9ed84b0d45
This will facilitate embedding tcache into tsd, which will require proper initialization cannot be done via the static initializer. Make tsd->rtree_ctx to be initialized via rtree_ctx_data_init().
312 lines
8.9 KiB
C
312 lines
8.9 KiB
C
#include "test/jemalloc_test.h"
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rtree_node_alloc_t *rtree_node_alloc_orig;
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rtree_node_dalloc_t *rtree_node_dalloc_orig;
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rtree_leaf_alloc_t *rtree_leaf_alloc_orig;
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rtree_leaf_dalloc_t *rtree_leaf_dalloc_orig;
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/* Potentially too large to safely place on the stack. */
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rtree_t test_rtree;
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static rtree_node_elm_t *
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rtree_node_alloc_intercept(tsdn_t *tsdn, rtree_t *rtree, size_t nelms) {
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rtree_node_elm_t *node;
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if (rtree != &test_rtree) {
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return rtree_node_alloc_orig(tsdn, rtree, nelms);
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}
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malloc_mutex_unlock(tsdn, &rtree->init_lock);
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node = (rtree_node_elm_t *)calloc(nelms, sizeof(rtree_node_elm_t));
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assert_ptr_not_null(node, "Unexpected calloc() failure");
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malloc_mutex_lock(tsdn, &rtree->init_lock);
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return node;
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}
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static void
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rtree_node_dalloc_intercept(tsdn_t *tsdn, rtree_t *rtree,
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rtree_node_elm_t *node) {
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if (rtree != &test_rtree) {
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rtree_node_dalloc_orig(tsdn, rtree, node);
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return;
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}
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free(node);
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}
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static rtree_leaf_elm_t *
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rtree_leaf_alloc_intercept(tsdn_t *tsdn, rtree_t *rtree, size_t nelms) {
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rtree_leaf_elm_t *leaf;
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if (rtree != &test_rtree) {
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return rtree_leaf_alloc_orig(tsdn, rtree, nelms);
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}
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malloc_mutex_unlock(tsdn, &rtree->init_lock);
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leaf = (rtree_leaf_elm_t *)calloc(nelms, sizeof(rtree_leaf_elm_t));
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assert_ptr_not_null(leaf, "Unexpected calloc() failure");
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malloc_mutex_lock(tsdn, &rtree->init_lock);
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return leaf;
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}
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static void
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rtree_leaf_dalloc_intercept(tsdn_t *tsdn, rtree_t *rtree,
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rtree_leaf_elm_t *leaf) {
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if (rtree != &test_rtree) {
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rtree_leaf_dalloc_orig(tsdn, rtree, leaf);
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return;
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}
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free(leaf);
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}
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TEST_BEGIN(test_rtree_read_empty) {
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tsdn_t *tsdn;
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tsdn = tsdn_fetch();
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rtree_t *rtree = &test_rtree;
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rtree_ctx_t rtree_ctx;
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rtree_ctx_data_init(&rtree_ctx);
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assert_false(rtree_new(rtree, false), "Unexpected rtree_new() failure");
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assert_ptr_null(rtree_extent_read(tsdn, rtree, &rtree_ctx, PAGE,
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false), "rtree_extent_read() should return NULL for empty tree");
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rtree_delete(tsdn, rtree);
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}
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TEST_END
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#define NTHREADS 8
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#define MAX_NBITS 30
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#define NITERS 1000
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#define SEED 42
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typedef struct {
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rtree_t *rtree;
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uint32_t seed;
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} thd_start_arg_t;
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static void *
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thd_start(void *varg) {
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thd_start_arg_t *arg = (thd_start_arg_t *)varg;
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rtree_ctx_t rtree_ctx;
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rtree_ctx_data_init(&rtree_ctx);
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sfmt_t *sfmt;
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extent_t *extent;
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tsdn_t *tsdn;
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unsigned i;
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sfmt = init_gen_rand(arg->seed);
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extent = (extent_t *)malloc(sizeof(extent));
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assert_ptr_not_null(extent, "Unexpected malloc() failure");
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extent_init(extent, NULL, NULL, 0, false, NSIZES, 0,
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extent_state_active, false, false);
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tsdn = tsdn_fetch();
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for (i = 0; i < NITERS; i++) {
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uintptr_t key = (uintptr_t)(gen_rand64(sfmt) & ((ZU(1) <<
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MAX_NBITS) - ZU(1)));
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if (i % 2 == 0) {
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rtree_leaf_elm_t *elm = rtree_leaf_elm_acquire(tsdn,
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arg->rtree, &rtree_ctx, key, false, true);
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assert_ptr_not_null(elm,
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"Unexpected rtree_leaf_elm_acquire() failure");
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rtree_leaf_elm_write(tsdn, arg->rtree, elm, true,
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extent, NSIZES, false);
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rtree_leaf_elm_release(tsdn, arg->rtree, elm);
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elm = rtree_leaf_elm_acquire(tsdn, arg->rtree,
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&rtree_ctx, key, true, false);
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assert_ptr_not_null(elm,
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"Unexpected rtree_leaf_elm_acquire() failure");
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rtree_leaf_elm_extent_read(tsdn, arg->rtree, elm, true,
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true);
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rtree_leaf_elm_szind_read(tsdn, arg->rtree, elm, true,
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true);
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rtree_leaf_elm_slab_read(tsdn, arg->rtree, elm, true,
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true);
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rtree_leaf_elm_release(tsdn, arg->rtree, elm);
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} else {
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rtree_extent_read(tsdn, arg->rtree, &rtree_ctx, key,
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false);
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}
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}
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free(extent);
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fini_gen_rand(sfmt);
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return NULL;
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}
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TEST_BEGIN(test_rtree_concurrent) {
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thd_start_arg_t arg;
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thd_t thds[NTHREADS];
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sfmt_t *sfmt;
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tsdn_t *tsdn;
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sfmt = init_gen_rand(SEED);
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tsdn = tsdn_fetch();
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arg.rtree = &test_rtree;
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assert_false(rtree_new(arg.rtree, false),
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"Unexpected rtree_new() failure");
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arg.seed = gen_rand32(sfmt);
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for (unsigned i = 0; i < NTHREADS; i++) {
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thd_create(&thds[i], thd_start, (void *)&arg);
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}
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for (unsigned i = 0; i < NTHREADS; i++) {
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thd_join(thds[i], NULL);
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}
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rtree_delete(tsdn, arg.rtree);
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fini_gen_rand(sfmt);
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}
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TEST_END
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#undef NTHREADS
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#undef NITERS
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#undef SEED
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TEST_BEGIN(test_rtree_extrema) {
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extent_t extent_a, extent_b;
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extent_init(&extent_a, NULL, NULL, LARGE_MINCLASS, false,
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size2index(LARGE_MINCLASS), 0, extent_state_active, false, false);
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extent_init(&extent_b, NULL, NULL, 0, false, NSIZES, 0,
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extent_state_active, false, false);
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tsdn_t *tsdn = tsdn_fetch();
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rtree_t *rtree = &test_rtree;
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rtree_ctx_t rtree_ctx;
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rtree_ctx_data_init(&rtree_ctx);
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assert_false(rtree_new(rtree, false), "Unexpected rtree_new() failure");
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assert_false(rtree_write(tsdn, rtree, &rtree_ctx, PAGE, &extent_a,
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extent_szind_get(&extent_a), extent_slab_get(&extent_a)),
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"Unexpected rtree_write() failure");
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rtree_szind_slab_update(tsdn, rtree, &rtree_ctx, PAGE,
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extent_szind_get(&extent_a), extent_slab_get(&extent_a));
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assert_ptr_eq(rtree_extent_read(tsdn, rtree, &rtree_ctx, PAGE, true),
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&extent_a,
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"rtree_extent_read() should return previously set value");
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assert_false(rtree_write(tsdn, rtree, &rtree_ctx, ~((uintptr_t)0),
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&extent_b, extent_szind_get_maybe_invalid(&extent_b),
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extent_slab_get(&extent_b)), "Unexpected rtree_write() failure");
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assert_ptr_eq(rtree_extent_read(tsdn, rtree, &rtree_ctx,
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~((uintptr_t)0), true), &extent_b,
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"rtree_extent_read() should return previously set value");
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rtree_delete(tsdn, rtree);
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}
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TEST_END
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TEST_BEGIN(test_rtree_bits) {
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tsdn_t *tsdn = tsdn_fetch();
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uintptr_t keys[] = {PAGE, PAGE + 1,
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PAGE + (((uintptr_t)1) << LG_PAGE) - 1};
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extent_t extent;
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extent_init(&extent, NULL, NULL, 0, false, NSIZES, 0,
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extent_state_active, false, false);
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rtree_t *rtree = &test_rtree;
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rtree_ctx_t rtree_ctx;
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rtree_ctx_data_init(&rtree_ctx);
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assert_false(rtree_new(rtree, false), "Unexpected rtree_new() failure");
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for (unsigned i = 0; i < sizeof(keys)/sizeof(uintptr_t); i++) {
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assert_false(rtree_write(tsdn, rtree, &rtree_ctx, keys[i],
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&extent, NSIZES, false),
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"Unexpected rtree_write() failure");
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for (unsigned j = 0; j < sizeof(keys)/sizeof(uintptr_t); j++) {
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assert_ptr_eq(rtree_extent_read(tsdn, rtree, &rtree_ctx,
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keys[j], true), &extent,
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"rtree_extent_read() should return previously set "
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"value and ignore insignificant key bits; i=%u, "
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"j=%u, set key=%#"FMTxPTR", get key=%#"FMTxPTR, i,
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j, keys[i], keys[j]);
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}
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assert_ptr_null(rtree_extent_read(tsdn, rtree, &rtree_ctx,
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(((uintptr_t)2) << LG_PAGE), false),
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"Only leftmost rtree leaf should be set; i=%u", i);
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rtree_clear(tsdn, rtree, &rtree_ctx, keys[i]);
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}
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rtree_delete(tsdn, rtree);
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}
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TEST_END
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TEST_BEGIN(test_rtree_random) {
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#define NSET 16
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#define SEED 42
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sfmt_t *sfmt = init_gen_rand(SEED);
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tsdn_t *tsdn = tsdn_fetch();
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uintptr_t keys[NSET];
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rtree_t *rtree = &test_rtree;
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rtree_ctx_t rtree_ctx;
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rtree_ctx_data_init(&rtree_ctx);
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extent_t extent;
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extent_init(&extent, NULL, NULL, 0, false, NSIZES, 0,
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extent_state_active, false, false);
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assert_false(rtree_new(rtree, false), "Unexpected rtree_new() failure");
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for (unsigned i = 0; i < NSET; i++) {
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keys[i] = (uintptr_t)gen_rand64(sfmt);
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rtree_leaf_elm_t *elm = rtree_leaf_elm_acquire(tsdn, rtree,
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&rtree_ctx, keys[i], false, true);
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assert_ptr_not_null(elm,
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"Unexpected rtree_leaf_elm_acquire() failure");
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rtree_leaf_elm_write(tsdn, rtree, elm, true, &extent, NSIZES,
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false);
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rtree_leaf_elm_release(tsdn, rtree, elm);
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assert_ptr_eq(rtree_extent_read(tsdn, rtree, &rtree_ctx,
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keys[i], true), &extent,
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"rtree_extent_read() should return previously set value");
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}
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for (unsigned i = 0; i < NSET; i++) {
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assert_ptr_eq(rtree_extent_read(tsdn, rtree, &rtree_ctx,
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keys[i], true), &extent,
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"rtree_extent_read() should return previously set value, "
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"i=%u", i);
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}
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for (unsigned i = 0; i < NSET; i++) {
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rtree_clear(tsdn, rtree, &rtree_ctx, keys[i]);
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assert_ptr_null(rtree_extent_read(tsdn, rtree, &rtree_ctx,
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keys[i], true),
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"rtree_extent_read() should return previously set value");
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}
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for (unsigned i = 0; i < NSET; i++) {
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assert_ptr_null(rtree_extent_read(tsdn, rtree, &rtree_ctx,
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keys[i], true),
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"rtree_extent_read() should return previously set value");
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}
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rtree_delete(tsdn, rtree);
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fini_gen_rand(sfmt);
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#undef NSET
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#undef SEED
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}
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TEST_END
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int
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main(void) {
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rtree_node_alloc_orig = rtree_node_alloc;
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rtree_node_alloc = rtree_node_alloc_intercept;
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rtree_node_dalloc_orig = rtree_node_dalloc;
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rtree_node_dalloc = rtree_node_dalloc_intercept;
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rtree_leaf_alloc_orig = rtree_leaf_alloc;
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rtree_leaf_alloc = rtree_leaf_alloc_intercept;
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rtree_leaf_dalloc_orig = rtree_leaf_dalloc;
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rtree_leaf_dalloc = rtree_leaf_dalloc_intercept;
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return test(
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test_rtree_read_empty,
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test_rtree_concurrent,
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test_rtree_extrema,
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test_rtree_bits,
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test_rtree_random);
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}
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