lib/Target/AArch64/AArch64RegisterInfo.td - llvm - Git at Google

 //===- AArch64RegisterInfo.td - ARM Register defs ----------*- tablegen -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file contains declarations that describe the AArch64 register file
 //
 //===----------------------------------------------------------------------===//

 let Namespace = "AArch64" in {
 def sub_128 : SubRegIndex;
 def sub_64 : SubRegIndex;
 def sub_32 : SubRegIndex;
 def sub_16 : SubRegIndex;
 def sub_8  : SubRegIndex;

 // The VPR registers are handled as sub-registers of FPR equivalents, but
 // they're really the same thing. We give this concept a special index.
 def sub_alias : SubRegIndex;
 }

 // Registers are identified with 5-bit ID numbers.
 class AArch64Reg<bits<16> enc, string n> : Register<n> {
   let HWEncoding = enc;
   let Namespace = "AArch64";
 }

 class AArch64RegWithSubs<bits<16> enc, string n, list<Register> subregs = [],
                          list<SubRegIndex> inds = []>
       : AArch64Reg<enc, n> {
   let SubRegs = subregs;
   let SubRegIndices = inds;
 }

 //===----------------------------------------------------------------------===//
 //  Integer registers: w0-w30, wzr, wsp, x0-x30, xzr, sp
 //===----------------------------------------------------------------------===//

 foreach Index = 0-30 in {
   def W#Index : AArch64Reg< Index, "w"#Index>, DwarfRegNum<[Index]>;
 }

 def WSP : AArch64Reg<31, "wsp">, DwarfRegNum<[31]>;
 def WZR : AArch64Reg<31, "wzr">;

 // Could be combined with previous loop, but this way leaves w and x registers
 // consecutive as LLVM register numbers, which makes for easier debugging.
 foreach Index = 0-30 in {
   def X#Index : AArch64RegWithSubs<Index, "x"#Index,
                                    [!cast<Register>("W"#Index)], [sub_32]>,
                 DwarfRegNum<[Index]>;
 }

 def XSP : AArch64RegWithSubs<31, "sp", [WSP], [sub_32]>, DwarfRegNum<[31]>;
 def XZR : AArch64RegWithSubs<31, "xzr", [WZR], [sub_32]>;

 // Most instructions treat register 31 as zero for reads and a black-hole for
 // writes.

 // Note that the order of registers is important for the Disassembler here:
 // tablegen uses it to form MCRegisterClass::getRegister, which we assume can
 // take an encoding value.
 def GPR32 : RegisterClass<"AArch64", [i32], 32,
                           (add (sequence "W%u", 0, 30), WZR)> {
 }

 def GPR64 : RegisterClass<"AArch64", [i64], 64,
                           (add (sequence "X%u", 0, 30), XZR)> {
 }

 def GPR32nowzr : RegisterClass<"AArch64", [i32], 32,
                                (sequence "W%u", 0, 30)> {
 }

 def GPR64noxzr : RegisterClass<"AArch64", [i64], 64,
                                (sequence "X%u", 0, 30)> {
 }

 // For tail calls, we can't use callee-saved registers or the structure-return
 // register, as they are supposed to be live across function calls and may be
 // clobbered by the epilogue.
 def tcGPR64 : RegisterClass<"AArch64", [i64], 64,
                             (add (sequence "X%u", 0, 7),
                                  (sequence "X%u", 9, 18))> {
 }


 // Certain addressing-useful instructions accept sp directly. Again the order of
 // registers is important to the Disassembler.
 def GPR32wsp : RegisterClass<"AArch64", [i32], 32,
                              (add (sequence "W%u", 0, 30), WSP)> {
 }

 def GPR64xsp : RegisterClass<"AArch64", [i64], 64,
                              (add (sequence "X%u", 0, 30), XSP)> {
 }

 // Some aliases *only* apply to SP (e.g. MOV uses different encoding for SP and
 // non-SP variants). We can't use a bare register in those patterns because
 // TableGen doesn't like it, so we need a class containing just stack registers
 def Rxsp : RegisterClass<"AArch64", [i64], 64,
                          (add XSP)> {
 }

 def Rwsp : RegisterClass<"AArch64", [i32], 32,
                          (add WSP)> {
 }

 //===----------------------------------------------------------------------===//
 //  Scalar registers in the vector unit:
 //  b0-b31, h0-h31, s0-s31, d0-d31, q0-q31
 //===----------------------------------------------------------------------===//

 foreach Index = 0-31 in {
   def B # Index : AArch64Reg< Index, "b" # Index>,
                   DwarfRegNum<[!add(Index, 64)]>;

   def H # Index : AArch64RegWithSubs<Index, "h" # Index,
                                      [!cast<Register>("B" # Index)], [sub_8]>,
                   DwarfRegNum<[!add(Index, 64)]>;

   def S # Index : AArch64RegWithSubs<Index, "s" # Index,
                                      [!cast<Register>("H" # Index)], [sub_16]>,
                   DwarfRegNum<[!add(Index, 64)]>;

   def D # Index : AArch64RegWithSubs<Index, "d" # Index,
                                      [!cast<Register>("S" # Index)], [sub_32]>,
                   DwarfRegNum<[!add(Index, 64)]>;

   def Q # Index : AArch64RegWithSubs<Index, "q" # Index,
                                      [!cast<Register>("D" # Index)], [sub_64]>,
                   DwarfRegNum<[!add(Index, 64)]>;
 }


 def FPR8 : RegisterClass<"AArch64", [i8], 8,
                           (sequence "B%u", 0, 31)> {
 }

 def FPR16 : RegisterClass<"AArch64", [f16], 16,
                           (sequence "H%u", 0, 31)> {
 }

 def FPR32 : RegisterClass<"AArch64", [f32], 32,
                           (sequence "S%u", 0, 31)> {
 }

 def FPR64 : RegisterClass<"AArch64", [f64], 64,
                           (sequence "D%u", 0, 31)> {
 }

 def FPR128 : RegisterClass<"AArch64", [f128], 128,
                           (sequence "Q%u", 0, 31)> {
 }


 //===----------------------------------------------------------------------===//
 //  Vector registers:
 //===----------------------------------------------------------------------===//

 // NEON registers simply specify the overall vector, and it's expected that
 // Instructions will individually specify the acceptable data layout. In
 // principle this leaves two approaches open:
 //   + An operand, giving a single ADDvvv instruction (for example). This turns
 //     out to be unworkable in the assembly parser (without every Instruction
 //     having a "cvt" function, at least) because the constraints can't be
 //     properly enforced. It also complicates specifying patterns since each
 //     instruction will accept many types.
 //  + A bare token (e.g. ".2d"). This means the AsmParser has to know specific
 //    details about NEON registers, but simplifies most other details.
 //
 // The second approach was taken.

 foreach Index = 0-31 in {
   def V # Index  : AArch64RegWithSubs<Index, "v" # Index,
                                       [!cast<Register>("Q" # Index)],
                                       [sub_alias]>,
             DwarfRegNum<[!add(Index, 64)]>;
 }

 // These two classes contain the same registers, which should be reasonably
 // sensible for MC and allocation purposes, but allows them to be treated
 // separately for things like stack spilling.
 def VPR64 : RegisterClass<"AArch64", [v2f32, v2i32, v4i16, v8i8], 64,
                           (sequence "V%u", 0, 31)>;

 def VPR128 : RegisterClass<"AArch64",
                            [v2f64, v2i64, v4f32, v4i32, v8i16, v16i8], 128,
                            (sequence "V%u", 0, 31)>;

 // Flags register
 def NZCV : Register<"nzcv"> {
   let Namespace = "AArch64";
 }

 def FlagClass : RegisterClass<"AArch64", [i32], 32, (add NZCV)> {
   let CopyCost = -1;
   let isAllocatable = 0;
 }
	//===- AArch64RegisterInfo.td - ARM Register defs ----------- tablegen --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains declarations that describe the AArch64 register file
	//
	//===----------------------------------------------------------------------===//

	let Namespace = "AArch64" in {
	def sub_128 : SubRegIndex;
	def sub_64 : SubRegIndex;
	def sub_32 : SubRegIndex;
	def sub_16 : SubRegIndex;
	def sub_8 : SubRegIndex;

	// The VPR registers are handled as sub-registers of FPR equivalents, but
	// they're really the same thing. We give this concept a special index.
	def sub_alias : SubRegIndex;
	}

	// Registers are identified with 5-bit ID numbers.
	class AArch64Reg<bits<16> enc, string n> : Register<n> {
	let HWEncoding = enc;
	let Namespace = "AArch64";
	}

	class AArch64RegWithSubs<bits<16> enc, string n, list<Register> subregs = [],
	list<SubRegIndex> inds = []>
	: AArch64Reg<enc, n> {
	let SubRegs = subregs;
	let SubRegIndices = inds;
	}

	//===----------------------------------------------------------------------===//
	// Integer registers: w0-w30, wzr, wsp, x0-x30, xzr, sp
	//===----------------------------------------------------------------------===//

	foreach Index = 0-30 in {
	def W#Index : AArch64Reg< Index, "w"#Index>, DwarfRegNum<[Index]>;
	}

	def WSP : AArch64Reg<31, "wsp">, DwarfRegNum<[31]>;
	def WZR : AArch64Reg<31, "wzr">;

	// Could be combined with previous loop, but this way leaves w and x registers
	// consecutive as LLVM register numbers, which makes for easier debugging.
	foreach Index = 0-30 in {
	def X#Index : AArch64RegWithSubs<Index, "x"#Index,
	[!cast<Register>("W"#Index)], [sub_32]>,
	DwarfRegNum<[Index]>;
	}

	def XSP : AArch64RegWithSubs<31, "sp", [WSP], [sub_32]>, DwarfRegNum<[31]>;
	def XZR : AArch64RegWithSubs<31, "xzr", [WZR], [sub_32]>;

	// Most instructions treat register 31 as zero for reads and a black-hole for
	// writes.

	// Note that the order of registers is important for the Disassembler here:
	// tablegen uses it to form MCRegisterClass::getRegister, which we assume can
	// take an encoding value.
	def GPR32 : RegisterClass<"AArch64", [i32], 32,
	(add (sequence "W%u", 0, 30), WZR)> {
	}

	def GPR64 : RegisterClass<"AArch64", [i64], 64,
	(add (sequence "X%u", 0, 30), XZR)> {
	}

	def GPR32nowzr : RegisterClass<"AArch64", [i32], 32,
	(sequence "W%u", 0, 30)> {
	}

	def GPR64noxzr : RegisterClass<"AArch64", [i64], 64,
	(sequence "X%u", 0, 30)> {
	}

	// For tail calls, we can't use callee-saved registers or the structure-return
	// register, as they are supposed to be live across function calls and may be
	// clobbered by the epilogue.
	def tcGPR64 : RegisterClass<"AArch64", [i64], 64,
	(add (sequence "X%u", 0, 7),
	(sequence "X%u", 9, 18))> {
	}


	// Certain addressing-useful instructions accept sp directly. Again the order of
	// registers is important to the Disassembler.
	def GPR32wsp : RegisterClass<"AArch64", [i32], 32,
	(add (sequence "W%u", 0, 30), WSP)> {
	}

	def GPR64xsp : RegisterClass<"AArch64", [i64], 64,
	(add (sequence "X%u", 0, 30), XSP)> {
	}

	// Some aliases only apply to SP (e.g. MOV uses different encoding for SP and
	// non-SP variants). We can't use a bare register in those patterns because
	// TableGen doesn't like it, so we need a class containing just stack registers
	def Rxsp : RegisterClass<"AArch64", [i64], 64,
	(add XSP)> {
	}

	def Rwsp : RegisterClass<"AArch64", [i32], 32,
	(add WSP)> {
	}

	//===----------------------------------------------------------------------===//
	// Scalar registers in the vector unit:
	// b0-b31, h0-h31, s0-s31, d0-d31, q0-q31
	//===----------------------------------------------------------------------===//

	foreach Index = 0-31 in {
	def B # Index : AArch64Reg< Index, "b" # Index>,
	DwarfRegNum<[!add(Index, 64)]>;

	def H # Index : AArch64RegWithSubs<Index, "h" # Index,
	[!cast<Register>("B" # Index)], [sub_8]>,
	DwarfRegNum<[!add(Index, 64)]>;

	def S # Index : AArch64RegWithSubs<Index, "s" # Index,
	[!cast<Register>("H" # Index)], [sub_16]>,
	DwarfRegNum<[!add(Index, 64)]>;

	def D # Index : AArch64RegWithSubs<Index, "d" # Index,
	[!cast<Register>("S" # Index)], [sub_32]>,
	DwarfRegNum<[!add(Index, 64)]>;

	def Q # Index : AArch64RegWithSubs<Index, "q" # Index,
	[!cast<Register>("D" # Index)], [sub_64]>,
	DwarfRegNum<[!add(Index, 64)]>;
	}


	def FPR8 : RegisterClass<"AArch64", [i8], 8,
	(sequence "B%u", 0, 31)> {
	}

	def FPR16 : RegisterClass<"AArch64", [f16], 16,
	(sequence "H%u", 0, 31)> {
	}

	def FPR32 : RegisterClass<"AArch64", [f32], 32,
	(sequence "S%u", 0, 31)> {
	}

	def FPR64 : RegisterClass<"AArch64", [f64], 64,
	(sequence "D%u", 0, 31)> {
	}

	def FPR128 : RegisterClass<"AArch64", [f128], 128,
	(sequence "Q%u", 0, 31)> {
	}


	//===----------------------------------------------------------------------===//
	// Vector registers:
	//===----------------------------------------------------------------------===//

	// NEON registers simply specify the overall vector, and it's expected that
	// Instructions will individually specify the acceptable data layout. In
	// principle this leaves two approaches open:
	// + An operand, giving a single ADDvvv instruction (for example). This turns
	// out to be unworkable in the assembly parser (without every Instruction
	// having a "cvt" function, at least) because the constraints can't be
	// properly enforced. It also complicates specifying patterns since each
	// instruction will accept many types.
	// + A bare token (e.g. ".2d"). This means the AsmParser has to know specific
	// details about NEON registers, but simplifies most other details.
	//
	// The second approach was taken.

	foreach Index = 0-31 in {
	def V # Index : AArch64RegWithSubs<Index, "v" # Index,
	[!cast<Register>("Q" # Index)],
	[sub_alias]>,
	DwarfRegNum<[!add(Index, 64)]>;
	}

	// These two classes contain the same registers, which should be reasonably
	// sensible for MC and allocation purposes, but allows them to be treated
	// separately for things like stack spilling.
	def VPR64 : RegisterClass<"AArch64", [v2f32, v2i32, v4i16, v8i8], 64,
	(sequence "V%u", 0, 31)>;

	def VPR128 : RegisterClass<"AArch64",
	[v2f64, v2i64, v4f32, v4i32, v8i16, v16i8], 128,
	(sequence "V%u", 0, 31)>;

	// Flags register
	def NZCV : Register<"nzcv"> {
	let Namespace = "AArch64";
	}

	def FlagClass : RegisterClass<"AArch64", [i32], 32, (add NZCV)> {
	let CopyCost = -1;
	let isAllocatable = 0;
	}