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+.. SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
+
+================
+bpftool-gen
+================
+-------------------------------------------------------------------------------
+tool for BPF code-generation
+-------------------------------------------------------------------------------
+
+:Manual section: 8
+
+.. include:: substitutions.rst
+
+SYNOPSIS
+========
+
+	**bpftool** [*OPTIONS*] **gen** *COMMAND*
+
+	*OPTIONS* := { |COMMON_OPTIONS| | { **-L** | **--use-loader** } }
+
+	*COMMAND* := { **object** | **skeleton** | **help** }
+
+GEN COMMANDS
+=============
+
+|	**bpftool** **gen object** *OUTPUT_FILE* *INPUT_FILE* [*INPUT_FILE*...]
+|	**bpftool** **gen skeleton** *FILE* [**name** *OBJECT_NAME*]
+|	**bpftool** **gen subskeleton** *FILE* [**name** *OBJECT_NAME*]
+|	**bpftool** **gen min_core_btf** *INPUT* *OUTPUT* *OBJECT* [*OBJECT*...]
+|	**bpftool** **gen help**
+
+DESCRIPTION
+===========
+	**bpftool gen object** *OUTPUT_FILE* *INPUT_FILE* [*INPUT_FILE*...]
+		  Statically link (combine) together one or more *INPUT_FILE*'s
+		  into a single resulting *OUTPUT_FILE*. All the files involved
+		  are BPF ELF object files.
+
+		  The rules of BPF static linking are mostly the same as for
+		  user-space object files, but in addition to combining data
+		  and instruction sections, .BTF and .BTF.ext (if present in
+		  any of the input files) data are combined together. .BTF
+		  data is deduplicated, so all the common types across
+		  *INPUT_FILE*'s will only be represented once in the resulting
+		  BTF information.
+
+		  BPF static linking allows to partition BPF source code into
+		  individually compiled files that are then linked into
+		  a single resulting BPF object file, which can be used to
+		  generated BPF skeleton (with **gen skeleton** command) or
+		  passed directly into **libbpf** (using **bpf_object__open()**
+		  family of APIs).
+
+	**bpftool gen skeleton** *FILE*
+		  Generate BPF skeleton C header file for a given *FILE*.
+
+		  BPF skeleton is an alternative interface to existing libbpf
+		  APIs for working with BPF objects. Skeleton code is intended
+		  to significantly shorten and simplify code to load and work
+		  with BPF programs from userspace side. Generated code is
+		  tailored to specific input BPF object *FILE*, reflecting its
+		  structure by listing out available maps, program, variables,
+		  etc. Skeleton eliminates the need to lookup mentioned
+		  components by name. Instead, if skeleton instantiation
+		  succeeds, they are populated in skeleton structure as valid
+		  libbpf types (e.g., **struct bpf_map** pointer) and can be
+		  passed to existing generic libbpf APIs.
+
+		  In addition to simple and reliable access to maps and
+		  programs, skeleton provides a storage for BPF links (**struct
+		  bpf_link**) for each BPF program within BPF object. When
+		  requested, supported BPF programs will be automatically
+		  attached and resulting BPF links stored for further use by
+		  user in pre-allocated fields in skeleton struct. For BPF
+		  programs that can't be automatically attached by libbpf,
+		  user can attach them manually, but store resulting BPF link
+		  in per-program link field. All such set up links will be
+		  automatically destroyed on BPF skeleton destruction. This
+		  eliminates the need for users to manage links manually and
+		  rely on libbpf support to detach programs and free up
+		  resources.
+
+		  Another facility provided by BPF skeleton is an interface to
+		  global variables of all supported kinds: mutable, read-only,
+		  as well as extern ones. This interface allows to pre-setup
+		  initial values of variables before BPF object is loaded and
+		  verified by kernel. For non-read-only variables, the same
+		  interface can be used to fetch values of global variables on
+		  userspace side, even if they are modified by BPF code.
+
+		  During skeleton generation, contents of source BPF object
+		  *FILE* is embedded within generated code and is thus not
+		  necessary to keep around. This ensures skeleton and BPF
+		  object file are matching 1-to-1 and always stay in sync.
+		  Generated code is dual-licensed under LGPL-2.1 and
+		  BSD-2-Clause licenses.
+
+		  It is a design goal and guarantee that skeleton interfaces
+		  are interoperable with generic libbpf APIs. User should
+		  always be able to use skeleton API to create and load BPF
+		  object, and later use libbpf APIs to keep working with
+		  specific maps, programs, etc.
+
+		  As part of skeleton, few custom functions are generated.
+		  Each of them is prefixed with object name. Object name can
+		  either be derived from object file name, i.e., if BPF object
+		  file name is **example.o**, BPF object name will be
+		  **example**. Object name can be also specified explicitly
+		  through **name** *OBJECT_NAME* parameter. The following
+		  custom functions are provided (assuming **example** as
+		  the object name):
+
+		  - **example__open** and **example__open_opts**.
+		    These functions are used to instantiate skeleton. It
+		    corresponds to libbpf's **bpf_object__open**\ () API.
+		    **_opts** variants accepts extra **bpf_object_open_opts**
+		    options.
+
+		  - **example__load**.
+		    This function creates maps, loads and verifies BPF
+		    programs, initializes global data maps. It corresponds to
+		    libppf's **bpf_object__load**\ () API.
+
+		  - **example__open_and_load** combines **example__open** and
+		    **example__load** invocations in one commonly used
+		    operation.
+
+		  - **example__attach** and **example__detach**
+		    This pair of functions allow to attach and detach,
+		    correspondingly, already loaded BPF object. Only BPF
+		    programs of types supported by libbpf for auto-attachment
+		    will be auto-attached and their corresponding BPF links
+		    instantiated. For other BPF programs, user can manually
+		    create a BPF link and assign it to corresponding fields in
+		    skeleton struct. **example__detach** will detach both
+		    links created automatically, as well as those populated by
+		    user manually.
+
+		  - **example__destroy**
+		    Detach and unload BPF programs, free up all the resources
+		    used by skeleton and BPF object.
+
+		  If BPF object has global variables, corresponding structs
+		  with memory layout corresponding to global data data section
+		  layout will be created. Currently supported ones are: *.data*,
+		  *.bss*, *.rodata*, and *.kconfig* structs/data sections.
+		  These data sections/structs can be used to set up initial
+		  values of variables, if set before **example__load**.
+		  Afterwards, if target kernel supports memory-mapped BPF
+		  arrays, same structs can be used to fetch and update
+		  (non-read-only) data from userspace, with same simplicity
+		  as for BPF side.
+
+	**bpftool gen subskeleton** *FILE*
+		  Generate BPF subskeleton C header file for a given *FILE*.
+
+		  Subskeletons are similar to skeletons, except they do not own
+		  the corresponding maps, programs, or global variables. They
+		  require that the object file used to generate them is already
+		  loaded into a *bpf_object* by some other means.
+
+		  This functionality is useful when a library is included into a
+		  larger BPF program. A subskeleton for the library would have
+		  access to all objects and globals defined in it, without
+		  having to know about the larger program.
+
+		  Consequently, there are only two functions defined
+		  for subskeletons:
+
+		  - **example__open(bpf_object\*)**
+		    Instantiates a subskeleton from an already opened (but not
+		    necessarily loaded) **bpf_object**.
+
+		  - **example__destroy()**
+		    Frees the storage for the subskeleton but *does not* unload
+		    any BPF programs or maps.
+
+	**bpftool** **gen min_core_btf** *INPUT* *OUTPUT* *OBJECT* [*OBJECT*...]
+		  Generate a minimum BTF file as *OUTPUT*, derived from a given
+		  *INPUT* BTF file, containing all needed BTF types so one, or
+		  more, given eBPF objects CO-RE relocations may be satisfied.
+
+		  When kernels aren't compiled with CONFIG_DEBUG_INFO_BTF,
+		  libbpf, when loading an eBPF object, has to rely on external
+		  BTF files to be able to calculate CO-RE relocations.
+
+		  Usually, an external BTF file is built from existing kernel
+		  DWARF data using pahole. It contains all the types used by
+		  its respective kernel image and, because of that, is big.
+
+		  The min_core_btf feature builds smaller BTF files, customized
+		  to one or multiple eBPF objects, so they can be distributed
+		  together with an eBPF CO-RE based application, turning the
+		  application portable to different kernel versions.
+
+		  Check examples bellow for more information how to use it.
+
+	**bpftool gen help**
+		  Print short help message.
+
+OPTIONS
+=======
+	.. include:: common_options.rst
+
+	-L, --use-loader
+		  For skeletons, generate a "light" skeleton (also known as "loader"
+		  skeleton). A light skeleton contains a loader eBPF program. It does
+		  not use the majority of the libbpf infrastructure, and does not need
+		  libelf.
+
+EXAMPLES
+========
+**$ cat example1.bpf.c**
+
+::
+
+  #include <stdbool.h>
+  #include <linux/ptrace.h>
+  #include <linux/bpf.h>
+  #include <bpf/bpf_helpers.h>
+
+  const volatile int param1 = 42;
+  bool global_flag = true;
+  struct { int x; } data = {};
+
+  SEC("raw_tp/sys_enter")
+  int handle_sys_enter(struct pt_regs *ctx)
+  {
+  	static long my_static_var;
+  	if (global_flag)
+  		my_static_var++;
+  	else
+  		data.x += param1;
+  	return 0;
+  }
+
+**$ cat example2.bpf.c**
+
+::
+
+  #include <linux/ptrace.h>
+  #include <linux/bpf.h>
+  #include <bpf/bpf_helpers.h>
+
+  struct {
+  	__uint(type, BPF_MAP_TYPE_HASH);
+  	__uint(max_entries, 128);
+  	__type(key, int);
+  	__type(value, long);
+  } my_map SEC(".maps");
+
+  SEC("raw_tp/sys_exit")
+  int handle_sys_exit(struct pt_regs *ctx)
+  {
+  	int zero = 0;
+  	bpf_map_lookup_elem(&my_map, &zero);
+  	return 0;
+  }
+
+This is example BPF application with two BPF programs and a mix of BPF maps
+and global variables. Source code is split across two source code files.
+
+**$ clang -target bpf -g example1.bpf.c -o example1.bpf.o**
+
+**$ clang -target bpf -g example2.bpf.c -o example2.bpf.o**
+
+**$ bpftool gen object example.bpf.o example1.bpf.o example2.bpf.o**
+
+This set of commands compiles *example1.bpf.c* and *example2.bpf.c*
+individually and then statically links respective object files into the final
+BPF ELF object file *example.bpf.o*.
+
+**$ bpftool gen skeleton example.bpf.o name example | tee example.skel.h**
+
+::
+
+  /* SPDX-License-Identifier: (LGPL-2.1 OR BSD-2-Clause) */
+
+  /* THIS FILE IS AUTOGENERATED! */
+  #ifndef __EXAMPLE_SKEL_H__
+  #define __EXAMPLE_SKEL_H__
+
+  #include <stdlib.h>
+  #include <bpf/libbpf.h>
+
+  struct example {
+  	struct bpf_object_skeleton *skeleton;
+  	struct bpf_object *obj;
+  	struct {
+  		struct bpf_map *rodata;
+  		struct bpf_map *data;
+  		struct bpf_map *bss;
+  		struct bpf_map *my_map;
+  	} maps;
+  	struct {
+  		struct bpf_program *handle_sys_enter;
+  		struct bpf_program *handle_sys_exit;
+  	} progs;
+  	struct {
+  		struct bpf_link *handle_sys_enter;
+  		struct bpf_link *handle_sys_exit;
+  	} links;
+  	struct example__bss {
+  		struct {
+  			int x;
+  		} data;
+  	} *bss;
+  	struct example__data {
+  		_Bool global_flag;
+  		long int handle_sys_enter_my_static_var;
+  	} *data;
+  	struct example__rodata {
+  		int param1;
+  	} *rodata;
+  };
+
+  static void example__destroy(struct example *obj);
+  static inline struct example *example__open_opts(
+                const struct bpf_object_open_opts *opts);
+  static inline struct example *example__open();
+  static inline int example__load(struct example *obj);
+  static inline struct example *example__open_and_load();
+  static inline int example__attach(struct example *obj);
+  static inline void example__detach(struct example *obj);
+
+  #endif /* __EXAMPLE_SKEL_H__ */
+
+**$ cat example.c**
+
+::
+
+  #include "example.skel.h"
+
+  int main()
+  {
+  	struct example *skel;
+  	int err = 0;
+
+  	skel = example__open();
+  	if (!skel)
+  		goto cleanup;
+
+  	skel->rodata->param1 = 128;
+
+  	err = example__load(skel);
+  	if (err)
+  		goto cleanup;
+
+  	err = example__attach(skel);
+  	if (err)
+  		goto cleanup;
+
+  	/* all libbpf APIs are usable */
+  	printf("my_map name: %s\n", bpf_map__name(skel->maps.my_map));
+  	printf("sys_enter prog FD: %d\n",
+  	       bpf_program__fd(skel->progs.handle_sys_enter));
+
+  	/* detach and re-attach sys_exit program */
+  	bpf_link__destroy(skel->links.handle_sys_exit);
+  	skel->links.handle_sys_exit =
+  		bpf_program__attach(skel->progs.handle_sys_exit);
+
+  	printf("my_static_var: %ld\n",
+  	       skel->bss->handle_sys_enter_my_static_var);
+
+  cleanup:
+  	example__destroy(skel);
+  	return err;
+  }
+
+**# ./example**
+
+::
+
+  my_map name: my_map
+  sys_enter prog FD: 8
+  my_static_var: 7
+
+This is a stripped-out version of skeleton generated for above example code.
+
+min_core_btf
+------------
+
+**$ bpftool btf dump file 5.4.0-example.btf format raw**
+
+::
+
+  [1] INT 'long unsigned int' size=8 bits_offset=0 nr_bits=64 encoding=(none)
+  [2] CONST '(anon)' type_id=1
+  [3] VOLATILE '(anon)' type_id=1
+  [4] ARRAY '(anon)' type_id=1 index_type_id=21 nr_elems=2
+  [5] PTR '(anon)' type_id=8
+  [6] CONST '(anon)' type_id=5
+  [7] INT 'char' size=1 bits_offset=0 nr_bits=8 encoding=(none)
+  [8] CONST '(anon)' type_id=7
+  [9] INT 'unsigned int' size=4 bits_offset=0 nr_bits=32 encoding=(none)
+  <long output>
+
+**$ bpftool btf dump file one.bpf.o format raw**
+
+::
+
+  [1] PTR '(anon)' type_id=2
+  [2] STRUCT 'trace_event_raw_sys_enter' size=64 vlen=4
+        'ent' type_id=3 bits_offset=0
+        'id' type_id=7 bits_offset=64
+        'args' type_id=9 bits_offset=128
+        '__data' type_id=12 bits_offset=512
+  [3] STRUCT 'trace_entry' size=8 vlen=4
+        'type' type_id=4 bits_offset=0
+        'flags' type_id=5 bits_offset=16
+        'preempt_count' type_id=5 bits_offset=24
+  <long output>
+
+**$ bpftool gen min_core_btf 5.4.0-example.btf 5.4.0-smaller.btf one.bpf.o**
+
+**$ bpftool btf dump file 5.4.0-smaller.btf format raw**
+
+::
+
+  [1] TYPEDEF 'pid_t' type_id=6
+  [2] STRUCT 'trace_event_raw_sys_enter' size=64 vlen=1
+        'args' type_id=4 bits_offset=128
+  [3] STRUCT 'task_struct' size=9216 vlen=2
+        'pid' type_id=1 bits_offset=17920
+        'real_parent' type_id=7 bits_offset=18048
+  [4] ARRAY '(anon)' type_id=5 index_type_id=8 nr_elems=6
+  [5] INT 'long unsigned int' size=8 bits_offset=0 nr_bits=64 encoding=(none)
+  [6] TYPEDEF '__kernel_pid_t' type_id=8
+  [7] PTR '(anon)' type_id=3
+  [8] INT 'int' size=4 bits_offset=0 nr_bits=32 encoding=SIGNED
+  <end>
+
+Now, the "5.4.0-smaller.btf" file may be used by libbpf as an external BTF file
+when loading the "one.bpf.o" object into the "5.4.0-example" kernel. Note that
+the generated BTF file won't allow other eBPF objects to be loaded, just the
+ones given to min_core_btf.
+
+::
+
+  LIBBPF_OPTS(bpf_object_open_opts, opts, .btf_custom_path = "5.4.0-smaller.btf");
+  struct bpf_object *obj;
+
+  obj = bpf_object__open_file("one.bpf.o", &opts);
+
+  ...