include/llvm/MC/MCInstrAnalysis.h - llvm - Git at Google

 //===- llvm/MC/MCInstrAnalysis.h - InstrDesc target hooks -------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the MCInstrAnalysis class which the MCTargetDescs can
 // derive from to give additional information to MC.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_MC_MCINSTRANALYSIS_H
 #define LLVM_MC_MCINSTRANALYSIS_H

 #include "llvm/MC/MCInst.h"
 #include "llvm/MC/MCInstrDesc.h"
 #include "llvm/MC/MCInstrInfo.h"
 #include <cstdint>

 namespace llvm {

 class MCRegisterInfo;
 class Triple;

 class MCInstrAnalysis {
 protected:
   friend class Target;

   const MCInstrInfo *Info;

 public:
   MCInstrAnalysis(const MCInstrInfo *Info) : Info(Info) {}
   virtual ~MCInstrAnalysis() = default;

   virtual bool isBranch(const MCInst &Inst) const {
     return Info->get(Inst.getOpcode()).isBranch();
   }

   virtual bool isConditionalBranch(const MCInst &Inst) const {
     return Info->get(Inst.getOpcode()).isConditionalBranch();
   }

   virtual bool isUnconditionalBranch(const MCInst &Inst) const {
     return Info->get(Inst.getOpcode()).isUnconditionalBranch();
   }

   virtual bool isIndirectBranch(const MCInst &Inst) const {
     return Info->get(Inst.getOpcode()).isIndirectBranch();
   }

   virtual bool isCall(const MCInst &Inst) const {
     return Info->get(Inst.getOpcode()).isCall();
   }

   virtual bool isReturn(const MCInst &Inst) const {
     return Info->get(Inst.getOpcode()).isReturn();
   }

   virtual bool isTerminator(const MCInst &Inst) const {
     return Info->get(Inst.getOpcode()).isTerminator();
   }

   /// Returns true if at least one of the register writes performed by
   /// \param Inst implicitly clears the upper portion of all super-registers.
   ///
   /// Example: on X86-64, a write to EAX implicitly clears the upper half of
   /// RAX. Also (still on x86) an XMM write perfomed by an AVX 128-bit
   /// instruction implicitly clears the upper portion of the correspondent
   /// YMM register.
   ///
   /// This method also updates an APInt which is used as mask of register
   /// writes. There is one bit for every explicit/implicit write performed by
   /// the instruction. If a write implicitly clears its super-registers, then
   /// the corresponding bit is set (vic. the corresponding bit is cleared).
   ///
   /// The first bits in the APint are related to explicit writes. The remaining
   /// bits are related to implicit writes. The sequence of writes follows the
   /// machine operand sequence. For implicit writes, the sequence is defined by
   /// the MCInstrDesc.
   ///
   /// The assumption is that the bit-width of the APInt is correctly set by
   /// the caller. The default implementation conservatively assumes that none of
   /// the writes clears the upper portion of a super-register.
   virtual bool clearsSuperRegisters(const MCRegisterInfo &MRI,
                                     const MCInst &Inst,
                                     APInt &Writes) const;

   /// Returns true if MI is a dependency breaking zero-idiom for the given
   /// subtarget.
   ///
   /// Mask is used to identify input operands that have their dependency
   /// broken. Each bit of the mask is associated with a specific input operand.
   /// Bits associated with explicit input operands are laid out first in the
   /// mask; implicit operands come after explicit operands.
   ///
   /// Dependencies are broken only for operands that have their corresponding bit
   /// set. Operands that have their bit cleared, or that don't have a
   /// corresponding bit in the mask don't have their dependency broken.  Note
   /// that Mask may not be big enough to describe all operands.  The assumption
   /// for operands that don't have a correspondent bit in the mask is that those
   /// are still data dependent.
   ///
   /// The only exception to the rule is for when Mask has all zeroes.
   /// A zero mask means: dependencies are broken for all explicit register
   /// operands.
   virtual bool isZeroIdiom(const MCInst &MI, APInt &Mask,
                            unsigned CPUID) const {
     return false;
   }

   /// Returns true if MI is a dependency breaking instruction for the
   /// subtarget associated with CPUID .
   ///
   /// The value computed by a dependency breaking instruction is not dependent
   /// on the inputs. An example of dependency breaking instruction on X86 is
   /// `XOR %eax, %eax`.
   ///
   /// If MI is a dependency breaking instruction for subtarget CPUID, then Mask
   /// can be inspected to identify independent operands.
   ///
   /// Essentially, each bit of the mask corresponds to an input operand.
   /// Explicit operands are laid out first in the mask; implicit operands follow
   /// explicit operands. Bits are set for operands that are independent.
   ///
   /// Note that the number of bits in Mask may not be equivalent to the sum of
   /// explicit and implicit operands in MI. Operands that don't have a
   /// corresponding bit in Mask are assumed "not independente".
   ///
   /// The only exception is for when Mask is all zeroes. That means: explicit
   /// input operands of MI are independent.
   virtual bool isDependencyBreaking(const MCInst &MI, APInt &Mask,
                                     unsigned CPUID) const {
     return isZeroIdiom(MI, Mask, CPUID);
   }

   /// Returns true if MI is a candidate for move elimination.
   ///
   /// Different subtargets may apply different constraints to optimizable
   /// register moves. For example, on most X86 subtargets, a candidate for move
   /// elimination cannot specify the same register for both source and
   /// destination.
   virtual bool isOptimizableRegisterMove(const MCInst &MI,
                                          unsigned CPUID) const {
     return false;
   }

   /// Given a branch instruction try to get the address the branch
   /// targets. Return true on success, and the address in Target.
   virtual bool
   evaluateBranch(const MCInst &Inst, uint64_t Addr, uint64_t Size,
                  uint64_t &Target) const;

   /// Returns (PLT virtual address, GOT virtual address) pairs for PLT entries.
   virtual std::vector<std::pair<uint64_t, uint64_t>>
   findPltEntries(uint64_t PltSectionVA, ArrayRef<uint8_t> PltContents,
                  uint64_t GotPltSectionVA, const Triple &TargetTriple) const {
     return {};
   }
 };

 } // end namespace llvm

 #endif // LLVM_MC_MCINSTRANALYSIS_H
	//===- llvm/MC/MCInstrAnalysis.h - InstrDesc target hooks -------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the MCInstrAnalysis class which the MCTargetDescs can
	// derive from to give additional information to MC.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_MC_MCINSTRANALYSIS_H
	#define LLVM_MC_MCINSTRANALYSIS_H

	#include "llvm/MC/MCInst.h"
	#include "llvm/MC/MCInstrDesc.h"
	#include "llvm/MC/MCInstrInfo.h"
	#include <cstdint>

	namespace llvm {

	class MCRegisterInfo;
	class Triple;

	class MCInstrAnalysis {
	protected:
	friend class Target;

	const MCInstrInfo *Info;

	public:
	MCInstrAnalysis(const MCInstrInfo *Info) : Info(Info) {}
	virtual ~MCInstrAnalysis() = default;

	virtual bool isBranch(const MCInst &Inst) const {
	return Info->get(Inst.getOpcode()).isBranch();
	}

	virtual bool isConditionalBranch(const MCInst &Inst) const {
	return Info->get(Inst.getOpcode()).isConditionalBranch();
	}

	virtual bool isUnconditionalBranch(const MCInst &Inst) const {
	return Info->get(Inst.getOpcode()).isUnconditionalBranch();
	}

	virtual bool isIndirectBranch(const MCInst &Inst) const {
	return Info->get(Inst.getOpcode()).isIndirectBranch();
	}

	virtual bool isCall(const MCInst &Inst) const {
	return Info->get(Inst.getOpcode()).isCall();
	}

	virtual bool isReturn(const MCInst &Inst) const {
	return Info->get(Inst.getOpcode()).isReturn();
	}

	virtual bool isTerminator(const MCInst &Inst) const {
	return Info->get(Inst.getOpcode()).isTerminator();
	}

	/// Returns true if at least one of the register writes performed by
	/// \param Inst implicitly clears the upper portion of all super-registers.
	///
	/// Example: on X86-64, a write to EAX implicitly clears the upper half of
	/// RAX. Also (still on x86) an XMM write perfomed by an AVX 128-bit
	/// instruction implicitly clears the upper portion of the correspondent
	/// YMM register.
	///
	/// This method also updates an APInt which is used as mask of register
	/// writes. There is one bit for every explicit/implicit write performed by
	/// the instruction. If a write implicitly clears its super-registers, then
	/// the corresponding bit is set (vic. the corresponding bit is cleared).
	///
	/// The first bits in the APint are related to explicit writes. The remaining
	/// bits are related to implicit writes. The sequence of writes follows the
	/// machine operand sequence. For implicit writes, the sequence is defined by
	/// the MCInstrDesc.
	///
	/// The assumption is that the bit-width of the APInt is correctly set by
	/// the caller. The default implementation conservatively assumes that none of
	/// the writes clears the upper portion of a super-register.
	virtual bool clearsSuperRegisters(const MCRegisterInfo &MRI,
	const MCInst &Inst,
	APInt &Writes) const;

	/// Returns true if MI is a dependency breaking zero-idiom for the given
	/// subtarget.
	///
	/// Mask is used to identify input operands that have their dependency
	/// broken. Each bit of the mask is associated with a specific input operand.
	/// Bits associated with explicit input operands are laid out first in the
	/// mask; implicit operands come after explicit operands.
	///
	/// Dependencies are broken only for operands that have their corresponding bit
	/// set. Operands that have their bit cleared, or that don't have a
	/// corresponding bit in the mask don't have their dependency broken. Note
	/// that Mask may not be big enough to describe all operands. The assumption
	/// for operands that don't have a correspondent bit in the mask is that those
	/// are still data dependent.
	///
	/// The only exception to the rule is for when Mask has all zeroes.
	/// A zero mask means: dependencies are broken for all explicit register
	/// operands.
	virtual bool isZeroIdiom(const MCInst &MI, APInt &Mask,
	unsigned CPUID) const {
	return false;
	}

	/// Returns true if MI is a dependency breaking instruction for the
	/// subtarget associated with CPUID .
	///
	/// The value computed by a dependency breaking instruction is not dependent
	/// on the inputs. An example of dependency breaking instruction on X86 is
	/// `XOR %eax, %eax`.
	///
	/// If MI is a dependency breaking instruction for subtarget CPUID, then Mask
	/// can be inspected to identify independent operands.
	///
	/// Essentially, each bit of the mask corresponds to an input operand.
	/// Explicit operands are laid out first in the mask; implicit operands follow
	/// explicit operands. Bits are set for operands that are independent.
	///
	/// Note that the number of bits in Mask may not be equivalent to the sum of
	/// explicit and implicit operands in MI. Operands that don't have a
	/// corresponding bit in Mask are assumed "not independente".
	///
	/// The only exception is for when Mask is all zeroes. That means: explicit
	/// input operands of MI are independent.
	virtual bool isDependencyBreaking(const MCInst &MI, APInt &Mask,
	unsigned CPUID) const {
	return isZeroIdiom(MI, Mask, CPUID);
	}

	/// Returns true if MI is a candidate for move elimination.
	///
	/// Different subtargets may apply different constraints to optimizable
	/// register moves. For example, on most X86 subtargets, a candidate for move
	/// elimination cannot specify the same register for both source and
	/// destination.
	virtual bool isOptimizableRegisterMove(const MCInst &MI,
	unsigned CPUID) const {
	return false;
	}

	/// Given a branch instruction try to get the address the branch
	/// targets. Return true on success, and the address in Target.
	virtual bool
	evaluateBranch(const MCInst &Inst, uint64_t Addr, uint64_t Size,
	uint64_t &Target) const;

	/// Returns (PLT virtual address, GOT virtual address) pairs for PLT entries.
	virtual std::vector<std::pair<uint64_t, uint64_t>>
	findPltEntries(uint64_t PltSectionVA, ArrayRef<uint8_t> PltContents,
	uint64_t GotPltSectionVA, const Triple &TargetTriple) const {
	return {};
	}
	};

	} // end namespace llvm

	#endif // LLVM_MC_MCINSTRANALYSIS_H