ap/lib/libssl/openssl-1.1.1o/test/secmemtest.c - T106_DC - Gitiles

 /*
  * Copyright 2015-2018 The OpenSSL Project Authors. All Rights Reserved.
  *
  * Licensed under the OpenSSL license (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 <openssl/crypto.h>

 #include "testutil.h"
 #include "../e_os.h"

 static int test_sec_mem(void)
 {
 #ifdef OPENSSL_SECURE_MEMORY
     int testresult = 0;
     char *p = NULL, *q = NULL, *r = NULL, *s = NULL;

     TEST_info("Secure memory is implemented.");

     s = OPENSSL_secure_malloc(20);
     /* s = non-secure 20 */
     if (!TEST_ptr(s)
         || !TEST_false(CRYPTO_secure_allocated(s)))
         goto end;
     r = OPENSSL_secure_malloc(20);
     /* r = non-secure 20, s = non-secure 20 */
     if (!TEST_ptr(r)
         || !TEST_true(CRYPTO_secure_malloc_init(4096, 32))
         || !TEST_false(CRYPTO_secure_allocated(r)))
         goto end;
     p = OPENSSL_secure_malloc(20);
     if (!TEST_ptr(p)
         /* r = non-secure 20, p = secure 20, s = non-secure 20 */
         || !TEST_true(CRYPTO_secure_allocated(p))
         /* 20 secure -> 32-byte minimum allocation unit */
         || !TEST_size_t_eq(CRYPTO_secure_used(), 32))
         goto end;
     q = OPENSSL_malloc(20);
     if (!TEST_ptr(q))
         goto end;
     /* r = non-secure 20, p = secure 20, q = non-secure 20, s = non-secure 20 */
     if (!TEST_false(CRYPTO_secure_allocated(q)))
         goto end;
     OPENSSL_secure_clear_free(s, 20);
     s = OPENSSL_secure_malloc(20);
     if (!TEST_ptr(s)
         /* r = non-secure 20, p = secure 20, q = non-secure 20, s = secure 20 */
         || !TEST_true(CRYPTO_secure_allocated(s))
         /* 2 * 20 secure -> 64 bytes allocated */
         || !TEST_size_t_eq(CRYPTO_secure_used(), 64))
         goto end;
     OPENSSL_secure_clear_free(p, 20);
     p = NULL;
     /* 20 secure -> 32 bytes allocated */
     if (!TEST_size_t_eq(CRYPTO_secure_used(), 32))
         goto end;
     OPENSSL_free(q);
     q = NULL;
     /* should not complete, as secure memory is still allocated */
     if (!TEST_false(CRYPTO_secure_malloc_done())
         || !TEST_true(CRYPTO_secure_malloc_initialized()))
         goto end;
     OPENSSL_secure_free(s);
     s = NULL;
     /* secure memory should now be 0, so done should complete */
     if (!TEST_size_t_eq(CRYPTO_secure_used(), 0)
         || !TEST_true(CRYPTO_secure_malloc_done())
         || !TEST_false(CRYPTO_secure_malloc_initialized()))
         goto end;

     TEST_info("Possible infinite loop: allocate more than available");
     if (!TEST_true(CRYPTO_secure_malloc_init(32768, 16)))
         goto end;
     TEST_ptr_null(OPENSSL_secure_malloc((size_t)-1));
     TEST_true(CRYPTO_secure_malloc_done());

     /*
      * If init fails, then initialized should be false, if not, this
      * could cause an infinite loop secure_malloc, but we don't test it
      */
     if (TEST_false(CRYPTO_secure_malloc_init(16, 16)) &&
         !TEST_false(CRYPTO_secure_malloc_initialized())) {
         TEST_true(CRYPTO_secure_malloc_done());
         goto end;
     }

     /*-
      * There was also a possible infinite loop when the number of
      * elements was 1<<31, as |int i| was set to that, which is a
      * negative number. However, it requires minimum input values:
      *
      * CRYPTO_secure_malloc_init((size_t)1<<34, (size_t)1<<4);
      *
      * Which really only works on 64-bit systems, since it took 16 GB
      * secure memory arena to trigger the problem. It naturally takes
      * corresponding amount of available virtual and physical memory
      * for test to be feasible/representative. Since we can't assume
      * that every system is equipped with that much memory, the test
      * remains disabled. If the reader of this comment really wants
      * to make sure that infinite loop is fixed, they can enable the
      * code below.
      */
 # if 0
     /*-
      * On Linux and BSD this test has a chance to complete in minimal
      * time and with minimum side effects, because mlock is likely to
      * fail because of RLIMIT_MEMLOCK, which is customarily [much]
      * smaller than 16GB. In other words Linux and BSD users can be
      * limited by virtual space alone...
      */
     if (sizeof(size_t) > 4) {
         TEST_info("Possible infinite loop: 1<<31 limit");
         if (TEST_true(CRYPTO_secure_malloc_init((size_t)1<<34, (size_t)1<<4) != 0))
             TEST_true(CRYPTO_secure_malloc_done());
     }
 # endif

     /* this can complete - it was not really secure */
     testresult = 1;
  end:
     OPENSSL_secure_free(p);
     OPENSSL_free(q);
     OPENSSL_secure_free(r);
     OPENSSL_secure_free(s);
     return testresult;
 #else
     TEST_info("Secure memory is *not* implemented.");
     /* Should fail. */
     return TEST_false(CRYPTO_secure_malloc_init(4096, 32));
 #endif
 }

 static int test_sec_mem_clear(void)
 {
 #ifdef OPENSSL_SECURE_MEMORY
     const int size = 64;
     unsigned char *p = NULL;
     int i, res = 0;

     if (!TEST_true(CRYPTO_secure_malloc_init(4096, 32))
             || !TEST_ptr(p = OPENSSL_secure_malloc(size)))
         goto err;

     for (i = 0; i < size; i++)
         if (!TEST_uchar_eq(p[i], 0))
             goto err;

     for (i = 0; i < size; i++)
         p[i] = (unsigned char)(i + ' ' + 1);

     OPENSSL_secure_free(p);

     /*
      * A deliberate use after free here to verify that the memory has been
      * cleared properly.  Since secure free doesn't return the memory to
      * libc's memory pool, it technically isn't freed.  However, the header
      * bytes have to be skipped and these consist of two pointers in the
      * current implementation.
      */
     for (i = sizeof(void *) * 2; i < size; i++)
         if (!TEST_uchar_eq(p[i], 0))
             return 0;

     res = 1;
     p = NULL;
 err:
     OPENSSL_secure_free(p);
     CRYPTO_secure_malloc_done();
     return res;
 #else
     return 1;
 #endif
 }

 int setup_tests(void)
 {
     ADD_TEST(test_sec_mem);
     ADD_TEST(test_sec_mem_clear);
     return 1;
 }
	/*
	* Copyright 2015-2018 The OpenSSL Project Authors. All Rights Reserved.
	*
	* Licensed under the OpenSSL license (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 <openssl/crypto.h>

	#include "testutil.h"
	#include "../e_os.h"

	static int test_sec_mem(void)
	{
	#ifdef OPENSSL_SECURE_MEMORY
	int testresult = 0;
	char p = NULL, q = NULL, r = NULL, s = NULL;

	TEST_info("Secure memory is implemented.");

	s = OPENSSL_secure_malloc(20);
	/* s = non-secure 20 */
	if (!TEST_ptr(s)
	\|\| !TEST_false(CRYPTO_secure_allocated(s)))
	goto end;
	r = OPENSSL_secure_malloc(20);
	/* r = non-secure 20, s = non-secure 20 */
	if (!TEST_ptr(r)
	\|\| !TEST_true(CRYPTO_secure_malloc_init(4096, 32))
	\|\| !TEST_false(CRYPTO_secure_allocated(r)))
	goto end;
	p = OPENSSL_secure_malloc(20);
	if (!TEST_ptr(p)
	/* r = non-secure 20, p = secure 20, s = non-secure 20 */
	\|\| !TEST_true(CRYPTO_secure_allocated(p))
	/* 20 secure -> 32-byte minimum allocation unit */
	\|\| !TEST_size_t_eq(CRYPTO_secure_used(), 32))
	goto end;
	q = OPENSSL_malloc(20);
	if (!TEST_ptr(q))
	goto end;
	/* r = non-secure 20, p = secure 20, q = non-secure 20, s = non-secure 20 */
	if (!TEST_false(CRYPTO_secure_allocated(q)))
	goto end;
	OPENSSL_secure_clear_free(s, 20);
	s = OPENSSL_secure_malloc(20);
	if (!TEST_ptr(s)
	/* r = non-secure 20, p = secure 20, q = non-secure 20, s = secure 20 */
	\|\| !TEST_true(CRYPTO_secure_allocated(s))
	/* 2 * 20 secure -> 64 bytes allocated */
	\|\| !TEST_size_t_eq(CRYPTO_secure_used(), 64))
	goto end;
	OPENSSL_secure_clear_free(p, 20);
	p = NULL;
	/* 20 secure -> 32 bytes allocated */
	if (!TEST_size_t_eq(CRYPTO_secure_used(), 32))
	goto end;
	OPENSSL_free(q);
	q = NULL;
	/* should not complete, as secure memory is still allocated */
	if (!TEST_false(CRYPTO_secure_malloc_done())
	\|\| !TEST_true(CRYPTO_secure_malloc_initialized()))
	goto end;
	OPENSSL_secure_free(s);
	s = NULL;
	/* secure memory should now be 0, so done should complete */
	if (!TEST_size_t_eq(CRYPTO_secure_used(), 0)
	\|\| !TEST_true(CRYPTO_secure_malloc_done())
	\|\| !TEST_false(CRYPTO_secure_malloc_initialized()))
	goto end;

	TEST_info("Possible infinite loop: allocate more than available");
	if (!TEST_true(CRYPTO_secure_malloc_init(32768, 16)))
	goto end;
	TEST_ptr_null(OPENSSL_secure_malloc((size_t)-1));
	TEST_true(CRYPTO_secure_malloc_done());

	/*
	* If init fails, then initialized should be false, if not, this
	* could cause an infinite loop secure_malloc, but we don't test it
	*/
	if (TEST_false(CRYPTO_secure_malloc_init(16, 16)) &&
	!TEST_false(CRYPTO_secure_malloc_initialized())) {
	TEST_true(CRYPTO_secure_malloc_done());
	goto end;
	}

	/*-
	* There was also a possible infinite loop when the number of
	* elements was 1<<31, as \|int i\| was set to that, which is a
	* negative number. However, it requires minimum input values:
	*
	* CRYPTO_secure_malloc_init((size_t)1<<34, (size_t)1<<4);
	*
	* Which really only works on 64-bit systems, since it took 16 GB
	* secure memory arena to trigger the problem. It naturally takes
	* corresponding amount of available virtual and physical memory
	* for test to be feasible/representative. Since we can't assume
	* that every system is equipped with that much memory, the test
	* remains disabled. If the reader of this comment really wants
	* to make sure that infinite loop is fixed, they can enable the
	* code below.
	*/
	# if 0
	/*-
	* On Linux and BSD this test has a chance to complete in minimal
	* time and with minimum side effects, because mlock is likely to
	* fail because of RLIMIT_MEMLOCK, which is customarily [much]
	* smaller than 16GB. In other words Linux and BSD users can be
	* limited by virtual space alone...
	*/
	if (sizeof(size_t) > 4) {
	TEST_info("Possible infinite loop: 1<<31 limit");
	if (TEST_true(CRYPTO_secure_malloc_init((size_t)1<<34, (size_t)1<<4) != 0))
	TEST_true(CRYPTO_secure_malloc_done());
	}
	# endif

	/* this can complete - it was not really secure */
	testresult = 1;
	end:
	OPENSSL_secure_free(p);
	OPENSSL_free(q);
	OPENSSL_secure_free(r);
	OPENSSL_secure_free(s);
	return testresult;
	#else
	TEST_info("Secure memory is not implemented.");
	/* Should fail. */
	return TEST_false(CRYPTO_secure_malloc_init(4096, 32));
	#endif
	}

	static int test_sec_mem_clear(void)
	{
	#ifdef OPENSSL_SECURE_MEMORY
	const int size = 64;
	unsigned char *p = NULL;
	int i, res = 0;

	if (!TEST_true(CRYPTO_secure_malloc_init(4096, 32))
	\|\| !TEST_ptr(p = OPENSSL_secure_malloc(size)))
	goto err;

	for (i = 0; i < size; i++)
	if (!TEST_uchar_eq(p[i], 0))
	goto err;

	for (i = 0; i < size; i++)
	p[i] = (unsigned char)(i + ' ' + 1);

	OPENSSL_secure_free(p);

	/*
	* A deliberate use after free here to verify that the memory has been
	* cleared properly. Since secure free doesn't return the memory to
	* libc's memory pool, it technically isn't freed. However, the header
	* bytes have to be skipped and these consist of two pointers in the
	* current implementation.
	*/
	for (i = sizeof(void ) 2; i < size; i++)
	if (!TEST_uchar_eq(p[i], 0))
	return 0;

	res = 1;
	p = NULL;
	err:
	OPENSSL_secure_free(p);
	CRYPTO_secure_malloc_done();
	return res;
	#else
	return 1;
	#endif
	}

	int setup_tests(void)
	{
	ADD_TEST(test_sec_mem);
	ADD_TEST(test_sec_mem_clear);
	return 1;
	}