include/clang/Basic/arm_neon_incl.td - llvm-project/clang - Git at Google

 //===--- arm_neon_incl.td - ARM NEON compiler interface -------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file defines data structures shared by arm_neon.td and arm_fp16.td.
 //  It constains base operation classes, operations, instructions, instruction
 //  modifiers, etc.
 //
 //===----------------------------------------------------------------------===//
 //
 // Each intrinsic is a subclass of the Inst class. An intrinsic can either
 // generate a __builtin_* call or it can expand to a set of generic operations.
 //
 // The operations are subclasses of Operation providing a list of DAGs, the
 // last of which is the return value. The available DAG nodes are documented
 // below.
 //
 //===----------------------------------------------------------------------===//

 // The base Operation class. All operations must subclass this.
 class Operation<list<dag> ops=[]> {
   list<dag> Ops = ops;
   bit Unavailable = 0;
 }
 // An operation that only contains a single DAG.
 class Op<dag op> : Operation<[op]>;
 // A shorter version of Operation - takes a list of DAGs. The last of these will
 // be the return value.
 class LOp<list<dag> ops> : Operation<ops>;

 // These defs and classes are used internally to implement the SetTheory
 // expansion and should be ignored.
 foreach Index = 0-63 in
   def sv#Index;
 class MaskExpand;

 //===----------------------------------------------------------------------===//
 // Available operations
 //===----------------------------------------------------------------------===//

 // DAG arguments can either be operations (documented below) or variables.
 // Variables are prefixed with '$'. There are variables for each input argument,
 // with the name $pN, where N starts at zero. So the zero'th argument will be
 // $p0, the first $p1 etc.

 // op - Binary or unary operator, depending on the number of arguments. The
 //      operator itself is just treated as a raw string and is not checked.
 // example: (op "+", $p0, $p1) -> "__p0 + __p1".
 //          (op "-", $p0)      -> "-__p0"
 def op;
 // call - Invoke another intrinsic. The input types are type checked and
 //        disambiguated. If there is no intrinsic defined that takes
 //        the given types (or if there is a type ambiguity) an error is
 //        generated at tblgen time. The name of the intrinsic is the raw
 //        name as given to the Inst class (not mangled).
 // example: (call "vget_high", $p0) -> "vgetq_high_s16(__p0)"
 //            (assuming $p0 has type int16x8_t).
 def call;
 // call_mangled - Invoke another intrinsic matching the mangled name variation
 //                of the caller's base type. If there is no intrinsic defined
 //                that has the variation and takes the given types, an error
 //                is generated at tblgen time.
 // example: (call_mangled "vfma_lane", $p0, $p1) -> "vfma_lane(__p0, __p1)"
 //            (assuming non-LaneQ caller)
 //          (call_mangled "vfma_lane", $p0, $p1) -> "vfma_laneq(__p0, __p1)"
 //            (assuming LaneQ caller)
 def call_mangled;
 // cast - Perform a cast to a different type. This gets emitted as a static
 //        C-style cast. For a pure reinterpret cast (T x = *(T*)&y), use
 //        "bitcast".
 //
 //        The syntax is (cast MOD* VAL). The last argument is the value to
 //        cast, preceded by a sequence of type modifiers. The target type
 //        starts off as the type of VAL, and is modified by MOD in sequence.
 //        The available modifiers are:
 //          - $X  - Take the type of parameter/variable X. For example:
 //                  (cast $p0, $p1) would cast $p1 to the type of $p0.
 //          - "R" - The type of the return type.
 //          - A typedef string - A NEON or stdint.h type that is then parsed.
 //                               for example: (cast "uint32x4_t", $p0).
 //          - "U" - Make the type unsigned.
 //          - "S" - Make the type signed.
 //          - "H" - Halve the number of lanes in the type.
 //          - "D" - Double the number of lanes in the type.
 //          - "8" - Convert type to an equivalent vector of 8-bit signed
 //                  integers.
 //          - "32" - Convert type to an equivalent vector of 32-bit integers.
 // example: (cast "R", "U", $p0) -> "(uint32x4_t)__p0" (assuming the return
 //           value is of type "int32x4_t".
 //          (cast $p0, "D", "8", $p1) -> "(int8x16_t)__p1" (assuming __p0
 //           has type float64x1_t or any other vector type of 64 bits).
 //          (cast "int32_t", $p2) -> "(int32_t)__p2"
 def cast;
 // bitcast - Same as "cast", except a reinterpret-cast is produced:
 //             (bitcast "T", $p0) -> "*(T*)&__p0".
 //           The VAL argument is saved to a temporary so it can be used
 //           as an l-value.
 def bitcast;
 // dup - Take a scalar argument and create a vector by duplicating it into
 //       all lanes. The type of the vector is the base type of the intrinsic.
 // example: (dup $p1) -> "(uint32x2_t) {__p1, __p1}" (assuming the base type
 //          is uint32x2_t).
 def dup;
 // dup_typed - Take a vector and a scalar argument, and create a new vector of
 //             the same type by duplicating the scalar value into all lanes.
 // example: (dup_typed $p1, $p2) -> "(float16x4_t) {__p2, __p2, __p2, __p2}"
 //          (assuming __p1 is float16x4_t, and __p2 is a compatible scalar).
 def dup_typed;
 // save_temp - Create a temporary (local) variable. The variable takes a name
 //             based on the zero'th parameter and can be referenced using
 //             using that name in subsequent DAGs in the same
 //             operation. The scope of a temp is the operation. If a variable
 //             with the given name already exists, an error will be given at
 //             tblgen time.
 // example: [(save_temp $var, (call "foo", $p0)),
 //           (op "+", $var, $p1)] ->
 //              "int32x2_t __var = foo(__p0); return __var + __p1;"
 def save_temp;
 // name_replace - Return the name of the current intrinsic with the first
 //                argument replaced by the second argument. Raises an error if
 //                the first argument does not exist in the intrinsic name.
 // example: (call (name_replace "_high_", "_"), $p0) (to call the non-high
 //            version of this intrinsic).
 def name_replace;
 // literal - Create a literal piece of code. The code is treated as a raw
 //           string, and must be given a type. The type is a stdint.h or
 //           NEON intrinsic type as given to (cast).
 // example: (literal "int32_t", "0")
 def literal;
 // shuffle - Create a vector shuffle. The syntax is (shuffle ARG0, ARG1, MASK).
 //           The MASK argument is a set of elements. The elements are generated
 //           from the two special defs "mask0" and "mask1". "mask0" expands to
 //           the lane indices in sequence for ARG0, and "mask1" expands to
 //           the lane indices in sequence for ARG1. They can be used as-is, e.g.
 //
 //             (shuffle $p0, $p1, mask0) -> $p0
 //             (shuffle $p0, $p1, mask1) -> $p1
 //
 //           or, more usefully, they can be manipulated using the SetTheory
 //           operators plus some extra operators defined in the NEON emitter.
 //           The operators are described below.
 // example: (shuffle $p0, $p1, (add (highhalf mask0), (highhalf mask1))) ->
 //            A concatenation of the high halves of the input vectors.
 def shuffle;

 // add, interleave, decimate: These set operators are vanilla SetTheory
 // operators and take their normal definition.
 def add;
 def interleave;
 def decimate;
 // rotl - Rotate set left by a number of elements.
 // example: (rotl mask0, 3) -> [3, 4, 5, 6, 0, 1, 2]
 def rotl;
 // rotl - Rotate set right by a number of elements.
 // example: (rotr mask0, 3) -> [4, 5, 6, 0, 1, 2, 3]
 def rotr;
 // highhalf - Take only the high half of the input.
 // example: (highhalf mask0) -> [4, 5, 6, 7] (assuming mask0 had 8 elements)
 def highhalf;
 // highhalf - Take only the low half of the input.
 // example: (lowhalf mask0) -> [0, 1, 2, 3] (assuming mask0 had 8 elements)
 def lowhalf;
 // rev - Perform a variable-width reversal of the elements. The zero'th argument
 //       is a width in bits to reverse. The lanes this maps to is determined
 //       based on the element width of the underlying type.
 // example: (rev 32, mask0) -> [3, 2, 1, 0, 7, 6, 5, 4] (if 8-bit elements)
 // example: (rev 32, mask0) -> [1, 0, 3, 2]             (if 16-bit elements)
 def rev;
 // mask0 - The initial sequence of lanes for shuffle ARG0
 def mask0 : MaskExpand;
 // mask0 - The initial sequence of lanes for shuffle ARG1
 def mask1 : MaskExpand;

 def OP_NONE  : Operation;
 def OP_UNAVAILABLE : Operation {
   let Unavailable = 1;
 }

 //===----------------------------------------------------------------------===//
 // Instruction definitions
 //===----------------------------------------------------------------------===//

 // Every intrinsic subclasses "Inst". An intrinsic has a name, a prototype and
 // a sequence of typespecs.
 //
 // The name is the base name of the intrinsic, for example "vget_lane". This is
 // then mangled by the tblgen backend to add type information ("vget_lane_s16").
 //
 // A typespec is a sequence of uppercase characters (modifiers) followed by one
 // lowercase character. A typespec encodes a particular "base type" of the
 // intrinsic.
 //
 // An example typespec is "Qs" - quad-size short - uint16x8_t. The available
 // typespec codes are given below.
 //
 // The string given to an Inst class is a sequence of typespecs. The intrinsic
 // is instantiated for every typespec in the sequence. For example "sdQsQd".
 //
 // The prototype is a string that defines the return type of the intrinsic
 // and the type of each argument. The return type and every argument gets a
 // set of "modifiers" that can change in some way the "base type" of the
 // intrinsic.
 //
 // Typespecs
 // ---------
 // c: char
 // s: short
 // i: int
 // l: long
 // k: 128-bit long
 // f: float
 // h: half-float
 // d: double
 // b: bfloat16
 //
 // Typespec modifiers
 // ------------------
 // S: scalar, only used for function mangling.
 // U: unsigned
 // Q: 128b
 // H: 128b without mangling 'q'
 // P: polynomial
 //
 // Prototype modifiers
 // -------------------
 // prototype: return (arg, arg, ...)
 //
 // Each type modifier is either a single character, or a group surrounded by
 // parentheses.
 //
 // .: default
 // v: change to void category.
 // S: change to signed integer category.
 // U: change to unsigned integer category.
 // F: change to floating category.
 // B: change to BFloat16
 // P: change to polynomial category.
 // p: change polynomial to equivalent integer category. Otherwise nop.
 //
 // >: double element width (vector size unchanged).
 // <: half element width (vector size unchanged).
 //
 // 1: change to scalar.
 // 2: change to struct of two vectors.
 // 3: change to struct of three vectors.
 // 4: change to struct of four vectors.
 //
 // *: make a pointer argument.
 // c: make a constant argument (for pointers).
 //
 // Q: force 128-bit width.
 // q: force 64-bit width.
 //
 // I: make 32-bit signed scalar immediate
 // !: make this the key type passed to CGBuiltin.cpp in a polymorphic call.


 // Every intrinsic subclasses Inst.
 class Inst <string n, string p, string t, Operation o> {
   string Name = n;
   string Prototype = p;
   string Types = t;
   string ArchGuard = "";
   string TargetGuard = "";

   Operation Operation = o;
   bit BigEndianSafe = 0;
   bit isShift = 0;
   bit isScalarShift = 0;
   bit isScalarNarrowShift = 0;
   bit isVCVT_N = 0;
   bit isVXAR = 0;
   // For immediate checks: the immediate will be assumed to specify the lane of
   // a Q register. Only used for intrinsics which end up calling polymorphic
   // builtins.
   bit isLaneQ = 0;

   // Certain intrinsics have different names than their representative
   // instructions. This field allows us to handle this correctly when we
   // are generating tests.
   string InstName = "";

   // Certain intrinsics even though they are not a WOpInst or LOpInst,
   // generate a WOpInst/LOpInst instruction (see below for definition
   // of a WOpInst/LOpInst). For testing purposes we need to know
   // this. Ex: vset_lane which outputs vmov instructions.
   bit isHiddenWInst = 0;
   bit isHiddenLInst = 0;

   string CartesianProductWith = "";
 }

 // The following instruction classes are implemented via builtins.
 // These declarations are used to generate Builtins.def:
 //
 // SInst: Instruction with signed/unsigned suffix (e.g., "s8", "u8", "p8")
 // IInst: Instruction with generic integer suffix (e.g., "i8")
 // WInst: Instruction with only bit size suffix (e.g., "8")
 class SInst<string n, string p, string t> : Inst<n, p, t, OP_NONE> {}
 class IInst<string n, string p, string t> : Inst<n, p, t, OP_NONE> {}
 class WInst<string n, string p, string t> : Inst<n, p, t, OP_NONE> {}

 // The following instruction classes are implemented via operators
 // instead of builtins. As such these declarations are only used for
 // the purpose of generating tests.
 //
 // SOpInst:       Instruction with signed/unsigned suffix (e.g., "s8",
 //                "u8", "p8").
 // IOpInst:       Instruction with generic integer suffix (e.g., "i8").
 // WOpInst:       Instruction with bit size only suffix (e.g., "8").
 // LOpInst:       Logical instruction with no bit size suffix.
 // NoTestOpInst:  Intrinsic that has no corresponding instruction.
 class SOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}
 class IOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}
 class WOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}
 class LOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}
 class NoTestOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}
	//===--- arm_neon_incl.td - ARM NEON compiler interface -------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines data structures shared by arm_neon.td and arm_fp16.td.
	// It constains base operation classes, operations, instructions, instruction
	// modifiers, etc.
	//
	//===----------------------------------------------------------------------===//
	//
	// Each intrinsic is a subclass of the Inst class. An intrinsic can either
	// generate a __builtin_* call or it can expand to a set of generic operations.
	//
	// The operations are subclasses of Operation providing a list of DAGs, the
	// last of which is the return value. The available DAG nodes are documented
	// below.
	//
	//===----------------------------------------------------------------------===//

	// The base Operation class. All operations must subclass this.
	class Operation<list<dag> ops=[]> {
	list<dag> Ops = ops;
	bit Unavailable = 0;
	}
	// An operation that only contains a single DAG.
	class Op<dag op> : Operation<[op]>;
	// A shorter version of Operation - takes a list of DAGs. The last of these will
	// be the return value.
	class LOp<list<dag> ops> : Operation<ops>;

	// These defs and classes are used internally to implement the SetTheory
	// expansion and should be ignored.
	foreach Index = 0-63 in
	def sv#Index;
	class MaskExpand;

	//===----------------------------------------------------------------------===//
	// Available operations
	//===----------------------------------------------------------------------===//

	// DAG arguments can either be operations (documented below) or variables.
	// Variables are prefixed with '$'. There are variables for each input argument,
	// with the name $pN, where N starts at zero. So the zero'th argument will be
	// $p0, the first $p1 etc.

	// op - Binary or unary operator, depending on the number of arguments. The
	// operator itself is just treated as a raw string and is not checked.
	// example: (op "+", $p0, $p1) -> "__p0 + __p1".
	// (op "-", $p0) -> "-__p0"
	def op;
	// call - Invoke another intrinsic. The input types are type checked and
	// disambiguated. If there is no intrinsic defined that takes
	// the given types (or if there is a type ambiguity) an error is
	// generated at tblgen time. The name of the intrinsic is the raw
	// name as given to the Inst class (not mangled).
	// example: (call "vget_high", $p0) -> "vgetq_high_s16(__p0)"
	// (assuming $p0 has type int16x8_t).
	def call;
	// call_mangled - Invoke another intrinsic matching the mangled name variation
	// of the caller's base type. If there is no intrinsic defined
	// that has the variation and takes the given types, an error
	// is generated at tblgen time.
	// example: (call_mangled "vfma_lane", $p0, $p1) -> "vfma_lane(__p0, __p1)"
	// (assuming non-LaneQ caller)
	// (call_mangled "vfma_lane", $p0, $p1) -> "vfma_laneq(__p0, __p1)"
	// (assuming LaneQ caller)
	def call_mangled;
	// cast - Perform a cast to a different type. This gets emitted as a static
	// C-style cast. For a pure reinterpret cast (T x = (T)&y), use
	// "bitcast".
	//
	// The syntax is (cast MOD* VAL). The last argument is the value to
	// cast, preceded by a sequence of type modifiers. The target type
	// starts off as the type of VAL, and is modified by MOD in sequence.
	// The available modifiers are:
	// - $X - Take the type of parameter/variable X. For example:
	// (cast $p0, $p1) would cast $p1 to the type of $p0.
	// - "R" - The type of the return type.
	// - A typedef string - A NEON or stdint.h type that is then parsed.
	// for example: (cast "uint32x4_t", $p0).
	// - "U" - Make the type unsigned.
	// - "S" - Make the type signed.
	// - "H" - Halve the number of lanes in the type.
	// - "D" - Double the number of lanes in the type.
	// - "8" - Convert type to an equivalent vector of 8-bit signed
	// integers.
	// - "32" - Convert type to an equivalent vector of 32-bit integers.
	// example: (cast "R", "U", $p0) -> "(uint32x4_t)__p0" (assuming the return
	// value is of type "int32x4_t".
	// (cast $p0, "D", "8", $p1) -> "(int8x16_t)__p1" (assuming __p0
	// has type float64x1_t or any other vector type of 64 bits).
	// (cast "int32_t", $p2) -> "(int32_t)__p2"
	def cast;
	// bitcast - Same as "cast", except a reinterpret-cast is produced:
	// (bitcast "T", $p0) -> "(T)&__p0".
	// The VAL argument is saved to a temporary so it can be used
	// as an l-value.
	def bitcast;
	// dup - Take a scalar argument and create a vector by duplicating it into
	// all lanes. The type of the vector is the base type of the intrinsic.
	// example: (dup $p1) -> "(uint32x2_t) {__p1, __p1}" (assuming the base type
	// is uint32x2_t).
	def dup;
	// dup_typed - Take a vector and a scalar argument, and create a new vector of
	// the same type by duplicating the scalar value into all lanes.
	// example: (dup_typed $p1, $p2) -> "(float16x4_t) {__p2, __p2, __p2, __p2}"
	// (assuming __p1 is float16x4_t, and __p2 is a compatible scalar).
	def dup_typed;
	// save_temp - Create a temporary (local) variable. The variable takes a name
	// based on the zero'th parameter and can be referenced using
	// using that name in subsequent DAGs in the same
	// operation. The scope of a temp is the operation. If a variable
	// with the given name already exists, an error will be given at
	// tblgen time.
	// example: [(save_temp $var, (call "foo", $p0)),
	// (op "+", $var, $p1)] ->
	// "int32x2_t __var = foo(__p0); return __var + __p1;"
	def save_temp;
	// name_replace - Return the name of the current intrinsic with the first
	// argument replaced by the second argument. Raises an error if
	// the first argument does not exist in the intrinsic name.
	// example: (call (name_replace "_high_", "_"), $p0) (to call the non-high
	// version of this intrinsic).
	def name_replace;
	// literal - Create a literal piece of code. The code is treated as a raw
	// string, and must be given a type. The type is a stdint.h or
	// NEON intrinsic type as given to (cast).
	// example: (literal "int32_t", "0")
	def literal;
	// shuffle - Create a vector shuffle. The syntax is (shuffle ARG0, ARG1, MASK).
	// The MASK argument is a set of elements. The elements are generated
	// from the two special defs "mask0" and "mask1". "mask0" expands to
	// the lane indices in sequence for ARG0, and "mask1" expands to
	// the lane indices in sequence for ARG1. They can be used as-is, e.g.
	//
	// (shuffle $p0, $p1, mask0) -> $p0
	// (shuffle $p0, $p1, mask1) -> $p1
	//
	// or, more usefully, they can be manipulated using the SetTheory
	// operators plus some extra operators defined in the NEON emitter.
	// The operators are described below.
	// example: (shuffle $p0, $p1, (add (highhalf mask0), (highhalf mask1))) ->
	// A concatenation of the high halves of the input vectors.
	def shuffle;

	// add, interleave, decimate: These set operators are vanilla SetTheory
	// operators and take their normal definition.
	def add;
	def interleave;
	def decimate;
	// rotl - Rotate set left by a number of elements.
	// example: (rotl mask0, 3) -> [3, 4, 5, 6, 0, 1, 2]
	def rotl;
	// rotl - Rotate set right by a number of elements.
	// example: (rotr mask0, 3) -> [4, 5, 6, 0, 1, 2, 3]
	def rotr;
	// highhalf - Take only the high half of the input.
	// example: (highhalf mask0) -> [4, 5, 6, 7] (assuming mask0 had 8 elements)
	def highhalf;
	// highhalf - Take only the low half of the input.
	// example: (lowhalf mask0) -> [0, 1, 2, 3] (assuming mask0 had 8 elements)
	def lowhalf;
	// rev - Perform a variable-width reversal of the elements. The zero'th argument
	// is a width in bits to reverse. The lanes this maps to is determined
	// based on the element width of the underlying type.
	// example: (rev 32, mask0) -> [3, 2, 1, 0, 7, 6, 5, 4] (if 8-bit elements)
	// example: (rev 32, mask0) -> [1, 0, 3, 2] (if 16-bit elements)
	def rev;
	// mask0 - The initial sequence of lanes for shuffle ARG0
	def mask0 : MaskExpand;
	// mask0 - The initial sequence of lanes for shuffle ARG1
	def mask1 : MaskExpand;

	def OP_NONE : Operation;
	def OP_UNAVAILABLE : Operation {
	let Unavailable = 1;
	}

	//===----------------------------------------------------------------------===//
	// Instruction definitions
	//===----------------------------------------------------------------------===//

	// Every intrinsic subclasses "Inst". An intrinsic has a name, a prototype and
	// a sequence of typespecs.
	//
	// The name is the base name of the intrinsic, for example "vget_lane". This is
	// then mangled by the tblgen backend to add type information ("vget_lane_s16").
	//
	// A typespec is a sequence of uppercase characters (modifiers) followed by one
	// lowercase character. A typespec encodes a particular "base type" of the
	// intrinsic.
	//
	// An example typespec is "Qs" - quad-size short - uint16x8_t. The available
	// typespec codes are given below.
	//
	// The string given to an Inst class is a sequence of typespecs. The intrinsic
	// is instantiated for every typespec in the sequence. For example "sdQsQd".
	//
	// The prototype is a string that defines the return type of the intrinsic
	// and the type of each argument. The return type and every argument gets a
	// set of "modifiers" that can change in some way the "base type" of the
	// intrinsic.
	//
	// Typespecs
	// ---------
	// c: char
	// s: short
	// i: int
	// l: long
	// k: 128-bit long
	// f: float
	// h: half-float
	// d: double
	// b: bfloat16
	//
	// Typespec modifiers
	// ------------------
	// S: scalar, only used for function mangling.
	// U: unsigned
	// Q: 128b
	// H: 128b without mangling 'q'
	// P: polynomial
	//
	// Prototype modifiers
	// -------------------
	// prototype: return (arg, arg, ...)
	//
	// Each type modifier is either a single character, or a group surrounded by
	// parentheses.
	//
	// .: default
	// v: change to void category.
	// S: change to signed integer category.
	// U: change to unsigned integer category.
	// F: change to floating category.
	// B: change to BFloat16
	// P: change to polynomial category.
	// p: change polynomial to equivalent integer category. Otherwise nop.
	//
	// >: double element width (vector size unchanged).
	// <: half element width (vector size unchanged).
	//
	// 1: change to scalar.
	// 2: change to struct of two vectors.
	// 3: change to struct of three vectors.
	// 4: change to struct of four vectors.
	//
	// *: make a pointer argument.
	// c: make a constant argument (for pointers).
	//
	// Q: force 128-bit width.
	// q: force 64-bit width.
	//
	// I: make 32-bit signed scalar immediate
	// !: make this the key type passed to CGBuiltin.cpp in a polymorphic call.


	// Every intrinsic subclasses Inst.
	class Inst <string n, string p, string t, Operation o> {
	string Name = n;
	string Prototype = p;
	string Types = t;
	string ArchGuard = "";
	string TargetGuard = "";

	Operation Operation = o;
	bit BigEndianSafe = 0;
	bit isShift = 0;
	bit isScalarShift = 0;
	bit isScalarNarrowShift = 0;
	bit isVCVT_N = 0;
	bit isVXAR = 0;
	// For immediate checks: the immediate will be assumed to specify the lane of
	// a Q register. Only used for intrinsics which end up calling polymorphic
	// builtins.
	bit isLaneQ = 0;

	// Certain intrinsics have different names than their representative
	// instructions. This field allows us to handle this correctly when we
	// are generating tests.
	string InstName = "";

	// Certain intrinsics even though they are not a WOpInst or LOpInst,
	// generate a WOpInst/LOpInst instruction (see below for definition
	// of a WOpInst/LOpInst). For testing purposes we need to know
	// this. Ex: vset_lane which outputs vmov instructions.
	bit isHiddenWInst = 0;
	bit isHiddenLInst = 0;

	string CartesianProductWith = "";
	}

	// The following instruction classes are implemented via builtins.
	// These declarations are used to generate Builtins.def:
	//
	// SInst: Instruction with signed/unsigned suffix (e.g., "s8", "u8", "p8")
	// IInst: Instruction with generic integer suffix (e.g., "i8")
	// WInst: Instruction with only bit size suffix (e.g., "8")
	class SInst<string n, string p, string t> : Inst<n, p, t, OP_NONE> {}
	class IInst<string n, string p, string t> : Inst<n, p, t, OP_NONE> {}
	class WInst<string n, string p, string t> : Inst<n, p, t, OP_NONE> {}

	// The following instruction classes are implemented via operators
	// instead of builtins. As such these declarations are only used for
	// the purpose of generating tests.
	//
	// SOpInst: Instruction with signed/unsigned suffix (e.g., "s8",
	// "u8", "p8").
	// IOpInst: Instruction with generic integer suffix (e.g., "i8").
	// WOpInst: Instruction with bit size only suffix (e.g., "8").
	// LOpInst: Logical instruction with no bit size suffix.
	// NoTestOpInst: Intrinsic that has no corresponding instruction.
	class SOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}
	class IOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}
	class WOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}
	class LOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}
	class NoTestOpInst<string n, string p, string t, Operation o> : Inst<n, p, t, o> {}