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/*
* Copyright (C) Igor Sysoev
* Copyright (C) NGINX, Inc.
*/
#include <nxt_main.h>
#include "nxt_tests.h"
#include "nxt_rbtree1.h"
#define nxt_rbtree1_is_empty(tree) \
(((tree)->root) == (tree)->sentinel)
#define nxt_rbtree1_is_there_successor(tree, node) \
((node) != (tree)->sentinel)
nxt_inline nxt_rbtree1_node_t *
nxt_rbtree1_node_successor(nxt_rbtree1_t *tree, nxt_rbtree1_node_t *node)
{
nxt_rbtree1_node_t *parent;
if (node->right != tree->sentinel) {
return nxt_rbtree1_min(node->right, tree->sentinel);
}
for ( ;; ) {
parent = node->parent;
if (parent == NULL) {
return tree->sentinel;
}
if (node == parent->left) {
return parent;
}
node = parent;
}
}
static void nxt_rbtree1_test_insert_value(nxt_rbtree1_node_t *temp,
nxt_rbtree1_node_t *node, nxt_rbtree1_node_t *sentinel);
static nxt_int_t nxt_rbtree1_test_compare(nxt_rbtree1_node_t *node1,
nxt_rbtree1_node_t *node2);
static int nxt_cdecl nxt_rbtree1_test_sort_cmp(const void *one,
const void *two);
static nxt_rbtree1_node_t *nxt_rbtree1_test_find(nxt_rbtree1_t *tree,
nxt_rbtree1_node_t *node);
nxt_int_t
nxt_rbtree1_test(nxt_thread_t *thr, nxt_uint_t n)
{
uint32_t key, *keys;
nxt_uint_t i;
nxt_nsec_t start, end;
nxt_rbtree1_t tree;
nxt_rbtree1_node_t *node, *nodes, sentinel;
nxt_thread_time_update(thr);
nxt_log_error(NXT_LOG_NOTICE, thr->log, "rbtree1 test started: %ui", n);
nxt_rbtree1_init(&tree, &sentinel, nxt_rbtree1_test_insert_value);
nodes = nxt_malloc(n * sizeof(nxt_rbtree1_node_t));
if (nodes == NULL) {
return NXT_ERROR;
}
keys = nxt_malloc(n * sizeof(uint32_t));
if (keys == NULL) {
nxt_free(keys);
return NXT_ERROR;
}
key = 0;
for (i = 0; i < n; i++) {
key = nxt_murmur_hash2(&key, sizeof(uint32_t));
keys[i] = key;
nodes[i].key = key;
}
nxt_qsort(keys, n, sizeof(uint32_t), nxt_rbtree1_test_sort_cmp);
nxt_thread_time_update(thr);
start = nxt_thread_monotonic_time(thr);
for (i = 0; i < n; i++) {
nxt_rbtree1_insert(&tree, &nodes[i]);
}
for (i = 0; i < n; i++) {
if (nxt_rbtree1_test_find(&tree, &nodes[i]) != &nodes[i]) {
nxt_log_alert(thr->log, "rbtree1 test failed: %08XD not found",
nodes[i].key);
goto fail;
}
}
i = 0;
node = nxt_rbtree1_min(tree.root, tree.sentinel);
while (nxt_rbtree1_is_there_successor(&tree, node)) {
if (keys[i] != node->key) {
nxt_log_alert(thr->log, "rbtree1 test failed: %i: %08XD %08XD",
i, keys[i], node->key);
goto fail;
}
i++;
node = nxt_rbtree1_node_successor(&tree, node);
}
if (i != n) {
nxt_log_alert(thr->log, "rbtree1 test failed: %ui", i);
goto fail;
}
for (i = 0; i < n; i++) {
nxt_rbtree1_delete(&tree, &nodes[i]);
nxt_memset(&nodes[i], 0xA5, sizeof(nxt_rbtree1_node_t));
}
nxt_thread_time_update(thr);
end = nxt_thread_monotonic_time(thr);
if (!nxt_rbtree1_is_empty(&tree)) {
nxt_log_alert(thr->log, "rbtree1 test failed: tree is not empty");
goto fail;
}
nxt_free(keys);
nxt_free(nodes);
nxt_log_error(NXT_LOG_NOTICE, thr->log, "rbtree1 test passed %0.3fs",
(end - start) / 1000000000.0);
return NXT_OK;
fail:
nxt_free(keys);
nxt_free(nodes);
return NXT_ERROR;
}
static void
nxt_rbtree1_test_insert_value(nxt_rbtree1_node_t *temp,
nxt_rbtree1_node_t *node, nxt_rbtree1_node_t *sentinel)
{
nxt_rbtree1_node_t **p;
for ( ;; ) {
nxt_prefetch(temp->left);
nxt_prefetch(temp->right);
p = (node->key < temp->key) ? &temp->left : &temp->right;
if (*p == sentinel) {
break;
}
temp = *p;
}
*p = node;
node->parent = temp;
node->left = sentinel;
node->right = sentinel;
nxt_rbtree1_red(node);
}
/*
* Subtraction cannot be used in these comparison functions because the key
* values are spread uniform in whole 0 .. 2^32 range but are not grouped
* around some value as timeout values are.
*/
nxt_inline nxt_int_t
nxt_rbtree1_test_compare(nxt_rbtree1_node_t *node1, nxt_rbtree1_node_t *node2)
{
if (node1->key < node2->key) {
return -1;
}
if (node1->key == node2->key) {
return 0;
}
return 1;
}
static int nxt_cdecl
nxt_rbtree1_test_sort_cmp(const void *one, const void *two)
{
const uint32_t *first, *second;
first = one;
second = two;
if (*first < *second) {
return -1;
}
if (*first == *second) {
return 0;
}
return 1;
}
static nxt_rbtree1_node_t *
nxt_rbtree1_test_find(nxt_rbtree1_t *tree, nxt_rbtree1_node_t *node)
{
nxt_int_t n;
nxt_rbtree1_node_t *next, *sentinel;
next = tree->root;
sentinel = tree->sentinel;
while (next != sentinel) {
nxt_prefetch(next->left);
nxt_prefetch(next->right);
n = nxt_rbtree1_test_compare(node, next);
if (n < 0) {
next = next->left;
} else if (n > 0) {
next = next->right;
} else {
return next;
}
}
return NULL;
}
#if (NXT_TEST_RTDTSC)
#define NXT_RBT_STEP (21 * nxt_pagesize / 10 / sizeof(nxt_rbtree1_node_t))
static nxt_rbtree1_t mb_tree;
static nxt_rbtree1_node_t mb_sentinel;
static nxt_rbtree1_node_t *mb_nodes;
nxt_int_t
nxt_rbtree1_mb_start(nxt_thread_t *thr)
{
uint32_t key;
uint64_t start, end;
nxt_uint_t i, n;
n = NXT_RBT_STEP;
mb_nodes = nxt_malloc(NXT_RBT_NODES * n * sizeof(nxt_rbtree1_node_t));
if (mb_nodes == NULL) {
return NXT_ERROR;
}
nxt_rbtree1_init(&mb_tree, &mb_sentinel, nxt_rbtree1_test_insert_value);
key = 0;
for (i = 0; i < NXT_RBT_NODES; i++) {
key = nxt_murmur_hash2(&key, sizeof(uint32_t));
mb_nodes[n * i].key = key;
}
for (i = 0; i < NXT_RBT_NODES - 2; i++) {
nxt_rbtree1_insert(&mb_tree, &mb_nodes[n * i]);
}
n *= (NXT_RBT_NODES - 2);
start = nxt_rdtsc();
nxt_rbtree1_insert(&mb_tree, &mb_nodes[n]);
end = nxt_rdtsc();
nxt_log_error(NXT_LOG_NOTICE, thr->log,
"rbtree1 mb cached insert: %L cycles", end - start);
return NXT_OK;
}
void
nxt_rbtree1_mb_insert(nxt_thread_t *thr)
{
uint64_t start, end;
nxt_uint_t n;
n = NXT_RBT_STEP;
n *= (NXT_RBT_NODES - 1);
start = nxt_rdtsc();
nxt_rbtree1_insert(&mb_tree, &mb_nodes[n]);
end = nxt_rdtsc();
nxt_log_error(NXT_LOG_NOTICE, thr->log,
"rbtree1 mb insert: %L cycles", end - start);
}
void
nxt_rbtree1_mb_delete(nxt_thread_t *thr)
{
uint64_t start, end;
nxt_uint_t n;
n = NXT_RBT_STEP;
n *= (NXT_RBT_NODES / 4 + 1);
start = nxt_rdtsc();
nxt_rbtree1_delete(&mb_tree, &mb_nodes[n]);
end = nxt_rdtsc();
nxt_log_error(NXT_LOG_NOTICE, thr->log,
"rbtree1 mb delete: %L cycles", end - start);
nxt_free(mb_nodes);
}
#endif
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