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https://github.com/c64scene-ar/llvm-6502.git
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32e12df253
It seems that the Darwin PPC assembler requires r0 to be written as 0 when it means 0 (at least in lwarx/stwcx.). Fixes PR15605. git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@178142 91177308-0d34-0410-b5e6-96231b3b80d8
233 lines
8.1 KiB
TableGen
233 lines
8.1 KiB
TableGen
//===-- PPCRegisterInfo.td - The PowerPC Register File -----*- tablegen -*-===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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//
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//===----------------------------------------------------------------------===//
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let Namespace = "PPC" in {
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def sub_lt : SubRegIndex;
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def sub_gt : SubRegIndex;
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def sub_eq : SubRegIndex;
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def sub_un : SubRegIndex;
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def sub_32 : SubRegIndex;
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}
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class PPCReg<string n> : Register<n> {
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let Namespace = "PPC";
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}
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// We identify all our registers with a 5-bit ID, for consistency's sake.
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// GPR - One of the 32 32-bit general-purpose registers
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class GPR<bits<5> num, string n> : PPCReg<n> {
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let HWEncoding{4-0} = num;
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}
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// GP8 - One of the 32 64-bit general-purpose registers
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class GP8<GPR SubReg, string n> : PPCReg<n> {
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let HWEncoding = SubReg.HWEncoding;
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let SubRegs = [SubReg];
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let SubRegIndices = [sub_32];
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}
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// SPR - One of the 32-bit special-purpose registers
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class SPR<bits<10> num, string n> : PPCReg<n> {
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let HWEncoding{9-0} = num;
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}
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// FPR - One of the 32 64-bit floating-point registers
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class FPR<bits<5> num, string n> : PPCReg<n> {
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let HWEncoding{4-0} = num;
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}
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// VR - One of the 32 128-bit vector registers
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class VR<bits<5> num, string n> : PPCReg<n> {
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let HWEncoding{4-0} = num;
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}
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// CR - One of the 8 4-bit condition registers
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class CR<bits<3> num, string n, list<Register> subregs> : PPCReg<n> {
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let HWEncoding{2-0} = num;
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let SubRegs = subregs;
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}
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// CRBIT - One of the 32 1-bit condition register fields
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class CRBIT<bits<5> num, string n> : PPCReg<n> {
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let HWEncoding{4-0} = num;
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}
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// General-purpose registers
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foreach Index = 0-31 in {
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def R#Index : GPR<Index, "r"#Index>, DwarfRegNum<[-2, Index]>;
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}
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// 64-bit General-purpose registers
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foreach Index = 0-31 in {
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def X#Index : GP8<!cast<GPR>("R"#Index), "r"#Index>,
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DwarfRegNum<[Index, -2]>;
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}
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// Floating-point registers
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foreach Index = 0-31 in {
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def F#Index : FPR<Index, "f"#Index>,
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DwarfRegNum<[!add(Index, 32), !add(Index, 32)]>;
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}
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// Vector registers
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foreach Index = 0-31 in {
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def V#Index : VR<Index, "v"#Index>,
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DwarfRegNum<[!add(Index, 77), !add(Index, 77)]>;
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}
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// The reprsentation of r0 when treated as the constant 0.
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def ZERO : GPR<0, "0">;
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def ZERO8 : GP8<ZERO, "0">;
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// Representations of the frame pointer used by ISD::FRAMEADDR.
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def FP : GPR<0 /* arbitrary */, "**FRAME POINTER**">;
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def FP8 : GP8<FP, "**FRAME POINTER**">;
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// Condition register bits
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def CR0LT : CRBIT< 0, "0">;
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def CR0GT : CRBIT< 1, "1">;
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def CR0EQ : CRBIT< 2, "2">;
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def CR0UN : CRBIT< 3, "3">;
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def CR1LT : CRBIT< 4, "4">;
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def CR1GT : CRBIT< 5, "5">;
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def CR1EQ : CRBIT< 6, "6">;
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def CR1UN : CRBIT< 7, "7">;
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def CR2LT : CRBIT< 8, "8">;
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def CR2GT : CRBIT< 9, "9">;
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def CR2EQ : CRBIT<10, "10">;
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def CR2UN : CRBIT<11, "11">;
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def CR3LT : CRBIT<12, "12">;
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def CR3GT : CRBIT<13, "13">;
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def CR3EQ : CRBIT<14, "14">;
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def CR3UN : CRBIT<15, "15">;
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def CR4LT : CRBIT<16, "16">;
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def CR4GT : CRBIT<17, "17">;
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def CR4EQ : CRBIT<18, "18">;
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def CR4UN : CRBIT<19, "19">;
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def CR5LT : CRBIT<20, "20">;
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def CR5GT : CRBIT<21, "21">;
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def CR5EQ : CRBIT<22, "22">;
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def CR5UN : CRBIT<23, "23">;
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def CR6LT : CRBIT<24, "24">;
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def CR6GT : CRBIT<25, "25">;
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def CR6EQ : CRBIT<26, "26">;
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def CR6UN : CRBIT<27, "27">;
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def CR7LT : CRBIT<28, "28">;
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def CR7GT : CRBIT<29, "29">;
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def CR7EQ : CRBIT<30, "30">;
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def CR7UN : CRBIT<31, "31">;
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// Condition registers
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let SubRegIndices = [sub_lt, sub_gt, sub_eq, sub_un] in {
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def CR0 : CR<0, "cr0", [CR0LT, CR0GT, CR0EQ, CR0UN]>, DwarfRegNum<[68, 68]>;
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def CR1 : CR<1, "cr1", [CR1LT, CR1GT, CR1EQ, CR1UN]>, DwarfRegNum<[69, 69]>;
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def CR2 : CR<2, "cr2", [CR2LT, CR2GT, CR2EQ, CR2UN]>, DwarfRegNum<[70, 70]>;
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def CR3 : CR<3, "cr3", [CR3LT, CR3GT, CR3EQ, CR3UN]>, DwarfRegNum<[71, 71]>;
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def CR4 : CR<4, "cr4", [CR4LT, CR4GT, CR4EQ, CR4UN]>, DwarfRegNum<[72, 72]>;
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def CR5 : CR<5, "cr5", [CR5LT, CR5GT, CR5EQ, CR5UN]>, DwarfRegNum<[73, 73]>;
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def CR6 : CR<6, "cr6", [CR6LT, CR6GT, CR6EQ, CR6UN]>, DwarfRegNum<[74, 74]>;
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def CR7 : CR<7, "cr7", [CR7LT, CR7GT, CR7EQ, CR7UN]>, DwarfRegNum<[75, 75]>;
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}
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// Link register
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def LR : SPR<8, "lr">, DwarfRegNum<[-2, 65]>;
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//let Aliases = [LR] in
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def LR8 : SPR<8, "lr">, DwarfRegNum<[65, -2]>;
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// Count register
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def CTR : SPR<9, "ctr">, DwarfRegNum<[-2, 66]>;
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def CTR8 : SPR<9, "ctr">, DwarfRegNum<[66, -2]>;
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// VRsave register
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def VRSAVE: SPR<256, "VRsave">, DwarfRegNum<[109]>;
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// Carry bit. In the architecture this is really bit 0 of the XER register
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// (which really is SPR register 1); this is the only bit interesting to a
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// compiler.
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def CARRY: SPR<1, "ca">;
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// FP rounding mode: bits 30 and 31 of the FP status and control register
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// This is not allocated as a normal register; it appears only in
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// Uses and Defs. The ABI says it needs to be preserved by a function,
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// but this is not achieved by saving and restoring it as with
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// most registers, it has to be done in code; to make this work all the
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// return and call instructions are described as Uses of RM, so instructions
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// that do nothing but change RM will not get deleted.
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// Also, in the architecture it is not really a SPR; 512 is arbitrary.
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def RM: SPR<512, "**ROUNDING MODE**">;
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/// Register classes
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// Allocate volatiles first
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// then nonvolatiles in reverse order since stmw/lmw save from rN to r31
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def GPRC : RegisterClass<"PPC", [i32], 32, (add (sequence "R%u", 2, 12),
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(sequence "R%u", 30, 13),
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R31, R0, R1, FP)>;
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def G8RC : RegisterClass<"PPC", [i64], 64, (add (sequence "X%u", 2, 12),
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(sequence "X%u", 30, 14),
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X31, X13, X0, X1, FP8)>;
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// For some instructions r0 is special (representing the value 0 instead of
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// the value in the r0 register), and we use these register subclasses to
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// prevent r0 from being allocated for use by those instructions.
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def GPRC_NOR0 : RegisterClass<"PPC", [i32], 32, (add (sub GPRC, R0), ZERO)>;
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def G8RC_NOX0 : RegisterClass<"PPC", [i64], 64, (add (sub G8RC, X0), ZERO8)>;
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// Allocate volatiles first, then non-volatiles in reverse order. With the SVR4
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// ABI the size of the Floating-point register save area is determined by the
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// allocated non-volatile register with the lowest register number, as FP
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// register N is spilled to offset 8 * (32 - N) below the back chain word of the
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// previous stack frame. By allocating non-volatiles in reverse order we make
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// sure that the Floating-point register save area is always as small as
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// possible because there aren't any unused spill slots.
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def F8RC : RegisterClass<"PPC", [f64], 64, (add (sequence "F%u", 0, 13),
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(sequence "F%u", 31, 14))>;
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def F4RC : RegisterClass<"PPC", [f32], 32, (add F8RC)>;
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def VRRC : RegisterClass<"PPC", [v16i8,v8i16,v4i32,v4f32], 128,
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(add V2, V3, V4, V5, V0, V1, V6, V7, V8, V9, V10, V11,
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V12, V13, V14, V15, V16, V17, V18, V19, V31, V30,
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V29, V28, V27, V26, V25, V24, V23, V22, V21, V20)>;
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def CRBITRC : RegisterClass<"PPC", [i32], 32,
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(add CR0LT, CR0GT, CR0EQ, CR0UN,
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CR1LT, CR1GT, CR1EQ, CR1UN,
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CR2LT, CR2GT, CR2EQ, CR2UN,
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CR3LT, CR3GT, CR3EQ, CR3UN,
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CR4LT, CR4GT, CR4EQ, CR4UN,
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CR5LT, CR5GT, CR5EQ, CR5UN,
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CR6LT, CR6GT, CR6EQ, CR6UN,
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CR7LT, CR7GT, CR7EQ, CR7UN)>
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{
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let CopyCost = -1;
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}
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def CRRC : RegisterClass<"PPC", [i32], 32, (add CR0, CR1, CR5, CR6,
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CR7, CR2, CR3, CR4)>;
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// The CTR registers are not allocatable because they're used by the
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// decrement-and-branch instructions, and thus need to stay live across
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// multiple basic blocks.
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def CTRRC : RegisterClass<"PPC", [i32], 32, (add CTR)> {
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let isAllocatable = 0;
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}
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def CTRRC8 : RegisterClass<"PPC", [i64], 64, (add CTR8)> {
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let isAllocatable = 0;
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}
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def VRSAVERC : RegisterClass<"PPC", [i32], 32, (add VRSAVE)>;
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def CARRYRC : RegisterClass<"PPC", [i32], 32, (add CARRY)> {
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let CopyCost = -1;
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}
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