Documentation/arm64/memory-tagging-extension.rst - linux/kernel/git/davem/net - Git at Google

 ===============================================
 Memory Tagging Extension (MTE) in AArch64 Linux
 ===============================================

 Authors: Vincenzo Frascino <vincenzo.frascino@arm.com>
          Catalin Marinas <catalin.marinas@arm.com>

 Date: 2020-02-25

 This document describes the provision of the Memory Tagging Extension
 functionality in AArch64 Linux.

 Introduction
 ============

 ARMv8.5 based processors introduce the Memory Tagging Extension (MTE)
 feature. MTE is built on top of the ARMv8.0 virtual address tagging TBI
 (Top Byte Ignore) feature and allows software to access a 4-bit
 allocation tag for each 16-byte granule in the physical address space.
 Such memory range must be mapped with the Normal-Tagged memory
 attribute. A logical tag is derived from bits 59-56 of the virtual
 address used for the memory access. A CPU with MTE enabled will compare
 the logical tag against the allocation tag and potentially raise an
 exception on mismatch, subject to system registers configuration.

 Userspace Support
 =================

 When ``CONFIG_ARM64_MTE`` is selected and Memory Tagging Extension is
 supported by the hardware, the kernel advertises the feature to
 userspace via ``HWCAP2_MTE``.

 PROT_MTE
 --------

 To access the allocation tags, a user process must enable the Tagged
 memory attribute on an address range using a new ``prot`` flag for
 ``mmap()`` and ``mprotect()``:

 ``PROT_MTE`` - Pages allow access to the MTE allocation tags.

 The allocation tag is set to 0 when such pages are first mapped in the
 user address space and preserved on copy-on-write. ``MAP_SHARED`` is
 supported and the allocation tags can be shared between processes.

 **Note**: ``PROT_MTE`` is only supported on ``MAP_ANONYMOUS`` and
 RAM-based file mappings (``tmpfs``, ``memfd``). Passing it to other
 types of mapping will result in ``-EINVAL`` returned by these system
 calls.

 **Note**: The ``PROT_MTE`` flag (and corresponding memory type) cannot
 be cleared by ``mprotect()``.

 **Note**: ``madvise()`` memory ranges with ``MADV_DONTNEED`` and
 ``MADV_FREE`` may have the allocation tags cleared (set to 0) at any
 point after the system call.

 Tag Check Faults
 ----------------

 When ``PROT_MTE`` is enabled on an address range and a mismatch between
 the logical and allocation tags occurs on access, there are three
 configurable behaviours:

 - *Ignore* - This is the default mode. The CPU (and kernel) ignores the
   tag check fault.

 - *Synchronous* - The kernel raises a ``SIGSEGV`` synchronously, with
   ``.si_code = SEGV_MTESERR`` and ``.si_addr = <fault-address>``. The
   memory access is not performed. If ``SIGSEGV`` is ignored or blocked
   by the offending thread, the containing process is terminated with a
   ``coredump``.

 - *Asynchronous* - The kernel raises a ``SIGSEGV``, in the offending
   thread, asynchronously following one or multiple tag check faults,
   with ``.si_code = SEGV_MTEAERR`` and ``.si_addr = 0`` (the faulting
   address is unknown).

 The user can select the above modes, per thread, using the
 ``prctl(PR_SET_TAGGED_ADDR_CTRL, flags, 0, 0, 0)`` system call where
 ``flags`` contain one of the following values in the ``PR_MTE_TCF_MASK``
 bit-field:

 - ``PR_MTE_TCF_NONE``  - *Ignore* tag check faults
 - ``PR_MTE_TCF_SYNC``  - *Synchronous* tag check fault mode
 - ``PR_MTE_TCF_ASYNC`` - *Asynchronous* tag check fault mode

 The current tag check fault mode can be read using the
 ``prctl(PR_GET_TAGGED_ADDR_CTRL, 0, 0, 0, 0)`` system call.

 Tag checking can also be disabled for a user thread by setting the
 ``PSTATE.TCO`` bit with ``MSR TCO, #1``.

 **Note**: Signal handlers are always invoked with ``PSTATE.TCO = 0``,
 irrespective of the interrupted context. ``PSTATE.TCO`` is restored on
 ``sigreturn()``.

 **Note**: There are no *match-all* logical tags available for user
 applications.

 **Note**: Kernel accesses to the user address space (e.g. ``read()``
 system call) are not checked if the user thread tag checking mode is
 ``PR_MTE_TCF_NONE`` or ``PR_MTE_TCF_ASYNC``. If the tag checking mode is
 ``PR_MTE_TCF_SYNC``, the kernel makes a best effort to check its user
 address accesses, however it cannot always guarantee it. Kernel accesses
 to user addresses are always performed with an effective ``PSTATE.TCO``
 value of zero, regardless of the user configuration.

 Excluding Tags in the ``IRG``, ``ADDG`` and ``SUBG`` instructions
 -----------------------------------------------------------------

 The architecture allows excluding certain tags to be randomly generated
 via the ``GCR_EL1.Exclude`` register bit-field. By default, Linux
 excludes all tags other than 0. A user thread can enable specific tags
 in the randomly generated set using the ``prctl(PR_SET_TAGGED_ADDR_CTRL,
 flags, 0, 0, 0)`` system call where ``flags`` contains the tags bitmap
 in the ``PR_MTE_TAG_MASK`` bit-field.

 **Note**: The hardware uses an exclude mask but the ``prctl()``
 interface provides an include mask. An include mask of ``0`` (exclusion
 mask ``0xffff``) results in the CPU always generating tag ``0``.

 Initial process state
 ---------------------

 On ``execve()``, the new process has the following configuration:

 - ``PR_TAGGED_ADDR_ENABLE`` set to 0 (disabled)
 - Tag checking mode set to ``PR_MTE_TCF_NONE``
 - ``PR_MTE_TAG_MASK`` set to 0 (all tags excluded)
 - ``PSTATE.TCO`` set to 0
 - ``PROT_MTE`` not set on any of the initial memory maps

 On ``fork()``, the new process inherits the parent's configuration and
 memory map attributes with the exception of the ``madvise()`` ranges
 with ``MADV_WIPEONFORK`` which will have the data and tags cleared (set
 to 0).

 The ``ptrace()`` interface
 --------------------------

 ``PTRACE_PEEKMTETAGS`` and ``PTRACE_POKEMTETAGS`` allow a tracer to read
 the tags from or set the tags to a tracee's address space. The
 ``ptrace()`` system call is invoked as ``ptrace(request, pid, addr,
 data)`` where:

 - ``request`` - one of ``PTRACE_PEEKMTETAGS`` or ``PTRACE_POKEMTETAGS``.
 - ``pid`` - the tracee's PID.
 - ``addr`` - address in the tracee's address space.
 - ``data`` - pointer to a ``struct iovec`` where ``iov_base`` points to
   a buffer of ``iov_len`` length in the tracer's address space.

 The tags in the tracer's ``iov_base`` buffer are represented as one
 4-bit tag per byte and correspond to a 16-byte MTE tag granule in the
 tracee's address space.

 **Note**: If ``addr`` is not aligned to a 16-byte granule, the kernel
 will use the corresponding aligned address.

 ``ptrace()`` return value:

 - 0 - tags were copied, the tracer's ``iov_len`` was updated to the
   number of tags transferred. This may be smaller than the requested
   ``iov_len`` if the requested address range in the tracee's or the
   tracer's space cannot be accessed or does not have valid tags.
 - ``-EPERM`` - the specified process cannot be traced.
 - ``-EIO`` - the tracee's address range cannot be accessed (e.g. invalid
   address) and no tags copied. ``iov_len`` not updated.
 - ``-EFAULT`` - fault on accessing the tracer's memory (``struct iovec``
   or ``iov_base`` buffer) and no tags copied. ``iov_len`` not updated.
 - ``-EOPNOTSUPP`` - the tracee's address does not have valid tags (never
   mapped with the ``PROT_MTE`` flag). ``iov_len`` not updated.

 **Note**: There are no transient errors for the requests above, so user
 programs should not retry in case of a non-zero system call return.

 ``PTRACE_GETREGSET`` and ``PTRACE_SETREGSET`` with ``addr ==
 ``NT_ARM_TAGGED_ADDR_CTRL`` allow ``ptrace()`` access to the tagged
 address ABI control and MTE configuration of a process as per the
 ``prctl()`` options described in
 Documentation/arm64/tagged-address-abi.rst and above. The corresponding
 ``regset`` is 1 element of 8 bytes (``sizeof(long))``).

 Example of correct usage
 ========================

 *MTE Example code*

 .. code-block:: c

     /*
      * To be compiled with -march=armv8.5-a+memtag
      */
     #include <errno.h>
     #include <stdint.h>
     #include <stdio.h>
     #include <stdlib.h>
     #include <unistd.h>
     #include <sys/auxv.h>
     #include <sys/mman.h>
     #include <sys/prctl.h>

     /*
      * From arch/arm64/include/uapi/asm/hwcap.h
      */
     #define HWCAP2_MTE              (1 << 18)

     /*
      * From arch/arm64/include/uapi/asm/mman.h
      */
     #define PROT_MTE                 0x20

     /*
      * From include/uapi/linux/prctl.h
      */
     #define PR_SET_TAGGED_ADDR_CTRL 55
     #define PR_GET_TAGGED_ADDR_CTRL 56
     # define PR_TAGGED_ADDR_ENABLE  (1UL << 0)
     # define PR_MTE_TCF_SHIFT       1
     # define PR_MTE_TCF_NONE        (0UL << PR_MTE_TCF_SHIFT)
     # define PR_MTE_TCF_SYNC        (1UL << PR_MTE_TCF_SHIFT)
     # define PR_MTE_TCF_ASYNC       (2UL << PR_MTE_TCF_SHIFT)
     # define PR_MTE_TCF_MASK        (3UL << PR_MTE_TCF_SHIFT)
     # define PR_MTE_TAG_SHIFT       3
     # define PR_MTE_TAG_MASK        (0xffffUL << PR_MTE_TAG_SHIFT)

     /*
      * Insert a random logical tag into the given pointer.
      */
     #define insert_random_tag(ptr) ({                       \
             uint64_t __val;                                 \
             asm("irg %0, %1" : "=r" (__val) : "r" (ptr));   \
             __val;                                          \
     })

     /*
      * Set the allocation tag on the destination address.
      */
     #define set_tag(tagged_addr) do {                                      \
             asm volatile("stg %0, [%0]" : : "r" (tagged_addr) : "memory"); \
     } while (0)

     int main()
     {
             unsigned char *a;
             unsigned long page_sz = sysconf(_SC_PAGESIZE);
             unsigned long hwcap2 = getauxval(AT_HWCAP2);

             /* check if MTE is present */
             if (!(hwcap2 & HWCAP2_MTE))
                     return EXIT_FAILURE;

             /*
              * Enable the tagged address ABI, synchronous MTE tag check faults and
              * allow all non-zero tags in the randomly generated set.
              */
             if (prctl(PR_SET_TAGGED_ADDR_CTRL,
                       PR_TAGGED_ADDR_ENABLE | PR_MTE_TCF_SYNC | (0xfffe << PR_MTE_TAG_SHIFT),
                       0, 0, 0)) {
                     perror("prctl() failed");
                     return EXIT_FAILURE;
             }

             a = mmap(0, page_sz, PROT_READ | PROT_WRITE,
                      MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
             if (a == MAP_FAILED) {
                     perror("mmap() failed");
                     return EXIT_FAILURE;
             }

             /*
              * Enable MTE on the above anonymous mmap. The flag could be passed
              * directly to mmap() and skip this step.
              */
             if (mprotect(a, page_sz, PROT_READ | PROT_WRITE | PROT_MTE)) {
                     perror("mprotect() failed");
                     return EXIT_FAILURE;
             }

             /* access with the default tag (0) */
             a[0] = 1;
             a[1] = 2;

             printf("a[0] = %hhu a[1] = %hhu\n", a[0], a[1]);

             /* set the logical and allocation tags */
             a = (unsigned char *)insert_random_tag(a);
             set_tag(a);

             printf("%p\n", a);

             /* non-zero tag access */
             a[0] = 3;
             printf("a[0] = %hhu a[1] = %hhu\n", a[0], a[1]);

             /*
              * If MTE is enabled correctly the next instruction will generate an
              * exception.
              */
             printf("Expecting SIGSEGV...\n");
             a[16] = 0xdd;

             /* this should not be printed in the PR_MTE_TCF_SYNC mode */
             printf("...haven't got one\n");

             return EXIT_FAILURE;
     }
	===============================================
	Memory Tagging Extension (MTE) in AArch64 Linux
	===============================================

	Authors: Vincenzo Frascino <vincenzo.frascino@arm.com>
	Catalin Marinas <catalin.marinas@arm.com>

	Date: 2020-02-25

	This document describes the provision of the Memory Tagging Extension
	functionality in AArch64 Linux.

	Introduction
	============

	ARMv8.5 based processors introduce the Memory Tagging Extension (MTE)
	feature. MTE is built on top of the ARMv8.0 virtual address tagging TBI
	(Top Byte Ignore) feature and allows software to access a 4-bit
	allocation tag for each 16-byte granule in the physical address space.
	Such memory range must be mapped with the Normal-Tagged memory
	attribute. A logical tag is derived from bits 59-56 of the virtual
	address used for the memory access. A CPU with MTE enabled will compare
	the logical tag against the allocation tag and potentially raise an
	exception on mismatch, subject to system registers configuration.

	Userspace Support
	=================

	When ``CONFIG_ARM64_MTE`` is selected and Memory Tagging Extension is
	supported by the hardware, the kernel advertises the feature to
	userspace via ``HWCAP2_MTE``.

	PROT_MTE
	--------

	To access the allocation tags, a user process must enable the Tagged
	memory attribute on an address range using a new ``prot`` flag for
	``mmap()`` and ``mprotect()``:

	``PROT_MTE`` - Pages allow access to the MTE allocation tags.

	The allocation tag is set to 0 when such pages are first mapped in the
	user address space and preserved on copy-on-write. ``MAP_SHARED`` is
	supported and the allocation tags can be shared between processes.

	Note: ``PROT_MTE`` is only supported on ``MAP_ANONYMOUS`` and
	RAM-based file mappings (``tmpfs``, ``memfd``). Passing it to other
	types of mapping will result in ``-EINVAL`` returned by these system
	calls.

	Note: The ``PROT_MTE`` flag (and corresponding memory type) cannot
	be cleared by ``mprotect()``.

	Note: ``madvise()`` memory ranges with ``MADV_DONTNEED`` and
	``MADV_FREE`` may have the allocation tags cleared (set to 0) at any
	point after the system call.

	Tag Check Faults
	----------------

	When ``PROT_MTE`` is enabled on an address range and a mismatch between
	the logical and allocation tags occurs on access, there are three
	configurable behaviours:

	- Ignore - This is the default mode. The CPU (and kernel) ignores the
	tag check fault.

	- Synchronous - The kernel raises a ``SIGSEGV`` synchronously, with
	``.si_code = SEGV_MTESERR`` and ``.si_addr = <fault-address>``. The
	memory access is not performed. If ``SIGSEGV`` is ignored or blocked
	by the offending thread, the containing process is terminated with a
	``coredump``.

	- Asynchronous - The kernel raises a ``SIGSEGV``, in the offending
	thread, asynchronously following one or multiple tag check faults,
	with ``.si_code = SEGV_MTEAERR`` and ``.si_addr = 0`` (the faulting
	address is unknown).

	The user can select the above modes, per thread, using the
	``prctl(PR_SET_TAGGED_ADDR_CTRL, flags, 0, 0, 0)`` system call where
	``flags`` contain one of the following values in the ``PR_MTE_TCF_MASK``
	bit-field:

	- ``PR_MTE_TCF_NONE`` - Ignore tag check faults
	- ``PR_MTE_TCF_SYNC`` - Synchronous tag check fault mode
	- ``PR_MTE_TCF_ASYNC`` - Asynchronous tag check fault mode

	The current tag check fault mode can be read using the
	``prctl(PR_GET_TAGGED_ADDR_CTRL, 0, 0, 0, 0)`` system call.

	Tag checking can also be disabled for a user thread by setting the
	``PSTATE.TCO`` bit with ``MSR TCO, #1``.

	Note: Signal handlers are always invoked with ``PSTATE.TCO = 0``,
	irrespective of the interrupted context. ``PSTATE.TCO`` is restored on
	``sigreturn()``.

	Note: There are no match-all logical tags available for user
	applications.

	Note: Kernel accesses to the user address space (e.g. ``read()``
	system call) are not checked if the user thread tag checking mode is
	``PR_MTE_TCF_NONE`` or ``PR_MTE_TCF_ASYNC``. If the tag checking mode is
	``PR_MTE_TCF_SYNC``, the kernel makes a best effort to check its user
	address accesses, however it cannot always guarantee it. Kernel accesses
	to user addresses are always performed with an effective ``PSTATE.TCO``
	value of zero, regardless of the user configuration.

	Excluding Tags in the ``IRG``, ``ADDG`` and ``SUBG`` instructions
	-----------------------------------------------------------------

	The architecture allows excluding certain tags to be randomly generated
	via the ``GCR_EL1.Exclude`` register bit-field. By default, Linux
	excludes all tags other than 0. A user thread can enable specific tags
	in the randomly generated set using the ``prctl(PR_SET_TAGGED_ADDR_CTRL,
	flags, 0, 0, 0)`` system call where ``flags`` contains the tags bitmap
	in the ``PR_MTE_TAG_MASK`` bit-field.

	Note: The hardware uses an exclude mask but the ``prctl()``
	interface provides an include mask. An include mask of ``0`` (exclusion
	mask ``0xffff``) results in the CPU always generating tag ``0``.

	Initial process state
	---------------------

	On ``execve()``, the new process has the following configuration:

	- ``PR_TAGGED_ADDR_ENABLE`` set to 0 (disabled)
	- Tag checking mode set to ``PR_MTE_TCF_NONE``
	- ``PR_MTE_TAG_MASK`` set to 0 (all tags excluded)
	- ``PSTATE.TCO`` set to 0
	- ``PROT_MTE`` not set on any of the initial memory maps

	On ``fork()``, the new process inherits the parent's configuration and
	memory map attributes with the exception of the ``madvise()`` ranges
	with ``MADV_WIPEONFORK`` which will have the data and tags cleared (set
	to 0).

	The ``ptrace()`` interface
	--------------------------

	``PTRACE_PEEKMTETAGS`` and ``PTRACE_POKEMTETAGS`` allow a tracer to read
	the tags from or set the tags to a tracee's address space. The
	``ptrace()`` system call is invoked as ``ptrace(request, pid, addr,
	data)`` where:

	- ``request`` - one of ``PTRACE_PEEKMTETAGS`` or ``PTRACE_POKEMTETAGS``.
	- ``pid`` - the tracee's PID.
	- ``addr`` - address in the tracee's address space.
	- ``data`` - pointer to a ``struct iovec`` where ``iov_base`` points to
	a buffer of ``iov_len`` length in the tracer's address space.

	The tags in the tracer's ``iov_base`` buffer are represented as one
	4-bit tag per byte and correspond to a 16-byte MTE tag granule in the
	tracee's address space.

	Note: If ``addr`` is not aligned to a 16-byte granule, the kernel
	will use the corresponding aligned address.

	``ptrace()`` return value:

	- 0 - tags were copied, the tracer's ``iov_len`` was updated to the
	number of tags transferred. This may be smaller than the requested
	``iov_len`` if the requested address range in the tracee's or the
	tracer's space cannot be accessed or does not have valid tags.
	- ``-EPERM`` - the specified process cannot be traced.
	- ``-EIO`` - the tracee's address range cannot be accessed (e.g. invalid
	address) and no tags copied. ``iov_len`` not updated.
	- ``-EFAULT`` - fault on accessing the tracer's memory (``struct iovec``
	or ``iov_base`` buffer) and no tags copied. ``iov_len`` not updated.
	- ``-EOPNOTSUPP`` - the tracee's address does not have valid tags (never
	mapped with the ``PROT_MTE`` flag). ``iov_len`` not updated.

	Note: There are no transient errors for the requests above, so user
	programs should not retry in case of a non-zero system call return.

	``PTRACE_GETREGSET`` and ``PTRACE_SETREGSET`` with ``addr ==
	``NT_ARM_TAGGED_ADDR_CTRL`` allow ``ptrace()`` access to the tagged
	address ABI control and MTE configuration of a process as per the
	``prctl()`` options described in
	Documentation/arm64/tagged-address-abi.rst and above. The corresponding
	``regset`` is 1 element of 8 bytes (``sizeof(long))``).

	Example of correct usage
	========================

	MTE Example code

	.. code-block:: c

	/*
	* To be compiled with -march=armv8.5-a+memtag
	*/
	#include <errno.h>
	#include <stdint.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <unistd.h>
	#include <sys/auxv.h>
	#include <sys/mman.h>
	#include <sys/prctl.h>

	/*
	* From arch/arm64/include/uapi/asm/hwcap.h
	*/
	#define HWCAP2_MTE (1 << 18)

	/*
	* From arch/arm64/include/uapi/asm/mman.h
	*/
	#define PROT_MTE 0x20

	/*
	* From include/uapi/linux/prctl.h
	*/
	#define PR_SET_TAGGED_ADDR_CTRL 55
	#define PR_GET_TAGGED_ADDR_CTRL 56
	# define PR_TAGGED_ADDR_ENABLE (1UL << 0)
	# define PR_MTE_TCF_SHIFT 1
	# define PR_MTE_TCF_NONE (0UL << PR_MTE_TCF_SHIFT)
	# define PR_MTE_TCF_SYNC (1UL << PR_MTE_TCF_SHIFT)
	# define PR_MTE_TCF_ASYNC (2UL << PR_MTE_TCF_SHIFT)
	# define PR_MTE_TCF_MASK (3UL << PR_MTE_TCF_SHIFT)
	# define PR_MTE_TAG_SHIFT 3
	# define PR_MTE_TAG_MASK (0xffffUL << PR_MTE_TAG_SHIFT)

	/*
	* Insert a random logical tag into the given pointer.
	*/
	#define insert_random_tag(ptr) ({ \
	uint64_t __val; \
	asm("irg %0, %1" : "=r" (__val) : "r" (ptr)); \
	__val; \
	})

	/*
	* Set the allocation tag on the destination address.
	*/
	#define set_tag(tagged_addr) do { \
	asm volatile("stg %0, [%0]" : : "r" (tagged_addr) : "memory"); \
	} while (0)

	int main()
	{
	unsigned char *a;
	unsigned long page_sz = sysconf(_SC_PAGESIZE);
	unsigned long hwcap2 = getauxval(AT_HWCAP2);

	/* check if MTE is present */
	if (!(hwcap2 & HWCAP2_MTE))
	return EXIT_FAILURE;

	/*
	* Enable the tagged address ABI, synchronous MTE tag check faults and
	* allow all non-zero tags in the randomly generated set.
	*/
	if (prctl(PR_SET_TAGGED_ADDR_CTRL,
	PR_TAGGED_ADDR_ENABLE \| PR_MTE_TCF_SYNC \| (0xfffe << PR_MTE_TAG_SHIFT),
	0, 0, 0)) {
	perror("prctl() failed");
	return EXIT_FAILURE;
	}

	a = mmap(0, page_sz, PROT_READ \| PROT_WRITE,
	MAP_PRIVATE \| MAP_ANONYMOUS, -1, 0);
	if (a == MAP_FAILED) {
	perror("mmap() failed");
	return EXIT_FAILURE;
	}

	/*
	* Enable MTE on the above anonymous mmap. The flag could be passed
	* directly to mmap() and skip this step.
	*/
	if (mprotect(a, page_sz, PROT_READ \| PROT_WRITE \| PROT_MTE)) {
	perror("mprotect() failed");
	return EXIT_FAILURE;
	}

	/* access with the default tag (0) */
	a[0] = 1;
	a[1] = 2;

	printf("a[0] = %hhu a[1] = %hhu\n", a[0], a[1]);

	/* set the logical and allocation tags */
	a = (unsigned char *)insert_random_tag(a);
	set_tag(a);

	printf("%p\n", a);

	/* non-zero tag access */
	a[0] = 3;
	printf("a[0] = %hhu a[1] = %hhu\n", a[0], a[1]);

	/*
	* If MTE is enabled correctly the next instruction will generate an
	* exception.
	*/
	printf("Expecting SIGSEGV...\n");
	a[16] = 0xdd;

	/* this should not be printed in the PR_MTE_TCF_SYNC mode */
	printf("...haven't got one\n");

	return EXIT_FAILURE;
	}