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910 lines
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ReStructuredText
=====================
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BPF Type Format (BTF)
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=====================
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1. Introduction
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***************
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BTF (BPF Type Format) is the metadata format which encodes the debug info
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related to BPF program/map. The name BTF was used initially to describe data
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types. The BTF was later extended to include function info for defined
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subroutines, and line info for source/line information.
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The debug info is used for map pretty print, function signature, etc. The
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function signature enables better bpf program/function kernel symbol. The line
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info helps generate source annotated translated byte code, jited code and
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verifier log.
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The BTF specification contains two parts,
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* BTF kernel API
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* BTF ELF file format
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The kernel API is the contract between user space and kernel. The kernel
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verifies the BTF info before using it. The ELF file format is a user space
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contract between ELF file and libbpf loader.
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The type and string sections are part of the BTF kernel API, describing the
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debug info (mostly types related) referenced by the bpf program. These two
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sections are discussed in details in :ref:`BTF_Type_String`.
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.. _BTF_Type_String:
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2. BTF Type and String Encoding
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*******************************
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The file ``include/uapi/linux/btf.h`` provides high-level definition of how
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types/strings are encoded.
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The beginning of data blob must be::
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struct btf_header {
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__u16 magic;
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__u8 version;
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__u8 flags;
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__u32 hdr_len;
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/* All offsets are in bytes relative to the end of this header */
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__u32 type_off; /* offset of type section */
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__u32 type_len; /* length of type section */
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__u32 str_off; /* offset of string section */
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__u32 str_len; /* length of string section */
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};
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The magic is ``0xeB9F``, which has different encoding for big and little
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endian systems, and can be used to test whether BTF is generated for big- or
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little-endian target. The ``btf_header`` is designed to be extensible with
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``hdr_len`` equal to ``sizeof(struct btf_header)`` when a data blob is
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generated.
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2.1 String Encoding
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===================
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The first string in the string section must be a null string. The rest of
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string table is a concatenation of other null-terminated strings.
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2.2 Type Encoding
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=================
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The type id ``0`` is reserved for ``void`` type. The type section is parsed
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sequentially and type id is assigned to each recognized type starting from id
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``1``. Currently, the following types are supported::
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#define BTF_KIND_INT 1 /* Integer */
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#define BTF_KIND_PTR 2 /* Pointer */
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#define BTF_KIND_ARRAY 3 /* Array */
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#define BTF_KIND_STRUCT 4 /* Struct */
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#define BTF_KIND_UNION 5 /* Union */
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#define BTF_KIND_ENUM 6 /* Enumeration */
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#define BTF_KIND_FWD 7 /* Forward */
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#define BTF_KIND_TYPEDEF 8 /* Typedef */
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#define BTF_KIND_VOLATILE 9 /* Volatile */
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#define BTF_KIND_CONST 10 /* Const */
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#define BTF_KIND_RESTRICT 11 /* Restrict */
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#define BTF_KIND_FUNC 12 /* Function */
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#define BTF_KIND_FUNC_PROTO 13 /* Function Proto */
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#define BTF_KIND_VAR 14 /* Variable */
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#define BTF_KIND_DATASEC 15 /* Section */
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Note that the type section encodes debug info, not just pure types.
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``BTF_KIND_FUNC`` is not a type, and it represents a defined subprogram.
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Each type contains the following common data::
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struct btf_type {
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__u32 name_off;
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/* "info" bits arrangement
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* bits 0-15: vlen (e.g. # of struct's members)
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* bits 16-23: unused
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* bits 24-27: kind (e.g. int, ptr, array...etc)
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* bits 28-30: unused
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* bit 31: kind_flag, currently used by
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* struct, union and fwd
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*/
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__u32 info;
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/* "size" is used by INT, ENUM, STRUCT and UNION.
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* "size" tells the size of the type it is describing.
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*
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* "type" is used by PTR, TYPEDEF, VOLATILE, CONST, RESTRICT,
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* FUNC and FUNC_PROTO.
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* "type" is a type_id referring to another type.
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*/
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union {
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__u32 size;
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__u32 type;
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};
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};
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For certain kinds, the common data are followed by kind-specific data. The
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``name_off`` in ``struct btf_type`` specifies the offset in the string table.
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The following sections detail encoding of each kind.
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2.2.1 BTF_KIND_INT
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~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: any valid offset
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_INT
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* ``info.vlen``: 0
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* ``size``: the size of the int type in bytes.
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``btf_type`` is followed by a ``u32`` with the following bits arrangement::
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#define BTF_INT_ENCODING(VAL) (((VAL) & 0x0f000000) >> 24)
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#define BTF_INT_OFFSET(VAL) (((VAL) & 0x00ff0000) >> 16)
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#define BTF_INT_BITS(VAL) ((VAL) & 0x000000ff)
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The ``BTF_INT_ENCODING`` has the following attributes::
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#define BTF_INT_SIGNED (1 << 0)
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#define BTF_INT_CHAR (1 << 1)
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#define BTF_INT_BOOL (1 << 2)
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The ``BTF_INT_ENCODING()`` provides extra information: signedness, char, or
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bool, for the int type. The char and bool encoding are mostly useful for
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pretty print. At most one encoding can be specified for the int type.
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The ``BTF_INT_BITS()`` specifies the number of actual bits held by this int
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type. For example, a 4-bit bitfield encodes ``BTF_INT_BITS()`` equals to 4.
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The ``btf_type.size * 8`` must be equal to or greater than ``BTF_INT_BITS()``
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for the type. The maximum value of ``BTF_INT_BITS()`` is 128.
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The ``BTF_INT_OFFSET()`` specifies the starting bit offset to calculate values
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for this int. For example, a bitfield struct member has:
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* btf member bit offset 100 from the start of the structure,
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* btf member pointing to an int type,
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* the int type has ``BTF_INT_OFFSET() = 2`` and ``BTF_INT_BITS() = 4``
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Then in the struct memory layout, this member will occupy ``4`` bits starting
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from bits ``100 + 2 = 102``.
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Alternatively, the bitfield struct member can be the following to access the
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same bits as the above:
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* btf member bit offset 102,
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* btf member pointing to an int type,
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* the int type has ``BTF_INT_OFFSET() = 0`` and ``BTF_INT_BITS() = 4``
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The original intention of ``BTF_INT_OFFSET()`` is to provide flexibility of
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bitfield encoding. Currently, both llvm and pahole generate
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``BTF_INT_OFFSET() = 0`` for all int types.
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2.2.2 BTF_KIND_PTR
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~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: 0
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_PTR
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* ``info.vlen``: 0
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* ``type``: the pointee type of the pointer
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No additional type data follow ``btf_type``.
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2.2.3 BTF_KIND_ARRAY
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~~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: 0
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_ARRAY
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* ``info.vlen``: 0
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* ``size/type``: 0, not used
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``btf_type`` is followed by one ``struct btf_array``::
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struct btf_array {
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__u32 type;
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__u32 index_type;
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__u32 nelems;
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};
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The ``struct btf_array`` encoding:
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* ``type``: the element type
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* ``index_type``: the index type
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* ``nelems``: the number of elements for this array (``0`` is also allowed).
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The ``index_type`` can be any regular int type (``u8``, ``u16``, ``u32``,
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``u64``, ``unsigned __int128``). The original design of including
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``index_type`` follows DWARF, which has an ``index_type`` for its array type.
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Currently in BTF, beyond type verification, the ``index_type`` is not used.
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The ``struct btf_array`` allows chaining through element type to represent
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multidimensional arrays. For example, for ``int a[5][6]``, the following type
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information illustrates the chaining:
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* [1]: int
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* [2]: array, ``btf_array.type = [1]``, ``btf_array.nelems = 6``
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* [3]: array, ``btf_array.type = [2]``, ``btf_array.nelems = 5``
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Currently, both pahole and llvm collapse multidimensional array into
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one-dimensional array, e.g., for ``a[5][6]``, the ``btf_array.nelems`` is
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equal to ``30``. This is because the original use case is map pretty print
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where the whole array is dumped out so one-dimensional array is enough. As
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more BTF usage is explored, pahole and llvm can be changed to generate proper
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chained representation for multidimensional arrays.
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2.2.4 BTF_KIND_STRUCT
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~~~~~~~~~~~~~~~~~~~~~
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2.2.5 BTF_KIND_UNION
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~~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: 0 or offset to a valid C identifier
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* ``info.kind_flag``: 0 or 1
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* ``info.kind``: BTF_KIND_STRUCT or BTF_KIND_UNION
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* ``info.vlen``: the number of struct/union members
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* ``info.size``: the size of the struct/union in bytes
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``btf_type`` is followed by ``info.vlen`` number of ``struct btf_member``.::
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struct btf_member {
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__u32 name_off;
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__u32 type;
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__u32 offset;
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};
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``struct btf_member`` encoding:
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* ``name_off``: offset to a valid C identifier
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* ``type``: the member type
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* ``offset``: <see below>
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If the type info ``kind_flag`` is not set, the offset contains only bit offset
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of the member. Note that the base type of the bitfield can only be int or enum
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type. If the bitfield size is 32, the base type can be either int or enum
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type. If the bitfield size is not 32, the base type must be int, and int type
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``BTF_INT_BITS()`` encodes the bitfield size.
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If the ``kind_flag`` is set, the ``btf_member.offset`` contains both member
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bitfield size and bit offset. The bitfield size and bit offset are calculated
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as below.::
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#define BTF_MEMBER_BITFIELD_SIZE(val) ((val) >> 24)
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#define BTF_MEMBER_BIT_OFFSET(val) ((val) & 0xffffff)
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In this case, if the base type is an int type, it must be a regular int type:
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* ``BTF_INT_OFFSET()`` must be 0.
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* ``BTF_INT_BITS()`` must be equal to ``{1,2,4,8,16} * 8``.
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The following kernel patch introduced ``kind_flag`` and explained why both
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modes exist:
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https://github.com/torvalds/linux/commit/9d5f9f701b1891466fb3dbb1806ad97716f95cc3#diff-fa650a64fdd3968396883d2fe8215ff3
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2.2.6 BTF_KIND_ENUM
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~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: 0 or offset to a valid C identifier
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_ENUM
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* ``info.vlen``: number of enum values
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* ``size``: 4
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``btf_type`` is followed by ``info.vlen`` number of ``struct btf_enum``.::
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struct btf_enum {
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__u32 name_off;
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__s32 val;
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};
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The ``btf_enum`` encoding:
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* ``name_off``: offset to a valid C identifier
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* ``val``: any value
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2.2.7 BTF_KIND_FWD
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~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: offset to a valid C identifier
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* ``info.kind_flag``: 0 for struct, 1 for union
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* ``info.kind``: BTF_KIND_FWD
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* ``info.vlen``: 0
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* ``type``: 0
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No additional type data follow ``btf_type``.
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2.2.8 BTF_KIND_TYPEDEF
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~~~~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: offset to a valid C identifier
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_TYPEDEF
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* ``info.vlen``: 0
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* ``type``: the type which can be referred by name at ``name_off``
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No additional type data follow ``btf_type``.
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2.2.9 BTF_KIND_VOLATILE
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~~~~~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: 0
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_VOLATILE
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* ``info.vlen``: 0
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* ``type``: the type with ``volatile`` qualifier
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No additional type data follow ``btf_type``.
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2.2.10 BTF_KIND_CONST
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~~~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: 0
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_CONST
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* ``info.vlen``: 0
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* ``type``: the type with ``const`` qualifier
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No additional type data follow ``btf_type``.
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2.2.11 BTF_KIND_RESTRICT
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~~~~~~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: 0
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_RESTRICT
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* ``info.vlen``: 0
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* ``type``: the type with ``restrict`` qualifier
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No additional type data follow ``btf_type``.
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2.2.12 BTF_KIND_FUNC
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~~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: offset to a valid C identifier
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_FUNC
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* ``info.vlen``: 0
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* ``type``: a BTF_KIND_FUNC_PROTO type
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No additional type data follow ``btf_type``.
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A BTF_KIND_FUNC defines not a type, but a subprogram (function) whose
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signature is defined by ``type``. The subprogram is thus an instance of that
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type. The BTF_KIND_FUNC may in turn be referenced by a func_info in the
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:ref:`BTF_Ext_Section` (ELF) or in the arguments to :ref:`BPF_Prog_Load`
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(ABI).
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2.2.13 BTF_KIND_FUNC_PROTO
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~~~~~~~~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: 0
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_FUNC_PROTO
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* ``info.vlen``: # of parameters
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* ``type``: the return type
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``btf_type`` is followed by ``info.vlen`` number of ``struct btf_param``.::
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struct btf_param {
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__u32 name_off;
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__u32 type;
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};
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If a BTF_KIND_FUNC_PROTO type is referred by a BTF_KIND_FUNC type, then
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``btf_param.name_off`` must point to a valid C identifier except for the
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possible last argument representing the variable argument. The btf_param.type
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refers to parameter type.
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If the function has variable arguments, the last parameter is encoded with
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``name_off = 0`` and ``type = 0``.
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2.2.14 BTF_KIND_VAR
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~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: offset to a valid C identifier
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_VAR
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* ``info.vlen``: 0
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* ``type``: the type of the variable
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``btf_type`` is followed by a single ``struct btf_variable`` with the
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following data::
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struct btf_var {
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__u32 linkage;
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};
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``struct btf_var`` encoding:
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* ``linkage``: currently only static variable 0, or globally allocated
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variable in ELF sections 1
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Not all type of global variables are supported by LLVM at this point.
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The following is currently available:
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* static variables with or without section attributes
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* global variables with section attributes
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The latter is for future extraction of map key/value type id's from a
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map definition.
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2.2.15 BTF_KIND_DATASEC
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~~~~~~~~~~~~~~~~~~~~~~~
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``struct btf_type`` encoding requirement:
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* ``name_off``: offset to a valid name associated with a variable or
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one of .data/.bss/.rodata
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* ``info.kind_flag``: 0
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* ``info.kind``: BTF_KIND_DATASEC
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* ``info.vlen``: # of variables
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* ``size``: total section size in bytes (0 at compilation time, patched
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to actual size by BPF loaders such as libbpf)
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``btf_type`` is followed by ``info.vlen`` number of ``struct btf_var_secinfo``.::
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struct btf_var_secinfo {
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__u32 type;
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__u32 offset;
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__u32 size;
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};
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``struct btf_var_secinfo`` encoding:
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* ``type``: the type of the BTF_KIND_VAR variable
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* ``offset``: the in-section offset of the variable
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* ``size``: the size of the variable in bytes
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3. BTF Kernel API
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*****************
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The following bpf syscall command involves BTF:
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|
* BPF_BTF_LOAD: load a blob of BTF data into kernel
|
|
* BPF_MAP_CREATE: map creation with btf key and value type info.
|
|
* BPF_PROG_LOAD: prog load with btf function and line info.
|
|
* BPF_BTF_GET_FD_BY_ID: get a btf fd
|
|
* BPF_OBJ_GET_INFO_BY_FD: btf, func_info, line_info
|
|
and other btf related info are returned.
|
|
|
|
The workflow typically looks like:
|
|
::
|
|
|
|
Application:
|
|
BPF_BTF_LOAD
|
|
|
|
|
v
|
|
BPF_MAP_CREATE and BPF_PROG_LOAD
|
|
|
|
|
V
|
|
......
|
|
|
|
Introspection tool:
|
|
......
|
|
BPF_{PROG,MAP}_GET_NEXT_ID (get prog/map id's)
|
|
|
|
|
V
|
|
BPF_{PROG,MAP}_GET_FD_BY_ID (get a prog/map fd)
|
|
|
|
|
V
|
|
BPF_OBJ_GET_INFO_BY_FD (get bpf_prog_info/bpf_map_info with btf_id)
|
|
| |
|
|
V |
|
|
BPF_BTF_GET_FD_BY_ID (get btf_fd) |
|
|
| |
|
|
V |
|
|
BPF_OBJ_GET_INFO_BY_FD (get btf) |
|
|
| |
|
|
V V
|
|
pretty print types, dump func signatures and line info, etc.
|
|
|
|
|
|
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.
|
|
|
|
3.2 BPF_MAP_CREATE
|
|
==================
|
|
|
|
A map can be created with ``btf_fd`` and specified key/value type id.::
|
|
|
|
__u32 btf_fd; /* fd pointing to a BTF type data */
|
|
__u32 btf_key_type_id; /* BTF type_id of the key */
|
|
__u32 btf_value_type_id; /* BTF type_id of the value */
|
|
|
|
In libbpf, the map can be defined with extra annotation like below:
|
|
::
|
|
|
|
struct bpf_map_def SEC("maps") btf_map = {
|
|
.type = BPF_MAP_TYPE_ARRAY,
|
|
.key_size = sizeof(int),
|
|
.value_size = sizeof(struct ipv_counts),
|
|
.max_entries = 4,
|
|
};
|
|
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.
|
|
|
|
.. _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:
|
|
::
|
|
|
|
__u32 insn_cnt;
|
|
__aligned_u64 insns;
|
|
......
|
|
__u32 prog_btf_fd; /* fd pointing to BTF type data */
|
|
__u32 func_info_rec_size; /* userspace bpf_func_info size */
|
|
__aligned_u64 func_info; /* func info */
|
|
__u32 func_info_cnt; /* number of bpf_func_info records */
|
|
__u32 line_info_rec_size; /* userspace bpf_line_info size */
|
|
__aligned_u64 line_info; /* line info */
|
|
__u32 line_info_cnt; /* number of bpf_line_info records */
|
|
|
|
The func_info and line_info are an array of below, respectively.::
|
|
|
|
struct bpf_func_info {
|
|
__u32 insn_off; /* [0, insn_cnt - 1] */
|
|
__u32 type_id; /* pointing to a BTF_KIND_FUNC type */
|
|
};
|
|
struct bpf_line_info {
|
|
__u32 insn_off; /* [0, insn_cnt - 1] */
|
|
__u32 file_name_off; /* offset to string table for the filename */
|
|
__u32 line_off; /* offset to string table for the source line */
|
|
__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.
|
|
|
|
Below are requirements for func_info:
|
|
* func_info[0].insn_off must be 0.
|
|
* the func_info insn_off is in strictly increasing order and matches
|
|
bpf func boundaries.
|
|
|
|
Below are requirements for line_info:
|
|
* the first insn in each func must have a line_info record pointing to it.
|
|
* the line_info insn_off is in strictly increasing order.
|
|
|
|
For line_info, the line number and column number are defined as below:
|
|
::
|
|
|
|
#define BPF_LINE_INFO_LINE_NUM(line_col) ((line_col) >> 10)
|
|
#define BPF_LINE_INFO_LINE_COL(line_col) ((line_col) & 0x3ff)
|
|
|
|
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.
|
|
|
|
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
|
|
===============================
|
|
|
|
An introspection tool cannot use id to get details about program or maps.
|
|
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.
|
|
|
|
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 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.
|
|
|
|
4. ELF File Format Interface
|
|
****************************
|
|
|
|
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`.
|
|
|
|
.. _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 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::
|
|
|
|
struct btf_ext_header {
|
|
__u16 magic;
|
|
__u8 version;
|
|
__u8 flags;
|
|
__u32 hdr_len;
|
|
|
|
/* All offsets are in bytes relative to the end of this header */
|
|
__u32 func_info_off;
|
|
__u32 func_info_len;
|
|
__u32 line_info_off;
|
|
__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.
|
|
|
|
The func_info is organized as below.::
|
|
|
|
func_info_rec_size
|
|
btf_ext_info_sec for section #1 /* func_info for section #1 */
|
|
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.::
|
|
|
|
struct btf_ext_info_sec {
|
|
__u32 sec_name_off; /* offset to section name */
|
|
__u32 num_info;
|
|
/* Followed by num_info * record_size number of bytes */
|
|
__u8 data[0];
|
|
};
|
|
|
|
Here, num_info must be greater than 0.
|
|
|
|
The line_info is organized as below.::
|
|
|
|
line_info_rec_size
|
|
btf_ext_info_sec for section #1 /* line_info for section #1 */
|
|
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.
|
|
|
|
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``).
|
|
|
|
5. Using BTF
|
|
************
|
|
|
|
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,::
|
|
|
|
enum A { A1, A2, A3, A4, A5 };
|
|
typedef enum A ___A;
|
|
struct tmp_t {
|
|
char a1:4;
|
|
int a2:4;
|
|
int :4;
|
|
__u32 a3:4;
|
|
int b;
|
|
___A b1:4;
|
|
enum A b2:4;
|
|
};
|
|
struct bpf_map_def SEC("maps") tmpmap = {
|
|
.type = BPF_MAP_TYPE_ARRAY,
|
|
.key_size = sizeof(__u32),
|
|
.value_size = sizeof(struct tmp_t),
|
|
.max_entries = 1,
|
|
};
|
|
BPF_ANNOTATE_KV_PAIR(tmpmap, int, struct tmp_t);
|
|
|
|
bpftool is able to pretty print like below:
|
|
::
|
|
|
|
[{
|
|
"key": 0,
|
|
"value": {
|
|
"a1": 0x2,
|
|
"a2": 0x4,
|
|
"a3": 0x6,
|
|
"b": 7,
|
|
"b1": 0x8,
|
|
"b2": 0xa
|
|
}
|
|
}
|
|
]
|
|
|
|
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.::
|
|
|
|
$ bpftool prog dump jited pinned /sys/fs/bpf/test_btf_haskv
|
|
[...]
|
|
int test_long_fname_2(struct dummy_tracepoint_args * arg):
|
|
bpf_prog_44a040bf25481309_test_long_fname_2:
|
|
; static int test_long_fname_2(struct dummy_tracepoint_args *arg)
|
|
0: push %rbp
|
|
1: mov %rsp,%rbp
|
|
4: sub $0x30,%rsp
|
|
b: sub $0x28,%rbp
|
|
f: mov %rbx,0x0(%rbp)
|
|
13: mov %r13,0x8(%rbp)
|
|
17: mov %r14,0x10(%rbp)
|
|
1b: mov %r15,0x18(%rbp)
|
|
1f: xor %eax,%eax
|
|
21: mov %rax,0x20(%rbp)
|
|
25: xor %esi,%esi
|
|
; int key = 0;
|
|
27: mov %esi,-0x4(%rbp)
|
|
; if (!arg->sock)
|
|
2a: mov 0x8(%rdi),%rdi
|
|
; if (!arg->sock)
|
|
2e: cmp $0x0,%rdi
|
|
32: je 0x0000000000000070
|
|
34: mov %rbp,%rsi
|
|
; counts = bpf_map_lookup_elem(&btf_map, &key);
|
|
[...]
|
|
|
|
5.3 Verifier Log
|
|
================
|
|
|
|
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.
|
|
*/
|
|
data = (void *)(long)xdp->data;
|
|
data_end = (void *)(long)xdp->data_end;
|
|
/*
|
|
if (data + 4 > data_end)
|
|
return XDP_DROP;
|
|
*/
|
|
*(u32 *)data = dst->dst;
|
|
|
|
$ bpftool prog load ./test_xdp_noinline.o /sys/fs/bpf/test_xdp_noinline type xdp
|
|
; data = (void *)(long)xdp->data;
|
|
224: (79) r2 = *(u64 *)(r10 -112)
|
|
225: (61) r2 = *(u32 *)(r2 +0)
|
|
; *(u32 *)data = dst->dst;
|
|
226: (63) *(u32 *)(r2 +0) = r1
|
|
invalid access to packet, off=0 size=4, R2(id=0,off=0,r=0)
|
|
R2 offset is outside of the packet
|
|
|
|
6. BTF Generation
|
|
*****************
|
|
|
|
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,::
|
|
|
|
-bash-4.4$ cat t.c
|
|
struct t {
|
|
int a:2;
|
|
int b:3;
|
|
int c:2;
|
|
} g;
|
|
-bash-4.4$ gcc -c -O2 -g t.c
|
|
-bash-4.4$ pahole -JV t.o
|
|
File t.o:
|
|
[1] STRUCT t kind_flag=1 size=4 vlen=3
|
|
a type_id=2 bitfield_size=2 bits_offset=0
|
|
b type_id=2 bitfield_size=3 bits_offset=2
|
|
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.::
|
|
|
|
-bash-4.4$ cat t2.c
|
|
typedef int __int32;
|
|
struct t2 {
|
|
int a2;
|
|
int (*f2)(char q1, __int32 q2, ...);
|
|
int (*f3)();
|
|
} g2;
|
|
int main() { return 0; }
|
|
int test() { return 0; }
|
|
-bash-4.4$ clang -c -g -O2 -target bpf t2.c
|
|
-bash-4.4$ readelf -S t2.o
|
|
......
|
|
[ 8] .BTF PROGBITS 0000000000000000 00000247
|
|
000000000000016e 0000000000000000 0 0 1
|
|
[ 9] .BTF.ext PROGBITS 0000000000000000 000003b5
|
|
0000000000000060 0000000000000000 0 0 1
|
|
[10] .rel.BTF.ext REL 0000000000000000 000007e0
|
|
0000000000000040 0000000000000010 16 9 8
|
|
......
|
|
-bash-4.4$ clang -S -g -O2 -target bpf t2.c
|
|
-bash-4.4$ cat t2.s
|
|
......
|
|
.section .BTF,"",@progbits
|
|
.short 60319 # 0xeb9f
|
|
.byte 1
|
|
.byte 0
|
|
.long 24
|
|
.long 0
|
|
.long 220
|
|
.long 220
|
|
.long 122
|
|
.long 0 # BTF_KIND_FUNC_PROTO(id = 1)
|
|
.long 218103808 # 0xd000000
|
|
.long 2
|
|
.long 83 # BTF_KIND_INT(id = 2)
|
|
.long 16777216 # 0x1000000
|
|
.long 4
|
|
.long 16777248 # 0x1000020
|
|
......
|
|
.byte 0 # string offset=0
|
|
.ascii ".text" # string offset=1
|
|
.byte 0
|
|
.ascii "/home/yhs/tmp-pahole/t2.c" # string offset=7
|
|
.byte 0
|
|
.ascii "int main() { return 0; }" # string offset=33
|
|
.byte 0
|
|
.ascii "int test() { return 0; }" # string offset=58
|
|
.byte 0
|
|
.ascii "int" # string offset=83
|
|
......
|
|
.section .BTF.ext,"",@progbits
|
|
.short 60319 # 0xeb9f
|
|
.byte 1
|
|
.byte 0
|
|
.long 24
|
|
.long 0
|
|
.long 28
|
|
.long 28
|
|
.long 44
|
|
.long 8 # FuncInfo
|
|
.long 1 # FuncInfo section string offset=1
|
|
.long 2
|
|
.long .Lfunc_begin0
|
|
.long 3
|
|
.long .Lfunc_begin1
|
|
.long 5
|
|
.long 16 # LineInfo
|
|
.long 1 # LineInfo section string offset=1
|
|
.long 2
|
|
.long .Ltmp0
|
|
.long 7
|
|
.long 33
|
|
.long 7182 # Line 7 Col 14
|
|
.long .Ltmp3
|
|
.long 7
|
|
.long 58
|
|
.long 8206 # Line 8 Col 14
|
|
|
|
7. Testing
|
|
**********
|
|
|
|
Kernel bpf selftest `test_btf.c` provides extensive set of BTF-related tests.
|