llvm/lib/Analysis/VFABIDemangling.cpp - llvm-project - Git at Google

 //===- VFABIDemangling.cpp - Vector Function ABI demangling utilities. ---===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ADT/SmallSet.h"
 #include "llvm/ADT/SmallString.h"
 #include "llvm/Analysis/VectorUtils.h"

 using namespace llvm;

 namespace {
 /// Utilities for the Vector Function ABI name parser.

 /// Return types for the parser functions.
 enum class ParseRet {
   OK,   // Found.
   None, // Not found.
   Error // Syntax error.
 };

 /// Extracts the `<isa>` information from the mangled string, and
 /// sets the `ISA` accordingly.
 ParseRet tryParseISA(StringRef &MangledName, VFISAKind &ISA) {
   if (MangledName.empty())
     return ParseRet::Error;

   if (MangledName.startswith(VFABI::_LLVM_)) {
     MangledName = MangledName.drop_front(strlen(VFABI::_LLVM_));
     ISA = VFISAKind::LLVM;
   } else {
     ISA = StringSwitch<VFISAKind>(MangledName.take_front(1))
               .Case("n", VFISAKind::AdvancedSIMD)
               .Case("s", VFISAKind::SVE)
               .Case("b", VFISAKind::SSE)
               .Case("c", VFISAKind::AVX)
               .Case("d", VFISAKind::AVX2)
               .Case("e", VFISAKind::AVX512)
               .Default(VFISAKind::Unknown);
     MangledName = MangledName.drop_front(1);
   }

   return ParseRet::OK;
 }

 /// Extracts the `<mask>` information from the mangled string, and
 /// sets `IsMasked` accordingly. The input string `MangledName` is
 /// left unmodified.
 ParseRet tryParseMask(StringRef &MangledName, bool &IsMasked) {
   if (MangledName.consume_front("M")) {
     IsMasked = true;
     return ParseRet::OK;
   }

   if (MangledName.consume_front("N")) {
     IsMasked = false;
     return ParseRet::OK;
   }

   return ParseRet::Error;
 }

 /// Extract the `<vlen>` information from the mangled string, and
 /// sets `VF` accordingly. A `<vlen> == "x"` token is interpreted as a scalable
 /// vector length. On success, the `<vlen>` token is removed from
 /// the input string `ParseString`.
 ///
 ParseRet tryParseVLEN(StringRef &ParseString, unsigned &VF, bool &IsScalable) {
   if (ParseString.consume_front("x")) {
     // Set VF to 0, to be later adjusted to a value grater than zero
     // by looking at the signature of the vector function with
     // `getECFromSignature`.
     VF = 0;
     IsScalable = true;
     return ParseRet::OK;
   }

   if (ParseString.consumeInteger(10, VF))
     return ParseRet::Error;

   // The token `0` is invalid for VLEN.
   if (VF == 0)
     return ParseRet::Error;

   IsScalable = false;
   return ParseRet::OK;
 }

 /// The function looks for the following strings at the beginning of
 /// the input string `ParseString`:
 ///
 ///  <token> <number>
 ///
 /// On success, it removes the parsed parameter from `ParseString`,
 /// sets `PKind` to the correspondent enum value, sets `Pos` to
 /// <number>, and return success.  On a syntax error, it return a
 /// parsing error. If nothing is parsed, it returns None.
 ///
 /// The function expects <token> to be one of "ls", "Rs", "Us" or
 /// "Ls".
 ParseRet tryParseLinearTokenWithRuntimeStep(StringRef &ParseString,
                                             VFParamKind &PKind, int &Pos,
                                             const StringRef Token) {
   if (ParseString.consume_front(Token)) {
     PKind = VFABI::getVFParamKindFromString(Token);
     if (ParseString.consumeInteger(10, Pos))
       return ParseRet::Error;
     return ParseRet::OK;
   }

   return ParseRet::None;
 }

 /// The function looks for the following stringt at the beginning of
 /// the input string `ParseString`:
 ///
 ///  <token> <number>
 ///
 /// <token> is one of "ls", "Rs", "Us" or "Ls".
 ///
 /// On success, it removes the parsed parameter from `ParseString`,
 /// sets `PKind` to the correspondent enum value, sets `StepOrPos` to
 /// <number>, and return success.  On a syntax error, it return a
 /// parsing error. If nothing is parsed, it returns None.
 ParseRet tryParseLinearWithRuntimeStep(StringRef &ParseString,
                                        VFParamKind &PKind, int &StepOrPos) {
   ParseRet Ret;

   // "ls" <RuntimeStepPos>
   Ret = tryParseLinearTokenWithRuntimeStep(ParseString, PKind, StepOrPos, "ls");
   if (Ret != ParseRet::None)
     return Ret;

   // "Rs" <RuntimeStepPos>
   Ret = tryParseLinearTokenWithRuntimeStep(ParseString, PKind, StepOrPos, "Rs");
   if (Ret != ParseRet::None)
     return Ret;

   // "Ls" <RuntimeStepPos>
   Ret = tryParseLinearTokenWithRuntimeStep(ParseString, PKind, StepOrPos, "Ls");
   if (Ret != ParseRet::None)
     return Ret;

   // "Us" <RuntimeStepPos>
   Ret = tryParseLinearTokenWithRuntimeStep(ParseString, PKind, StepOrPos, "Us");
   if (Ret != ParseRet::None)
     return Ret;

   return ParseRet::None;
 }

 /// The function looks for the following strings at the beginning of
 /// the input string `ParseString`:
 ///
 ///  <token> {"n"} <number>
 ///
 /// On success, it removes the parsed parameter from `ParseString`,
 /// sets `PKind` to the correspondent enum value, sets `LinearStep` to
 /// <number>, and return success.  On a syntax error, it return a
 /// parsing error. If nothing is parsed, it returns None.
 ///
 /// The function expects <token> to be one of "l", "R", "U" or
 /// "L".
 ParseRet tryParseCompileTimeLinearToken(StringRef &ParseString,
                                         VFParamKind &PKind, int &LinearStep,
                                         const StringRef Token) {
   if (ParseString.consume_front(Token)) {
     PKind = VFABI::getVFParamKindFromString(Token);
     const bool Negate = ParseString.consume_front("n");
     if (ParseString.consumeInteger(10, LinearStep))
       LinearStep = 1;
     if (Negate)
       LinearStep *= -1;
     return ParseRet::OK;
   }

   return ParseRet::None;
 }

 /// The function looks for the following strings at the beginning of
 /// the input string `ParseString`:
 ///
 /// ["l" | "R" | "U" | "L"] {"n"} <number>
 ///
 /// On success, it removes the parsed parameter from `ParseString`,
 /// sets `PKind` to the correspondent enum value, sets `LinearStep` to
 /// <number>, and return success.  On a syntax error, it return a
 /// parsing error. If nothing is parsed, it returns None.
 ParseRet tryParseLinearWithCompileTimeStep(StringRef &ParseString,
                                            VFParamKind &PKind, int &StepOrPos) {
   // "l" {"n"} <CompileTimeStep>
   if (tryParseCompileTimeLinearToken(ParseString, PKind, StepOrPos, "l") ==
       ParseRet::OK)
     return ParseRet::OK;

   // "R" {"n"} <CompileTimeStep>
   if (tryParseCompileTimeLinearToken(ParseString, PKind, StepOrPos, "R") ==
       ParseRet::OK)
     return ParseRet::OK;

   // "L" {"n"} <CompileTimeStep>
   if (tryParseCompileTimeLinearToken(ParseString, PKind, StepOrPos, "L") ==
       ParseRet::OK)
     return ParseRet::OK;

   // "U" {"n"} <CompileTimeStep>
   if (tryParseCompileTimeLinearToken(ParseString, PKind, StepOrPos, "U") ==
       ParseRet::OK)
     return ParseRet::OK;

   return ParseRet::None;
 }

 /// Looks into the <parameters> part of the mangled name in search
 /// for valid paramaters at the beginning of the string
 /// `ParseString`.
 ///
 /// On success, it removes the parsed parameter from `ParseString`,
 /// sets `PKind` to the correspondent enum value, sets `StepOrPos`
 /// accordingly, and return success.  On a syntax error, it return a
 /// parsing error. If nothing is parsed, it returns None.
 ParseRet tryParseParameter(StringRef &ParseString, VFParamKind &PKind,
                            int &StepOrPos) {
   if (ParseString.consume_front("v")) {
     PKind = VFParamKind::Vector;
     StepOrPos = 0;
     return ParseRet::OK;
   }

   if (ParseString.consume_front("u")) {
     PKind = VFParamKind::OMP_Uniform;
     StepOrPos = 0;
     return ParseRet::OK;
   }

   const ParseRet HasLinearRuntime =
       tryParseLinearWithRuntimeStep(ParseString, PKind, StepOrPos);
   if (HasLinearRuntime != ParseRet::None)
     return HasLinearRuntime;

   const ParseRet HasLinearCompileTime =
       tryParseLinearWithCompileTimeStep(ParseString, PKind, StepOrPos);
   if (HasLinearCompileTime != ParseRet::None)
     return HasLinearCompileTime;

   return ParseRet::None;
 }

 /// Looks into the <parameters> part of the mangled name in search
 /// of a valid 'aligned' clause. The function should be invoked
 /// after parsing a parameter via `tryParseParameter`.
 ///
 /// On success, it removes the parsed parameter from `ParseString`,
 /// sets `PKind` to the correspondent enum value, sets `StepOrPos`
 /// accordingly, and return success.  On a syntax error, it return a
 /// parsing error. If nothing is parsed, it returns None.
 ParseRet tryParseAlign(StringRef &ParseString, Align &Alignment) {
   uint64_t Val;
   //    "a" <number>
   if (ParseString.consume_front("a")) {
     if (ParseString.consumeInteger(10, Val))
       return ParseRet::Error;

     if (!isPowerOf2_64(Val))
       return ParseRet::Error;

     Alignment = Align(Val);

     return ParseRet::OK;
   }

   return ParseRet::None;
 }
 #ifndef NDEBUG
 // Verify the assumtion that all vectors in the signature of a vector
 // function have the same number of elements.
 bool verifyAllVectorsHaveSameWidth(FunctionType *Signature) {
   SmallVector<VectorType *, 2> VecTys;
   if (auto *RetTy = dyn_cast<VectorType>(Signature->getReturnType()))
     VecTys.push_back(RetTy);
   for (auto *Ty : Signature->params())
     if (auto *VTy = dyn_cast<VectorType>(Ty))
       VecTys.push_back(VTy);

   if (VecTys.size() <= 1)
     return true;

   assert(VecTys.size() > 1 && "Invalid number of elements.");
   const ElementCount EC = VecTys[0]->getElementCount();
   return llvm::all_of(llvm::drop_begin(VecTys), [&EC](VectorType *VTy) {
     return (EC == VTy->getElementCount());
   });
 }

 #endif // NDEBUG

 // Extract the VectorizationFactor from a given function signature,
 // under the assumtion that all vectors have the same number of
 // elements, i.e. same ElementCount.Min.
 ElementCount getECFromSignature(FunctionType *Signature) {
   assert(verifyAllVectorsHaveSameWidth(Signature) &&
          "Invalid vector signature.");

   if (auto *RetTy = dyn_cast<VectorType>(Signature->getReturnType()))
     return RetTy->getElementCount();
   for (auto *Ty : Signature->params())
     if (auto *VTy = dyn_cast<VectorType>(Ty))
       return VTy->getElementCount();

   return ElementCount::getFixed(/*Min=*/1);
 }
 } // namespace

 // Format of the ABI name:
 // _ZGV<isa><mask><vlen><parameters>_<scalarname>[(<redirection>)]
 Optional<VFInfo> VFABI::tryDemangleForVFABI(StringRef MangledName,
                                             const Module &M) {
   const StringRef OriginalName = MangledName;
   // Assume there is no custom name <redirection>, and therefore the
   // vector name consists of
   // _ZGV<isa><mask><vlen><parameters>_<scalarname>.
   StringRef VectorName = MangledName;

   // Parse the fixed size part of the manled name
   if (!MangledName.consume_front("_ZGV"))
     return None;

   // Extract ISA. An unknow ISA is also supported, so we accept all
   // values.
   VFISAKind ISA;
   if (tryParseISA(MangledName, ISA) != ParseRet::OK)
     return None;

   // Extract <mask>.
   bool IsMasked;
   if (tryParseMask(MangledName, IsMasked) != ParseRet::OK)
     return None;

   // Parse the variable size, starting from <vlen>.
   unsigned VF;
   bool IsScalable;
   if (tryParseVLEN(MangledName, VF, IsScalable) != ParseRet::OK)
     return None;

   // Parse the <parameters>.
   ParseRet ParamFound;
   SmallVector<VFParameter, 8> Parameters;
   do {
     const unsigned ParameterPos = Parameters.size();
     VFParamKind PKind;
     int StepOrPos;
     ParamFound = tryParseParameter(MangledName, PKind, StepOrPos);

     // Bail off if there is a parsing error in the parsing of the parameter.
     if (ParamFound == ParseRet::Error)
       return None;

     if (ParamFound == ParseRet::OK) {
       Align Alignment;
       // Look for the alignment token "a <number>".
       const ParseRet AlignFound = tryParseAlign(MangledName, Alignment);
       // Bail off if there is a syntax error in the align token.
       if (AlignFound == ParseRet::Error)
         return None;

       // Add the parameter.
       Parameters.push_back({ParameterPos, PKind, StepOrPos, Alignment});
     }
   } while (ParamFound == ParseRet::OK);

   // A valid MangledName must have at least one valid entry in the
   // <parameters>.
   if (Parameters.empty())
     return None;

   // Check for the <scalarname> and the optional <redirection>, which
   // are separated from the prefix with "_"
   if (!MangledName.consume_front("_"))
     return None;

   // The rest of the string must be in the format:
   // <scalarname>[(<redirection>)]
   const StringRef ScalarName =
       MangledName.take_while([](char In) { return In != '('; });

   if (ScalarName.empty())
     return None;

   // Reduce MangledName to [(<redirection>)].
   MangledName = MangledName.ltrim(ScalarName);
   // Find the optional custom name redirection.
   if (MangledName.consume_front("(")) {
     if (!MangledName.consume_back(")"))
       return None;
     // Update the vector variant with the one specified by the user.
     VectorName = MangledName;
     // If the vector name is missing, bail out.
     if (VectorName.empty())
       return None;
   }

   // LLVM internal mapping via the TargetLibraryInfo (TLI) must be
   // redirected to an existing name.
   if (ISA == VFISAKind::LLVM && VectorName == OriginalName)
     return None;

   // When <mask> is "M", we need to add a parameter that is used as
   // global predicate for the function.
   if (IsMasked) {
     const unsigned Pos = Parameters.size();
     Parameters.push_back({Pos, VFParamKind::GlobalPredicate});
   }

   // Asserts for parameters of type `VFParamKind::GlobalPredicate`, as
   // prescribed by the Vector Function ABI specifications supported by
   // this parser:
   // 1. Uniqueness.
   // 2. Must be the last in the parameter list.
   const auto NGlobalPreds = std::count_if(
       Parameters.begin(), Parameters.end(), [](const VFParameter PK) {
         return PK.ParamKind == VFParamKind::GlobalPredicate;
       });
   assert(NGlobalPreds < 2 && "Cannot have more than one global predicate.");
   if (NGlobalPreds)
     assert(Parameters.back().ParamKind == VFParamKind::GlobalPredicate &&
            "The global predicate must be the last parameter");

   // Adjust the VF for scalable signatures. The EC.Min is not encoded
   // in the name of the function, but it is encoded in the IR
   // signature of the function. We need to extract this information
   // because it is needed by the loop vectorizer, which reasons in
   // terms of VectorizationFactor or ElementCount. In particular, we
   // need to make sure that the VF field of the VFShape class is never
   // set to 0.
   if (IsScalable) {
     const Function *F = M.getFunction(VectorName);
     // The declaration of the function must be present in the module
     // to be able to retrieve its signature.
     if (!F)
       return None;
     const ElementCount EC = getECFromSignature(F->getFunctionType());
     VF = EC.getKnownMinValue();
   }

   // 1. We don't accept a zero lanes vectorization factor.
   // 2. We don't accept the demangling if the vector function is not
   // present in the module.
   if (VF == 0)
     return None;
   if (!M.getFunction(VectorName))
     return None;

   const VFShape Shape({ElementCount::get(VF, IsScalable), Parameters});
   return VFInfo({Shape, std::string(ScalarName), std::string(VectorName), ISA});
 }

 VFParamKind VFABI::getVFParamKindFromString(const StringRef Token) {
   const VFParamKind ParamKind = StringSwitch<VFParamKind>(Token)
                                     .Case("v", VFParamKind::Vector)
                                     .Case("l", VFParamKind::OMP_Linear)
                                     .Case("R", VFParamKind::OMP_LinearRef)
                                     .Case("L", VFParamKind::OMP_LinearVal)
                                     .Case("U", VFParamKind::OMP_LinearUVal)
                                     .Case("ls", VFParamKind::OMP_LinearPos)
                                     .Case("Ls", VFParamKind::OMP_LinearValPos)
                                     .Case("Rs", VFParamKind::OMP_LinearRefPos)
                                     .Case("Us", VFParamKind::OMP_LinearUValPos)
                                     .Case("u", VFParamKind::OMP_Uniform)
                                     .Default(VFParamKind::Unknown);

   if (ParamKind != VFParamKind::Unknown)
     return ParamKind;

   // This function should never be invoked with an invalid input.
   llvm_unreachable("This fuction should be invoken only on parameters"
                    " that have a textual representation in the mangled name"
                    " of the Vector Function ABI");
 }
	//===- VFABIDemangling.cpp - Vector Function ABI demangling utilities. ---===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ADT/SmallSet.h"
	#include "llvm/ADT/SmallString.h"
	#include "llvm/Analysis/VectorUtils.h"

	using namespace llvm;

	namespace {
	/// Utilities for the Vector Function ABI name parser.

	/// Return types for the parser functions.
	enum class ParseRet {
	OK, // Found.
	None, // Not found.
	Error // Syntax error.
	};

	/// Extracts the `<isa>` information from the mangled string, and
	/// sets the `ISA` accordingly.
	ParseRet tryParseISA(StringRef &MangledName, VFISAKind &ISA) {
	if (MangledName.empty())
	return ParseRet::Error;

	if (MangledName.startswith(VFABI::_LLVM_)) {
	MangledName = MangledName.drop_front(strlen(VFABI::_LLVM_));
	ISA = VFISAKind::LLVM;
	} else {
	ISA = StringSwitch<VFISAKind>(MangledName.take_front(1))
	.Case("n", VFISAKind::AdvancedSIMD)
	.Case("s", VFISAKind::SVE)
	.Case("b", VFISAKind::SSE)
	.Case("c", VFISAKind::AVX)
	.Case("d", VFISAKind::AVX2)
	.Case("e", VFISAKind::AVX512)
	.Default(VFISAKind::Unknown);
	MangledName = MangledName.drop_front(1);
	}

	return ParseRet::OK;
	}

	/// Extracts the `<mask>` information from the mangled string, and
	/// sets `IsMasked` accordingly. The input string `MangledName` is
	/// left unmodified.
	ParseRet tryParseMask(StringRef &MangledName, bool &IsMasked) {
	if (MangledName.consume_front("M")) {
	IsMasked = true;
	return ParseRet::OK;
	}

	if (MangledName.consume_front("N")) {
	IsMasked = false;
	return ParseRet::OK;
	}

	return ParseRet::Error;
	}

	/// Extract the `<vlen>` information from the mangled string, and
	/// sets `VF` accordingly. A `<vlen> == "x"` token is interpreted as a scalable
	/// vector length. On success, the `<vlen>` token is removed from
	/// the input string `ParseString`.
	///
	ParseRet tryParseVLEN(StringRef &ParseString, unsigned &VF, bool &IsScalable) {
	if (ParseString.consume_front("x")) {
	// Set VF to 0, to be later adjusted to a value grater than zero
	// by looking at the signature of the vector function with
	// `getECFromSignature`.
	VF = 0;
	IsScalable = true;
	return ParseRet::OK;
	}

	if (ParseString.consumeInteger(10, VF))
	return ParseRet::Error;

	// The token `0` is invalid for VLEN.
	if (VF == 0)
	return ParseRet::Error;

	IsScalable = false;
	return ParseRet::OK;
	}

	/// The function looks for the following strings at the beginning of
	/// the input string `ParseString`:
	///
	/// <token> <number>
	///
	/// On success, it removes the parsed parameter from `ParseString`,
	/// sets `PKind` to the correspondent enum value, sets `Pos` to
	/// <number>, and return success. On a syntax error, it return a
	/// parsing error. If nothing is parsed, it returns None.
	///
	/// The function expects <token> to be one of "ls", "Rs", "Us" or
	/// "Ls".
	ParseRet tryParseLinearTokenWithRuntimeStep(StringRef &ParseString,
	VFParamKind &PKind, int &Pos,
	const StringRef Token) {
	if (ParseString.consume_front(Token)) {
	PKind = VFABI::getVFParamKindFromString(Token);
	if (ParseString.consumeInteger(10, Pos))
	return ParseRet::Error;
	return ParseRet::OK;
	}

	return ParseRet::None;
	}

	/// The function looks for the following stringt at the beginning of
	/// the input string `ParseString`:
	///
	/// <token> <number>
	///
	/// <token> is one of "ls", "Rs", "Us" or "Ls".
	///
	/// On success, it removes the parsed parameter from `ParseString`,
	/// sets `PKind` to the correspondent enum value, sets `StepOrPos` to
	/// <number>, and return success. On a syntax error, it return a
	/// parsing error. If nothing is parsed, it returns None.
	ParseRet tryParseLinearWithRuntimeStep(StringRef &ParseString,
	VFParamKind &PKind, int &StepOrPos) {
	ParseRet Ret;

	// "ls" <RuntimeStepPos>
	Ret = tryParseLinearTokenWithRuntimeStep(ParseString, PKind, StepOrPos, "ls");
	if (Ret != ParseRet::None)
	return Ret;

	// "Rs" <RuntimeStepPos>
	Ret = tryParseLinearTokenWithRuntimeStep(ParseString, PKind, StepOrPos, "Rs");
	if (Ret != ParseRet::None)
	return Ret;

	// "Ls" <RuntimeStepPos>
	Ret = tryParseLinearTokenWithRuntimeStep(ParseString, PKind, StepOrPos, "Ls");
	if (Ret != ParseRet::None)
	return Ret;

	// "Us" <RuntimeStepPos>
	Ret = tryParseLinearTokenWithRuntimeStep(ParseString, PKind, StepOrPos, "Us");
	if (Ret != ParseRet::None)
	return Ret;

	return ParseRet::None;
	}

	/// The function looks for the following strings at the beginning of
	/// the input string `ParseString`:
	///
	/// <token> {"n"} <number>
	///
	/// On success, it removes the parsed parameter from `ParseString`,
	/// sets `PKind` to the correspondent enum value, sets `LinearStep` to
	/// <number>, and return success. On a syntax error, it return a
	/// parsing error. If nothing is parsed, it returns None.
	///
	/// The function expects <token> to be one of "l", "R", "U" or
	/// "L".
	ParseRet tryParseCompileTimeLinearToken(StringRef &ParseString,
	VFParamKind &PKind, int &LinearStep,
	const StringRef Token) {
	if (ParseString.consume_front(Token)) {
	PKind = VFABI::getVFParamKindFromString(Token);
	const bool Negate = ParseString.consume_front("n");
	if (ParseString.consumeInteger(10, LinearStep))
	LinearStep = 1;
	if (Negate)
	LinearStep *= -1;
	return ParseRet::OK;
	}

	return ParseRet::None;
	}

	/// The function looks for the following strings at the beginning of
	/// the input string `ParseString`:
	///
	/// ["l" \| "R" \| "U" \| "L"] {"n"} <number>
	///
	/// On success, it removes the parsed parameter from `ParseString`,
	/// sets `PKind` to the correspondent enum value, sets `LinearStep` to
	/// <number>, and return success. On a syntax error, it return a
	/// parsing error. If nothing is parsed, it returns None.
	ParseRet tryParseLinearWithCompileTimeStep(StringRef &ParseString,
	VFParamKind &PKind, int &StepOrPos) {
	// "l" {"n"} <CompileTimeStep>
	if (tryParseCompileTimeLinearToken(ParseString, PKind, StepOrPos, "l") ==
	ParseRet::OK)
	return ParseRet::OK;

	// "R" {"n"} <CompileTimeStep>
	if (tryParseCompileTimeLinearToken(ParseString, PKind, StepOrPos, "R") ==
	ParseRet::OK)
	return ParseRet::OK;

	// "L" {"n"} <CompileTimeStep>
	if (tryParseCompileTimeLinearToken(ParseString, PKind, StepOrPos, "L") ==
	ParseRet::OK)
	return ParseRet::OK;

	// "U" {"n"} <CompileTimeStep>
	if (tryParseCompileTimeLinearToken(ParseString, PKind, StepOrPos, "U") ==
	ParseRet::OK)
	return ParseRet::OK;

	return ParseRet::None;
	}

	/// Looks into the <parameters> part of the mangled name in search
	/// for valid paramaters at the beginning of the string
	/// `ParseString`.
	///
	/// On success, it removes the parsed parameter from `ParseString`,
	/// sets `PKind` to the correspondent enum value, sets `StepOrPos`
	/// accordingly, and return success. On a syntax error, it return a
	/// parsing error. If nothing is parsed, it returns None.
	ParseRet tryParseParameter(StringRef &ParseString, VFParamKind &PKind,
	int &StepOrPos) {
	if (ParseString.consume_front("v")) {
	PKind = VFParamKind::Vector;
	StepOrPos = 0;
	return ParseRet::OK;
	}

	if (ParseString.consume_front("u")) {
	PKind = VFParamKind::OMP_Uniform;
	StepOrPos = 0;
	return ParseRet::OK;
	}

	const ParseRet HasLinearRuntime =
	tryParseLinearWithRuntimeStep(ParseString, PKind, StepOrPos);
	if (HasLinearRuntime != ParseRet::None)
	return HasLinearRuntime;

	const ParseRet HasLinearCompileTime =
	tryParseLinearWithCompileTimeStep(ParseString, PKind, StepOrPos);
	if (HasLinearCompileTime != ParseRet::None)
	return HasLinearCompileTime;

	return ParseRet::None;
	}

	/// Looks into the <parameters> part of the mangled name in search
	/// of a valid 'aligned' clause. The function should be invoked
	/// after parsing a parameter via `tryParseParameter`.
	///
	/// On success, it removes the parsed parameter from `ParseString`,
	/// sets `PKind` to the correspondent enum value, sets `StepOrPos`
	/// accordingly, and return success. On a syntax error, it return a
	/// parsing error. If nothing is parsed, it returns None.
	ParseRet tryParseAlign(StringRef &ParseString, Align &Alignment) {
	uint64_t Val;
	// "a" <number>
	if (ParseString.consume_front("a")) {
	if (ParseString.consumeInteger(10, Val))
	return ParseRet::Error;

	if (!isPowerOf2_64(Val))
	return ParseRet::Error;

	Alignment = Align(Val);

	return ParseRet::OK;
	}

	return ParseRet::None;
	}
	#ifndef NDEBUG
	// Verify the assumtion that all vectors in the signature of a vector
	// function have the same number of elements.
	bool verifyAllVectorsHaveSameWidth(FunctionType *Signature) {
	SmallVector<VectorType *, 2> VecTys;
	if (auto *RetTy = dyn_cast<VectorType>(Signature->getReturnType()))
	VecTys.push_back(RetTy);
	for (auto *Ty : Signature->params())
	if (auto *VTy = dyn_cast<VectorType>(Ty))
	VecTys.push_back(VTy);

	if (VecTys.size() <= 1)
	return true;

	assert(VecTys.size() > 1 && "Invalid number of elements.");
	const ElementCount EC = VecTys[0]->getElementCount();
	return llvm::all_of(llvm::drop_begin(VecTys), [&EC](VectorType *VTy) {
	return (EC == VTy->getElementCount());
	});
	}

	#endif // NDEBUG

	// Extract the VectorizationFactor from a given function signature,
	// under the assumtion that all vectors have the same number of
	// elements, i.e. same ElementCount.Min.
	ElementCount getECFromSignature(FunctionType *Signature) {
	assert(verifyAllVectorsHaveSameWidth(Signature) &&
	"Invalid vector signature.");

	if (auto *RetTy = dyn_cast<VectorType>(Signature->getReturnType()))
	return RetTy->getElementCount();
	for (auto *Ty : Signature->params())
	if (auto *VTy = dyn_cast<VectorType>(Ty))
	return VTy->getElementCount();

	return ElementCount::getFixed(/Min=/1);
	}
	} // namespace

	// Format of the ABI name:
	// _ZGV<isa><mask><vlen><parameters>_<scalarname>[(<redirection>)]
	Optional<VFInfo> VFABI::tryDemangleForVFABI(StringRef MangledName,
	const Module &M) {
	const StringRef OriginalName = MangledName;
	// Assume there is no custom name <redirection>, and therefore the
	// vector name consists of
	// _ZGV<isa><mask><vlen><parameters>_<scalarname>.
	StringRef VectorName = MangledName;

	// Parse the fixed size part of the manled name
	if (!MangledName.consume_front("_ZGV"))
	return None;

	// Extract ISA. An unknow ISA is also supported, so we accept all
	// values.
	VFISAKind ISA;
	if (tryParseISA(MangledName, ISA) != ParseRet::OK)
	return None;

	// Extract <mask>.
	bool IsMasked;
	if (tryParseMask(MangledName, IsMasked) != ParseRet::OK)
	return None;

	// Parse the variable size, starting from <vlen>.
	unsigned VF;
	bool IsScalable;
	if (tryParseVLEN(MangledName, VF, IsScalable) != ParseRet::OK)
	return None;

	// Parse the <parameters>.
	ParseRet ParamFound;
	SmallVector<VFParameter, 8> Parameters;
	do {
	const unsigned ParameterPos = Parameters.size();
	VFParamKind PKind;
	int StepOrPos;
	ParamFound = tryParseParameter(MangledName, PKind, StepOrPos);

	// Bail off if there is a parsing error in the parsing of the parameter.
	if (ParamFound == ParseRet::Error)
	return None;

	if (ParamFound == ParseRet::OK) {
	Align Alignment;
	// Look for the alignment token "a <number>".
	const ParseRet AlignFound = tryParseAlign(MangledName, Alignment);
	// Bail off if there is a syntax error in the align token.
	if (AlignFound == ParseRet::Error)
	return None;

	// Add the parameter.
	Parameters.push_back({ParameterPos, PKind, StepOrPos, Alignment});
	}
	} while (ParamFound == ParseRet::OK);

	// A valid MangledName must have at least one valid entry in the
	// <parameters>.
	if (Parameters.empty())
	return None;

	// Check for the <scalarname> and the optional <redirection>, which
	// are separated from the prefix with "_"
	if (!MangledName.consume_front("_"))
	return None;

	// The rest of the string must be in the format:
	// <scalarname>[(<redirection>)]
	const StringRef ScalarName =
	MangledName.take_while([](char In) { return In != '('; });

	if (ScalarName.empty())
	return None;

	// Reduce MangledName to [(<redirection>)].
	MangledName = MangledName.ltrim(ScalarName);
	// Find the optional custom name redirection.
	if (MangledName.consume_front("(")) {
	if (!MangledName.consume_back(")"))
	return None;
	// Update the vector variant with the one specified by the user.
	VectorName = MangledName;
	// If the vector name is missing, bail out.
	if (VectorName.empty())
	return None;
	}

	// LLVM internal mapping via the TargetLibraryInfo (TLI) must be
	// redirected to an existing name.
	if (ISA == VFISAKind::LLVM && VectorName == OriginalName)
	return None;

	// When <mask> is "M", we need to add a parameter that is used as
	// global predicate for the function.
	if (IsMasked) {
	const unsigned Pos = Parameters.size();
	Parameters.push_back({Pos, VFParamKind::GlobalPredicate});
	}

	// Asserts for parameters of type `VFParamKind::GlobalPredicate`, as
	// prescribed by the Vector Function ABI specifications supported by
	// this parser:
	// 1. Uniqueness.
	// 2. Must be the last in the parameter list.
	const auto NGlobalPreds = std::count_if(
	Parameters.begin(), Parameters.end(), [](const VFParameter PK) {
	return PK.ParamKind == VFParamKind::GlobalPredicate;
	});
	assert(NGlobalPreds < 2 && "Cannot have more than one global predicate.");
	if (NGlobalPreds)
	assert(Parameters.back().ParamKind == VFParamKind::GlobalPredicate &&
	"The global predicate must be the last parameter");

	// Adjust the VF for scalable signatures. The EC.Min is not encoded
	// in the name of the function, but it is encoded in the IR
	// signature of the function. We need to extract this information
	// because it is needed by the loop vectorizer, which reasons in
	// terms of VectorizationFactor or ElementCount. In particular, we
	// need to make sure that the VF field of the VFShape class is never
	// set to 0.
	if (IsScalable) {
	const Function *F = M.getFunction(VectorName);
	// The declaration of the function must be present in the module
	// to be able to retrieve its signature.
	if (!F)
	return None;
	const ElementCount EC = getECFromSignature(F->getFunctionType());
	VF = EC.getKnownMinValue();
	}

	// 1. We don't accept a zero lanes vectorization factor.
	// 2. We don't accept the demangling if the vector function is not
	// present in the module.
	if (VF == 0)
	return None;
	if (!M.getFunction(VectorName))
	return None;

	const VFShape Shape({ElementCount::get(VF, IsScalable), Parameters});
	return VFInfo({Shape, std::string(ScalarName), std::string(VectorName), ISA});
	}

	VFParamKind VFABI::getVFParamKindFromString(const StringRef Token) {
	const VFParamKind ParamKind = StringSwitch<VFParamKind>(Token)
	.Case("v", VFParamKind::Vector)
	.Case("l", VFParamKind::OMP_Linear)
	.Case("R", VFParamKind::OMP_LinearRef)
	.Case("L", VFParamKind::OMP_LinearVal)
	.Case("U", VFParamKind::OMP_LinearUVal)
	.Case("ls", VFParamKind::OMP_LinearPos)
	.Case("Ls", VFParamKind::OMP_LinearValPos)
	.Case("Rs", VFParamKind::OMP_LinearRefPos)
	.Case("Us", VFParamKind::OMP_LinearUValPos)
	.Case("u", VFParamKind::OMP_Uniform)
	.Default(VFParamKind::Unknown);

	if (ParamKind != VFParamKind::Unknown)
	return ParamKind;

	// This function should never be invoked with an invalid input.
	llvm_unreachable("This fuction should be invoken only on parameters"
	" that have a textual representation in the mangled name"
	" of the Vector Function ABI");
	}