//===- X86RecognizableInstr.h - Disassembler instruction spec ----*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file is part of the X86 Disassembler Emitter. // It contains the interface of a single recognizable instruction. // Documentation for the disassembler emitter in general can be found in // X86DisasemblerEmitter.h. // //===----------------------------------------------------------------------===// #ifndef X86RECOGNIZABLEINSTR_H #define X86RECOGNIZABLEINSTR_H #include "X86DisassemblerTables.h" #include "CodeGenTarget.h" #include "llvm/TableGen/Record.h" #include "llvm/Support/DataTypes.h" #include "llvm/ADT/SmallVector.h" namespace llvm { namespace X86Disassembler { /// RecognizableInstr - Encapsulates all information required to decode a single /// instruction, as extracted from the LLVM instruction tables. Has methods /// to interpret the information available in the LLVM tables, and to emit the /// instruction into DisassemblerTables. class RecognizableInstr { private: /// The opcode of the instruction, as used in an MCInst InstrUID UID; /// The record from the .td files corresponding to this instruction const Record* Rec; /// The prefix field from the record uint8_t Prefix; /// The opcode field from the record; this is the opcode used in the Intel /// encoding and therefore distinct from the UID uint8_t Opcode; /// The form field from the record uint8_t Form; /// The segment override field from the record uint8_t SegOvr; /// The hasOpSizePrefix field from the record bool HasOpSizePrefix; /// The hasREX_WPrefix field from the record bool HasREX_WPrefix; /// The hasVEXPrefix field from the record bool HasVEXPrefix; /// The hasVEX_4VPrefix field from the record bool HasVEX_4VPrefix; /// The hasVEX_WPrefix field from the record bool HasVEX_WPrefix; /// Inferred from the operands; indicates whether the L bit in the VEX prefix is set bool HasVEX_LPrefix; // The ignoreVEX_L field from the record bool IgnoresVEX_L; /// The hasLockPrefix field from the record bool HasLockPrefix; /// The isCodeGenOnly filed from the record bool IsCodeGenOnly; // Whether the instruction has the predicate "In64BitMode" bool Is64Bit; // Whether the instruction has the predicate "In32BitMode" bool Is32Bit; /// The instruction name as listed in the tables std::string Name; /// The AT&T AsmString for the instruction std::string AsmString; /// Indicates whether the instruction is SSE bool IsSSE; /// Indicates whether the instruction has FR operands - MOVs with FR operands /// are typically ignored bool HasFROperands; /// Indicates whether the instruction should be emitted into the decode /// tables; regardless, it will be emitted into the instruction info table bool ShouldBeEmitted; /// The operands of the instruction, as listed in the CodeGenInstruction. /// They are not one-to-one with operands listed in the MCInst; for example, /// memory operands expand to 5 operands in the MCInst const std::vector<CGIOperandList::OperandInfo>* Operands; /// The description of the instruction that is emitted into the instruction /// info table InstructionSpecifier* Spec; /// insnContext - Returns the primary context in which the instruction is /// valid. /// /// @return - The context in which the instruction is valid. InstructionContext insnContext() const; enum filter_ret { FILTER_STRONG, // instruction has no place in the instruction tables FILTER_WEAK, // instruction may conflict, and should be eliminated if // it does FILTER_NORMAL // instruction should have high priority and generate an // error if it conflcits with any other FILTER_NORMAL // instruction }; /// filter - Determines whether the instruction should be decodable. Some /// instructions are pure intrinsics and use unencodable operands; many /// synthetic instructions are duplicates of other instructions; other /// instructions only differ in the logical way in which they are used, and /// have the same decoding. Because these would cause decode conflicts, /// they must be filtered out. /// /// @return - The degree of filtering to be applied (see filter_ret). filter_ret filter() const; /// hasFROperands - Returns true if any operand is a FR operand. bool hasFROperands() const; /// has256BitOperands - Returns true if any operand is a 256-bit SSE operand. bool has256BitOperands() const; /// typeFromString - Translates an operand type from the string provided in /// the LLVM tables to an OperandType for use in the operand specifier. /// /// @param s - The string, as extracted by calling Rec->getName() /// on a CodeGenInstruction::OperandInfo. /// @param isSSE - Indicates whether the instruction is an SSE /// instruction. For SSE instructions, immediates are /// fixed-size rather than being affected by the /// mandatory OpSize prefix. /// @param hasREX_WPrefix - Indicates whether the instruction has a REX.W /// prefix. If it does, 32-bit register operands stay /// 32-bit regardless of the operand size. /// @param hasOpSizePrefix- Indicates whether the instruction has an OpSize /// prefix. If it does not, then 16-bit register /// operands stay 16-bit. /// @return - The operand's type. static OperandType typeFromString(const std::string& s, bool isSSE, bool hasREX_WPrefix, bool hasOpSizePrefix); /// immediateEncodingFromString - Translates an immediate encoding from the /// string provided in the LLVM tables to an OperandEncoding for use in /// the operand specifier. /// /// @param s - See typeFromString(). /// @param hasOpSizePrefix - Indicates whether the instruction has an OpSize /// prefix. If it does not, then 16-bit immediate /// operands stay 16-bit. /// @return - The operand's encoding. static OperandEncoding immediateEncodingFromString(const std::string &s, bool hasOpSizePrefix); /// rmRegisterEncodingFromString - Like immediateEncodingFromString, but /// handles operands that are in the REG field of the ModR/M byte. static OperandEncoding rmRegisterEncodingFromString(const std::string &s, bool hasOpSizePrefix); /// rmRegisterEncodingFromString - Like immediateEncodingFromString, but /// handles operands that are in the REG field of the ModR/M byte. static OperandEncoding roRegisterEncodingFromString(const std::string &s, bool hasOpSizePrefix); static OperandEncoding memoryEncodingFromString(const std::string &s, bool hasOpSizePrefix); static OperandEncoding relocationEncodingFromString(const std::string &s, bool hasOpSizePrefix); static OperandEncoding opcodeModifierEncodingFromString(const std::string &s, bool hasOpSizePrefix); static OperandEncoding vvvvRegisterEncodingFromString(const std::string &s, bool HasOpSizePrefix); /// handleOperand - Converts a single operand from the LLVM table format to /// the emitted table format, handling any duplicate operands it encounters /// and then one non-duplicate. /// /// @param optional - Determines whether to assert that the /// operand exists. /// @param operandIndex - The index into the generated operand table. /// Incremented by this function one or more /// times to reflect possible duplicate /// operands). /// @param physicalOperandIndex - The index of the current operand into the /// set of non-duplicate ('physical') operands. /// Incremented by this function once. /// @param numPhysicalOperands - The number of non-duplicate operands in the /// instructions. /// @param operandMapping - The operand mapping, which has an entry for /// each operand that indicates whether it is a /// duplicate, and of what. void handleOperand(bool optional, unsigned &operandIndex, unsigned &physicalOperandIndex, unsigned &numPhysicalOperands, unsigned *operandMapping, OperandEncoding (*encodingFromString) (const std::string&, bool hasOpSizePrefix)); /// shouldBeEmitted - Returns the shouldBeEmitted field. Although filter() /// filters out many instructions, at various points in decoding we /// determine that the instruction should not actually be decodable. In /// particular, MMX MOV instructions aren't emitted, but they're only /// identified during operand parsing. /// /// @return - true if at this point we believe the instruction should be /// emitted; false if not. This will return false if filter() returns false /// once emitInstructionSpecifier() has been called. bool shouldBeEmitted() const { return ShouldBeEmitted; } /// emitInstructionSpecifier - Loads the instruction specifier for the current /// instruction into a DisassemblerTables. /// /// @arg tables - The DisassemblerTables to populate with the specifier for /// the current instruction. void emitInstructionSpecifier(DisassemblerTables &tables); /// emitDecodePath - Populates the proper fields in the decode tables /// corresponding to the decode paths for this instruction. /// /// @arg tables - The DisassemblerTables to populate with the decode /// decode information for the current instruction. void emitDecodePath(DisassemblerTables &tables) const; /// Constructor - Initializes a RecognizableInstr with the appropriate fields /// from a CodeGenInstruction. /// /// @arg tables - The DisassemblerTables that the specifier will be added to. /// @arg insn - The CodeGenInstruction to extract information from. /// @arg uid - The unique ID of the current instruction. RecognizableInstr(DisassemblerTables &tables, const CodeGenInstruction &insn, InstrUID uid); public: /// processInstr - Accepts a CodeGenInstruction and loads decode information /// for it into a DisassemblerTables if appropriate. /// /// @arg tables - The DiassemblerTables to be populated with decode /// information. /// @arg insn - The CodeGenInstruction to be used as a source for this /// information. /// @uid - The unique ID of the instruction. static void processInstr(DisassemblerTables &tables, const CodeGenInstruction &insn, InstrUID uid); }; } // namespace X86Disassembler } // namespace llvm #endif