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author | Andrii Nakryiko <andriin@fb.com> | 2019-02-28 17:12:20 -0800 |
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committer | Daniel Borkmann <daniel@iogearbox.net> | 2019-03-02 00:40:04 +0100 |
commit | 9ab5305dbe3ffcd146852e28aa76a917e45c7541 (patch) | |
tree | a7adf548a4d183b5321ba8dc6a9c02e9a1ae2629 /Documentation/bpf | |
parent | 5efc529fb428e042c08a598b9afc5c5e2c600d74 (diff) | |
download | linux-9ab5305dbe3ffcd146852e28aa76a917e45c7541.tar.bz2 |
docs/btf: reflow text to fill up to 78 characters
Reflow paragraphs to more fully and evenly fill 78 character lines.
Signed-off-by: Andrii Nakryiko <andriin@fb.com>
Acked-by: Yonghong Song <yhs@fb.com>
Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
Diffstat (limited to 'Documentation/bpf')
-rw-r--r-- | Documentation/bpf/btf.rst | 300 |
1 files changed, 140 insertions, 160 deletions
diff --git a/Documentation/bpf/btf.rst b/Documentation/bpf/btf.rst index 1d761f1c5b2b..9a60a5d60e38 100644 --- a/Documentation/bpf/btf.rst +++ b/Documentation/bpf/btf.rst @@ -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. - -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. +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 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_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_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_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; |