src/IceInstARM32.def - SwiftShader - Git at Google

 //===- subzero/src/IceInstARM32.def - X-Macros for ARM32 insts --*- C++ -*-===//
 //
 //                        The Subzero Code Generator
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines properties of ARM32 instructions in the form of x-macros.
 //
 //===----------------------------------------------------------------------===//

 #ifndef SUBZERO_SRC_ICEINSTARM32_DEF
 #define SUBZERO_SRC_ICEINSTARM32_DEF

 // NOTE: PC and SP are not considered isInt, to avoid register allocating.
 // For the NaCl sandbox we also need to r9 for TLS, so just reserve always.
 // TODO(jvoung): Allow r9 to be isInt when sandboxing is turned off
 // (native mode).
 #define REGARM32_GPR_TABLE                                                     \
   /* val, encode, name, scratch, preserved, stackptr, frameptr, isInt, isFP */ \
   X(Reg_r0,  = 0,            "r0",  1, 0, 0, 0, 1, 0)                   \
   X(Reg_r1,  = Reg_r0 + 1,   "r1",  1, 0, 0, 0, 1, 0)                   \
   X(Reg_r2,  = Reg_r0 + 2,   "r2",  1, 0, 0, 0, 1, 0)                   \
   X(Reg_r3,  = Reg_r0 + 3,   "r3",  1, 0, 0, 0, 1, 0)                   \
   X(Reg_r4,  = Reg_r0 + 4,   "r4",  0, 1, 0, 0, 1, 0)                   \
   X(Reg_r5,  = Reg_r0 + 5,   "r5",  0, 1, 0, 0, 1, 0)                   \
   X(Reg_r6,  = Reg_r0 + 6,   "r6",  0, 1, 0, 0, 1, 0)                   \
   X(Reg_r7,  = Reg_r0 + 7,   "r7",  0, 1, 0, 0, 1, 0)                   \
   X(Reg_r8,  = Reg_r0 + 8,   "r8",  0, 1, 0, 0, 1, 0)                   \
   X(Reg_r9,  = Reg_r0 + 9,   "r9",  0, 1, 0, 0, 0, 0)                   \
   X(Reg_r10, = Reg_r0 + 10,  "r10", 0, 1, 0, 0, 1, 0)                   \
   X(Reg_fp,  = Reg_r0 + 11,  "fp",  0, 1, 0, 1, 1, 0)                   \
   X(Reg_ip,  = Reg_r0 + 12,  "ip",  1, 0, 0, 0, 1, 0)                   \
   X(Reg_sp,  = Reg_r0 + 13,  "sp",  0, 1, 1, 0, 0, 0)                   \
   X(Reg_lr,  = Reg_r0 + 14,  "lr",  0, 1, 0, 0, 1, 0)                   \
   X(Reg_pc,  = Reg_r0 + 15,  "pc",  0, 1, 0, 0, 0, 0)                   \
 //#define X(val, encode, name, scratch, preserved, stackptr, frameptr,
 //          isInt, isFP)

 // TODO(jvoung): List FP registers and know S0 == D0 == Q0, etc.
 // Be able to grab even registers, and the corresponding odd register
 // for each even register.

 // We also provide a combined table, so that there is a namespace where
 // all of the registers are considered and have distinct numberings.
 // This is in contrast to the above, where the "encode" is based on how
 // the register numbers will be encoded in binaries and values can overlap.
 #define REGARM32_TABLE                                                  \
   /* val, encode, name, scratch, preserved, stackptr, frameptr, isInt, isFP */ \
   REGARM32_GPR_TABLE
 //#define X(val, encode, name, scratch, preserved, stackptr, frameptr,
 //          isInt, isFP)

 #define REGARM32_TABLE_BOUNDS                                           \
   /* val, init */                                                       \
   X(Reg_GPR_First, = Reg_r0)                                            \
   X(Reg_GPR_Last,  = Reg_pc)
 //define X(val, init)

 // TODO(jvoung): add condition code tables, etc.

 // Load/Store instruction width suffixes.
 #define ICETYPEARM32_TABLE                                              \
   /* tag,          element type, width, addr off bits sext, zext */     \
   X(IceType_void,  IceType_void, "",  0, 0)                             \
   X(IceType_i1,    IceType_void, "b", 8, 12)                            \
   X(IceType_i8,    IceType_void, "b", 8, 12)                            \
   X(IceType_i16,   IceType_void, "h", 8, 8)                             \
   X(IceType_i32,   IceType_void, "", 12, 12)                            \
   X(IceType_i64,   IceType_void, "d", 8, 8)                             \
   X(IceType_f32,   IceType_void, "", 10, 10)                            \
   X(IceType_f64,   IceType_void, "", 10, 10)                            \
   X(IceType_v4i1,  IceType_i32 , "",  0,  0)                            \
   X(IceType_v8i1,  IceType_i16 , "",  0,  0)                            \
   X(IceType_v16i1, IceType_i8  , "",  0,  0)                            \
   X(IceType_v16i8, IceType_i8  , "",  0,  0)                            \
   X(IceType_v8i16, IceType_i16 , "",  0,  0)                            \
   X(IceType_v4i32, IceType_i32 , "",  0,  0)                            \
   X(IceType_v4f32, IceType_f32 , "",  0,  0)                            \
 //#define X(tag, elementty, width, sbits, ubits)

 // Shifter types for Data-processing operands as defined in section A5.1.2.
 #define ICEINSTARM32SHIFT_TABLE                                         \
   /* enum value, emit */                                                \
   X(LSL, "lsl")                                                         \
   X(LSR, "lsr")                                                         \
   X(ASR, "asr")                                                         \
   X(ROR, "ror")                                                         \
   X(RRX, "rrx")                                                         \
 //#define X(tag, emit)

 // Attributes for the condition code 4-bit encoding (that is independent
 // of the APSR's NZCV fields). For example, EQ is 0, but corresponds to
 // Z = 1, and NE is 1, but corresponds to Z = 0.
 #define ICEINSTARM32COND_TABLE                                          \
   /* enum value, encoding, opposite, emit */                            \
   X(EQ, 0, NE, "eq") /* equal */                                        \
   X(NE, 1, EQ, "ne") /* not equal */                                    \
   X(CS, 2, CC, "cs") /* carry set/unsigned (AKA hs: higher or same) */  \
   X(CC, 3, CS, "cc") /* carry clear/unsigned (AKA lo: lower) */         \
   X(MI, 4, PL, "mi") /* minus/negative */                               \
   X(PL, 5, MI, "pl") /* plus/positive or zero */                        \
   X(VS, 6, VC, "vs") /* overflow (float unordered) */                   \
   X(VC, 7, VS, "vc") /* no overflow (float not unordered) */            \
   X(HI, 8, LS, "hi") /* unsigned higher */                              \
   X(LS, 9, HI, "ls") /* unsigned lower or same */                       \
   X(GE, 10, LT, "ge") /* signed greater than or equal */                \
   X(LT, 11, GE, "lt") /* signed less than */                            \
   X(GT, 12, LE, "gt") /* signed greater than */                         \
   X(LE, 13, GT, "le") /* signed less than or equal */                   \
   X(AL, 14, kNone, "") /* always (unconditional) */                     \
   X(kNone, 15, kNone, "??") /* special condition / none */              \
 //#define(tag, encode, opp, emit)

 #endif // SUBZERO_SRC_ICEINSTARM32_DEF
	//===- subzero/src/IceInstARM32.def - X-Macros for ARM32 insts --- C++ --===//
	//
	// The Subzero Code Generator
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines properties of ARM32 instructions in the form of x-macros.
	//
	//===----------------------------------------------------------------------===//

	#ifndef SUBZERO_SRC_ICEINSTARM32_DEF
	#define SUBZERO_SRC_ICEINSTARM32_DEF

	// NOTE: PC and SP are not considered isInt, to avoid register allocating.
	// For the NaCl sandbox we also need to r9 for TLS, so just reserve always.
	// TODO(jvoung): Allow r9 to be isInt when sandboxing is turned off
	// (native mode).
	#define REGARM32_GPR_TABLE \
	/* val, encode, name, scratch, preserved, stackptr, frameptr, isInt, isFP */ \
	X(Reg_r0, = 0, "r0", 1, 0, 0, 0, 1, 0) \
	X(Reg_r1, = Reg_r0 + 1, "r1", 1, 0, 0, 0, 1, 0) \
	X(Reg_r2, = Reg_r0 + 2, "r2", 1, 0, 0, 0, 1, 0) \
	X(Reg_r3, = Reg_r0 + 3, "r3", 1, 0, 0, 0, 1, 0) \
	X(Reg_r4, = Reg_r0 + 4, "r4", 0, 1, 0, 0, 1, 0) \
	X(Reg_r5, = Reg_r0 + 5, "r5", 0, 1, 0, 0, 1, 0) \
	X(Reg_r6, = Reg_r0 + 6, "r6", 0, 1, 0, 0, 1, 0) \
	X(Reg_r7, = Reg_r0 + 7, "r7", 0, 1, 0, 0, 1, 0) \
	X(Reg_r8, = Reg_r0 + 8, "r8", 0, 1, 0, 0, 1, 0) \
	X(Reg_r9, = Reg_r0 + 9, "r9", 0, 1, 0, 0, 0, 0) \
	X(Reg_r10, = Reg_r0 + 10, "r10", 0, 1, 0, 0, 1, 0) \
	X(Reg_fp, = Reg_r0 + 11, "fp", 0, 1, 0, 1, 1, 0) \
	X(Reg_ip, = Reg_r0 + 12, "ip", 1, 0, 0, 0, 1, 0) \
	X(Reg_sp, = Reg_r0 + 13, "sp", 0, 1, 1, 0, 0, 0) \
	X(Reg_lr, = Reg_r0 + 14, "lr", 0, 1, 0, 0, 1, 0) \
	X(Reg_pc, = Reg_r0 + 15, "pc", 0, 1, 0, 0, 0, 0) \
	//#define X(val, encode, name, scratch, preserved, stackptr, frameptr,
	// isInt, isFP)

	// TODO(jvoung): List FP registers and know S0 == D0 == Q0, etc.
	// Be able to grab even registers, and the corresponding odd register
	// for each even register.

	// We also provide a combined table, so that there is a namespace where
	// all of the registers are considered and have distinct numberings.
	// This is in contrast to the above, where the "encode" is based on how
	// the register numbers will be encoded in binaries and values can overlap.
	#define REGARM32_TABLE \
	/* val, encode, name, scratch, preserved, stackptr, frameptr, isInt, isFP */ \
	REGARM32_GPR_TABLE
	//#define X(val, encode, name, scratch, preserved, stackptr, frameptr,
	// isInt, isFP)

	#define REGARM32_TABLE_BOUNDS \
	/* val, init */ \
	X(Reg_GPR_First, = Reg_r0) \
	X(Reg_GPR_Last, = Reg_pc)
	//define X(val, init)

	// TODO(jvoung): add condition code tables, etc.

	// Load/Store instruction width suffixes.
	#define ICETYPEARM32_TABLE \
	/* tag, element type, width, addr off bits sext, zext */ \
	X(IceType_void, IceType_void, "", 0, 0) \
	X(IceType_i1, IceType_void, "b", 8, 12) \
	X(IceType_i8, IceType_void, "b", 8, 12) \
	X(IceType_i16, IceType_void, "h", 8, 8) \
	X(IceType_i32, IceType_void, "", 12, 12) \
	X(IceType_i64, IceType_void, "d", 8, 8) \
	X(IceType_f32, IceType_void, "", 10, 10) \
	X(IceType_f64, IceType_void, "", 10, 10) \
	X(IceType_v4i1, IceType_i32 , "", 0, 0) \
	X(IceType_v8i1, IceType_i16 , "", 0, 0) \
	X(IceType_v16i1, IceType_i8 , "", 0, 0) \
	X(IceType_v16i8, IceType_i8 , "", 0, 0) \
	X(IceType_v8i16, IceType_i16 , "", 0, 0) \
	X(IceType_v4i32, IceType_i32 , "", 0, 0) \
	X(IceType_v4f32, IceType_f32 , "", 0, 0) \
	//#define X(tag, elementty, width, sbits, ubits)

	// Shifter types for Data-processing operands as defined in section A5.1.2.
	#define ICEINSTARM32SHIFT_TABLE \
	/* enum value, emit */ \
	X(LSL, "lsl") \
	X(LSR, "lsr") \
	X(ASR, "asr") \
	X(ROR, "ror") \
	X(RRX, "rrx") \
	//#define X(tag, emit)

	// Attributes for the condition code 4-bit encoding (that is independent
	// of the APSR's NZCV fields). For example, EQ is 0, but corresponds to
	// Z = 1, and NE is 1, but corresponds to Z = 0.
	#define ICEINSTARM32COND_TABLE \
	/* enum value, encoding, opposite, emit */ \
	X(EQ, 0, NE, "eq") /* equal */ \
	X(NE, 1, EQ, "ne") /* not equal */ \
	X(CS, 2, CC, "cs") /* carry set/unsigned (AKA hs: higher or same) */ \
	X(CC, 3, CS, "cc") /* carry clear/unsigned (AKA lo: lower) */ \
	X(MI, 4, PL, "mi") /* minus/negative */ \
	X(PL, 5, MI, "pl") /* plus/positive or zero */ \
	X(VS, 6, VC, "vs") /* overflow (float unordered) */ \
	X(VC, 7, VS, "vc") /* no overflow (float not unordered) */ \
	X(HI, 8, LS, "hi") /* unsigned higher */ \
	X(LS, 9, HI, "ls") /* unsigned lower or same */ \
	X(GE, 10, LT, "ge") /* signed greater than or equal */ \
	X(LT, 11, GE, "lt") /* signed less than */ \
	X(GT, 12, LE, "gt") /* signed greater than */ \
	X(LE, 13, GT, "le") /* signed less than or equal */ \
	X(AL, 14, kNone, "") /* always (unconditional) */ \
	X(kNone, 15, kNone, "??") /* special condition / none */ \
	//#define(tag, encode, opp, emit)

	#endif // SUBZERO_SRC_ICEINSTARM32_DEF