third_party/subzero/src/IceRegistersMIPS32.h - SwiftShader - Git at Google

 //===- subzero/src/IceRegistersMIPS32.h - Register information --*- C++ -*-===//
 //
 //                        The Subzero Code Generator
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 ///
 /// \file
 /// \brief Declares the registers and their encodings for MIPS32.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef SUBZERO_SRC_ICEREGISTERSMIPS32_H
 #define SUBZERO_SRC_ICEREGISTERSMIPS32_H

 #include "IceDefs.h"
 #include "IceInstMIPS32.def"
 #include "IceOperand.h" // RC_Target
 #include "IceTypes.h"

 namespace Ice {
 namespace MIPS32 {
 namespace RegMIPS32 {

 /// An enum of every register. The enum value may not match the encoding used to
 /// binary encode register operands in instructions.
 enum AllRegisters {
 #define X(val, encode, name, scratch, preserved, stackptr, frameptr, isInt,    \
           isI64Pair, isFP32, isFP64, isVec128, alias_init)                     \
   val,
   REGMIPS32_TABLE
 #undef X
       Reg_NUM,
 #define X(val, init) val init,
   REGMIPS32_TABLE_BOUNDS
 #undef X
 };

 /// An enum of GPR Registers. The enum value does match the encoding used to
 /// binary encode register operands in instructions.
 enum GPRRegister {
 #define X(val, encode, name, scratch, preserved, stackptr, frameptr, isInt,    \
           isI64Pair, isFP32, isFP64, isVec128, alias_init)                     \
                                                                                \
   Encoded_##val = encode,
   REGMIPS32_GPR_TABLE
 #undef X
       Encoded_Not_GPR = -1
 };

 /// An enum of FPR Registers. The enum value does match the encoding used to
 /// binary encode register operands in instructions.
 enum FPRRegister {
 #define X(val, encode, name, scratch, preserved, stackptr, frameptr, isInt,    \
           isI64Pair, isFP32, isFP64, isVec128, alias_init)                     \
                                                                                \
   Encoded_##val = encode,
   REGMIPS32_FPR_TABLE
 #undef X
       Encoded_Not_FPR = -1
 };

 // TODO(jvoung): Floating point and vector registers...
 // Need to model overlap and difference in encoding too.

 static inline GPRRegister getEncodedGPR(RegNumT RegNum) {
   assert(int(Reg_GPR_First) <= int(RegNum));
   assert(unsigned(RegNum) <= Reg_GPR_Last);
   return GPRRegister(RegNum - Reg_GPR_First);
 }

 static inline bool isGPRReg(RegNumT RegNum) {
   bool IsGPR = ((int(Reg_GPR_First) <= int(RegNum)) &&
                 (unsigned(RegNum) <= Reg_GPR_Last)) ||
                ((int(Reg_I64PAIR_First) <= int(RegNum)) &&
                 (unsigned(RegNum) <= Reg_I64PAIR_Last));
   return IsGPR;
 }

 static inline FPRRegister getEncodedFPR(RegNumT RegNum) {
   assert(int(Reg_FPR_First) <= int(RegNum));
   assert(unsigned(RegNum) <= Reg_FPR_Last);
   return FPRRegister(RegNum - Reg_FPR_First);
 }

 static inline bool isFPRReg(RegNumT RegNum) {
   return ((int(Reg_FPR_First) <= int(RegNum)) &&
           (unsigned(RegNum) <= Reg_FPR_Last));
 }

 static inline FPRRegister getEncodedFPR64(RegNumT RegNum) {
   assert(int(Reg_F64PAIR_First) <= int(RegNum));
   assert(unsigned(RegNum) <= Reg_F64PAIR_Last);
   return FPRRegister((RegNum - Reg_F64PAIR_First) * 2);
 }

 static inline bool isFPR64Reg(RegNumT RegNum) {
   return (int(Reg_F64PAIR_First) <= int(RegNum)) &&
          (unsigned(RegNum) <= Reg_F64PAIR_Last);
 }

 const char *getRegName(RegNumT RegNum);

 static inline RegNumT get64PairFirstRegNum(RegNumT RegNum) {
   assert(unsigned(RegNum) >= Reg_I64PAIR_First);
   assert(unsigned(RegNum) <= Reg_F64PAIR_Last);
   if (unsigned(RegNum) >= Reg_F64PAIR_First &&
       unsigned(RegNum) <= Reg_F64PAIR_Last)
     return RegNumT::fixme(((RegNum - Reg_F64PAIR_First) * 2) +
                           unsigned(Reg_FPR_First));
   if (unsigned(RegNum) >= Reg_I64PAIR_First && unsigned(RegNum) <= Reg_T8T9)
     return RegNumT::fixme(((RegNum - Reg_I64PAIR_First) * 2) +
                           unsigned(Reg_V0));
   return RegMIPS32::Reg_LO;
 }

 static inline RegNumT get64PairSecondRegNum(RegNumT RegNum) {
   assert(unsigned(RegNum) >= Reg_I64PAIR_First);
   assert(unsigned(RegNum) <= Reg_F64PAIR_Last);
   if (unsigned(RegNum) >= Reg_F64PAIR_First &&
       unsigned(RegNum) <= Reg_F64PAIR_Last)
     return RegNumT::fixme(((RegNum - Reg_F64PAIR_First) * 2) +
                           unsigned(Reg_FPR_First) + 1);
   if (unsigned(RegNum) >= Reg_I64PAIR_First && unsigned(RegNum) <= Reg_T8T9)
     return RegNumT::fixme(((RegNum - Reg_I64PAIR_First) * 2) +
                           unsigned(Reg_V1));
   return RegMIPS32::Reg_HI;
 }

 } // end of namespace RegMIPS32

 // Extend enum RegClass with MIPS32-specific register classes (if any).
 enum RegClassMIPS32 : uint8_t { RCMIPS32_NUM = RC_Target };

 } // end of namespace MIPS32
 } // end of namespace Ice

 #endif // SUBZERO_SRC_ICEREGISTERSMIPS32_H
	//===- subzero/src/IceRegistersMIPS32.h - Register information --- C++ --===//
	//
	// The Subzero Code Generator
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	///
	/// \file
	/// \brief Declares the registers and their encodings for MIPS32.
	///
	//===----------------------------------------------------------------------===//

	#ifndef SUBZERO_SRC_ICEREGISTERSMIPS32_H
	#define SUBZERO_SRC_ICEREGISTERSMIPS32_H

	#include "IceDefs.h"
	#include "IceInstMIPS32.def"
	#include "IceOperand.h" // RC_Target
	#include "IceTypes.h"

	namespace Ice {
	namespace MIPS32 {
	namespace RegMIPS32 {

	/// An enum of every register. The enum value may not match the encoding used to
	/// binary encode register operands in instructions.
	enum AllRegisters {
	#define X(val, encode, name, scratch, preserved, stackptr, frameptr, isInt, \
	isI64Pair, isFP32, isFP64, isVec128, alias_init) \
	val,
	REGMIPS32_TABLE
	#undef X
	Reg_NUM,
	#define X(val, init) val init,
	REGMIPS32_TABLE_BOUNDS
	#undef X
	};

	/// An enum of GPR Registers. The enum value does match the encoding used to
	/// binary encode register operands in instructions.
	enum GPRRegister {
	#define X(val, encode, name, scratch, preserved, stackptr, frameptr, isInt, \
	isI64Pair, isFP32, isFP64, isVec128, alias_init) \
	\
	Encoded_##val = encode,
	REGMIPS32_GPR_TABLE
	#undef X
	Encoded_Not_GPR = -1
	};

	/// An enum of FPR Registers. The enum value does match the encoding used to
	/// binary encode register operands in instructions.
	enum FPRRegister {
	#define X(val, encode, name, scratch, preserved, stackptr, frameptr, isInt, \
	isI64Pair, isFP32, isFP64, isVec128, alias_init) \
	\
	Encoded_##val = encode,
	REGMIPS32_FPR_TABLE
	#undef X
	Encoded_Not_FPR = -1
	};

	// TODO(jvoung): Floating point and vector registers...
	// Need to model overlap and difference in encoding too.

	static inline GPRRegister getEncodedGPR(RegNumT RegNum) {
	assert(int(Reg_GPR_First) <= int(RegNum));
	assert(unsigned(RegNum) <= Reg_GPR_Last);
	return GPRRegister(RegNum - Reg_GPR_First);
	}

	static inline bool isGPRReg(RegNumT RegNum) {
	bool IsGPR = ((int(Reg_GPR_First) <= int(RegNum)) &&
	(unsigned(RegNum) <= Reg_GPR_Last)) \|\|
	((int(Reg_I64PAIR_First) <= int(RegNum)) &&
	(unsigned(RegNum) <= Reg_I64PAIR_Last));
	return IsGPR;
	}

	static inline FPRRegister getEncodedFPR(RegNumT RegNum) {
	assert(int(Reg_FPR_First) <= int(RegNum));
	assert(unsigned(RegNum) <= Reg_FPR_Last);
	return FPRRegister(RegNum - Reg_FPR_First);
	}

	static inline bool isFPRReg(RegNumT RegNum) {
	return ((int(Reg_FPR_First) <= int(RegNum)) &&
	(unsigned(RegNum) <= Reg_FPR_Last));
	}

	static inline FPRRegister getEncodedFPR64(RegNumT RegNum) {
	assert(int(Reg_F64PAIR_First) <= int(RegNum));
	assert(unsigned(RegNum) <= Reg_F64PAIR_Last);
	return FPRRegister((RegNum - Reg_F64PAIR_First) * 2);
	}

	static inline bool isFPR64Reg(RegNumT RegNum) {
	return (int(Reg_F64PAIR_First) <= int(RegNum)) &&
	(unsigned(RegNum) <= Reg_F64PAIR_Last);
	}

	const char *getRegName(RegNumT RegNum);

	static inline RegNumT get64PairFirstRegNum(RegNumT RegNum) {
	assert(unsigned(RegNum) >= Reg_I64PAIR_First);
	assert(unsigned(RegNum) <= Reg_F64PAIR_Last);
	if (unsigned(RegNum) >= Reg_F64PAIR_First &&
	unsigned(RegNum) <= Reg_F64PAIR_Last)
	return RegNumT::fixme(((RegNum - Reg_F64PAIR_First) * 2) +
	unsigned(Reg_FPR_First));
	if (unsigned(RegNum) >= Reg_I64PAIR_First && unsigned(RegNum) <= Reg_T8T9)
	return RegNumT::fixme(((RegNum - Reg_I64PAIR_First) * 2) +
	unsigned(Reg_V0));
	return RegMIPS32::Reg_LO;
	}

	static inline RegNumT get64PairSecondRegNum(RegNumT RegNum) {
	assert(unsigned(RegNum) >= Reg_I64PAIR_First);
	assert(unsigned(RegNum) <= Reg_F64PAIR_Last);
	if (unsigned(RegNum) >= Reg_F64PAIR_First &&
	unsigned(RegNum) <= Reg_F64PAIR_Last)
	return RegNumT::fixme(((RegNum - Reg_F64PAIR_First) * 2) +
	unsigned(Reg_FPR_First) + 1);
	if (unsigned(RegNum) >= Reg_I64PAIR_First && unsigned(RegNum) <= Reg_T8T9)
	return RegNumT::fixme(((RegNum - Reg_I64PAIR_First) * 2) +
	unsigned(Reg_V1));
	return RegMIPS32::Reg_HI;
	}

	} // end of namespace RegMIPS32

	// Extend enum RegClass with MIPS32-specific register classes (if any).
	enum RegClassMIPS32 : uint8_t { RCMIPS32_NUM = RC_Target };

	} // end of namespace MIPS32
	} // end of namespace Ice

	#endif // SUBZERO_SRC_ICEREGISTERSMIPS32_H