#include "test/jemalloc_test.h" static unsigned get_nsizes_impl(const char *cmd) { unsigned ret; size_t z; z = sizeof(unsigned); assert_d_eq(mallctl(cmd, (void *)&ret, &z, NULL, 0), 0, "Unexpected mallctl(\"%s\", ...) failure", cmd); return (ret); } static unsigned get_nhuge(void) { return (get_nsizes_impl("arenas.nhchunks")); } static size_t get_size_impl(const char *cmd, size_t ind) { size_t ret; size_t z; size_t mib[4]; size_t miblen = 4; z = sizeof(size_t); assert_d_eq(mallctlnametomib(cmd, mib, &miblen), 0, "Unexpected mallctlnametomib(\"%s\", ...) failure", cmd); mib[2] = ind; z = sizeof(size_t); assert_d_eq(mallctlbymib(mib, miblen, (void *)&ret, &z, NULL, 0), 0, "Unexpected mallctlbymib([\"%s\", %zu], ...) failure", cmd, ind); return (ret); } static size_t get_huge_size(size_t ind) { return (get_size_impl("arenas.hchunk.0.size", ind)); } /* * On systems which can't merge extents, tests that call this function generate * a lot of dirty memory very quickly. Purging between cycles mitigates * potential OOM on e.g. 32-bit Windows. */ static void purge(void) { assert_d_eq(mallctl("arena.0.purge", NULL, NULL, NULL, 0), 0, "Unexpected mallctl error"); } TEST_BEGIN(test_overflow) { size_t hugemax; hugemax = get_huge_size(get_nhuge()-1); assert_ptr_null(mallocx(hugemax+1, 0), "Expected OOM for mallocx(size=%#zx, 0)", hugemax+1); assert_ptr_null(mallocx(ZU(PTRDIFF_MAX)+1, 0), "Expected OOM for mallocx(size=%#zx, 0)", ZU(PTRDIFF_MAX)+1); assert_ptr_null(mallocx(SIZE_T_MAX, 0), "Expected OOM for mallocx(size=%#zx, 0)", SIZE_T_MAX); assert_ptr_null(mallocx(1, MALLOCX_ALIGN(ZU(PTRDIFF_MAX)+1)), "Expected OOM for mallocx(size=1, MALLOCX_ALIGN(%#zx))", ZU(PTRDIFF_MAX)+1); } TEST_END TEST_BEGIN(test_oom) { size_t hugemax; bool oom; void *ptrs[3]; unsigned i; /* * It should be impossible to allocate three objects that each consume * nearly half the virtual address space. */ hugemax = get_huge_size(get_nhuge()-1); oom = false; for (i = 0; i < sizeof(ptrs) / sizeof(void *); i++) { ptrs[i] = mallocx(hugemax, 0); if (ptrs[i] == NULL) oom = true; } assert_true(oom, "Expected OOM during series of calls to mallocx(size=%zu, 0)", hugemax); for (i = 0; i < sizeof(ptrs) / sizeof(void *); i++) { if (ptrs[i] != NULL) dallocx(ptrs[i], 0); } purge(); #if LG_SIZEOF_PTR == 3 assert_ptr_null(mallocx(0x8000000000000000ULL, MALLOCX_ALIGN(0x8000000000000000ULL)), "Expected OOM for mallocx()"); assert_ptr_null(mallocx(0x8000000000000000ULL, MALLOCX_ALIGN(0x80000000)), "Expected OOM for mallocx()"); #else assert_ptr_null(mallocx(0x80000000UL, MALLOCX_ALIGN(0x80000000UL)), "Expected OOM for mallocx()"); #endif } TEST_END TEST_BEGIN(test_basic) { #define MAXSZ (((size_t)1) << 23) size_t sz; for (sz = 1; sz < MAXSZ; sz = nallocx(sz, 0) + 1) { size_t nsz, rsz; void *p; nsz = nallocx(sz, 0); assert_zu_ne(nsz, 0, "Unexpected nallocx() error"); p = mallocx(sz, 0); assert_ptr_not_null(p, "Unexpected mallocx(size=%zx, flags=0) error", sz); rsz = sallocx(p, 0); assert_zu_ge(rsz, sz, "Real size smaller than expected"); assert_zu_eq(nsz, rsz, "nallocx()/sallocx() size mismatch"); dallocx(p, 0); p = mallocx(sz, 0); assert_ptr_not_null(p, "Unexpected mallocx(size=%zx, flags=0) error", sz); dallocx(p, 0); nsz = nallocx(sz, MALLOCX_ZERO); assert_zu_ne(nsz, 0, "Unexpected nallocx() error"); p = mallocx(sz, MALLOCX_ZERO); assert_ptr_not_null(p, "Unexpected mallocx(size=%zx, flags=MALLOCX_ZERO) error", nsz); rsz = sallocx(p, 0); assert_zu_eq(nsz, rsz, "nallocx()/sallocx() rsize mismatch"); dallocx(p, 0); purge(); } #undef MAXSZ } TEST_END TEST_BEGIN(test_alignment_and_size) { #define MAXALIGN (((size_t)1) << 23) #define NITER 4 size_t nsz, rsz, sz, alignment, total; unsigned i; void *ps[NITER]; for (i = 0; i < NITER; i++) ps[i] = NULL; for (alignment = 8; alignment <= MAXALIGN; alignment <<= 1) { total = 0; for (sz = 1; sz < 3 * alignment && sz < (1U << 31); sz += (alignment >> (LG_SIZEOF_PTR-1)) - 1) { for (i = 0; i < NITER; i++) { nsz = nallocx(sz, MALLOCX_ALIGN(alignment) | MALLOCX_ZERO); assert_zu_ne(nsz, 0, "nallocx() error for alignment=%zu, " "size=%zu (%#zx)", alignment, sz, sz); ps[i] = mallocx(sz, MALLOCX_ALIGN(alignment) | MALLOCX_ZERO); assert_ptr_not_null(ps[i], "mallocx() error for alignment=%zu, " "size=%zu (%#zx)", alignment, sz, sz); rsz = sallocx(ps[i], 0); assert_zu_ge(rsz, sz, "Real size smaller than expected for " "alignment=%zu, size=%zu", alignment, sz); assert_zu_eq(nsz, rsz, "nallocx()/sallocx() size mismatch for " "alignment=%zu, size=%zu", alignment, sz); assert_ptr_null( (void *)((uintptr_t)ps[i] & (alignment-1)), "%p inadequately aligned for" " alignment=%zu, size=%zu", ps[i], alignment, sz); total += rsz; if (total >= (MAXALIGN << 1)) break; } for (i = 0; i < NITER; i++) { if (ps[i] != NULL) { dallocx(ps[i], 0); ps[i] = NULL; } } } purge(); } #undef MAXALIGN #undef NITER } TEST_END int main(void) { return (test( test_overflow, test_oom, test_basic, test_alignment_and_size)); }