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bed2308186
NOTE: If this broke your out-of-tree backend, in *RegisterInfo.td, change the instances of SubRegIndex that have a comps template arg to use the ComposedSubRegIndex class instead. In TableGen land, this adds Size and Offset attributes to SubRegIndex, and the ComposedSubRegIndex class, for which the Size and Offset are computed by TableGen. This also adds an accessor in MCRegisterInfo, and Size/Offsets for the X86 and ARM subreg indices. git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@183020 91177308-0d34-0410-b5e6-96231b3b80d8
417 lines
17 KiB
TableGen
417 lines
17 KiB
TableGen
//===-- ARMRegisterInfo.td - ARM Register defs -------------*- 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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// Declarations that describe the ARM register file
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//===----------------------------------------------------------------------===//
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// Registers are identified with 4-bit ID numbers.
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class ARMReg<bits<16> Enc, string n, list<Register> subregs = []> : Register<n> {
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let HWEncoding = Enc;
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let Namespace = "ARM";
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let SubRegs = subregs;
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// All bits of ARM registers with sub-registers are covered by sub-registers.
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let CoveredBySubRegs = 1;
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}
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class ARMFReg<bits<16> Enc, string n> : Register<n> {
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let HWEncoding = Enc;
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let Namespace = "ARM";
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}
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// Subregister indices.
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let Namespace = "ARM" in {
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def qqsub_0 : SubRegIndex<256>;
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def qqsub_1 : SubRegIndex<256, 256>;
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// Note: Code depends on these having consecutive numbers.
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def qsub_0 : SubRegIndex<128>;
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def qsub_1 : SubRegIndex<128, 128>;
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def qsub_2 : ComposedSubRegIndex<qqsub_1, qsub_0>;
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def qsub_3 : ComposedSubRegIndex<qqsub_1, qsub_1>;
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def dsub_0 : SubRegIndex<64>;
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def dsub_1 : SubRegIndex<64, 64>;
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def dsub_2 : ComposedSubRegIndex<qsub_1, dsub_0>;
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def dsub_3 : ComposedSubRegIndex<qsub_1, dsub_1>;
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def dsub_4 : ComposedSubRegIndex<qsub_2, dsub_0>;
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def dsub_5 : ComposedSubRegIndex<qsub_2, dsub_1>;
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def dsub_6 : ComposedSubRegIndex<qsub_3, dsub_0>;
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def dsub_7 : ComposedSubRegIndex<qsub_3, dsub_1>;
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def ssub_0 : SubRegIndex<32>;
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def ssub_1 : SubRegIndex<32, 32>;
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def ssub_2 : ComposedSubRegIndex<dsub_1, ssub_0>;
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def ssub_3 : ComposedSubRegIndex<dsub_1, ssub_1>;
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def gsub_0 : SubRegIndex<32>;
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def gsub_1 : SubRegIndex<32, 32>;
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// Let TableGen synthesize the remaining 12 ssub_* indices.
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// We don't need to name them.
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}
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// Integer registers
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def R0 : ARMReg< 0, "r0">, DwarfRegNum<[0]>;
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def R1 : ARMReg< 1, "r1">, DwarfRegNum<[1]>;
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def R2 : ARMReg< 2, "r2">, DwarfRegNum<[2]>;
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def R3 : ARMReg< 3, "r3">, DwarfRegNum<[3]>;
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def R4 : ARMReg< 4, "r4">, DwarfRegNum<[4]>;
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def R5 : ARMReg< 5, "r5">, DwarfRegNum<[5]>;
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def R6 : ARMReg< 6, "r6">, DwarfRegNum<[6]>;
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def R7 : ARMReg< 7, "r7">, DwarfRegNum<[7]>;
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// These require 32-bit instructions.
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let CostPerUse = 1 in {
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def R8 : ARMReg< 8, "r8">, DwarfRegNum<[8]>;
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def R9 : ARMReg< 9, "r9">, DwarfRegNum<[9]>;
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def R10 : ARMReg<10, "r10">, DwarfRegNum<[10]>;
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def R11 : ARMReg<11, "r11">, DwarfRegNum<[11]>;
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def R12 : ARMReg<12, "r12">, DwarfRegNum<[12]>;
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def SP : ARMReg<13, "sp">, DwarfRegNum<[13]>;
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def LR : ARMReg<14, "lr">, DwarfRegNum<[14]>;
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def PC : ARMReg<15, "pc">, DwarfRegNum<[15]>;
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}
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// Float registers
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def S0 : ARMFReg< 0, "s0">; def S1 : ARMFReg< 1, "s1">;
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def S2 : ARMFReg< 2, "s2">; def S3 : ARMFReg< 3, "s3">;
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def S4 : ARMFReg< 4, "s4">; def S5 : ARMFReg< 5, "s5">;
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def S6 : ARMFReg< 6, "s6">; def S7 : ARMFReg< 7, "s7">;
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def S8 : ARMFReg< 8, "s8">; def S9 : ARMFReg< 9, "s9">;
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def S10 : ARMFReg<10, "s10">; def S11 : ARMFReg<11, "s11">;
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def S12 : ARMFReg<12, "s12">; def S13 : ARMFReg<13, "s13">;
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def S14 : ARMFReg<14, "s14">; def S15 : ARMFReg<15, "s15">;
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def S16 : ARMFReg<16, "s16">; def S17 : ARMFReg<17, "s17">;
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def S18 : ARMFReg<18, "s18">; def S19 : ARMFReg<19, "s19">;
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def S20 : ARMFReg<20, "s20">; def S21 : ARMFReg<21, "s21">;
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def S22 : ARMFReg<22, "s22">; def S23 : ARMFReg<23, "s23">;
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def S24 : ARMFReg<24, "s24">; def S25 : ARMFReg<25, "s25">;
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def S26 : ARMFReg<26, "s26">; def S27 : ARMFReg<27, "s27">;
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def S28 : ARMFReg<28, "s28">; def S29 : ARMFReg<29, "s29">;
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def S30 : ARMFReg<30, "s30">; def S31 : ARMFReg<31, "s31">;
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// Aliases of the F* registers used to hold 64-bit fp values (doubles)
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let SubRegIndices = [ssub_0, ssub_1] in {
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def D0 : ARMReg< 0, "d0", [S0, S1]>, DwarfRegNum<[256]>;
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def D1 : ARMReg< 1, "d1", [S2, S3]>, DwarfRegNum<[257]>;
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def D2 : ARMReg< 2, "d2", [S4, S5]>, DwarfRegNum<[258]>;
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def D3 : ARMReg< 3, "d3", [S6, S7]>, DwarfRegNum<[259]>;
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def D4 : ARMReg< 4, "d4", [S8, S9]>, DwarfRegNum<[260]>;
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def D5 : ARMReg< 5, "d5", [S10, S11]>, DwarfRegNum<[261]>;
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def D6 : ARMReg< 6, "d6", [S12, S13]>, DwarfRegNum<[262]>;
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def D7 : ARMReg< 7, "d7", [S14, S15]>, DwarfRegNum<[263]>;
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def D8 : ARMReg< 8, "d8", [S16, S17]>, DwarfRegNum<[264]>;
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def D9 : ARMReg< 9, "d9", [S18, S19]>, DwarfRegNum<[265]>;
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def D10 : ARMReg<10, "d10", [S20, S21]>, DwarfRegNum<[266]>;
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def D11 : ARMReg<11, "d11", [S22, S23]>, DwarfRegNum<[267]>;
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def D12 : ARMReg<12, "d12", [S24, S25]>, DwarfRegNum<[268]>;
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def D13 : ARMReg<13, "d13", [S26, S27]>, DwarfRegNum<[269]>;
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def D14 : ARMReg<14, "d14", [S28, S29]>, DwarfRegNum<[270]>;
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def D15 : ARMReg<15, "d15", [S30, S31]>, DwarfRegNum<[271]>;
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}
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// VFP3 defines 16 additional double registers
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def D16 : ARMFReg<16, "d16">, DwarfRegNum<[272]>;
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def D17 : ARMFReg<17, "d17">, DwarfRegNum<[273]>;
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def D18 : ARMFReg<18, "d18">, DwarfRegNum<[274]>;
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def D19 : ARMFReg<19, "d19">, DwarfRegNum<[275]>;
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def D20 : ARMFReg<20, "d20">, DwarfRegNum<[276]>;
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def D21 : ARMFReg<21, "d21">, DwarfRegNum<[277]>;
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def D22 : ARMFReg<22, "d22">, DwarfRegNum<[278]>;
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def D23 : ARMFReg<23, "d23">, DwarfRegNum<[279]>;
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def D24 : ARMFReg<24, "d24">, DwarfRegNum<[280]>;
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def D25 : ARMFReg<25, "d25">, DwarfRegNum<[281]>;
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def D26 : ARMFReg<26, "d26">, DwarfRegNum<[282]>;
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def D27 : ARMFReg<27, "d27">, DwarfRegNum<[283]>;
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def D28 : ARMFReg<28, "d28">, DwarfRegNum<[284]>;
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def D29 : ARMFReg<29, "d29">, DwarfRegNum<[285]>;
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def D30 : ARMFReg<30, "d30">, DwarfRegNum<[286]>;
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def D31 : ARMFReg<31, "d31">, DwarfRegNum<[287]>;
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// Advanced SIMD (NEON) defines 16 quad-word aliases
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let SubRegIndices = [dsub_0, dsub_1] in {
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def Q0 : ARMReg< 0, "q0", [D0, D1]>;
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def Q1 : ARMReg< 1, "q1", [D2, D3]>;
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def Q2 : ARMReg< 2, "q2", [D4, D5]>;
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def Q3 : ARMReg< 3, "q3", [D6, D7]>;
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def Q4 : ARMReg< 4, "q4", [D8, D9]>;
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def Q5 : ARMReg< 5, "q5", [D10, D11]>;
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def Q6 : ARMReg< 6, "q6", [D12, D13]>;
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def Q7 : ARMReg< 7, "q7", [D14, D15]>;
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}
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let SubRegIndices = [dsub_0, dsub_1] in {
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def Q8 : ARMReg< 8, "q8", [D16, D17]>;
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def Q9 : ARMReg< 9, "q9", [D18, D19]>;
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def Q10 : ARMReg<10, "q10", [D20, D21]>;
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def Q11 : ARMReg<11, "q11", [D22, D23]>;
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def Q12 : ARMReg<12, "q12", [D24, D25]>;
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def Q13 : ARMReg<13, "q13", [D26, D27]>;
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def Q14 : ARMReg<14, "q14", [D28, D29]>;
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def Q15 : ARMReg<15, "q15", [D30, D31]>;
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}
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// Current Program Status Register.
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// We model fpscr with two registers: FPSCR models the control bits and will be
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// reserved. FPSCR_NZCV models the flag bits and will be unreserved. APSR_NZCV
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// models the APSR when it's accessed by some special instructions. In such cases
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// it has the same encoding as PC.
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def CPSR : ARMReg<0, "cpsr">;
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def APSR : ARMReg<1, "apsr">;
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def APSR_NZCV : ARMReg<15, "apsr_nzcv">;
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def SPSR : ARMReg<2, "spsr">;
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def FPSCR : ARMReg<3, "fpscr">;
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def FPSCR_NZCV : ARMReg<3, "fpscr_nzcv"> {
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let Aliases = [FPSCR];
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}
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def ITSTATE : ARMReg<4, "itstate">;
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// Special Registers - only available in privileged mode.
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def FPSID : ARMReg<0, "fpsid">;
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def MVFR1 : ARMReg<6, "mvfr1">;
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def MVFR0 : ARMReg<7, "mvfr0">;
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def FPEXC : ARMReg<8, "fpexc">;
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// Register classes.
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//
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// pc == Program Counter
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// lr == Link Register
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// sp == Stack Pointer
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// r12 == ip (scratch)
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// r7 == Frame Pointer (thumb-style backtraces)
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// r9 == May be reserved as Thread Register
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// r11 == Frame Pointer (arm-style backtraces)
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// r10 == Stack Limit
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//
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def GPR : RegisterClass<"ARM", [i32], 32, (add (sequence "R%u", 0, 12),
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SP, LR, PC)> {
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// Allocate LR as the first CSR since it is always saved anyway.
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// For Thumb1 mode, we don't want to allocate hi regs at all, as we don't
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// know how to spill them. If we make our prologue/epilogue code smarter at
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// some point, we can go back to using the above allocation orders for the
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// Thumb1 instructions that know how to use hi regs.
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let AltOrders = [(add LR, GPR), (trunc GPR, 8)];
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let AltOrderSelect = [{
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return 1 + MF.getTarget().getSubtarget<ARMSubtarget>().isThumb1Only();
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}];
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}
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// GPRs without the PC. Some ARM instructions do not allow the PC in
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// certain operand slots, particularly as the destination. Primarily
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// useful for disassembly.
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def GPRnopc : RegisterClass<"ARM", [i32], 32, (sub GPR, PC)> {
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let AltOrders = [(add LR, GPRnopc), (trunc GPRnopc, 8)];
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let AltOrderSelect = [{
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return 1 + MF.getTarget().getSubtarget<ARMSubtarget>().isThumb1Only();
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}];
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}
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// GPRs without the PC but with APSR. Some instructions allow accessing the
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// APSR, while actually encoding PC in the register field. This is usefull
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// for assembly and disassembly only.
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def GPRwithAPSR : RegisterClass<"ARM", [i32], 32, (add GPR, APSR_NZCV)> {
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let AltOrders = [(add LR, GPRnopc), (trunc GPRnopc, 8)];
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let AltOrderSelect = [{
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return 1 + MF.getTarget().getSubtarget<ARMSubtarget>().isThumb1Only();
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}];
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}
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// GPRsp - Only the SP is legal. Used by Thumb1 instructions that want the
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// implied SP argument list.
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// FIXME: It would be better to not use this at all and refactor the
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// instructions to not have SP an an explicit argument. That makes
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// frame index resolution a bit trickier, though.
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def GPRsp : RegisterClass<"ARM", [i32], 32, (add SP)>;
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// restricted GPR register class. Many Thumb2 instructions allow the full
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// register range for operands, but have undefined behaviours when PC
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// or SP (R13 or R15) are used. The ARM ISA refers to these operands
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// via the BadReg() pseudo-code description.
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def rGPR : RegisterClass<"ARM", [i32], 32, (sub GPR, SP, PC)> {
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let AltOrders = [(add LR, rGPR), (trunc rGPR, 8)];
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let AltOrderSelect = [{
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return 1 + MF.getTarget().getSubtarget<ARMSubtarget>().isThumb1Only();
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}];
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}
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// Thumb registers are R0-R7 normally. Some instructions can still use
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// the general GPR register class above (MOV, e.g.)
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def tGPR : RegisterClass<"ARM", [i32], 32, (trunc GPR, 8)>;
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// The high registers in thumb mode, R8-R15.
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def hGPR : RegisterClass<"ARM", [i32], 32, (sub GPR, tGPR)>;
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// For tail calls, we can't use callee-saved registers, as they are restored
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// to the saved value before the tail call, which would clobber a call address.
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// Note, getMinimalPhysRegClass(R0) returns tGPR because of the names of
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// this class and the preceding one(!) This is what we want.
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def tcGPR : RegisterClass<"ARM", [i32], 32, (add R0, R1, R2, R3, R9, R12)> {
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let AltOrders = [(and tcGPR, tGPR)];
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let AltOrderSelect = [{
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return MF.getTarget().getSubtarget<ARMSubtarget>().isThumb1Only();
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}];
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}
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// Condition code registers.
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def CCR : RegisterClass<"ARM", [i32], 32, (add CPSR)> {
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let CopyCost = -1; // Don't allow copying of status registers.
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let isAllocatable = 0;
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}
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// Scalar single precision floating point register class..
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// FIXME: Allocation order changed to s0, s2, s4, ... as a quick hack to
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// avoid partial-write dependencies on D registers (S registers are
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// renamed as portions of D registers).
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def SPR : RegisterClass<"ARM", [f32], 32, (add (decimate
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(sequence "S%u", 0, 31), 2),
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(sequence "S%u", 0, 31))>;
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// Subset of SPR which can be used as a source of NEON scalars for 16-bit
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// operations
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def SPR_8 : RegisterClass<"ARM", [f32], 32, (sequence "S%u", 0, 15)>;
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// Scalar double precision floating point / generic 64-bit vector register
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// class.
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// ARM requires only word alignment for double. It's more performant if it
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// is double-word alignment though.
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def DPR : RegisterClass<"ARM", [f64, v8i8, v4i16, v2i32, v1i64, v2f32], 64,
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(sequence "D%u", 0, 31)> {
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// Allocate non-VFP2 registers D16-D31 first.
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let AltOrders = [(rotl DPR, 16)];
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let AltOrderSelect = [{ return 1; }];
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}
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// Subset of DPR that are accessible with VFP2 (and so that also have
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// 32-bit SPR subregs).
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def DPR_VFP2 : RegisterClass<"ARM", [f64, v8i8, v4i16, v2i32, v1i64, v2f32], 64,
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(trunc DPR, 16)>;
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// Subset of DPR which can be used as a source of NEON scalars for 16-bit
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// operations
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def DPR_8 : RegisterClass<"ARM", [f64, v8i8, v4i16, v2i32, v1i64, v2f32], 64,
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(trunc DPR, 8)>;
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// Generic 128-bit vector register class.
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def QPR : RegisterClass<"ARM", [v16i8, v8i16, v4i32, v2i64, v4f32, v2f64], 128,
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(sequence "Q%u", 0, 15)> {
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// Allocate non-VFP2 aliases Q8-Q15 first.
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let AltOrders = [(rotl QPR, 8)];
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let AltOrderSelect = [{ return 1; }];
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}
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// Subset of QPR that have 32-bit SPR subregs.
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def QPR_VFP2 : RegisterClass<"ARM", [v16i8, v8i16, v4i32, v2i64, v4f32, v2f64],
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128, (trunc QPR, 8)>;
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// Subset of QPR that have DPR_8 and SPR_8 subregs.
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def QPR_8 : RegisterClass<"ARM", [v16i8, v8i16, v4i32, v2i64, v4f32, v2f64],
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128, (trunc QPR, 4)>;
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// Pseudo-registers representing odd-even pairs of D registers. The even-odd
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// pairs are already represented by the Q registers.
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// These are needed by NEON instructions requiring two consecutive D registers.
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// There is no D31_D0 register as that is always an UNPREDICTABLE encoding.
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def TuplesOE2D : RegisterTuples<[dsub_0, dsub_1],
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[(decimate (shl DPR, 1), 2),
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(decimate (shl DPR, 2), 2)]>;
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// Register class representing a pair of consecutive D registers.
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// Use the Q registers for the even-odd pairs.
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def DPair : RegisterClass<"ARM", [v16i8, v8i16, v4i32, v2i64, v4f32, v2f64],
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128, (interleave QPR, TuplesOE2D)> {
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// Allocate starting at non-VFP2 registers D16-D31 first.
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// Prefer even-odd pairs as they are easier to copy.
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let AltOrders = [(add (rotl QPR, 8), (rotl DPair, 16))];
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let AltOrderSelect = [{ return 1; }];
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}
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// Pseudo-registers representing even-odd pairs of GPRs from R1 to R13/SP.
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// These are needed by instructions (e.g. ldrexd/strexd) requiring even-odd GPRs.
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def Tuples2R : RegisterTuples<[gsub_0, gsub_1],
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[(add R0, R2, R4, R6, R8, R10, R12),
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(add R1, R3, R5, R7, R9, R11, SP)]>;
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// Register class representing a pair of even-odd GPRs.
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def GPRPair : RegisterClass<"ARM", [untyped], 64, (add Tuples2R)> {
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let Size = 64; // 2 x 32 bits, we have no predefined type of that size.
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}
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// Pseudo-registers representing 3 consecutive D registers.
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def Tuples3D : RegisterTuples<[dsub_0, dsub_1, dsub_2],
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[(shl DPR, 0),
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(shl DPR, 1),
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(shl DPR, 2)]>;
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// 3 consecutive D registers.
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def DTriple : RegisterClass<"ARM", [untyped], 64, (add Tuples3D)> {
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let Size = 192; // 3 x 64 bits, we have no predefined type of that size.
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}
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// Pseudo 256-bit registers to represent pairs of Q registers. These should
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// never be present in the emitted code.
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// These are used for NEON load / store instructions, e.g., vld4, vst3.
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def Tuples2Q : RegisterTuples<[qsub_0, qsub_1], [(shl QPR, 0), (shl QPR, 1)]>;
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// Pseudo 256-bit vector register class to model pairs of Q registers
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// (4 consecutive D registers).
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def QQPR : RegisterClass<"ARM", [v4i64], 256, (add Tuples2Q)> {
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// Allocate non-VFP2 aliases first.
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let AltOrders = [(rotl QQPR, 8)];
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let AltOrderSelect = [{ return 1; }];
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}
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// Tuples of 4 D regs that isn't also a pair of Q regs.
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def TuplesOE4D : RegisterTuples<[dsub_0, dsub_1, dsub_2, dsub_3],
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[(decimate (shl DPR, 1), 2),
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(decimate (shl DPR, 2), 2),
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(decimate (shl DPR, 3), 2),
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(decimate (shl DPR, 4), 2)]>;
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// 4 consecutive D registers.
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def DQuad : RegisterClass<"ARM", [v4i64], 256,
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(interleave Tuples2Q, TuplesOE4D)>;
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// Pseudo 512-bit registers to represent four consecutive Q registers.
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def Tuples2QQ : RegisterTuples<[qqsub_0, qqsub_1],
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[(shl QQPR, 0), (shl QQPR, 2)]>;
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// Pseudo 512-bit vector register class to model 4 consecutive Q registers
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// (8 consecutive D registers).
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def QQQQPR : RegisterClass<"ARM", [v8i64], 256, (add Tuples2QQ)> {
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// Allocate non-VFP2 aliases first.
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let AltOrders = [(rotl QQQQPR, 8)];
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let AltOrderSelect = [{ return 1; }];
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}
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// Pseudo-registers representing 2-spaced consecutive D registers.
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def Tuples2DSpc : RegisterTuples<[dsub_0, dsub_2],
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[(shl DPR, 0),
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(shl DPR, 2)]>;
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// Spaced pairs of D registers.
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def DPairSpc : RegisterClass<"ARM", [v2i64], 64, (add Tuples2DSpc)>;
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def Tuples3DSpc : RegisterTuples<[dsub_0, dsub_2, dsub_4],
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[(shl DPR, 0),
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(shl DPR, 2),
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(shl DPR, 4)]>;
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// Spaced triples of D registers.
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def DTripleSpc : RegisterClass<"ARM", [untyped], 64, (add Tuples3DSpc)> {
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let Size = 192; // 3 x 64 bits, we have no predefined type of that size.
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}
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def Tuples4DSpc : RegisterTuples<[dsub_0, dsub_2, dsub_4, dsub_6],
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[(shl DPR, 0),
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(shl DPR, 2),
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(shl DPR, 4),
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(shl DPR, 6)]>;
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// Spaced quads of D registers.
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def DQuadSpc : RegisterClass<"ARM", [v4i64], 64, (add Tuples3DSpc)>;
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