mirror of
https://mirrors.bfsu.edu.cn/git/linux.git
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fbc5669de6
The BTF_TYPE_SAFE_NESTED macro was replaced by the BTF_TYPE_SAFE_TRUSTED,
BTF_TYPE_SAFE_RCU, and BTF_TYPE_SAFE_RCU_OR_NULL macros. Fix the docs
correspondingly.
Fixes: 6fcd486b3a
("bpf: Refactor RCU enforcement in the verifier.")
Signed-off-by: Anton Protopopov <aspsk@isovalent.com>
Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
Acked-by: Yonghong Song <yhs@fb.com>
Link: https://lore.kernel.org/bpf/20230622095424.1024244-1-aspsk@isovalent.com
657 lines
24 KiB
ReStructuredText
657 lines
24 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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.. _kfuncs-header-label:
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=============================
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BPF Kernel Functions (kfuncs)
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=============================
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1. Introduction
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===============
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BPF Kernel Functions or more commonly known as kfuncs are functions in the Linux
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kernel which are exposed for use by BPF programs. Unlike normal BPF helpers,
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kfuncs do not have a stable interface and can change from one kernel release to
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another. Hence, BPF programs need to be updated in response to changes in the
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kernel. See :ref:`BPF_kfunc_lifecycle_expectations` for more information.
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2. Defining a kfunc
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===================
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There are two ways to expose a kernel function to BPF programs, either make an
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existing function in the kernel visible, or add a new wrapper for BPF. In both
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cases, care must be taken that BPF program can only call such function in a
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valid context. To enforce this, visibility of a kfunc can be per program type.
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If you are not creating a BPF wrapper for existing kernel function, skip ahead
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to :ref:`BPF_kfunc_nodef`.
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2.1 Creating a wrapper kfunc
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----------------------------
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When defining a wrapper kfunc, the wrapper function should have extern linkage.
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This prevents the compiler from optimizing away dead code, as this wrapper kfunc
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is not invoked anywhere in the kernel itself. It is not necessary to provide a
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prototype in a header for the wrapper kfunc.
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An example is given below::
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/* Disables missing prototype warnings */
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__diag_push();
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__diag_ignore_all("-Wmissing-prototypes",
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"Global kfuncs as their definitions will be in BTF");
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__bpf_kfunc struct task_struct *bpf_find_get_task_by_vpid(pid_t nr)
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{
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return find_get_task_by_vpid(nr);
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}
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__diag_pop();
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A wrapper kfunc is often needed when we need to annotate parameters of the
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kfunc. Otherwise one may directly make the kfunc visible to the BPF program by
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registering it with the BPF subsystem. See :ref:`BPF_kfunc_nodef`.
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2.2 Annotating kfunc parameters
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-------------------------------
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Similar to BPF helpers, there is sometime need for additional context required
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by the verifier to make the usage of kernel functions safer and more useful.
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Hence, we can annotate a parameter by suffixing the name of the argument of the
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kfunc with a __tag, where tag may be one of the supported annotations.
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2.2.1 __sz Annotation
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---------------------
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This annotation is used to indicate a memory and size pair in the argument list.
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An example is given below::
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__bpf_kfunc void bpf_memzero(void *mem, int mem__sz)
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{
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...
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}
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Here, the verifier will treat first argument as a PTR_TO_MEM, and second
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argument as its size. By default, without __sz annotation, the size of the type
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of the pointer is used. Without __sz annotation, a kfunc cannot accept a void
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pointer.
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2.2.2 __k Annotation
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--------------------
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This annotation is only understood for scalar arguments, where it indicates that
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the verifier must check the scalar argument to be a known constant, which does
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not indicate a size parameter, and the value of the constant is relevant to the
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safety of the program.
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An example is given below::
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__bpf_kfunc void *bpf_obj_new(u32 local_type_id__k, ...)
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{
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...
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}
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Here, bpf_obj_new uses local_type_id argument to find out the size of that type
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ID in program's BTF and return a sized pointer to it. Each type ID will have a
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distinct size, hence it is crucial to treat each such call as distinct when
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values don't match during verifier state pruning checks.
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Hence, whenever a constant scalar argument is accepted by a kfunc which is not a
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size parameter, and the value of the constant matters for program safety, __k
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suffix should be used.
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2.2.3 __uninit Annotation
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-------------------------
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This annotation is used to indicate that the argument will be treated as
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uninitialized.
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An example is given below::
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__bpf_kfunc int bpf_dynptr_from_skb(..., struct bpf_dynptr_kern *ptr__uninit)
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{
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...
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}
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Here, the dynptr will be treated as an uninitialized dynptr. Without this
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annotation, the verifier will reject the program if the dynptr passed in is
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not initialized.
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2.2.4 __opt Annotation
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-------------------------
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This annotation is used to indicate that the buffer associated with an __sz or __szk
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argument may be null. If the function is passed a nullptr in place of the buffer,
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the verifier will not check that length is appropriate for the buffer. The kfunc is
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responsible for checking if this buffer is null before using it.
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An example is given below::
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__bpf_kfunc void *bpf_dynptr_slice(..., void *buffer__opt, u32 buffer__szk)
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{
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...
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}
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Here, the buffer may be null. If buffer is not null, it at least of size buffer_szk.
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Either way, the returned buffer is either NULL, or of size buffer_szk. Without this
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annotation, the verifier will reject the program if a null pointer is passed in with
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a nonzero size.
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.. _BPF_kfunc_nodef:
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2.3 Using an existing kernel function
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-------------------------------------
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When an existing function in the kernel is fit for consumption by BPF programs,
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it can be directly registered with the BPF subsystem. However, care must still
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be taken to review the context in which it will be invoked by the BPF program
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and whether it is safe to do so.
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2.4 Annotating kfuncs
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---------------------
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In addition to kfuncs' arguments, verifier may need more information about the
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type of kfunc(s) being registered with the BPF subsystem. To do so, we define
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flags on a set of kfuncs as follows::
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BTF_SET8_START(bpf_task_set)
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BTF_ID_FLAGS(func, bpf_get_task_pid, KF_ACQUIRE | KF_RET_NULL)
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BTF_ID_FLAGS(func, bpf_put_pid, KF_RELEASE)
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BTF_SET8_END(bpf_task_set)
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This set encodes the BTF ID of each kfunc listed above, and encodes the flags
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along with it. Ofcourse, it is also allowed to specify no flags.
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kfunc definitions should also always be annotated with the ``__bpf_kfunc``
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macro. This prevents issues such as the compiler inlining the kfunc if it's a
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static kernel function, or the function being elided in an LTO build as it's
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not used in the rest of the kernel. Developers should not manually add
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annotations to their kfunc to prevent these issues. If an annotation is
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required to prevent such an issue with your kfunc, it is a bug and should be
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added to the definition of the macro so that other kfuncs are similarly
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protected. An example is given below::
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__bpf_kfunc struct task_struct *bpf_get_task_pid(s32 pid)
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{
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...
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}
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2.4.1 KF_ACQUIRE flag
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---------------------
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The KF_ACQUIRE flag is used to indicate that the kfunc returns a pointer to a
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refcounted object. The verifier will then ensure that the pointer to the object
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is eventually released using a release kfunc, or transferred to a map using a
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referenced kptr (by invoking bpf_kptr_xchg). If not, the verifier fails the
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loading of the BPF program until no lingering references remain in all possible
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explored states of the program.
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2.4.2 KF_RET_NULL flag
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----------------------
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The KF_RET_NULL flag is used to indicate that the pointer returned by the kfunc
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may be NULL. Hence, it forces the user to do a NULL check on the pointer
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returned from the kfunc before making use of it (dereferencing or passing to
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another helper). This flag is often used in pairing with KF_ACQUIRE flag, but
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both are orthogonal to each other.
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2.4.3 KF_RELEASE flag
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---------------------
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The KF_RELEASE flag is used to indicate that the kfunc releases the pointer
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passed in to it. There can be only one referenced pointer that can be passed
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in. All copies of the pointer being released are invalidated as a result of
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invoking kfunc with this flag. KF_RELEASE kfuncs automatically receive the
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protection afforded by the KF_TRUSTED_ARGS flag described below.
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2.4.4 KF_TRUSTED_ARGS flag
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--------------------------
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The KF_TRUSTED_ARGS flag is used for kfuncs taking pointer arguments. It
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indicates that the all pointer arguments are valid, and that all pointers to
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BTF objects have been passed in their unmodified form (that is, at a zero
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offset, and without having been obtained from walking another pointer, with one
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exception described below).
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There are two types of pointers to kernel objects which are considered "valid":
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1. Pointers which are passed as tracepoint or struct_ops callback arguments.
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2. Pointers which were returned from a KF_ACQUIRE kfunc.
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Pointers to non-BTF objects (e.g. scalar pointers) may also be passed to
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KF_TRUSTED_ARGS kfuncs, and may have a non-zero offset.
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The definition of "valid" pointers is subject to change at any time, and has
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absolutely no ABI stability guarantees.
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As mentioned above, a nested pointer obtained from walking a trusted pointer is
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no longer trusted, with one exception. If a struct type has a field that is
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guaranteed to be valid (trusted or rcu, as in KF_RCU description below) as long
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as its parent pointer is valid, the following macros can be used to express
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that to the verifier:
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* ``BTF_TYPE_SAFE_TRUSTED``
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* ``BTF_TYPE_SAFE_RCU``
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* ``BTF_TYPE_SAFE_RCU_OR_NULL``
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For example,
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.. code-block:: c
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BTF_TYPE_SAFE_TRUSTED(struct socket) {
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struct sock *sk;
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};
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or
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.. code-block:: c
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BTF_TYPE_SAFE_RCU(struct task_struct) {
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const cpumask_t *cpus_ptr;
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struct css_set __rcu *cgroups;
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struct task_struct __rcu *real_parent;
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struct task_struct *group_leader;
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};
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In other words, you must:
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1. Wrap the valid pointer type in a ``BTF_TYPE_SAFE_*`` macro.
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2. Specify the type and name of the valid nested field. This field must match
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the field in the original type definition exactly.
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A new type declared by a ``BTF_TYPE_SAFE_*`` macro also needs to be emitted so
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that it appears in BTF. For example, ``BTF_TYPE_SAFE_TRUSTED(struct socket)``
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is emitted in the ``type_is_trusted()`` function as follows:
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.. code-block:: c
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BTF_TYPE_EMIT(BTF_TYPE_SAFE_TRUSTED(struct socket));
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2.4.5 KF_SLEEPABLE flag
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-----------------------
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The KF_SLEEPABLE flag is used for kfuncs that may sleep. Such kfuncs can only
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be called by sleepable BPF programs (BPF_F_SLEEPABLE).
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2.4.6 KF_DESTRUCTIVE flag
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--------------------------
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The KF_DESTRUCTIVE flag is used to indicate functions calling which is
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destructive to the system. For example such a call can result in system
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rebooting or panicking. Due to this additional restrictions apply to these
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calls. At the moment they only require CAP_SYS_BOOT capability, but more can be
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added later.
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2.4.7 KF_RCU flag
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-----------------
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The KF_RCU flag is a weaker version of KF_TRUSTED_ARGS. The kfuncs marked with
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KF_RCU expect either PTR_TRUSTED or MEM_RCU arguments. The verifier guarantees
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that the objects are valid and there is no use-after-free. The pointers are not
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NULL, but the object's refcount could have reached zero. The kfuncs need to
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consider doing refcnt != 0 check, especially when returning a KF_ACQUIRE
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pointer. Note as well that a KF_ACQUIRE kfunc that is KF_RCU should very likely
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also be KF_RET_NULL.
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.. _KF_deprecated_flag:
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2.4.8 KF_DEPRECATED flag
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------------------------
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The KF_DEPRECATED flag is used for kfuncs which are scheduled to be
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changed or removed in a subsequent kernel release. A kfunc that is
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marked with KF_DEPRECATED should also have any relevant information
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captured in its kernel doc. Such information typically includes the
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kfunc's expected remaining lifespan, a recommendation for new
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functionality that can replace it if any is available, and possibly a
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rationale for why it is being removed.
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Note that while on some occasions, a KF_DEPRECATED kfunc may continue to be
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supported and have its KF_DEPRECATED flag removed, it is likely to be far more
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difficult to remove a KF_DEPRECATED flag after it's been added than it is to
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prevent it from being added in the first place. As described in
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:ref:`BPF_kfunc_lifecycle_expectations`, users that rely on specific kfuncs are
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encouraged to make their use-cases known as early as possible, and participate
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in upstream discussions regarding whether to keep, change, deprecate, or remove
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those kfuncs if and when such discussions occur.
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2.5 Registering the kfuncs
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--------------------------
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Once the kfunc is prepared for use, the final step to making it visible is
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registering it with the BPF subsystem. Registration is done per BPF program
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type. An example is shown below::
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BTF_SET8_START(bpf_task_set)
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BTF_ID_FLAGS(func, bpf_get_task_pid, KF_ACQUIRE | KF_RET_NULL)
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BTF_ID_FLAGS(func, bpf_put_pid, KF_RELEASE)
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BTF_SET8_END(bpf_task_set)
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static const struct btf_kfunc_id_set bpf_task_kfunc_set = {
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.owner = THIS_MODULE,
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.set = &bpf_task_set,
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};
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static int init_subsystem(void)
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{
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return register_btf_kfunc_id_set(BPF_PROG_TYPE_TRACING, &bpf_task_kfunc_set);
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}
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late_initcall(init_subsystem);
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2.6 Specifying no-cast aliases with ___init
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--------------------------------------------
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The verifier will always enforce that the BTF type of a pointer passed to a
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kfunc by a BPF program, matches the type of pointer specified in the kfunc
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definition. The verifier, does, however, allow types that are equivalent
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according to the C standard to be passed to the same kfunc arg, even if their
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BTF_IDs differ.
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For example, for the following type definition:
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.. code-block:: c
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struct bpf_cpumask {
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cpumask_t cpumask;
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refcount_t usage;
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};
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The verifier would allow a ``struct bpf_cpumask *`` to be passed to a kfunc
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taking a ``cpumask_t *`` (which is a typedef of ``struct cpumask *``). For
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instance, both ``struct cpumask *`` and ``struct bpf_cpmuask *`` can be passed
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to bpf_cpumask_test_cpu().
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In some cases, this type-aliasing behavior is not desired. ``struct
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nf_conn___init`` is one such example:
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.. code-block:: c
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struct nf_conn___init {
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struct nf_conn ct;
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};
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The C standard would consider these types to be equivalent, but it would not
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always be safe to pass either type to a trusted kfunc. ``struct
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nf_conn___init`` represents an allocated ``struct nf_conn`` object that has
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*not yet been initialized*, so it would therefore be unsafe to pass a ``struct
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nf_conn___init *`` to a kfunc that's expecting a fully initialized ``struct
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nf_conn *`` (e.g. ``bpf_ct_change_timeout()``).
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In order to accommodate such requirements, the verifier will enforce strict
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PTR_TO_BTF_ID type matching if two types have the exact same name, with one
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being suffixed with ``___init``.
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.. _BPF_kfunc_lifecycle_expectations:
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3. kfunc lifecycle expectations
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===============================
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kfuncs provide a kernel <-> kernel API, and thus are not bound by any of the
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strict stability restrictions associated with kernel <-> user UAPIs. This means
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they can be thought of as similar to EXPORT_SYMBOL_GPL, and can therefore be
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modified or removed by a maintainer of the subsystem they're defined in when
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it's deemed necessary.
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Like any other change to the kernel, maintainers will not change or remove a
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kfunc without having a reasonable justification. Whether or not they'll choose
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to change a kfunc will ultimately depend on a variety of factors, such as how
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widely used the kfunc is, how long the kfunc has been in the kernel, whether an
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alternative kfunc exists, what the norm is in terms of stability for the
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subsystem in question, and of course what the technical cost is of continuing
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to support the kfunc.
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There are several implications of this:
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a) kfuncs that are widely used or have been in the kernel for a long time will
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be more difficult to justify being changed or removed by a maintainer. In
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other words, kfuncs that are known to have a lot of users and provide
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significant value provide stronger incentives for maintainers to invest the
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time and complexity in supporting them. It is therefore important for
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developers that are using kfuncs in their BPF programs to communicate and
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explain how and why those kfuncs are being used, and to participate in
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discussions regarding those kfuncs when they occur upstream.
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b) Unlike regular kernel symbols marked with EXPORT_SYMBOL_GPL, BPF programs
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that call kfuncs are generally not part of the kernel tree. This means that
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refactoring cannot typically change callers in-place when a kfunc changes,
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as is done for e.g. an upstreamed driver being updated in place when a
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kernel symbol is changed.
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Unlike with regular kernel symbols, this is expected behavior for BPF
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symbols, and out-of-tree BPF programs that use kfuncs should be considered
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relevant to discussions and decisions around modifying and removing those
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kfuncs. The BPF community will take an active role in participating in
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upstream discussions when necessary to ensure that the perspectives of such
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users are taken into account.
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c) A kfunc will never have any hard stability guarantees. BPF APIs cannot and
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will not ever hard-block a change in the kernel purely for stability
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reasons. That being said, kfuncs are features that are meant to solve
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problems and provide value to users. The decision of whether to change or
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remove a kfunc is a multivariate technical decision that is made on a
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case-by-case basis, and which is informed by data points such as those
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mentioned above. It is expected that a kfunc being removed or changed with
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no warning will not be a common occurrence or take place without sound
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justification, but it is a possibility that must be accepted if one is to
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use kfuncs.
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3.1 kfunc deprecation
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---------------------
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As described above, while sometimes a maintainer may find that a kfunc must be
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changed or removed immediately to accommodate some changes in their subsystem,
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usually kfuncs will be able to accommodate a longer and more measured
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deprecation process. For example, if a new kfunc comes along which provides
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superior functionality to an existing kfunc, the existing kfunc may be
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deprecated for some period of time to allow users to migrate their BPF programs
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to use the new one. Or, if a kfunc has no known users, a decision may be made
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to remove the kfunc (without providing an alternative API) after some
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deprecation period so as to provide users with a window to notify the kfunc
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maintainer if it turns out that the kfunc is actually being used.
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It's expected that the common case will be that kfuncs will go through a
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deprecation period rather than being changed or removed without warning. As
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described in :ref:`KF_deprecated_flag`, the kfunc framework provides the
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KF_DEPRECATED flag to kfunc developers to signal to users that a kfunc has been
|
|
deprecated. Once a kfunc has been marked with KF_DEPRECATED, the following
|
|
procedure is followed for removal:
|
|
|
|
1. Any relevant information for deprecated kfuncs is documented in the kfunc's
|
|
kernel docs. This documentation will typically include the kfunc's expected
|
|
remaining lifespan, a recommendation for new functionality that can replace
|
|
the usage of the deprecated function (or an explanation as to why no such
|
|
replacement exists), etc.
|
|
|
|
2. The deprecated kfunc is kept in the kernel for some period of time after it
|
|
was first marked as deprecated. This time period will be chosen on a
|
|
case-by-case basis, and will typically depend on how widespread the use of
|
|
the kfunc is, how long it has been in the kernel, and how hard it is to move
|
|
to alternatives. This deprecation time period is "best effort", and as
|
|
described :ref:`above<BPF_kfunc_lifecycle_expectations>`, circumstances may
|
|
sometimes dictate that the kfunc be removed before the full intended
|
|
deprecation period has elapsed.
|
|
|
|
3. After the deprecation period the kfunc will be removed. At this point, BPF
|
|
programs calling the kfunc will be rejected by the verifier.
|
|
|
|
4. Core kfuncs
|
|
==============
|
|
|
|
The BPF subsystem provides a number of "core" kfuncs that are potentially
|
|
applicable to a wide variety of different possible use cases and programs.
|
|
Those kfuncs are documented here.
|
|
|
|
4.1 struct task_struct * kfuncs
|
|
-------------------------------
|
|
|
|
There are a number of kfuncs that allow ``struct task_struct *`` objects to be
|
|
used as kptrs:
|
|
|
|
.. kernel-doc:: kernel/bpf/helpers.c
|
|
:identifiers: bpf_task_acquire bpf_task_release
|
|
|
|
These kfuncs are useful when you want to acquire or release a reference to a
|
|
``struct task_struct *`` that was passed as e.g. a tracepoint arg, or a
|
|
struct_ops callback arg. For example:
|
|
|
|
.. code-block:: c
|
|
|
|
/**
|
|
* A trivial example tracepoint program that shows how to
|
|
* acquire and release a struct task_struct * pointer.
|
|
*/
|
|
SEC("tp_btf/task_newtask")
|
|
int BPF_PROG(task_acquire_release_example, struct task_struct *task, u64 clone_flags)
|
|
{
|
|
struct task_struct *acquired;
|
|
|
|
acquired = bpf_task_acquire(task);
|
|
if (acquired)
|
|
/*
|
|
* In a typical program you'd do something like store
|
|
* the task in a map, and the map will automatically
|
|
* release it later. Here, we release it manually.
|
|
*/
|
|
bpf_task_release(acquired);
|
|
return 0;
|
|
}
|
|
|
|
|
|
References acquired on ``struct task_struct *`` objects are RCU protected.
|
|
Therefore, when in an RCU read region, you can obtain a pointer to a task
|
|
embedded in a map value without having to acquire a reference:
|
|
|
|
.. code-block:: c
|
|
|
|
#define private(name) SEC(".data." #name) __hidden __attribute__((aligned(8)))
|
|
private(TASK) static struct task_struct *global;
|
|
|
|
/**
|
|
* A trivial example showing how to access a task stored
|
|
* in a map using RCU.
|
|
*/
|
|
SEC("tp_btf/task_newtask")
|
|
int BPF_PROG(task_rcu_read_example, struct task_struct *task, u64 clone_flags)
|
|
{
|
|
struct task_struct *local_copy;
|
|
|
|
bpf_rcu_read_lock();
|
|
local_copy = global;
|
|
if (local_copy)
|
|
/*
|
|
* We could also pass local_copy to kfuncs or helper functions here,
|
|
* as we're guaranteed that local_copy will be valid until we exit
|
|
* the RCU read region below.
|
|
*/
|
|
bpf_printk("Global task %s is valid", local_copy->comm);
|
|
else
|
|
bpf_printk("No global task found");
|
|
bpf_rcu_read_unlock();
|
|
|
|
/* At this point we can no longer reference local_copy. */
|
|
|
|
return 0;
|
|
}
|
|
|
|
----
|
|
|
|
A BPF program can also look up a task from a pid. This can be useful if the
|
|
caller doesn't have a trusted pointer to a ``struct task_struct *`` object that
|
|
it can acquire a reference on with bpf_task_acquire().
|
|
|
|
.. kernel-doc:: kernel/bpf/helpers.c
|
|
:identifiers: bpf_task_from_pid
|
|
|
|
Here is an example of it being used:
|
|
|
|
.. code-block:: c
|
|
|
|
SEC("tp_btf/task_newtask")
|
|
int BPF_PROG(task_get_pid_example, struct task_struct *task, u64 clone_flags)
|
|
{
|
|
struct task_struct *lookup;
|
|
|
|
lookup = bpf_task_from_pid(task->pid);
|
|
if (!lookup)
|
|
/* A task should always be found, as %task is a tracepoint arg. */
|
|
return -ENOENT;
|
|
|
|
if (lookup->pid != task->pid) {
|
|
/* bpf_task_from_pid() looks up the task via its
|
|
* globally-unique pid from the init_pid_ns. Thus,
|
|
* the pid of the lookup task should always be the
|
|
* same as the input task.
|
|
*/
|
|
bpf_task_release(lookup);
|
|
return -EINVAL;
|
|
}
|
|
|
|
/* bpf_task_from_pid() returns an acquired reference,
|
|
* so it must be dropped before returning from the
|
|
* tracepoint handler.
|
|
*/
|
|
bpf_task_release(lookup);
|
|
return 0;
|
|
}
|
|
|
|
4.2 struct cgroup * kfuncs
|
|
--------------------------
|
|
|
|
``struct cgroup *`` objects also have acquire and release functions:
|
|
|
|
.. kernel-doc:: kernel/bpf/helpers.c
|
|
:identifiers: bpf_cgroup_acquire bpf_cgroup_release
|
|
|
|
These kfuncs are used in exactly the same manner as bpf_task_acquire() and
|
|
bpf_task_release() respectively, so we won't provide examples for them.
|
|
|
|
----
|
|
|
|
Other kfuncs available for interacting with ``struct cgroup *`` objects are
|
|
bpf_cgroup_ancestor() and bpf_cgroup_from_id(), allowing callers to access
|
|
the ancestor of a cgroup and find a cgroup by its ID, respectively. Both
|
|
return a cgroup kptr.
|
|
|
|
.. kernel-doc:: kernel/bpf/helpers.c
|
|
:identifiers: bpf_cgroup_ancestor
|
|
|
|
.. kernel-doc:: kernel/bpf/helpers.c
|
|
:identifiers: bpf_cgroup_from_id
|
|
|
|
Eventually, BPF should be updated to allow this to happen with a normal memory
|
|
load in the program itself. This is currently not possible without more work in
|
|
the verifier. bpf_cgroup_ancestor() can be used as follows:
|
|
|
|
.. code-block:: c
|
|
|
|
/**
|
|
* Simple tracepoint example that illustrates how a cgroup's
|
|
* ancestor can be accessed using bpf_cgroup_ancestor().
|
|
*/
|
|
SEC("tp_btf/cgroup_mkdir")
|
|
int BPF_PROG(cgrp_ancestor_example, struct cgroup *cgrp, const char *path)
|
|
{
|
|
struct cgroup *parent;
|
|
|
|
/* The parent cgroup resides at the level before the current cgroup's level. */
|
|
parent = bpf_cgroup_ancestor(cgrp, cgrp->level - 1);
|
|
if (!parent)
|
|
return -ENOENT;
|
|
|
|
bpf_printk("Parent id is %d", parent->self.id);
|
|
|
|
/* Return the parent cgroup that was acquired above. */
|
|
bpf_cgroup_release(parent);
|
|
return 0;
|
|
}
|
|
|
|
4.3 struct cpumask * kfuncs
|
|
---------------------------
|
|
|
|
BPF provides a set of kfuncs that can be used to query, allocate, mutate, and
|
|
destroy struct cpumask * objects. Please refer to :ref:`cpumasks-header-label`
|
|
for more details.
|