obj = hwloc_get_obj_by_type(topo, OBJ_TYPE, num_objs-1);
}
if( obj->type == OBJ_TYPE ) {
hwloc_set_cpubind(topo, obj->cpuset, HWLOC_CPUBIND_THREAD);
}
else {
printf("Error: Invalid object\n");
exit(-1);
}
set = hwloc_bitmap_alloc();
hwloc_get_cpubind(topo, set, HWLOC_CPUBIND_THREAD);
hwloc_bitmap_asprintf(&buffer, set);
printf("%s : [objs = %d] : cpuset is %s\n", (main_thread ? "Main" : "Peer"), num_objs, buffer);
free(buffer);
hwloc_bitmap_free(set);
}