tools/bpf/bpftool/Documentation/bpftool-gen.rst - linux - Git at Google

 ================
 bpftool-gen
 ================
 -------------------------------------------------------------------------------
 tool for BPF code-generation
 -------------------------------------------------------------------------------

 :Manual section: 8

 SYNOPSIS
 ========

 	**bpftool** [*OPTIONS*] **gen** *COMMAND*

 	*OPTIONS* := { { **-j** | **--json** } [{ **-p** | **--pretty** }] }

 	*COMMAND* := { **skeleton** | **help** }

 GEN COMMANDS
 =============

 |	**bpftool** **gen skeleton** *FILE*
 |	**bpftool** **gen help**

 DESCRIPTION
 ===========
 	**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, derived from
 		  object file name. I.e., if BPF object file name is
 		  **example.o**, BPF object name will be **example**. The
 		  following custom functions are provided in such case:

 		  - **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 help**
 		  Print short help message.

 OPTIONS
 =======
 	.. include:: common_options.rst

 EXAMPLES
 ========
 **$ cat example.c**

 ::

   #include <stdbool.h>
   #include <linux/ptrace.h>
   #include <linux/bpf.h>
   #include "bpf_helpers.h"

   const volatile int param1 = 42;
   bool global_flag = true;
   struct { int x; } data = {};

   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_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;
   }

   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.

 **$ bpftool gen skeleton example.o**

 ::

   /* 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_user.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_user**

 ::

   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.
	================
	bpftool-gen
	================
	-------------------------------------------------------------------------------
	tool for BPF code-generation
	-------------------------------------------------------------------------------

	:Manual section: 8

	SYNOPSIS
	========

	bpftool [OPTIONS] gen COMMAND

	OPTIONS := { { -j \| --json } [{ -p \| --pretty }] }

	COMMAND := { skeleton \| help }

	GEN COMMANDS
	=============

	\| bpftool gen skeleton FILE
	\| bpftool gen help

	DESCRIPTION
	===========
	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, derived from
	object file name. I.e., if BPF object file name is
	example.o, BPF object name will be example. The
	following custom functions are provided in such case:

	- 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 help
	Print short help message.

	OPTIONS
	=======
	.. include:: common_options.rst

	EXAMPLES
	========
	$ cat example.c

	::

	#include <stdbool.h>
	#include <linux/ptrace.h>
	#include <linux/bpf.h>
	#include "bpf_helpers.h"

	const volatile int param1 = 42;
	bool global_flag = true;
	struct { int x; } data = {};

	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_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;
	}

	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.

	$ bpftool gen skeleton example.o

	::

	/* 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_user.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_user

	::

	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.