#include "test/jemalloc_test.h" #include #include "jemalloc/internal/rb.h" #define rbtn_black_height(a_type, a_field, a_rbt, r_height) do { \ a_type *rbp_bh_t; \ for (rbp_bh_t = (a_rbt)->rbt_root, (r_height) = 0; rbp_bh_t != \ NULL; rbp_bh_t = rbtn_left_get(a_type, a_field, \ rbp_bh_t)) { \ if (!rbtn_red_get(a_type, a_field, rbp_bh_t)) { \ (r_height)++; \ } \ } \ } while (0) static bool summarize_always_returns_true = false; typedef struct node_s node_t; struct node_s { #define NODE_MAGIC 0x9823af7e uint32_t magic; rb_node(node_t) link; /* Order used by nodes. */ uint64_t key; /* * Our made-up summary property is "specialness", with summarization * taking the max. */ uint64_t specialness; /* * Used by some of the test randomization to avoid double-removing * nodes. */ bool mid_remove; /* * To test searching functionality, we want to temporarily weaken the * ordering to allow non-equal nodes that nevertheless compare equal. */ bool allow_duplicates; /* * In check_consistency, it's handy to know a node's rank in the tree; * this tracks it (but only there; not all tests use this). */ int rank; int filtered_rank; /* * Replicate the internal structure of the tree, to make sure the * implementation doesn't miss any updates. */ const node_t *summary_lchild; const node_t *summary_rchild; uint64_t summary_max_specialness; }; static int node_cmp(const node_t *a, const node_t *b) { int ret; expect_u32_eq(a->magic, NODE_MAGIC, "Bad magic"); expect_u32_eq(b->magic, NODE_MAGIC, "Bad magic"); ret = (a->key > b->key) - (a->key < b->key); if (ret == 0 && !a->allow_duplicates) { /* * Duplicates are not allowed in the tree, so force an * arbitrary ordering for non-identical items with equal keys, * unless the user is searching and wants to allow the * duplicate. */ ret = (((uintptr_t)a) > ((uintptr_t)b)) - (((uintptr_t)a) < ((uintptr_t)b)); } return ret; } static uint64_t node_subtree_specialness(node_t *n, const node_t *lchild, const node_t *rchild) { uint64_t subtree_specialness = n->specialness; if (lchild != NULL && lchild->summary_max_specialness > subtree_specialness) { subtree_specialness = lchild->summary_max_specialness; } if (rchild != NULL && rchild->summary_max_specialness > subtree_specialness) { subtree_specialness = rchild->summary_max_specialness; } return subtree_specialness; } static bool node_summarize(node_t *a, const node_t *lchild, const node_t *rchild) { uint64_t new_summary_max_specialness = node_subtree_specialness( a, lchild, rchild); bool changed = (a->summary_lchild != lchild) || (a->summary_rchild != rchild) || (new_summary_max_specialness != a->summary_max_specialness); a->summary_max_specialness = new_summary_max_specialness; a->summary_lchild = lchild; a->summary_rchild = rchild; return changed || summarize_always_returns_true; } typedef rb_tree(node_t) tree_t; rb_summarized_proto(static, tree_, tree_t, node_t); rb_summarized_gen(static, tree_, tree_t, node_t, link, node_cmp, node_summarize); static bool specialness_filter_node(void *ctx, node_t *node) { uint64_t specialness = *(uint64_t *)ctx; return node->specialness >= specialness; } static bool specialness_filter_subtree(void *ctx, node_t *node) { uint64_t specialness = *(uint64_t *)ctx; return node->summary_max_specialness >= specialness; } static node_t * tree_iterate_cb(tree_t *tree, node_t *node, void *data) { unsigned *i = (unsigned *)data; node_t *search_node; expect_u32_eq(node->magic, NODE_MAGIC, "Bad magic"); /* Test rb_search(). */ search_node = tree_search(tree, node); expect_ptr_eq(search_node, node, "tree_search() returned unexpected node"); /* Test rb_nsearch(). */ search_node = tree_nsearch(tree, node); expect_ptr_eq(search_node, node, "tree_nsearch() returned unexpected node"); /* Test rb_psearch(). */ search_node = tree_psearch(tree, node); expect_ptr_eq(search_node, node, "tree_psearch() returned unexpected node"); (*i)++; return NULL; } TEST_BEGIN(test_rb_empty) { tree_t tree; node_t key; tree_new(&tree); expect_true(tree_empty(&tree), "Tree should be empty"); expect_ptr_null(tree_first(&tree), "Unexpected node"); expect_ptr_null(tree_last(&tree), "Unexpected node"); key.key = 0; key.magic = NODE_MAGIC; expect_ptr_null(tree_search(&tree, &key), "Unexpected node"); key.key = 0; key.magic = NODE_MAGIC; expect_ptr_null(tree_nsearch(&tree, &key), "Unexpected node"); key.key = 0; key.magic = NODE_MAGIC; expect_ptr_null(tree_psearch(&tree, &key), "Unexpected node"); unsigned nodes = 0; tree_iter_filtered(&tree, NULL, &tree_iterate_cb, &nodes, &specialness_filter_node, &specialness_filter_subtree, NULL); expect_u_eq(0, nodes, ""); nodes = 0; tree_reverse_iter_filtered(&tree, NULL, &tree_iterate_cb, &nodes, &specialness_filter_node, &specialness_filter_subtree, NULL); expect_u_eq(0, nodes, ""); expect_ptr_null(tree_first_filtered(&tree, &specialness_filter_node, &specialness_filter_subtree, NULL), ""); expect_ptr_null(tree_last_filtered(&tree, &specialness_filter_node, &specialness_filter_subtree, NULL), ""); key.key = 0; key.magic = NODE_MAGIC; expect_ptr_null(tree_search_filtered(&tree, &key, &specialness_filter_node, &specialness_filter_subtree, NULL), ""); expect_ptr_null(tree_nsearch_filtered(&tree, &key, &specialness_filter_node, &specialness_filter_subtree, NULL), ""); expect_ptr_null(tree_psearch_filtered(&tree, &key, &specialness_filter_node, &specialness_filter_subtree, NULL), ""); } TEST_END static unsigned tree_recurse(node_t *node, unsigned black_height, unsigned black_depth) { unsigned ret = 0; node_t *left_node; node_t *right_node; if (node == NULL) { return ret; } left_node = rbtn_left_get(node_t, link, node); right_node = rbtn_right_get(node_t, link, node); expect_ptr_eq(left_node, node->summary_lchild, "summary missed a tree update"); expect_ptr_eq(right_node, node->summary_rchild, "summary missed a tree update"); uint64_t expected_subtree_specialness = node_subtree_specialness(node, left_node, right_node); expect_u64_eq(expected_subtree_specialness, node->summary_max_specialness, "Incorrect summary"); if (!rbtn_red_get(node_t, link, node)) { black_depth++; } /* Red nodes must be interleaved with black nodes. */ if (rbtn_red_get(node_t, link, node)) { if (left_node != NULL) { expect_false(rbtn_red_get(node_t, link, left_node), "Node should be black"); } if (right_node != NULL) { expect_false(rbtn_red_get(node_t, link, right_node), "Node should be black"); } } /* Self. */ expect_u32_eq(node->magic, NODE_MAGIC, "Bad magic"); /* Left subtree. */ if (left_node != NULL) { ret += tree_recurse(left_node, black_height, black_depth); } else { ret += (black_depth != black_height); } /* Right subtree. */ if (right_node != NULL) { ret += tree_recurse(right_node, black_height, black_depth); } else { ret += (black_depth != black_height); } return ret; } static unsigned tree_iterate(tree_t *tree) { unsigned i; i = 0; tree_iter(tree, NULL, tree_iterate_cb, (void *)&i); return i; } static unsigned tree_iterate_reverse(tree_t *tree) { unsigned i; i = 0; tree_reverse_iter(tree, NULL, tree_iterate_cb, (void *)&i); return i; } static void node_remove(tree_t *tree, node_t *node, unsigned nnodes) { node_t *search_node; unsigned black_height, imbalances; tree_remove(tree, node); /* Test rb_nsearch(). */ search_node = tree_nsearch(tree, node); if (search_node != NULL) { expect_u64_ge(search_node->key, node->key, "Key ordering error"); } /* Test rb_psearch(). */ search_node = tree_psearch(tree, node); if (search_node != NULL) { expect_u64_le(search_node->key, node->key, "Key ordering error"); } node->magic = 0; rbtn_black_height(node_t, link, tree, black_height); imbalances = tree_recurse(tree->rbt_root, black_height, 0); expect_u_eq(imbalances, 0, "Tree is unbalanced"); expect_u_eq(tree_iterate(tree), nnodes-1, "Unexpected node iteration count"); expect_u_eq(tree_iterate_reverse(tree), nnodes-1, "Unexpected node iteration count"); } static node_t * remove_iterate_cb(tree_t *tree, node_t *node, void *data) { unsigned *nnodes = (unsigned *)data; node_t *ret = tree_next(tree, node); node_remove(tree, node, *nnodes); return ret; } static node_t * remove_reverse_iterate_cb(tree_t *tree, node_t *node, void *data) { unsigned *nnodes = (unsigned *)data; node_t *ret = tree_prev(tree, node); node_remove(tree, node, *nnodes); return ret; } static void destroy_cb(node_t *node, void *data) { unsigned *nnodes = (unsigned *)data; expect_u_gt(*nnodes, 0, "Destruction removed too many nodes"); (*nnodes)--; } TEST_BEGIN(test_rb_random) { enum { NNODES = 25, NBAGS = 500, SEED = 42 }; sfmt_t *sfmt; uint64_t bag[NNODES]; tree_t tree; node_t nodes[NNODES]; unsigned i, j, k, black_height, imbalances; sfmt = init_gen_rand(SEED); for (i = 0; i < NBAGS; i++) { switch (i) { case 0: /* Insert in order. */ for (j = 0; j < NNODES; j++) { bag[j] = j; } break; case 1: /* Insert in reverse order. */ for (j = 0; j < NNODES; j++) { bag[j] = NNODES - j - 1; } break; default: for (j = 0; j < NNODES; j++) { bag[j] = gen_rand64_range(sfmt, NNODES); } } /* * We alternate test behavior with a period of 2 here, and a * period of 5 down below, so there's no cycle in which certain * combinations get omitted. */ summarize_always_returns_true = (i % 2 == 0); for (j = 1; j <= NNODES; j++) { /* Initialize tree and nodes. */ tree_new(&tree); for (k = 0; k < j; k++) { nodes[k].magic = NODE_MAGIC; nodes[k].key = bag[k]; nodes[k].specialness = gen_rand64_range(sfmt, NNODES); nodes[k].mid_remove = false; nodes[k].allow_duplicates = false; nodes[k].summary_lchild = NULL; nodes[k].summary_rchild = NULL; nodes[k].summary_max_specialness = 0; } /* Insert nodes. */ for (k = 0; k < j; k++) { tree_insert(&tree, &nodes[k]); rbtn_black_height(node_t, link, &tree, black_height); imbalances = tree_recurse(tree.rbt_root, black_height, 0); expect_u_eq(imbalances, 0, "Tree is unbalanced"); expect_u_eq(tree_iterate(&tree), k+1, "Unexpected node iteration count"); expect_u_eq(tree_iterate_reverse(&tree), k+1, "Unexpected node iteration count"); expect_false(tree_empty(&tree), "Tree should not be empty"); expect_ptr_not_null(tree_first(&tree), "Tree should not be empty"); expect_ptr_not_null(tree_last(&tree), "Tree should not be empty"); tree_next(&tree, &nodes[k]); tree_prev(&tree, &nodes[k]); } /* Remove nodes. */ switch (i % 5) { case 0: for (k = 0; k < j; k++) { node_remove(&tree, &nodes[k], j - k); } break; case 1: for (k = j; k > 0; k--) { node_remove(&tree, &nodes[k-1], k); } break; case 2: { node_t *start; unsigned nnodes = j; start = NULL; do { start = tree_iter(&tree, start, remove_iterate_cb, (void *)&nnodes); nnodes--; } while (start != NULL); expect_u_eq(nnodes, 0, "Removal terminated early"); break; } case 3: { node_t *start; unsigned nnodes = j; start = NULL; do { start = tree_reverse_iter(&tree, start, remove_reverse_iterate_cb, (void *)&nnodes); nnodes--; } while (start != NULL); expect_u_eq(nnodes, 0, "Removal terminated early"); break; } case 4: { unsigned nnodes = j; tree_destroy(&tree, destroy_cb, &nnodes); expect_u_eq(nnodes, 0, "Destruction terminated early"); break; } default: not_reached(); } } } fini_gen_rand(sfmt); } TEST_END static void expect_simple_consistency(tree_t *tree, uint64_t specialness, bool expected_empty, node_t *expected_first, node_t *expected_last) { bool empty; node_t *first; node_t *last; empty = tree_empty_filtered(tree, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_b_eq(expected_empty, empty, ""); first = tree_first_filtered(tree, &specialness_filter_node, &specialness_filter_subtree, (void *)&specialness); expect_ptr_eq(expected_first, first, ""); last = tree_last_filtered(tree, &specialness_filter_node, &specialness_filter_subtree, (void *)&specialness); expect_ptr_eq(expected_last, last, ""); } TEST_BEGIN(test_rb_filter_simple) { enum {FILTER_NODES = 10}; node_t nodes[FILTER_NODES]; for (unsigned i = 0; i < FILTER_NODES; i++) { nodes[i].magic = NODE_MAGIC; nodes[i].key = i; if (i == 0) { nodes[i].specialness = 0; } else { nodes[i].specialness = ffs_u(i); } nodes[i].mid_remove = false; nodes[i].allow_duplicates = false; nodes[i].summary_lchild = NULL; nodes[i].summary_rchild = NULL; nodes[i].summary_max_specialness = 0; } summarize_always_returns_true = false; tree_t tree; tree_new(&tree); /* Should be empty */ expect_simple_consistency(&tree, /* specialness */ 0, /* empty */ true, /* first */ NULL, /* last */ NULL); /* Fill in just the odd nodes. */ for (int i = 1; i < FILTER_NODES; i += 2) { tree_insert(&tree, &nodes[i]); } /* A search for an odd node should succeed. */ expect_simple_consistency(&tree, /* specialness */ 0, /* empty */ false, /* first */ &nodes[1], /* last */ &nodes[9]); /* But a search for an even one should fail. */ expect_simple_consistency(&tree, /* specialness */ 1, /* empty */ true, /* first */ NULL, /* last */ NULL); /* Now we add an even. */ tree_insert(&tree, &nodes[4]); expect_simple_consistency(&tree, /* specialness */ 1, /* empty */ false, /* first */ &nodes[4], /* last */ &nodes[4]); /* A smaller even, and a larger even. */ tree_insert(&tree, &nodes[2]); tree_insert(&tree, &nodes[8]); /* * A first-search (resp. last-search) for an even should switch to the * lower (higher) one, now that it's been added. */ expect_simple_consistency(&tree, /* specialness */ 1, /* empty */ false, /* first */ &nodes[2], /* last */ &nodes[8]); /* * If we remove 2, a first-search we should go back to 4, while a * last-search should remain unchanged. */ tree_remove(&tree, &nodes[2]); expect_simple_consistency(&tree, /* specialness */ 1, /* empty */ false, /* first */ &nodes[4], /* last */ &nodes[8]); /* Reinsert 2, then find it again. */ tree_insert(&tree, &nodes[2]); expect_simple_consistency(&tree, /* specialness */ 1, /* empty */ false, /* first */ &nodes[2], /* last */ &nodes[8]); /* Searching for a multiple of 4 should not have changed. */ expect_simple_consistency(&tree, /* specialness */ 2, /* empty */ false, /* first */ &nodes[4], /* last */ &nodes[8]); /* And a multiple of 8 */ expect_simple_consistency(&tree, /* specialness */ 3, /* empty */ false, /* first */ &nodes[8], /* last */ &nodes[8]); /* But not a multiple of 16 */ expect_simple_consistency(&tree, /* specialness */ 4, /* empty */ true, /* first */ NULL, /* last */ NULL); } TEST_END typedef struct iter_ctx_s iter_ctx_t; struct iter_ctx_s { int ncalls; node_t *last_node; int ncalls_max; bool forward; }; static node_t * tree_iterate_filtered_cb(tree_t *tree, node_t *node, void *arg) { iter_ctx_t *ctx = (iter_ctx_t *)arg; ctx->ncalls++; expect_u64_ge(node->specialness, 1, "Should only invoke cb on nodes that pass the filter"); if (ctx->last_node != NULL) { if (ctx->forward) { expect_d_lt(node_cmp(ctx->last_node, node), 0, "Incorrect iteration order"); } else { expect_d_gt(node_cmp(ctx->last_node, node), 0, "Incorrect iteration order"); } } ctx->last_node = node; if (ctx->ncalls == ctx->ncalls_max) { return node; } return NULL; } static int qsort_node_cmp(const void *ap, const void *bp) { node_t *a = *(node_t **)ap; node_t *b = *(node_t **)bp; return node_cmp(a, b); } #define UPDATE_TEST_MAX 100 static void check_consistency(tree_t *tree, node_t nodes[UPDATE_TEST_MAX], int nnodes) { uint64_t specialness = 1; bool empty; bool real_empty = true; node_t *first; node_t *real_first = NULL; node_t *last; node_t *real_last = NULL; for (int i = 0; i < nnodes; i++) { if (nodes[i].specialness >= specialness) { real_empty = false; if (real_first == NULL || node_cmp(&nodes[i], real_first) < 0) { real_first = &nodes[i]; } if (real_last == NULL || node_cmp(&nodes[i], real_last) > 0) { real_last = &nodes[i]; } } } empty = tree_empty_filtered(tree, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_b_eq(real_empty, empty, ""); first = tree_first_filtered(tree, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_first, first, ""); last = tree_last_filtered(tree, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_last, last, ""); for (int i = 0; i < nnodes; i++) { node_t *next_filtered; node_t *real_next_filtered = NULL; node_t *prev_filtered; node_t *real_prev_filtered = NULL; for (int j = 0; j < nnodes; j++) { if (nodes[j].specialness < specialness) { continue; } if (node_cmp(&nodes[j], &nodes[i]) < 0 && (real_prev_filtered == NULL || node_cmp(&nodes[j], real_prev_filtered) > 0)) { real_prev_filtered = &nodes[j]; } if (node_cmp(&nodes[j], &nodes[i]) > 0 && (real_next_filtered == NULL || node_cmp(&nodes[j], real_next_filtered) < 0)) { real_next_filtered = &nodes[j]; } } next_filtered = tree_next_filtered(tree, &nodes[i], &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_next_filtered, next_filtered, ""); prev_filtered = tree_prev_filtered(tree, &nodes[i], &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_prev_filtered, prev_filtered, ""); node_t *search_filtered; node_t *real_search_filtered; node_t *nsearch_filtered; node_t *real_nsearch_filtered; node_t *psearch_filtered; node_t *real_psearch_filtered; /* * search, nsearch, psearch from a node before nodes[i] in the * ordering. */ node_t before; before.magic = NODE_MAGIC; before.key = nodes[i].key - 1; before.allow_duplicates = false; real_search_filtered = NULL; search_filtered = tree_search_filtered(tree, &before, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_search_filtered, search_filtered, ""); real_nsearch_filtered = (nodes[i].specialness >= specialness ? &nodes[i] : real_next_filtered); nsearch_filtered = tree_nsearch_filtered(tree, &before, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_nsearch_filtered, nsearch_filtered, ""); real_psearch_filtered = real_prev_filtered; psearch_filtered = tree_psearch_filtered(tree, &before, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_psearch_filtered, psearch_filtered, ""); /* search, nsearch, psearch from nodes[i] */ real_search_filtered = (nodes[i].specialness >= specialness ? &nodes[i] : NULL); search_filtered = tree_search_filtered(tree, &nodes[i], &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_search_filtered, search_filtered, ""); real_nsearch_filtered = (nodes[i].specialness >= specialness ? &nodes[i] : real_next_filtered); nsearch_filtered = tree_nsearch_filtered(tree, &nodes[i], &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_nsearch_filtered, nsearch_filtered, ""); real_psearch_filtered = (nodes[i].specialness >= specialness ? &nodes[i] : real_prev_filtered); psearch_filtered = tree_psearch_filtered(tree, &nodes[i], &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_psearch_filtered, psearch_filtered, ""); /* * search, nsearch, psearch from a node equivalent to but * distinct from nodes[i]. */ node_t equiv; equiv.magic = NODE_MAGIC; equiv.key = nodes[i].key; equiv.allow_duplicates = true; real_search_filtered = (nodes[i].specialness >= specialness ? &nodes[i] : NULL); search_filtered = tree_search_filtered(tree, &equiv, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_search_filtered, search_filtered, ""); real_nsearch_filtered = (nodes[i].specialness >= specialness ? &nodes[i] : real_next_filtered); nsearch_filtered = tree_nsearch_filtered(tree, &equiv, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_nsearch_filtered, nsearch_filtered, ""); real_psearch_filtered = (nodes[i].specialness >= specialness ? &nodes[i] : real_prev_filtered); psearch_filtered = tree_psearch_filtered(tree, &equiv, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_psearch_filtered, psearch_filtered, ""); /* * search, nsearch, psearch from a node after nodes[i] in the * ordering. */ node_t after; after.magic = NODE_MAGIC; after.key = nodes[i].key + 1; after.allow_duplicates = false; real_search_filtered = NULL; search_filtered = tree_search_filtered(tree, &after, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_search_filtered, search_filtered, ""); real_nsearch_filtered = real_next_filtered; nsearch_filtered = tree_nsearch_filtered(tree, &after, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_nsearch_filtered, nsearch_filtered, ""); real_psearch_filtered = (nodes[i].specialness >= specialness ? &nodes[i] : real_prev_filtered); psearch_filtered = tree_psearch_filtered(tree, &after, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(real_psearch_filtered, psearch_filtered, ""); } /* Filtered iteration test setup. */ int nspecial = 0; node_t *sorted_nodes[UPDATE_TEST_MAX]; node_t *sorted_filtered_nodes[UPDATE_TEST_MAX]; for (int i = 0; i < nnodes; i++) { sorted_nodes[i] = &nodes[i]; } qsort(sorted_nodes, nnodes, sizeof(node_t *), &qsort_node_cmp); for (int i = 0; i < nnodes; i++) { sorted_nodes[i]->rank = i; sorted_nodes[i]->filtered_rank = nspecial; if (sorted_nodes[i]->specialness >= 1) { sorted_filtered_nodes[nspecial] = sorted_nodes[i]; nspecial++; } } node_t *iter_result; iter_ctx_t ctx; ctx.ncalls = 0; ctx.last_node = NULL; ctx.ncalls_max = INT_MAX; ctx.forward = true; /* Filtered forward iteration from the beginning. */ iter_result = tree_iter_filtered(tree, NULL, &tree_iterate_filtered_cb, &ctx, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_null(iter_result, ""); expect_d_eq(nspecial, ctx.ncalls, ""); /* Filtered forward iteration from a starting point. */ for (int i = 0; i < nnodes; i++) { ctx.ncalls = 0; ctx.last_node = NULL; iter_result = tree_iter_filtered(tree, &nodes[i], &tree_iterate_filtered_cb, &ctx, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_null(iter_result, ""); expect_d_eq(nspecial - nodes[i].filtered_rank, ctx.ncalls, ""); } /* Filtered forward iteration from the beginning, with stopping */ for (int i = 0; i < nspecial; i++) { ctx.ncalls = 0; ctx.last_node = NULL; ctx.ncalls_max = i + 1; iter_result = tree_iter_filtered(tree, NULL, &tree_iterate_filtered_cb, &ctx, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(sorted_filtered_nodes[i], iter_result, ""); expect_d_eq(ctx.ncalls, i + 1, ""); } /* Filtered forward iteration from a starting point, with stopping. */ for (int i = 0; i < nnodes; i++) { for (int j = 0; j < nspecial - nodes[i].filtered_rank; j++) { ctx.ncalls = 0; ctx.last_node = NULL; ctx.ncalls_max = j + 1; iter_result = tree_iter_filtered(tree, &nodes[i], &tree_iterate_filtered_cb, &ctx, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_d_eq(j + 1, ctx.ncalls, ""); expect_ptr_eq(sorted_filtered_nodes[ nodes[i].filtered_rank + j], iter_result, ""); } } /* Backwards iteration. */ ctx.ncalls = 0; ctx.last_node = NULL; ctx.ncalls_max = INT_MAX; ctx.forward = false; /* Filtered backward iteration from the end. */ iter_result = tree_reverse_iter_filtered(tree, NULL, &tree_iterate_filtered_cb, &ctx, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_null(iter_result, ""); expect_d_eq(nspecial, ctx.ncalls, ""); /* Filtered backward iteration from a starting point. */ for (int i = 0; i < nnodes; i++) { ctx.ncalls = 0; ctx.last_node = NULL; iter_result = tree_reverse_iter_filtered(tree, &nodes[i], &tree_iterate_filtered_cb, &ctx, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_null(iter_result, ""); int surplus_rank = (nodes[i].specialness >= 1 ? 1 : 0); expect_d_eq(nodes[i].filtered_rank + surplus_rank, ctx.ncalls, ""); } /* Filtered backward iteration from the end, with stopping */ for (int i = 0; i < nspecial; i++) { ctx.ncalls = 0; ctx.last_node = NULL; ctx.ncalls_max = i + 1; iter_result = tree_reverse_iter_filtered(tree, NULL, &tree_iterate_filtered_cb, &ctx, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_ptr_eq(sorted_filtered_nodes[nspecial - i - 1], iter_result, ""); expect_d_eq(ctx.ncalls, i + 1, ""); } /* Filtered backward iteration from a starting point, with stopping. */ for (int i = 0; i < nnodes; i++) { int surplus_rank = (nodes[i].specialness >= 1 ? 1 : 0); for (int j = 0; j < nodes[i].filtered_rank + surplus_rank; j++) { ctx.ncalls = 0; ctx.last_node = NULL; ctx.ncalls_max = j + 1; iter_result = tree_reverse_iter_filtered(tree, &nodes[i], &tree_iterate_filtered_cb, &ctx, &specialness_filter_node, &specialness_filter_subtree, &specialness); expect_d_eq(j + 1, ctx.ncalls, ""); expect_ptr_eq(sorted_filtered_nodes[ nodes[i].filtered_rank - j - 1 + surplus_rank], iter_result, ""); } } } static void do_update_search_test(int nnodes, int ntrees, int nremovals, int nupdates) { node_t nodes[UPDATE_TEST_MAX]; assert(nnodes <= UPDATE_TEST_MAX); sfmt_t *sfmt = init_gen_rand(12345); for (int i = 0; i < ntrees; i++) { tree_t tree; tree_new(&tree); for (int j = 0; j < nnodes; j++) { nodes[j].magic = NODE_MAGIC; /* * In consistency checking, we increment or decrement a * key and assume that the result is not a key in the * tree. This isn't a *real* concern with 64-bit keys * and a good PRNG, but why not be correct anyways? */ nodes[j].key = 2 * gen_rand64(sfmt); nodes[j].specialness = 0; nodes[j].mid_remove = false; nodes[j].allow_duplicates = false; nodes[j].summary_lchild = NULL; nodes[j].summary_rchild = NULL; nodes[j].summary_max_specialness = 0; tree_insert(&tree, &nodes[j]); } for (int j = 0; j < nremovals; j++) { int victim = (int)gen_rand64_range(sfmt, nnodes); if (!nodes[victim].mid_remove) { tree_remove(&tree, &nodes[victim]); nodes[victim].mid_remove = true; } } for (int j = 0; j < nnodes; j++) { if (nodes[j].mid_remove) { nodes[j].mid_remove = false; nodes[j].key = 2 * gen_rand64(sfmt); tree_insert(&tree, &nodes[j]); } } for (int j = 0; j < nupdates; j++) { uint32_t ind = gen_rand32_range(sfmt, nnodes); nodes[ind].specialness = 1 - nodes[ind].specialness; tree_update_summaries(&tree, &nodes[ind]); check_consistency(&tree, nodes, nnodes); } } } TEST_BEGIN(test_rb_update_search) { summarize_always_returns_true = false; do_update_search_test(2, 100, 3, 50); do_update_search_test(5, 100, 3, 50); do_update_search_test(12, 100, 5, 1000); do_update_search_test(100, 1, 50, 500); } TEST_END typedef rb_tree(node_t) unsummarized_tree_t; rb_gen(static UNUSED, unsummarized_tree_, unsummarized_tree_t, node_t, link, node_cmp); static node_t * unsummarized_tree_iterate_cb(unsummarized_tree_t *tree, node_t *node, void *data) { unsigned *i = (unsigned *)data; (*i)++; return NULL; } /* * The unsummarized and summarized funtionality is implemented via the same * functions; we don't really need to do much more than test that we can exclude * the filtered functionality without anything breaking. */ TEST_BEGIN(test_rb_unsummarized) { unsummarized_tree_t tree; unsummarized_tree_new(&tree); unsigned nnodes = 0; unsummarized_tree_iter(&tree, NULL, &unsummarized_tree_iterate_cb, &nnodes); expect_u_eq(0, nnodes, ""); } TEST_END int main(void) { return test_no_reentrancy( test_rb_empty, test_rb_random, test_rb_filter_simple, test_rb_update_search, test_rb_unsummarized); }