doc/man3/OPENSSL_secure_malloc.pod - third_party/openssl - Git at Google

 =pod

 =head1 NAME

 CRYPTO_secure_malloc_init, CRYPTO_secure_malloc_initialized,
 CRYPTO_secure_malloc_done, OPENSSL_secure_malloc, CRYPTO_secure_malloc,
 OPENSSL_secure_zalloc, CRYPTO_secure_zalloc, OPENSSL_secure_free,
 CRYPTO_secure_free, OPENSSL_secure_actual_size, OPENSSL_secure_allocated,
 CRYPTO_secure_used - secure heap storage

 =head1 SYNOPSIS

  #include <openssl/crypto.h>

  int CRYPTO_secure_malloc_init(size_t size, int minsize);

  int CRYPTO_secure_malloc_initialized();

  int CRYPTO_secure_malloc_done();

  void *OPENSSL_secure_malloc(size_t num);
  void *CRYPTO_secure_malloc(size_t num, const char *file, int line);

  void *OPENSSL_secure_zalloc(size_t num);
  void *CRYPTO_secure_zalloc(size_t num, const char *file, int line);

  void OPENSSL_secure_free(void* ptr);
  void CRYPTO_secure_free(void *ptr, const char *, int);

  size_t OPENSSL_secure_actual_size(const void *ptr);
  int OPENSSL_secure_allocated(const void *ptr);

  size_t CRYPTO_secure_used();

 =head1 DESCRIPTION

 In order to help protect applications (particularly long-running servers)
 from pointer overruns or underruns that could return arbitrary data from
 the program's dynamic memory area, where keys and other sensitive
 information might be stored, OpenSSL supports the concept of a "secure heap."
 The level and type of security guarantees depend on the operating system.
 It is a good idea to review the code and see if it addresses your
 threat model and concerns.

 If a secure heap is used, then private key B<BIGNUM> values are stored there.
 This protects long-term storage of private keys, but will not necessarily
 put all intermediate values and computations there.

 CRYPTO_secure_malloc_init() creates the secure heap, with the specified
 C<size> in bytes. The C<minsize> parameter is the minimum size to
 allocate from the heap. Both C<size> and C<minsize> must be a power
 of two.

 CRYPTO_secure_malloc_initialized() indicates whether or not the secure
 heap as been initialized and is available.

 CRYPTO_secure_malloc_done() releases the heap and makes the memory unavailable
 to the process if all secure memory has been freed.
 It can take noticeably long to complete.

 OPENSSL_secure_malloc() allocates C<num> bytes from the heap.
 If CRYPTO_secure_malloc_init() is not called, this is equivalent to
 calling OPENSSL_malloc().
 It is a macro that expands to
 CRYPTO_secure_malloc() and adds the C<__FILE__> and C<__LINE__> parameters.

 OPENSSL_secure_zalloc() and CRYPTO_secure_zalloc() are like
 OPENSSL_secure_malloc() and CRYPTO_secure_malloc(), respectively,
 except that they call memset() to zero the memory before returning.

 OPENSSL_secure_free() releases the memory at C<ptr> back to the heap.
 It must be called with a value previously obtained from
 OPENSSL_secure_malloc().
 If CRYPTO_secure_malloc_init() is not called, this is equivalent to
 calling OPENSSL_free().
 It exists for consistency with OPENSSL_secure_malloc() , and
 is a macro that expands to CRYPTO_secure_free() and adds the C<__FILE__>
 and C<__LINE__> parameters..

 OPENSSL_secure_allocated() tells whether or not a pointer is within
 the secure heap.
 OPENSSL_secure_actual_size() tells the actual size allocated to the
 pointer; implementations may allocate more space than initially
 requested, in order to "round up" and reduce secure heap fragmentation.

 CRYPTO_secure_used() returns the number of bytes allocated in the
 secure heap.

 =head1 RETURN VALUES

 CRYPTO_secure_malloc_init() returns 0 on failure, 1 if successful,
 and 2 if successful but the heap could not be protected by memory
 mapping.

 CRYPTO_secure_malloc_initialized() returns 1 if the secure heap is
 available (that is, if CRYPTO_secure_malloc_init() has been called,
 but CRYPTO_secure_malloc_done() has not been called or failed) or 0 if not.

 OPENSSL_secure_malloc() and OPENSSL_secure_zalloc() return a pointer into
 the secure heap of the requested size, or C<NULL> if memory could not be
 allocated.

 CRYPTO_secure_allocated() returns 1 if the pointer is in the secure heap, or 0 if not.

 CRYPTO_secure_malloc_done() returns 1 if the secure memory area is released, or 0 if not.

 OPENSSL_secure_free() returns no values.

 =head1 SEE ALSO

 L<OPENSSL_malloc(3)>,
 L<BN_new(3)>

 =head1 COPYRIGHT

 Copyright 2015-2016 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
 L<https://www.openssl.org/source/license.html>.

 =cut
	=pod

	=head1 NAME

	CRYPTO_secure_malloc_init, CRYPTO_secure_malloc_initialized,
	CRYPTO_secure_malloc_done, OPENSSL_secure_malloc, CRYPTO_secure_malloc,
	OPENSSL_secure_zalloc, CRYPTO_secure_zalloc, OPENSSL_secure_free,
	CRYPTO_secure_free, OPENSSL_secure_actual_size, OPENSSL_secure_allocated,
	CRYPTO_secure_used - secure heap storage

	=head1 SYNOPSIS

	#include <openssl/crypto.h>

	int CRYPTO_secure_malloc_init(size_t size, int minsize);

	int CRYPTO_secure_malloc_initialized();

	int CRYPTO_secure_malloc_done();

	void *OPENSSL_secure_malloc(size_t num);
	void CRYPTO_secure_malloc(size_t num, const char file, int line);

	void *OPENSSL_secure_zalloc(size_t num);
	void CRYPTO_secure_zalloc(size_t num, const char file, int line);

	void OPENSSL_secure_free(void* ptr);
	void CRYPTO_secure_free(void ptr, const char , int);

	size_t OPENSSL_secure_actual_size(const void *ptr);
	int OPENSSL_secure_allocated(const void *ptr);

	size_t CRYPTO_secure_used();

	=head1 DESCRIPTION

	In order to help protect applications (particularly long-running servers)
	from pointer overruns or underruns that could return arbitrary data from
	the program's dynamic memory area, where keys and other sensitive
	information might be stored, OpenSSL supports the concept of a "secure heap."
	The level and type of security guarantees depend on the operating system.
	It is a good idea to review the code and see if it addresses your
	threat model and concerns.

	If a secure heap is used, then private key B<BIGNUM> values are stored there.
	This protects long-term storage of private keys, but will not necessarily
	put all intermediate values and computations there.

	CRYPTO_secure_malloc_init() creates the secure heap, with the specified
	C<size> in bytes. The C<minsize> parameter is the minimum size to
	allocate from the heap. Both C<size> and C<minsize> must be a power
	of two.

	CRYPTO_secure_malloc_initialized() indicates whether or not the secure
	heap as been initialized and is available.

	CRYPTO_secure_malloc_done() releases the heap and makes the memory unavailable
	to the process if all secure memory has been freed.
	It can take noticeably long to complete.

	OPENSSL_secure_malloc() allocates C<num> bytes from the heap.
	If CRYPTO_secure_malloc_init() is not called, this is equivalent to
	calling OPENSSL_malloc().
	It is a macro that expands to
	CRYPTO_secure_malloc() and adds the C<__FILE__> and C<__LINE__> parameters.

	OPENSSL_secure_zalloc() and CRYPTO_secure_zalloc() are like
	OPENSSL_secure_malloc() and CRYPTO_secure_malloc(), respectively,
	except that they call memset() to zero the memory before returning.

	OPENSSL_secure_free() releases the memory at C<ptr> back to the heap.
	It must be called with a value previously obtained from
	OPENSSL_secure_malloc().
	If CRYPTO_secure_malloc_init() is not called, this is equivalent to
	calling OPENSSL_free().
	It exists for consistency with OPENSSL_secure_malloc() , and
	is a macro that expands to CRYPTO_secure_free() and adds the C<__FILE__>
	and C<__LINE__> parameters..

	OPENSSL_secure_allocated() tells whether or not a pointer is within
	the secure heap.
	OPENSSL_secure_actual_size() tells the actual size allocated to the
	pointer; implementations may allocate more space than initially
	requested, in order to "round up" and reduce secure heap fragmentation.

	CRYPTO_secure_used() returns the number of bytes allocated in the
	secure heap.

	=head1 RETURN VALUES

	CRYPTO_secure_malloc_init() returns 0 on failure, 1 if successful,
	and 2 if successful but the heap could not be protected by memory
	mapping.

	CRYPTO_secure_malloc_initialized() returns 1 if the secure heap is
	available (that is, if CRYPTO_secure_malloc_init() has been called,
	but CRYPTO_secure_malloc_done() has not been called or failed) or 0 if not.

	OPENSSL_secure_malloc() and OPENSSL_secure_zalloc() return a pointer into
	the secure heap of the requested size, or C<NULL> if memory could not be
	allocated.

	CRYPTO_secure_allocated() returns 1 if the pointer is in the secure heap, or 0 if not.

	CRYPTO_secure_malloc_done() returns 1 if the secure memory area is released, or 0 if not.

	OPENSSL_secure_free() returns no values.

	=head1 SEE ALSO

	L<OPENSSL_malloc(3)>,
	L<BN_new(3)>

	=head1 COPYRIGHT

	Copyright 2015-2016 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
	L<https://www.openssl.org/source/license.html>.

	=cut