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so it will be consistent with code mm directory and with Documentation/admin-guide/mm and won't be confused with virtual machines. Signed-off-by: Mike Rapoport <rppt@linux.ibm.com> Suggested-by: Matthew Wilcox <willy@infradead.org> Tested-by: Ira Weiny <ira.weiny@intel.com> Acked-by: Jonathan Corbet <corbet@lwn.net> Acked-by: Wu XiangCheng <bobwxc@email.cn>
154 lines
5.6 KiB
ReStructuredText
154 lines
5.6 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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=====================================
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Virtually Mapped Kernel Stack Support
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=====================================
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:Author: Shuah Khan <skhan@linuxfoundation.org>
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.. contents:: :local:
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Overview
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--------
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This is a compilation of information from the code and original patch
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series that introduced the `Virtually Mapped Kernel Stacks feature
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<https://lwn.net/Articles/694348/>`
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Introduction
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------------
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Kernel stack overflows are often hard to debug and make the kernel
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susceptible to exploits. Problems could show up at a later time making
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it difficult to isolate and root-cause.
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Virtually-mapped kernel stacks with guard pages causes kernel stack
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overflows to be caught immediately rather than causing difficult to
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diagnose corruptions.
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HAVE_ARCH_VMAP_STACK and VMAP_STACK configuration options enable
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support for virtually mapped stacks with guard pages. This feature
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causes reliable faults when the stack overflows. The usability of
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the stack trace after overflow and response to the overflow itself
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is architecture dependent.
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.. note::
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As of this writing, arm64, powerpc, riscv, s390, um, and x86 have
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support for VMAP_STACK.
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HAVE_ARCH_VMAP_STACK
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--------------------
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Architectures that can support Virtually Mapped Kernel Stacks should
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enable this bool configuration option. The requirements are:
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- vmalloc space must be large enough to hold many kernel stacks. This
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may rule out many 32-bit architectures.
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- Stacks in vmalloc space need to work reliably. For example, if
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vmap page tables are created on demand, either this mechanism
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needs to work while the stack points to a virtual address with
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unpopulated page tables or arch code (switch_to() and switch_mm(),
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most likely) needs to ensure that the stack's page table entries
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are populated before running on a possibly unpopulated stack.
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- If the stack overflows into a guard page, something reasonable
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should happen. The definition of "reasonable" is flexible, but
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instantly rebooting without logging anything would be unfriendly.
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VMAP_STACK
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----------
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VMAP_STACK bool configuration option when enabled allocates virtually
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mapped task stacks. This option depends on HAVE_ARCH_VMAP_STACK.
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- Enable this if you want the use virtually-mapped kernel stacks
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with guard pages. This causes kernel stack overflows to be caught
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immediately rather than causing difficult-to-diagnose corruption.
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.. note::
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Using this feature with KASAN requires architecture support
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for backing virtual mappings with real shadow memory, and
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KASAN_VMALLOC must be enabled.
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.. note::
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VMAP_STACK is enabled, it is not possible to run DMA on stack
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allocated data.
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Kernel configuration options and dependencies keep changing. Refer to
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the latest code base:
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`Kconfig <https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/arch/Kconfig>`
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Allocation
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-----------
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When a new kernel thread is created, thread stack is allocated from
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virtually contiguous memory pages from the page level allocator. These
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pages are mapped into contiguous kernel virtual space with PAGE_KERNEL
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protections.
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alloc_thread_stack_node() calls __vmalloc_node_range() to allocate stack
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with PAGE_KERNEL protections.
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- Allocated stacks are cached and later reused by new threads, so memcg
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accounting is performed manually on assigning/releasing stacks to tasks.
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Hence, __vmalloc_node_range is called without __GFP_ACCOUNT.
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- vm_struct is cached to be able to find when thread free is initiated
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in interrupt context. free_thread_stack() can be called in interrupt
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context.
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- On arm64, all VMAP's stacks need to have the same alignment to ensure
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that VMAP'd stack overflow detection works correctly. Arch specific
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vmap stack allocator takes care of this detail.
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- This does not address interrupt stacks - according to the original patch
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Thread stack allocation is initiated from clone(), fork(), vfork(),
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kernel_thread() via kernel_clone(). Leaving a few hints for searching
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the code base to understand when and how thread stack is allocated.
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Bulk of the code is in:
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`kernel/fork.c <https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/kernel/fork.c>`.
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stack_vm_area pointer in task_struct keeps track of the virtually allocated
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stack and a non-null stack_vm_area pointer serves as a indication that the
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virtually mapped kernel stacks are enabled.
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::
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struct vm_struct *stack_vm_area;
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Stack overflow handling
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-----------------------
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Leading and trailing guard pages help detect stack overflows. When stack
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overflows into the guard pages, handlers have to be careful not overflow
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the stack again. When handlers are called, it is likely that very little
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stack space is left.
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On x86, this is done by handling the page fault indicating the kernel
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stack overflow on the double-fault stack.
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Testing VMAP allocation with guard pages
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----------------------------------------
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How do we ensure that VMAP_STACK is actually allocating with a leading
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and trailing guard page? The following lkdtm tests can help detect any
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regressions.
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::
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void lkdtm_STACK_GUARD_PAGE_LEADING()
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void lkdtm_STACK_GUARD_PAGE_TRAILING()
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Conclusions
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-----------
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- A percpu cache of vmalloced stacks appears to be a bit faster than a
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high-order stack allocation, at least when the cache hits.
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- THREAD_INFO_IN_TASK gets rid of arch-specific thread_info entirely and
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simply embed the thread_info (containing only flags) and 'int cpu' into
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task_struct.
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- The thread stack can be free'ed as soon as the task is dead (without
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waiting for RCU) and then, if vmapped stacks are in use, cache the
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entire stack for reuse on the same cpu.
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