#include "test/jemalloc_test.h" #include "jemalloc/internal/hpa.h" #include "jemalloc/internal/nstime.h" #define SHARD_IND 111 #define ALLOC_MAX (HUGEPAGE / 4) typedef struct test_data_s test_data_t; struct test_data_s { /* * Must be the first member -- we convert back and forth between the * test_data_t and the hpa_shard_t; */ hpa_shard_t shard; hpa_central_t central; base_t *base; edata_cache_t shard_edata_cache; emap_t emap; }; static hpa_shard_opts_t test_hpa_shard_opts_default = { /* slab_max_alloc */ ALLOC_MAX, /* hugification threshold */ HUGEPAGE, /* dirty_mult */ FXP_INIT_PERCENT(25), /* deferral_allowed */ false, /* hugify_delay_ms */ 10 * 1000, }; static hpa_shard_t * create_test_data(hpa_hooks_t *hooks, hpa_shard_opts_t *opts) { bool err; base_t *base = base_new(TSDN_NULL, /* ind */ SHARD_IND, &ehooks_default_extent_hooks, /* metadata_use_hooks */ true); assert_ptr_not_null(base, ""); test_data_t *test_data = malloc(sizeof(test_data_t)); assert_ptr_not_null(test_data, ""); test_data->base = base; err = edata_cache_init(&test_data->shard_edata_cache, base); assert_false(err, ""); err = emap_init(&test_data->emap, test_data->base, /* zeroed */ false); assert_false(err, ""); err = hpa_central_init(&test_data->central, test_data->base, hooks); assert_false(err, ""); err = hpa_shard_init(&test_data->shard, &test_data->central, &test_data->emap, test_data->base, &test_data->shard_edata_cache, SHARD_IND, opts); assert_false(err, ""); return (hpa_shard_t *)test_data; } static void destroy_test_data(hpa_shard_t *shard) { test_data_t *test_data = (test_data_t *)shard; base_delete(TSDN_NULL, test_data->base); free(test_data); } TEST_BEGIN(test_alloc_max) { test_skip_if(!hpa_supported()); hpa_shard_t *shard = create_test_data(&hpa_hooks_default, &test_hpa_shard_opts_default); tsdn_t *tsdn = tsd_tsdn(tsd_fetch()); edata_t *edata; /* Small max */ bool deferred_work_generated = false; edata = pai_alloc(tsdn, &shard->pai, ALLOC_MAX, PAGE, false, false, false, &deferred_work_generated); expect_ptr_not_null(edata, "Allocation of small max failed"); edata = pai_alloc(tsdn, &shard->pai, ALLOC_MAX + PAGE, PAGE, false, false, false, &deferred_work_generated); expect_ptr_null(edata, "Allocation of larger than small max succeeded"); destroy_test_data(shard); } TEST_END typedef struct mem_contents_s mem_contents_t; struct mem_contents_s { uintptr_t my_addr; size_t size; edata_t *my_edata; rb_node(mem_contents_t) link; }; static int mem_contents_cmp(const mem_contents_t *a, const mem_contents_t *b) { return (a->my_addr > b->my_addr) - (a->my_addr < b->my_addr); } typedef rb_tree(mem_contents_t) mem_tree_t; rb_gen(static, mem_tree_, mem_tree_t, mem_contents_t, link, mem_contents_cmp); static void node_assert_ordered(mem_contents_t *a, mem_contents_t *b) { assert_zu_lt(a->my_addr, a->my_addr + a->size, "Overflow"); assert_zu_le(a->my_addr + a->size, b->my_addr, ""); } static void node_check(mem_tree_t *tree, mem_contents_t *contents) { edata_t *edata = contents->my_edata; assert_ptr_eq(contents, (void *)contents->my_addr, ""); assert_ptr_eq(contents, edata_base_get(edata), ""); assert_zu_eq(contents->size, edata_size_get(edata), ""); assert_ptr_eq(contents->my_edata, edata, ""); mem_contents_t *next = mem_tree_next(tree, contents); if (next != NULL) { node_assert_ordered(contents, next); } mem_contents_t *prev = mem_tree_prev(tree, contents); if (prev != NULL) { node_assert_ordered(prev, contents); } } static void node_insert(mem_tree_t *tree, edata_t *edata, size_t npages) { mem_contents_t *contents = (mem_contents_t *)edata_base_get(edata); contents->my_addr = (uintptr_t)edata_base_get(edata); contents->size = edata_size_get(edata); contents->my_edata = edata; mem_tree_insert(tree, contents); node_check(tree, contents); } static void node_remove(mem_tree_t *tree, edata_t *edata) { mem_contents_t *contents = (mem_contents_t *)edata_base_get(edata); node_check(tree, contents); mem_tree_remove(tree, contents); } TEST_BEGIN(test_stress) { test_skip_if(!hpa_supported()); hpa_shard_t *shard = create_test_data(&hpa_hooks_default, &test_hpa_shard_opts_default); tsdn_t *tsdn = tsd_tsdn(tsd_fetch()); const size_t nlive_edatas_max = 500; size_t nlive_edatas = 0; edata_t **live_edatas = calloc(nlive_edatas_max, sizeof(edata_t *)); /* * Nothing special about this constant; we're only fixing it for * consistency across runs. */ size_t prng_state = (size_t)0x76999ffb014df07c; mem_tree_t tree; mem_tree_new(&tree); bool deferred_work_generated = false; for (size_t i = 0; i < 100 * 1000; i++) { size_t operation = prng_range_zu(&prng_state, 2); if (operation == 0) { /* Alloc */ if (nlive_edatas == nlive_edatas_max) { continue; } /* * We make sure to get an even balance of small and * large allocations. */ size_t npages_min = 1; size_t npages_max = ALLOC_MAX / PAGE; size_t npages = npages_min + prng_range_zu(&prng_state, npages_max - npages_min); edata_t *edata = pai_alloc(tsdn, &shard->pai, npages * PAGE, PAGE, false, false, false, &deferred_work_generated); assert_ptr_not_null(edata, "Unexpected allocation failure"); live_edatas[nlive_edatas] = edata; nlive_edatas++; node_insert(&tree, edata, npages); } else { /* Free. */ if (nlive_edatas == 0) { continue; } size_t victim = prng_range_zu(&prng_state, nlive_edatas); edata_t *to_free = live_edatas[victim]; live_edatas[victim] = live_edatas[nlive_edatas - 1]; nlive_edatas--; node_remove(&tree, to_free); pai_dalloc(tsdn, &shard->pai, to_free, &deferred_work_generated); } } size_t ntreenodes = 0; for (mem_contents_t *contents = mem_tree_first(&tree); contents != NULL; contents = mem_tree_next(&tree, contents)) { ntreenodes++; node_check(&tree, contents); } expect_zu_eq(ntreenodes, nlive_edatas, ""); /* * Test hpa_shard_destroy, which requires as a precondition that all its * extents have been deallocated. */ for (size_t i = 0; i < nlive_edatas; i++) { edata_t *to_free = live_edatas[i]; node_remove(&tree, to_free); pai_dalloc(tsdn, &shard->pai, to_free, &deferred_work_generated); } hpa_shard_destroy(tsdn, shard); free(live_edatas); destroy_test_data(shard); } TEST_END static void expect_contiguous(edata_t **edatas, size_t nedatas) { for (size_t i = 0; i < nedatas; i++) { size_t expected = (size_t)edata_base_get(edatas[0]) + i * PAGE; expect_zu_eq(expected, (size_t)edata_base_get(edatas[i]), "Mismatch at index %zu", i); } } TEST_BEGIN(test_alloc_dalloc_batch) { test_skip_if(!hpa_supported()); hpa_shard_t *shard = create_test_data(&hpa_hooks_default, &test_hpa_shard_opts_default); tsdn_t *tsdn = tsd_tsdn(tsd_fetch()); bool deferred_work_generated = false; enum {NALLOCS = 8}; edata_t *allocs[NALLOCS]; /* * Allocate a mix of ways; first half from regular alloc, second half * from alloc_batch. */ for (size_t i = 0; i < NALLOCS / 2; i++) { allocs[i] = pai_alloc(tsdn, &shard->pai, PAGE, PAGE, /* zero */ false, /* guarded */ false, /* frequent_reuse */ false, &deferred_work_generated); expect_ptr_not_null(allocs[i], "Unexpected alloc failure"); } edata_list_active_t allocs_list; edata_list_active_init(&allocs_list); size_t nsuccess = pai_alloc_batch(tsdn, &shard->pai, PAGE, NALLOCS / 2, &allocs_list, &deferred_work_generated); expect_zu_eq(NALLOCS / 2, nsuccess, "Unexpected oom"); for (size_t i = NALLOCS / 2; i < NALLOCS; i++) { allocs[i] = edata_list_active_first(&allocs_list); edata_list_active_remove(&allocs_list, allocs[i]); } /* * Should have allocated them contiguously, despite the differing * methods used. */ void *orig_base = edata_base_get(allocs[0]); expect_contiguous(allocs, NALLOCS); /* * Batch dalloc the first half, individually deallocate the second half. */ for (size_t i = 0; i < NALLOCS / 2; i++) { edata_list_active_append(&allocs_list, allocs[i]); } pai_dalloc_batch(tsdn, &shard->pai, &allocs_list, &deferred_work_generated); for (size_t i = NALLOCS / 2; i < NALLOCS; i++) { pai_dalloc(tsdn, &shard->pai, allocs[i], &deferred_work_generated); } /* Reallocate (individually), and ensure reuse and contiguity. */ for (size_t i = 0; i < NALLOCS; i++) { allocs[i] = pai_alloc(tsdn, &shard->pai, PAGE, PAGE, /* zero */ false, /* guarded */ false, /* frequent_reuse */ false, &deferred_work_generated); expect_ptr_not_null(allocs[i], "Unexpected alloc failure."); } void *new_base = edata_base_get(allocs[0]); expect_ptr_eq(orig_base, new_base, "Failed to reuse the allocated memory."); expect_contiguous(allocs, NALLOCS); destroy_test_data(shard); } TEST_END static uintptr_t defer_bump_ptr = HUGEPAGE * 123; static void * defer_test_map(size_t size) { void *result = (void *)defer_bump_ptr; defer_bump_ptr += size; return result; } static void defer_test_unmap(void *ptr, size_t size) { (void)ptr; (void)size; } static bool defer_purge_called = false; static void defer_test_purge(void *ptr, size_t size) { (void)ptr; (void)size; defer_purge_called = true; } static bool defer_hugify_called = false; static void defer_test_hugify(void *ptr, size_t size) { defer_hugify_called = true; } static bool defer_dehugify_called = false; static void defer_test_dehugify(void *ptr, size_t size) { defer_dehugify_called = true; } static nstime_t defer_curtime; static void defer_test_curtime(nstime_t *r_time, bool first_reading) { *r_time = defer_curtime; } static uint64_t defer_test_ms_since(nstime_t *past_time) { return (nstime_ns(&defer_curtime) - nstime_ns(past_time)) / 1000 / 1000; } TEST_BEGIN(test_defer_time) { test_skip_if(!hpa_supported()); hpa_hooks_t hooks; hooks.map = &defer_test_map; hooks.unmap = &defer_test_unmap; hooks.purge = &defer_test_purge; hooks.hugify = &defer_test_hugify; hooks.dehugify = &defer_test_dehugify; hooks.curtime = &defer_test_curtime; hooks.ms_since = &defer_test_ms_since; hpa_shard_opts_t opts = test_hpa_shard_opts_default; opts.deferral_allowed = true; hpa_shard_t *shard = create_test_data(&hooks, &opts); bool deferred_work_generated = false; nstime_init(&defer_curtime, 0); tsdn_t *tsdn = tsd_tsdn(tsd_fetch()); edata_t *edatas[HUGEPAGE_PAGES]; for (int i = 0; i < (int)HUGEPAGE_PAGES; i++) { edatas[i] = pai_alloc(tsdn, &shard->pai, PAGE, PAGE, false, false, false, &deferred_work_generated); expect_ptr_not_null(edatas[i], "Unexpected null edata"); } hpa_shard_do_deferred_work(tsdn, shard); expect_false(defer_hugify_called, "Hugified too early"); /* Hugification delay is set to 10 seconds in options. */ nstime_init2(&defer_curtime, 11, 0); hpa_shard_do_deferred_work(tsdn, shard); expect_true(defer_hugify_called, "Failed to hugify"); defer_hugify_called = false; /* Purge. Recall that dirty_mult is .25. */ for (int i = 0; i < (int)HUGEPAGE_PAGES / 2; i++) { pai_dalloc(tsdn, &shard->pai, edatas[i], &deferred_work_generated); } hpa_shard_do_deferred_work(tsdn, shard); expect_false(defer_hugify_called, "Hugified too early"); expect_true(defer_dehugify_called, "Should have dehugified"); expect_true(defer_purge_called, "Should have purged"); defer_hugify_called = false; defer_dehugify_called = false; defer_purge_called = false; /* * Refill the page. We now meet the hugification threshold; we should * be marked for pending hugify. */ for (int i = 0; i < (int)HUGEPAGE_PAGES / 2; i++) { edatas[i] = pai_alloc(tsdn, &shard->pai, PAGE, PAGE, false, false, false, &deferred_work_generated); expect_ptr_not_null(edatas[i], "Unexpected null edata"); } /* * We would be ineligible for hugification, had we not already met the * threshold before dipping below it. */ pai_dalloc(tsdn, &shard->pai, edatas[0], &deferred_work_generated); /* Wait for the threshold again. */ nstime_init2(&defer_curtime, 22, 0); hpa_shard_do_deferred_work(tsdn, shard); expect_true(defer_hugify_called, "Hugified too early"); expect_false(defer_dehugify_called, "Unexpected dehugify"); expect_false(defer_purge_called, "Unexpected purge"); destroy_test_data(shard); } TEST_END int main(void) { /* * These trigger unused-function warnings on CI runs, even if declared * with static inline. */ (void)mem_tree_empty; (void)mem_tree_last; (void)mem_tree_search; (void)mem_tree_nsearch; (void)mem_tree_psearch; (void)mem_tree_iter; (void)mem_tree_reverse_iter; (void)mem_tree_destroy; return test_no_reentrancy( test_alloc_max, test_stress, test_alloc_dalloc_batch, test_defer_time); }