[deliverable/linux.git] / Documentation / x86 / intel_mpx.txt

1. Intel(R) MPX Overview
========================

Intel(R) Memory Protection Extensions (Intel(R) MPX) is a new capability
introduced into Intel Architecture. Intel MPX provides hardware features
that can be used in conjunction with compiler changes to check memory
references, for those references whose compile-time normal intentions are
usurped at runtime due to buffer overflow or underflow.

For more information, please refer to Intel(R) Architecture Instruction
Set Extensions Programming Reference, Chapter 9: Intel(R) Memory Protection
Extensions.

Note: Currently no hardware with MPX ISA is available but it is always
possible to use SDE (Intel(R) Software Development Emulator) instead, which
can be downloaded from
http://software.intel.com/en-us/articles/intel-software-development-emulator


2. How to get the advantage of MPX
==================================

For MPX to work, changes are required in the kernel, binutils and compiler.
No source changes are required for applications, just a recompile.

There are a lot of moving parts of this to all work right. The following
is how we expect the compiler, application and kernel to work together.

1) Application developer compiles with -fmpx. The compiler will add the
   instrumentation as well as some setup code called early after the app
   starts. New instruction prefixes are noops for old CPUs.
2) That setup code allocates (virtual) space for the "bounds directory",
   points the "bndcfgu" register to the directory (must also set the valid
   bit) and notifies the kernel (via the new prctl(PR_MPX_ENABLE_MANAGEMENT))
   that the app will be using MPX.  The app must be careful not to access
   the bounds tables between the time when it populates "bndcfgu" and
   when it calls the prctl().  This might be hard to guarantee if the app
   is compiled with MPX.  You can add "__attribute__((bnd_legacy))" to
   the function to disable MPX instrumentation to help guarantee this.
   Also be careful not to call out to any other code which might be
   MPX-instrumented.
3) The kernel detects that the CPU has MPX, allows the new prctl() to
   succeed, and notes the location of the bounds directory. Userspace is
   expected to keep the bounds directory at that locationWe note it
   instead of reading it each time because the 'xsave' operation needed
   to access the bounds directory register is an expensive operation.
4) If the application needs to spill bounds out of the 4 registers, it
   issues a bndstx instruction. Since the bounds directory is empty at
   this point, a bounds fault (#BR) is raised, the kernel allocates a
   bounds table (in the user address space) and makes the relevant entry
   in the bounds directory point to the new table.
5) If the application violates the bounds specified in the bounds registers,
   a separate kind of #BR is raised which will deliver a signal with
   information about the violation in the 'struct siginfo'.
6) Whenever memory is freed, we know that it can no longer contain valid
   pointers, and we attempt to free the associated space in the bounds
   tables. If an entire table becomes unused, we will attempt to free
   the table and remove the entry in the directory.

To summarize, there are essentially three things interacting here:

GCC with -fmpx:
 * enables annotation of code with MPX instructions and prefixes
 * inserts code early in the application to call in to the "gcc runtime"
GCC MPX Runtime:
 * Checks for hardware MPX support in cpuid leaf
 * allocates virtual space for the bounds directory (malloc() essentially)
 * points the hardware BNDCFGU register at the directory
 * calls a new prctl(PR_MPX_ENABLE_MANAGEMENT) to notify the kernel to
   start managing the bounds directories
Kernel MPX Code:
 * Checks for hardware MPX support in cpuid leaf
 * Handles #BR exceptions and sends SIGSEGV to the app when it violates
   bounds, like during a buffer overflow.
 * When bounds are spilled in to an unallocated bounds table, the kernel
   notices in the #BR exception, allocates the virtual space, then
   updates the bounds directory to point to the new table. It keeps
   special track of the memory with a VM_MPX flag.
 * Frees unused bounds tables at the time that the memory they described
   is unmapped.


3. How does MPX kernel code work
================================

Handling #BR faults caused by MPX
---------------------------------

When MPX is enabled, there are 2 new situations that can generate
#BR faults.
  * new bounds tables (BT) need to be allocated to save bounds.
  * bounds violation caused by MPX instructions.

We hook #BR handler to handle these two new situations.

On-demand kernel allocation of bounds tables
--------------------------------------------

MPX only has 4 hardware registers for storing bounds information. If
MPX-enabled code needs more than these 4 registers, it needs to spill
them somewhere. It has two special instructions for this which allow
the bounds to be moved between the bounds registers and some new "bounds
tables".

#BR exceptions are a new class of exceptions just for MPX. They are
similar conceptually to a page fault and will be raised by the MPX
hardware during both bounds violations or when the tables are not
present. The kernel handles those #BR exceptions for not-present tables
by carving the space out of the normal processes address space and then
pointing the bounds-directory over to it.

The tables need to be accessed and controlled by userspace because
the instructions for moving bounds in and out of them are extremely
frequent. They potentially happen every time a register points to
memory. Any direct kernel involvement (like a syscall) to access the
tables would obviously destroy performance.

Why not do this in userspace? MPX does not strictly require anything in
the kernel. It can theoretically be done completely from userspace. Here
are a few ways this could be done. We don't think any of them are practical
in the real-world, but here they are.

Q: Can virtual space simply be reserved for the bounds tables so that we
   never have to allocate them?
A: MPX-enabled application will possibly create a lot of bounds tables in
   process address space to save bounds information. These tables can take
   up huge swaths of memory (as much as 80% of the memory on the system)
   even if we clean them up aggressively. In the worst-case scenario, the
   tables can be 4x the size of the data structure being tracked. IOW, a
   1-page structure can require 4 bounds-table pages. An X-GB virtual
   area needs 4*X GB of virtual space, plus 2GB for the bounds directory.
   If we were to preallocate them for the 128TB of user virtual address
   space, we would need to reserve 512TB+2GB, which is larger than the
   entire virtual address space today. This means they can not be reserved
   ahead of time. Also, a single process's pre-popualated bounds directory
   consumes 2GB of virtual *AND* physical memory. IOW, it's completely
   infeasible to prepopulate bounds directories.

Q: Can we preallocate bounds table space at the same time memory is
   allocated which might contain pointers that might eventually need
   bounds tables?
A: This would work if we could hook the site of each and every memory
   allocation syscall. This can be done for small, constrained applications.
   But, it isn't practical at a larger scale since a given app has no
   way of controlling how all the parts of the app might allocate memory
   (think libraries). The kernel is really the only place to intercept
   these calls.

Q: Could a bounds fault be handed to userspace and the tables allocated
   there in a signal handler intead of in the kernel?
A: mmap() is not on the list of safe async handler functions and even
   if mmap() would work it still requires locking or nasty tricks to
   keep track of the allocation state there.

Having ruled out all of the userspace-only approaches for managing
bounds tables that we could think of, we create them on demand in
the kernel.

Decoding MPX instructions
-------------------------

If a #BR is generated due to a bounds violation caused by MPX.
We need to decode MPX instructions to get violation address and
set this address into extended struct siginfo.

The _sigfault feild of struct siginfo is extended as follow:

87		/* SIGILL, SIGFPE, SIGSEGV, SIGBUS */
88		struct {
89			void __user *_addr; /* faulting insn/memory ref. */
90 #ifdef __ARCH_SI_TRAPNO
91			int _trapno;	/* TRAP # which caused the signal */
92 #endif
93			short _addr_lsb; /* LSB of the reported address */
94			struct {
95				void __user *_lower;
96				void __user *_upper;
97			} _addr_bnd;
98		} _sigfault;

The '_addr' field refers to violation address, and new '_addr_and'
field refers to the upper/lower bounds when a #BR is caused.

Glibc will be also updated to support this new siginfo. So user
can get violation address and bounds when bounds violations occur.

Cleanup unused bounds tables
----------------------------

When a BNDSTX instruction attempts to save bounds to a bounds directory
entry marked as invalid, a #BR is generated. This is an indication that
no bounds table exists for this entry. In this case the fault handler
will allocate a new bounds table on demand.

Since the kernel allocated those tables on-demand without userspace
knowledge, it is also responsible for freeing them when the associated
mappings go away.

Here, the solution for this issue is to hook do_munmap() to check
whether one process is MPX enabled. If yes, those bounds tables covered
in the virtual address region which is being unmapped will be freed also.

Adding new prctl commands
-------------------------

Two new prctl commands are added to enable and disable MPX bounds tables
management in kernel.

155	#define PR_MPX_ENABLE_MANAGEMENT	43
156	#define PR_MPX_DISABLE_MANAGEMENT	44

Runtime library in userspace is responsible for allocation of bounds
directory. So kernel have to use XSAVE instruction to get the base
of bounds directory from BNDCFG register.

But XSAVE is expected to be very expensive. In order to do performance
optimization, we have to get the base of bounds directory and save it
into struct mm_struct to be used in future during PR_MPX_ENABLE_MANAGEMENT
command execution.


4. Special rules
================

1) If userspace is requesting help from the kernel to do the management
of bounds tables, it may not create or modify entries in the bounds directory.

Certainly users can allocate bounds tables and forcibly point the bounds
directory at them through XSAVE instruction, and then set valid bit
of bounds entry to have this entry valid.  But, the kernel will decline
to assist in managing these tables.

2) Userspace may not take multiple bounds directory entries and point
them at the same bounds table.

This is allowed architecturally.  See more information "Intel(R) Architecture
Instruction Set Extensions Programming Reference" (9.3.4).

However, if users did this, the kernel might be fooled in to unmaping an
in-use bounds table since it does not recognize sharing.
Commit	Line	Data
57765636 QR	1	1. Intel(R) MPX Overview
	2	========================
	3
	4	Intel(R) Memory Protection Extensions (Intel(R) MPX) is a new capability
	5	introduced into Intel Architecture. Intel MPX provides hardware features
	6	that can be used in conjunction with compiler changes to check memory
	7	references, for those references whose compile-time normal intentions are
	8	usurped at runtime due to buffer overflow or underflow.
	9
	10	For more information, please refer to Intel(R) Architecture Instruction
	11	Set Extensions Programming Reference, Chapter 9: Intel(R) Memory Protection
	12	Extensions.
	13
	14	Note: Currently no hardware with MPX ISA is available but it is always
	15	possible to use SDE (Intel(R) Software Development Emulator) instead, which
	16	can be downloaded from
	17	http://software.intel.com/en-us/articles/intel-software-development-emulator
	18
	19
	20	2. How to get the advantage of MPX
	21	==================================
	22
	23	For MPX to work, changes are required in the kernel, binutils and compiler.
	24	No source changes are required for applications, just a recompile.
	25
	26	There are a lot of moving parts of this to all work right. The following
	27	is how we expect the compiler, application and kernel to work together.
	28
	29	1) Application developer compiles with -fmpx. The compiler will add the
	30	instrumentation as well as some setup code called early after the app
	31	starts. New instruction prefixes are noops for old CPUs.
	32	2) That setup code allocates (virtual) space for the "bounds directory",
010e593b DH	33	points the "bndcfgu" register to the directory (must also set the valid
	34	bit) and notifies the kernel (via the new prctl(PR_MPX_ENABLE_MANAGEMENT))
	35	that the app will be using MPX. The app must be careful not to access
	36	the bounds tables between the time when it populates "bndcfgu" and
	37	when it calls the prctl(). This might be hard to guarantee if the app
	38	is compiled with MPX. You can add "__attribute__((bnd_legacy))" to
	39	the function to disable MPX instrumentation to help guarantee this.
	40	Also be careful not to call out to any other code which might be
	41	MPX-instrumented.
57765636 QR	42	3) The kernel detects that the CPU has MPX, allows the new prctl() to
	43	succeed, and notes the location of the bounds directory. Userspace is
	44	expected to keep the bounds directory at that locationWe note it
	45	instead of reading it each time because the 'xsave' operation needed
	46	to access the bounds directory register is an expensive operation.
	47	4) If the application needs to spill bounds out of the 4 registers, it
	48	issues a bndstx instruction. Since the bounds directory is empty at
	49	this point, a bounds fault (#BR) is raised, the kernel allocates a
	50	bounds table (in the user address space) and makes the relevant entry
	51	in the bounds directory point to the new table.
	52	5) If the application violates the bounds specified in the bounds registers,
	53	a separate kind of #BR is raised which will deliver a signal with
	54	information about the violation in the 'struct siginfo'.
	55	6) Whenever memory is freed, we know that it can no longer contain valid
	56	pointers, and we attempt to free the associated space in the bounds
	57	tables. If an entire table becomes unused, we will attempt to free
	58	the table and remove the entry in the directory.
	59
	60	To summarize, there are essentially three things interacting here:
	61
	62	GCC with -fmpx:
	63	* enables annotation of code with MPX instructions and prefixes
	64	* inserts code early in the application to call in to the "gcc runtime"
	65	GCC MPX Runtime:
	66	* Checks for hardware MPX support in cpuid leaf
	67	* allocates virtual space for the bounds directory (malloc() essentially)
	68	* points the hardware BNDCFGU register at the directory
	69	* calls a new prctl(PR_MPX_ENABLE_MANAGEMENT) to notify the kernel to
	70	start managing the bounds directories
	71	Kernel MPX Code:
	72	* Checks for hardware MPX support in cpuid leaf
	73	* Handles #BR exceptions and sends SIGSEGV to the app when it violates
	74	bounds, like during a buffer overflow.
	75	* When bounds are spilled in to an unallocated bounds table, the kernel
	76	notices in the #BR exception, allocates the virtual space, then
	77	updates the bounds directory to point to the new table. It keeps
	78	special track of the memory with a VM_MPX flag.
	79	* Frees unused bounds tables at the time that the memory they described
	80	is unmapped.
	81
	82
	83	3. How does MPX kernel code work
	84	================================
	85
	86	Handling #BR faults caused by MPX
	87	---------------------------------
	88
	89	When MPX is enabled, there are 2 new situations that can generate
	90	#BR faults.
	91	* new bounds tables (BT) need to be allocated to save bounds.
	92	* bounds violation caused by MPX instructions.
	93
	94	We hook #BR handler to handle these two new situations.
	95
	96	On-demand kernel allocation of bounds tables
	97	--------------------------------------------
	98
	99	MPX only has 4 hardware registers for storing bounds information. If
	100	MPX-enabled code needs more than these 4 registers, it needs to spill
	101	them somewhere. It has two special instructions for this which allow
	102	the bounds to be moved between the bounds registers and some new "bounds
	103	tables".
	104
	105	#BR exceptions are a new class of exceptions just for MPX. They are
106	similar conceptually to a page fault and will be raised by the MPX
107	hardware during both bounds violations or when the tables are not
108	present. The kernel handles those #BR exceptions for not-present tables
109	by carving the space out of the normal processes address space and then
110	pointing the bounds-directory over to it.
111
112	The tables need to be accessed and controlled by userspace because
113	the instructions for moving bounds in and out of them are extremely
114	frequent. They potentially happen every time a register points to
115	memory. Any direct kernel involvement (like a syscall) to access the
116	tables would obviously destroy performance.
117
118	Why not do this in userspace? MPX does not strictly require anything in
119	the kernel. It can theoretically be done completely from userspace. Here
120	are a few ways this could be done. We don't think any of them are practical
121	in the real-world, but here they are.
122
123	Q: Can virtual space simply be reserved for the bounds tables so that we
124	never have to allocate them?
125	A: MPX-enabled application will possibly create a lot of bounds tables in
126	process address space to save bounds information. These tables can take
127	up huge swaths of memory (as much as 80% of the memory on the system)
128	even if we clean them up aggressively. In the worst-case scenario, the
129	tables can be 4x the size of the data structure being tracked. IOW, a
130	1-page structure can require 4 bounds-table pages. An X-GB virtual
131	area needs 4*X GB of virtual space, plus 2GB for the bounds directory.
132	If we were to preallocate them for the 128TB of user virtual address
133	space, we would need to reserve 512TB+2GB, which is larger than the
134	entire virtual address space today. This means they can not be reserved
135	ahead of time. Also, a single process's pre-popualated bounds directory
136	consumes 2GB of virtual AND physical memory. IOW, it's completely
137	infeasible to prepopulate bounds directories.
138
139	Q: Can we preallocate bounds table space at the same time memory is
140	allocated which might contain pointers that might eventually need
141	bounds tables?
142	A: This would work if we could hook the site of each and every memory
143	allocation syscall. This can be done for small, constrained applications.
144	But, it isn't practical at a larger scale since a given app has no
145	way of controlling how all the parts of the app might allocate memory
146	(think libraries). The kernel is really the only place to intercept
147	these calls.
148
149	Q: Could a bounds fault be handed to userspace and the tables allocated
150	there in a signal handler intead of in the kernel?
151	A: mmap() is not on the list of safe async handler functions and even
152	if mmap() would work it still requires locking or nasty tricks to
153	keep track of the allocation state there.
154
155	Having ruled out all of the userspace-only approaches for managing
156	bounds tables that we could think of, we create them on demand in
157	the kernel.
158
159	Decoding MPX instructions
160	-------------------------
161
162	If a #BR is generated due to a bounds violation caused by MPX.
163	We need to decode MPX instructions to get violation address and
164	set this address into extended struct siginfo.
165
166	The _sigfault feild of struct siginfo is extended as follow:
167
168	87 /* SIGILL, SIGFPE, SIGSEGV, SIGBUS */
169	88 struct {
170	89 void __user _addr; / faulting insn/memory ref. */
171	90 #ifdef __ARCH_SI_TRAPNO
172	91 int _trapno; /* TRAP # which caused the signal */
173	92 #endif
174	93 short _addr_lsb; /* LSB of the reported address */
175	94 struct {
176	95 void __user *_lower;
177	96 void __user *_upper;
178	97 } _addr_bnd;
179	98 } _sigfault;
180
181	The '_addr' field refers to violation address, and new '_addr_and'
182	field refers to the upper/lower bounds when a #BR is caused.
183
184	Glibc will be also updated to support this new siginfo. So user
185	can get violation address and bounds when bounds violations occur.
186
187	Cleanup unused bounds tables
188	----------------------------
189
190	When a BNDSTX instruction attempts to save bounds to a bounds directory
191	entry marked as invalid, a #BR is generated. This is an indication that
192	no bounds table exists for this entry. In this case the fault handler
193	will allocate a new bounds table on demand.
194
195	Since the kernel allocated those tables on-demand without userspace
196	knowledge, it is also responsible for freeing them when the associated
197	mappings go away.
198
199	Here, the solution for this issue is to hook do_munmap() to check
200	whether one process is MPX enabled. If yes, those bounds tables covered
201	in the virtual address region which is being unmapped will be freed also.
202
203	Adding new prctl commands
204	-------------------------
205
206	Two new prctl commands are added to enable and disable MPX bounds tables
207	management in kernel.
208
209	155 #define PR_MPX_ENABLE_MANAGEMENT 43
210	156 #define PR_MPX_DISABLE_MANAGEMENT 44
211
212	Runtime library in userspace is responsible for allocation of bounds
213	directory. So kernel have to use XSAVE instruction to get the base
214	of bounds directory from BNDCFG register.
215
216	But XSAVE is expected to be very expensive. In order to do performance
217	optimization, we have to get the base of bounds directory and save it
218	into struct mm_struct to be used in future during PR_MPX_ENABLE_MANAGEMENT
219	command execution.
220
221
222	4. Special rules
223	================
224
225	1) If userspace is requesting help from the kernel to do the management
226	of bounds tables, it may not create or modify entries in the bounds directory.
227
228	Certainly users can allocate bounds tables and forcibly point the bounds
229	directory at them through XSAVE instruction, and then set valid bit
230	of bounds entry to have this entry valid. But, the kernel will decline
231	to assist in managing these tables.
232
233	2) Userspace may not take multiple bounds directory entries and point
234	them at the same bounds table.
235
236	This is allowed architecturally. See more information "Intel(R) Architecture
237	Instruction Set Extensions Programming Reference" (9.3.4).
238
239	However, if users did this, the kernel might be fooled in to unmaping an
240	in-use bounds table since it does not recognize sharing.