clang/docs/ConstantInterpreter.rst - llvm-project - Git at Google

 ====================
 Constant Interpreter
 ====================

 .. contents::
    :local:

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

 The constexpr interpreter aims to replace the existing tree evaluator in
 clang, improving performance on constructs which are executed inefficiently
 by the evaluator. The interpreter is activated using the following flags:

 * ``-fexperimental-new-constant-interpreter`` enables the interpreter,
   emitting an error if an unsupported feature is encountered

 Bytecode Compilation
 ====================

 Bytecode compilation is handled in ``ByteCodeStmtGen.h`` for statements
 and ``ByteCodeExprGen.h`` for expressions. The compiler has two different
 backends: one to generate bytecode for functions (``ByteCodeEmitter``) and
 one to directly evaluate expressions as they are compiled, without
 generating bytecode (``EvalEmitter``). All functions are compiled to
 bytecode, while toplevel expressions used in constant contexts are directly
 evaluated since the bytecode would never be reused. This mechanism aims to
 pave the way towards replacing the evaluator, improving its performance on
 functions and loops, while being just as fast on single-use toplevel
 expressions.

 The interpreter relies on stack-based, strongly-typed opcodes. The glue
 logic between the code generator, along with the enumeration and
 description of opcodes, can be found in ``Opcodes.td``. The opcodes are
 implemented as generic template methods in ``Interp.h`` and instantiated
 with the relevant primitive types by the interpreter loop or by the
 evaluating emitter.

 Primitive Types
 ---------------

 * ``PT_{U|S}int{8|16|32|64}``

   Signed or unsigned integers of a specific bit width, implemented using
   the ```Integral``` type.

 * ``PT_{U|S}intFP``

   Signed or unsigned integers of an arbitrary, but fixed width used to
   implement integral types which are required by the target, but are not
   supported by the host. Under the hood, they rely on APValue. The
   ``Integral`` specialisation for these types is required by opcodes to
   share an implementation with fixed integrals.

 * ``PT_Bool``

   Representation for boolean types, essentially a 1-bit unsigned
   ``Integral``.

 * ``PT_RealFP``

   Arbitrary, but fixed precision floating point numbers. Could be
   specialised in the future similarly to integers in order to improve
   floating point performance.

 * ``PT_Ptr``

   Pointer type, defined in ``"Pointer.h"``. A pointer can be either null,
   reference interpreter-allocated memory (``BlockPointer``) or point to an
   address which can be derived, but not accessed (``ExternPointer``).

 * ``PT_FnPtr``

   Function pointer type, can also be a null function pointer. Defined
   in ``"FnPointer.h"``.

 * ``PT_MemPtr``

   Member pointer type, can also be a null member pointer. Defined
   in ``"MemberPointer.h"``

 * ``PT_VoidPtr``

   Void pointer type, can be used for rount-trip casts. Represented as
   the union of all pointers which can be cast to void.
   Defined in ``"VoidPointer.h"``.

 * ``PT_ObjCBlockPtr``

   Pointer type for ObjC blocks. Defined in ``"ObjCBlockPointer.h"``.

 Composite types
 ---------------

 The interpreter distinguishes two kinds of composite types: arrays and
 records (structs and classes). Unions are represented as records, except
 at most a single field can be marked as active. The contents of inactive
 fields are kept until they are reactivated and overwritten.
 Complex numbers (``_Complex``) and vectors
 (``__attribute((vector_size(16)))``) are treated as arrays.


 Bytecode Execution
 ==================

 Bytecode is executed using a stack-based interpreter. The execution
 context consists of an ``InterpStack``, along with a chain of
 ``InterpFrame`` objects storing the call frames. Frames are built by
 call instructions and destroyed by return instructions. They perform
 one allocation to reserve space for all locals in a single block.
 These objects store all the required information to emit stack traces
 whenever evaluation fails.

 Memory Organisation
 ===================

 Memory management in the interpreter relies on 3 data structures: ``Block``
 objects which store the data and associated inline metadata, ``Pointer``
 objects which refer to or into blocks, and ``Descriptor`` structures which
 describe blocks and subobjects nested inside blocks.

 Blocks
 ------

 Blocks contain data interleaved with metadata. They are allocated either
 statically in the code generator (globals, static members, dummy parameter
 values etc.) or dynamically in the interpreter, when creating the frame
 containing the local variables of a function. Blocks are associated with a
 descriptor that characterises the entire allocation, along with a few
 additional attributes:

 * ``IsStatic`` indicates whether the block has static duration in the
   interpreter, i.e. it is not a local in a frame.

 * ``DeclID`` identifies each global declaration (it is set to an invalid
   and irrelevant value for locals) in order to prevent illegal writes and
   reads involving globals and temporaries with static storage duration.

 Static blocks are never deallocated, but local ones might be deallocated
 even when there are live pointers to them. Pointers are only valid as
 long as the blocks they point to are valid, so a block with pointers to
 it whose lifetime ends is kept alive until all pointers to it go out of
 scope. Since the frame is destroyed on function exit, such blocks are
 turned into a ``DeadBlock`` and copied to storage managed by the
 interpreter itself, not the frame. Reads and writes to these blocks are
 illegal and cause an appropriate diagnostic to be emitted. When the last
 pointer goes out of scope, dead blocks are also deallocated.

 The lifetime of blocks is managed through 3 methods stored in the
 descriptor of the block:

 * **CtorFn**: initializes the metadata which is store in the block,
   alongside actual data. Invokes the default constructors of objects
   which are not trivial (``Pointer``, ``RealFP``, etc.)

 * **DtorFn**: invokes the destructors of non-trivial objects.

 * **MoveFn**: moves a block to dead storage.

 Non-static blocks track all the pointers into them through an intrusive
 doubly-linked list, required to adjust and invalidate all pointers when
 transforming a block into a dead block. If the lifetime of an object ends,
 all pointers to it are invalidated, emitting the appropriate diagnostics when
 dereferenced.

 The interpreter distinguishes 3 different kinds of blocks:

 * **Primitives**

   A block containing a single primitive with no additional metadata.

 * **Arrays of primitives**

   An array of primitives contains a pointer to an ``InitMap`` storage as its
   first field: the initialisation map is a bit map indicating all elements of
   the array which were initialised. If the pointer is null, no elements were
   initialised, while a value of ``(InitMap*)-1`` indicates that the object was
   fully initialised. When all fields are initialised, the map is deallocated
   and replaced with that token.

   Array elements are stored sequentially, without padding, after the pointer
   to the map.

 * **Arrays of composites and records**

   Each element in an array of composites is preceded by an ``InlineDescriptor``
   which stores the attributes specific to the field and not the whole
   allocation site. Descriptors and elements are stored sequentially in the
   block.
   Records are laid out identically to arrays of composites: each field and base
   class is preceded by an inline descriptor. The ``InlineDescriptor``
   has the following fields:

    * **Offset**: byte offset into the array or record, used to step back to the
      parent array or record.
    * **IsConst**: flag indicating if the field is const-qualified.
    * **IsInitialized**: flag indicating whether the field or element was
      initialized. For non-primitive fields, this is only relevant to determine
      the dynamic type of objects during construction.
    * **IsBase**: flag indicating whether the record is a base class. In that
      case, the offset can be used to identify the derived class.
    * **IsActive**: indicates if the field is the active field of a union.
    * **IsMutable**: indicates if the field is marked as mutable.

 Inline descriptors are filled in by the `CtorFn` of blocks, which leaves storage
 in an uninitialised, but valid state.

 Descriptors
 -----------

 Descriptors are generated at bytecode compilation time and contain information
 required to determine if a particular memory access is allowed in constexpr.
 They also carry all the information required to emit a diagnostic involving
 a memory access, such as the declaration which originates the block.
 Currently there is a single kind of descriptor encoding information for all
 block types.

 Pointers
 --------

 Pointers, implemented in ``Pointer.h`` are represented as a tagged union.
 Some of these may not yet be available in upstream ``clang``.

  * **BlockPointer**: used to reference memory allocated and managed by the
    interpreter, being the only pointer kind which allows dereferencing in the
    interpreter
  * **ExternPointer**: points to memory which can be addressed, but not read by
    the interpreter. It is equivalent to APValue, tracking a declaration and a path
    of fields and indices into that allocation.
  * **TargetPointer**: represents a target address derived from a base address
    through pointer arithmetic, such as ``((int *)0x100)[20]``. Null pointers are
    target pointers with a zero offset.
  * **TypeInfoPointer**: tracks information for the opaque type returned by
    ``typeid``
  * **InvalidPointer**: is dummy pointer created by an invalid operation which
    allows the interpreter to continue execution. Does not allow pointer
    arithmetic or dereferencing.

 Besides the previously mentioned union, a number of other pointer-like types
 have their own type:

  * **ObjCBlockPointer** tracks Objective-C blocks
  * **FnPointer** tracks functions and lazily caches their compiled version
  * **MemberPointer** tracks C++ object members

 Void pointers, which can be built by casting any of the aforementioned
 pointers, are implemented as a union of all pointer types. The ``BitCast``
 opcode is responsible for performing all legal conversions between these
 types and primitive integers.

 BlockPointer
 ~~~~~~~~~~~~

 Block pointers track a ``Pointee``, the block to which they point, along
 with a ``Base`` and an ``Offset``. The base identifies the innermost field,
 while the offset points to an array element relative to the base (including
 one-past-end pointers). The offset identifies the array element or field
 which is referenced, while the base points to the outer object or array which
 contains the field. These two fields allow all pointers to be uniquely
 identified, disambiguated and characterised.

 As an example, consider the following structure:

 .. code-block:: c

     struct A {
         struct B {
             int x;
             int y;
         } b;
         struct C {
             int a;
             int b;
         } c[2];
         int z;
     };
     constexpr A a;

 On the target, ``&a`` and ``&a.b.x`` are equal. So are ``&a.c[0]`` and
 ``&a.c[0].a``. In the interpreter, all these pointers must be
 distinguished since the are all allowed to address distinct range of
 memory.

 In the interpreter, the object would require 240 bytes of storage and
 would have its field interleaved with metadata. The pointers which can
 be derived to the object are illustrated in the following diagram:

 ::

       0   16  32  40  56  64  80  96  112 120 136 144 160 176 184 200 208 224 240
   +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+
   + B | D | D | x | D | y | D | D | D | a | D | b | D | D | a | D | b | D | z |
   +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+
       ^   ^   ^       ^       ^   ^   ^       ^       ^   ^       ^       ^
       |   |   |       |       |   |   |   &a.c[0].b   |   |   &a.c[1].b   |
       a   |&a.b.x   &a.y    &a.c  |&a.c[0].a          |&a.c[1].a          |
         &a.b                   &a.c[0]            &a.c[1]               &a.z

 The ``Base`` offset of all pointers points to the start of a field or
 an array and is preceded by an inline descriptor (unless ``Base`` is
 zero, pointing to the root). All the relevant attributes can be read
 from either the inline descriptor or the descriptor of the block.


 Array elements are identified by the ``Offset`` field of pointers,
 pointing to past the inline descriptors for composites and before
 the actual data in the case of primitive arrays. The ``Offset``
 points to the offset where primitives can be read from. As an example,
 ``a.c + 1`` would have the same base as ``a.c`` since it is an element
 of ``a.c``, but its offset would point to ``&a.c[1]``. The
 array-to-pointer decay operation adjusts a pointer to an array (where
 the offset is equal to the base) to a pointer to the first element.

 ExternPointer
 ~~~~~~~~~~~~~

 Extern pointers can be derived, pointing into symbols which are not
 readable from constexpr. An external pointer consists of a base
 declaration, along with a path designating a subobject, similar to
 the ``LValuePath`` of an APValue. Extern pointers can be converted
 to block pointers if the underlying variable is defined after the
 pointer is created, as is the case in the following example:

 .. code-block:: c

   extern const int a;
   constexpr const int *p = &a;
   const int a = 5;
   static_assert(*p == 5, "x");

 TargetPointer
 ~~~~~~~~~~~~~

 While null pointer arithmetic or integer-to-pointer conversion is
 banned in constexpr, some expressions on target offsets must be folded,
 replicating the behaviour of the ``offsetof`` builtin. Target pointers
 are characterised by 3 offsets: a field offset, an array offset and a
 base offset, along with a descriptor specifying the type the pointer is
 supposed to refer to. Array indexing adjusts the array offset, while the
 field offset is adjusted when a pointer to a member is created. Casting
 an integer to a pointer sets the value of the base offset. As a special
 case, null pointers are target pointers with all offsets set to 0.

 TypeInfoPointer
 ~~~~~~~~~~~~~~~

 ``TypeInfoPointer`` tracks two types: the type assigned to
 ``std::type_info`` and the type which was passed to ``typeinfo``.

 InvalidPointer
 ~~~~~~~~~~~~~~

 Such pointers are built by operations which cannot generate valid
 pointers, allowing the interpreter to continue execution after emitting
 a warning. Inspecting such a pointer stops execution.

 TODO
 ====

 Missing Language Features
 -------------------------

 * Changing the active field of unions
 * ``volatile``
 * ``__builtin_constant_p``
 * ``dynamic_cast``
 * ``new`` and ``delete``
 * Fixed Point numbers and arithmetic on Complex numbers
 * Several builtin methods, including string operations and
   ``__builtin_bit_cast``
 * Continue-after-failure: a form of exception handling at the bytecode
   level should be implemented to allow execution to resume. As an example,
   argument evaluation should resume after the computation of an argument fails.
 * Pointer-to-Integer conversions
 * Lazy descriptors: the interpreter creates a ``Record`` and ``Descriptor``
   when it encounters a type: ones which are not yet defined should be lazily
   created when required

 Known Bugs
 ----------

 * If execution fails, memory storing APInts and APFloats is leaked when the
   stack is cleared
	====================
	Constant Interpreter
	====================

	.. contents::
	:local:

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

	The constexpr interpreter aims to replace the existing tree evaluator in
	clang, improving performance on constructs which are executed inefficiently
	by the evaluator. The interpreter is activated using the following flags:

	* ``-fexperimental-new-constant-interpreter`` enables the interpreter,
	emitting an error if an unsupported feature is encountered

	Bytecode Compilation
	====================

	Bytecode compilation is handled in ``ByteCodeStmtGen.h`` for statements
	and ``ByteCodeExprGen.h`` for expressions. The compiler has two different
	backends: one to generate bytecode for functions (``ByteCodeEmitter``) and
	one to directly evaluate expressions as they are compiled, without
	generating bytecode (``EvalEmitter``). All functions are compiled to
	bytecode, while toplevel expressions used in constant contexts are directly
	evaluated since the bytecode would never be reused. This mechanism aims to
	pave the way towards replacing the evaluator, improving its performance on
	functions and loops, while being just as fast on single-use toplevel
	expressions.

	The interpreter relies on stack-based, strongly-typed opcodes. The glue
	logic between the code generator, along with the enumeration and
	description of opcodes, can be found in ``Opcodes.td``. The opcodes are
	implemented as generic template methods in ``Interp.h`` and instantiated
	with the relevant primitive types by the interpreter loop or by the
	evaluating emitter.

	Primitive Types
	---------------

	* ``PT_{U\|S}int{8\|16\|32\|64}``

	Signed or unsigned integers of a specific bit width, implemented using
	the ```Integral``` type.

	* ``PT_{U\|S}intFP``

	Signed or unsigned integers of an arbitrary, but fixed width used to
	implement integral types which are required by the target, but are not
	supported by the host. Under the hood, they rely on APValue. The
	``Integral`` specialisation for these types is required by opcodes to
	share an implementation with fixed integrals.

	* ``PT_Bool``

	Representation for boolean types, essentially a 1-bit unsigned
	``Integral``.

	* ``PT_RealFP``

	Arbitrary, but fixed precision floating point numbers. Could be
	specialised in the future similarly to integers in order to improve
	floating point performance.

	* ``PT_Ptr``

	Pointer type, defined in ``"Pointer.h"``. A pointer can be either null,
	reference interpreter-allocated memory (``BlockPointer``) or point to an
	address which can be derived, but not accessed (``ExternPointer``).

	* ``PT_FnPtr``

	Function pointer type, can also be a null function pointer. Defined
	in ``"FnPointer.h"``.

	* ``PT_MemPtr``

	Member pointer type, can also be a null member pointer. Defined
	in ``"MemberPointer.h"``

	* ``PT_VoidPtr``

	Void pointer type, can be used for rount-trip casts. Represented as
	the union of all pointers which can be cast to void.
	Defined in ``"VoidPointer.h"``.

	* ``PT_ObjCBlockPtr``

	Pointer type for ObjC blocks. Defined in ``"ObjCBlockPointer.h"``.

	Composite types
	---------------

	The interpreter distinguishes two kinds of composite types: arrays and
	records (structs and classes). Unions are represented as records, except
	at most a single field can be marked as active. The contents of inactive
	fields are kept until they are reactivated and overwritten.
	Complex numbers (``_Complex``) and vectors
	(``__attribute((vector_size(16)))``) are treated as arrays.


	Bytecode Execution
	==================

	Bytecode is executed using a stack-based interpreter. The execution
	context consists of an ``InterpStack``, along with a chain of
	``InterpFrame`` objects storing the call frames. Frames are built by
	call instructions and destroyed by return instructions. They perform
	one allocation to reserve space for all locals in a single block.
	These objects store all the required information to emit stack traces
	whenever evaluation fails.

	Memory Organisation
	===================

	Memory management in the interpreter relies on 3 data structures: ``Block``
	objects which store the data and associated inline metadata, ``Pointer``
	objects which refer to or into blocks, and ``Descriptor`` structures which
	describe blocks and subobjects nested inside blocks.

	Blocks
	------

	Blocks contain data interleaved with metadata. They are allocated either
	statically in the code generator (globals, static members, dummy parameter
	values etc.) or dynamically in the interpreter, when creating the frame
	containing the local variables of a function. Blocks are associated with a
	descriptor that characterises the entire allocation, along with a few
	additional attributes:

	* ``IsStatic`` indicates whether the block has static duration in the
	interpreter, i.e. it is not a local in a frame.

	* ``DeclID`` identifies each global declaration (it is set to an invalid
	and irrelevant value for locals) in order to prevent illegal writes and
	reads involving globals and temporaries with static storage duration.

	Static blocks are never deallocated, but local ones might be deallocated
	even when there are live pointers to them. Pointers are only valid as
	long as the blocks they point to are valid, so a block with pointers to
	it whose lifetime ends is kept alive until all pointers to it go out of
	scope. Since the frame is destroyed on function exit, such blocks are
	turned into a ``DeadBlock`` and copied to storage managed by the
	interpreter itself, not the frame. Reads and writes to these blocks are
	illegal and cause an appropriate diagnostic to be emitted. When the last
	pointer goes out of scope, dead blocks are also deallocated.

	The lifetime of blocks is managed through 3 methods stored in the
	descriptor of the block:

	* CtorFn: initializes the metadata which is store in the block,
	alongside actual data. Invokes the default constructors of objects
	which are not trivial (``Pointer``, ``RealFP``, etc.)

	* DtorFn: invokes the destructors of non-trivial objects.

	* MoveFn: moves a block to dead storage.

	Non-static blocks track all the pointers into them through an intrusive
	doubly-linked list, required to adjust and invalidate all pointers when
	transforming a block into a dead block. If the lifetime of an object ends,
	all pointers to it are invalidated, emitting the appropriate diagnostics when
	dereferenced.

	The interpreter distinguishes 3 different kinds of blocks:

	* Primitives

	A block containing a single primitive with no additional metadata.

	* Arrays of primitives

	An array of primitives contains a pointer to an ``InitMap`` storage as its
	first field: the initialisation map is a bit map indicating all elements of
	the array which were initialised. If the pointer is null, no elements were
	initialised, while a value of ``(InitMap*)-1`` indicates that the object was
	fully initialised. When all fields are initialised, the map is deallocated
	and replaced with that token.

	Array elements are stored sequentially, without padding, after the pointer
	to the map.

	* Arrays of composites and records

	Each element in an array of composites is preceded by an ``InlineDescriptor``
	which stores the attributes specific to the field and not the whole
	allocation site. Descriptors and elements are stored sequentially in the
	block.
	Records are laid out identically to arrays of composites: each field and base
	class is preceded by an inline descriptor. The ``InlineDescriptor``
	has the following fields:

	* Offset: byte offset into the array or record, used to step back to the
	parent array or record.
	* IsConst: flag indicating if the field is const-qualified.
	* IsInitialized: flag indicating whether the field or element was
	initialized. For non-primitive fields, this is only relevant to determine
	the dynamic type of objects during construction.
	* IsBase: flag indicating whether the record is a base class. In that
	case, the offset can be used to identify the derived class.
	* IsActive: indicates if the field is the active field of a union.
	* IsMutable: indicates if the field is marked as mutable.

	Inline descriptors are filled in by the `CtorFn` of blocks, which leaves storage
	in an uninitialised, but valid state.

	Descriptors
	-----------

	Descriptors are generated at bytecode compilation time and contain information
	required to determine if a particular memory access is allowed in constexpr.
	They also carry all the information required to emit a diagnostic involving
	a memory access, such as the declaration which originates the block.
	Currently there is a single kind of descriptor encoding information for all
	block types.

	Pointers
	--------

	Pointers, implemented in ``Pointer.h`` are represented as a tagged union.
	Some of these may not yet be available in upstream ``clang``.

	* BlockPointer: used to reference memory allocated and managed by the
	interpreter, being the only pointer kind which allows dereferencing in the
	interpreter
	* ExternPointer: points to memory which can be addressed, but not read by
	the interpreter. It is equivalent to APValue, tracking a declaration and a path
	of fields and indices into that allocation.
	* TargetPointer: represents a target address derived from a base address
	through pointer arithmetic, such as ``((int *)0x100)[20]``. Null pointers are
	target pointers with a zero offset.
	* TypeInfoPointer: tracks information for the opaque type returned by
	``typeid``
	* InvalidPointer: is dummy pointer created by an invalid operation which
	allows the interpreter to continue execution. Does not allow pointer
	arithmetic or dereferencing.

	Besides the previously mentioned union, a number of other pointer-like types
	have their own type:

	* ObjCBlockPointer tracks Objective-C blocks
	* FnPointer tracks functions and lazily caches their compiled version
	* MemberPointer tracks C++ object members

	Void pointers, which can be built by casting any of the aforementioned
	pointers, are implemented as a union of all pointer types. The ``BitCast``
	opcode is responsible for performing all legal conversions between these
	types and primitive integers.

	BlockPointer
	~~~~~~~~~~~~

	Block pointers track a ``Pointee``, the block to which they point, along
	with a ``Base`` and an ``Offset``. The base identifies the innermost field,
	while the offset points to an array element relative to the base (including
	one-past-end pointers). The offset identifies the array element or field
	which is referenced, while the base points to the outer object or array which
	contains the field. These two fields allow all pointers to be uniquely
	identified, disambiguated and characterised.

	As an example, consider the following structure:

	.. code-block:: c

	struct A {
	struct B {
	int x;
	int y;
	} b;
	struct C {
	int a;
	int b;
	} c[2];
	int z;
	};
	constexpr A a;

	On the target, ``&a`` and ``&a.b.x`` are equal. So are ``&a.c[0]`` and
	``&a.c[0].a``. In the interpreter, all these pointers must be
	distinguished since the are all allowed to address distinct range of
	memory.

	In the interpreter, the object would require 240 bytes of storage and
	would have its field interleaved with metadata. The pointers which can
	be derived to the object are illustrated in the following diagram:

	::

	0 16 32 40 56 64 80 96 112 120 136 144 160 176 184 200 208 224 240
	+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+
	+ B \| D \| D \| x \| D \| y \| D \| D \| D \| a \| D \| b \| D \| D \| a \| D \| b \| D \| z \|
	+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+
	^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^
	\| \| \| \| \| \| \| &a.c[0].b \| \| &a.c[1].b \|
	a \|&a.b.x &a.y &a.c \|&a.c[0].a \|&a.c[1].a \|
	&a.b &a.c[0] &a.c[1] &a.z

	The ``Base`` offset of all pointers points to the start of a field or
	an array and is preceded by an inline descriptor (unless ``Base`` is
	zero, pointing to the root). All the relevant attributes can be read
	from either the inline descriptor or the descriptor of the block.


	Array elements are identified by the ``Offset`` field of pointers,
	pointing to past the inline descriptors for composites and before
	the actual data in the case of primitive arrays. The ``Offset``
	points to the offset where primitives can be read from. As an example,
	``a.c + 1`` would have the same base as ``a.c`` since it is an element
	of ``a.c``, but its offset would point to ``&a.c[1]``. The
	array-to-pointer decay operation adjusts a pointer to an array (where
	the offset is equal to the base) to a pointer to the first element.

	ExternPointer
	~~~~~~~~~~~~~

	Extern pointers can be derived, pointing into symbols which are not
	readable from constexpr. An external pointer consists of a base
	declaration, along with a path designating a subobject, similar to
	the ``LValuePath`` of an APValue. Extern pointers can be converted
	to block pointers if the underlying variable is defined after the
	pointer is created, as is the case in the following example:

	.. code-block:: c

	extern const int a;
	constexpr const int *p = &a;
	const int a = 5;
	static_assert(*p == 5, "x");

	TargetPointer
	~~~~~~~~~~~~~

	While null pointer arithmetic or integer-to-pointer conversion is
	banned in constexpr, some expressions on target offsets must be folded,
	replicating the behaviour of the ``offsetof`` builtin. Target pointers
	are characterised by 3 offsets: a field offset, an array offset and a
	base offset, along with a descriptor specifying the type the pointer is
	supposed to refer to. Array indexing adjusts the array offset, while the
	field offset is adjusted when a pointer to a member is created. Casting
	an integer to a pointer sets the value of the base offset. As a special
	case, null pointers are target pointers with all offsets set to 0.

	TypeInfoPointer
	~~~~~~~~~~~~~~~

	``TypeInfoPointer`` tracks two types: the type assigned to
	``std::type_info`` and the type which was passed to ``typeinfo``.

	InvalidPointer
	~~~~~~~~~~~~~~

	Such pointers are built by operations which cannot generate valid
	pointers, allowing the interpreter to continue execution after emitting
	a warning. Inspecting such a pointer stops execution.

	TODO
	====

	Missing Language Features
	-------------------------

	* Changing the active field of unions
	* ``volatile``
	* ``__builtin_constant_p``
	* ``dynamic_cast``
	* ``new`` and ``delete``
	* Fixed Point numbers and arithmetic on Complex numbers
	* Several builtin methods, including string operations and
	``__builtin_bit_cast``
	* Continue-after-failure: a form of exception handling at the bytecode
	level should be implemented to allow execution to resume. As an example,
	argument evaluation should resume after the computation of an argument fails.
	* Pointer-to-Integer conversions
	* Lazy descriptors: the interpreter creates a ``Record`` and ``Descriptor``
	when it encounters a type: ones which are not yet defined should be lazily
	created when required

	Known Bugs
	----------

	* If execution fails, memory storing APInts and APFloats is leaked when the
	stack is cleared