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Documentation/bpf/btf.rst
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@ -5,43 +5,35 @@ BPF Type Format (BTF)
1. Introduction
***************
BTF (BPF Type Format) is the metadata format which
encodes the debug info related to BPF program/map.
The name BTF was used initially to describe
data types. The BTF was later extended to include
function info for defined subroutines, and line info
for source/line information.
BTF (BPF Type Format) is the metadata format which encodes the debug info
related to BPF program/map. The name BTF was used initially to describe data
types. The BTF was later extended to include function info for defined
subroutines, and line info for source/line information.
The debug info is used for map pretty print, function
signature, etc. The function signature enables better
bpf program/function kernel symbol.
The line info helps generate
source annotated translated byte code, jited code
and verifier log.
The debug info is used for map pretty print, function signature, etc. The
function signature enables better bpf program/function kernel symbol. The line
info helps generate source annotated translated byte code, jited code and
verifier log.
The BTF specification contains two parts,
* BTF kernel API
* BTF ELF file format
The kernel API is the contract between
user space and kernel. The kernel verifies
the BTF info before using it.
The ELF file format is a user space contract
between ELF file and libbpf loader.
The kernel API is the contract between user space and kernel. The kernel
verifies the BTF info before using it. The ELF file format is a user space
contract between ELF file and libbpf loader.
The type and string sections are part of the
BTF kernel API, describing the debug info
(mostly types related) referenced by the bpf program.
These two sections are discussed in
details in :ref:`BTF_Type_String`.
The type and string sections are part of the BTF kernel API, describing the
debug info (mostly types related) referenced by the bpf program. These two
sections are discussed in details in :ref:`BTF_Type_String`.
.. _BTF_Type_String:
2. BTF Type and String Encoding
*******************************
The file ``include/uapi/linux/btf.h`` provides high-level
definition of how types/strings are encoded.
The file ``include/uapi/linux/btf.h`` provides high-level definition of how
types/strings are encoded.
The beginning of data blob must be::
@ -59,25 +51,23 @@ The beginning of data blob must be::
};
The magic is ``0xeB9F``, which has different encoding for big and little
endian systems, and can be used to test whether BTF is generated for
big- or little-endian target.
The ``btf_header`` is designed to be extensible with ``hdr_len`` equal to
``sizeof(struct btf_header)`` when a data blob is generated.
endian systems, and can be used to test whether BTF is generated for big- or
little-endian target. The ``btf_header`` is designed to be extensible with
``hdr_len`` equal to ``sizeof(struct btf_header)`` when a data blob is
generated.
2.1 String Encoding
===================
The first string in the string section must be a null string.
The rest of string table is a concatenation of other null-terminated
strings.
The first string in the string section must be a null string. The rest of
string table is a concatenation of other null-terminated strings.
2.2 Type Encoding
=================
The type id ``0`` is reserved for ``void`` type.
The type section is parsed sequentially and type id is assigned to
each recognized type starting from id ``1``.
Currently, the following types are supported::
The type id ``0`` is reserved for ``void`` type. The type section is parsed
sequentially and type id is assigned to each recognized type starting from id
``1``. Currently, the following types are supported::
#define BTF_KIND_INT 1 /* Integer */
#define BTF_KIND_PTR 2 /* Pointer */
@ -122,9 +112,9 @@ Each type contains the following common data::
};
};
For certain kinds, the common data are followed by kind-specific data.
The ``name_off`` in ``struct btf_type`` specifies the offset in the string
table. The following sections detail encoding of each kind.
For certain kinds, the common data are followed by kind-specific data. The
``name_off`` in ``struct btf_type`` specifies the offset in the string table.
The following sections detail encoding of each kind.
2.2.1 BTF_KIND_INT
~~~~~~~~~~~~~~~~~~
@ -148,38 +138,33 @@ The ``BTF_INT_ENCODING`` has the following attributes::
#define BTF_INT_CHAR (1 << 1)
#define BTF_INT_BOOL (1 << 2)
The ``BTF_INT_ENCODING()`` provides extra information: signedness,
char, or bool, for the int type. The char and bool encoding
are mostly useful for pretty print. At most one encoding can
be specified for the int type.
The ``BTF_INT_ENCODING()`` provides extra information: signedness, char, or
bool, for the int type. The char and bool encoding are mostly useful for
pretty print. At most one encoding can be specified for the int type.
The ``BTF_INT_BITS()`` specifies the number of actual bits held by
this int type. For example, a 4-bit bitfield encodes
``BTF_INT_BITS()`` equals to 4. The ``btf_type.size * 8``
must be equal to or greater than ``BTF_INT_BITS()`` for the type.
The maximum value of ``BTF_INT_BITS()`` is 128.
The ``BTF_INT_BITS()`` specifies the number of actual bits held by this int
type. For example, a 4-bit bitfield encodes ``BTF_INT_BITS()`` equals to 4.
The ``btf_type.size * 8`` must be equal to or greater than ``BTF_INT_BITS()``
for the type. The maximum value of ``BTF_INT_BITS()`` is 128.
The ``BTF_INT_OFFSET()`` specifies the starting bit offset to
calculate values for this int. For example, a bitfield struct
member has:
* btf member bit offset 100 from the start of the structure,
* btf member pointing to an int type,
* the int type has ``BTF_INT_OFFSET() = 2`` and ``BTF_INT_BITS() = 4``
The ``BTF_INT_OFFSET()`` specifies the starting bit offset to calculate values
for this int. For example, a bitfield struct member has: * btf member bit
offset 100 from the start of the structure, * btf member pointing to an int
type, * the int type has ``BTF_INT_OFFSET() = 2`` and ``BTF_INT_BITS() = 4``
Then in the struct memory layout, this member will occupy
``4`` bits starting from bits ``100 + 2 = 102``.
Then in the struct memory layout, this member will occupy ``4`` bits starting
from bits ``100 + 2 = 102``.
Alternatively, the bitfield struct member can be the following to
access the same bits as the above:
Alternatively, the bitfield struct member can be the following to access the
same bits as the above:
* btf member bit offset 102,
* btf member pointing to an int type,
* the int type has ``BTF_INT_OFFSET() = 0`` and ``BTF_INT_BITS() = 4``
The original intention of ``BTF_INT_OFFSET()`` is to provide
flexibility of bitfield encoding.
Currently, both llvm and pahole generate ``BTF_INT_OFFSET() = 0``
for all int types.
The original intention of ``BTF_INT_OFFSET()`` is to provide flexibility of
bitfield encoding. Currently, both llvm and pahole generate
``BTF_INT_OFFSET() = 0`` for all int types.
2.2.2 BTF_KIND_PTR
~~~~~~~~~~~~~~~~~~
@ -216,26 +201,25 @@ The ``struct btf_array`` encoding:
* ``index_type``: the index type
* ``nelems``: the number of elements for this array (``0`` is also allowed).
The ``index_type`` can be any regular int type
(``u8``, ``u16``, ``u32``, ``u64``, ``unsigned __int128``).
The original design of including ``index_type`` follows DWARF,
which has an ``index_type`` for its array type.
The ``index_type`` can be any regular int type (``u8``, ``u16``, ``u32``,
``u64``, ``unsigned __int128``). The original design of including
``index_type`` follows DWARF, which has an ``index_type`` for its array type.
Currently in BTF, beyond type verification, the ``index_type`` is not used.
The ``struct btf_array`` allows chaining through element type to represent
multidimensional arrays. For example, for ``int a[5][6]``, the following
type information illustrates the chaining:
multidimensional arrays. For example, for ``int a[5][6]``, the following type
information illustrates the chaining:
* [1]: int
* [2]: array, ``btf_array.type = [1]``, ``btf_array.nelems = 6``
* [3]: array, ``btf_array.type = [2]``, ``btf_array.nelems = 5``
Currently, both pahole and llvm collapse multidimensional array
into one-dimensional array, e.g., for ``a[5][6]``, the ``btf_array.nelems``
is equal to ``30``. This is because the original use case is map pretty
print where the whole array is dumped out so one-dimensional array
is enough. As more BTF usage is explored, pahole and llvm can be
changed to generate proper chained representation for multidimensional arrays.
Currently, both pahole and llvm collapse multidimensional array into
one-dimensional array, e.g., for ``a[5][6]``, the ``btf_array.nelems`` is
equal to ``30``. This is because the original use case is map pretty print
where the whole array is dumped out so one-dimensional array is enough. As
more BTF usage is explored, pahole and llvm can be changed to generate proper
chained representation for multidimensional arrays.
2.2.4 BTF_KIND_STRUCT
~~~~~~~~~~~~~~~~~~~~~
@ -262,28 +246,26 @@ changed to generate proper chained representation for multidimensional arrays.
* ``type``: the member type
* ``offset``: <see below>
If the type info ``kind_flag`` is not set, the offset contains
only bit offset of the member. Note that the base type of the
bitfield can only be int or enum type. If the bitfield size
is 32, the base type can be either int or enum type.
If the bitfield size is not 32, the base type must be int,
and int type ``BTF_INT_BITS()`` encodes the bitfield size.
If the type info ``kind_flag`` is not set, the offset contains only bit offset
of the member. Note that the base type of the bitfield can only be int or enum
type. If the bitfield size is 32, the base type can be either int or enum
type. If the bitfield size is not 32, the base type must be int, and int type
``BTF_INT_BITS()`` encodes the bitfield size.
If the ``kind_flag`` is set, the ``btf_member.offset``
contains both member bitfield size and bit offset. The
bitfield size and bit offset are calculated as below.::
If the ``kind_flag`` is set, the ``btf_member.offset`` contains both member
bitfield size and bit offset. The bitfield size and bit offset are calculated
as below.::
#define BTF_MEMBER_BITFIELD_SIZE(val) ((val) >> 24)
#define BTF_MEMBER_BIT_OFFSET(val) ((val) & 0xffffff)
In this case, if the base type is an int type, it must
be a regular int type:
In this case, if the base type is an int type, it must be a regular int type:
* ``BTF_INT_OFFSET()`` must be 0.
* ``BTF_INT_BITS()`` must be equal to ``{1,2,4,8,16} * 8``.
The following kernel patch introduced ``kind_flag`` and
explained why both modes exist:
The following kernel patch introduced ``kind_flag`` and explained why both
modes exist:
https://github.com/torvalds/linux/commit/9d5f9f701b1891466fb3dbb1806ad97716f95cc3#diff-fa650a64fdd3968396883d2fe8215ff3
@ -381,10 +363,10 @@ No additional type data follow ``btf_type``.
No additional type data follow ``btf_type``.
A BTF_KIND_FUNC defines not a type, but a subprogram (function) whose
signature is defined by ``type``. The subprogram is thus an instance of
that type. The BTF_KIND_FUNC may in turn be referenced by a func_info in
the :ref:`BTF_Ext_Section` (ELF) or in the arguments to
:ref:`BPF_Prog_Load` (ABI).
signature is defined by ``type``. The subprogram is thus an instance of that
type. The BTF_KIND_FUNC may in turn be referenced by a func_info in the
:ref:`BTF_Ext_Section` (ELF) or in the arguments to :ref:`BPF_Prog_Load`
(ABI).
2.2.13 BTF_KIND_FUNC_PROTO
~~~~~~~~~~~~~~~~~~~~~~~~~~
@ -403,13 +385,13 @@ the :ref:`BTF_Ext_Section` (ELF) or in the arguments to
__u32 type;
};
If a BTF_KIND_FUNC_PROTO type is referred by a BTF_KIND_FUNC type,
then ``btf_param.name_off`` must point to a valid C identifier
except for the possible last argument representing the variable
argument. The btf_param.type refers to parameter type.
If a BTF_KIND_FUNC_PROTO type is referred by a BTF_KIND_FUNC type, then
``btf_param.name_off`` must point to a valid C identifier except for the
possible last argument representing the variable argument. The btf_param.type
refers to parameter type.
If the function has variable arguments, the last parameter
is encoded with ``name_off = 0`` and ``type = 0``.
If the function has variable arguments, the last parameter is encoded with
``name_off = 0`` and ``type = 0``.
3. BTF Kernel API
*****************
@ -457,10 +439,9 @@ The workflow typically looks like:
3.1 BPF_BTF_LOAD
================
Load a blob of BTF data into kernel. A blob of data,
described in :ref:`BTF_Type_String`,
can be directly loaded into the kernel.
A ``btf_fd`` is returned to a userspace.
Load a blob of BTF data into kernel. A blob of data, described in
:ref:`BTF_Type_String`, can be directly loaded into the kernel. A ``btf_fd``
is returned to a userspace.
3.2 BPF_MAP_CREATE
==================
@ -482,18 +463,18 @@ In libbpf, the map can be defined with extra annotation like below:
};
BPF_ANNOTATE_KV_PAIR(btf_map, int, struct ipv_counts);
Here, the parameters for macro BPF_ANNOTATE_KV_PAIR are map name,
key and value types for the map.
During ELF parsing, libbpf is able to extract key/value type_id's
and assign them to BPF_MAP_CREATE attributes automatically.
Here, the parameters for macro BPF_ANNOTATE_KV_PAIR are map name, key and
value types for the map. During ELF parsing, libbpf is able to extract
key/value type_id's and assign them to BPF_MAP_CREATE attributes
automatically.
.. _BPF_Prog_Load:
3.3 BPF_PROG_LOAD
=================
During prog_load, func_info and line_info can be passed to kernel with
proper values for the following attributes:
During prog_load, func_info and line_info can be passed to kernel with proper
values for the following attributes:
::
__u32 insn_cnt;
@ -520,9 +501,9 @@ The func_info and line_info are an array of below, respectively.::
__u32 line_col; /* line number and column number */
};
func_info_rec_size is the size of each func_info record, and line_info_rec_size
is the size of each line_info record. Passing the record size to kernel make
it possible to extend the record itself in the future.
func_info_rec_size is the size of each func_info record, and
line_info_rec_size is the size of each line_info record. Passing the record
size to kernel make it possible to extend the record itself in the future.
Below are requirements for func_info:
* func_info[0].insn_off must be 0.
@ -541,13 +522,12 @@ For line_info, the line number and column number are defined as below:
3.4 BPF_{PROG,MAP}_GET_NEXT_ID
In kernel, every loaded program, map or btf has a unique id.
The id won't change during the lifetime of a program, map, or btf.
In kernel, every loaded program, map or btf has a unique id. The id won't
change during the lifetime of a program, map, or btf.
The bpf syscall command BPF_{PROG,MAP}_GET_NEXT_ID
returns all id's, one for each command, to user space, for bpf
program or maps, respectively,
so an inspection tool can inspect all programs and maps.
The bpf syscall command BPF_{PROG,MAP}_GET_NEXT_ID returns all id's, one for
each command, to user space, for bpf program or maps, respectively, so an
inspection tool can inspect all programs and maps.
3.5 BPF_{PROG,MAP}_GET_FD_BY_ID
@ -557,24 +537,23 @@ A file descriptor needs to be obtained first for reference-counting purpose.
3.6 BPF_OBJ_GET_INFO_BY_FD
==========================
Once a program/map fd is acquired, an introspection tool can
get the detailed information from kernel about this fd,
some of which are BTF-related. For example,
``bpf_map_info`` returns ``btf_id`` and key/value type ids.
``bpf_prog_info`` returns ``btf_id``, func_info, and line info
for translated bpf byte codes, and jited_line_info.
Once a program/map fd is acquired, an introspection tool can get the detailed
information from kernel about this fd, some of which are BTF-related. For
example, ``bpf_map_info`` returns ``btf_id`` and key/value type ids.
``bpf_prog_info`` returns ``btf_id``, func_info, and line info for translated
bpf byte codes, and jited_line_info.
3.7 BPF_BTF_GET_FD_BY_ID
========================
With ``btf_id`` obtained in ``bpf_map_info`` and ``bpf_prog_info``,
bpf syscall command BPF_BTF_GET_FD_BY_ID can retrieve a btf fd.
Then, with command BPF_OBJ_GET_INFO_BY_FD, the btf blob, originally
loaded into the kernel with BPF_BTF_LOAD, can be retrieved.
With ``btf_id`` obtained in ``bpf_map_info`` and ``bpf_prog_info``, bpf
syscall command BPF_BTF_GET_FD_BY_ID can retrieve a btf fd. Then, with
command BPF_OBJ_GET_INFO_BY_FD, the btf blob, originally loaded into the
kernel with BPF_BTF_LOAD, can be retrieved.
With the btf blob, ``bpf_map_info``, and ``bpf_prog_info``, an introspection
tool has full btf knowledge and is able to pretty print map key/values,
dump func signatures and line info, along with byte/jit codes.
tool has full btf knowledge and is able to pretty print map key/values, dump
func signatures and line info, along with byte/jit codes.
4. ELF File Format Interface
****************************
@ -582,19 +561,19 @@ dump func signatures and line info, along with byte/jit codes.
4.1 .BTF section
================
The .BTF section contains type and string data. The format of this section
is same as the one describe in :ref:`BTF_Type_String`.
The .BTF section contains type and string data. The format of this section is
same as the one describe in :ref:`BTF_Type_String`.
.. _BTF_Ext_Section:
4.2 .BTF.ext section
====================
The .BTF.ext section encodes func_info and line_info which
needs loader manipulation before loading into the kernel.
The .BTF.ext section encodes func_info and line_info which needs loader
manipulation before loading into the kernel.
The specification for .BTF.ext section is defined at
``tools/lib/bpf/btf.h`` and ``tools/lib/bpf/btf.c``.
The specification for .BTF.ext section is defined at ``tools/lib/bpf/btf.h``
and ``tools/lib/bpf/btf.c``.
The current header of .BTF.ext section::
@ -611,9 +590,9 @@ The current header of .BTF.ext section::
__u32 line_info_len;
};
It is very similar to .BTF section. Instead of type/string section,
it contains func_info and line_info section. See :ref:`BPF_Prog_Load`
for details about func_info and line_info record format.
It is very similar to .BTF section. Instead of type/string section, it
contains func_info and line_info section. See :ref:`BPF_Prog_Load` for details
about func_info and line_info record format.
The func_info is organized as below.::
@ -622,9 +601,9 @@ The func_info is organized as below.::
btf_ext_info_sec for section #2 /* func_info for section #2 */
...
``func_info_rec_size`` specifies the size of ``bpf_func_info`` structure
when .BTF.ext is generated. ``btf_ext_info_sec``, defined below, is
a collection of func_info for each specific ELF section.::
``func_info_rec_size`` specifies the size of ``bpf_func_info`` structure when
.BTF.ext is generated. ``btf_ext_info_sec``, defined below, is a collection of
func_info for each specific ELF section.::
struct btf_ext_info_sec {
__u32 sec_name_off; /* offset to section name */
@ -642,14 +621,14 @@ The line_info is organized as below.::
btf_ext_info_sec for section #2 /* line_info for section #2 */
...
``line_info_rec_size`` specifies the size of ``bpf_line_info`` structure
when .BTF.ext is generated.
``line_info_rec_size`` specifies the size of ``bpf_line_info`` structure when
.BTF.ext is generated.
The interpretation of ``bpf_func_info->insn_off`` and
``bpf_line_info->insn_off`` is different between kernel API and ELF API.
For kernel API, the ``insn_off`` is the instruction offset in the unit
of ``struct bpf_insn``. For ELF API, the ``insn_off`` is the byte offset
from the beginning of section (``btf_ext_info_sec->sec_name_off``).
``bpf_line_info->insn_off`` is different between kernel API and ELF API. For
kernel API, the ``insn_off`` is the instruction offset in the unit of ``struct
bpf_insn``. For ELF API, the ``insn_off`` is the byte offset from the
beginning of section (``btf_ext_info_sec->sec_name_off``).
5. Using BTF
************
@ -657,10 +636,9 @@ from the beginning of section (``btf_ext_info_sec->sec_name_off``).
5.1 bpftool map pretty print
============================
With BTF, the map key/value can be printed based on fields rather than
simply raw bytes. This is especially
valuable for large structure or if your data structure
has bitfields. For example, for the following map,::
With BTF, the map key/value can be printed based on fields rather than simply
raw bytes. This is especially valuable for large structure or if your data
structure has bitfields. For example, for the following map,::
enum A { A1, A2, A3, A4, A5 };
typedef enum A ___A;
@ -700,9 +678,9 @@ bpftool is able to pretty print like below:
5.2 bpftool prog dump
=====================
The following is an example showing how func_info and line_info
can help prog dump with better kernel symbol names, function prototypes
and line information.::
The following is an example showing how func_info and line_info can help prog
dump with better kernel symbol names, function prototypes and line
information.::
$ bpftool prog dump jited pinned /sys/fs/bpf/test_btf_haskv
[...]
@ -734,7 +712,8 @@ and line information.::
5.3 Verifier Log
================
The following is an example of how line_info can help debugging verification failure.::
The following is an example of how line_info can help debugging verification
failure.::
/* The code at tools/testing/selftests/bpf/test_xdp_noinline.c
* is modified as below.
@ -763,8 +742,8 @@ You need latest pahole
https://git.kernel.org/pub/scm/devel/pahole/pahole.git/
or llvm (8.0 or later). The pahole acts as a dwarf2btf converter. It doesn't support .BTF.ext
and btf BTF_KIND_FUNC type yet. For example,::
or llvm (8.0 or later). The pahole acts as a dwarf2btf converter. It doesn't
support .BTF.ext and btf BTF_KIND_FUNC type yet. For example,::
-bash-4.4$ cat t.c
struct t {
@ -781,8 +760,9 @@ and btf BTF_KIND_FUNC type yet. For example,::
c type_id=2 bitfield_size=2 bits_offset=5
[2] INT int size=4 bit_offset=0 nr_bits=32 encoding=SIGNED
The llvm is able to generate .BTF and .BTF.ext directly with -g for bpf target only.
The assembly code (-S) is able to show the BTF encoding in assembly format.::
The llvm is able to generate .BTF and .BTF.ext directly with -g for bpf target
only. The assembly code (-S) is able to show the BTF encoding in assembly
format.::
-bash-4.4$ cat t2.c
typedef int __int32;