docs/PCSectionsMetadata.rst - llvm-project/llvm - Git at Google

 =========================
 LLVM PC Sections Metadata
 =========================

 .. contents::
    :local:

 Introduction
 ============

 PC Sections Metadata can be attached to instructions and functions, for which
 addresses, viz. program counters (PCs), are to be emitted in specially encoded
 binary sections. Metadata is assigned as an ``MDNode`` of the ``MD_pcsections``
 (``!pcsections``) kind; the following section describes the metadata format.

 Metadata Format
 ===============

 An arbitrary number of interleaved ``MDString`` and constant operators can be
 added, where a new ``MDString`` always denotes a section name, followed by an
 arbitrary number of auxiliary constant data encoded along the PC of the
 instruction or function. The first operator must be a ``MDString`` denoting the
 first section.

 .. code-block:: none

   !0 = !{
     !"<section#1>"
     [ , !1 ... ]
     [ !"<section#2">
       [ , !2 ... ]
       ... ]
   }
   !1 = !{ iXX <aux-consts#1>, ... }
   !2 = !{ iXX <aux-consts#2>, ... }
   ...

 The occurrence of ``section#1``, ``section#2``, ..., ``section#N`` in the
 metadata causes the backend to emit the PC for the associated instruction or
 function to all named sections. For each emitted PC in a section #N, the
 constants ``aux-consts#N`` in the tuple ``!N`` will be emitted after the PC.
 Multiple tuples with constant data may be provided after a section name string
 (e.g. ``!0 = !{"s1", !1, !2}``), and a single constant tuple may be reused for
 different sections (e.g. ``!0 = !{"s1", !1, "s2", !1}``).

 Binary Encoding
 ===============

 *Instructions* result in emitting a single PC, and *functions* result in
 emission of the start of the function and a 32-bit size. This is followed by
 the auxiliary constants that followed the respective section name in the
 ``MD_pcsections`` metadata.

 To avoid relocations in the final binary, each PC address stored at ``entry``
 is a relative relocation, computed as ``pc - entry``. To decode, a user has to
 compute ``entry + *entry``.

 The size of each entry depends on the code model. With large and medium sized
 code models, the entry size matches pointer size. For any smaller code model
 the entry size is just 32 bits.

 Encoding Options
 ----------------

 Optional encoding options can be passed in the first ``MDString`` operator:
 ``<section>!<options>``. The following options are available:

     * ``C`` -- Compress constant integers of size 2-8 bytes as ULEB128; this
       includes the function size (but excludes the PC entry).

 For example, ``foo!C`` will emit into section ``foo`` with all constants
 encoded as ULEB128.

 Guarantees on Code Generation
 =============================

 Attaching ``!pcsections`` metadata to LLVM IR instructions *shall not* affect
 optimizations or code generation outside the requested PC sections.

 While relying on LLVM IR metadata to request PC sections makes the above
 guarantee relatively trivial, propagation of metadata through the optimization
 and code generation pipeline has the following guarantees.

 Metadata Propagation
 --------------------

 In general, LLVM *does not make any guarantees* about preserving IR metadata
 (attached to an ``Instruction``) through IR transformations. When using PC
 sections metadata, this guarantee is unchanged, and ``!pcsections`` metadata is
 remains *optional* until lowering to machine IR (MIR).

 Note for Code Generation
 ------------------------

 As with other LLVM IR metadata, there are no requirements for LLVM IR
 transformation passes to preserve ``!pcsections`` metadata, with the following
 exceptions:

     * The ``AtomicExpandPass`` shall preserve ``!pcsections`` metadata
       according to the below rules 1-4.

 When translating LLVM IR to MIR, the ``!pcsections`` metadata shall be copied
 from the source ``Instruction`` to the target ``MachineInstr`` (set with
 ``MachineInstr::setPCSections()``). The instruction selectors and MIR
 optimization passes shall preserve PC sections metadata as follows:

     1. Replacements will preserve PC sections metadata of the replaced
        instruction.

     2. Duplications will preserve PC sections metadata of the copied
        instruction.

     3. Merging will preserve PC sections metadata of one of the two
        instructions (no guarantee on which instruction's metadata is used).

     4. Deletions will loose PC sections metadata.

 This is similar to debug info, and the ``BuildMI()`` helper provides a
 convenient way to propagate debug info and ``!pcsections`` metadata in the
 ``MIMetadata`` bundle.

 Note for Metadata Users
 -----------------------

 Use cases for ``!pcsections`` metadata should either be fully tolerant to
 missing metadata, or the passes inserting ``!pcsections`` metadata should run
 *after* all LLVM IR optimization passes to preserve the metadata until being
 translated to MIR.
	=========================
	LLVM PC Sections Metadata
	=========================

	.. contents::
	:local:

	Introduction
	============

	PC Sections Metadata can be attached to instructions and functions, for which
	addresses, viz. program counters (PCs), are to be emitted in specially encoded
	binary sections. Metadata is assigned as an ``MDNode`` of the ``MD_pcsections``
	(``!pcsections``) kind; the following section describes the metadata format.

	Metadata Format
	===============

	An arbitrary number of interleaved ``MDString`` and constant operators can be
	added, where a new ``MDString`` always denotes a section name, followed by an
	arbitrary number of auxiliary constant data encoded along the PC of the
	instruction or function. The first operator must be a ``MDString`` denoting the
	first section.

	.. code-block:: none

	!0 = !{
	!"<section#1>"
	[ , !1 ... ]
	[ !"<section#2">
	[ , !2 ... ]
	... ]
	}
	!1 = !{ iXX <aux-consts#1>, ... }
	!2 = !{ iXX <aux-consts#2>, ... }
	...

	The occurrence of ``section#1``, ``section#2``, ..., ``section#N`` in the
	metadata causes the backend to emit the PC for the associated instruction or
	function to all named sections. For each emitted PC in a section #N, the
	constants ``aux-consts#N`` in the tuple ``!N`` will be emitted after the PC.
	Multiple tuples with constant data may be provided after a section name string
	(e.g. ``!0 = !{"s1", !1, !2}``), and a single constant tuple may be reused for
	different sections (e.g. ``!0 = !{"s1", !1, "s2", !1}``).

	Binary Encoding
	===============

	Instructions result in emitting a single PC, and functions result in
	emission of the start of the function and a 32-bit size. This is followed by
	the auxiliary constants that followed the respective section name in the
	``MD_pcsections`` metadata.

	To avoid relocations in the final binary, each PC address stored at ``entry``
	is a relative relocation, computed as ``pc - entry``. To decode, a user has to
	compute ``entry + *entry``.

	The size of each entry depends on the code model. With large and medium sized
	code models, the entry size matches pointer size. For any smaller code model
	the entry size is just 32 bits.

	Encoding Options
	----------------

	Optional encoding options can be passed in the first ``MDString`` operator:
	``<section>!<options>``. The following options are available:

	* ``C`` -- Compress constant integers of size 2-8 bytes as ULEB128; this
	includes the function size (but excludes the PC entry).

	For example, ``foo!C`` will emit into section ``foo`` with all constants
	encoded as ULEB128.

	Guarantees on Code Generation
	=============================

	Attaching ``!pcsections`` metadata to LLVM IR instructions shall not affect
	optimizations or code generation outside the requested PC sections.

	While relying on LLVM IR metadata to request PC sections makes the above
	guarantee relatively trivial, propagation of metadata through the optimization
	and code generation pipeline has the following guarantees.

	Metadata Propagation
	--------------------

	In general, LLVM does not make any guarantees about preserving IR metadata
	(attached to an ``Instruction``) through IR transformations. When using PC
	sections metadata, this guarantee is unchanged, and ``!pcsections`` metadata is
	remains optional until lowering to machine IR (MIR).

	Note for Code Generation
	------------------------

	As with other LLVM IR metadata, there are no requirements for LLVM IR
	transformation passes to preserve ``!pcsections`` metadata, with the following
	exceptions:

	* The ``AtomicExpandPass`` shall preserve ``!pcsections`` metadata
	according to the below rules 1-4.

	When translating LLVM IR to MIR, the ``!pcsections`` metadata shall be copied
	from the source ``Instruction`` to the target ``MachineInstr`` (set with
	``MachineInstr::setPCSections()``). The instruction selectors and MIR
	optimization passes shall preserve PC sections metadata as follows:

	1. Replacements will preserve PC sections metadata of the replaced
	instruction.

	2. Duplications will preserve PC sections metadata of the copied
	instruction.

	3. Merging will preserve PC sections metadata of one of the two
	instructions (no guarantee on which instruction's metadata is used).

	4. Deletions will loose PC sections metadata.

	This is similar to debug info, and the ``BuildMI()`` helper provides a
	convenient way to propagate debug info and ``!pcsections`` metadata in the
	``MIMetadata`` bundle.

	Note for Metadata Users
	-----------------------

	Use cases for ``!pcsections`` metadata should either be fully tolerant to
	missing metadata, or the passes inserting ``!pcsections`` metadata should run
	after all LLVM IR optimization passes to preserve the metadata until being
	translated to MIR.