mirror of
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3888fa134e
scripts/documentation-file-ref-check reports warnings for (valid) cross-links
of form:
:ref:`Documentation/bpf/btf <BTF_Ext_Section>`
Adding extension to the file name helps to avoid the warning, e.g:
:ref:`Documentation/bpf/btf.rst <BTF_Ext_Section>`
Fixes: be4033d360
("docs/bpf: Add description for CO-RE relocations")
Reported-by: kernel test robot <lkp@intel.com>
Signed-off-by: Eduard Zingerman <eddyz87@gmail.com>
Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
Acked-by: Jiri Olsa <jolsa@kernel.org>
Closes: https://lore.kernel.org/oe-kbuild-all/202309010804.G3MpXo59-lkp@intel.com
Link: https://lore.kernel.org/bpf/20230901125935.487972-1-eddyz87@gmail.com
547 lines
21 KiB
ReStructuredText
547 lines
21 KiB
ReStructuredText
.. SPDX-License-Identifier: (LGPL-2.1 OR BSD-2-Clause)
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====================
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BPF LLVM Relocations
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====================
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This document describes LLVM BPF backend relocation types.
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Relocation Record
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=================
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LLVM BPF backend records each relocation with the following 16-byte
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ELF structure::
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typedef struct
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{
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Elf64_Addr r_offset; // Offset from the beginning of section.
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Elf64_Xword r_info; // Relocation type and symbol index.
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} Elf64_Rel;
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For example, for the following code::
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int g1 __attribute__((section("sec")));
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int g2 __attribute__((section("sec")));
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static volatile int l1 __attribute__((section("sec")));
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static volatile int l2 __attribute__((section("sec")));
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int test() {
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return g1 + g2 + l1 + l2;
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}
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Compiled with ``clang --target=bpf -O2 -c test.c``, the following is
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the code with ``llvm-objdump -dr test.o``::
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0: 18 01 00 00 00 00 00 00 00 00 00 00 00 00 00 00 r1 = 0 ll
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0000000000000000: R_BPF_64_64 g1
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2: 61 11 00 00 00 00 00 00 r1 = *(u32 *)(r1 + 0)
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3: 18 02 00 00 00 00 00 00 00 00 00 00 00 00 00 00 r2 = 0 ll
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0000000000000018: R_BPF_64_64 g2
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5: 61 20 00 00 00 00 00 00 r0 = *(u32 *)(r2 + 0)
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6: 0f 10 00 00 00 00 00 00 r0 += r1
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7: 18 01 00 00 08 00 00 00 00 00 00 00 00 00 00 00 r1 = 8 ll
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0000000000000038: R_BPF_64_64 sec
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9: 61 11 00 00 00 00 00 00 r1 = *(u32 *)(r1 + 0)
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10: 0f 10 00 00 00 00 00 00 r0 += r1
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11: 18 01 00 00 0c 00 00 00 00 00 00 00 00 00 00 00 r1 = 12 ll
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0000000000000058: R_BPF_64_64 sec
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13: 61 11 00 00 00 00 00 00 r1 = *(u32 *)(r1 + 0)
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14: 0f 10 00 00 00 00 00 00 r0 += r1
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15: 95 00 00 00 00 00 00 00 exit
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There are four relocations in the above for four ``LD_imm64`` instructions.
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The following ``llvm-readelf -r test.o`` shows the binary values of the four
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relocations::
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Relocation section '.rel.text' at offset 0x190 contains 4 entries:
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Offset Info Type Symbol's Value Symbol's Name
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0000000000000000 0000000600000001 R_BPF_64_64 0000000000000000 g1
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0000000000000018 0000000700000001 R_BPF_64_64 0000000000000004 g2
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0000000000000038 0000000400000001 R_BPF_64_64 0000000000000000 sec
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0000000000000058 0000000400000001 R_BPF_64_64 0000000000000000 sec
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Each relocation is represented by ``Offset`` (8 bytes) and ``Info`` (8 bytes).
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For example, the first relocation corresponds to the first instruction
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(Offset 0x0) and the corresponding ``Info`` indicates the relocation type
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of ``R_BPF_64_64`` (type 1) and the entry in the symbol table (entry 6).
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The following is the symbol table with ``llvm-readelf -s test.o``::
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Symbol table '.symtab' contains 8 entries:
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Num: Value Size Type Bind Vis Ndx Name
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0: 0000000000000000 0 NOTYPE LOCAL DEFAULT UND
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1: 0000000000000000 0 FILE LOCAL DEFAULT ABS test.c
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2: 0000000000000008 4 OBJECT LOCAL DEFAULT 4 l1
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3: 000000000000000c 4 OBJECT LOCAL DEFAULT 4 l2
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4: 0000000000000000 0 SECTION LOCAL DEFAULT 4 sec
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5: 0000000000000000 128 FUNC GLOBAL DEFAULT 2 test
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6: 0000000000000000 4 OBJECT GLOBAL DEFAULT 4 g1
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7: 0000000000000004 4 OBJECT GLOBAL DEFAULT 4 g2
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The 6th entry is global variable ``g1`` with value 0.
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Similarly, the second relocation is at ``.text`` offset ``0x18``, instruction 3,
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has a type of ``R_BPF_64_64`` and refers to entry 7 in the symbol table.
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The second relocation resolves to global variable ``g2`` which has a symbol
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value 4. The symbol value represents the offset from the start of ``.data``
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section where the initial value of the global variable ``g2`` is stored.
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The third and fourth relocations refer to static variables ``l1``
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and ``l2``. From the ``.rel.text`` section above, it is not clear
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to which symbols they really refer as they both refer to
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symbol table entry 4, symbol ``sec``, which has ``STT_SECTION`` type
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and represents a section. So for a static variable or function,
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the section offset is written to the original insn
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buffer, which is called ``A`` (addend). Looking at
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above insn ``7`` and ``11``, they have section offset ``8`` and ``12``.
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From symbol table, we can find that they correspond to entries ``2``
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and ``3`` for ``l1`` and ``l2``.
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In general, the ``A`` is 0 for global variables and functions,
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and is the section offset or some computation result based on
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section offset for static variables/functions. The non-section-offset
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case refers to function calls. See below for more details.
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Different Relocation Types
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==========================
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Six relocation types are supported. The following is an overview and
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``S`` represents the value of the symbol in the symbol table::
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Enum ELF Reloc Type Description BitSize Offset Calculation
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0 R_BPF_NONE None
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1 R_BPF_64_64 ld_imm64 insn 32 r_offset + 4 S + A
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2 R_BPF_64_ABS64 normal data 64 r_offset S + A
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3 R_BPF_64_ABS32 normal data 32 r_offset S + A
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4 R_BPF_64_NODYLD32 .BTF[.ext] data 32 r_offset S + A
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10 R_BPF_64_32 call insn 32 r_offset + 4 (S + A) / 8 - 1
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For example, ``R_BPF_64_64`` relocation type is used for ``ld_imm64`` instruction.
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The actual to-be-relocated data (0 or section offset)
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is stored at ``r_offset + 4`` and the read/write
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data bitsize is 32 (4 bytes). The relocation can be resolved with
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the symbol value plus implicit addend. Note that the ``BitSize`` is 32 which
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means the section offset must be less than or equal to ``UINT32_MAX`` and this
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is enforced by LLVM BPF backend.
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In another case, ``R_BPF_64_ABS64`` relocation type is used for normal 64-bit data.
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The actual to-be-relocated data is stored at ``r_offset`` and the read/write data
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bitsize is 64 (8 bytes). The relocation can be resolved with
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the symbol value plus implicit addend.
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Both ``R_BPF_64_ABS32`` and ``R_BPF_64_NODYLD32`` types are for 32-bit data.
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But ``R_BPF_64_NODYLD32`` specifically refers to relocations in ``.BTF`` and
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``.BTF.ext`` sections. For cases like bcc where llvm ``ExecutionEngine RuntimeDyld``
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is involved, ``R_BPF_64_NODYLD32`` types of relocations should not be resolved
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to actual function/variable address. Otherwise, ``.BTF`` and ``.BTF.ext``
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become unusable by bcc and kernel.
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Type ``R_BPF_64_32`` is used for call instruction. The call target section
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offset is stored at ``r_offset + 4`` (32bit) and calculated as
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``(S + A) / 8 - 1``.
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Examples
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========
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Types ``R_BPF_64_64`` and ``R_BPF_64_32`` are used to resolve ``ld_imm64``
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and ``call`` instructions. For example::
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__attribute__((noinline)) __attribute__((section("sec1")))
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int gfunc(int a, int b) {
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return a * b;
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}
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static __attribute__((noinline)) __attribute__((section("sec1")))
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int lfunc(int a, int b) {
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return a + b;
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}
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int global __attribute__((section("sec2")));
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int test(int a, int b) {
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return gfunc(a, b) + lfunc(a, b) + global;
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}
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Compiled with ``clang --target=bpf -O2 -c test.c``, we will have
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following code with `llvm-objdump -dr test.o``::
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Disassembly of section .text:
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0000000000000000 <test>:
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0: bf 26 00 00 00 00 00 00 r6 = r2
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1: bf 17 00 00 00 00 00 00 r7 = r1
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2: 85 10 00 00 ff ff ff ff call -1
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0000000000000010: R_BPF_64_32 gfunc
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3: bf 08 00 00 00 00 00 00 r8 = r0
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4: bf 71 00 00 00 00 00 00 r1 = r7
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5: bf 62 00 00 00 00 00 00 r2 = r6
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6: 85 10 00 00 02 00 00 00 call 2
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0000000000000030: R_BPF_64_32 sec1
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7: 0f 80 00 00 00 00 00 00 r0 += r8
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8: 18 01 00 00 00 00 00 00 00 00 00 00 00 00 00 00 r1 = 0 ll
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0000000000000040: R_BPF_64_64 global
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10: 61 11 00 00 00 00 00 00 r1 = *(u32 *)(r1 + 0)
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11: 0f 10 00 00 00 00 00 00 r0 += r1
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12: 95 00 00 00 00 00 00 00 exit
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Disassembly of section sec1:
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0000000000000000 <gfunc>:
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0: bf 20 00 00 00 00 00 00 r0 = r2
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1: 2f 10 00 00 00 00 00 00 r0 *= r1
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2: 95 00 00 00 00 00 00 00 exit
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0000000000000018 <lfunc>:
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3: bf 20 00 00 00 00 00 00 r0 = r2
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4: 0f 10 00 00 00 00 00 00 r0 += r1
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5: 95 00 00 00 00 00 00 00 exit
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The first relocation corresponds to ``gfunc(a, b)`` where ``gfunc`` has a value of 0,
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so the ``call`` instruction offset is ``(0 + 0)/8 - 1 = -1``.
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The second relocation corresponds to ``lfunc(a, b)`` where ``lfunc`` has a section
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offset ``0x18``, so the ``call`` instruction offset is ``(0 + 0x18)/8 - 1 = 2``.
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The third relocation corresponds to ld_imm64 of ``global``, which has a section
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offset ``0``.
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The following is an example to show how R_BPF_64_ABS64 could be generated::
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int global() { return 0; }
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struct t { void *g; } gbl = { global };
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Compiled with ``clang --target=bpf -O2 -g -c test.c``, we will see a
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relocation below in ``.data`` section with command
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``llvm-readelf -r test.o``::
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Relocation section '.rel.data' at offset 0x458 contains 1 entries:
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Offset Info Type Symbol's Value Symbol's Name
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0000000000000000 0000000700000002 R_BPF_64_ABS64 0000000000000000 global
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The relocation says the first 8-byte of ``.data`` section should be
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filled with address of ``global`` variable.
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With ``llvm-readelf`` output, we can see that dwarf sections have a bunch of
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``R_BPF_64_ABS32`` and ``R_BPF_64_ABS64`` relocations::
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Relocation section '.rel.debug_info' at offset 0x468 contains 13 entries:
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Offset Info Type Symbol's Value Symbol's Name
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0000000000000006 0000000300000003 R_BPF_64_ABS32 0000000000000000 .debug_abbrev
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000000000000000c 0000000400000003 R_BPF_64_ABS32 0000000000000000 .debug_str
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0000000000000012 0000000400000003 R_BPF_64_ABS32 0000000000000000 .debug_str
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0000000000000016 0000000600000003 R_BPF_64_ABS32 0000000000000000 .debug_line
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000000000000001a 0000000400000003 R_BPF_64_ABS32 0000000000000000 .debug_str
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000000000000001e 0000000200000002 R_BPF_64_ABS64 0000000000000000 .text
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000000000000002b 0000000400000003 R_BPF_64_ABS32 0000000000000000 .debug_str
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0000000000000037 0000000800000002 R_BPF_64_ABS64 0000000000000000 gbl
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0000000000000040 0000000400000003 R_BPF_64_ABS32 0000000000000000 .debug_str
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......
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The .BTF/.BTF.ext sections has R_BPF_64_NODYLD32 relocations::
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Relocation section '.rel.BTF' at offset 0x538 contains 1 entries:
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Offset Info Type Symbol's Value Symbol's Name
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0000000000000084 0000000800000004 R_BPF_64_NODYLD32 0000000000000000 gbl
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Relocation section '.rel.BTF.ext' at offset 0x548 contains 2 entries:
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Offset Info Type Symbol's Value Symbol's Name
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000000000000002c 0000000200000004 R_BPF_64_NODYLD32 0000000000000000 .text
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0000000000000040 0000000200000004 R_BPF_64_NODYLD32 0000000000000000 .text
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.. _btf-co-re-relocations:
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=================
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CO-RE Relocations
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=================
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From object file point of view CO-RE mechanism is implemented as a set
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of CO-RE specific relocation records. These relocation records are not
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related to ELF relocations and are encoded in .BTF.ext section.
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See :ref:`Documentation/bpf/btf.rst <BTF_Ext_Section>` for more
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information on .BTF.ext structure.
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CO-RE relocations are applied to BPF instructions to update immediate
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or offset fields of the instruction at load time with information
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relevant for target kernel.
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Field to patch is selected basing on the instruction class:
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* For BPF_ALU, BPF_ALU64, BPF_LD `immediate` field is patched;
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* For BPF_LDX, BPF_STX, BPF_ST `offset` field is patched;
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* BPF_JMP, BPF_JMP32 instructions **should not** be patched.
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Relocation kinds
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================
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There are several kinds of CO-RE relocations that could be split in
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three groups:
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* Field-based - patch instruction with field related information, e.g.
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change offset field of the BPF_LDX instruction to reflect offset
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of a specific structure field in the target kernel.
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* Type-based - patch instruction with type related information, e.g.
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change immediate field of the BPF_ALU move instruction to 0 or 1 to
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reflect if specific type is present in the target kernel.
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* Enum-based - patch instruction with enum related information, e.g.
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change immediate field of the BPF_LD_IMM64 instruction to reflect
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value of a specific enum literal in the target kernel.
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The complete list of relocation kinds is represented by the following enum:
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.. code-block:: c
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enum bpf_core_relo_kind {
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BPF_CORE_FIELD_BYTE_OFFSET = 0, /* field byte offset */
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BPF_CORE_FIELD_BYTE_SIZE = 1, /* field size in bytes */
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BPF_CORE_FIELD_EXISTS = 2, /* field existence in target kernel */
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BPF_CORE_FIELD_SIGNED = 3, /* field signedness (0 - unsigned, 1 - signed) */
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BPF_CORE_FIELD_LSHIFT_U64 = 4, /* bitfield-specific left bitshift */
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BPF_CORE_FIELD_RSHIFT_U64 = 5, /* bitfield-specific right bitshift */
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BPF_CORE_TYPE_ID_LOCAL = 6, /* type ID in local BPF object */
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BPF_CORE_TYPE_ID_TARGET = 7, /* type ID in target kernel */
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BPF_CORE_TYPE_EXISTS = 8, /* type existence in target kernel */
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BPF_CORE_TYPE_SIZE = 9, /* type size in bytes */
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BPF_CORE_ENUMVAL_EXISTS = 10, /* enum value existence in target kernel */
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BPF_CORE_ENUMVAL_VALUE = 11, /* enum value integer value */
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BPF_CORE_TYPE_MATCHES = 12, /* type match in target kernel */
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};
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Notes:
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* ``BPF_CORE_FIELD_LSHIFT_U64`` and ``BPF_CORE_FIELD_RSHIFT_U64`` are
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supposed to be used to read bitfield values using the following
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algorithm:
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.. code-block:: c
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// To read bitfield ``f`` from ``struct s``
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is_signed = relo(s->f, BPF_CORE_FIELD_SIGNED)
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off = relo(s->f, BPF_CORE_FIELD_BYTE_OFFSET)
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sz = relo(s->f, BPF_CORE_FIELD_BYTE_SIZE)
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l = relo(s->f, BPF_CORE_FIELD_LSHIFT_U64)
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r = relo(s->f, BPF_CORE_FIELD_RSHIFT_U64)
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// define ``v`` as signed or unsigned integer of size ``sz``
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v = *({s|u}<sz> *)((void *)s + off)
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v <<= l
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v >>= r
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* The ``BPF_CORE_TYPE_MATCHES`` queries matching relation, defined as
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follows:
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* for integers: types match if size and signedness match;
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* for arrays & pointers: target types are recursively matched;
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* for structs & unions:
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* local members need to exist in target with the same name;
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* for each member we recursively check match unless it is already behind a
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pointer, in which case we only check matching names and compatible kind;
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* for enums:
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* local variants have to have a match in target by symbolic name (but not
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numeric value);
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* size has to match (but enum may match enum64 and vice versa);
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* for function pointers:
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* number and position of arguments in local type has to match target;
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* for each argument and the return value we recursively check match.
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CO-RE Relocation Record
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=======================
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Relocation record is encoded as the following structure:
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.. code-block:: c
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struct bpf_core_relo {
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__u32 insn_off;
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__u32 type_id;
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__u32 access_str_off;
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enum bpf_core_relo_kind kind;
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};
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* ``insn_off`` - instruction offset (in bytes) within a code section
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associated with this relocation;
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* ``type_id`` - BTF type ID of the "root" (containing) entity of a
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relocatable type or field;
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* ``access_str_off`` - offset into corresponding .BTF string section.
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String interpretation depends on specific relocation kind:
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* for field-based relocations, string encodes an accessed field using
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a sequence of field and array indices, separated by colon (:). It's
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conceptually very close to LLVM's `getelementptr <GEP_>`_ instruction's
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arguments for identifying offset to a field. For example, consider the
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following C code:
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.. code-block:: c
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struct sample {
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int a;
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int b;
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struct { int c[10]; };
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} __attribute__((preserve_access_index));
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struct sample *s;
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* Access to ``s[0].a`` would be encoded as ``0:0``:
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* ``0``: first element of ``s`` (as if ``s`` is an array);
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* ``0``: index of field ``a`` in ``struct sample``.
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* Access to ``s->a`` would be encoded as ``0:0`` as well.
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* Access to ``s->b`` would be encoded as ``0:1``:
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* ``0``: first element of ``s``;
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* ``1``: index of field ``b`` in ``struct sample``.
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* Access to ``s[1].c[5]`` would be encoded as ``1:2:0:5``:
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* ``1``: second element of ``s``;
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* ``2``: index of anonymous structure field in ``struct sample``;
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* ``0``: index of field ``c`` in anonymous structure;
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* ``5``: access to array element #5.
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* for type-based relocations, string is expected to be just "0";
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* for enum value-based relocations, string contains an index of enum
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value within its enum type;
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* ``kind`` - one of ``enum bpf_core_relo_kind``.
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.. _GEP: https://llvm.org/docs/LangRef.html#getelementptr-instruction
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.. _btf_co_re_relocation_examples:
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CO-RE Relocation Examples
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=========================
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For the following C code:
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.. code-block:: c
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struct foo {
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int a;
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int b;
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unsigned c:15;
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} __attribute__((preserve_access_index));
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enum bar { U, V };
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With the following BTF definitions:
|
|
|
|
.. code-block::
|
|
|
|
...
|
|
[2] STRUCT 'foo' size=8 vlen=2
|
|
'a' type_id=3 bits_offset=0
|
|
'b' type_id=3 bits_offset=32
|
|
'c' type_id=4 bits_offset=64 bitfield_size=15
|
|
[3] INT 'int' size=4 bits_offset=0 nr_bits=32 encoding=SIGNED
|
|
[4] INT 'unsigned int' size=4 bits_offset=0 nr_bits=32 encoding=(none)
|
|
...
|
|
[16] ENUM 'bar' encoding=UNSIGNED size=4 vlen=2
|
|
'U' val=0
|
|
'V' val=1
|
|
|
|
Field offset relocations are generated automatically when
|
|
``__attribute__((preserve_access_index))`` is used, for example:
|
|
|
|
.. code-block:: c
|
|
|
|
void alpha(struct foo *s, volatile unsigned long *g) {
|
|
*g = s->a;
|
|
s->a = 1;
|
|
}
|
|
|
|
00 <alpha>:
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|
0: r3 = *(s32 *)(r1 + 0x0)
|
|
00: CO-RE <byte_off> [2] struct foo::a (0:0)
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|
1: *(u64 *)(r2 + 0x0) = r3
|
|
2: *(u32 *)(r1 + 0x0) = 0x1
|
|
10: CO-RE <byte_off> [2] struct foo::a (0:0)
|
|
3: exit
|
|
|
|
|
|
All relocation kinds could be requested via built-in functions.
|
|
E.g. field-based relocations:
|
|
|
|
.. code-block:: c
|
|
|
|
void bravo(struct foo *s, volatile unsigned long *g) {
|
|
*g = __builtin_preserve_field_info(s->b, 0 /* field byte offset */);
|
|
*g = __builtin_preserve_field_info(s->b, 1 /* field byte size */);
|
|
*g = __builtin_preserve_field_info(s->b, 2 /* field existence */);
|
|
*g = __builtin_preserve_field_info(s->b, 3 /* field signedness */);
|
|
*g = __builtin_preserve_field_info(s->c, 4 /* bitfield left shift */);
|
|
*g = __builtin_preserve_field_info(s->c, 5 /* bitfield right shift */);
|
|
}
|
|
|
|
20 <bravo>:
|
|
4: r1 = 0x4
|
|
20: CO-RE <byte_off> [2] struct foo::b (0:1)
|
|
5: *(u64 *)(r2 + 0x0) = r1
|
|
6: r1 = 0x4
|
|
30: CO-RE <byte_sz> [2] struct foo::b (0:1)
|
|
7: *(u64 *)(r2 + 0x0) = r1
|
|
8: r1 = 0x1
|
|
40: CO-RE <field_exists> [2] struct foo::b (0:1)
|
|
9: *(u64 *)(r2 + 0x0) = r1
|
|
10: r1 = 0x1
|
|
50: CO-RE <signed> [2] struct foo::b (0:1)
|
|
11: *(u64 *)(r2 + 0x0) = r1
|
|
12: r1 = 0x31
|
|
60: CO-RE <lshift_u64> [2] struct foo::c (0:2)
|
|
13: *(u64 *)(r2 + 0x0) = r1
|
|
14: r1 = 0x31
|
|
70: CO-RE <rshift_u64> [2] struct foo::c (0:2)
|
|
15: *(u64 *)(r2 + 0x0) = r1
|
|
16: exit
|
|
|
|
|
|
Type-based relocations:
|
|
|
|
.. code-block:: c
|
|
|
|
void charlie(struct foo *s, volatile unsigned long *g) {
|
|
*g = __builtin_preserve_type_info(*s, 0 /* type existence */);
|
|
*g = __builtin_preserve_type_info(*s, 1 /* type size */);
|
|
*g = __builtin_preserve_type_info(*s, 2 /* type matches */);
|
|
*g = __builtin_btf_type_id(*s, 0 /* type id in this object file */);
|
|
*g = __builtin_btf_type_id(*s, 1 /* type id in target kernel */);
|
|
}
|
|
|
|
88 <charlie>:
|
|
17: r1 = 0x1
|
|
88: CO-RE <type_exists> [2] struct foo
|
|
18: *(u64 *)(r2 + 0x0) = r1
|
|
19: r1 = 0xc
|
|
98: CO-RE <type_size> [2] struct foo
|
|
20: *(u64 *)(r2 + 0x0) = r1
|
|
21: r1 = 0x1
|
|
a8: CO-RE <type_matches> [2] struct foo
|
|
22: *(u64 *)(r2 + 0x0) = r1
|
|
23: r1 = 0x2 ll
|
|
b8: CO-RE <local_type_id> [2] struct foo
|
|
25: *(u64 *)(r2 + 0x0) = r1
|
|
26: r1 = 0x2 ll
|
|
d0: CO-RE <target_type_id> [2] struct foo
|
|
28: *(u64 *)(r2 + 0x0) = r1
|
|
29: exit
|
|
|
|
Enum-based relocations:
|
|
|
|
.. code-block:: c
|
|
|
|
void delta(struct foo *s, volatile unsigned long *g) {
|
|
*g = __builtin_preserve_enum_value(*(enum bar *)U, 0 /* enum literal existence */);
|
|
*g = __builtin_preserve_enum_value(*(enum bar *)V, 1 /* enum literal value */);
|
|
}
|
|
|
|
f0 <delta>:
|
|
30: r1 = 0x1 ll
|
|
f0: CO-RE <enumval_exists> [16] enum bar::U = 0
|
|
32: *(u64 *)(r2 + 0x0) = r1
|
|
33: r1 = 0x1 ll
|
|
108: CO-RE <enumval_value> [16] enum bar::V = 1
|
|
35: *(u64 *)(r2 + 0x0) = r1
|
|
36: exit
|