docs/Extensions.rst - llvm - Git at Google

 ===============
 LLVM Extensions
 ===============

 .. contents::
    :local:

 .. toctree::
    :hidden:

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

 This document describes extensions to tools and formats LLVM seeks compatibility
 with.

 General Assembly Syntax
 ===========================

 C99-style Hexadecimal Floating-point Constants
 ----------------------------------------------

 LLVM's assemblers allow floating-point constants to be written in C99's
 hexadecimal format instead of decimal if desired.

 .. code-block:: gas

   .section .data
   .float 0x1c2.2ap3

 Machine-specific Assembly Syntax
 ================================

 X86/COFF-Dependent
 ------------------

 Relocations
 ^^^^^^^^^^^

 The following additional relocation types are supported:

 **@IMGREL** (AT&T syntax only) generates an image-relative relocation that
 corresponds to the COFF relocation types ``IMAGE_REL_I386_DIR32NB`` (32-bit) or
 ``IMAGE_REL_AMD64_ADDR32NB`` (64-bit).

 .. code-block:: text

   .text
   fun:
     mov foo@IMGREL(%ebx, %ecx, 4), %eax

   .section .pdata
     .long fun@IMGREL
     .long (fun@imgrel + 0x3F)
     .long $unwind$fun@imgrel

 **.secrel32** generates a relocation that corresponds to the COFF relocation
 types ``IMAGE_REL_I386_SECREL`` (32-bit) or ``IMAGE_REL_AMD64_SECREL`` (64-bit).

 **.secidx** relocation generates an index of the section that contains
 the target.  It corresponds to the COFF relocation types
 ``IMAGE_REL_I386_SECTION`` (32-bit) or ``IMAGE_REL_AMD64_SECTION`` (64-bit).

 .. code-block:: none

   .section .debug$S,"rn"
     .long 4
     .long 242
     .long 40
     .secrel32 _function_name + 0
     .secidx   _function_name
     ...

 ``.linkonce`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 Syntax:

    ``.linkonce [ comdat type ]``

 Supported COMDAT types:

 ``discard``
    Discards duplicate sections with the same COMDAT symbol. This is the default
    if no type is specified.

 ``one_only``
    If the symbol is defined multiple times, the linker issues an error.

 ``same_size``
    Duplicates are discarded, but the linker issues an error if any have
    different sizes.

 ``same_contents``
    Duplicates are discarded, but the linker issues an error if any duplicates
    do not have exactly the same content.

 ``largest``
    Links the largest section from among the duplicates.

 ``newest``
    Links the newest section from among the duplicates.


 .. code-block:: gas

   .section .text$foo
   .linkonce
     ...

 ``.section`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 MC supports passing the information in ``.linkonce`` at the end of
 ``.section``. For example,  these two codes are equivalent

 .. code-block:: gas

   .section secName, "dr", discard, "Symbol1"
   .globl Symbol1
   Symbol1:
   .long 1

 .. code-block:: gas

   .section secName, "dr"
   .linkonce discard
   .globl Symbol1
   Symbol1:
   .long 1

 Note that in the combined form the COMDAT symbol is explicit. This
 extension exists to support multiple sections with the same name in
 different COMDATs:


 .. code-block:: gas

   .section secName, "dr", discard, "Symbol1"
   .globl Symbol1
   Symbol1:
   .long 1

   .section secName, "dr", discard, "Symbol2"
   .globl Symbol2
   Symbol2:
   .long 1

 In addition to the types allowed with ``.linkonce``, ``.section`` also accepts
 ``associative``. The meaning is that the section is linked  if a certain other
 COMDAT section is linked. This other section is indicated by the comdat symbol
 in this directive. It can be any symbol defined in the associated section, but
 is usually the associated section's comdat.

    The following restrictions apply to the associated section:

    1. It must be a COMDAT section.
    2. It cannot be another associative COMDAT section.

 In the following example the symobl ``sym`` is the comdat symbol of ``.foo``
 and ``.bar`` is associated to ``.foo``.

 .. code-block:: gas

 	.section	.foo,"bw",discard, "sym"
 	.section	.bar,"rd",associative, "sym"

 MC supports these flags in the COFF ``.section`` directive:

   - ``b``: BSS section (``IMAGE_SCN_CNT_INITIALIZED_DATA``)
   - ``d``: Data section (``IMAGE_SCN_CNT_UNINITIALIZED_DATA``)
   - ``n``: Section is not loaded (``IMAGE_SCN_LNK_REMOVE``)
   - ``r``: Read-only
   - ``s``: Shared section
   - ``w``: Writable
   - ``x``: Executable section
   - ``y``: Not readable
   - ``D``: Discardable (``IMAGE_SCN_MEM_DISCARDABLE``)

 These flags are all compatible with gas, with the exception of the ``D`` flag,
 which gnu as does not support. For gas compatibility, sections with a name
 starting with ".debug" are implicitly discardable.


 ARM64/COFF-Dependent
 --------------------

 Relocations
 ^^^^^^^^^^^

 The following additional symbol variants are supported:

 **:secrel_lo12:** generates a relocation that corresponds to the COFF relocation
 types ``IMAGE_REL_ARM64_SECREL_LOW12A`` or ``IMAGE_REL_ARM64_SECREL_LOW12L``.

 **:secrel_hi12:** generates a relocation that corresponds to the COFF relocation
 type ``IMAGE_REL_ARM64_SECREL_HIGH12A``.

 .. code-block:: gas

     add x0, x0, :secrel_hi12:symbol
     ldr x0, [x0, :secrel_lo12:symbol]

     add x1, x1, :secrel_hi12:symbol
     add x1, x1, :secrel_lo12:symbol
     ...


 ELF-Dependent
 -------------

 ``.section`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^

 In order to support creating multiple sections with the same name and comdat,
 it is possible to add an unique number at the end of the ``.seciton`` directive.
 For example, the following code creates two sections named ``.text``.

 .. code-block:: gas

 	.section	.text,"ax",@progbits,unique,1
         nop

 	.section	.text,"ax",@progbits,unique,2
         nop


 The unique number is not present in the resulting object at all. It is just used
 in the assembler to differentiate the sections.

 The 'o' flag is mapped to SHF_LINK_ORDER. If it is present, a symbol
 must be given that identifies the section to be placed is the
 .sh_link.

 .. code-block:: gas

         .section .foo,"a",@progbits
         .Ltmp:
         .section .bar,"ao",@progbits,.Ltmp

 which is equivalent to just

 .. code-block:: gas

         .section .foo,"a",@progbits
         .section .bar,"ao",@progbits,.foo

 ``.linker-options`` Section (linker options)
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 In order to support passing linker options from the frontend to the linker, a
 special section of type ``SHT_LLVM_LINKER_OPTIONS`` (usually named
 ``.linker-options`` though the name is not significant as it is identified by
 the type).  The contents of this section is a simple pair-wise encoding of
 directives for consideration by the linker.  The strings are encoded as standard
 null-terminated UTF-8 strings.  They are emitted inline to avoid having the
 linker traverse the object file for retrieving the value.  The linker is
 permitted to not honour the option and instead provide a warning/error to the
 user that the requested option was not honoured.

 The section has type ``SHT_LLVM_LINKER_OPTIONS`` and has the ``SHF_EXCLUDE``
 flag to ensure that the section is treated as opaque by linkers which do not
 support the feature and will not be emitted into the final linked binary.

 This would be equivalent to the follow raw assembly:

 .. code-block:: gas

   .section ".linker-options","e",@llvm_linker_options
   .asciz "option 1"
   .asciz "value 1"
   .asciz "option 2"
   .asciz "value 2"

 The following directives are specified:

   - lib

     The parameter identifies a library to be linked against.  The library will
     be looked up in the default and any specified library search paths
     (specified to this point).

   - libpath

     The paramter identifies an additional library search path to be considered
     when looking up libraries after the inclusion of this option.

 ``SHT_LLVM_CALL_GRAPH_PROFILE`` Section (Call Graph Profile)
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 This section is used to pass a call graph profile to the linker which can be
 used to optimize the placement of sections.  It contains a sequence of
 (from symbol, to symbol, weight) tuples.

 It shall have a type of ``SHT_LLVM_CALL_GRAPH_PROFILE`` (0x6fff4c02), shall
 have the ``SHF_EXCLUDE`` flag set, the ``sh_link`` member shall hold the section
 header index of the associated symbol table, and shall have a ``sh_entsize`` of
 16.  It should be named ``.llvm.call-graph-profile``.

 The contents of the section shall be a sequence of ``Elf_CGProfile`` entries.

 .. code-block:: c

   typedef struct {
     Elf_Word cgp_from;
     Elf_Word cgp_to;
     Elf_Xword cgp_weight;
   } Elf_CGProfile;

 cgp_from
   The symbol index of the source of the edge.

 cgp_to
   The symbol index of the destination of the edge.

 cgp_weight
   The weight of the edge.

 This is represented in assembly as:

 .. code-block:: gas

   .cg_profile from, to, 42

 ``.cg_profile`` directives are processed at the end of the file.  It is an error
 if either ``from`` or ``to`` are undefined temporary symbols.  If either symbol
 is a temporary symbol, then the section symbol is used instead.  If either
 symbol is undefined, then that symbol is defined as if ``.weak symbol`` has been
 written at the end of the file.  This forces the symbol to show up in the symbol
 table.

 ``SHT_LLVM_ADDRSIG`` Section (address-significance table)
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 This section is used to mark symbols as address-significant, i.e. the address
 of the symbol is used in a comparison or leaks outside the translation unit. It
 has the same meaning as the absence of the LLVM attributes ``unnamed_addr``
 and ``local_unnamed_addr``.

 Any sections referred to by symbols that are not marked as address-significant
 in any object file may be safely merged by a linker without breaking the
 address uniqueness guarantee provided by the C and C++ language standards.

 The contents of the section are a sequence of ULEB128-encoded integers
 referring to the symbol table indexes of the address-significant symbols.

 There are two associated assembly directives:

 .. code-block:: gas

   .addrsig

 This instructs the assembler to emit an address-significance table. Without
 this directive, all symbols are considered address-significant.

 .. code-block:: gas

   .addrsig_sym sym

 This marks ``sym`` as address-significant.

 CodeView-Dependent
 ------------------

 ``.cv_file`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^
 Syntax:
   ``.cv_file`` *FileNumber FileName* [ *checksum* ] [ *checksumkind* ]

 ``.cv_func_id`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^
 Introduces a function ID that can be used with ``.cv_loc``.

 Syntax:
   ``.cv_func_id`` *FunctionId*

 ``.cv_inline_site_id`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
 Introduces a function ID that can be used with ``.cv_loc``. Includes
 ``inlined at`` source location information for use in the line table of the
 caller, whether the caller is a real function or another inlined call site.

 Syntax:
   ``.cv_inline_site_id`` *FunctionId* ``within`` *Function* ``inlined_at`` *FileNumber Line* [ *Colomn* ]

 ``.cv_loc`` Directive
 ^^^^^^^^^^^^^^^^^^^^^
 The first number is a file number, must have been previously assigned with a
 ``.file`` directive, the second number is the line number and optionally the
 third number is a column position (zero if not specified).  The remaining
 optional items are ``.loc`` sub-directives.

 Syntax:
   ``.cv_loc`` *FunctionId FileNumber* [ *Line* ] [ *Column* ] [ *prologue_end* ] [ ``is_stmt`` *value* ]

 ``.cv_linetable`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^
 Syntax:
   ``.cv_linetable`` *FunctionId* ``,`` *FunctionStart* ``,`` *FunctionEnd*

 ``.cv_inline_linetable`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
 Syntax:
   ``.cv_inline_linetable`` *PrimaryFunctionId* ``,`` *FileNumber Line FunctionStart FunctionEnd*

 ``.cv_def_range`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^
 The *GapStart* and *GapEnd* options may be repeated as needed.

 Syntax:
   ``.cv_def_range`` *RangeStart RangeEnd* [ *GapStart GapEnd* ] ``,`` *bytes*

 ``.cv_stringtable`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 ``.cv_filechecksums`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 ``.cv_filechecksumoffset`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
 Syntax:
   ``.cv_filechecksumoffset`` *FileNumber*

 ``.cv_fpo_data`` Directive
 ^^^^^^^^^^^^^^^^^^^^^^^^^^
 Syntax:
   ``.cv_fpo_data`` *procsym*

 Target Specific Behaviour
 =========================

 X86
 ---

 Relocations
 ^^^^^^^^^^^

 ``@ABS8`` can be applied to symbols which appear as immediate operands to
 instructions that have an 8-bit immediate form for that operand. It causes
 the assembler to use the 8-bit form and an 8-bit relocation (e.g. ``R_386_8``
 or ``R_X86_64_8``) for the symbol.

 For example:

 .. code-block:: gas

   cmpq $foo@ABS8, %rdi

 This causes the assembler to select the form of the 64-bit ``cmpq`` instruction
 that takes an 8-bit immediate operand that is sign extended to 64 bits, as
 opposed to ``cmpq $foo, %rdi`` which takes a 32-bit immediate operand. This
 is also not the same as ``cmpb $foo, %dil``, which is an 8-bit comparison.

 Windows on ARM
 --------------

 Stack Probe Emission
 ^^^^^^^^^^^^^^^^^^^^

 The reference implementation (Microsoft Visual Studio 2012) emits stack probes
 in the following fashion:

 .. code-block:: gas

   movw r4, #constant
   bl __chkstk
   sub.w sp, sp, r4

 However, this has the limitation of 32 MiB (±16MiB).  In order to accommodate
 larger binaries, LLVM supports the use of ``-mcode-model=large`` to allow a 4GiB
 range via a slight deviation.  It will generate an indirect jump as follows:

 .. code-block:: gas

   movw r4, #constant
   movw r12, :lower16:__chkstk
   movt r12, :upper16:__chkstk
   blx r12
   sub.w sp, sp, r4

 Variable Length Arrays
 ^^^^^^^^^^^^^^^^^^^^^^

 The reference implementation (Microsoft Visual Studio 2012) does not permit the
 emission of Variable Length Arrays (VLAs).

 The Windows ARM Itanium ABI extends the base ABI by adding support for emitting
 a dynamic stack allocation.  When emitting a variable stack allocation, a call
 to ``__chkstk`` is emitted unconditionally to ensure that guard pages are setup
 properly.  The emission of this stack probe emission is handled similar to the
 standard stack probe emission.

 The MSVC environment does not emit code for VLAs currently.

 Windows on ARM64
 ----------------

 Stack Probe Emission
 ^^^^^^^^^^^^^^^^^^^^

 The reference implementation (Microsoft Visual Studio 2017) emits stack probes
 in the following fashion:

 .. code-block:: gas

   mov x15, #constant
   bl __chkstk
   sub sp, sp, x15, lsl #4

 However, this has the limitation of 256 MiB (±128MiB).  In order to accommodate
 larger binaries, LLVM supports the use of ``-mcode-model=large`` to allow a 8GiB
 (±4GiB) range via a slight deviation.  It will generate an indirect jump as
 follows:

 .. code-block:: gas

   mov x15, #constant
   adrp x16, __chkstk
   add x16, x16, :lo12:__chkstk
   blr x16
   sub sp, sp, x15, lsl #4
	===============
	LLVM Extensions
	===============

	.. contents::
	:local:

	.. toctree::
	:hidden:

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

	This document describes extensions to tools and formats LLVM seeks compatibility
	with.

	General Assembly Syntax
	===========================

	C99-style Hexadecimal Floating-point Constants
	----------------------------------------------

	LLVM's assemblers allow floating-point constants to be written in C99's
	hexadecimal format instead of decimal if desired.

	.. code-block:: gas

	.section .data
	.float 0x1c2.2ap3

	Machine-specific Assembly Syntax
	================================

	X86/COFF-Dependent
	------------------

	Relocations
	^^^^^^^^^^^

	The following additional relocation types are supported:

	@IMGREL (AT&T syntax only) generates an image-relative relocation that
	corresponds to the COFF relocation types ``IMAGE_REL_I386_DIR32NB`` (32-bit) or
	``IMAGE_REL_AMD64_ADDR32NB`` (64-bit).

	.. code-block:: text

	.text
	fun:
	mov foo@IMGREL(%ebx, %ecx, 4), %eax

	.section .pdata
	.long fun@IMGREL
	.long (fun@imgrel + 0x3F)
	.long $unwind$fun@imgrel

	.secrel32 generates a relocation that corresponds to the COFF relocation
	types ``IMAGE_REL_I386_SECREL`` (32-bit) or ``IMAGE_REL_AMD64_SECREL`` (64-bit).

	.secidx relocation generates an index of the section that contains
	the target. It corresponds to the COFF relocation types
	``IMAGE_REL_I386_SECTION`` (32-bit) or ``IMAGE_REL_AMD64_SECTION`` (64-bit).

	.. code-block:: none

	.section .debug$S,"rn"
	.long 4
	.long 242
	.long 40
	.secrel32 _function_name + 0
	.secidx _function_name
	...

	``.linkonce`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	Syntax:

	``.linkonce [ comdat type ]``

	Supported COMDAT types:

	``discard``
	Discards duplicate sections with the same COMDAT symbol. This is the default
	if no type is specified.

	``one_only``
	If the symbol is defined multiple times, the linker issues an error.

	``same_size``
	Duplicates are discarded, but the linker issues an error if any have
	different sizes.

	``same_contents``
	Duplicates are discarded, but the linker issues an error if any duplicates
	do not have exactly the same content.

	``largest``
	Links the largest section from among the duplicates.

	``newest``
	Links the newest section from among the duplicates.


	.. code-block:: gas

	.section .text$foo
	.linkonce
	...

	``.section`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	MC supports passing the information in ``.linkonce`` at the end of
	``.section``. For example, these two codes are equivalent

	.. code-block:: gas

	.section secName, "dr", discard, "Symbol1"
	.globl Symbol1
	Symbol1:
	.long 1

	.. code-block:: gas

	.section secName, "dr"
	.linkonce discard
	.globl Symbol1
	Symbol1:
	.long 1

	Note that in the combined form the COMDAT symbol is explicit. This
	extension exists to support multiple sections with the same name in
	different COMDATs:


	.. code-block:: gas

	.section secName, "dr", discard, "Symbol1"
	.globl Symbol1
	Symbol1:
	.long 1

	.section secName, "dr", discard, "Symbol2"
	.globl Symbol2
	Symbol2:
	.long 1

	In addition to the types allowed with ``.linkonce``, ``.section`` also accepts
	``associative``. The meaning is that the section is linked if a certain other
	COMDAT section is linked. This other section is indicated by the comdat symbol
	in this directive. It can be any symbol defined in the associated section, but
	is usually the associated section's comdat.

	The following restrictions apply to the associated section:

	1. It must be a COMDAT section.
	2. It cannot be another associative COMDAT section.

	In the following example the symobl ``sym`` is the comdat symbol of ``.foo``
	and ``.bar`` is associated to ``.foo``.

	.. code-block:: gas

	.section .foo,"bw",discard, "sym"
	.section .bar,"rd",associative, "sym"

	MC supports these flags in the COFF ``.section`` directive:

	- ``b``: BSS section (``IMAGE_SCN_CNT_INITIALIZED_DATA``)
	- ``d``: Data section (``IMAGE_SCN_CNT_UNINITIALIZED_DATA``)
	- ``n``: Section is not loaded (``IMAGE_SCN_LNK_REMOVE``)
	- ``r``: Read-only
	- ``s``: Shared section
	- ``w``: Writable
	- ``x``: Executable section
	- ``y``: Not readable
	- ``D``: Discardable (``IMAGE_SCN_MEM_DISCARDABLE``)

	These flags are all compatible with gas, with the exception of the ``D`` flag,
	which gnu as does not support. For gas compatibility, sections with a name
	starting with ".debug" are implicitly discardable.


	ARM64/COFF-Dependent
	--------------------

	Relocations
	^^^^^^^^^^^

	The following additional symbol variants are supported:

	:secrel_lo12: generates a relocation that corresponds to the COFF relocation
	types ``IMAGE_REL_ARM64_SECREL_LOW12A`` or ``IMAGE_REL_ARM64_SECREL_LOW12L``.

	:secrel_hi12: generates a relocation that corresponds to the COFF relocation
	type ``IMAGE_REL_ARM64_SECREL_HIGH12A``.

	.. code-block:: gas

	add x0, x0, :secrel_hi12:symbol
	ldr x0, [x0, :secrel_lo12:symbol]

	add x1, x1, :secrel_hi12:symbol
	add x1, x1, :secrel_lo12:symbol
	...


	ELF-Dependent
	-------------

	``.section`` Directive
	^^^^^^^^^^^^^^^^^^^^^^

	In order to support creating multiple sections with the same name and comdat,
	it is possible to add an unique number at the end of the ``.seciton`` directive.
	For example, the following code creates two sections named ``.text``.

	.. code-block:: gas

	.section .text,"ax",@progbits,unique,1
	nop

	.section .text,"ax",@progbits,unique,2
	nop


	The unique number is not present in the resulting object at all. It is just used
	in the assembler to differentiate the sections.

	The 'o' flag is mapped to SHF_LINK_ORDER. If it is present, a symbol
	must be given that identifies the section to be placed is the
	.sh_link.

	.. code-block:: gas

	.section .foo,"a",@progbits
	.Ltmp:
	.section .bar,"ao",@progbits,.Ltmp

	which is equivalent to just

	.. code-block:: gas

	.section .foo,"a",@progbits
	.section .bar,"ao",@progbits,.foo

	``.linker-options`` Section (linker options)
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	In order to support passing linker options from the frontend to the linker, a
	special section of type ``SHT_LLVM_LINKER_OPTIONS`` (usually named
	``.linker-options`` though the name is not significant as it is identified by
	the type). The contents of this section is a simple pair-wise encoding of
	directives for consideration by the linker. The strings are encoded as standard
	null-terminated UTF-8 strings. They are emitted inline to avoid having the
	linker traverse the object file for retrieving the value. The linker is
	permitted to not honour the option and instead provide a warning/error to the
	user that the requested option was not honoured.

	The section has type ``SHT_LLVM_LINKER_OPTIONS`` and has the ``SHF_EXCLUDE``
	flag to ensure that the section is treated as opaque by linkers which do not
	support the feature and will not be emitted into the final linked binary.

	This would be equivalent to the follow raw assembly:

	.. code-block:: gas

	.section ".linker-options","e",@llvm_linker_options
	.asciz "option 1"
	.asciz "value 1"
	.asciz "option 2"
	.asciz "value 2"

	The following directives are specified:

	- lib

	The parameter identifies a library to be linked against. The library will
	be looked up in the default and any specified library search paths
	(specified to this point).

	- libpath

	The paramter identifies an additional library search path to be considered
	when looking up libraries after the inclusion of this option.

	``SHT_LLVM_CALL_GRAPH_PROFILE`` Section (Call Graph Profile)
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	This section is used to pass a call graph profile to the linker which can be
	used to optimize the placement of sections. It contains a sequence of
	(from symbol, to symbol, weight) tuples.

	It shall have a type of ``SHT_LLVM_CALL_GRAPH_PROFILE`` (0x6fff4c02), shall
	have the ``SHF_EXCLUDE`` flag set, the ``sh_link`` member shall hold the section
	header index of the associated symbol table, and shall have a ``sh_entsize`` of
	16. It should be named ``.llvm.call-graph-profile``.

	The contents of the section shall be a sequence of ``Elf_CGProfile`` entries.

	.. code-block:: c

	typedef struct {
	Elf_Word cgp_from;
	Elf_Word cgp_to;
	Elf_Xword cgp_weight;
	} Elf_CGProfile;

	cgp_from
	The symbol index of the source of the edge.

	cgp_to
	The symbol index of the destination of the edge.

	cgp_weight
	The weight of the edge.

	This is represented in assembly as:

	.. code-block:: gas

	.cg_profile from, to, 42

	``.cg_profile`` directives are processed at the end of the file. It is an error
	if either ``from`` or ``to`` are undefined temporary symbols. If either symbol
	is a temporary symbol, then the section symbol is used instead. If either
	symbol is undefined, then that symbol is defined as if ``.weak symbol`` has been
	written at the end of the file. This forces the symbol to show up in the symbol
	table.

	``SHT_LLVM_ADDRSIG`` Section (address-significance table)
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	This section is used to mark symbols as address-significant, i.e. the address
	of the symbol is used in a comparison or leaks outside the translation unit. It
	has the same meaning as the absence of the LLVM attributes ``unnamed_addr``
	and ``local_unnamed_addr``.

	Any sections referred to by symbols that are not marked as address-significant
	in any object file may be safely merged by a linker without breaking the
	address uniqueness guarantee provided by the C and C++ language standards.

	The contents of the section are a sequence of ULEB128-encoded integers
	referring to the symbol table indexes of the address-significant symbols.

	There are two associated assembly directives:

	.. code-block:: gas

	.addrsig

	This instructs the assembler to emit an address-significance table. Without
	this directive, all symbols are considered address-significant.

	.. code-block:: gas

	.addrsig_sym sym

	This marks ``sym`` as address-significant.

	CodeView-Dependent
	------------------

	``.cv_file`` Directive
	^^^^^^^^^^^^^^^^^^^^^^
	Syntax:
	``.cv_file`` FileNumber FileName [ checksum ] [ checksumkind ]

	``.cv_func_id`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^
	Introduces a function ID that can be used with ``.cv_loc``.

	Syntax:
	``.cv_func_id`` FunctionId

	``.cv_inline_site_id`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
	Introduces a function ID that can be used with ``.cv_loc``. Includes
	``inlined at`` source location information for use in the line table of the
	caller, whether the caller is a real function or another inlined call site.

	Syntax:
	``.cv_inline_site_id`` FunctionId ``within`` Function ``inlined_at`` FileNumber Line [ Colomn ]

	``.cv_loc`` Directive
	^^^^^^^^^^^^^^^^^^^^^
	The first number is a file number, must have been previously assigned with a
	``.file`` directive, the second number is the line number and optionally the
	third number is a column position (zero if not specified). The remaining
	optional items are ``.loc`` sub-directives.

	Syntax:
	``.cv_loc`` FunctionId FileNumber [ Line ] [ Column ] [ prologue_end ] [ ``is_stmt`` value ]

	``.cv_linetable`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^^
	Syntax:
	``.cv_linetable`` FunctionId ``,`` FunctionStart ``,`` FunctionEnd

	``.cv_inline_linetable`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
	Syntax:
	``.cv_inline_linetable`` PrimaryFunctionId ``,`` FileNumber Line FunctionStart FunctionEnd

	``.cv_def_range`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^^
	The GapStart and GapEnd options may be repeated as needed.

	Syntax:
	``.cv_def_range`` RangeStart RangeEnd [ GapStart GapEnd ] ``,`` bytes

	``.cv_stringtable`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	``.cv_filechecksums`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	``.cv_filechecksumoffset`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
	Syntax:
	``.cv_filechecksumoffset`` FileNumber

	``.cv_fpo_data`` Directive
	^^^^^^^^^^^^^^^^^^^^^^^^^^
	Syntax:
	``.cv_fpo_data`` procsym

	Target Specific Behaviour
	=========================

	X86
	---

	Relocations
	^^^^^^^^^^^

	``@ABS8`` can be applied to symbols which appear as immediate operands to
	instructions that have an 8-bit immediate form for that operand. It causes
	the assembler to use the 8-bit form and an 8-bit relocation (e.g. ``R_386_8``
	or ``R_X86_64_8``) for the symbol.

	For example:

	.. code-block:: gas

	cmpq $foo@ABS8, %rdi

	This causes the assembler to select the form of the 64-bit ``cmpq`` instruction
	that takes an 8-bit immediate operand that is sign extended to 64 bits, as
	opposed to ``cmpq $foo, %rdi`` which takes a 32-bit immediate operand. This
	is also not the same as ``cmpb $foo, %dil``, which is an 8-bit comparison.

	Windows on ARM
	--------------

	Stack Probe Emission
	^^^^^^^^^^^^^^^^^^^^

	The reference implementation (Microsoft Visual Studio 2012) emits stack probes
	in the following fashion:

	.. code-block:: gas

	movw r4, #constant
	bl __chkstk
	sub.w sp, sp, r4

	However, this has the limitation of 32 MiB (±16MiB). In order to accommodate
	larger binaries, LLVM supports the use of ``-mcode-model=large`` to allow a 4GiB
	range via a slight deviation. It will generate an indirect jump as follows:

	.. code-block:: gas

	movw r4, #constant
	movw r12, :lower16:__chkstk
	movt r12, :upper16:__chkstk
	blx r12
	sub.w sp, sp, r4

	Variable Length Arrays
	^^^^^^^^^^^^^^^^^^^^^^

	The reference implementation (Microsoft Visual Studio 2012) does not permit the
	emission of Variable Length Arrays (VLAs).

	The Windows ARM Itanium ABI extends the base ABI by adding support for emitting
	a dynamic stack allocation. When emitting a variable stack allocation, a call
	to ``__chkstk`` is emitted unconditionally to ensure that guard pages are setup
	properly. The emission of this stack probe emission is handled similar to the
	standard stack probe emission.

	The MSVC environment does not emit code for VLAs currently.

	Windows on ARM64
	----------------

	Stack Probe Emission
	^^^^^^^^^^^^^^^^^^^^

	The reference implementation (Microsoft Visual Studio 2017) emits stack probes
	in the following fashion:

	.. code-block:: gas

	mov x15, #constant
	bl __chkstk
	sub sp, sp, x15, lsl #4

	However, this has the limitation of 256 MiB (±128MiB). In order to accommodate
	larger binaries, LLVM supports the use of ``-mcode-model=large`` to allow a 8GiB
	(±4GiB) range via a slight deviation. It will generate an indirect jump as
	follows:

	.. code-block:: gas

	mov x15, #constant
	adrp x16, __chkstk
	add x16, x16, :lo12:__chkstk
	blr x16
	sub sp, sp, x15, lsl #4