/*
* Copyright (c) 2004-2005 The Trustees of Indiana University and Indiana
* University Research and Technology
* Corporation. All rights reserved.
* Copyright (c) 2004-2005 The University of Tennessee and The University
* of Tennessee Research Foundation. All rights
* reserved.
* Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
* University of Stuttgart. All rights reserved.
* Copyright (c) 2004-2005 The Regents of the University of California.
* All rights reserved.
* Copyright (c) 2006 Cisco Systems, Inc. All rights reserved.
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*/
#include "ompi_config.h"
#ifdef HAVE_STDINT_H
#include <stdint.h>
#endif
#ifdef HAVE_SYS_TIME_H
#include <sys/time.h>
#else
#include <sys/_time.h>
#endif
#include <string.h>
#include "support.h"
#include "ompi/class/ompi_free_list.h"
#include "ompi/class/ompi_rb_tree.h"
#include "ompi/mca/mpool/base/base.h"
#define NUM_KEYS 10000
#define SEED 1
int keys[] = {
0, 1, 2, 3, 4, 5, 6, 7
};
int values[] = {
10, 11, 12, 13, 14, 15, 16, 17
};
int comp_fn(void * ele1, void * ele2);
void test1(void);
int comp_fn(void * ele1, void * ele2)
{
if(*((int *) ele1) > *((int *) ele2)) {
return(1);
}
if(*((int *) ele1) < *((int *) ele2)) {
return(-1);
}
return(0);
}
struct my_key_t{
void *base;
void *bound;
}; typedef struct my_key_t my_key_t;
struct my_val_t{
my_key_t* key;
int val;
}; typedef struct my_val_t my_val_t;
int comp_key(void* key1, void* key2) {
if( ((my_key_t*) key1)->base <
((my_key_t*) key2)->base) {
return -1;
}
else if ( ((my_key_t*) key1)->base >
((my_key_t*) key2)->bound) {
return 1;
}
else {
return 0;
}
}
void test_keys(void)
{
ompi_rb_tree_t tree;
int rc, i, *result;
my_key_t keys[NUM_KEYS];
my_val_t vals[NUM_KEYS];
char buf[200];
my_key_t *cur_key;
my_val_t *cur_val;
long tmp;
OBJ_CONSTRUCT(&tree, ompi_rb_tree_t);
rc = ompi_rb_tree_init(&tree, comp_key);
srand(SEED);
for(i = 0; i < NUM_KEYS; i++) {
cur_key = &(keys[i]);
cur_val = &(vals[i]);
cur_val->key = cur_key;
cur_val->val = i;
tmp = (long) rand();
cur_key->base = (void*) tmp;
tmp += (long) rand();
cur_key->bound = (void*) tmp;
rc = ompi_rb_tree_insert(&tree, cur_key, cur_val);
if(OMPI_SUCCESS != rc) {
test_failure("error inserting element in the tree");
}
}
for(i = 0; i < NUM_KEYS; i+=2) {
cur_key = &(keys[i]);
rc = ompi_rb_tree_delete(&tree, cur_key);
if(OMPI_SUCCESS != rc) {
test_failure("error deleting element in the tree");
}
}
for(i = 1; i < NUM_KEYS; i+=2) {
cur_key = &(keys[i]);
cur_val = (my_val_t*) ompi_rb_tree_find(&tree, cur_key);
if(cur_val == NULL) {
test_failure("lookup returned NULL item");
}
else if(cur_val->val != i && (cur_val->key->base > cur_key->base ||
cur_val->key->bound < cur_key->base)) {
sprintf(buf, "lookup returned invalid item, returned %d, extected %d",
cur_val->val, i);
test_failure(buf);
}
}
}
void test1(void)
{
ompi_rb_tree_t tree;
int rc;
void * result;
OBJ_CONSTRUCT(&tree, ompi_rb_tree_t);
rc = ompi_rb_tree_init(&tree, comp_fn);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly initialize the tree");
}
rc = ompi_rb_tree_insert(&tree, &keys[0], &values[0]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[0]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[0], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[1], &values[1]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[1]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[1], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[2], &values[2]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[2]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[2], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[3], &values[3]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[3]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[3], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[4], &values[4]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[4]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[4], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[5], &values[5]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[5]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[5], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[6], &values[6]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[6]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[6], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[7], &values[7]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[7]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[7], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_size(&tree);
if(!test_verify_int(8, rc)) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_delete(&tree, &keys[0]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly delete a node");
}
result = ompi_rb_tree_find(&tree, &keys[0]);
if(NULL != result) {
test_failure("lookup returned a value instead of null!");
} else {
test_success();
}
OBJ_DESTRUCT(&tree);
}
/* the following test is based on memory lookups in the mpool */
int mem_node_compare(void * key1, void * key2);
void test2(void);
/* the maximum number of memory pools a piece of memory can be registered with */
#define MAX_REGISTRATIONS 10
/* the number of memory segments to allocate */
#define NUM_ALLOCATIONS 500
struct ompi_test_rb_key_t
{
void * bottom; /* the bottom of the memory range */
void * top; /* the top of the memory range */
};
typedef struct ompi_test_rb_key_t ompi_test_rb_key_t;
struct ompi_test_rb_value_t
{
ompi_free_list_item_t super; /* the parent class */
ompi_test_rb_key_t key; /* the key which holds the memory pointers */
mca_mpool_base_module_t* registered_mpools[MAX_REGISTRATIONS];
/* the mpools the memory is registered with */
};
typedef struct ompi_test_rb_value_t ompi_test_rb_value_t;
OBJ_CLASS_INSTANCE(ompi_test_rb_value_t, ompi_free_list_item_t, NULL, NULL);
int mem_node_compare(void * key1, void * key2)
{
if(((ompi_test_rb_key_t *) key1)->bottom <
((ompi_test_rb_key_t *) key2)->bottom)
{
return -1;
}
else if(((ompi_test_rb_key_t *) key1)->bottom >
((ompi_test_rb_key_t *) key2)->top)
{
return 1;
}
return 0;
}
void test2(void)
{
ompi_free_list_t key_list;
ompi_free_list_item_t * new_value;
ompi_rb_tree_t tree;
int rc, i, size;
void * result, * lookup;
void * mem[NUM_ALLOCATIONS];
ompi_free_list_item_t * key_array[NUM_ALLOCATIONS];
struct timeval start, end;
OBJ_CONSTRUCT(&key_list, ompi_free_list_t);
ompi_free_list_init(&key_list, sizeof(ompi_test_rb_value_t),
OBJ_CLASS(ompi_test_rb_value_t), 0, -1 , 128, NULL);
OBJ_CONSTRUCT(&tree, ompi_rb_tree_t);
rc = ompi_rb_tree_init(&tree, mem_node_compare);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly initialize the tree");
}
size = 1;
for(i = 0; i < NUM_ALLOCATIONS; i++)
{
mem[i] = malloc(size);
if(NULL == mem[i])
{
test_failure("system out of memory");
return;
}
OMPI_FREE_LIST_GET(&key_list, new_value, rc);
if(OMPI_SUCCESS != rc)
{
test_failure("failed to get memory from free list");
}
key_array[i] = new_value;
((ompi_test_rb_value_t *) new_value)->key.bottom = mem[i];
((ompi_test_rb_value_t *) new_value)->key.top =
(void *) ((size_t) mem[i] + size - 1);
((ompi_test_rb_value_t *) new_value)->registered_mpools[0] = (void *) i;
rc = ompi_rb_tree_insert(&tree, &((ompi_test_rb_value_t *)new_value)->key,
new_value);
if(OMPI_SUCCESS != rc)
{
test_failure("failed to properly insert a new node");
}
size += 1;
}
gettimeofday(&start, NULL);
for(i = 0; i < NUM_ALLOCATIONS; i++)
{
lookup = (void *) ((size_t) mem[i] + i);
result = ompi_rb_tree_find(&tree, &lookup);
if(NULL == result)
{
test_failure("lookup returned null!");
} else if(i != ((int) ((ompi_test_rb_value_t *) result)->registered_mpools[0]))
{
test_failure("lookup returned wrong node!");
}
result = ompi_rb_tree_find(&tree, &lookup);
if(NULL == result)
{
test_failure("lookup returned null!");
} else if(i != ((int) ((ompi_test_rb_value_t *) result)->registered_mpools[0]))
{
test_failure("lookup returned wrong node!");
}
}
gettimeofday(&end, NULL);
#if 0
i = (end.tv_sec - start.tv_sec) * 1000000 + (end.tv_usec - start.tv_usec);
printf("In a %d node tree, %d lookups took %f microseonds each\n",
NUM_ALLOCATIONS, NUM_ALLOCATIONS * 2,
(float) i / (float) (NUM_ALLOCATIONS * 2));
#endif
for(i = 0; i < NUM_ALLOCATIONS; i++)
{
if(NULL != mem[i])
{
free(mem[i]);
}
OMPI_FREE_LIST_RETURN(&(key_list), key_array[i]);
}
OBJ_DESTRUCT(&tree);
OBJ_DESTRUCT(&key_list);
}
int main(int argc, char **argv)
{
test_init("ompi_rb_tree_t");
test1();
test2();
/* test_keys(); */
return test_finalize();
}
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