375 lines
16 KiB
ReStructuredText
375 lines
16 KiB
ReStructuredText
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.. SPDX-License-Identifier: GPL-2.0
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.. _deprecated:
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=====================================================================
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Deprecated Interfaces, Language Features, Attributes, and Conventions
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=====================================================================
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In a perfect world, it would be possible to convert all instances of
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some deprecated API into the new API and entirely remove the old API in
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a single development cycle. However, due to the size of the kernel, the
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maintainership hierarchy, and timing, it's not always feasible to do these
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kinds of conversions at once. This means that new instances may sneak into
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the kernel while old ones are being removed, only making the amount of
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work to remove the API grow. In order to educate developers about what
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has been deprecated and why, this list has been created as a place to
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point when uses of deprecated things are proposed for inclusion in the
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kernel.
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__deprecated
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------------
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While this attribute does visually mark an interface as deprecated,
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it `does not produce warnings during builds any more
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<https://git.kernel.org/linus/771c035372a036f83353eef46dbb829780330234>`_
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because one of the standing goals of the kernel is to build without
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warnings and no one was actually doing anything to remove these deprecated
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interfaces. While using `__deprecated` is nice to note an old API in
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a header file, it isn't the full solution. Such interfaces must either
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be fully removed from the kernel, or added to this file to discourage
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others from using them in the future.
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BUG() and BUG_ON()
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------------------
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Use WARN() and WARN_ON() instead, and handle the "impossible"
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error condition as gracefully as possible. While the BUG()-family
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of APIs were originally designed to act as an "impossible situation"
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assert and to kill a kernel thread "safely", they turn out to just be
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too risky. (e.g. "In what order do locks need to be released? Have
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various states been restored?") Very commonly, using BUG() will
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destabilize a system or entirely break it, which makes it impossible
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to debug or even get viable crash reports. Linus has `very strong
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<https://lore.kernel.org/lkml/CA+55aFy6jNLsywVYdGp83AMrXBo_P-pkjkphPGrO=82SPKCpLQ@mail.gmail.com/>`_
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feelings `about this
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<https://lore.kernel.org/lkml/CAHk-=whDHsbK3HTOpTF=ue_o04onRwTEaK_ZoJp_fjbqq4+=Jw@mail.gmail.com/>`_.
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Note that the WARN()-family should only be used for "expected to
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be unreachable" situations. If you want to warn about "reachable
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but undesirable" situations, please use the pr_warn()-family of
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functions. System owners may have set the *panic_on_warn* sysctl,
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to make sure their systems do not continue running in the face of
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"unreachable" conditions. (For example, see commits like `this one
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<https://git.kernel.org/linus/d4689846881d160a4d12a514e991a740bcb5d65a>`_.)
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open-coded arithmetic in allocator arguments
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--------------------------------------------
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Dynamic size calculations (especially multiplication) should not be
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performed in memory allocator (or similar) function arguments due to the
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risk of them overflowing. This could lead to values wrapping around and a
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smaller allocation being made than the caller was expecting. Using those
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allocations could lead to linear overflows of heap memory and other
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misbehaviors. (One exception to this is literal values where the compiler
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can warn if they might overflow. However, the preferred way in these
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cases is to refactor the code as suggested below to avoid the open-coded
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arithmetic.)
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For example, do not use ``count * size`` as an argument, as in::
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foo = kmalloc(count * size, GFP_KERNEL);
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Instead, the 2-factor form of the allocator should be used::
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foo = kmalloc_array(count, size, GFP_KERNEL);
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Specifically, kmalloc() can be replaced with kmalloc_array(), and
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kzalloc() can be replaced with kcalloc().
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If no 2-factor form is available, the saturate-on-overflow helpers should
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be used::
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bar = vmalloc(array_size(count, size));
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Another common case to avoid is calculating the size of a structure with
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a trailing array of others structures, as in::
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header = kzalloc(sizeof(*header) + count * sizeof(*header->item),
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GFP_KERNEL);
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Instead, use the helper::
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header = kzalloc(struct_size(header, item, count), GFP_KERNEL);
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.. note:: If you are using struct_size() on a structure containing a zero-length
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or a one-element array as a trailing array member, please refactor such
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array usage and switch to a `flexible array member
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<#zero-length-and-one-element-arrays>`_ instead.
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For other calculations, please compose the use of the size_mul(),
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size_add(), and size_sub() helpers. For example, in the case of::
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foo = krealloc(current_size + chunk_size * (count - 3), GFP_KERNEL);
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Instead, use the helpers::
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foo = krealloc(size_add(current_size,
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size_mul(chunk_size,
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size_sub(count, 3))), GFP_KERNEL);
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For more details, also see array3_size() and flex_array_size(),
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as well as the related check_mul_overflow(), check_add_overflow(),
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check_sub_overflow(), and check_shl_overflow() family of functions.
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simple_strtol(), simple_strtoll(), simple_strtoul(), simple_strtoull()
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----------------------------------------------------------------------
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The simple_strtol(), simple_strtoll(),
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simple_strtoul(), and simple_strtoull() functions
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explicitly ignore overflows, which may lead to unexpected results
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in callers. The respective kstrtol(), kstrtoll(),
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kstrtoul(), and kstrtoull() functions tend to be the
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correct replacements, though note that those require the string to be
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NUL or newline terminated.
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strcpy()
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--------
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strcpy() performs no bounds checking on the destination buffer. This
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could result in linear overflows beyond the end of the buffer, leading to
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all kinds of misbehaviors. While `CONFIG_FORTIFY_SOURCE=y` and various
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compiler flags help reduce the risk of using this function, there is
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no good reason to add new uses of this function. The safe replacement
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is strscpy(), though care must be given to any cases where the return
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value of strcpy() was used, since strscpy() does not return a pointer to
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the destination, but rather a count of non-NUL bytes copied (or negative
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errno when it truncates).
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strncpy() on NUL-terminated strings
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-----------------------------------
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Use of strncpy() does not guarantee that the destination buffer will
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be NUL terminated. This can lead to various linear read overflows and
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other misbehavior due to the missing termination. It also NUL-pads
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the destination buffer if the source contents are shorter than the
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destination buffer size, which may be a needless performance penalty
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for callers using only NUL-terminated strings.
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When the destination is required to be NUL-terminated, the replacement is
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strscpy(), though care must be given to any cases where the return value
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of strncpy() was used, since strscpy() does not return a pointer to the
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destination, but rather a count of non-NUL bytes copied (or negative
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errno when it truncates). Any cases still needing NUL-padding should
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instead use strscpy_pad().
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If a caller is using non-NUL-terminated strings, strtomem() should be
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used, and the destinations should be marked with the `__nonstring
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<https://gcc.gnu.org/onlinedocs/gcc/Common-Variable-Attributes.html>`_
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attribute to avoid future compiler warnings. For cases still needing
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NUL-padding, strtomem_pad() can be used.
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strlcpy()
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---------
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strlcpy() reads the entire source buffer first (since the return value
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is meant to match that of strlen()). This read may exceed the destination
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size limit. This is both inefficient and can lead to linear read overflows
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if a source string is not NUL-terminated. The safe replacement is strscpy(),
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though care must be given to any cases where the return value of strlcpy()
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is used, since strscpy() will return negative errno values when it truncates.
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%p format specifier
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-------------------
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Traditionally, using "%p" in format strings would lead to regular address
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exposure flaws in dmesg, proc, sysfs, etc. Instead of leaving these to
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be exploitable, all "%p" uses in the kernel are being printed as a hashed
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value, rendering them unusable for addressing. New uses of "%p" should not
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be added to the kernel. For text addresses, using "%pS" is likely better,
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as it produces the more useful symbol name instead. For nearly everything
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else, just do not add "%p" at all.
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Paraphrasing Linus's current `guidance <https://lore.kernel.org/lkml/CA+55aFwQEd_d40g4mUCSsVRZzrFPUJt74vc6PPpb675hYNXcKw@mail.gmail.com/>`_:
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- If the hashed "%p" value is pointless, ask yourself whether the pointer
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itself is important. Maybe it should be removed entirely?
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- If you really think the true pointer value is important, why is some
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system state or user privilege level considered "special"? If you think
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you can justify it (in comments and commit log) well enough to stand
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up to Linus's scrutiny, maybe you can use "%px", along with making sure
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you have sensible permissions.
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If you are debugging something where "%p" hashing is causing problems,
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you can temporarily boot with the debug flag "`no_hash_pointers
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<https://git.kernel.org/linus/5ead723a20e0447bc7db33dc3070b420e5f80aa6>`_".
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Variable Length Arrays (VLAs)
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-----------------------------
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Using stack VLAs produces much worse machine code than statically
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sized stack arrays. While these non-trivial `performance issues
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<https://git.kernel.org/linus/02361bc77888>`_ are reason enough to
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eliminate VLAs, they are also a security risk. Dynamic growth of a stack
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array may exceed the remaining memory in the stack segment. This could
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lead to a crash, possible overwriting sensitive contents at the end of the
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stack (when built without `CONFIG_THREAD_INFO_IN_TASK=y`), or overwriting
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memory adjacent to the stack (when built without `CONFIG_VMAP_STACK=y`)
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Implicit switch case fall-through
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---------------------------------
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The C language allows switch cases to fall through to the next case
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when a "break" statement is missing at the end of a case. This, however,
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introduces ambiguity in the code, as it's not always clear if the missing
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break is intentional or a bug. For example, it's not obvious just from
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looking at the code if `STATE_ONE` is intentionally designed to fall
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through into `STATE_TWO`::
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switch (value) {
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case STATE_ONE:
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do_something();
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case STATE_TWO:
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do_other();
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break;
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default:
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WARN("unknown state");
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}
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As there have been a long list of flaws `due to missing "break" statements
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<https://cwe.mitre.org/data/definitions/484.html>`_, we no longer allow
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implicit fall-through. In order to identify intentional fall-through
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cases, we have adopted a pseudo-keyword macro "fallthrough" which
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expands to gcc's extension `__attribute__((__fallthrough__))
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<https://gcc.gnu.org/onlinedocs/gcc/Statement-Attributes.html>`_.
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(When the C17/C18 `[[fallthrough]]` syntax is more commonly supported by
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C compilers, static analyzers, and IDEs, we can switch to using that syntax
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for the macro pseudo-keyword.)
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All switch/case blocks must end in one of:
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* break;
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* fallthrough;
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* continue;
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* goto <label>;
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* return [expression];
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Zero-length and one-element arrays
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----------------------------------
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There is a regular need in the kernel to provide a way to declare having
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a dynamically sized set of trailing elements in a structure. Kernel code
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should always use `"flexible array members" <https://en.wikipedia.org/wiki/Flexible_array_member>`_
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for these cases. The older style of one-element or zero-length arrays should
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no longer be used.
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In older C code, dynamically sized trailing elements were done by specifying
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a one-element array at the end of a structure::
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struct something {
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size_t count;
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struct foo items[1];
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};
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This led to fragile size calculations via sizeof() (which would need to
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remove the size of the single trailing element to get a correct size of
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the "header"). A `GNU C extension <https://gcc.gnu.org/onlinedocs/gcc/Zero-Length.html>`_
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was introduced to allow for zero-length arrays, to avoid these kinds of
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size problems::
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struct something {
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size_t count;
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struct foo items[0];
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};
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But this led to other problems, and didn't solve some problems shared by
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both styles, like not being able to detect when such an array is accidentally
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being used _not_ at the end of a structure (which could happen directly, or
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when such a struct was in unions, structs of structs, etc).
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C99 introduced "flexible array members", which lacks a numeric size for
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the array declaration entirely::
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struct something {
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size_t count;
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struct foo items[];
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};
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This is the way the kernel expects dynamically sized trailing elements
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to be declared. It allows the compiler to generate errors when the
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flexible array does not occur last in the structure, which helps to prevent
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some kind of `undefined behavior
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<https://git.kernel.org/linus/76497732932f15e7323dc805e8ea8dc11bb587cf>`_
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bugs from being inadvertently introduced to the codebase. It also allows
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the compiler to correctly analyze array sizes (via sizeof(),
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`CONFIG_FORTIFY_SOURCE`, and `CONFIG_UBSAN_BOUNDS`). For instance,
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there is no mechanism that warns us that the following application of the
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sizeof() operator to a zero-length array always results in zero::
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struct something {
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size_t count;
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struct foo items[0];
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};
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struct something *instance;
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instance = kmalloc(struct_size(instance, items, count), GFP_KERNEL);
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instance->count = count;
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size = sizeof(instance->items) * instance->count;
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memcpy(instance->items, source, size);
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At the last line of code above, ``size`` turns out to be ``zero``, when one might
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have thought it represents the total size in bytes of the dynamic memory recently
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allocated for the trailing array ``items``. Here are a couple examples of this
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issue: `link 1
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<https://git.kernel.org/linus/f2cd32a443da694ac4e28fbf4ac6f9d5cc63a539>`_,
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`link 2
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<https://git.kernel.org/linus/ab91c2a89f86be2898cee208d492816ec238b2cf>`_.
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Instead, `flexible array members have incomplete type, and so the sizeof()
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operator may not be applied <https://gcc.gnu.org/onlinedocs/gcc/Zero-Length.html>`_,
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so any misuse of such operators will be immediately noticed at build time.
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With respect to one-element arrays, one has to be acutely aware that `such arrays
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occupy at least as much space as a single object of the type
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<https://gcc.gnu.org/onlinedocs/gcc/Zero-Length.html>`_,
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hence they contribute to the size of the enclosing structure. This is prone
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to error every time people want to calculate the total size of dynamic memory
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to allocate for a structure containing an array of this kind as a member::
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struct something {
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size_t count;
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struct foo items[1];
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};
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struct something *instance;
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instance = kmalloc(struct_size(instance, items, count - 1), GFP_KERNEL);
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instance->count = count;
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size = sizeof(instance->items) * instance->count;
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memcpy(instance->items, source, size);
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In the example above, we had to remember to calculate ``count - 1`` when using
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the struct_size() helper, otherwise we would have --unintentionally-- allocated
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memory for one too many ``items`` objects. The cleanest and least error-prone way
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to implement this is through the use of a `flexible array member`, together with
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struct_size() and flex_array_size() helpers::
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|
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struct something {
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size_t count;
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struct foo items[];
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};
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struct something *instance;
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instance = kmalloc(struct_size(instance, items, count), GFP_KERNEL);
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instance->count = count;
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memcpy(instance->items, source, flex_array_size(instance, items, instance->count));
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There are two special cases of replacement where the DECLARE_FLEX_ARRAY()
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|
helper needs to be used. (Note that it is named __DECLARE_FLEX_ARRAY() for
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use in UAPI headers.) Those cases are when the flexible array is either
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alone in a struct or is part of a union. These are disallowed by the C99
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specification, but for no technical reason (as can be seen by both the
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existing use of such arrays in those places and the work-around that
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DECLARE_FLEX_ARRAY() uses). For example, to convert this::
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struct something {
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...
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union {
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struct type1 one[0];
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struct type2 two[0];
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};
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};
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The helper must be used::
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struct something {
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...
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union {
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DECLARE_FLEX_ARRAY(struct type1, one);
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DECLARE_FLEX_ARRAY(struct type2, two);
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};
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};
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