//===-- llvm/Target/TargetInstrDesc.h - Instruction Descriptors -*- 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 TargetOperandInfo and TargetInstrDesc classes, which // are used to describe target instructions and their operands. // //===----------------------------------------------------------------------===// #ifndef LLVM_TARGET_TARGETINSTRDESC_H #define LLVM_TARGET_TARGETINSTRDESC_H namespace llvm { class TargetRegisterClass; class TargetRegisterInfo; //===----------------------------------------------------------------------===// // Machine Operand Flags and Description //===----------------------------------------------------------------------===// namespace TOI { // Operand constraints enum OperandConstraint { TIED_TO = 0, // Must be allocated the same register as. EARLY_CLOBBER // Operand is an early clobber register operand }; /// OperandFlags - These are flags set on operands, but should be considered /// private, all access should go through the TargetOperandInfo accessors. /// See the accessors for a description of what these are. enum OperandFlags { LookupPtrRegClass = 0, Predicate, OptionalDef }; } /// TargetOperandInfo - This holds information about one operand of a machine /// instruction, indicating the register class for register operands, etc. /// class TargetOperandInfo { public: /// RegClass - This specifies the register class enumeration of the operand /// if the operand is a register. If isLookupPtrRegClass is set, then this is /// an index that is passed to TargetRegisterInfo::getPointerRegClass(x) to /// get a dynamic register class. /// /// NOTE: This member should be considered to be private, all access should go /// through "getRegClass(TRI)" below. unsigned short RegClass; /// Flags - These are flags from the TOI::OperandFlags enum. unsigned short Flags; /// Lower 16 bits are used to specify which constraints are set. The higher 16 /// bits are used to specify the value of constraints (4 bits each). unsigned Constraints; /// Currently no other information. /// getRegClass - Get the register class for the operand, handling resolution /// of "symbolic" pointer register classes etc. If this is not a register /// operand, this returns null. const TargetRegisterClass *getRegClass(const TargetRegisterInfo *TRI) const; /// isLookupPtrRegClass - Set if this operand is a pointer value and it /// requires a callback to look up its register class. bool isLookupPtrRegClass() const { return Flags&(1 <> Pos) & 0xf; } return -1; } /// getOpcode - Return the opcode number for this descriptor. unsigned getOpcode() const { return Opcode; } /// getName - Return the name of the record in the .td file for this /// instruction, for example "ADD8ri". const char *getName() const { return Name; } /// getNumOperands - Return the number of declared MachineOperands for this /// MachineInstruction. Note that variadic (isVariadic() returns true) /// instructions may have additional operands at the end of the list, and note /// that the machine instruction may include implicit register def/uses as /// well. unsigned getNumOperands() const { return NumOperands; } /// getNumDefs - Return the number of MachineOperands that are register /// definitions. Register definitions always occur at the start of the /// machine operand list. This is the number of "outs" in the .td file, /// and does not include implicit defs. unsigned getNumDefs() const { return NumDefs; } /// isVariadic - Return true if this instruction can have a variable number of /// operands. In this case, the variable operands will be after the normal /// operands but before the implicit definitions and uses (if any are /// present). bool isVariadic() const { return Flags & (1 << TID::Variadic); } /// hasOptionalDef - Set if this instruction has an optional definition, e.g. /// ARM instructions which can set condition code if 's' bit is set. bool hasOptionalDef() const { return Flags & (1 << TID::HasOptionalDef); } /// getImplicitUses - Return a list of registers that are potentially /// read by any instance of this machine instruction. For example, on X86, /// the "adc" instruction adds two register operands and adds the carry bit in /// from the flags register. In this case, the instruction is marked as /// implicitly reading the flags. Likewise, the variable shift instruction on /// X86 is marked as implicitly reading the 'CL' register, which it always /// does. /// /// This method returns null if the instruction has no implicit uses. const unsigned *getImplicitUses() const { return ImplicitUses; } /// getImplicitDefs - Return a list of registers that are potentially /// written by any instance of this machine instruction. For example, on X86, /// many instructions implicitly set the flags register. In this case, they /// are marked as setting the FLAGS. Likewise, many instructions always /// deposit their result in a physical register. For example, the X86 divide /// instruction always deposits the quotient and remainder in the EAX/EDX /// registers. For that instruction, this will return a list containing the /// EAX/EDX/EFLAGS registers. /// /// This method returns null if the instruction has no implicit defs. const unsigned *getImplicitDefs() const { return ImplicitDefs; } /// hasImplicitUseOfPhysReg - Return true if this instruction implicitly /// uses the specified physical register. bool hasImplicitUseOfPhysReg(unsigned Reg) const { if (const unsigned *ImpUses = ImplicitUses) for (; *ImpUses; ++ImpUses) if (*ImpUses == Reg) return true; return false; } /// hasImplicitDefOfPhysReg - Return true if this instruction implicitly /// defines the specified physical register. bool hasImplicitDefOfPhysReg(unsigned Reg) const { if (const unsigned *ImpDefs = ImplicitDefs) for (; *ImpDefs; ++ImpDefs) if (*ImpDefs == Reg) return true; return false; } /// getRegClassBarriers - Return a list of register classes that are /// completely clobbered by this machine instruction. For example, on X86 /// the call instructions will completely clobber all the registers in the /// fp stack and XMM classes. /// /// This method returns null if the instruction doesn't completely clobber /// any register class. const TargetRegisterClass **getRegClassBarriers() const { return RCBarriers; } /// getSchedClass - Return the scheduling class for this instruction. The /// scheduling class is an index into the InstrItineraryData table. This /// returns zero if there is no known scheduling information for the /// instruction. /// unsigned getSchedClass() const { return SchedClass; } bool isReturn() const { return Flags & (1 << TID::Return); } bool isCall() const { return Flags & (1 << TID::Call); } /// isBarrier - Returns true if the specified instruction stops control flow /// from executing the instruction immediately following it. Examples include /// unconditional branches and return instructions. bool isBarrier() const { return Flags & (1 << TID::Barrier); } /// isTerminator - Returns true if this instruction part of the terminator for /// a basic block. Typically this is things like return and branch /// instructions. /// /// Various passes use this to insert code into the bottom of a basic block, /// but before control flow occurs. bool isTerminator() const { return Flags & (1 << TID::Terminator); } /// isBranch - Returns true if this is a conditional, unconditional, or /// indirect branch. Predicates below can be used to discriminate between /// these cases, and the TargetInstrInfo::AnalyzeBranch method can be used to /// get more information. bool isBranch() const { return Flags & (1 << TID::Branch); } /// isIndirectBranch - Return true if this is an indirect branch, such as a /// branch through a register. bool isIndirectBranch() const { return Flags & (1 << TID::IndirectBranch); } /// isConditionalBranch - Return true if this is a branch which may fall /// through to the next instruction or may transfer control flow to some other /// block. The TargetInstrInfo::AnalyzeBranch method can be used to get more /// information about this branch. bool isConditionalBranch() const { return isBranch() & !isBarrier() & !isIndirectBranch(); } /// isUnconditionalBranch - Return true if this is a branch which always /// transfers control flow to some other block. The /// TargetInstrInfo::AnalyzeBranch method can be used to get more information /// about this branch. bool isUnconditionalBranch() const { return isBranch() & isBarrier() & !isIndirectBranch(); } // isPredicable - Return true if this instruction has a predicate operand that // controls execution. It may be set to 'always', or may be set to other /// values. There are various methods in TargetInstrInfo that can be used to /// control and modify the predicate in this instruction. bool isPredicable() const { return Flags & (1 << TID::Predicable); } /// isNotDuplicable - Return true if this instruction cannot be safely /// duplicated. For example, if the instruction has a unique labels attached /// to it, duplicating it would cause multiple definition errors. bool isNotDuplicable() const { return Flags & (1 << TID::NotDuplicable); } /// hasDelaySlot - Returns true if the specified instruction has a delay slot /// which must be filled by the code generator. bool hasDelaySlot() const { return Flags & (1 << TID::DelaySlot); } /// canFoldAsLoad - Return true for instructions that can be folded as /// memory operands in other instructions. The most common use for this /// is instructions that are simple loads from memory that don't modify /// the loaded value in any way, but it can also be used for instructions /// that can be expressed as constant-pool loads, such as V_SETALLONES /// on x86, to allow them to be folded when it is beneficial. /// This should only be set on instructions that return a value in their /// only virtual register definition. bool canFoldAsLoad() const { return Flags & (1 << TID::FoldableAsLoad); } //===--------------------------------------------------------------------===// // Side Effect Analysis //===--------------------------------------------------------------------===// /// mayLoad - Return true if this instruction could possibly read memory. /// Instructions with this flag set are not necessarily simple load /// instructions, they may load a value and modify it, for example. bool mayLoad() const { return Flags & (1 << TID::MayLoad); } /// mayStore - Return true if this instruction could possibly modify memory. /// Instructions with this flag set are not necessarily simple store /// instructions, they may store a modified value based on their operands, or /// may not actually modify anything, for example. bool mayStore() const { return Flags & (1 << TID::MayStore); } /// hasUnmodeledSideEffects - Return true if this instruction has side /// effects that are not modeled by other flags. This does not return true /// for instructions whose effects are captured by: /// /// 1. Their operand list and implicit definition/use list. Register use/def /// info is explicit for instructions. /// 2. Memory accesses. Use mayLoad/mayStore. /// 3. Calling, branching, returning: use isCall/isReturn/isBranch. /// /// Examples of side effects would be modifying 'invisible' machine state like /// a control register, flushing a cache, modifying a register invisible to /// LLVM, etc. /// bool hasUnmodeledSideEffects() const { return Flags & (1 << TID::UnmodeledSideEffects); } //===--------------------------------------------------------------------===// // Flags that indicate whether an instruction can be modified by a method. //===--------------------------------------------------------------------===// /// isCommutable - Return true if this may be a 2- or 3-address /// instruction (of the form "X = op Y, Z, ..."), which produces the same /// result if Y and Z are exchanged. If this flag is set, then the /// TargetInstrInfo::commuteInstruction method may be used to hack on the /// instruction. /// /// Note that this flag may be set on instructions that are only commutable /// sometimes. In these cases, the call to commuteInstruction will fail. /// Also note that some instructions require non-trivial modification to /// commute them. bool isCommutable() const { return Flags & (1 << TID::Commutable); } /// isConvertibleTo3Addr - Return true if this is a 2-address instruction /// which can be changed into a 3-address instruction if needed. Doing this /// transformation can be profitable in the register allocator, because it /// means that the instruction can use a 2-address form if possible, but /// degrade into a less efficient form if the source and dest register cannot /// be assigned to the same register. For example, this allows the x86 /// backend to turn a "shl reg, 3" instruction into an LEA instruction, which /// is the same speed as the shift but has bigger code size. /// /// If this returns true, then the target must implement the /// TargetInstrInfo::convertToThreeAddress method for this instruction, which /// is allowed to fail if the transformation isn't valid for this specific /// instruction (e.g. shl reg, 4 on x86). /// bool isConvertibleTo3Addr() const { return Flags & (1 << TID::ConvertibleTo3Addr); } /// usesCustomInsertionHook - Return true if this instruction requires /// custom insertion support when the DAG scheduler is inserting it into a /// machine basic block. If this is true for the instruction, it basically /// means that it is a pseudo instruction used at SelectionDAG time that is /// expanded out into magic code by the target when MachineInstrs are formed. /// /// If this is true, the TargetLoweringInfo::InsertAtEndOfBasicBlock method /// is used to insert this into the MachineBasicBlock. bool usesCustomInsertionHook() const { return Flags & (1 << TID::UsesCustomInserter); } /// isRematerializable - Returns true if this instruction is a candidate for /// remat. This flag is deprecated, please don't use it anymore. If this /// flag is set, the isReallyTriviallyReMaterializable() method is called to /// verify the instruction is really rematable. bool isRematerializable() const { return Flags & (1 << TID::Rematerializable); } /// isAsCheapAsAMove - Returns true if this instruction has the same cost (or /// less) than a move instruction. This is useful during certain types of /// optimizations (e.g., remat during two-address conversion or machine licm) /// where we would like to remat or hoist the instruction, but not if it costs /// more than moving the instruction into the appropriate register. Note, we /// are not marking copies from and to the same register class with this flag. bool isAsCheapAsAMove() const { return Flags & (1 << TID::CheapAsAMove); } /// hasExtraSrcRegAllocReq - Returns true if this instruction source operands /// have special register allocation requirements that are not captured by the /// operand register classes. e.g. ARM::STRD's two source registers must be an /// even / odd pair, ARM::STM registers have to be in ascending order. /// Post-register allocation passes should not attempt to change allocations /// for sources of instructions with this flag. bool hasExtraSrcRegAllocReq() const { return Flags & (1 << TID::ExtraSrcRegAllocReq); } /// hasExtraDefRegAllocReq - Returns true if this instruction def operands /// have special register allocation requirements that are not captured by the /// operand register classes. e.g. ARM::LDRD's two def registers must be an /// even / odd pair, ARM::LDM registers have to be in ascending order. /// Post-register allocation passes should not attempt to change allocations /// for definitions of instructions with this flag. bool hasExtraDefRegAllocReq() const { return Flags & (1 << TID::ExtraDefRegAllocReq); } }; } // end namespace llvm #endif