6db4831e98
Android 14
245 lines
11 KiB
Plaintext
245 lines
11 KiB
Plaintext
1. Intel(R) MPX Overview
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========================
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Intel(R) Memory Protection Extensions (Intel(R) MPX) is a new capability
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introduced into Intel Architecture. Intel MPX provides hardware features
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that can be used in conjunction with compiler changes to check memory
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references, for those references whose compile-time normal intentions are
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usurped at runtime due to buffer overflow or underflow.
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You can tell if your CPU supports MPX by looking in /proc/cpuinfo:
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cat /proc/cpuinfo | grep ' mpx '
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For more information, please refer to Intel(R) Architecture Instruction
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Set Extensions Programming Reference, Chapter 9: Intel(R) Memory Protection
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Extensions.
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Note: As of December 2014, no hardware with MPX is available but it is
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possible to use SDE (Intel(R) Software Development Emulator) instead, which
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can be downloaded from
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http://software.intel.com/en-us/articles/intel-software-development-emulator
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2. How to get the advantage of MPX
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==================================
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For MPX to work, changes are required in the kernel, binutils and compiler.
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No source changes are required for applications, just a recompile.
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There are a lot of moving parts of this to all work right. The following
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is how we expect the compiler, application and kernel to work together.
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1) Application developer compiles with -fmpx. The compiler will add the
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instrumentation as well as some setup code called early after the app
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starts. New instruction prefixes are noops for old CPUs.
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2) That setup code allocates (virtual) space for the "bounds directory",
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points the "bndcfgu" register to the directory (must also set the valid
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bit) and notifies the kernel (via the new prctl(PR_MPX_ENABLE_MANAGEMENT))
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that the app will be using MPX. The app must be careful not to access
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the bounds tables between the time when it populates "bndcfgu" and
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when it calls the prctl(). This might be hard to guarantee if the app
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is compiled with MPX. You can add "__attribute__((bnd_legacy))" to
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the function to disable MPX instrumentation to help guarantee this.
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Also be careful not to call out to any other code which might be
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MPX-instrumented.
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3) The kernel detects that the CPU has MPX, allows the new prctl() to
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succeed, and notes the location of the bounds directory. Userspace is
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expected to keep the bounds directory at that location. We note it
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instead of reading it each time because the 'xsave' operation needed
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to access the bounds directory register is an expensive operation.
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4) If the application needs to spill bounds out of the 4 registers, it
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issues a bndstx instruction. Since the bounds directory is empty at
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this point, a bounds fault (#BR) is raised, the kernel allocates a
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bounds table (in the user address space) and makes the relevant entry
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in the bounds directory point to the new table.
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5) If the application violates the bounds specified in the bounds registers,
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a separate kind of #BR is raised which will deliver a signal with
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information about the violation in the 'struct siginfo'.
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6) Whenever memory is freed, we know that it can no longer contain valid
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pointers, and we attempt to free the associated space in the bounds
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tables. If an entire table becomes unused, we will attempt to free
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the table and remove the entry in the directory.
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To summarize, there are essentially three things interacting here:
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GCC with -fmpx:
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* enables annotation of code with MPX instructions and prefixes
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* inserts code early in the application to call in to the "gcc runtime"
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GCC MPX Runtime:
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* Checks for hardware MPX support in cpuid leaf
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* allocates virtual space for the bounds directory (malloc() essentially)
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* points the hardware BNDCFGU register at the directory
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* calls a new prctl(PR_MPX_ENABLE_MANAGEMENT) to notify the kernel to
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start managing the bounds directories
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Kernel MPX Code:
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* Checks for hardware MPX support in cpuid leaf
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* Handles #BR exceptions and sends SIGSEGV to the app when it violates
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bounds, like during a buffer overflow.
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* When bounds are spilled in to an unallocated bounds table, the kernel
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notices in the #BR exception, allocates the virtual space, then
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updates the bounds directory to point to the new table. It keeps
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special track of the memory with a VM_MPX flag.
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* Frees unused bounds tables at the time that the memory they described
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is unmapped.
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3. How does MPX kernel code work
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================================
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Handling #BR faults caused by MPX
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---------------------------------
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When MPX is enabled, there are 2 new situations that can generate
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#BR faults.
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* new bounds tables (BT) need to be allocated to save bounds.
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* bounds violation caused by MPX instructions.
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We hook #BR handler to handle these two new situations.
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On-demand kernel allocation of bounds tables
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--------------------------------------------
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MPX only has 4 hardware registers for storing bounds information. If
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MPX-enabled code needs more than these 4 registers, it needs to spill
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them somewhere. It has two special instructions for this which allow
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the bounds to be moved between the bounds registers and some new "bounds
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tables".
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#BR exceptions are a new class of exceptions just for MPX. They are
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similar conceptually to a page fault and will be raised by the MPX
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hardware during both bounds violations or when the tables are not
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present. The kernel handles those #BR exceptions for not-present tables
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by carving the space out of the normal processes address space and then
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pointing the bounds-directory over to it.
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The tables need to be accessed and controlled by userspace because
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the instructions for moving bounds in and out of them are extremely
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frequent. They potentially happen every time a register points to
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memory. Any direct kernel involvement (like a syscall) to access the
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tables would obviously destroy performance.
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Why not do this in userspace? MPX does not strictly require anything in
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the kernel. It can theoretically be done completely from userspace. Here
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are a few ways this could be done. We don't think any of them are practical
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in the real-world, but here they are.
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Q: Can virtual space simply be reserved for the bounds tables so that we
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never have to allocate them?
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A: MPX-enabled application will possibly create a lot of bounds tables in
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process address space to save bounds information. These tables can take
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up huge swaths of memory (as much as 80% of the memory on the system)
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even if we clean them up aggressively. In the worst-case scenario, the
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tables can be 4x the size of the data structure being tracked. IOW, a
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1-page structure can require 4 bounds-table pages. An X-GB virtual
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area needs 4*X GB of virtual space, plus 2GB for the bounds directory.
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If we were to preallocate them for the 128TB of user virtual address
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space, we would need to reserve 512TB+2GB, which is larger than the
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entire virtual address space today. This means they can not be reserved
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ahead of time. Also, a single process's pre-populated bounds directory
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consumes 2GB of virtual *AND* physical memory. IOW, it's completely
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infeasible to prepopulate bounds directories.
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Q: Can we preallocate bounds table space at the same time memory is
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allocated which might contain pointers that might eventually need
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bounds tables?
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A: This would work if we could hook the site of each and every memory
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allocation syscall. This can be done for small, constrained applications.
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But, it isn't practical at a larger scale since a given app has no
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way of controlling how all the parts of the app might allocate memory
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(think libraries). The kernel is really the only place to intercept
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these calls.
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Q: Could a bounds fault be handed to userspace and the tables allocated
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there in a signal handler instead of in the kernel?
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A: mmap() is not on the list of safe async handler functions and even
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if mmap() would work it still requires locking or nasty tricks to
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keep track of the allocation state there.
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Having ruled out all of the userspace-only approaches for managing
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bounds tables that we could think of, we create them on demand in
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the kernel.
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Decoding MPX instructions
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-------------------------
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If a #BR is generated due to a bounds violation caused by MPX.
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We need to decode MPX instructions to get violation address and
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set this address into extended struct siginfo.
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The _sigfault field of struct siginfo is extended as follow:
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87 /* SIGILL, SIGFPE, SIGSEGV, SIGBUS */
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88 struct {
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89 void __user *_addr; /* faulting insn/memory ref. */
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90 #ifdef __ARCH_SI_TRAPNO
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91 int _trapno; /* TRAP # which caused the signal */
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92 #endif
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93 short _addr_lsb; /* LSB of the reported address */
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94 struct {
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95 void __user *_lower;
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96 void __user *_upper;
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97 } _addr_bnd;
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98 } _sigfault;
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The '_addr' field refers to violation address, and new '_addr_and'
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field refers to the upper/lower bounds when a #BR is caused.
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Glibc will be also updated to support this new siginfo. So user
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can get violation address and bounds when bounds violations occur.
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Cleanup unused bounds tables
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----------------------------
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When a BNDSTX instruction attempts to save bounds to a bounds directory
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entry marked as invalid, a #BR is generated. This is an indication that
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no bounds table exists for this entry. In this case the fault handler
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will allocate a new bounds table on demand.
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Since the kernel allocated those tables on-demand without userspace
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knowledge, it is also responsible for freeing them when the associated
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mappings go away.
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Here, the solution for this issue is to hook do_munmap() to check
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whether one process is MPX enabled. If yes, those bounds tables covered
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in the virtual address region which is being unmapped will be freed also.
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Adding new prctl commands
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-------------------------
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Two new prctl commands are added to enable and disable MPX bounds tables
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management in kernel.
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155 #define PR_MPX_ENABLE_MANAGEMENT 43
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156 #define PR_MPX_DISABLE_MANAGEMENT 44
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Runtime library in userspace is responsible for allocation of bounds
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directory. So kernel have to use XSAVE instruction to get the base
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of bounds directory from BNDCFG register.
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But XSAVE is expected to be very expensive. In order to do performance
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optimization, we have to get the base of bounds directory and save it
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into struct mm_struct to be used in future during PR_MPX_ENABLE_MANAGEMENT
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command execution.
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4. Special rules
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================
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1) If userspace is requesting help from the kernel to do the management
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of bounds tables, it may not create or modify entries in the bounds directory.
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Certainly users can allocate bounds tables and forcibly point the bounds
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directory at them through XSAVE instruction, and then set valid bit
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of bounds entry to have this entry valid. But, the kernel will decline
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to assist in managing these tables.
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2) Userspace may not take multiple bounds directory entries and point
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them at the same bounds table.
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This is allowed architecturally. See more information "Intel(R) Architecture
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Instruction Set Extensions Programming Reference" (9.3.4).
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However, if users did this, the kernel might be fooled in to unmapping an
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in-use bounds table since it does not recognize sharing.
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