server-skynet-source-3rd-je.../test/unit/hpa.c

#include "test/jemalloc_test.h"

#include "jemalloc/internal/hpa.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;
	base_t *base;
	edata_cache_t shard_edata_cache;

	emap_t emap;
};

static hpa_shard_t *
create_test_data() {
	bool err;
	base_t *base = base_new(TSDN_NULL, /* ind */ SHARD_IND,
	    &ehooks_default_extent_hooks);
	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, "");

	hpa_shard_opts_t opts = HPA_SHARD_OPTS_DEFAULT;
	opts.slab_max_alloc = ALLOC_MAX;

	err = hpa_shard_init(&test_data->shard, &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();
	tsdn_t *tsdn = tsd_tsdn(tsd_fetch());

	edata_t *edata;

	/* Small max */
	edata = pai_alloc(tsdn, &shard->pai, ALLOC_MAX, PAGE, false);
	expect_ptr_not_null(edata, "Allocation of small max failed");
	edata = pai_alloc(tsdn, &shard->pai, ALLOC_MAX + PAGE, PAGE, false);
	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();

	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);

	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);
			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);
		}
	}

	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);
	}
	hpa_shard_destroy(tsdn, shard);

	free(live_edatas);
	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);
}
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`#include "test/jemalloc_test.h"`

			`#include "jemalloc/internal/hpa.h"`

HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`#define SHARD_IND 111`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`#define ALLOC_MAX (HUGEPAGE / 4)`
HPA: add size-exclusion functionality. I.e. only allowing allocations under or over certain sizes. 2020-09-05 09:29:28 +08:00
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`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: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`base_t *base;`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`edata_cache_t shard_edata_cache;`

			`emap_t emap;`
			`};`

			`static hpa_shard_t *`
			`create_test_data() {`
			`bool err;`
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`base_t base = base_new(TSDN_NULL, / ind */ SHARD_IND,`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`&ehooks_default_extent_hooks);`
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`assert_ptr_not_null(base, "");`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00
			`test_data_t *test_data = malloc(sizeof(test_data_t));`
			`assert_ptr_not_null(test_data, "");`

HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`test_data->base = base;`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`err = edata_cache_init(&test_data->shard_edata_cache, base);`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`assert_false(err, "");`

HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`err = emap_init(&test_data->emap, test_data->base, /* zeroed */ false);`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`assert_false(err, "");`

Pull HPA options into a containing struct. Currently that just means max_alloc, but we're about to add more. While we're touching these lines anyways, tweak things to be more in line with testing. 2020-12-09 08:33:39 +08:00			`hpa_shard_opts_t opts = HPA_SHARD_OPTS_DEFAULT;`
			`opts.slab_max_alloc = ALLOC_MAX;`

HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`err = hpa_shard_init(&test_data->shard, &test_data->emap,`
Introduce hpdata_t. Using an edata_t both for hugepages and the allocations within those hugepages was convenient at first, but has outlived its usefulness. Representing hugepages explicitly, with their own data structure, will make future development easier. 2020-11-18 08:32:45 +08:00			`test_data->base, &test_data->shard_edata_cache, SHARD_IND,`
Pull HPA options into a containing struct. Currently that just means max_alloc, but we're about to add more. While we're touching these lines anyways, tweak things to be more in line with testing. 2020-12-09 08:33:39 +08:00			`&opts);`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`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;`
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`base_delete(TSDN_NULL, test_data->base);`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`free(test_data);`
			`}`

HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`TEST_BEGIN(test_alloc_max) {`
HPA unit test: skip if unsupported. Previously, we replicated the logic in hpa_supported in the test as well. 2020-12-03 07:54:29 +08:00			`test_skip_if(!hpa_supported());`
HPA: add size-exclusion functionality. I.e. only allowing allocations under or over certain sizes. 2020-09-05 09:29:28 +08:00
			`hpa_shard_t *shard = create_test_data();`
			`tsdn_t *tsdn = tsd_tsdn(tsd_fetch());`

			`edata_t *edata;`

			`/* Small max */`
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`edata = pai_alloc(tsdn, &shard->pai, ALLOC_MAX, PAGE, false);`
HPA: add size-exclusion functionality. I.e. only allowing allocations under or over certain sizes. 2020-09-05 09:29:28 +08:00			`expect_ptr_not_null(edata, "Allocation of small max failed");`
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`edata = pai_alloc(tsdn, &shard->pai, ALLOC_MAX + PAGE, PAGE, false);`
HPA: add size-exclusion functionality. I.e. only allowing allocations under or over certain sizes. 2020-09-05 09:29:28 +08:00			`expect_ptr_null(edata, "Allocation of larger than small max succeeded");`

			`destroy_test_data(shard);`
			`}`
			`TEST_END`

HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`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) {`
HPA unit test: skip if unsupported. Previously, we replicated the logic in hpa_supported in the test as well. 2020-12-03 07:54:29 +08:00			`test_skip_if(!hpa_supported());`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00
			`hpa_shard_t *shard = create_test_data();`

			`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);`

			`for (size_t i = 0; i < 100 * 1000; i++) {`
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`size_t operation = prng_range_zu(&prng_state, 2);`
			`if (operation == 0) {`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`/* Alloc */`
			`if (nlive_edatas == nlive_edatas_max) {`
			`continue;`
			`}`

			`/*`
			`* We make sure to get an even balance of small and`
			`* large allocations.`
			`*/`
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`size_t npages_min = 1;`
			`size_t npages_max = ALLOC_MAX / PAGE;`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`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);`
			`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);`
			`}`
			`}`

			`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);`
			`}`
			`hpa_shard_destroy(tsdn, shard);`

			`free(live_edatas);`
			`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(`
HPA: Manage whole hugepages at a time. This redesigns the HPA implementation to allow us to manage hugepages all at once, locally, without relying on a global fallback. 2020-11-10 05:49:30 +08:00			`test_alloc_max,`
HPA: Tie components into a PAI implementation. 2020-08-15 04:36:41 +08:00			`test_stress);`
			`}`