linux-x64/clang/include/llvm/CodeGen/StackMaps.h - hafnium/prebuilts - Git at Google

 //===- StackMaps.h - StackMaps ----------------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CODEGEN_STACKMAPS_H
 #define LLVM_CODEGEN_STACKMAPS_H

 #include "llvm/ADT/MapVector.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/CodeGen/MachineInstr.h"
 #include "llvm/IR/CallingConv.h"
 #include "llvm/MC/MCSymbol.h"
 #include "llvm/Support/Debug.h"
 #include <algorithm>
 #include <cassert>
 #include <cstdint>
 #include <vector>

 namespace llvm {

 class AsmPrinter;
 class MCExpr;
 class MCStreamer;
 class raw_ostream;
 class TargetRegisterInfo;

 /// \brief MI-level stackmap operands.
 ///
 /// MI stackmap operations take the form:
 /// <id>, <numBytes>, live args...
 class StackMapOpers {
 public:
   /// Enumerate the meta operands.
   enum { IDPos, NBytesPos };

 private:
   const MachineInstr* MI;

 public:
   explicit StackMapOpers(const MachineInstr *MI);

   /// Return the ID for the given stackmap
   uint64_t getID() const { return MI->getOperand(IDPos).getImm(); }

   /// Return the number of patchable bytes the given stackmap should emit.
   uint32_t getNumPatchBytes() const {
     return MI->getOperand(NBytesPos).getImm();
   }

   /// Get the operand index of the variable list of non-argument operands.
   /// These hold the "live state".
   unsigned getVarIdx() const {
     // Skip ID, nShadowBytes.
     return 2;
   }
 };

 /// \brief MI-level patchpoint operands.
 ///
 /// MI patchpoint operations take the form:
 /// [<def>], <id>, <numBytes>, <target>, <numArgs>, <cc>, ...
 ///
 /// IR patchpoint intrinsics do not have the <cc> operand because calling
 /// convention is part of the subclass data.
 ///
 /// SD patchpoint nodes do not have a def operand because it is part of the
 /// SDValue.
 ///
 /// Patchpoints following the anyregcc convention are handled specially. For
 /// these, the stack map also records the location of the return value and
 /// arguments.
 class PatchPointOpers {
 public:
   /// Enumerate the meta operands.
   enum { IDPos, NBytesPos, TargetPos, NArgPos, CCPos, MetaEnd };

 private:
   const MachineInstr *MI;
   bool HasDef;

   unsigned getMetaIdx(unsigned Pos = 0) const {
     assert(Pos < MetaEnd && "Meta operand index out of range.");
     return (HasDef ? 1 : 0) + Pos;
   }

   const MachineOperand &getMetaOper(unsigned Pos) const {
     return MI->getOperand(getMetaIdx(Pos));
   }

 public:
   explicit PatchPointOpers(const MachineInstr *MI);

   bool isAnyReg() const { return (getCallingConv() == CallingConv::AnyReg); }
   bool hasDef() const { return HasDef; }

   /// Return the ID for the given patchpoint.
   uint64_t getID() const { return getMetaOper(IDPos).getImm(); }

   /// Return the number of patchable bytes the given patchpoint should emit.
   uint32_t getNumPatchBytes() const {
     return getMetaOper(NBytesPos).getImm();
   }

   /// Returns the target of the underlying call.
   const MachineOperand &getCallTarget() const {
     return getMetaOper(TargetPos);
   }

   /// Returns the calling convention
   CallingConv::ID getCallingConv() const {
     return getMetaOper(CCPos).getImm();
   }

   unsigned getArgIdx() const { return getMetaIdx() + MetaEnd; }

   /// Return the number of call arguments
   uint32_t getNumCallArgs() const {
     return MI->getOperand(getMetaIdx(NArgPos)).getImm();
   }

   /// Get the operand index of the variable list of non-argument operands.
   /// These hold the "live state".
   unsigned getVarIdx() const {
     return getMetaIdx() + MetaEnd + getNumCallArgs();
   }

   /// Get the index at which stack map locations will be recorded.
   /// Arguments are not recorded unless the anyregcc convention is used.
   unsigned getStackMapStartIdx() const {
     if (isAnyReg())
       return getArgIdx();
     return getVarIdx();
   }

   /// \brief Get the next scratch register operand index.
   unsigned getNextScratchIdx(unsigned StartIdx = 0) const;
 };

 /// MI-level Statepoint operands
 ///
 /// Statepoint operands take the form:
 ///   <id>, <num patch bytes >, <num call arguments>, <call target>,
 ///   [call arguments...],
 ///   <StackMaps::ConstantOp>, <calling convention>,
 ///   <StackMaps::ConstantOp>, <statepoint flags>,
 ///   <StackMaps::ConstantOp>, <num deopt args>, [deopt args...],
 ///   <gc base/derived pairs...> <gc allocas...>
 /// Note that the last two sets of arguments are not currently length
 ///   prefixed.
 class StatepointOpers {
   // TODO:: we should change the STATEPOINT representation so that CC and
   // Flags should be part of meta operands, with args and deopt operands, and
   // gc operands all prefixed by their length and a type code. This would be
   // much more consistent.
 public:
   // These values are aboolute offsets into the operands of the statepoint
   // instruction.
   enum { IDPos, NBytesPos, NCallArgsPos, CallTargetPos, MetaEnd };

   // These values are relative offests from the start of the statepoint meta
   // arguments (i.e. the end of the call arguments).
   enum { CCOffset = 1, FlagsOffset = 3, NumDeoptOperandsOffset = 5 };

   explicit StatepointOpers(const MachineInstr *MI) : MI(MI) {}

   /// Get starting index of non call related arguments
   /// (calling convention, statepoint flags, vm state and gc state).
   unsigned getVarIdx() const {
     return MI->getOperand(NCallArgsPos).getImm() + MetaEnd;
   }

   /// Return the ID for the given statepoint.
   uint64_t getID() const { return MI->getOperand(IDPos).getImm(); }

   /// Return the number of patchable bytes the given statepoint should emit.
   uint32_t getNumPatchBytes() const {
     return MI->getOperand(NBytesPos).getImm();
   }

   /// Returns the target of the underlying call.
   const MachineOperand &getCallTarget() const {
     return MI->getOperand(CallTargetPos);
   }

 private:
   const MachineInstr *MI;
 };

 class StackMaps {
 public:
   struct Location {
     enum LocationType {
       Unprocessed,
       Register,
       Direct,
       Indirect,
       Constant,
       ConstantIndex
     };
     LocationType Type = Unprocessed;
     unsigned Size = 0;
     unsigned Reg = 0;
     int64_t Offset = 0;

     Location() = default;
     Location(LocationType Type, unsigned Size, unsigned Reg, int64_t Offset)
         : Type(Type), Size(Size), Reg(Reg), Offset(Offset) {}
   };

   struct LiveOutReg {
     unsigned short Reg = 0;
     unsigned short DwarfRegNum = 0;
     unsigned short Size = 0;

     LiveOutReg() = default;
     LiveOutReg(unsigned short Reg, unsigned short DwarfRegNum,
                unsigned short Size)
         : Reg(Reg), DwarfRegNum(DwarfRegNum), Size(Size) {}
   };

   // OpTypes are used to encode information about the following logical
   // operand (which may consist of several MachineOperands) for the
   // OpParser.
   using OpType = enum { DirectMemRefOp, IndirectMemRefOp, ConstantOp };

   StackMaps(AsmPrinter &AP);

   void reset() {
     CSInfos.clear();
     ConstPool.clear();
     FnInfos.clear();
   }

   /// \brief Generate a stackmap record for a stackmap instruction.
   ///
   /// MI must be a raw STACKMAP, not a PATCHPOINT.
   void recordStackMap(const MachineInstr &MI);

   /// \brief Generate a stackmap record for a patchpoint instruction.
   void recordPatchPoint(const MachineInstr &MI);

   /// \brief Generate a stackmap record for a statepoint instruction.
   void recordStatepoint(const MachineInstr &MI);

   /// If there is any stack map data, create a stack map section and serialize
   /// the map info into it. This clears the stack map data structures
   /// afterwards.
   void serializeToStackMapSection();

 private:
   static const char *WSMP;

   using LocationVec = SmallVector<Location, 8>;
   using LiveOutVec = SmallVector<LiveOutReg, 8>;
   using ConstantPool = MapVector<uint64_t, uint64_t>;

   struct FunctionInfo {
     uint64_t StackSize = 0;
     uint64_t RecordCount = 1;

     FunctionInfo() = default;
     explicit FunctionInfo(uint64_t StackSize) : StackSize(StackSize) {}
   };

   struct CallsiteInfo {
     const MCExpr *CSOffsetExpr = nullptr;
     uint64_t ID = 0;
     LocationVec Locations;
     LiveOutVec LiveOuts;

     CallsiteInfo() = default;
     CallsiteInfo(const MCExpr *CSOffsetExpr, uint64_t ID,
                  LocationVec &&Locations, LiveOutVec &&LiveOuts)
         : CSOffsetExpr(CSOffsetExpr), ID(ID), Locations(std::move(Locations)),
           LiveOuts(std::move(LiveOuts)) {}
   };

   using FnInfoMap = MapVector<const MCSymbol *, FunctionInfo>;
   using CallsiteInfoList = std::vector<CallsiteInfo>;

   AsmPrinter &AP;
   CallsiteInfoList CSInfos;
   ConstantPool ConstPool;
   FnInfoMap FnInfos;

   MachineInstr::const_mop_iterator
   parseOperand(MachineInstr::const_mop_iterator MOI,
                MachineInstr::const_mop_iterator MOE, LocationVec &Locs,
                LiveOutVec &LiveOuts) const;

   /// \brief Create a live-out register record for the given register @p Reg.
   LiveOutReg createLiveOutReg(unsigned Reg,
                               const TargetRegisterInfo *TRI) const;

   /// \brief Parse the register live-out mask and return a vector of live-out
   /// registers that need to be recorded in the stackmap.
   LiveOutVec parseRegisterLiveOutMask(const uint32_t *Mask) const;

   /// This should be called by the MC lowering code _immediately_ before
   /// lowering the MI to an MCInst. It records where the operands for the
   /// instruction are stored, and outputs a label to record the offset of
   /// the call from the start of the text section. In special cases (e.g. AnyReg
   /// calling convention) the return register is also recorded if requested.
   void recordStackMapOpers(const MachineInstr &MI, uint64_t ID,
                            MachineInstr::const_mop_iterator MOI,
                            MachineInstr::const_mop_iterator MOE,
                            bool recordResult = false);

   /// \brief Emit the stackmap header.
   void emitStackmapHeader(MCStreamer &OS);

   /// \brief Emit the function frame record for each function.
   void emitFunctionFrameRecords(MCStreamer &OS);

   /// \brief Emit the constant pool.
   void emitConstantPoolEntries(MCStreamer &OS);

   /// \brief Emit the callsite info for each stackmap/patchpoint intrinsic call.
   void emitCallsiteEntries(MCStreamer &OS);

   void print(raw_ostream &OS);
   void debug() { print(dbgs()); }
 };

 } // end namespace llvm

 #endif // LLVM_CODEGEN_STACKMAPS_H
	//===- StackMaps.h - StackMaps ----------------------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CODEGEN_STACKMAPS_H
	#define LLVM_CODEGEN_STACKMAPS_H

	#include "llvm/ADT/MapVector.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/CodeGen/MachineInstr.h"
	#include "llvm/IR/CallingConv.h"
	#include "llvm/MC/MCSymbol.h"
	#include "llvm/Support/Debug.h"
	#include <algorithm>
	#include <cassert>
	#include <cstdint>
	#include <vector>

	namespace llvm {

	class AsmPrinter;
	class MCExpr;
	class MCStreamer;
	class raw_ostream;
	class TargetRegisterInfo;

	/// \brief MI-level stackmap operands.
	///
	/// MI stackmap operations take the form:
	/// <id>, <numBytes>, live args...
	class StackMapOpers {
	public:
	/// Enumerate the meta operands.
	enum { IDPos, NBytesPos };

	private:
	const MachineInstr* MI;

	public:
	explicit StackMapOpers(const MachineInstr *MI);

	/// Return the ID for the given stackmap
	uint64_t getID() const { return MI->getOperand(IDPos).getImm(); }

	/// Return the number of patchable bytes the given stackmap should emit.
	uint32_t getNumPatchBytes() const {
	return MI->getOperand(NBytesPos).getImm();
	}

	/// Get the operand index of the variable list of non-argument operands.
	/// These hold the "live state".
	unsigned getVarIdx() const {
	// Skip ID, nShadowBytes.
	return 2;
	}
	};

	/// \brief MI-level patchpoint operands.
	///
	/// MI patchpoint operations take the form:
	/// [<def>], <id>, <numBytes>, <target>, <numArgs>, <cc>, ...
	///
	/// IR patchpoint intrinsics do not have the <cc> operand because calling
	/// convention is part of the subclass data.
	///
	/// SD patchpoint nodes do not have a def operand because it is part of the
	/// SDValue.
	///
	/// Patchpoints following the anyregcc convention are handled specially. For
	/// these, the stack map also records the location of the return value and
	/// arguments.
	class PatchPointOpers {
	public:
	/// Enumerate the meta operands.
	enum { IDPos, NBytesPos, TargetPos, NArgPos, CCPos, MetaEnd };

	private:
	const MachineInstr *MI;
	bool HasDef;

	unsigned getMetaIdx(unsigned Pos = 0) const {
	assert(Pos < MetaEnd && "Meta operand index out of range.");
	return (HasDef ? 1 : 0) + Pos;
	}

	const MachineOperand &getMetaOper(unsigned Pos) const {
	return MI->getOperand(getMetaIdx(Pos));
	}

	public:
	explicit PatchPointOpers(const MachineInstr *MI);

	bool isAnyReg() const { return (getCallingConv() == CallingConv::AnyReg); }
	bool hasDef() const { return HasDef; }

	/// Return the ID for the given patchpoint.
	uint64_t getID() const { return getMetaOper(IDPos).getImm(); }

	/// Return the number of patchable bytes the given patchpoint should emit.
	uint32_t getNumPatchBytes() const {
	return getMetaOper(NBytesPos).getImm();
	}

	/// Returns the target of the underlying call.
	const MachineOperand &getCallTarget() const {
	return getMetaOper(TargetPos);
	}

	/// Returns the calling convention
	CallingConv::ID getCallingConv() const {
	return getMetaOper(CCPos).getImm();
	}

	unsigned getArgIdx() const { return getMetaIdx() + MetaEnd; }

	/// Return the number of call arguments
	uint32_t getNumCallArgs() const {
	return MI->getOperand(getMetaIdx(NArgPos)).getImm();
	}

	/// Get the operand index of the variable list of non-argument operands.
	/// These hold the "live state".
	unsigned getVarIdx() const {
	return getMetaIdx() + MetaEnd + getNumCallArgs();
	}

	/// Get the index at which stack map locations will be recorded.
	/// Arguments are not recorded unless the anyregcc convention is used.
	unsigned getStackMapStartIdx() const {
	if (isAnyReg())
	return getArgIdx();
	return getVarIdx();
	}

	/// \brief Get the next scratch register operand index.
	unsigned getNextScratchIdx(unsigned StartIdx = 0) const;
	};

	/// MI-level Statepoint operands
	///
	/// Statepoint operands take the form:
	/// <id>, <num patch bytes >, <num call arguments>, <call target>,
	/// [call arguments...],
	/// <StackMaps::ConstantOp>, <calling convention>,
	/// <StackMaps::ConstantOp>, <statepoint flags>,
	/// <StackMaps::ConstantOp>, <num deopt args>, [deopt args...],
	/// <gc base/derived pairs...> <gc allocas...>
	/// Note that the last two sets of arguments are not currently length
	/// prefixed.
	class StatepointOpers {
	// TODO:: we should change the STATEPOINT representation so that CC and
	// Flags should be part of meta operands, with args and deopt operands, and
	// gc operands all prefixed by their length and a type code. This would be
	// much more consistent.
	public:
	// These values are aboolute offsets into the operands of the statepoint
	// instruction.
	enum { IDPos, NBytesPos, NCallArgsPos, CallTargetPos, MetaEnd };

	// These values are relative offests from the start of the statepoint meta
	// arguments (i.e. the end of the call arguments).
	enum { CCOffset = 1, FlagsOffset = 3, NumDeoptOperandsOffset = 5 };

	explicit StatepointOpers(const MachineInstr *MI) : MI(MI) {}

	/// Get starting index of non call related arguments
	/// (calling convention, statepoint flags, vm state and gc state).
	unsigned getVarIdx() const {
	return MI->getOperand(NCallArgsPos).getImm() + MetaEnd;
	}

	/// Return the ID for the given statepoint.
	uint64_t getID() const { return MI->getOperand(IDPos).getImm(); }

	/// Return the number of patchable bytes the given statepoint should emit.
	uint32_t getNumPatchBytes() const {
	return MI->getOperand(NBytesPos).getImm();
	}

	/// Returns the target of the underlying call.
	const MachineOperand &getCallTarget() const {
	return MI->getOperand(CallTargetPos);
	}

	private:
	const MachineInstr *MI;
	};

	class StackMaps {
	public:
	struct Location {
	enum LocationType {
	Unprocessed,
	Register,
	Direct,
	Indirect,
	Constant,
	ConstantIndex
	};
	LocationType Type = Unprocessed;
	unsigned Size = 0;
	unsigned Reg = 0;
	int64_t Offset = 0;

	Location() = default;
	Location(LocationType Type, unsigned Size, unsigned Reg, int64_t Offset)
	: Type(Type), Size(Size), Reg(Reg), Offset(Offset) {}
	};

	struct LiveOutReg {
	unsigned short Reg = 0;
	unsigned short DwarfRegNum = 0;
	unsigned short Size = 0;

	LiveOutReg() = default;
	LiveOutReg(unsigned short Reg, unsigned short DwarfRegNum,
	unsigned short Size)
	: Reg(Reg), DwarfRegNum(DwarfRegNum), Size(Size) {}
	};

	// OpTypes are used to encode information about the following logical
	// operand (which may consist of several MachineOperands) for the
	// OpParser.
	using OpType = enum { DirectMemRefOp, IndirectMemRefOp, ConstantOp };

	StackMaps(AsmPrinter &AP);

	void reset() {
	CSInfos.clear();
	ConstPool.clear();
	FnInfos.clear();
	}

	/// \brief Generate a stackmap record for a stackmap instruction.
	///
	/// MI must be a raw STACKMAP, not a PATCHPOINT.
	void recordStackMap(const MachineInstr &MI);

	/// \brief Generate a stackmap record for a patchpoint instruction.
	void recordPatchPoint(const MachineInstr &MI);

	/// \brief Generate a stackmap record for a statepoint instruction.
	void recordStatepoint(const MachineInstr &MI);

	/// If there is any stack map data, create a stack map section and serialize
	/// the map info into it. This clears the stack map data structures
	/// afterwards.
	void serializeToStackMapSection();

	private:
	static const char *WSMP;

	using LocationVec = SmallVector<Location, 8>;
	using LiveOutVec = SmallVector<LiveOutReg, 8>;
	using ConstantPool = MapVector<uint64_t, uint64_t>;

	struct FunctionInfo {
	uint64_t StackSize = 0;
	uint64_t RecordCount = 1;

	FunctionInfo() = default;
	explicit FunctionInfo(uint64_t StackSize) : StackSize(StackSize) {}
	};

	struct CallsiteInfo {
	const MCExpr *CSOffsetExpr = nullptr;
	uint64_t ID = 0;
	LocationVec Locations;
	LiveOutVec LiveOuts;

	CallsiteInfo() = default;
	CallsiteInfo(const MCExpr *CSOffsetExpr, uint64_t ID,
	LocationVec &&Locations, LiveOutVec &&LiveOuts)
	: CSOffsetExpr(CSOffsetExpr), ID(ID), Locations(std::move(Locations)),
	LiveOuts(std::move(LiveOuts)) {}
	};

	using FnInfoMap = MapVector<const MCSymbol *, FunctionInfo>;
	using CallsiteInfoList = std::vector<CallsiteInfo>;

	AsmPrinter &AP;
	CallsiteInfoList CSInfos;
	ConstantPool ConstPool;
	FnInfoMap FnInfos;

	MachineInstr::const_mop_iterator
	parseOperand(MachineInstr::const_mop_iterator MOI,
	MachineInstr::const_mop_iterator MOE, LocationVec &Locs,
	LiveOutVec &LiveOuts) const;

	/// \brief Create a live-out register record for the given register @p Reg.
	LiveOutReg createLiveOutReg(unsigned Reg,
	const TargetRegisterInfo *TRI) const;

	/// \brief Parse the register live-out mask and return a vector of live-out
	/// registers that need to be recorded in the stackmap.
	LiveOutVec parseRegisterLiveOutMask(const uint32_t *Mask) const;

	/// This should be called by the MC lowering code _immediately_ before
	/// lowering the MI to an MCInst. It records where the operands for the
	/// instruction are stored, and outputs a label to record the offset of
	/// the call from the start of the text section. In special cases (e.g. AnyReg
	/// calling convention) the return register is also recorded if requested.
	void recordStackMapOpers(const MachineInstr &MI, uint64_t ID,
	MachineInstr::const_mop_iterator MOI,
	MachineInstr::const_mop_iterator MOE,
	bool recordResult = false);

	/// \brief Emit the stackmap header.
	void emitStackmapHeader(MCStreamer &OS);

	/// \brief Emit the function frame record for each function.
	void emitFunctionFrameRecords(MCStreamer &OS);

	/// \brief Emit the constant pool.
	void emitConstantPoolEntries(MCStreamer &OS);

	/// \brief Emit the callsite info for each stackmap/patchpoint intrinsic call.
	void emitCallsiteEntries(MCStreamer &OS);

	void print(raw_ostream &OS);
	void debug() { print(dbgs()); }
	};

	} // end namespace llvm

	#endif // LLVM_CODEGEN_STACKMAPS_H