docs/security_advisories/security-advisory-tfv-1.rst - tf-a-mtk - Git at Google

 Advisory TFV-1 (CVE-2016-10319)
 ===============================

 +----------------+-------------------------------------------------------------+
 | Title          | Malformed Firmware Update SMC can result in copy of         |
 |                | unexpectedly large data into secure memory                  |
 +================+=============================================================+
 | CVE ID         | `CVE-2016-10319`_                                           |
 +----------------+-------------------------------------------------------------+
 | Date           | 18 Oct 2016                                                 |
 +----------------+-------------------------------------------------------------+
 | Versions       | v1.2 and v1.3 (since commit `48bfb88`_)                     |
 | Affected       |                                                             |
 +----------------+-------------------------------------------------------------+
 | Configurations | Platforms that use AArch64 BL1 plus untrusted normal world  |
 | Affected       | firmware update code executing before BL31                  |
 +----------------+-------------------------------------------------------------+
 | Impact         | Copy of unexpectedly large data into the free secure memory |
 |                | reported by BL1 platform code                               |
 +----------------+-------------------------------------------------------------+
 | Fix Version    | `Pull Request #783`_                                        |
 +----------------+-------------------------------------------------------------+
 | Credit         | IOActive                                                    |
 +----------------+-------------------------------------------------------------+

 Generic Trusted Firmware (TF) BL1 code contains an SMC interface that is briefly
 available after cold reset to support the Firmware Update (FWU) feature (also
 known as recovery mode). This allows most FWU functionality to be implemented in
 the normal world, while retaining the essential image authentication
 functionality in BL1. When cold boot reaches the EL3 Runtime Software (for
 example, BL31 on AArch64 systems), the FWU SMC interface is replaced by the EL3
 Runtime SMC interface. Platforms may choose how much of this FWU functionality
 to use, if any.

 The BL1 FWU SMC handling code, currently only supported on AArch64, contains
 several vulnerabilities that may be exploited when *all* the following
 conditions apply:

 1. Platform code uses TF BL1 with the ``TRUSTED_BOARD_BOOT`` build option
    enabled.

 2. Platform code arranges for untrusted normal world FWU code to be executed in
    the cold boot path, before BL31 starts. Untrusted in this sense means code
    that is not in ROM or has not been authenticated or has otherwise been
    executed by an attacker.

 3. Platform code copies the insecure pattern described below from the ARM
    platform version of ``bl1_plat_mem_check()``.

 The vulnerabilities consist of potential integer overflows in the input
 validation checks while handling the ``FWU_SMC_IMAGE_COPY`` SMC. The SMC
 implementation is designed to copy an image into secure memory for subsequent
 authentication, but the vulnerabilities may allow an attacker to copy
 unexpectedly large data into secure memory. Note that a separate vulnerability
 is required to leverage these vulnerabilities; for example a way to get the
 system to change its behaviour based on the unexpected secure memory contents.

 Two of the vulnerabilities are in the function ``bl1_fwu_image_copy()`` in
 ``bl1/bl1_fwu.c``. These are listed below, referring to the v1.3 tagged version
 of the code:

 - Line 155:

   .. code:: c

     /*
      * If last block is more than expected then
      * clip the block to the required image size.
      */
     if (image_desc->copied_size + block_size >
          image_desc->image_info.image_size) {
         block_size = image_desc->image_info.image_size -
             image_desc->copied_size;
         WARN("BL1-FWU: Copy argument block_size > remaining image size."
             " Clipping block_size\n");
     }

     /* Make sure the image src/size is mapped. */
     if (bl1_plat_mem_check(image_src, block_size, flags)) {
         WARN("BL1-FWU: Copy arguments source/size not mapped\n");
         return -ENOMEM;
     }

     INFO("BL1-FWU: Continuing image copy in blocks\n");

     /* Copy image for given block size. */
     base_addr += image_desc->copied_size;
     image_desc->copied_size += block_size;
     memcpy((void *)base_addr, (const void *)image_src, block_size);
     ...

   This code fragment is executed when the image copy operation is performed in
   blocks over multiple SMCs. ``block_size`` is an SMC argument and therefore
   potentially controllable by an attacker. A very large value may result in an
   integer overflow in the 1st ``if`` statement, which would bypass the check,
   allowing an unclipped ``block_size`` to be passed into
   ``bl1_plat_mem_check()``. If ``bl1_plat_mem_check()`` also passes, this may
   result in an unexpectedly large copy of data into secure memory.

 - Line 206:

   .. code:: c

     /* Make sure the image src/size is mapped. */
     if (bl1_plat_mem_check(image_src, block_size, flags)) {
         WARN("BL1-FWU: Copy arguments source/size not mapped\n");
         return -ENOMEM;
     }

     /* Find out how much free trusted ram remains after BL1 load */
     mem_layout = bl1_plat_sec_mem_layout();
     if ((image_desc->image_info.image_base < mem_layout->free_base) ||
          (image_desc->image_info.image_base + image_size >
           mem_layout->free_base + mem_layout->free_size)) {
         WARN("BL1-FWU: Memory not available to copy\n");
         return -ENOMEM;
     }

     /* Update the image size. */
     image_desc->image_info.image_size = image_size;

     /* Copy image for given size. */
     memcpy((void *)base_addr, (const void *)image_src, block_size);
     ...

   This code fragment is executed during the 1st invocation of the image copy
   operation. Both ``block_size`` and ``image_size`` are SMC arguments. A very
   large value of ``image_size`` may result in an integer overflow in the 2nd
   ``if`` statement, which would bypass the check, allowing execution to proceed.
   If ``bl1_plat_mem_check()`` also passes, this may result in an unexpectedly
   large copy of data into secure memory.

 If the platform's implementation of ``bl1_plat_mem_check()`` is correct then it
 may help prevent the above 2 vulnerabilities from being exploited. However, the
 ARM platform version of this function contains a similar vulnerability:

 - Line 88 of ``plat/arm/common/arm_bl1_fwu.c`` in function of
   ``bl1_plat_mem_check()``:

   .. code:: c

     while (mmap[index].mem_size) {
         if ((mem_base >= mmap[index].mem_base) &&
             ((mem_base + mem_size)
             <= (mmap[index].mem_base +
             mmap[index].mem_size)))
             return 0;

         index++;
     }
     ...

   This function checks that the passed memory region is within one of the
   regions mapped in by ARM platforms. Here, ``mem_size`` may be the
   ``block_size`` passed from ``bl1_fwu_image_copy()``. A very large value of
   ``mem_size`` may result in an integer overflow and the function to incorrectly
   return success. Platforms that copy this insecure pattern will have the same
   vulnerability.

 .. _CVE-2016-10319: http://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2016-10319
 .. _48bfb88: https://github.com/ARM-software/arm-trusted-firmware/commit/48bfb88
 .. _Pull Request #783: https://github.com/ARM-software/arm-trusted-firmware/pull/783
	Advisory TFV-1 (CVE-2016-10319)
	===============================

	+----------------+-------------------------------------------------------------+
	\| Title \| Malformed Firmware Update SMC can result in copy of \|
	\| \| unexpectedly large data into secure memory \|
	+================+=============================================================+
	\| CVE ID \| `CVE-2016-10319`_ \|
	+----------------+-------------------------------------------------------------+
	\| Date \| 18 Oct 2016 \|
	+----------------+-------------------------------------------------------------+
	\| Versions \| v1.2 and v1.3 (since commit `48bfb88`_) \|
	\| Affected \| \|
	+----------------+-------------------------------------------------------------+
	\| Configurations \| Platforms that use AArch64 BL1 plus untrusted normal world \|
	\| Affected \| firmware update code executing before BL31 \|
	+----------------+-------------------------------------------------------------+
	\| Impact \| Copy of unexpectedly large data into the free secure memory \|
	\| \| reported by BL1 platform code \|
	+----------------+-------------------------------------------------------------+
	\| Fix Version \| `Pull Request #783`_ \|
	+----------------+-------------------------------------------------------------+
	\| Credit \| IOActive \|
	+----------------+-------------------------------------------------------------+

	Generic Trusted Firmware (TF) BL1 code contains an SMC interface that is briefly
	available after cold reset to support the Firmware Update (FWU) feature (also
	known as recovery mode). This allows most FWU functionality to be implemented in
	the normal world, while retaining the essential image authentication
	functionality in BL1. When cold boot reaches the EL3 Runtime Software (for
	example, BL31 on AArch64 systems), the FWU SMC interface is replaced by the EL3
	Runtime SMC interface. Platforms may choose how much of this FWU functionality
	to use, if any.

	The BL1 FWU SMC handling code, currently only supported on AArch64, contains
	several vulnerabilities that may be exploited when all the following
	conditions apply:

	1. Platform code uses TF BL1 with the ``TRUSTED_BOARD_BOOT`` build option
	enabled.

	2. Platform code arranges for untrusted normal world FWU code to be executed in
	the cold boot path, before BL31 starts. Untrusted in this sense means code
	that is not in ROM or has not been authenticated or has otherwise been
	executed by an attacker.

	3. Platform code copies the insecure pattern described below from the ARM
	platform version of ``bl1_plat_mem_check()``.

	The vulnerabilities consist of potential integer overflows in the input
	validation checks while handling the ``FWU_SMC_IMAGE_COPY`` SMC. The SMC
	implementation is designed to copy an image into secure memory for subsequent
	authentication, but the vulnerabilities may allow an attacker to copy
	unexpectedly large data into secure memory. Note that a separate vulnerability
	is required to leverage these vulnerabilities; for example a way to get the
	system to change its behaviour based on the unexpected secure memory contents.

	Two of the vulnerabilities are in the function ``bl1_fwu_image_copy()`` in
	``bl1/bl1_fwu.c``. These are listed below, referring to the v1.3 tagged version
	of the code:

	- Line 155:

	.. code:: c

	/*
	* If last block is more than expected then
	* clip the block to the required image size.
	*/
	if (image_desc->copied_size + block_size >
	image_desc->image_info.image_size) {
	block_size = image_desc->image_info.image_size -
	image_desc->copied_size;
	WARN("BL1-FWU: Copy argument block_size > remaining image size."
	" Clipping block_size\n");
	}

	/* Make sure the image src/size is mapped. */
	if (bl1_plat_mem_check(image_src, block_size, flags)) {
	WARN("BL1-FWU: Copy arguments source/size not mapped\n");
	return -ENOMEM;
	}

	INFO("BL1-FWU: Continuing image copy in blocks\n");

	/* Copy image for given block size. */
	base_addr += image_desc->copied_size;
	image_desc->copied_size += block_size;
	memcpy((void )base_addr, (const void )image_src, block_size);
	...

	This code fragment is executed when the image copy operation is performed in
	blocks over multiple SMCs. ``block_size`` is an SMC argument and therefore
	potentially controllable by an attacker. A very large value may result in an
	integer overflow in the 1st ``if`` statement, which would bypass the check,
	allowing an unclipped ``block_size`` to be passed into
	``bl1_plat_mem_check()``. If ``bl1_plat_mem_check()`` also passes, this may
	result in an unexpectedly large copy of data into secure memory.

	- Line 206:

	.. code:: c

	/* Make sure the image src/size is mapped. */
	if (bl1_plat_mem_check(image_src, block_size, flags)) {
	WARN("BL1-FWU: Copy arguments source/size not mapped\n");
	return -ENOMEM;
	}

	/* Find out how much free trusted ram remains after BL1 load */
	mem_layout = bl1_plat_sec_mem_layout();
	if ((image_desc->image_info.image_base < mem_layout->free_base) \|\|
	(image_desc->image_info.image_base + image_size >
	mem_layout->free_base + mem_layout->free_size)) {
	WARN("BL1-FWU: Memory not available to copy\n");
	return -ENOMEM;
	}

	/* Update the image size. */
	image_desc->image_info.image_size = image_size;

	/* Copy image for given size. */
	memcpy((void )base_addr, (const void )image_src, block_size);
	...

	This code fragment is executed during the 1st invocation of the image copy
	operation. Both ``block_size`` and ``image_size`` are SMC arguments. A very
	large value of ``image_size`` may result in an integer overflow in the 2nd
	``if`` statement, which would bypass the check, allowing execution to proceed.
	If ``bl1_plat_mem_check()`` also passes, this may result in an unexpectedly
	large copy of data into secure memory.

	If the platform's implementation of ``bl1_plat_mem_check()`` is correct then it
	may help prevent the above 2 vulnerabilities from being exploited. However, the
	ARM platform version of this function contains a similar vulnerability:

	- Line 88 of ``plat/arm/common/arm_bl1_fwu.c`` in function of
	``bl1_plat_mem_check()``:

	.. code:: c

	while (mmap[index].mem_size) {
	if ((mem_base >= mmap[index].mem_base) &&
	((mem_base + mem_size)
	<= (mmap[index].mem_base +
	mmap[index].mem_size)))
	return 0;

	index++;
	}
	...

	This function checks that the passed memory region is within one of the
	regions mapped in by ARM platforms. Here, ``mem_size`` may be the
	``block_size`` passed from ``bl1_fwu_image_copy()``. A very large value of
	``mem_size`` may result in an integer overflow and the function to incorrectly
	return success. Platforms that copy this insecure pattern will have the same
	vulnerability.

	.. _CVE-2016-10319: http://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2016-10319
	.. _48bfb88: https://github.com/ARM-software/arm-trusted-firmware/commit/48bfb88
	.. _Pull Request #783: https://github.com/ARM-software/arm-trusted-firmware/pull/783