/* * Copyright 2025 The OpenSSL Project Authors. All Rights Reserved. * * Licensed under the Apache License 2.0 (the "License"). You may not use * this file except in compliance with the License. You can obtain a copy * in the file LICENSE in the source distribution or at * https://www.openssl.org/source/license.html */ #include #include #include #include #include #include #include "testutil.h" #ifndef USE_CUSTOM_ALLOC_FNS # define USE_CUSTOM_ALLOC_FNS 0 #endif /* Change to 1 to see every call of the custom allocator functions */ #define CUSTOM_FN_PRINT_CALLS 0 enum exp_ret_flags { EXP_FAIL = 0x10 }; enum exp_ret { /** Expecting success */ EXP_NONNULL, /** Zero-size special case: can either return NULL or a special pointer */ EXP_ZERO_SIZE, /** Expecting an error due to insufficient memory */ EXP_OOM = EXP_FAIL, /** Expecting error due to invalid arguments */ EXP_INVAL, /** Expecting error due to integer overflow */ EXP_INT_OF, }; #define IS_FAIL(exp_) (!!((int) (exp) & (int) EXP_FAIL)) static const char test_fn[] = "test_file_name"; enum { test_line = 31415926 }; #define SQRT_SIZE_T ((size_t) 1 << (sizeof(size_t) * (CHAR_BIT / 2))) #define SQSQRT_SIZE_T ((size_t) 1 << (sizeof(size_t) * (CHAR_BIT / 4))) #define MIN(a, b) ((a) < (b) ? (a) : (b)) #if !defined(OPENSSL_NO_CRYPTO_MDEBUG) || USE_CUSTOM_ALLOC_FNS struct call_counts { int malloc; int realloc; int free; }; #endif #if !defined(OPENSSL_NO_CRYPTO_MDEBUG) static struct call_counts mdebug_counts; #endif #if USE_CUSTOM_ALLOC_FNS static struct call_counts saved_custom_counts, cur_custom_counts; #endif static const struct array_alloc_vector { size_t nmemb; size_t size; enum exp_ret exp_malloc; enum exp_ret exp_calloc; } array_alloc_vectors[] = { { 0, 0, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, 1, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, SQRT_SIZE_T - 1, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, SQRT_SIZE_T, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, SIZE_MAX, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 1, 0, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { SQRT_SIZE_T - 1, 0, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { SIZE_MAX, 0, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 1, 1, EXP_NONNULL, EXP_NONNULL }, { SQRT_SIZE_T / 2, SQRT_SIZE_T, EXP_OOM, EXP_OOM }, { SQRT_SIZE_T, SQRT_SIZE_T, EXP_ZERO_SIZE, EXP_INT_OF }, /* Some magic numbers */ #if SIZE_MAX == 4294967295U { 641, 6700417, EXP_NONNULL, EXP_INT_OF }, #else /* Of course there are no archutectures other than 32- and 64-bit ones */ { 274177, 67280421310721LLU, EXP_NONNULL, EXP_INT_OF }, #endif { SIZE_MAX / 4 * 3, SIZE_MAX / 2, EXP_OOM, EXP_INT_OF }, }; static const struct array_realloc_vector { size_t size; size_t orig_nmemb; size_t new_nmemb; enum exp_ret exp_orig; enum exp_ret exp_new; enum exp_ret exp_orig_array; enum exp_ret exp_new_array; } array_realloc_vectors[] = { { 0, 0, 0, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, 0, 1, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, 0, SIZE_MAX, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, 1, 0, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, SIZE_MAX, 0, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, 1, SIZE_MAX, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, SIZE_MAX, 1, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, SIZE_MAX, SIZE_MAX, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 1, 0, 0, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 1, 0, 1, EXP_ZERO_SIZE, EXP_NONNULL, EXP_ZERO_SIZE, EXP_NONNULL }, { 1, 0, SIZE_MAX, EXP_ZERO_SIZE, EXP_OOM, EXP_ZERO_SIZE, EXP_OOM }, { 1, 1, 0, EXP_NONNULL, EXP_ZERO_SIZE, EXP_NONNULL, EXP_ZERO_SIZE }, { 1, SIZE_MAX, 0, EXP_OOM, EXP_ZERO_SIZE, EXP_OOM, EXP_ZERO_SIZE }, { 1, 123, 345, EXP_NONNULL, EXP_NONNULL, EXP_NONNULL, EXP_NONNULL }, { 1, 345, 123, EXP_NONNULL, EXP_NONNULL, EXP_NONNULL, EXP_NONNULL }, { 12, 34, 56, EXP_NONNULL, EXP_NONNULL, EXP_NONNULL, EXP_NONNULL }, { 12, 56, 34, EXP_NONNULL, EXP_NONNULL, EXP_NONNULL, EXP_NONNULL }, { SQSQRT_SIZE_T, SIZE_MAX / SQSQRT_SIZE_T + 1, SIZE_MAX / SQSQRT_SIZE_T + 2, EXP_ZERO_SIZE, EXP_NONNULL, EXP_INT_OF, EXP_INT_OF }, { SQSQRT_SIZE_T, SIZE_MAX / SQSQRT_SIZE_T + 2, SIZE_MAX / SQSQRT_SIZE_T + 1, EXP_NONNULL, EXP_ZERO_SIZE, EXP_INT_OF, EXP_INT_OF }, { 123, 12, SIZE_MAX / 123 + 12, EXP_NONNULL, EXP_NONNULL, EXP_NONNULL, EXP_INT_OF }, { 123, SIZE_MAX / 123 + 12, 12, EXP_NONNULL, EXP_NONNULL, EXP_INT_OF, EXP_NONNULL }, }; static const struct array_aligned_alloc_vector { size_t nmemb; size_t size; size_t align; enum exp_ret exp; enum exp_ret exp_array; } array_aligned_alloc_vectors[] = { { 0, 0, 0, EXP_INVAL, EXP_INVAL }, { 0, 0, 1, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, 0, 2, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, 0, 3, EXP_INVAL, EXP_INVAL }, { 0, 0, 4, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, 0, 64, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 0, 0, SQSQRT_SIZE_T, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, /* * This one gets mem_alloc_custom_fns_test killed with SIGKILL * on the linux-arm64 github runner. */ /* { 0, 0, SQRT_SIZE_T, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, */ { 0, 0, 64, EXP_ZERO_SIZE, EXP_ZERO_SIZE }, { 8, 8, 63, EXP_INVAL, EXP_INVAL }, { 8, 8, 64, EXP_NONNULL, EXP_NONNULL }, { SIZE_MAX / 8 + 9, 8, 64, EXP_NONNULL, EXP_INT_OF }, /* * posix_memalign expected to fail with ENOMEM, while the open-coded * implementation tries to alloc size + alignment, which should fail * on integer overflow. */ { 1, SIZE_MAX / 2 + 2, SIZE_MAX / 2 + 1, #if (defined(_BSD_SOURCE) \ || (defined(_POSIX_C_SOURCE) && _POSIX_C_SOURCE >= 200112L)) \ && !USE_CUSTOM_ALLOC_FNS || defined(OPENSSL_SMALL_FOOTPRINT) EXP_OOM, EXP_OOM #else EXP_INT_OF, EXP_INT_OF #endif }, }; static int secure_memory_is_secure; #if USE_CUSTOM_ALLOC_FNS static void *my_malloc(const size_t num, const char * const file, const int line) { void * const p = malloc(num); # if CUSTOM_FN_PRINT_CALLS if (file == test_fn || file == NULL || (strcmp(file, OPENSSL_FILE) == 0 && file[0] != '\0')) TEST_note("[%s:%d]: malloc(%#zx) -> %p", file, line, num, p); # endif if (cur_custom_counts.malloc < INT_MAX) cur_custom_counts.malloc++; return p; } static void *my_realloc(void * const addr, const size_t num, const char * const file, const int line) { # if CUSTOM_FN_PRINT_CALLS const uintptr_t old_addr = (uintptr_t) addr; # endif void * const p = realloc(addr, num); # if CUSTOM_FN_PRINT_CALLS if (file == test_fn || file == NULL || (strcmp(file, OPENSSL_FILE) == 0 && file[0] != '\0')) TEST_note("[%s:%d]: realloc(%#" PRIxPTR ", %#zx) -> %p", file, line, old_addr, num, p); # endif if (cur_custom_counts.realloc < INT_MAX) cur_custom_counts.realloc++; return p; } static void my_free(void * const addr, const char * const file, const int line) { # if CUSTOM_FN_PRINT_CALLS if (file == test_fn || file == NULL || (strcmp(file, OPENSSL_FILE) == 0 && file[0] != '\0')) TEST_note("[%s:%d]: free(%p)", file, line, addr); # endif if (cur_custom_counts.free < INT_MAX) cur_custom_counts.free++; free(addr); } #endif /* USE_CUSTOM_ALLOC_FNS */ static bool check_zero_mem(char *p, size_t sz) { for (size_t i = 0; i < sz; i++) { if (p[i] != 0) { TEST_error("Non-zero byte %zu of %zu (%#04hhx)", i, sz, p[i]); return false; } } return true; } static void save_counts(void) { #if !defined(OPENSSL_NO_CRYPTO_MDEBUG) CRYPTO_get_alloc_counts(&mdebug_counts.malloc, &mdebug_counts.realloc, &mdebug_counts.free); #endif #if USE_CUSTOM_ALLOC_FNS saved_custom_counts = cur_custom_counts; #endif } static void check_exp_prep(void) { ERR_set_mark(); save_counts(); } /* * Retrieve fresh call counts and check against the expected ones, * when the latter are no less than zero. */ static bool check_counts(int exp_mallocs, int exp_reallocs, int exp_frees) { int test_result = 1; #if !defined(OPENSSL_NO_CRYPTO_MDEBUG) { struct call_counts cur; CRYPTO_get_alloc_counts(&cur.malloc, &cur.realloc, &cur.free); if (exp_mallocs >= 0 && !TEST_int_eq(cur.malloc - mdebug_counts.malloc, exp_mallocs)) test_result = 0; if (exp_reallocs >= 0 && !TEST_int_eq(cur.realloc - mdebug_counts.realloc, exp_reallocs)) test_result = 0; if (exp_frees >= 0 && !TEST_int_eq(cur.free - mdebug_counts.free, exp_frees)) test_result = 0; } #endif #if USE_CUSTOM_ALLOC_FNS if (exp_mallocs >= 0 && !TEST_int_eq(cur_custom_counts.malloc - saved_custom_counts.malloc, exp_mallocs)) test_result = 0; if (exp_reallocs >= 0 && !TEST_int_eq(cur_custom_counts.realloc - saved_custom_counts.realloc, exp_reallocs)) test_result = 0; if (exp_frees >= 0 && !TEST_int_eq(cur_custom_counts.free - saved_custom_counts.free, exp_frees)) test_result = 0; #endif return test_result; } static int check_exp(const char * const fn, const int ln, const size_t sz, const bool secure, const bool zero, char * const ret, const enum exp_ret exp, int exp_mallocs, int exp_reallocs) { int num_errs; unsigned long err_code = 0; const char *err_file = NULL; int err_line = 0; const char *err_func = NULL; const char *err_data = NULL; int err_flags = 0; int test_result = 1; unsigned long oom_err; num_errs = ERR_count_to_mark(); if (num_errs > 0) { err_code = ERR_peek_last_error_all(&err_file, &err_line, &err_func, &err_data, &err_flags); } switch (exp) { case EXP_OOM: oom_err = secure ? CRYPTO_R_SECURE_MALLOC_FAILURE : ERR_R_MALLOC_FAILURE; if (!TEST_ptr_null(ret) || !TEST_int_eq(num_errs, 1) || !TEST_ulong_eq(err_code, ERR_PACK(ERR_LIB_CRYPTO, 0, oom_err)) || !TEST_str_eq(err_file, fn) || !TEST_int_eq(err_line, ln) || !TEST_str_eq(err_func, "") || !TEST_str_eq(err_data, "") || !TEST_int_eq(err_flags, 0)) test_result = 0; break; case EXP_INVAL: if (!TEST_ptr_null(ret) || !TEST_int_eq(num_errs, 1) || !TEST_ulong_eq(err_code, ERR_PACK(ERR_LIB_CRYPTO, 0, ERR_R_PASSED_INVALID_ARGUMENT)) || !TEST_str_eq(err_file, fn) || !TEST_int_eq(err_line, ln) || !TEST_str_eq(err_func, "") || !TEST_str_eq(err_data, "") || !TEST_int_eq(err_flags, 0)) test_result = 0; break; case EXP_INT_OF: if (!TEST_ptr_null(ret) || !TEST_int_eq(num_errs, 1) || !TEST_ulong_eq(err_code, ERR_PACK(ERR_LIB_CRYPTO, 0, CRYPTO_R_INTEGER_OVERFLOW)) || !TEST_str_eq(err_file, fn) || !TEST_int_eq(err_line, ln) || !TEST_str_eq(err_func, "") || !TEST_str_eq(err_data, "") || !TEST_int_eq(err_flags, 0)) test_result = 0; break; case EXP_NONNULL: if (!TEST_ptr(ret) || !TEST_int_eq(num_errs, 0)) { test_result = 0; } else if (zero) { if (!check_zero_mem(ret, sz)) test_result = 0; } break; case EXP_ZERO_SIZE: /* * Since the pointer ca either be NULL or non-NULL, depending * on implementation, we can only check for the absence of errors. */ if (!TEST_int_eq(num_errs, 0)) test_result = 0; break; default: TEST_error("Unexpected expected result"); test_result = 0; } ERR_pop_to_mark(); /* * We don't check for frees here as there's a non-trivial amount * of free calls in the error handling routines. */ test_result &= check_counts(exp_mallocs, exp_reallocs, -1); return test_result; } static int test_xalloc(const bool secure, const bool array, const bool zero, const bool macro, const struct array_alloc_vector *td) { char *ret; int ln = test_line; size_t sz = td->nmemb * td->size; enum exp_ret exp = array ? td->exp_calloc : td->exp_malloc; bool really_secure = secure && secure_memory_is_secure; int exp_cnt = 0; int res; check_exp_prep(); if (macro) { if (secure) { if (array) { if (zero) ln = OPENSSL_LINE, ret = OPENSSL_secure_calloc(td->nmemb, td->size); else ln = OPENSSL_LINE, ret = OPENSSL_secure_malloc_array(td->nmemb, td->size); } else { if (zero) ln = OPENSSL_LINE, ret = OPENSSL_secure_zalloc(sz); else ln = OPENSSL_LINE, ret = OPENSSL_secure_malloc(sz); } } else { if (array) { if (zero) ln = OPENSSL_LINE, ret = OPENSSL_calloc(td->nmemb, td->size); else ln = OPENSSL_LINE, ret = OPENSSL_malloc_array(td->nmemb, td->size); } else { if (zero) ln = OPENSSL_LINE, ret = OPENSSL_zalloc(sz); else ln = OPENSSL_LINE, ret = OPENSSL_malloc(sz); } } } else { if (array) { ret = (secure ? (zero ? CRYPTO_secure_calloc : CRYPTO_secure_malloc_array) : (zero ? CRYPTO_calloc : CRYPTO_malloc_array))(td->nmemb, td->size, test_fn, test_line); } else { ret = (secure ? (zero ? CRYPTO_secure_zalloc : CRYPTO_secure_malloc) : (zero ? CRYPTO_zalloc : CRYPTO_malloc))(sz, test_fn, test_line); } } /* * There is an OPENSSL_calloc in ERR_set_debug, triggered * from ossl_report_alloc_err_ex. */ exp_cnt += IS_FAIL(exp) && (!macro || (bool) OPENSSL_FILE[0]); /* * Secure allocations don't trigger alloc counting. * EXP_OOM is special as it comes on return from the (called and counted) * allocation function. */ if (!really_secure) exp_cnt += !!(exp == EXP_OOM || !IS_FAIL(exp)); res = check_exp(macro ? OPENSSL_FILE : test_fn, ln, sz, really_secure, zero, ret, exp, exp_cnt, 0); if (really_secure) OPENSSL_secure_free(ret); else OPENSSL_free(ret); return res; } static int test_xrealloc(const bool clear, const bool array, const bool macro, const struct array_realloc_vector *td) { char *ret = NULL; char *old_ret = NULL; int exp_malloc_cnt, exp_realloc_cnt; int res = 1; size_t i; /* * Do two passes, first with NULL ptr, then with the result of the first * call. */ for (i = 0; i < 2; i++) { size_t nmemb = i ? td->new_nmemb : td->orig_nmemb; size_t old_nmemb = i ? td->orig_nmemb : 0; size_t sz = nmemb * td->size; size_t old_sz = old_nmemb * td->size; int ln = test_line; enum exp_ret exp = i ? (array ? td->exp_new_array : td->exp_new) : (array ? td->exp_orig_array : td->exp_orig); enum exp_ret exp2 = !i ? (array ? td->exp_new_array : td->exp_new) : (array ? td->exp_orig_array : td->exp_orig); exp_malloc_cnt = exp_realloc_cnt = 0; /* clear_realloc_array checks both new and old sizes */ if (clear && array && i && exp2 == EXP_INT_OF) exp = EXP_INT_OF; if (exp != EXP_INT_OF) { if (clear) { /* * clear_alloc just calls cleanse if contraction has been * requested. */ if (ret == NULL || sz > old_sz) exp_malloc_cnt++; } else { exp_realloc_cnt++; #if !USE_CUSTOM_ALLOC_FNS /* CRYPTO_malloc() is called explicitly when p is NULL. */ if (ret == NULL) exp_malloc_cnt++; #endif } } else { if (!macro || OPENSSL_FILE[0] != '\0') exp_malloc_cnt++; } check_exp_prep(); if (macro) { if (array) { if (clear) ln = OPENSSL_LINE, ret = OPENSSL_clear_realloc_array(ret, old_nmemb, nmemb, td->size); else ln = OPENSSL_LINE, ret = OPENSSL_realloc_array(ret, nmemb, td->size); } else { if (clear) ln = OPENSSL_LINE, ret = OPENSSL_clear_realloc(ret, old_sz, sz); else ln = OPENSSL_LINE, ret = OPENSSL_realloc(ret, sz); } } else { if (array) { if (clear) ret = CRYPTO_clear_realloc_array(ret, old_nmemb, nmemb, td->size, test_fn, test_line); else ret = CRYPTO_realloc_array(ret, nmemb, td->size, test_fn, test_line); } else { if (clear) ret = CRYPTO_clear_realloc(ret, old_sz, sz, test_fn, test_line); else ret = CRYPTO_realloc(ret, sz, test_fn, test_line); } } /* * There is an OPENSSL_calloc in ERR_set_debug, triggered * from ossl_report_alloc_err_ex. */ exp_malloc_cnt += !!(exp == EXP_OOM && (!macro || (bool) OPENSSL_FILE[0])); res = check_exp(macro ? OPENSSL_FILE : test_fn, ln, sz, false, false, ret, exp, exp_malloc_cnt, exp_realloc_cnt); if (res == 0) TEST_error("realloc return code check fail with i = %zu, ret = %p" ", old_nmemb = %#zx, nmemb = %#zx, size = %#zx", i, (void *) ret, old_nmemb, nmemb, td->size); /* Write data on the first pass and check it on the second */ if (res != 0 && exp == EXP_NONNULL && exp2 == EXP_NONNULL) { size_t check_sz = MIN(td->orig_nmemb * td->size, td->new_nmemb * td->size); size_t j; size_t num_err = 0; if (i != 0) { for (j = 0; j < check_sz; j++) { char exp_val = (uint8_t) ((uintptr_t) td * 253 + j * 17); if (ret[j] != exp_val) { if (!num_err) TEST_error("Memory mismatch at byte %zu of %zu: " "%#04hhx != %#04hhx", j, check_sz, ret[j], exp_val); res = 0; num_err++; } } if (num_err != 0) TEST_error("Total errors: %zu", num_err); } else { for (j = 0; j < check_sz; j++) ret[j] = (uint8_t) ((uintptr_t) td * 253 + j * 17); } } /* Freeing the old allocation if realloc has failed */ if (ret == NULL && exp != EXP_ZERO_SIZE) OPENSSL_free(old_ret); old_ret = ret; } OPENSSL_free(ret); return res; } static int test_xaligned_alloc(const bool array, const bool macro, const struct array_aligned_alloc_vector *td) { char *ret; int ln = test_line; size_t sz = td->nmemb * td->size; enum exp_ret exp = array ? td->exp_array : td->exp; int exp_cnt = 0; void *freeptr = &freeptr; int res = 1; check_exp_prep(); if (macro) { if (array) { ln = OPENSSL_LINE, ret = OPENSSL_aligned_alloc_array(td->nmemb, td->size, td->align, &freeptr); } else { ln = OPENSSL_LINE, ret = OPENSSL_aligned_alloc(sz, td->align, &freeptr); } } else { if (array) ret = CRYPTO_aligned_alloc_array(td->nmemb, td->size, td->align, &freeptr, test_fn, test_line); else ret = CRYPTO_aligned_alloc(sz, td->align, &freeptr, test_fn, test_line); } #if !defined(OPENSSL_SMALL_FOOTPRINT) /* * aligned_alloc doesn't increment the call counts by itself, and * OPENSSL_malloc is only called when the open-coded implementation * is used. */ # if USE_CUSTOM_ALLOC_FNS \ || !(defined(_BSD_SOURCE) || (defined(_POSIX_C_SOURCE) && _POSIX_C_SOURCE >= 200112L)) exp_cnt += !!(exp != EXP_INT_OF && exp != EXP_INVAL); # endif #else /* OPENSSL_SMALL_FOOTPRINT */ exp = exp == EXP_INT_OF ? EXP_INT_OF : EXP_ZERO_SIZE; #endif /* !OPENSSL_SMALL_FOOTPRINT */ /* * There is an OPENSSL_calloc in ERR_set_debug, triggered * from ossl_report_alloc_err_ex. */ exp_cnt += IS_FAIL(exp) && (!macro || (bool) OPENSSL_FILE[0]); res &= check_exp(macro ? OPENSSL_FILE : test_fn, ln, sz, false, false, ret, exp, exp_cnt, 0); /* Check the pointer's alignment */ if (exp == EXP_NONNULL) { if (!TEST_uint64_t_eq((uintptr_t) ret & (td->align - 1), 0)) res = 0; } #if !defined(OPENSSL_SMALL_FOOTPRINT) if (IS_FAIL(exp) && !TEST_ptr_null(freeptr)) res = 0; if ((exp == EXP_NONNULL) && !TEST_ptr(freeptr)) res = 0; #else /* OPENSSL_SMALL_FOOTPRINT */ if (!TEST_ptr_null(ret) || !TEST_ptr_null(freeptr)) res = 0; #endif /* !OPENSSL_SMALL_FOOTPRINT */ OPENSSL_free(freeptr); return res; } static int test_malloc(const int i) { return test_xalloc(false, false, false, false, array_alloc_vectors + i) && test_xalloc(false, false, false, true, array_alloc_vectors + i); } static int test_zalloc(const int i) { return test_xalloc(false, false, true, false, array_alloc_vectors + i) && test_xalloc(false, false, true, true, array_alloc_vectors + i); } static int test_malloc_array(const int i) { return test_xalloc(false, true, false, false, array_alloc_vectors + i) && test_xalloc(false, true, false, true, array_alloc_vectors + i); } static int test_calloc(const int i) { return test_xalloc(false, true, true, false, array_alloc_vectors + i) && test_xalloc(false, true, true, true, array_alloc_vectors + i); } static int test_secure_malloc(const int i) { return test_xalloc(true, false, false, false, array_alloc_vectors + i) && test_xalloc(true, false, false, true, array_alloc_vectors + i); } static int test_secure_zalloc(const int i) { return test_xalloc(true, false, true, false, array_alloc_vectors + i) && test_xalloc(true, false, true, true, array_alloc_vectors + i); } static int test_secure_malloc_array(const int i) { return test_xalloc(true, true, false, false, array_alloc_vectors + i) && test_xalloc(true, true, false, true, array_alloc_vectors + i); } static int test_secure_calloc(const int i) { return test_xalloc(true, true, true, false, array_alloc_vectors + i) && test_xalloc(true, true, true, true, array_alloc_vectors + i); } static int test_realloc(const int i) { return test_xrealloc(false, false, false, array_realloc_vectors + i) && test_xrealloc(false, false, true, array_realloc_vectors + i); } static int test_clear_realloc(const int i) { return test_xrealloc(true, false, false, array_realloc_vectors + i) && test_xrealloc(true, false, true, array_realloc_vectors + i); } static int test_realloc_array(const int i) { return test_xrealloc(false, true, false, array_realloc_vectors + i) && test_xrealloc(false, true, true, array_realloc_vectors + i); } static int test_clear_realloc_array(const int i) { return test_xrealloc(true, true, false, array_realloc_vectors + i) && test_xrealloc(true, true, true, array_realloc_vectors + i); } static int test_aligned_alloc(const int i) { return test_xaligned_alloc(false, false, array_aligned_alloc_vectors + i) && test_xaligned_alloc(false, true, array_aligned_alloc_vectors + i); } static int test_aligned_alloc_array(const int i) { return test_xaligned_alloc(true, false, array_aligned_alloc_vectors + i) && test_xaligned_alloc(true, true, array_aligned_alloc_vectors + i); } static int test_free(void) { int test_result = 1; void *p; save_counts(); OPENSSL_free(NULL); if (!TEST_int_eq(check_counts(0, 0, 1), 1)) test_result = 0; save_counts(); CRYPTO_free(NULL, test_fn, test_line); if (!TEST_int_eq(check_counts(0, 0, 1), 1)) test_result = 0; save_counts(); p = OPENSSL_malloc(42); OPENSSL_free(p); if (!TEST_int_eq(check_counts(1, 0, 1), 1)) test_result = 0; save_counts(); p = CRYPTO_calloc(23, 69, test_fn, test_line); CRYPTO_free(p, test_fn, test_line); if (!TEST_int_eq(check_counts(1, 0, 1), 1)) test_result = 0; return test_result; } int setup_tests(void) { secure_memory_is_secure = CRYPTO_secure_malloc_init(65536, 4); TEST_info("secure memory init: %d", secure_memory_is_secure); ADD_ALL_TESTS(test_malloc, OSSL_NELEM(array_alloc_vectors)); ADD_ALL_TESTS(test_zalloc, OSSL_NELEM(array_alloc_vectors)); ADD_ALL_TESTS(test_malloc_array, OSSL_NELEM(array_alloc_vectors)); ADD_ALL_TESTS(test_calloc, OSSL_NELEM(array_alloc_vectors)); ADD_ALL_TESTS(test_secure_malloc, OSSL_NELEM(array_alloc_vectors)); ADD_ALL_TESTS(test_secure_zalloc, OSSL_NELEM(array_alloc_vectors)); ADD_ALL_TESTS(test_secure_malloc_array, OSSL_NELEM(array_alloc_vectors)); ADD_ALL_TESTS(test_secure_calloc, OSSL_NELEM(array_alloc_vectors)); ADD_ALL_TESTS(test_realloc, OSSL_NELEM(array_realloc_vectors)); ADD_ALL_TESTS(test_clear_realloc, OSSL_NELEM(array_realloc_vectors)); ADD_ALL_TESTS(test_realloc_array, OSSL_NELEM(array_realloc_vectors)); ADD_ALL_TESTS(test_clear_realloc_array, OSSL_NELEM(array_realloc_vectors)); ADD_ALL_TESTS(test_aligned_alloc, OSSL_NELEM(array_aligned_alloc_vectors)); ADD_ALL_TESTS(test_aligned_alloc_array, OSSL_NELEM(array_aligned_alloc_vectors)); ADD_TEST(test_free); return 1; } #if USE_CUSTOM_ALLOC_FNS int global_init(void) { if (!CRYPTO_set_mem_functions(my_malloc, my_realloc, my_free)) { fprintf(stderr, "Failed to override allocator functions"); return 0; } return 1; } #endif