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428 lines
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ReStructuredText
428 lines
16 KiB
ReStructuredText
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.. SPDX-License-Identifier: GPL-2.0
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.. Copyright (C) 2022, Google LLC.
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===================================
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The Kernel Memory Sanitizer (KMSAN)
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===================================
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KMSAN is a dynamic error detector aimed at finding uses of uninitialized
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values. It is based on compiler instrumentation, and is quite similar to the
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userspace `MemorySanitizer tool`_.
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An important note is that KMSAN is not intended for production use, because it
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drastically increases kernel memory footprint and slows the whole system down.
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Usage
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=====
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Building the kernel
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-------------------
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In order to build a kernel with KMSAN you will need a fresh Clang (14.0.6+).
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Please refer to `LLVM documentation`_ for the instructions on how to build Clang.
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Now configure and build the kernel with CONFIG_KMSAN enabled.
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Example report
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--------------
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Here is an example of a KMSAN report::
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=====================================================
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BUG: KMSAN: uninit-value in test_uninit_kmsan_check_memory+0x1be/0x380 [kmsan_test]
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test_uninit_kmsan_check_memory+0x1be/0x380 mm/kmsan/kmsan_test.c:273
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kunit_run_case_internal lib/kunit/test.c:333
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kunit_try_run_case+0x206/0x420 lib/kunit/test.c:374
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kunit_generic_run_threadfn_adapter+0x6d/0xc0 lib/kunit/try-catch.c:28
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kthread+0x721/0x850 kernel/kthread.c:327
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ret_from_fork+0x1f/0x30 ??:?
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Uninit was stored to memory at:
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do_uninit_local_array+0xfa/0x110 mm/kmsan/kmsan_test.c:260
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test_uninit_kmsan_check_memory+0x1a2/0x380 mm/kmsan/kmsan_test.c:271
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kunit_run_case_internal lib/kunit/test.c:333
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kunit_try_run_case+0x206/0x420 lib/kunit/test.c:374
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kunit_generic_run_threadfn_adapter+0x6d/0xc0 lib/kunit/try-catch.c:28
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kthread+0x721/0x850 kernel/kthread.c:327
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ret_from_fork+0x1f/0x30 ??:?
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Local variable uninit created at:
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do_uninit_local_array+0x4a/0x110 mm/kmsan/kmsan_test.c:256
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test_uninit_kmsan_check_memory+0x1a2/0x380 mm/kmsan/kmsan_test.c:271
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Bytes 4-7 of 8 are uninitialized
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Memory access of size 8 starts at ffff888083fe3da0
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CPU: 0 PID: 6731 Comm: kunit_try_catch Tainted: G B E 5.16.0-rc3+ #104
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Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
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=====================================================
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The report says that the local variable ``uninit`` was created uninitialized in
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``do_uninit_local_array()``. The third stack trace corresponds to the place
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where this variable was created.
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The first stack trace shows where the uninit value was used (in
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``test_uninit_kmsan_check_memory()``). The tool shows the bytes which were left
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uninitialized in the local variable, as well as the stack where the value was
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copied to another memory location before use.
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A use of uninitialized value ``v`` is reported by KMSAN in the following cases:
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- in a condition, e.g. ``if (v) { ... }``;
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- in an indexing or pointer dereferencing, e.g. ``array[v]`` or ``*v``;
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- when it is copied to userspace or hardware, e.g. ``copy_to_user(..., &v, ...)``;
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- when it is passed as an argument to a function, and
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``CONFIG_KMSAN_CHECK_PARAM_RETVAL`` is enabled (see below).
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The mentioned cases (apart from copying data to userspace or hardware, which is
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a security issue) are considered undefined behavior from the C11 Standard point
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of view.
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Disabling the instrumentation
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-----------------------------
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A function can be marked with ``__no_kmsan_checks``. Doing so makes KMSAN
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ignore uninitialized values in that function and mark its output as initialized.
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As a result, the user will not get KMSAN reports related to that function.
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Another function attribute supported by KMSAN is ``__no_sanitize_memory``.
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Applying this attribute to a function will result in KMSAN not instrumenting
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it, which can be helpful if we do not want the compiler to interfere with some
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low-level code (e.g. that marked with ``noinstr`` which implicitly adds
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``__no_sanitize_memory``).
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This however comes at a cost: stack allocations from such functions will have
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incorrect shadow/origin values, likely leading to false positives. Functions
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called from non-instrumented code may also receive incorrect metadata for their
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parameters.
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As a rule of thumb, avoid using ``__no_sanitize_memory`` explicitly.
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It is also possible to disable KMSAN for a single file (e.g. main.o)::
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KMSAN_SANITIZE_main.o := n
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or for the whole directory::
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KMSAN_SANITIZE := n
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in the Makefile. Think of this as applying ``__no_sanitize_memory`` to every
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function in the file or directory. Most users won't need KMSAN_SANITIZE, unless
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their code gets broken by KMSAN (e.g. runs at early boot time).
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Support
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=======
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In order for KMSAN to work the kernel must be built with Clang, which so far is
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the only compiler that has KMSAN support. The kernel instrumentation pass is
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based on the userspace `MemorySanitizer tool`_.
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The runtime library only supports x86_64 at the moment.
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How KMSAN works
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===============
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KMSAN shadow memory
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-------------------
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KMSAN associates a metadata byte (also called shadow byte) with every byte of
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kernel memory. A bit in the shadow byte is set iff the corresponding bit of the
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kernel memory byte is uninitialized. Marking the memory uninitialized (i.e.
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setting its shadow bytes to ``0xff``) is called poisoning, marking it
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initialized (setting the shadow bytes to ``0x00``) is called unpoisoning.
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When a new variable is allocated on the stack, it is poisoned by default by
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instrumentation code inserted by the compiler (unless it is a stack variable
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that is immediately initialized). Any new heap allocation done without
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``__GFP_ZERO`` is also poisoned.
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Compiler instrumentation also tracks the shadow values as they are used along
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the code. When needed, instrumentation code invokes the runtime library in
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``mm/kmsan/`` to persist shadow values.
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The shadow value of a basic or compound type is an array of bytes of the same
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length. When a constant value is written into memory, that memory is unpoisoned.
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When a value is read from memory, its shadow memory is also obtained and
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propagated into all the operations which use that value. For every instruction
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that takes one or more values the compiler generates code that calculates the
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shadow of the result depending on those values and their shadows.
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Example::
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int a = 0xff; // i.e. 0x000000ff
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int b;
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int c = a | b;
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In this case the shadow of ``a`` is ``0``, shadow of ``b`` is ``0xffffffff``,
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shadow of ``c`` is ``0xffffff00``. This means that the upper three bytes of
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``c`` are uninitialized, while the lower byte is initialized.
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Origin tracking
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---------------
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Every four bytes of kernel memory also have a so-called origin mapped to them.
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This origin describes the point in program execution at which the uninitialized
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value was created. Every origin is associated with either the full allocation
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stack (for heap-allocated memory), or the function containing the uninitialized
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variable (for locals).
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When an uninitialized variable is allocated on stack or heap, a new origin
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value is created, and that variable's origin is filled with that value. When a
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value is read from memory, its origin is also read and kept together with the
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shadow. For every instruction that takes one or more values, the origin of the
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result is one of the origins corresponding to any of the uninitialized inputs.
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If a poisoned value is written into memory, its origin is written to the
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corresponding storage as well.
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Example 1::
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int a = 42;
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int b;
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int c = a + b;
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In this case the origin of ``b`` is generated upon function entry, and is
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stored to the origin of ``c`` right before the addition result is written into
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memory.
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Several variables may share the same origin address, if they are stored in the
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same four-byte chunk. In this case every write to either variable updates the
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origin for all of them. We have to sacrifice precision in this case, because
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storing origins for individual bits (and even bytes) would be too costly.
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Example 2::
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int combine(short a, short b) {
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union ret_t {
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int i;
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short s[2];
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} ret;
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ret.s[0] = a;
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ret.s[1] = b;
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return ret.i;
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}
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If ``a`` is initialized and ``b`` is not, the shadow of the result would be
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0xffff0000, and the origin of the result would be the origin of ``b``.
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``ret.s[0]`` would have the same origin, but it will never be used, because
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that variable is initialized.
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If both function arguments are uninitialized, only the origin of the second
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argument is preserved.
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Origin chaining
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~~~~~~~~~~~~~~~
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To ease debugging, KMSAN creates a new origin for every store of an
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uninitialized value to memory. The new origin references both its creation stack
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and the previous origin the value had. This may cause increased memory
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consumption, so we limit the length of origin chains in the runtime.
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Clang instrumentation API
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-------------------------
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Clang instrumentation pass inserts calls to functions defined in
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``mm/kmsan/nstrumentation.c`` into the kernel code.
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Shadow manipulation
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~~~~~~~~~~~~~~~~~~~
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For every memory access the compiler emits a call to a function that returns a
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pair of pointers to the shadow and origin addresses of the given memory::
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typedef struct {
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void *shadow, *origin;
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} shadow_origin_ptr_t
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shadow_origin_ptr_t __msan_metadata_ptr_for_load_{1,2,4,8}(void *addr)
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shadow_origin_ptr_t __msan_metadata_ptr_for_store_{1,2,4,8}(void *addr)
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shadow_origin_ptr_t __msan_metadata_ptr_for_load_n(void *addr, uintptr_t size)
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shadow_origin_ptr_t __msan_metadata_ptr_for_store_n(void *addr, uintptr_t size)
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The function name depends on the memory access size.
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The compiler makes sure that for every loaded value its shadow and origin
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values are read from memory. When a value is stored to memory, its shadow and
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origin are also stored using the metadata pointers.
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Handling locals
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~~~~~~~~~~~~~~~
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A special function is used to create a new origin value for a local variable and
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set the origin of that variable to that value::
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void __msan_poison_alloca(void *addr, uintptr_t size, char *descr)
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Access to per-task data
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~~~~~~~~~~~~~~~~~~~~~~~
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At the beginning of every instrumented function KMSAN inserts a call to
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``__msan_get_context_state()``::
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kmsan_context_state *__msan_get_context_state(void)
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``kmsan_context_state`` is declared in ``include/linux/kmsan.h``::
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struct kmsan_context_state {
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char param_tls[KMSAN_PARAM_SIZE];
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char retval_tls[KMSAN_RETVAL_SIZE];
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char va_arg_tls[KMSAN_PARAM_SIZE];
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char va_arg_origin_tls[KMSAN_PARAM_SIZE];
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u64 va_arg_overflow_size_tls;
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char param_origin_tls[KMSAN_PARAM_SIZE];
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depot_stack_handle_t retval_origin_tls;
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};
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This structure is used by KMSAN to pass parameter shadows and origins between
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instrumented functions (unless the parameters are checked immediately by
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``CONFIG_KMSAN_CHECK_PARAM_RETVAL``).
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Passing uninitialized values to functions
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Clang's MemorySanitizer instrumentation has an option,
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``-fsanitize-memory-param-retval``, which makes the compiler check function
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parameters passed by value, as well as function return values.
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The option is controlled by ``CONFIG_KMSAN_CHECK_PARAM_RETVAL``, which is
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enabled by default to let KMSAN report uninitialized values earlier.
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Please refer to the `LKML discussion`_ for more details.
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Because of the way the checks are implemented in LLVM (they are only applied to
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parameters marked as ``noundef``), not all parameters are guaranteed to be
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checked, so we cannot give up the metadata storage in ``kmsan_context_state``.
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String functions
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~~~~~~~~~~~~~~~~
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The compiler replaces calls to ``memcpy()``/``memmove()``/``memset()`` with the
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following functions. These functions are also called when data structures are
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initialized or copied, making sure shadow and origin values are copied alongside
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with the data::
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void *__msan_memcpy(void *dst, void *src, uintptr_t n)
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void *__msan_memmove(void *dst, void *src, uintptr_t n)
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void *__msan_memset(void *dst, int c, uintptr_t n)
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Error reporting
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~~~~~~~~~~~~~~~
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For each use of a value the compiler emits a shadow check that calls
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``__msan_warning()`` in the case that value is poisoned::
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void __msan_warning(u32 origin)
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``__msan_warning()`` causes KMSAN runtime to print an error report.
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Inline assembly instrumentation
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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KMSAN instruments every inline assembly output with a call to::
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void __msan_instrument_asm_store(void *addr, uintptr_t size)
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, which unpoisons the memory region.
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This approach may mask certain errors, but it also helps to avoid a lot of
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false positives in bitwise operations, atomics etc.
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Sometimes the pointers passed into inline assembly do not point to valid memory.
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In such cases they are ignored at runtime.
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Runtime library
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---------------
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The code is located in ``mm/kmsan/``.
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Per-task KMSAN state
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~~~~~~~~~~~~~~~~~~~~
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Every task_struct has an associated KMSAN task state that holds the KMSAN
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context (see above) and a per-task flag disallowing KMSAN reports::
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struct kmsan_context {
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...
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bool allow_reporting;
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struct kmsan_context_state cstate;
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...
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}
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struct task_struct {
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...
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struct kmsan_context kmsan;
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...
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}
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KMSAN contexts
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~~~~~~~~~~~~~~
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When running in a kernel task context, KMSAN uses ``current->kmsan.cstate`` to
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hold the metadata for function parameters and return values.
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But in the case the kernel is running in the interrupt, softirq or NMI context,
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where ``current`` is unavailable, KMSAN switches to per-cpu interrupt state::
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DEFINE_PER_CPU(struct kmsan_ctx, kmsan_percpu_ctx);
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Metadata allocation
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~~~~~~~~~~~~~~~~~~~
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There are several places in the kernel for which the metadata is stored.
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1. Each ``struct page`` instance contains two pointers to its shadow and
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origin pages::
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struct page {
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...
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struct page *shadow, *origin;
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...
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};
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At boot-time, the kernel allocates shadow and origin pages for every available
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kernel page. This is done quite late, when the kernel address space is already
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fragmented, so normal data pages may arbitrarily interleave with the metadata
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pages.
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This means that in general for two contiguous memory pages their shadow/origin
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pages may not be contiguous. Consequently, if a memory access crosses the
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boundary of a memory block, accesses to shadow/origin memory may potentially
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corrupt other pages or read incorrect values from them.
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In practice, contiguous memory pages returned by the same ``alloc_pages()``
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call will have contiguous metadata, whereas if these pages belong to two
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different allocations their metadata pages can be fragmented.
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For the kernel data (``.data``, ``.bss`` etc.) and percpu memory regions
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there also are no guarantees on metadata contiguity.
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In the case ``__msan_metadata_ptr_for_XXX_YYY()`` hits the border between two
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pages with non-contiguous metadata, it returns pointers to fake shadow/origin regions::
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char dummy_load_page[PAGE_SIZE] __attribute__((aligned(PAGE_SIZE)));
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char dummy_store_page[PAGE_SIZE] __attribute__((aligned(PAGE_SIZE)));
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``dummy_load_page`` is zero-initialized, so reads from it always yield zeroes.
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All stores to ``dummy_store_page`` are ignored.
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2. For vmalloc memory and modules, there is a direct mapping between the memory
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range, its shadow and origin. KMSAN reduces the vmalloc area by 3/4, making only
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the first quarter available to ``vmalloc()``. The second quarter of the vmalloc
|
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|
area contains shadow memory for the first quarter, the third one holds the
|
||
|
origins. A small part of the fourth quarter contains shadow and origins for the
|
||
|
kernel modules. Please refer to ``arch/x86/include/asm/pgtable_64_types.h`` for
|
||
|
more details.
|
||
|
|
||
|
When an array of pages is mapped into a contiguous virtual memory space, their
|
||
|
shadow and origin pages are similarly mapped into contiguous regions.
|
||
|
|
||
|
References
|
||
|
==========
|
||
|
|
||
|
E. Stepanov, K. Serebryany. `MemorySanitizer: fast detector of uninitialized
|
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|
memory use in C++
|
||
|
<https://static.googleusercontent.com/media/research.google.com/en//pubs/archive/43308.pdf>`_.
|
||
|
In Proceedings of CGO 2015.
|
||
|
|
||
|
.. _MemorySanitizer tool: https://clang.llvm.org/docs/MemorySanitizer.html
|
||
|
.. _LLVM documentation: https://llvm.org/docs/GettingStarted.html
|
||
|
.. _LKML discussion: https://lore.kernel.org/all/20220614144853.3693273-1-glider@google.com/
|