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

 ===============
 Opaque Pointers
 ===============

 The Opaque Pointer Type
 =======================

 Traditionally, LLVM IR pointer types have contained a pointee type. For example,
 ``i32 *`` is a pointer that points to an ``i32`` somewhere in memory. However,
 due to a lack of pointee type semantics and various issues with having pointee
 types, there is a desire to remove pointee types from pointers.

 The opaque pointer type project aims to replace all pointer types containing
 pointee types in LLVM with an opaque pointer type. The new pointer type is
 tentatively represented textually as ``ptr``.

 Address spaces are still used to distinguish between different kinds of pointers
 where the distinction is relevant for lowering (e.g. data vs function pointers
 have different sizes on some architectures). Opaque pointers are not changing
 anything related to address spaces and lowering. For more information, see
 `DataLayout <LangRef.html#langref-datalayout>`_.

 Issues with explicit pointee types
 ==================================

 LLVM IR pointers can be cast back and forth between pointers with different
 pointee types. The pointee type does not necessarily actually represent the
 actual underlying type in memory. In other words, the pointee type contains no
 real semantics.

 Lots of operations do not actually care about the underlying type. These
 operations, typically intrinsics, usually end up taking an ``i8 *``. This causes
 lots of redundant no-op bitcasts in the IR to and from a pointer with a
 different pointee type. The extra bitcasts take up space and require extra work
 to look through in optimizations. And more bitcasts increases the chances of
 incorrect bitcasts, especially in regards to address spaces.

 Some instructions still need to know what type to treat the memory pointed to by
 the pointer as. For example, a load needs to know how many bytes to load from
 memory. In these cases, instructions themselves contain a type argument. For
 example the load instruction from older versions of LLVM

 .. code-block:: llvm

   load i64* %p

 becomes

 .. code-block:: llvm

   load i64, ptr %p

 A nice analogous transition that happened earlier in LLVM is integer signedness.
 There is no distinction between signed and unsigned integer types, rather the
 integer operations themselves contain what to treat the integer as. Initially,
 LLVM IR distinguished between unsigned and signed integer types. The transition
 from manifesting signedness in types to instructions happened early on in LLVM's
 life to the betterment of LLVM IR.

 I Still Need Pointee Types!
 ===========================

 The frontend should already know what type each operation operates on based on
 the input source code. However, some frontends like Clang may end up relying on
 LLVM pointer pointee types to keep track of pointee types. The frontend needs to
 keep track of frontend pointee types on its own.

 For optimizations around frontend types, pointee types are not useful due their
 lack of semantics. Rather, since LLVM IR works on untyped memory, for a frontend
 to tell LLVM about frontend types for the purposes of alias analysis, extra
 metadata is added to the IR. For more information, see `TBAA
 <LangRef.html#tbaa-metadata>`_.

 Some specific operations still need to know what type a pointer types to. For
 the most part, this is codegen and ABI specific. For example, `byval
 <LangRef.html#parameter-attributes>`_ arguments are pointers, but backends need
 to know the underlying type of the argument to properly lower it. In cases like
 these, the attributes contain a type argument. For example,

 .. code-block:: llvm

   call void @f(ptr byval(i32) %p)

 signifies that ``%p`` as an argument should be lowered as an ``i32`` passed
 indirectly.

 If you have use cases that this sort of fix doesn't cover, please email
 llvm-dev.

 Transition Plan
 ===============

 LLVM currently has many places that depend on pointee types. Each dependency on
 pointee types needs to be resolved in some way or another. This essentially
 translates to figuring out how to remove all calls to
 ``PointerType::getElementType`` and ``Type::getPointerElementType()``.

 Making everything use opaque pointers in one huge commit is infeasible. This
 needs to be done incrementally. The following steps need to be done, in no
 particular order:

 * Introduce the opaque pointer type

   * Already done

 * Remove remaining in-tree users of pointee types

   * There are many miscellaneous uses that should be cleaned up individually

   * Some of the larger use cases are mentioned below

 * Various ABI attributes and instructions that rely on pointee types need to be
   modified to specify the type separately

   * This has already happened for all instructions like loads, stores, GEPs,
     and various attributes like ``byval``

   * More cases may be found as work continues

 * Remove calls to and deprecate ``IRBuilder`` methods that rely on pointee types

   * For example, some of the ``IRBuilder::CreateGEP()`` methods use the pointer
     operand's pointee type to determine the GEP operand type

   * Some methods are already deprecated with ``LLVM_ATTRIBUTE_DEPRECATED``, such
     as some overloads of ``IRBuilder::CreateLoad()``

 * Allow bitcode auto-upgrade of legacy pointer type to the new opaque pointer
   type (not to be turned on until ready)

   * To support legacy bitcode, such as legacy stores/loads, we need to track
     pointee types for all values since legacy instructions may infer the types
     from a pointer operand's pointee type

 * Migrate frontends to not keep track of frontend pointee types via LLVM pointer
   pointee types

   * This is mostly Clang, see ``clang::CodeGen::Address::getElementType()``

 * Add option to internally treat all pointer types opaque pointers and see what
   breaks, starting with LLVM tests, then run Clang over large codebases

   * We don't want to start mass-updating tests until we're fairly confident that opaque pointers won't cause major issues

 * Replace legacy pointer types in LLVM tests with opaque pointer types

 Frontend Migration Steps
 ========================

 If you have your own frontend, there are a couple of things to do after opaque
 pointer types fully work.

 * Don't rely on LLVM pointee types to keep track of frontend pointee types

 * Migrate away from LLVM IR instruction builders that rely on pointee types

   * For example, ``IRBuilder::CreateGEP()`` has multiple overloads; make sure to
     use one where the source element type is explicitly passed in, not inferred
     from the pointer operand pointee type
	===============
	Opaque Pointers
	===============

	The Opaque Pointer Type
	=======================

	Traditionally, LLVM IR pointer types have contained a pointee type. For example,
	``i32 *`` is a pointer that points to an ``i32`` somewhere in memory. However,
	due to a lack of pointee type semantics and various issues with having pointee
	types, there is a desire to remove pointee types from pointers.

	The opaque pointer type project aims to replace all pointer types containing
	pointee types in LLVM with an opaque pointer type. The new pointer type is
	tentatively represented textually as ``ptr``.

	Address spaces are still used to distinguish between different kinds of pointers
	where the distinction is relevant for lowering (e.g. data vs function pointers
	have different sizes on some architectures). Opaque pointers are not changing
	anything related to address spaces and lowering. For more information, see
	`DataLayout <LangRef.html#langref-datalayout>`_.

	Issues with explicit pointee types
	==================================

	LLVM IR pointers can be cast back and forth between pointers with different
	pointee types. The pointee type does not necessarily actually represent the
	actual underlying type in memory. In other words, the pointee type contains no
	real semantics.

	Lots of operations do not actually care about the underlying type. These
	operations, typically intrinsics, usually end up taking an ``i8 *``. This causes
	lots of redundant no-op bitcasts in the IR to and from a pointer with a
	different pointee type. The extra bitcasts take up space and require extra work
	to look through in optimizations. And more bitcasts increases the chances of
	incorrect bitcasts, especially in regards to address spaces.

	Some instructions still need to know what type to treat the memory pointed to by
	the pointer as. For example, a load needs to know how many bytes to load from
	memory. In these cases, instructions themselves contain a type argument. For
	example the load instruction from older versions of LLVM

	.. code-block:: llvm

	load i64* %p

	becomes

	.. code-block:: llvm

	load i64, ptr %p

	A nice analogous transition that happened earlier in LLVM is integer signedness.
	There is no distinction between signed and unsigned integer types, rather the
	integer operations themselves contain what to treat the integer as. Initially,
	LLVM IR distinguished between unsigned and signed integer types. The transition
	from manifesting signedness in types to instructions happened early on in LLVM's
	life to the betterment of LLVM IR.

	I Still Need Pointee Types!
	===========================

	The frontend should already know what type each operation operates on based on
	the input source code. However, some frontends like Clang may end up relying on
	LLVM pointer pointee types to keep track of pointee types. The frontend needs to
	keep track of frontend pointee types on its own.

	For optimizations around frontend types, pointee types are not useful due their
	lack of semantics. Rather, since LLVM IR works on untyped memory, for a frontend
	to tell LLVM about frontend types for the purposes of alias analysis, extra
	metadata is added to the IR. For more information, see `TBAA
	<LangRef.html#tbaa-metadata>`_.

	Some specific operations still need to know what type a pointer types to. For
	the most part, this is codegen and ABI specific. For example, `byval
	<LangRef.html#parameter-attributes>`_ arguments are pointers, but backends need
	to know the underlying type of the argument to properly lower it. In cases like
	these, the attributes contain a type argument. For example,

	.. code-block:: llvm

	call void @f(ptr byval(i32) %p)

	signifies that ``%p`` as an argument should be lowered as an ``i32`` passed
	indirectly.

	If you have use cases that this sort of fix doesn't cover, please email
	llvm-dev.

	Transition Plan
	===============

	LLVM currently has many places that depend on pointee types. Each dependency on
	pointee types needs to be resolved in some way or another. This essentially
	translates to figuring out how to remove all calls to
	``PointerType::getElementType`` and ``Type::getPointerElementType()``.

	Making everything use opaque pointers in one huge commit is infeasible. This
	needs to be done incrementally. The following steps need to be done, in no
	particular order:

	* Introduce the opaque pointer type

	* Already done

	* Remove remaining in-tree users of pointee types

	* There are many miscellaneous uses that should be cleaned up individually

	* Some of the larger use cases are mentioned below

	* Various ABI attributes and instructions that rely on pointee types need to be
	modified to specify the type separately

	* This has already happened for all instructions like loads, stores, GEPs,
	and various attributes like ``byval``

	* More cases may be found as work continues

	* Remove calls to and deprecate ``IRBuilder`` methods that rely on pointee types

	* For example, some of the ``IRBuilder::CreateGEP()`` methods use the pointer
	operand's pointee type to determine the GEP operand type

	* Some methods are already deprecated with ``LLVM_ATTRIBUTE_DEPRECATED``, such
	as some overloads of ``IRBuilder::CreateLoad()``

	* Allow bitcode auto-upgrade of legacy pointer type to the new opaque pointer
	type (not to be turned on until ready)

	* To support legacy bitcode, such as legacy stores/loads, we need to track
	pointee types for all values since legacy instructions may infer the types
	from a pointer operand's pointee type

	* Migrate frontends to not keep track of frontend pointee types via LLVM pointer
	pointee types

	* This is mostly Clang, see ``clang::CodeGen::Address::getElementType()``

	* Add option to internally treat all pointer types opaque pointers and see what
	breaks, starting with LLVM tests, then run Clang over large codebases

	* We don't want to start mass-updating tests until we're fairly confident that opaque pointers won't cause major issues

	* Replace legacy pointer types in LLVM tests with opaque pointer types

	Frontend Migration Steps
	========================

	If you have your own frontend, there are a couple of things to do after opaque
	pointer types fully work.

	* Don't rely on LLVM pointee types to keep track of frontend pointee types

	* Migrate away from LLVM IR instruction builders that rely on pointee types

	* For example, ``IRBuilder::CreateGEP()`` has multiple overloads; make sure to
	use one where the source element type is explicitly passed in, not inferred
	from the pointer operand pointee type