#include "test/jemalloc_test.h" #include "jemalloc/internal/rtree.h" #define INVALID_ARENA_IND ((1U << MALLOCX_ARENA_BITS) - 1) /* Potentially too large to safely place on the stack. */ rtree_t test_rtree; TEST_BEGIN(test_rtree_read_empty) { tsdn_t *tsdn; tsdn = tsdn_fetch(); base_t *base = base_new(tsdn, 0, &ehooks_default_extent_hooks, /* metadata_use_hooks */ true); expect_ptr_not_null(base, "Unexpected base_new failure"); rtree_t *rtree = &test_rtree; rtree_ctx_t rtree_ctx; rtree_ctx_data_init(&rtree_ctx); expect_false(rtree_new(rtree, base, false), "Unexpected rtree_new() failure"); rtree_contents_t contents; expect_true(rtree_read_independent(tsdn, rtree, &rtree_ctx, PAGE, &contents), "rtree_read_independent() should fail on empty rtree."); base_delete(tsdn, base); } TEST_END #undef NTHREADS #undef NITERS #undef SEED static edata_t * alloc_edata(void) { void *ret = mallocx(sizeof(edata_t), MALLOCX_ALIGN(EDATA_ALIGNMENT)); assert_ptr_not_null(ret, "Unexpected mallocx() failure"); return ret; } TEST_BEGIN(test_rtree_extrema) { edata_t *edata_a, *edata_b; edata_a = alloc_edata(); edata_b = alloc_edata(); edata_init(edata_a, INVALID_ARENA_IND, NULL, SC_LARGE_MINCLASS, false, sz_size2index(SC_LARGE_MINCLASS), 0, extent_state_active, false, false, EXTENT_PAI_PAC, EXTENT_NOT_HEAD); edata_init(edata_b, INVALID_ARENA_IND, NULL, 0, false, SC_NSIZES, 0, extent_state_active, false, false, EXTENT_PAI_PAC, EXTENT_NOT_HEAD); tsdn_t *tsdn = tsdn_fetch(); base_t *base = base_new(tsdn, 0, &ehooks_default_extent_hooks, /* metadata_use_hooks */ true); expect_ptr_not_null(base, "Unexpected base_new failure"); rtree_t *rtree = &test_rtree; rtree_ctx_t rtree_ctx; rtree_ctx_data_init(&rtree_ctx); expect_false(rtree_new(rtree, base, false), "Unexpected rtree_new() failure"); rtree_contents_t contents_a; contents_a.edata = edata_a; contents_a.metadata.szind = edata_szind_get(edata_a); contents_a.metadata.slab = edata_slab_get(edata_a); contents_a.metadata.is_head = edata_is_head_get(edata_a); contents_a.metadata.state = edata_state_get(edata_a); expect_false(rtree_write(tsdn, rtree, &rtree_ctx, PAGE, contents_a), "Unexpected rtree_write() failure"); expect_false(rtree_write(tsdn, rtree, &rtree_ctx, PAGE, contents_a), "Unexpected rtree_write() failure"); rtree_contents_t read_contents_a = rtree_read(tsdn, rtree, &rtree_ctx, PAGE); expect_true(contents_a.edata == read_contents_a.edata && contents_a.metadata.szind == read_contents_a.metadata.szind && contents_a.metadata.slab == read_contents_a.metadata.slab && contents_a.metadata.is_head == read_contents_a.metadata.is_head && contents_a.metadata.state == read_contents_a.metadata.state, "rtree_read() should return previously set value"); rtree_contents_t contents_b; contents_b.edata = edata_b; contents_b.metadata.szind = edata_szind_get_maybe_invalid(edata_b); contents_b.metadata.slab = edata_slab_get(edata_b); contents_b.metadata.is_head = edata_is_head_get(edata_b); contents_b.metadata.state = edata_state_get(edata_b); expect_false(rtree_write(tsdn, rtree, &rtree_ctx, ~((uintptr_t)0), contents_b), "Unexpected rtree_write() failure"); rtree_contents_t read_contents_b = rtree_read(tsdn, rtree, &rtree_ctx, ~((uintptr_t)0)); assert_true(contents_b.edata == read_contents_b.edata && contents_b.metadata.szind == read_contents_b.metadata.szind && contents_b.metadata.slab == read_contents_b.metadata.slab && contents_b.metadata.is_head == read_contents_b.metadata.is_head && contents_b.metadata.state == read_contents_b.metadata.state, "rtree_read() should return previously set value"); base_delete(tsdn, base); } TEST_END TEST_BEGIN(test_rtree_bits) { tsdn_t *tsdn = tsdn_fetch(); base_t *base = base_new(tsdn, 0, &ehooks_default_extent_hooks, /* metadata_use_hooks */ true); expect_ptr_not_null(base, "Unexpected base_new failure"); uintptr_t keys[] = {PAGE, PAGE + 1, PAGE + (((uintptr_t)1) << LG_PAGE) - 1}; edata_t *edata_c = alloc_edata(); edata_init(edata_c, INVALID_ARENA_IND, NULL, 0, false, SC_NSIZES, 0, extent_state_active, false, false, EXTENT_PAI_PAC, EXTENT_NOT_HEAD); rtree_t *rtree = &test_rtree; rtree_ctx_t rtree_ctx; rtree_ctx_data_init(&rtree_ctx); expect_false(rtree_new(rtree, base, false), "Unexpected rtree_new() failure"); for (unsigned i = 0; i < sizeof(keys)/sizeof(uintptr_t); i++) { rtree_contents_t contents; contents.edata = edata_c; contents.metadata.szind = SC_NSIZES; contents.metadata.slab = false; contents.metadata.is_head = false; contents.metadata.state = extent_state_active; expect_false(rtree_write(tsdn, rtree, &rtree_ctx, keys[i], contents), "Unexpected rtree_write() failure"); for (unsigned j = 0; j < sizeof(keys)/sizeof(uintptr_t); j++) { expect_ptr_eq(rtree_read(tsdn, rtree, &rtree_ctx, keys[j]).edata, edata_c, "rtree_edata_read() should return previously set " "value and ignore insignificant key bits; i=%u, " "j=%u, set key=%#"FMTxPTR", get key=%#"FMTxPTR, i, j, keys[i], keys[j]); } expect_ptr_null(rtree_read(tsdn, rtree, &rtree_ctx, (((uintptr_t)2) << LG_PAGE)).edata, "Only leftmost rtree leaf should be set; i=%u", i); rtree_clear(tsdn, rtree, &rtree_ctx, keys[i]); } base_delete(tsdn, base); } TEST_END TEST_BEGIN(test_rtree_random) { #define NSET 16 #define SEED 42 sfmt_t *sfmt = init_gen_rand(SEED); tsdn_t *tsdn = tsdn_fetch(); base_t *base = base_new(tsdn, 0, &ehooks_default_extent_hooks, /* metadata_use_hooks */ true); expect_ptr_not_null(base, "Unexpected base_new failure"); uintptr_t keys[NSET]; rtree_t *rtree = &test_rtree; rtree_ctx_t rtree_ctx; rtree_ctx_data_init(&rtree_ctx); edata_t *edata_d = alloc_edata(); edata_init(edata_d, INVALID_ARENA_IND, NULL, 0, false, SC_NSIZES, 0, extent_state_active, false, false, EXTENT_PAI_PAC, EXTENT_NOT_HEAD); expect_false(rtree_new(rtree, base, false), "Unexpected rtree_new() failure"); for (unsigned i = 0; i < NSET; i++) { keys[i] = (uintptr_t)gen_rand64(sfmt); rtree_leaf_elm_t *elm = rtree_leaf_elm_lookup(tsdn, rtree, &rtree_ctx, keys[i], false, true); expect_ptr_not_null(elm, "Unexpected rtree_leaf_elm_lookup() failure"); rtree_contents_t contents; contents.edata = edata_d; contents.metadata.szind = SC_NSIZES; contents.metadata.slab = false; contents.metadata.is_head = false; contents.metadata.state = edata_state_get(edata_d); rtree_leaf_elm_write(tsdn, rtree, elm, contents); expect_ptr_eq(rtree_read(tsdn, rtree, &rtree_ctx, keys[i]).edata, edata_d, "rtree_edata_read() should return previously set value"); } for (unsigned i = 0; i < NSET; i++) { expect_ptr_eq(rtree_read(tsdn, rtree, &rtree_ctx, keys[i]).edata, edata_d, "rtree_edata_read() should return previously set value, " "i=%u", i); } for (unsigned i = 0; i < NSET; i++) { rtree_clear(tsdn, rtree, &rtree_ctx, keys[i]); expect_ptr_null(rtree_read(tsdn, rtree, &rtree_ctx, keys[i]).edata, "rtree_edata_read() should return previously set value"); } for (unsigned i = 0; i < NSET; i++) { expect_ptr_null(rtree_read(tsdn, rtree, &rtree_ctx, keys[i]).edata, "rtree_edata_read() should return previously set value"); } base_delete(tsdn, base); fini_gen_rand(sfmt); #undef NSET #undef SEED } TEST_END static void test_rtree_range_write(tsdn_t *tsdn, rtree_t *rtree, uintptr_t start, uintptr_t end) { rtree_ctx_t rtree_ctx; rtree_ctx_data_init(&rtree_ctx); edata_t *edata_e = alloc_edata(); edata_init(edata_e, INVALID_ARENA_IND, NULL, 0, false, SC_NSIZES, 0, extent_state_active, false, false, EXTENT_PAI_PAC, EXTENT_NOT_HEAD); rtree_contents_t contents; contents.edata = edata_e; contents.metadata.szind = SC_NSIZES; contents.metadata.slab = false; contents.metadata.is_head = false; contents.metadata.state = extent_state_active; expect_false(rtree_write(tsdn, rtree, &rtree_ctx, start, contents), "Unexpected rtree_write() failure"); expect_false(rtree_write(tsdn, rtree, &rtree_ctx, end, contents), "Unexpected rtree_write() failure"); rtree_write_range(tsdn, rtree, &rtree_ctx, start, end, contents); for (uintptr_t i = 0; i < ((end - start) >> LG_PAGE); i++) { expect_ptr_eq(rtree_read(tsdn, rtree, &rtree_ctx, start + (i << LG_PAGE)).edata, edata_e, "rtree_edata_read() should return previously set value"); } rtree_clear_range(tsdn, rtree, &rtree_ctx, start, end); rtree_leaf_elm_t *elm; for (uintptr_t i = 0; i < ((end - start) >> LG_PAGE); i++) { elm = rtree_leaf_elm_lookup(tsdn, rtree, &rtree_ctx, start + (i << LG_PAGE), false, false); expect_ptr_not_null(elm, "Should have been initialized."); expect_ptr_null(rtree_leaf_elm_read(tsdn, rtree, elm, false).edata, "Should have been cleared."); } } TEST_BEGIN(test_rtree_range) { tsdn_t *tsdn = tsdn_fetch(); base_t *base = base_new(tsdn, 0, &ehooks_default_extent_hooks, /* metadata_use_hooks */ true); expect_ptr_not_null(base, "Unexpected base_new failure"); rtree_t *rtree = &test_rtree; expect_false(rtree_new(rtree, base, false), "Unexpected rtree_new() failure"); /* Not crossing rtree node boundary first. */ uintptr_t start = ZU(1) << rtree_leaf_maskbits(); uintptr_t end = start + (ZU(100) << LG_PAGE); test_rtree_range_write(tsdn, rtree, start, end); /* Crossing rtree node boundary. */ start = (ZU(1) << rtree_leaf_maskbits()) - (ZU(10) << LG_PAGE); end = start + (ZU(100) << LG_PAGE); assert_ptr_ne((void *)rtree_leafkey(start), (void *)rtree_leafkey(end), "The range should span across two rtree nodes"); test_rtree_range_write(tsdn, rtree, start, end); base_delete(tsdn, base); } TEST_END int main(void) { return test( test_rtree_read_empty, test_rtree_extrema, test_rtree_bits, test_rtree_random, test_rtree_range); }