Hi Jeff,

Sorry for the delay. Thanks for your v2 updates.

On 9/30/24 5:26 PM, jeffxu@chromium.org wrote:

From: Jeff Xu jeffxu@chromium.org

Update doc after in-loop change: mprotect/madvise can have partially updated and munmap is atomic.

Fix indentation and clarify some sections to improve readability.

Signed-off-by: Jeff Xu jeffxu@chromium.org Fixes: df2a7df9a9aa ("mm/munmap: replace can_modify_mm with can_modify_vma") Fixes: 4a2dd02b0916 ("mm/mprotect: replace can_modify_mm with can_modify_vma") Fixes: 38075679b5f1 ("mm/mremap: replace can_modify_mm with can_modify_vma") Fixes: 23c57d1fa2b9 ("mseal: replace can_modify_mm_madv with a vma variant")

---

Documentation/userspace-api/mseal.rst | 304 ++++++++++++-------------- 1 file changed, 144 insertions(+), 160 deletions(-)

diff --git a/Documentation/userspace-api/mseal.rst b/Documentation/userspace-api/mseal.rst index 4132eec995a3..04d34b5adb8f 100644 --- a/Documentation/userspace-api/mseal.rst +++ b/Documentation/userspace-api/mseal.rst @@ -23,177 +23,161 @@ applications can additionally seal security critical data at runtime. A similar feature already exists in the XNU kernel with the VM_FLAGS_PERMANENT flag [1] and on OpenBSD with the mimmutable syscall [2].

-User API

-mseal()

-The mseal() syscall has the following signature:

-``int mseal(void addr, size_t len, unsigned long flags)``

-**addr/len**: virtual memory address range.

-The address range set by ``addr``/``len`` must meet:

• • The start address must be in an allocated VMA.
• • The start address must be page aligned.
• • The end address (``addr`` + ``len``) must be in an allocated VMA.
• • no gap (unallocated memory) between start and end address.

-The ``len`` will be paged aligned implicitly by the kernel.

-**flags**: reserved for future use.

-**return values**:

-- ``0``: Success.

-- ``-EINVAL``:

• • Invalid input ``flags``.
• • The start address (``addr``) is not page aligned.
• • Address range (``addr`` + ``len``) overflow.

-- ``-ENOMEM``:

• • The start address (``addr``) is not allocated.
• • The end address (``addr`` + ``len``) is not allocated.
• • A gap (unallocated memory) between start and end address.

-- ``-EPERM``:

• • sealing is supported only on 64-bit CPUs, 32-bit is not supported.

-- For above error cases, users can expect the given memory range is

• unmodified, i.e. no partial update.

-- There might be other internal errors/cases not listed here, e.g.

• error during merging/splitting VMAs, or the process reaching the max
• number of supported VMAs. In those cases, partial updates to the given
• memory range could happen. However, those cases should be rare.

-**Blocked operations after sealing**:

• Unmapping, moving to another location, and shrinking the size,
• via munmap() and mremap(), can leave an empty space, therefore
• can be replaced with a VMA with a new set of attributes.
• Moving or expanding a different VMA into the current location,
• via mremap().
• Modifying a VMA via mmap(MAP_FIXED).
• Size expansion, via mremap(), does not appear to pose any
• specific risks to sealed VMAs. It is included anyway because
• the use case is unclear. In any case, users can rely on
• merging to expand a sealed VMA.
• mprotect() and pkey_mprotect().
• Some destructive madvice() behaviors (e.g. MADV_DONTNEED)
• for anonymous memory, when users don't have write permission to the
• memory. Those behaviors can alter region contents by discarding pages,
• effectively a memset(0) for anonymous memory.
• Kernel will return -EPERM for blocked operations.
• For blocked operations, one can expect the given address is unmodified,
• i.e. no partial update. Note, this is different from existing mm
• system call behaviors, where partial updates are made till an error is
• found and returned to userspace. To give an example:
• Assume following code sequence:
• • ptr = mmap(null, 8192, PROT_NONE);
• • munmap(ptr + 4096, 4096);
• • ret1 = mprotect(ptr, 8192, PROT_READ);
• • mseal(ptr, 4096);
• • ret2 = mprotect(ptr, 8192, PROT_NONE);
• ret1 will be -ENOMEM, the page from ptr is updated to PROT_READ.
• ret2 will be -EPERM, the page remains to be PROT_READ.

-**Note**:

-- mseal() only works on 64-bit CPUs, not 32-bit CPU.

-- users can call mseal() multiple times, mseal() on an already sealed memory

• is a no-action (not error).

-- munseal() is not supported.

-Use cases:

+SYSCALL +======= +mseal syscall signature +-----------------------

• ``int mseal(void * addr, size_t len, unsigned long flags)``
• **addr**/**len**: virtual memory address range.

•  The address range set by **addr**/**len** must meet:
  

•     - The start address must be in an allocated VMA.
  

•     - The start address must be page aligned.
  

•     - The end address (**addr** + **len**) must be in an allocated VMA.
  

•     - no gap (unallocated memory) between start and end address.
  

•  The ``len`` will be paged aligned implicitly by the kernel.
  

• **flags**: reserved for future use.
• **Return values**:

•  - **0**: Success.
  

•  - **-EINVAL**:
  

•     * Invalid input ``flags``.
  

•     * The start address (``addr``) is not page aligned.
  

•     * Address range (``addr`` + ``len``) overflow.
  

•  - **-ENOMEM**:
  

•     * The start address (``addr``) is not allocated.
  

•     * The end address (``addr`` + ``len``) is not allocated.
  

•     * A gap (unallocated memory) between start and end address.
  

•  - **-EPERM**:
  

•     * sealing is supported only on 64-bit CPUs, 32-bit is not supported.
  

• **Note about error return**:

•  - For above error cases, users can expect the given memory range is
  

•    unmodified, i.e. no partial update.
  

•  - There might be other internal errors/cases not listed here, e.g.
  

•    error during merging/splitting VMAs, or the process reaching the max
  

maximum

•    number of supported VMAs. In those cases, partial updates to the given
  

•    memory range could happen. However, those cases should be rare.
  

• **Architecture support**:

•  mseal only works on 64-bit CPUs, not 32-bit CPUs.
  

• **Idempotent**:

•  users can call mseal multiple times. mseal on an already sealed memory
  

•  is a no-action (not error).
  

• **no munseal**

•  Once mapping is sealed, it can't be unsealed. kernel should never
  

The kernel

•  have munseal, this is consistent with other sealing feature, e.g.
  

•  F_SEAL_SEAL for file.
  

+Blocked mm syscall for sealed mapping +-------------------------------------

• It might be important to note: **once the mapping is sealed, it will
• stay in the process's memory until the process terminates**.
• Example::

•     *ptr = mmap(0, 4096, PROT_READ, MAP_ANONYMOUS | MAP_PRIVATE, 0, 0);
  

•     rc = mseal(ptr, 4096, 0);
  

•     /* munmap will fail */
  

•     rc = munmap(ptr, 4096);
  

•     assert(rc < 0);
  

• Blocked mm syscall:

•  - munmap
  

•  - mmap
  

•  - mremap
  

•  - mprotect and pkey_mprotect
  

•  - some destructive madvise behaviors: MADV_DONTNEED, MADV_FREE,
  

•    MADV_DONTNEED_LOCKED, MADV_FREE, MADV_DONTFORK, MADV_WIPEONFORK
  

• The first set of syscall to block is munmap, mremap, mmap. They can

syscalls

• either leave an empty space in the address space, therefore allow

allowing

• replacement with a new mapping with new set of attributes, or can
• overwrite the existing mapping with another mapping.
• mprotect and pkey_mprotect are blocked because they changes the
• protection bits (RWX) of the mapping.
• Some destructive madvise behaviors (MADV_DONTNEED, MADV_FREE,> + MADV_DONTNEED_LOCKED, MADV_FREE, MADV_DONTFORK, MADV_WIPEONFORK)
• for anonymous memory, when users don't have write permission to the
• memory. Those behaviors can alter region contents by discarding pages,

above is not a sentence but I don't know how to fix it.

• effectively a memset(0) for anonymous memory.
• Kernel will return -EPERM for blocked syscalls.
• When blocked syscall return -EPERM due to sealing, the memory regions may or may not be changed, depends on the syscall being blocked:

a blocked syscall returns depending on

and split that line into 2 lines.

•  - munmap: munmap is atomic. If one of VMAs in the given range is
  

•    sealed, none of VMAs are updated.
  

•  - mprotect, pkey_mprotect, madvise: partial update might happen, e.g.
  

•    when mprotect over multiple VMAs, mprotect might update the beginning
  

•    VMAs before reaching the sealed VMA and return -EPERM.
  

•  - mmap and mremap: undefined behavior.
  

+Use cases +=========

• glibc: The dynamic linker, during loading ELF executables, can apply sealing to
• non-writable memory segments.

-- Chrome browser: protect some security sensitive data-structures.

• mapping segments.

-Notes on which memory to seal:

+- Chrome browser: protect some security sensitive data structures. -It might be important to note that sealing changes the lifetime of a mapping, -i.e. the sealed mapping won’t be unmapped till the process terminates or the -exec system call is invoked. Applications can apply sealing to any virtual -memory region from userspace, but it is crucial to thoroughly analyze the -mapping's lifetime prior to apply the sealing. +When not to use mseal +===================== +Applications can apply sealing to any virtual memory region from userspace, +but it is *crucial to thoroughly analyze the mapping's lifetime* prior to +apply the sealing. This is because the sealed mapping *won’t be unmapped* +until the process terminates or the exec system call is invoked. For example:

• • aio/shm

• aio/shm can call mmap and  munmap on behalf of userspace, e.g.
  

• ksys_shmdt() in shm.c. The lifetimes of those mapping are not tied to
  

• the lifetime of the process. If those memories are sealed from userspace,
  

• then munmap will fail, causing leaks in VMA address space during the
  

• lifetime of the process.
  

• • ptr allocated by malloc (heap)

• Don't use mseal on the memory ptr return from malloc().
  

• malloc() is implemented by allocator, e.g. by glibc. Heap manager might
  

• allocate a ptr from brk or mapping created by mmap.
  

• If an app calls mseal on a ptr returned from malloc(), this can affect
  

• the heap manager's ability to manage the mappings; the outcome is
  

• non-deterministic.
  

• Example::
  

•    ptr = malloc(size);
  

•    /* don't call mseal on ptr return from malloc. */
  

•    mseal(ptr, size);
  

•    /* free will success, allocator can't shrink heap lower than ptr */
  

•    free(ptr);
  

+mseal doesn't block +=================== +In a nutshell, mseal blocks certain mm syscall from modifying some of VMA's +attributes, such as protection bits (RWX). Sealed mappings doesn't mean the +memory is immutable. -- aio/shm

• aio/shm can call mmap()/munmap() on behalf of userspace, e.g. ksys_shmdt() in
• shm.c. The lifetime of those mapping are not tied to the lifetime of the
• process. If those memories are sealed from userspace, then munmap() will fail,
• causing leaks in VMA address space during the lifetime of the process.

-- Brk (heap)

• Currently, userspace applications can seal parts of the heap by calling
• malloc() and mseal().
• let's assume following calls from user space:
• • ptr = malloc(size);
• • mprotect(ptr, size, RO);
• • mseal(ptr, size);
• • free(ptr);
• Technically, before mseal() is added, the user can change the protection of
• the heap by calling mprotect(RO). As long as the user changes the protection
• back to RW before free(), the memory range can be reused.
• Adding mseal() into the picture, however, the heap is then sealed partially,
• the user can still free it, but the memory remains to be RO. If the address
• is re-used by the heap manager for another malloc, the process might crash
• soon after. Therefore, it is important not to apply sealing to any memory
• that might get recycled.
• Furthermore, even if the application never calls the free() for the ptr,
• the heap manager may invoke the brk system call to shrink the size of the
• heap. In the kernel, the brk-shrink will call munmap(). Consequently,
• depending on the location of the ptr, the outcome of brk-shrink is
• nondeterministic.

-Additional notes:

As Jann Horn pointed out in [3], there are still a few ways to write -to RO memory, which is, in a way, by design. Those cases are not covered -by mseal(). If applications want to block such cases, sandbox tools (such as -seccomp, LSM, etc) might be considered. +to RO memory, which is, in a way, by design. And those could be blocked +by different security measures. Those cases are:

-- Write to read-only memory through /proc/self/mem interface. -- Write to read-only memory through ptrace (such as PTRACE_POKETEXT). -- userfaultfd.

• • Write to read-only memory through /proc/self/mem interface (FOLL_FORCE).
• • Write to read-only memory through ptrace (such as PTRACE_POKETEXT).
• • userfaultfd.

The idea that inspired this patch comes from Stephen Röttger’s work in V8 CFI [4]. Chrome browser in ChromeOS will be the first user of this API.

-Reference:

-[1] https://github.com/apple-oss-distributions/xnu/blob/1031c584a5e37aff177559b9...

-[2] https://man.openbsd.org/mimmutable.2

-[3] https://lore.kernel.org/lkml/CAG48ez3ShUYey+ZAFsU2i1RpQn0a5eOs2hzQ426FkcgnfU...

-[4] https://docs.google.com/document/d/1O2jwK4dxI3nRcOJuPYkonhTkNQfbmwdvxQMyXgea... +Reference +========= +- [1] https://github.com/apple-oss-distributions/xnu/blob/1031c584a5e37aff177559b9... +- [2] https://man.openbsd.org/mimmutable.2 +- [3] https://lore.kernel.org/lkml/CAG48ez3ShUYey+ZAFsU2i1RpQn0a5eOs2hzQ426FkcgnfU... +- [4] https://docs.google.com/document/d/1O2jwK4dxI3nRcOJuPYkonhTkNQfbmwdvxQMyXgea...

With those few changes:

Reviewed-by: Randy Dunlap rdunlap@infradead.org