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Linux/Documentation/bpf/libbpf/libbpf_overview.rst

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Differences between /Documentation/bpf/libbpf/libbpf_overview.rst (Architecture mips) and /Documentation/bpf/libbpf/libbpf_overview.rst (Architecture i386)


  1 .. SPDX-License-Identifier: GPL-2.0                 1 .. SPDX-License-Identifier: GPL-2.0
  2                                                     2 
  3 ===============                                     3 ===============
  4 libbpf Overview                                     4 libbpf Overview
  5 ===============                                     5 ===============
  6                                                     6 
  7 libbpf is a C-based library containing a BPF l      7 libbpf is a C-based library containing a BPF loader that takes compiled BPF
  8 object files and prepares and loads them into       8 object files and prepares and loads them into the Linux kernel. libbpf takes the
  9 heavy lifting of loading, verifying, and attac      9 heavy lifting of loading, verifying, and attaching BPF programs to various
 10 kernel hooks, allowing BPF application develop     10 kernel hooks, allowing BPF application developers to focus only on BPF program
 11 correctness and performance.                       11 correctness and performance.
 12                                                    12 
 13 The following are the high-level features supp     13 The following are the high-level features supported by libbpf:
 14                                                    14 
 15 * Provides high-level and low-level APIs for u     15 * Provides high-level and low-level APIs for user space programs to interact
 16   with BPF programs. The low-level APIs wrap a     16   with BPF programs. The low-level APIs wrap all the bpf system call
 17   functionality, which is useful when users ne     17   functionality, which is useful when users need more fine-grained control
 18   over the interactions between user space and     18   over the interactions between user space and BPF programs.
 19 * Provides overall support for the BPF object      19 * Provides overall support for the BPF object skeleton generated by bpftool.
 20   The skeleton file simplifies the process for     20   The skeleton file simplifies the process for the user space programs to access
 21   global variables and work with BPF programs.     21   global variables and work with BPF programs.
 22 * Provides BPF-side APIS, including BPF helper     22 * Provides BPF-side APIS, including BPF helper definitions, BPF maps support,
 23   and tracing helpers, allowing developers to      23   and tracing helpers, allowing developers to simplify BPF code writing.
 24 * Supports BPF CO-RE mechanism, enabling BPF d     24 * Supports BPF CO-RE mechanism, enabling BPF developers to write portable
 25   BPF programs that can be compiled once and r     25   BPF programs that can be compiled once and run across different kernel
 26   versions.                                        26   versions.
 27                                                    27 
 28 This document will delve into the above concep     28 This document will delve into the above concepts in detail, providing a deeper
 29 understanding of the capabilities and advantag     29 understanding of the capabilities and advantages of libbpf and how it can help
 30 you develop BPF applications efficiently.          30 you develop BPF applications efficiently.
 31                                                    31 
 32 BPF App Lifecycle and libbpf APIs                  32 BPF App Lifecycle and libbpf APIs
 33 ==================================                 33 ==================================
 34                                                    34 
 35 A BPF application consists of one or more BPF      35 A BPF application consists of one or more BPF programs (either cooperating or
 36 completely independent), BPF maps, and global      36 completely independent), BPF maps, and global variables. The global
 37 variables are shared between all BPF programs,     37 variables are shared between all BPF programs, which allows them to cooperate on
 38 a common set of data. libbpf provides APIs tha     38 a common set of data. libbpf provides APIs that user space programs can use to
 39 manipulate the BPF programs by triggering diff     39 manipulate the BPF programs by triggering different phases of a BPF application
 40 lifecycle.                                         40 lifecycle.
 41                                                    41 
 42 The following section provides a brief overvie     42 The following section provides a brief overview of each phase in the BPF life
 43 cycle:                                             43 cycle:
 44                                                    44 
 45 * **Open phase**: In this phase, libbpf parses     45 * **Open phase**: In this phase, libbpf parses the BPF
 46   object file and discovers BPF maps, BPF prog     46   object file and discovers BPF maps, BPF programs, and global variables. After
 47   a BPF app is opened, user space apps can mak     47   a BPF app is opened, user space apps can make additional adjustments
 48   (setting BPF program types, if necessary; pr     48   (setting BPF program types, if necessary; pre-setting initial values for
 49   global variables, etc.) before all the entit     49   global variables, etc.) before all the entities are created and loaded.
 50                                                    50 
 51 * **Load phase**: In the load phase, libbpf cr     51 * **Load phase**: In the load phase, libbpf creates BPF
 52   maps, resolves various relocations, and veri     52   maps, resolves various relocations, and verifies and loads BPF programs into
 53   the kernel. At this point, libbpf validates      53   the kernel. At this point, libbpf validates all the parts of a BPF application
 54   and loads the BPF program into the kernel, b     54   and loads the BPF program into the kernel, but no BPF program has yet been
 55   executed. After the load phase, it’s possi     55   executed. After the load phase, it’s possible to set up the initial BPF map
 56   state without racing with the BPF program co     56   state without racing with the BPF program code execution.
 57                                                    57 
 58 * **Attachment phase**: In this phase, libbpf      58 * **Attachment phase**: In this phase, libbpf
 59   attaches BPF programs to various BPF hook po     59   attaches BPF programs to various BPF hook points (e.g., tracepoints, kprobes,
 60   cgroup hooks, network packet processing pipe     60   cgroup hooks, network packet processing pipeline, etc.). During this
 61   phase, BPF programs perform useful work such     61   phase, BPF programs perform useful work such as processing
 62   packets, or updating BPF maps and global var     62   packets, or updating BPF maps and global variables that can be read from user
 63   space.                                           63   space.
 64                                                    64 
 65 * **Tear down phase**: In the tear down phase,     65 * **Tear down phase**: In the tear down phase,
 66   libbpf detaches BPF programs and unloads the     66   libbpf detaches BPF programs and unloads them from the kernel. BPF maps are
 67   destroyed, and all the resources used by the     67   destroyed, and all the resources used by the BPF app are freed.
 68                                                    68 
 69 BPF Object Skeleton File                           69 BPF Object Skeleton File
 70 ========================                           70 ========================
 71                                                    71 
 72 BPF skeleton is an alternative interface to li     72 BPF skeleton is an alternative interface to libbpf APIs for working with BPF
 73 objects. Skeleton code abstract away generic l     73 objects. Skeleton code abstract away generic libbpf APIs to significantly
 74 simplify code for manipulating BPF programs fr     74 simplify code for manipulating BPF programs from user space. Skeleton code
 75 includes a bytecode representation of the BPF      75 includes a bytecode representation of the BPF object file, simplifying the
 76 process of distributing your BPF code. With BP     76 process of distributing your BPF code. With BPF bytecode embedded, there are no
 77 extra files to deploy along with your applicat     77 extra files to deploy along with your application binary.
 78                                                    78 
 79 You can generate the skeleton header file ``(.     79 You can generate the skeleton header file ``(.skel.h)`` for a specific object
 80 file by passing the BPF object to the bpftool.     80 file by passing the BPF object to the bpftool. The generated BPF skeleton
 81 provides the following custom functions that c     81 provides the following custom functions that correspond to the BPF lifecycle,
 82 each of them prefixed with the specific object     82 each of them prefixed with the specific object name:
 83                                                    83 
 84 * ``<name>__open()`` – creates and opens BPF     84 * ``<name>__open()`` – creates and opens BPF application (``<name>`` stands for
 85   the specific bpf object name)                    85   the specific bpf object name)
 86 * ``<name>__load()`` – instantiates, loads,a     86 * ``<name>__load()`` – instantiates, loads,and verifies BPF application parts
 87 * ``<name>__attach()`` – attaches all auto-a     87 * ``<name>__attach()`` – attaches all auto-attachable BPF programs (it’s
 88   optional, you can have more control by using     88   optional, you can have more control by using libbpf APIs directly)
 89 * ``<name>__destroy()`` – detaches all BPF p     89 * ``<name>__destroy()`` – detaches all BPF programs and
 90   frees up all used resources                      90   frees up all used resources
 91                                                    91 
 92 Using the skeleton code is the recommended way     92 Using the skeleton code is the recommended way to work with bpf programs. Keep
 93 in mind, BPF skeleton provides access to the u     93 in mind, BPF skeleton provides access to the underlying BPF object, so whatever
 94 was possible to do with generic libbpf APIs is     94 was possible to do with generic libbpf APIs is still possible even when the BPF
 95 skeleton is used. It's an additive convenience     95 skeleton is used. It's an additive convenience feature, with no syscalls, and no
 96 cumbersome code.                                   96 cumbersome code.
 97                                                    97 
 98 Other Advantages of Using Skeleton File            98 Other Advantages of Using Skeleton File
 99 ---------------------------------------            99 ---------------------------------------
100                                                   100 
101 * BPF skeleton provides an interface for user     101 * BPF skeleton provides an interface for user space programs to work with BPF
102   global variables. The skeleton code memory m    102   global variables. The skeleton code memory maps global variables as a struct
103   into user space. The struct interface allows    103   into user space. The struct interface allows user space programs to initialize
104   BPF programs before the BPF load phase and f    104   BPF programs before the BPF load phase and fetch and update data from user
105   space afterward.                                105   space afterward.
106                                                   106 
107 * The ``skel.h`` file reflects the object file    107 * The ``skel.h`` file reflects the object file structure by listing out the
108   available maps, programs, etc. BPF skeleton     108   available maps, programs, etc. BPF skeleton provides direct access to all the
109   BPF maps and BPF programs as struct fields.     109   BPF maps and BPF programs as struct fields. This eliminates the need for
110   string-based lookups with ``bpf_object_find_    110   string-based lookups with ``bpf_object_find_map_by_name()`` and
111   ``bpf_object_find_program_by_name()`` APIs,     111   ``bpf_object_find_program_by_name()`` APIs, reducing errors due to BPF source
112   code and user-space code getting out of sync    112   code and user-space code getting out of sync.
113                                                   113 
114 * The embedded bytecode representation of the     114 * The embedded bytecode representation of the object file ensures that the
115   skeleton and the BPF object file are always     115   skeleton and the BPF object file are always in sync.
116                                                   116 
117 BPF Helpers                                       117 BPF Helpers
118 ===========                                       118 ===========
119                                                   119 
120 libbpf provides BPF-side APIs that BPF program    120 libbpf provides BPF-side APIs that BPF programs can use to interact with the
121 system. The BPF helpers definition allows deve    121 system. The BPF helpers definition allows developers to use them in BPF code as
122 any other plain C function. For example, there    122 any other plain C function. For example, there are helper functions to print
123 debugging messages, get the time since the sys    123 debugging messages, get the time since the system was booted, interact with BPF
124 maps, manipulate network packets, etc.            124 maps, manipulate network packets, etc.
125                                                   125 
126 For a complete description of what the helpers    126 For a complete description of what the helpers do, the arguments they take, and
127 the return value, see the `bpf-helpers            127 the return value, see the `bpf-helpers
128 <https://man7.org/linux/man-pages/man7/bpf-hel    128 <https://man7.org/linux/man-pages/man7/bpf-helpers.7.html>`_ man page.
129                                                   129 
130 BPF CO-RE (Compile Once – Run Everywhere)       130 BPF CO-RE (Compile Once – Run Everywhere)
131 =========================================         131 =========================================
132                                                   132 
133 BPF programs work in the kernel space and have    133 BPF programs work in the kernel space and have access to kernel memory and data
134 structures. One limitation that BPF applicatio    134 structures. One limitation that BPF applications come across is the lack of
135 portability across different kernel versions a    135 portability across different kernel versions and configurations. `BCC
136 <https://github.com/iovisor/bcc/>`_ is one of     136 <https://github.com/iovisor/bcc/>`_ is one of the solutions for BPF
137 portability. However, it comes with runtime ov    137 portability. However, it comes with runtime overhead and a large binary size
138 from embedding the compiler with the applicati    138 from embedding the compiler with the application.
139                                                   139 
140 libbpf steps up the BPF program portability by    140 libbpf steps up the BPF program portability by supporting the BPF CO-RE concept.
141 BPF CO-RE brings together BTF type information    141 BPF CO-RE brings together BTF type information, libbpf, and the compiler to
142 produce a single executable binary that you ca    142 produce a single executable binary that you can run on multiple kernel versions
143 and configurations.                               143 and configurations.
144                                                   144 
145 To make BPF programs portable libbpf relies on    145 To make BPF programs portable libbpf relies on the BTF type information of the
146 running kernel. Kernel also exposes this self-    146 running kernel. Kernel also exposes this self-describing authoritative BTF
147 information through ``sysfs`` at ``/sys/kernel    147 information through ``sysfs`` at ``/sys/kernel/btf/vmlinux``.
148                                                   148 
149 You can generate the BTF information for the r    149 You can generate the BTF information for the running kernel with the following
150 command:                                          150 command:
151                                                   151 
152 ::                                                152 ::
153                                                   153 
154   $ bpftool btf dump file /sys/kernel/btf/vmli    154   $ bpftool btf dump file /sys/kernel/btf/vmlinux format c > vmlinux.h
155                                                   155 
156 The command generates a ``vmlinux.h`` header f    156 The command generates a ``vmlinux.h`` header file with all kernel types
157 (:doc:`BTF types <../btf>`) that the running k    157 (:doc:`BTF types <../btf>`) that the running kernel uses. Including
158 ``vmlinux.h`` in your BPF program eliminates d    158 ``vmlinux.h`` in your BPF program eliminates dependency on system-wide kernel
159 headers.                                          159 headers.
160                                                   160 
161 libbpf enables portability of BPF programs by     161 libbpf enables portability of BPF programs by looking at the BPF program’s
162 recorded BTF type and relocation information a    162 recorded BTF type and relocation information and matching them to BTF
163 information (vmlinux) provided by the running     163 information (vmlinux) provided by the running kernel. libbpf then resolves and
164 matches all the types and fields, and updates     164 matches all the types and fields, and updates necessary offsets and other
165 relocatable data to ensure that BPF program’    165 relocatable data to ensure that BPF program’s logic functions correctly for a
166 specific kernel on the host. BPF CO-RE concept    166 specific kernel on the host. BPF CO-RE concept thus eliminates overhead
167 associated with BPF development and allows dev    167 associated with BPF development and allows developers to write portable BPF
168 applications without modifications and runtime    168 applications without modifications and runtime source code compilation on the
169 target machine.                                   169 target machine.
170                                                   170 
171 The following code snippet shows how to read t    171 The following code snippet shows how to read the parent field of a kernel
172 ``task_struct`` using BPF CO-RE and libbf. The    172 ``task_struct`` using BPF CO-RE and libbf. The basic helper to read a field in a
173 CO-RE relocatable manner is ``bpf_core_read(ds    173 CO-RE relocatable manner is ``bpf_core_read(dst, sz, src)``, which will read
174 ``sz`` bytes from the field referenced by ``sr    174 ``sz`` bytes from the field referenced by ``src`` into the memory pointed to by
175 ``dst``.                                          175 ``dst``.
176                                                   176 
177 .. code-block:: C                                 177 .. code-block:: C
178    :emphasize-lines: 6                            178    :emphasize-lines: 6
179                                                   179 
180     //...                                         180     //...
181     struct task_struct *task = (void *)bpf_get    181     struct task_struct *task = (void *)bpf_get_current_task();
182     struct task_struct *parent_task;              182     struct task_struct *parent_task;
183     int err;                                      183     int err;
184                                                   184 
185     err = bpf_core_read(&parent_task, sizeof(v    185     err = bpf_core_read(&parent_task, sizeof(void *), &task->parent);
186     if (err) {                                    186     if (err) {
187       /* handle error */                          187       /* handle error */
188     }                                             188     }
189                                                   189 
190     /* parent_task contains the value of task-    190     /* parent_task contains the value of task->parent pointer */
191                                                   191 
192 In the code snippet, we first get a pointer to    192 In the code snippet, we first get a pointer to the current ``task_struct`` using
193 ``bpf_get_current_task()``.  We then use ``bpf    193 ``bpf_get_current_task()``.  We then use ``bpf_core_read()`` to read the parent
194 field of task struct into the ``parent_task``     194 field of task struct into the ``parent_task`` variable. ``bpf_core_read()`` is
195 just like ``bpf_probe_read_kernel()`` BPF help    195 just like ``bpf_probe_read_kernel()`` BPF helper, except it records information
196 about the field that should be relocated on th    196 about the field that should be relocated on the target kernel. i.e, if the
197 ``parent`` field gets shifted to a different o    197 ``parent`` field gets shifted to a different offset within
198 ``struct task_struct`` due to some new field a    198 ``struct task_struct`` due to some new field added in front of it, libbpf will
199 automatically adjust the actual offset to the     199 automatically adjust the actual offset to the proper value.
200                                                   200 
201 Getting Started with libbpf                       201 Getting Started with libbpf
202 ===========================                       202 ===========================
203                                                   203 
204 Check out the `libbpf-bootstrap <https://githu    204 Check out the `libbpf-bootstrap <https://github.com/libbpf/libbpf-bootstrap>`_
205 repository with simple examples of using libbp    205 repository with simple examples of using libbpf to build various BPF
206 applications.                                     206 applications.
207                                                   207 
208 See also `libbpf API documentation                208 See also `libbpf API documentation
209 <https://libbpf.readthedocs.io/en/latest/api.h    209 <https://libbpf.readthedocs.io/en/latest/api.html>`_.
210                                                   210 
211 libbpf and Rust                                   211 libbpf and Rust
212 ===============                                   212 ===============
213                                                   213 
214 If you are building BPF applications in Rust,     214 If you are building BPF applications in Rust, it is recommended to use the
215 `Libbpf-rs <https://github.com/libbpf/libbpf-r    215 `Libbpf-rs <https://github.com/libbpf/libbpf-rs>`_ library instead of bindgen
216 bindings directly to libbpf. Libbpf-rs wraps l    216 bindings directly to libbpf. Libbpf-rs wraps libbpf functionality in
217 Rust-idiomatic interfaces and provides libbpf-    217 Rust-idiomatic interfaces and provides libbpf-cargo plugin to handle BPF code
218 compilation and skeleton generation. Using Lib    218 compilation and skeleton generation. Using Libbpf-rs will make building user
219 space part of the BPF application easier. Note    219 space part of the BPF application easier. Note that the BPF program themselves
220 must still be written in plain C.                 220 must still be written in plain C.
221                                                   221 
222 libbpf logging                                    222 libbpf logging
223 ==============                                    223 ==============
224                                                   224 
225 By default, libbpf logs informational and warn    225 By default, libbpf logs informational and warning messages to stderr. The
226 verbosity of these messages can be controlled     226 verbosity of these messages can be controlled by setting the environment
227 variable LIBBPF_LOG_LEVEL to either warn, info    227 variable LIBBPF_LOG_LEVEL to either warn, info, or debug. A custom log
228 callback can be set using ``libbpf_set_print()    228 callback can be set using ``libbpf_set_print()``.
229                                                   229 
230 Additional Documentation                          230 Additional Documentation
231 ========================                          231 ========================
232                                                   232 
233 * `Program types and ELF Sections <https://lib    233 * `Program types and ELF Sections <https://libbpf.readthedocs.io/en/latest/program_types.html>`_
234 * `API naming convention <https://libbpf.readt    234 * `API naming convention <https://libbpf.readthedocs.io/en/latest/libbpf_naming_convention.html>`_
235 * `Building libbpf <https://libbpf.readthedocs    235 * `Building libbpf <https://libbpf.readthedocs.io/en/latest/libbpf_build.html>`_
236 * `API documentation Convention <https://libbp    236 * `API documentation Convention <https://libbpf.readthedocs.io/en/latest/libbpf_naming_convention.html#api-documentation-convention>`_
                                                      

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