#include "test/jemalloc_test.h" TEST_BEGIN(test_small_extent_size) { unsigned nbins, i; size_t sz, extent_size; size_t mib[4]; size_t miblen = sizeof(mib) / sizeof(size_t); /* * Iterate over all small size classes, get their extent sizes, and * verify that the quantized size is the same as the extent size. */ sz = sizeof(unsigned); assert_d_eq(mallctl("arenas.nbins", (void *)&nbins, &sz, NULL, 0), 0, "Unexpected mallctl failure"); assert_d_eq(mallctlnametomib("arenas.bin.0.slab_size", mib, &miblen), 0, "Unexpected mallctlnametomib failure"); for (i = 0; i < nbins; i++) { mib[2] = i; sz = sizeof(size_t); assert_d_eq(mallctlbymib(mib, miblen, (void *)&extent_size, &sz, NULL, 0), 0, "Unexpected mallctlbymib failure"); assert_zu_eq(extent_size, extent_size_quantize_floor(extent_size), "Small extent quantization should be a no-op " "(extent_size=%zu)", extent_size); assert_zu_eq(extent_size, extent_size_quantize_ceil(extent_size), "Small extent quantization should be a no-op " "(extent_size=%zu)", extent_size); } } TEST_END TEST_BEGIN(test_large_extent_size) { bool cache_oblivious; unsigned nlextents, i; size_t sz, extent_size_prev, ceil_prev; size_t mib[4]; size_t miblen = sizeof(mib) / sizeof(size_t); /* * Iterate over all large size classes, get their extent sizes, and * verify that the quantized size is the same as the extent size. */ sz = sizeof(bool); assert_d_eq(mallctl("config.cache_oblivious", (void *)&cache_oblivious, &sz, NULL, 0), 0, "Unexpected mallctl failure"); sz = sizeof(unsigned); assert_d_eq(mallctl("arenas.nlextents", (void *)&nlextents, &sz, NULL, 0), 0, "Unexpected mallctl failure"); assert_d_eq(mallctlnametomib("arenas.lextent.0.size", mib, &miblen), 0, "Unexpected mallctlnametomib failure"); for (i = 0; i < nlextents; i++) { size_t lextent_size, extent_size, floor, ceil; mib[2] = i; sz = sizeof(size_t); assert_d_eq(mallctlbymib(mib, miblen, (void *)&lextent_size, &sz, NULL, 0), 0, "Unexpected mallctlbymib failure"); extent_size = cache_oblivious ? lextent_size + PAGE : lextent_size; floor = extent_size_quantize_floor(extent_size); ceil = extent_size_quantize_ceil(extent_size); assert_zu_eq(extent_size, floor, "Extent quantization should be a no-op for precise size " "(lextent_size=%zu, extent_size=%zu)", lextent_size, extent_size); assert_zu_eq(extent_size, ceil, "Extent quantization should be a no-op for precise size " "(lextent_size=%zu, extent_size=%zu)", lextent_size, extent_size); if (i > 0) { assert_zu_eq(extent_size_prev, extent_size_quantize_floor(extent_size - PAGE), "Floor should be a precise size"); if (extent_size_prev < ceil_prev) { assert_zu_eq(ceil_prev, extent_size, "Ceiling should be a precise size " "(extent_size_prev=%zu, ceil_prev=%zu, " "extent_size=%zu)", extent_size_prev, ceil_prev, extent_size); } } if (i + 1 < nlextents) { extent_size_prev = floor; ceil_prev = extent_size_quantize_ceil(extent_size + PAGE); } } } TEST_END TEST_BEGIN(test_monotonic) { #define SZ_MAX ZU(4 * 1024 * 1024) unsigned i; size_t floor_prev, ceil_prev; floor_prev = 0; ceil_prev = 0; for (i = 1; i <= SZ_MAX >> LG_PAGE; i++) { size_t extent_size, floor, ceil; extent_size = i << LG_PAGE; floor = extent_size_quantize_floor(extent_size); ceil = extent_size_quantize_ceil(extent_size); assert_zu_le(floor, extent_size, "Floor should be <= (floor=%zu, extent_size=%zu, ceil=%zu)", floor, extent_size, ceil); assert_zu_ge(ceil, extent_size, "Ceiling should be >= (floor=%zu, extent_size=%zu, " "ceil=%zu)", floor, extent_size, ceil); assert_zu_le(floor_prev, floor, "Floor should be monotonic " "(floor_prev=%zu, floor=%zu, extent_size=%zu, ceil=%zu)", floor_prev, floor, extent_size, ceil); assert_zu_le(ceil_prev, ceil, "Ceiling should be monotonic " "(floor=%zu, extent_size=%zu, ceil_prev=%zu, ceil=%zu)", floor, extent_size, ceil_prev, ceil); floor_prev = floor; ceil_prev = ceil; } } TEST_END int main(void) { return test( test_small_extent_size, test_large_extent_size, test_monotonic); }