//===-- AVRInstrInfo.td - AVR Instruction defs -------------*- tablegen -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file describes the AVR instructions in TableGen format. // //===----------------------------------------------------------------------===// include "AVRInstrFormats.td" //===----------------------------------------------------------------------===// // AVR Type Profiles //===----------------------------------------------------------------------===// def SDT_AVRCallSeqStart : SDCallSeqStart<[SDTCisVT<0, i16>, SDTCisVT<1, i16>]>; def SDT_AVRCallSeqEnd : SDCallSeqEnd<[SDTCisVT<0, i16>, SDTCisVT<1, i16>]>; def SDT_AVRCall : SDTypeProfile<0, -1, [SDTCisVT<0, iPTR>]>; def SDT_AVRWrapper : SDTypeProfile<1, 1, [SDTCisSameAs<0, 1>, SDTCisPtrTy<0>]>; def SDT_AVRBrcond : SDTypeProfile<0, 2, [SDTCisVT<0, OtherVT>, SDTCisVT<1, i8>]>; def SDT_AVRCmp : SDTypeProfile<0, 2, [SDTCisSameAs<0, 1>]>; def SDT_AVRTst : SDTypeProfile<0, 1, [SDTCisInt<0>]>; def SDT_AVRSelectCC : SDTypeProfile<1, 3, [SDTCisSameAs<0, 1>, SDTCisSameAs<1, 2>, SDTCisVT<3, i8>]>; //===----------------------------------------------------------------------===// // AVR Specific Node Definitions //===----------------------------------------------------------------------===// def AVRretglue : SDNode<"AVRISD::RET_GLUE", SDTNone, [SDNPHasChain, SDNPOptInGlue, SDNPVariadic]>; def AVRretiglue : SDNode<"AVRISD::RETI_GLUE", SDTNone, [SDNPHasChain, SDNPOptInGlue, SDNPVariadic]>; def AVRcallseq_start : SDNode<"ISD::CALLSEQ_START", SDT_AVRCallSeqStart, [SDNPHasChain, SDNPOutGlue]>; def AVRcallseq_end : SDNode<"ISD::CALLSEQ_END", SDT_AVRCallSeqEnd, [SDNPHasChain, SDNPOptInGlue, SDNPOutGlue]>; def AVRcall : SDNode<"AVRISD::CALL", SDT_AVRCall, [SDNPHasChain, SDNPOutGlue, SDNPOptInGlue, SDNPVariadic]>; def AVRWrapper : SDNode<"AVRISD::WRAPPER", SDT_AVRWrapper>; def AVRbrcond : SDNode<"AVRISD::BRCOND", SDT_AVRBrcond, [SDNPHasChain, SDNPInGlue]>; def AVRcmp : SDNode<"AVRISD::CMP", SDT_AVRCmp, [SDNPOutGlue]>; def AVRcmpc : SDNode<"AVRISD::CMPC", SDT_AVRCmp, [SDNPInGlue, SDNPOutGlue]>; def AVRtst : SDNode<"AVRISD::TST", SDT_AVRTst, [SDNPOutGlue]>; def AVRselectcc : SDNode<"AVRISD::SELECT_CC", SDT_AVRSelectCC, [SDNPInGlue]>; // Shift nodes. def AVRlsl : SDNode<"AVRISD::LSL", SDTIntUnaryOp>; def AVRlsr : SDNode<"AVRISD::LSR", SDTIntUnaryOp>; def AVRrol : SDNode<"AVRISD::ROL", SDTIntUnaryOp>; def AVRror : SDNode<"AVRISD::ROR", SDTIntUnaryOp>; def AVRasr : SDNode<"AVRISD::ASR", SDTIntUnaryOp>; def AVRlslhi : SDNode<"AVRISD::LSLHI", SDTIntUnaryOp>; def AVRlsrlo : SDNode<"AVRISD::LSRLO", SDTIntUnaryOp>; def AVRasrlo : SDNode<"AVRISD::ASRLO", SDTIntUnaryOp>; def AVRlslbn : SDNode<"AVRISD::LSLBN", SDTIntBinOp>; def AVRlsrbn : SDNode<"AVRISD::LSRBN", SDTIntBinOp>; def AVRasrbn : SDNode<"AVRISD::ASRBN", SDTIntBinOp>; def AVRlslwn : SDNode<"AVRISD::LSLWN", SDTIntBinOp>; def AVRlsrwn : SDNode<"AVRISD::LSRWN", SDTIntBinOp>; def AVRasrwn : SDNode<"AVRISD::ASRWN", SDTIntBinOp>; def AVRlslw : SDNode<"AVRISD::LSLW", SDTIntShiftDOp>; def AVRlsrw : SDNode<"AVRISD::LSRW", SDTIntShiftDOp>; def AVRasrw : SDNode<"AVRISD::ASRW", SDTIntShiftDOp>; // Pseudo shift nodes for non-constant shift amounts. def AVRlslLoop : SDNode<"AVRISD::LSLLOOP", SDTIntShiftOp>; def AVRlsrLoop : SDNode<"AVRISD::LSRLOOP", SDTIntShiftOp>; def AVRrolLoop : SDNode<"AVRISD::ROLLOOP", SDTIntShiftOp>; def AVRrorLoop : SDNode<"AVRISD::RORLOOP", SDTIntShiftOp>; def AVRasrLoop : SDNode<"AVRISD::ASRLOOP", SDTIntShiftOp>; // SWAP node. def AVRSwap : SDNode<"AVRISD::SWAP", SDTIntUnaryOp>; //===----------------------------------------------------------------------===// // AVR Operands, Complex Patterns and Transformations Definitions. //===----------------------------------------------------------------------===// def imm8_neg_XFORM : SDNodeXFormgetTargetConstant(-N->getAPIntValue(), SDLoc(N), MVT::i8); }]>; def imm16_neg_XFORM : SDNodeXFormgetTargetConstant(-N->getAPIntValue(), SDLoc(N), MVT::i16); }]>; def imm0_63_neg : PatLeaf<(imm), [{ int64_t val = -N->getSExtValue(); return val >= 0 && val < 64; }], imm16_neg_XFORM>; def uimm6 : PatLeaf<(imm), [{ return isUInt<6>(N->getZExtValue()); }]>; // imm_com8_XFORM - Return the complement of a imm_com8 value def imm_com8_XFORM : SDNodeXFormgetTargetConstant( ~((uint8_t) N->getZExtValue()), SDLoc(N), MVT::i8); }]>; // imm_com8 - Match an immediate that is a complement // of a 8-bit immediate. // Note: this pattern doesn't require an encoder method and such, as it's // only used on aliases (Pat<> and InstAlias<>). The actual encoding // is handled by the destination instructions, which use imm_com8. def imm_com8_asmoperand : AsmOperandClass { let Name = "ImmCom8"; } def imm_com8 : Operand { let ParserMatchClass = imm_com8_asmoperand; } def ioaddr_XFORM : SDNodeXFormgetIORegisterOffset(); return CurDAG->getTargetConstant( uint8_t(N->getZExtValue()) - offset, SDLoc(N), MVT::i8); }]>; def iobitpos8_XFORM : SDNodeXFormgetTargetConstant( Log2_32(uint8_t(N->getZExtValue())), SDLoc(N), MVT::i8); }]>; def iobitposn8_XFORM : SDNodeXFormgetTargetConstant( Log2_32(uint8_t(~N->getZExtValue())), SDLoc(N), MVT::i8); }]>; def ioaddr8 : PatLeaf<(imm), [{ uint8_t offset = Subtarget->getIORegisterOffset(); uint64_t val = N->getZExtValue() - offset; return val < 0x40; }], ioaddr_XFORM>; def lowioaddr8 : PatLeaf<(imm), [{ uint8_t offset = Subtarget->getIORegisterOffset(); uint64_t val = N->getZExtValue() - offset; return val < 0x20; }], ioaddr_XFORM>; def ioaddr16 : PatLeaf<(imm), [{ uint8_t offset = Subtarget->getIORegisterOffset(); uint64_t val = N->getZExtValue() - offset; return val < 0x3f; }], ioaddr_XFORM>; def iobitpos8 : PatLeaf<(imm), [{ return isPowerOf2_32(uint8_t(N->getZExtValue())); }], iobitpos8_XFORM>; def iobitposn8 : PatLeaf<(imm), [{ return isPowerOf2_32(uint8_t(~N->getZExtValue())); }], iobitposn8_XFORM>; def MemriAsmOperand : AsmOperandClass { let Name = "Memri"; let ParserMethod = "parseMemriOperand"; } /// Address operand for `reg+imm` used by STD and LDD. def memri : Operand { let MIOperandInfo = (ops PTRDISPREGS, i16imm); let PrintMethod = "printMemri"; let EncoderMethod = "encodeMemri"; let DecoderMethod = "decodeMemri"; let ParserMatchClass = MemriAsmOperand; } // Address operand for `SP+imm` used by STD{W}SPQRr def memspi : Operand { let MIOperandInfo = (ops GPRSP, i16imm); let PrintMethod = "printMemspi"; } def relbrtarget_7 : Operand { let PrintMethod = "printPCRelImm"; let EncoderMethod = "encodeRelCondBrTarget"; } def brtarget_13 : Operand { let PrintMethod = "printPCRelImm"; let EncoderMethod = "encodeRelCondBrTarget"; } def rcalltarget_13 : Operand { let PrintMethod = "printPCRelImm"; let EncoderMethod = "encodeRelCondBrTarget"; } // The target of a 22 or 16-bit call/jmp instruction. def call_target : Operand { let EncoderMethod = "encodeCallTarget"; let DecoderMethod = "decodeCallTarget"; } // A 16-bit address (which can lead to an R_AVR_16 relocation). def imm16 : Operand { let EncoderMethod = "encodeImm"; } // A 7-bit address (which can lead to an R_AVR_LDS_STS_16 relocation). def imm7tiny : Operand { let EncoderMethod = "encodeImm"; } /// A 6-bit immediate used in the ADIW/SBIW instructions. def imm_arith6 : Operand { let EncoderMethod = "encodeImm"; } /// An 8-bit immediate inside an instruction with the same format /// as the `LDI` instruction (the `FRdK` format). def imm_ldi8 : Operand { let EncoderMethod = "encodeImm"; } /// A 5-bit port number used in SBIC and friends (the `FIOBIT` format). def imm_port5 : Operand { let EncoderMethod = "encodeImm"; } /// A 6-bit port number used in the `IN` instruction and friends (the /// `FIORdA` format. def imm_port6 : Operand { let EncoderMethod = "encodeImm"; } // Addressing mode pattern reg+imm6 def addr : ComplexPattern; // AsmOperand class for a pointer register. // Used with the LD/ST family of instructions. // See FSTLD in AVRInstrFormats.td def PtrRegAsmOperand : AsmOperandClass { let Name = "Reg"; } // A special operand type for the LD/ST instructions. // It converts the pointer register number into a two-bit field used in the // instruction. def LDSTPtrReg : Operand { let MIOperandInfo = (ops PTRREGS); let EncoderMethod = "encodeLDSTPtrReg"; let ParserMatchClass = PtrRegAsmOperand; } // A special operand type for the LDD/STD instructions. // It behaves identically to the LD/ST version, except restricts // the pointer registers to Y and Z. def LDDSTDPtrReg : Operand { let MIOperandInfo = (ops PTRDISPREGS); let EncoderMethod = "encodeLDSTPtrReg"; let ParserMatchClass = PtrRegAsmOperand; } //===----------------------------------------------------------------------===// // AVR predicates for subtarget features //===----------------------------------------------------------------------===// def HasSRAM : Predicate<"Subtarget->hasSRAM()">, AssemblerPredicate<(all_of FeatureSRAM)>; def HasJMPCALL : Predicate<"Subtarget->hasJMPCALL()">, AssemblerPredicate<(all_of FeatureJMPCALL)>; def HasIJMPCALL : Predicate<"Subtarget->hasIJMPCALL()">, AssemblerPredicate<(all_of FeatureIJMPCALL)>; def HasEIJMPCALL : Predicate<"Subtarget->hasEIJMPCALL()">, AssemblerPredicate<(all_of FeatureEIJMPCALL)>; def HasADDSUBIW : Predicate<"Subtarget->hasADDSUBIW()">, AssemblerPredicate<(all_of FeatureADDSUBIW)>; def HasSmallStack : Predicate<"Subtarget->HasSmallStack()">, AssemblerPredicate<(all_of FeatureSmallStack)>; def HasMOVW : Predicate<"Subtarget->hasMOVW()">, AssemblerPredicate<(all_of FeatureMOVW)>; def HasLPM : Predicate<"Subtarget->hasLPM()">, AssemblerPredicate<(all_of FeatureLPM)>; def HasLPMX : Predicate<"Subtarget->hasLPMX()">, AssemblerPredicate<(all_of FeatureLPMX)>; def HasELPM : Predicate<"Subtarget->hasELPM()">, AssemblerPredicate<(all_of FeatureELPM)>; def HasELPMX : Predicate<"Subtarget->hasELPMX()">, AssemblerPredicate<(all_of FeatureELPMX)>; def HasSPM : Predicate<"Subtarget->hasSPM()">, AssemblerPredicate<(all_of FeatureSPM)>; def HasSPMX : Predicate<"Subtarget->hasSPMX()">, AssemblerPredicate<(all_of FeatureSPMX)>; def HasDES : Predicate<"Subtarget->hasDES()">, AssemblerPredicate<(all_of FeatureDES)>; def SupportsRMW : Predicate<"Subtarget->supportsRMW()">, AssemblerPredicate<(all_of FeatureRMW)>; def SupportsMultiplication : Predicate<"Subtarget->supportsMultiplication()">, AssemblerPredicate<(all_of FeatureMultiplication)>; def HasBREAK : Predicate<"Subtarget->hasBREAK()">, AssemblerPredicate<(all_of FeatureBREAK)>; def HasTinyEncoding : Predicate<"Subtarget->hasTinyEncoding()">, AssemblerPredicate<(all_of FeatureTinyEncoding)>; def HasNonTinyEncoding : Predicate<"!Subtarget->hasTinyEncoding()">, AssemblerPredicate<(any_of (not FeatureTinyEncoding))>; // AVR specific condition code. These correspond to AVR_*_COND in // AVRInstrInfo.td. They must be kept in synch. def AVR_COND_EQ : PatLeaf<(i8 0)>; def AVR_COND_NE : PatLeaf<(i8 1)>; def AVR_COND_GE : PatLeaf<(i8 2)>; def AVR_COND_LT : PatLeaf<(i8 3)>; def AVR_COND_SH : PatLeaf<(i8 4)>; def AVR_COND_LO : PatLeaf<(i8 5)>; def AVR_COND_MI : PatLeaf<(i8 6)>; def AVR_COND_PL : PatLeaf<(i8 7)>; //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // AVR Instruction list //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // ADJCALLSTACKDOWN/UP implicitly use/def SP because they may be expanded into // a stack adjustment and the codegen must know that they may modify the stack // pointer before prolog-epilog rewriting occurs. // Pessimistically assume ADJCALLSTACKDOWN / ADJCALLSTACKUP will become // sub / add which can clobber SREG. let Defs = [SP, SREG], Uses = [SP] in { def ADJCALLSTACKDOWN : Pseudo<(outs), (ins i16imm:$amt, i16imm:$amt2), "#ADJCALLSTACKDOWN", [(AVRcallseq_start timm:$amt, timm:$amt2)]>; // R31R30 is used to update SP. It is normally free because it is a // call-clobbered register but it is necessary to set it as a def as the // register allocator might use it in rare cases (for rematerialization, it // seems). hasSideEffects needs to be set to true so this instruction isn't // considered dead. let Defs = [R31R30], hasSideEffects = 1 in def ADJCALLSTACKUP : Pseudo<(outs), (ins i16imm:$amt1, i16imm:$amt2), "#ADJCALLSTACKUP", [(AVRcallseq_end timm:$amt1, timm:$amt2)]>; } //===----------------------------------------------------------------------===// // Addition //===----------------------------------------------------------------------===// let isCommutable = 1, Constraints = "$src = $rd", Defs = [SREG] in { // ADD Rd, Rr // Adds two 8-bit registers. def ADDRdRr : FRdRr<0b0000, 0b11, (outs GPR8:$rd),(ins GPR8:$src, GPR8:$rr), "add\t$rd, $rr", [(set i8:$rd, (add i8:$src, i8:$rr)), (implicit SREG)]>; // ADDW Rd+1:Rd, Rr+1:Rr // Pseudo instruction to add four 8-bit registers as two 16-bit values. // // Expands to: // add Rd, Rr // adc Rd+1, Rr+1 def ADDWRdRr : Pseudo<(outs DREGS:$rd), (ins DREGS:$src, DREGS:$rr), "addw\t$rd, $rr", [(set i16:$rd, (add i16:$src, i16:$rr)), (implicit SREG)]>; // ADC Rd, Rr // Adds two 8-bit registers with carry. let Uses = [SREG] in def ADCRdRr : FRdRr<0b0001, 0b11, (outs GPR8:$rd), (ins GPR8:$src, GPR8:$rr), "adc\t$rd, $rr", [(set i8:$rd, (adde i8:$src, i8:$rr)), (implicit SREG)]>; // ADCW Rd+1:Rd, Rr+1:Rr // Pseudo instruction to add four 8-bit registers as two 16-bit values with // carry. // // Expands to: // adc Rd, Rr // adc Rd+1, Rr+1 let Uses = [SREG] in def ADCWRdRr : Pseudo<(outs DREGS:$rd), (ins DREGS:$src, DREGS:$rr), "adcw\t$rd, $rr", [(set i16:$rd, (adde i16:$src, i16:$rr)), (implicit SREG)]>; // AIDW Rd, k // Adds an immediate 6-bit value K to Rd, placing the result in Rd. def ADIWRdK : FWRdK<0b0, (outs IWREGS:$rd), (ins IWREGS :$src, imm_arith6:$k), "adiw\t$rd, $k", [(set i16:$rd, (add i16:$src, uimm6:$k)), (implicit SREG)]>, Requires<[HasADDSUBIW]>; } //===----------------------------------------------------------------------===// // Subtraction //===----------------------------------------------------------------------===// let Constraints = "$rs = $rd", Defs = [SREG] in { // SUB Rd, Rr // Subtracts the 8-bit value of Rr from Rd and places the value in Rd. def SUBRdRr : FRdRr<0b0001, 0b10, (outs GPR8:$rd), (ins GPR8:$rs, GPR8:$rr), "sub\t$rd, $rr", [(set i8:$rd, (sub i8:$rs, i8:$rr)), (implicit SREG)]>; // SUBW Rd+1:Rd, Rr+1:Rr // Subtracts two 16-bit values and places the result into Rd. // // Expands to: // sub Rd, Rr // sbc Rd+1, Rr+1 def SUBWRdRr : Pseudo<(outs DREGS:$rd), (ins DREGS:$rs, DREGS:$rr), "subw\t$rd, $rr", [(set i16:$rd, (sub i16:$rs, i16:$rr)), (implicit SREG)]>; def SUBIRdK : FRdK<0b0101, (outs LD8:$rd), (ins LD8:$rs, imm_ldi8:$k), "subi\t$rd, $k", [(set i8:$rd, (sub i8:$rs, imm:$k)), (implicit SREG)]>; // SUBIW Rd+1:Rd, K+1:K // // Expands to: // subi Rd, K // sbci Rd+1, K+1 def SUBIWRdK : Pseudo<(outs DLDREGS:$rd), (ins DLDREGS:$rs, i16imm:$rr), "subiw\t$rd, $rr", [(set i16:$rd, (sub i16:$rs, imm:$rr)), (implicit SREG)]>; def SBIWRdK : FWRdK<0b1, (outs IWREGS:$rd), (ins IWREGS:$rs, imm_arith6:$k), "sbiw\t$rd, $k", [(set i16:$rd, (sub i16:$rs, uimm6:$k)), (implicit SREG)]>, Requires<[HasADDSUBIW]>; // Subtract with carry operations which must read the carry flag in SREG. let Uses = [SREG] in { def SBCRdRr : FRdRr<0b0000, 0b10, (outs GPR8:$rd), (ins GPR8:$rs, GPR8:$rr), "sbc\t$rd, $rr", [(set i8:$rd, (sube i8:$rs, i8:$rr)), (implicit SREG)]>; // SBCW Rd+1:Rd, Rr+1:Rr // // Expands to: // sbc Rd, Rr // sbc Rd+1, Rr+1 def SBCWRdRr : Pseudo<(outs DREGS:$rd), (ins DREGS:$rs, DREGS:$rr), "sbcw\t$rd, $rr", [(set i16:$rd, (sube i16:$rs, i16:$rr)), (implicit SREG)]>; def SBCIRdK : FRdK<0b0100, (outs LD8:$rd), (ins LD8:$rs, imm_ldi8:$k), "sbci\t$rd, $k", [(set i8:$rd, (sube i8:$rs, imm:$k)), (implicit SREG)]>; // SBCIW Rd+1:Rd, K+1:K // sbci Rd, K // sbci Rd+1, K+1 def SBCIWRdK : Pseudo<(outs DLDREGS:$rd), (ins DLDREGS:$rs, i16imm:$rr), "sbciw\t$rd, $rr", [(set i16:$rd, (sube i16:$rs, imm:$rr)), (implicit SREG)]>; } } //===----------------------------------------------------------------------===// // Increment and Decrement //===----------------------------------------------------------------------===// let Constraints = "$src = $rd", Defs = [SREG] in { def INCRd : FRd<0b1001, 0b0100011, (outs GPR8:$rd), (ins GPR8:$src), "inc\t$rd", [(set i8:$rd, (add i8:$src, 1)), (implicit SREG)]>; def DECRd : FRd<0b1001, 0b0101010, (outs GPR8:$rd), (ins GPR8:$src), "dec\t$rd", [(set i8:$rd, (add i8:$src, -1)), (implicit SREG)]>; } //===----------------------------------------------------------------------===// // Multiplication //===----------------------------------------------------------------------===// let isCommutable = 1, Defs = [R1, R0, SREG] in { // MUL Rd, Rr // Multiplies Rd by Rr and places the result into R1:R0. let usesCustomInserter = 1 in { def MULRdRr : FRdRr<0b1001, 0b11, (outs), (ins GPR8:$rd, GPR8:$rr), "mul\t$rd, $rr", []>, Requires<[SupportsMultiplication]>; def MULSRdRr : FMUL2RdRr<0, (outs), (ins LD8:$rd, LD8:$rr), "muls\t$rd, $rr", []>, Requires<[SupportsMultiplication]>; } def MULSURdRr : FMUL2RdRr<1, (outs), (ins LD8lo:$rd, LD8lo:$rr), "mulsu\t$rd, $rr", []>, Requires<[SupportsMultiplication]>; def FMUL : FFMULRdRr<0b01, (outs), (ins LD8lo:$rd, LD8lo:$rr), "fmul\t$rd, $rr", []>, Requires<[SupportsMultiplication]>; def FMULS : FFMULRdRr<0b10, (outs), (ins LD8lo:$rd, LD8lo:$rr), "fmuls\t$rd, $rr", []>, Requires<[SupportsMultiplication]>; def FMULSU : FFMULRdRr<0b11, (outs), (ins LD8lo:$rd, LD8lo:$rr), "fmulsu\t$rd, $rr", []>, Requires<[SupportsMultiplication]>; } let Defs = [R15, R14, R13, R12, R11, R10, R9, R8, R7, R6, R5, R4, R3, R2, R1, R0] in def DESK : FDES<(outs), (ins i8imm:$k), "des\t$k", []>, Requires<[HasDES]>; //===----------------------------------------------------------------------===// // Logic //===----------------------------------------------------------------------===// let Constraints = "$src = $rd", Defs = [SREG] in { // Register-Register logic instructions (which have the // property of commutativity). let isCommutable = 1 in { def ANDRdRr : FRdRr<0b0010, 0b00, (outs GPR8 : $rd), (ins GPR8 : $src, GPR8 : $rr), "and\t$rd, $rr", [(set i8 : $rd, (and i8 : $src, i8 : $rr)), (implicit SREG)]>; // ANDW Rd+1:Rd, Rr+1:Rr // // Expands to: // and Rd, Rr // and Rd+1, Rr+1 def ANDWRdRr : Pseudo<(outs DREGS : $rd), (ins DREGS : $src, DREGS : $rr), "andw\t$rd, $rr", [ (set i16 : $rd, (and i16 : $src, i16 : $rr)), (implicit SREG) ]>; def ORRdRr : FRdRr<0b0010, 0b10, (outs GPR8 : $rd), (ins GPR8 : $src, GPR8 : $rr), "or\t$rd, $rr", [(set i8 : $rd, (or i8 : $src, i8 : $rr)), (implicit SREG)]>; // ORW Rd+1:Rd, Rr+1:Rr // // Expands to: // or Rd, Rr // or Rd+1, Rr+1 def ORWRdRr : Pseudo<(outs DREGS : $rd), (ins DREGS : $src, DREGS : $rr), "orw\t$rd, $rr", [ (set i16 : $rd, (or i16 : $src, i16 : $rr)), (implicit SREG) ]>; def EORRdRr : FRdRr<0b0010, 0b01, (outs GPR8 : $rd), (ins GPR8 : $src, GPR8 : $rr), "eor\t$rd, $rr", [(set i8 : $rd, (xor i8 : $src, i8 : $rr)), (implicit SREG)]>; // EORW Rd+1:Rd, Rr+1:Rr // // Expands to: // eor Rd, Rr // eor Rd+1, Rr+1 def EORWRdRr : Pseudo<(outs DREGS : $rd), (ins DREGS : $src, DREGS : $rr), "eorw\t$rd, $rr", [ (set i16 : $rd, (xor i16 : $src, i16 : $rr)), (implicit SREG) ]>; } def ANDIRdK : FRdK<0b0111, (outs LD8 : $rd), (ins LD8 : $src, imm_ldi8 : $k), "andi\t$rd, $k", [(set i8 : $rd, (and i8 : $src, imm : $k)), (implicit SREG)]>; // ANDI Rd+1:Rd, K+1:K // // Expands to: // andi Rd, K // andi Rd+1, K+1 def ANDIWRdK : Pseudo<(outs DLDREGS : $rd), (ins DLDREGS : $src, i16imm : $k), "andiw\t$rd, $k", [(set i16 : $rd, (and i16 : $src, imm : $k)), (implicit SREG)]>; def ORIRdK : FRdK<0b0110, (outs LD8 : $rd), (ins LD8 : $src, imm_ldi8 : $k), "ori\t$rd, $k", [(set i8 : $rd, (or i8 : $src, imm : $k)), (implicit SREG)]>; // ORIW Rd+1:Rd, K+1,K // // Expands to: // ori Rd, K // ori Rd+1, K+1 def ORIWRdK : Pseudo<(outs DLDREGS : $rd), (ins DLDREGS : $src, i16imm : $rr), "oriw\t$rd, $rr", [(set i16 : $rd, (or i16 : $src, imm : $rr)), (implicit SREG)]>; } //===----------------------------------------------------------------------===// // One's/Two's Complement //===----------------------------------------------------------------------===// let Constraints = "$src = $rd", Defs = [SREG] in { def COMRd : FRd<0b1001, 0b0100000, (outs GPR8 : $rd), (ins GPR8 : $src), "com\t$rd", [(set i8 : $rd, (not i8 : $src)), (implicit SREG)]>; // COMW Rd+1:Rd // // Expands to: // com Rd // com Rd+1 def COMWRd : Pseudo<(outs DREGS : $rd), (ins DREGS : $src), "comw\t$rd", [(set i16 : $rd, (not i16 : $src)), (implicit SREG)]>; def NEGRd : FRd<0b1001, 0b0100001, (outs GPR8 : $rd), (ins GPR8 : $src), "neg\t$rd", [(set i8 : $rd, (ineg i8 : $src)), (implicit SREG)]>; // NEGW Rd+1:Rd // // Expands to: // neg Rd+1 // neg Rd // sbc Rd+1, r1 let hasSideEffects=0 in def NEGWRd : Pseudo<(outs DREGS:$rd), (ins DREGS:$src, GPR8:$zero), "negw\t$rd", []>; } // TST Rd // Test for zero of minus. // This operation is identical to a `Rd AND Rd`. def : InstAlias<"tst\t$rd", (ANDRdRr GPR8 : $rd, GPR8 : $rd)>; // SBR Rd, K // // Mnemonic alias to 'ORI Rd, K'. Same bit pattern, same operands, // same everything. def : InstAlias<"sbr\t$rd, $k", (ORIRdK LD8 : $rd, imm_ldi8 : $k), /* Disable display, so we don't override ORI */ 0>; //===----------------------------------------------------------------------===// // Jump instructions //===----------------------------------------------------------------------===// let isBarrier = 1, isBranch = 1, isTerminator = 1 in { def RJMPk : FBRk<0, (outs), (ins brtarget_13 : $k), "rjmp\t$k", [(br bb : $k)]>; let isIndirectBranch = 1, Uses = [R31R30] in def IJMP : F16<0b1001010000001001, (outs), (ins), "ijmp", []>, Requires<[HasIJMPCALL]>; let isIndirectBranch = 1, Uses = [R31R30] in def EIJMP : F16<0b1001010000011001, (outs), (ins), "eijmp", []>, Requires<[HasEIJMPCALL]>; def JMPk : F32BRk<0b110, (outs), (ins call_target : $k), "jmp\t$k", []>, Requires<[HasJMPCALL]>; } //===----------------------------------------------------------------------===// // Call instructions //===----------------------------------------------------------------------===// let isCall = 1 in { // SP is marked as a use to prevent stack-pointer assignments that appear // immediately before calls from potentially appearing dead. let Uses = [SP] in def RCALLk : FBRk<1, (outs), (ins rcalltarget_13:$k), "rcall\t$k", [(AVRcall imm:$k)]>; // SP is marked as a use to prevent stack-pointer assignments that appear // immediately before calls from potentially appearing dead. let Uses = [SP, R31R30] in def ICALL : F16<0b1001010100001001, (outs), (ins variable_ops), "icall", []>, Requires<[HasIJMPCALL]>; // SP is marked as a use to prevent stack-pointer assignments that appear // immediately before calls from potentially appearing dead. let Uses = [SP, R31R30] in def EICALL : F16<0b1001010100011001, (outs), (ins variable_ops), "eicall", []>, Requires<[HasEIJMPCALL]>; // SP is marked as a use to prevent stack-pointer assignments that appear // immediately before calls from potentially appearing dead. // // TODO: the imm field can be either 16 or 22 bits in devices with more // than 64k of ROM, fix it once we support the largest devices. let Uses = [SP] in def CALLk : F32BRk<0b111, (outs), (ins call_target:$k), "call\t$k", [(AVRcall imm:$k)]>, Requires<[HasJMPCALL]>; } //===----------------------------------------------------------------------===// // Return instructions. //===----------------------------------------------------------------------===// let isTerminator = 1, isReturn = 1, isBarrier = 1 in { def RET : F16<0b1001010100001000, (outs), (ins), "ret", [(AVRretglue)]>; def RETI : F16<0b1001010100011000, (outs), (ins), "reti", [(AVRretiglue)]>; } //===----------------------------------------------------------------------===// // Compare operations. //===----------------------------------------------------------------------===// let Defs = [SREG] in { // CPSE Rd, Rr // Compare Rd and Rr, skipping the next instruction if they are equal. let isBarrier = 1, isBranch = 1, isTerminator = 1 in def CPSE : FRdRr<0b0001, 0b00, (outs), (ins GPR8 : $rd, GPR8 : $rr), "cpse\t$rd, $rr", []>; def CPRdRr : FRdRr<0b0001, 0b01, (outs), (ins GPR8 : $rd, GPR8 : $rr), "cp\t$rd, $rr", [(AVRcmp i8 : $rd, i8 : $rr), (implicit SREG)]>; // CPW Rd+1:Rd, Rr+1:Rr // // Expands to: // cp Rd, Rr // cpc Rd+1, Rr+1 def CPWRdRr : Pseudo<(outs), (ins DREGS : $src, DREGS : $src2), "cpw\t$src, $src2", [(AVRcmp i16 : $src, i16 : $src2), (implicit SREG)]>; let Uses = [SREG] in def CPCRdRr : FRdRr<0b0000, 0b01, (outs), (ins GPR8 : $rd, GPR8 : $rr), "cpc\t$rd, $rr", [(AVRcmpc i8 : $rd, i8 : $rr), (implicit SREG)]>; // CPCW Rd+1:Rd. Rr+1:Rr // // Expands to: // cpc Rd, Rr // cpc Rd+1, Rr+1 let Uses = [SREG] in def CPCWRdRr : Pseudo<(outs), (ins DREGS : $src, DREGS : $src2), "cpcw\t$src, $src2", [(AVRcmpc i16 : $src, i16 : $src2), (implicit SREG)]>; // CPI Rd, K // Compares a register with an 8 bit immediate. def CPIRdK : FRdK<0b0011, (outs), (ins LD8 : $rd, imm_ldi8 : $k), "cpi\t$rd, $k", [(AVRcmp i8 : $rd, imm : $k), (implicit SREG)]>; } //===----------------------------------------------------------------------===// // Register conditional skipping/branching operations. //===----------------------------------------------------------------------===// let isBranch = 1, isTerminator = 1 in { // Conditional skipping on GPR register bits, and // conditional skipping on IO register bits. let isBarrier = 1 in { def SBRCRrB : FRdB<0b10, (outs), (ins GPR8 : $rd, i8imm : $b), "sbrc\t$rd, $b", []>; def SBRSRrB : FRdB<0b11, (outs), (ins GPR8 : $rd, i8imm : $b), "sbrs\t$rd, $b", []>; def SBICAb : FIOBIT<0b01, (outs), (ins imm_port5 : $addr, i8imm : $b), "sbic\t$addr, $b", []>; def SBISAb : FIOBIT<0b11, (outs), (ins imm_port5 : $addr, i8imm : $b), "sbis\t$addr, $b", []>; } // Relative branches on status flag bits. let Uses = [SREG] in { // BRBS s, k // Branch if `s` flag in status register is set. def BRBSsk : FSK<0, (outs), (ins i8imm : $s, relbrtarget_7 : $k), "brbs\t$s, $k", []>; // BRBC s, k // Branch if `s` flag in status register is clear. def BRBCsk : FSK<1, (outs), (ins i8imm : $s, relbrtarget_7 : $k), "brbc\t$s, $k", []>; } } // BRCS k // Branch if carry flag is set def : InstAlias<"brcs\t$k", (BRBSsk 0, relbrtarget_7 : $k)>; // BRCC k // Branch if carry flag is clear def : InstAlias<"brcc\t$k", (BRBCsk 0, relbrtarget_7 : $k)>; // BRHS k // Branch if half carry flag is set def : InstAlias<"brhs\t$k", (BRBSsk 5, relbrtarget_7 : $k)>; // BRHC k // Branch if half carry flag is clear def : InstAlias<"brhc\t$k", (BRBCsk 5, relbrtarget_7 : $k)>; // BRTS k // Branch if the T flag is set def : InstAlias<"brts\t$k", (BRBSsk 6, relbrtarget_7 : $k)>; // BRTC k // Branch if the T flag is clear def : InstAlias<"brtc\t$k", (BRBCsk 6, relbrtarget_7 : $k)>; // BRVS k // Branch if the overflow flag is set def : InstAlias<"brvs\t$k", (BRBSsk 3, relbrtarget_7 : $k)>; // BRVC k // Branch if the overflow flag is clear def : InstAlias<"brvc\t$k", (BRBCsk 3, relbrtarget_7 : $k)>; // BRIE k // Branch if the global interrupt flag is enabled def : InstAlias<"brie\t$k", (BRBSsk 7, relbrtarget_7 : $k)>; // BRID k // Branch if the global interrupt flag is disabled def : InstAlias<"brid\t$k", (BRBCsk 7, relbrtarget_7 : $k)>; //===----------------------------------------------------------------------===// // PC-relative conditional branches //===----------------------------------------------------------------------===// // Based on status register. We cannot simplify these into instruction aliases // because we also need to be able to specify a pattern to match for ISel. let isBranch = 1, isTerminator = 1, Uses = [SREG] in { def BREQk : FBRsk<0, 0b001, (outs), (ins relbrtarget_7 : $k), "breq\t$k", [(AVRbrcond bb : $k, AVR_COND_EQ)]>; def BRNEk : FBRsk<1, 0b001, (outs), (ins relbrtarget_7 : $k), "brne\t$k", [(AVRbrcond bb : $k, AVR_COND_NE)]>; def BRSHk : FBRsk<1, 0b000, (outs), (ins relbrtarget_7 : $k), "brsh\t$k", [(AVRbrcond bb : $k, AVR_COND_SH)]>; def BRLOk : FBRsk<0, 0b000, (outs), (ins relbrtarget_7 : $k), "brlo\t$k", [(AVRbrcond bb : $k, AVR_COND_LO)]>; def BRMIk : FBRsk<0, 0b010, (outs), (ins relbrtarget_7 : $k), "brmi\t$k", [(AVRbrcond bb : $k, AVR_COND_MI)]>; def BRPLk : FBRsk<1, 0b010, (outs), (ins relbrtarget_7 : $k), "brpl\t$k", [(AVRbrcond bb : $k, AVR_COND_PL)]>; def BRGEk : FBRsk<1, 0b100, (outs), (ins relbrtarget_7 : $k), "brge\t$k", [(AVRbrcond bb : $k, AVR_COND_GE)]>; def BRLTk : FBRsk<0, 0b100, (outs), (ins relbrtarget_7 : $k), "brlt\t$k", [(AVRbrcond bb : $k, AVR_COND_LT)]>; } //===----------------------------------------------------------------------===// // Data transfer instructions //===----------------------------------------------------------------------===// // 8 and 16-bit register move instructions. let hasSideEffects = 0 in { def MOVRdRr : FRdRr<0b0010, 0b11, (outs GPR8 : $rd), (ins GPR8 : $rr), "mov\t$rd, $rr", []>; def MOVWRdRr : FMOVWRdRr<(outs DREGS : $rd), (ins DREGS : $rr), "movw\t$rd, $rr", []>, Requires<[HasMOVW]>; } // Load immediate values into registers. let isReMaterializable = 1 in { def LDIRdK : FRdK<0b1110, (outs LD8 : $rd), (ins imm_ldi8 : $k), "ldi\t$rd, $k", [(set i8 : $rd, imm : $k)]>; // LDIW Rd+1:Rd, K+1:K // // Expands to: // ldi Rd, K // ldi Rd+1, K+1 def LDIWRdK : Pseudo<(outs DLDREGS : $dst), (ins i16imm : $src), "ldiw\t$dst, $src", [(set i16 : $dst, imm : $src)]>; } // Load from data space into register. let canFoldAsLoad = 1, isReMaterializable = 1 in { def LDSRdK : F32DM<0b0, (outs GPR8 : $rd), (ins imm16 : $k), "lds\t$rd, $k", [(set i8 : $rd, (load imm : $k))]>, Requires<[HasSRAM, HasNonTinyEncoding]>; // Load from data space into register, which is only available on AVRTiny. def LDSRdKTiny : FLDSSTSTINY<0b0, (outs LD8:$rd), (ins imm7tiny:$k), "lds\t$rd, $k", [(set i8:$rd, (load imm:$k))]>, Requires<[HasSRAM, HasTinyEncoding]>; // LDSW Rd+1:Rd, K+1:K // // Expands to: // lds Rd, (K+1:K) // lds Rd+1 (K+1:K) + 1 def LDSWRdK : Pseudo<(outs DREGS : $dst), (ins i16imm : $src), "ldsw\t$dst, $src", [(set i16 : $dst, (load imm : $src))]>, Requires<[HasSRAM, HasNonTinyEncoding]>; } // Indirect loads. let canFoldAsLoad = 1, isReMaterializable = 1 in { def LDRdPtr : FSTLD<0, 0b00, (outs GPR8 : $reg), (ins LDSTPtrReg : $ptrreg), "ld\t$reg, $ptrreg", [(set GPR8 : $reg, (load i16 : $ptrreg))]>, Requires<[HasSRAM]>; // LDW Rd+1:Rd, P // // Expands to: // ld Rd, P // ldd Rd+1, P+1 // On reduced tiny cores, this instruction expands to: // ld Rd, P+ // ld Rd+1, P+ // subiw P, 2 let Constraints = "@earlyclobber $reg" in def LDWRdPtr : Pseudo<(outs DREGS : $reg), (ins PTRDISPREGS : $ptrreg), "ldw\t$reg, $ptrreg", [(set i16 : $reg, (load i16 : $ptrreg))]>, Requires<[HasSRAM]>; } // Indirect loads (with postincrement or predecrement). let mayLoad = 1, hasSideEffects = 0, Constraints = "$ptrreg = $base_wb,@earlyclobber $reg" in { def LDRdPtrPi : FSTLD<0, 0b01, (outs GPR8 : $reg, PTRREGS : $base_wb), (ins LDSTPtrReg : $ptrreg), "ld\t$reg, $ptrreg+", []>, Requires<[HasSRAM]>; // LDW Rd+1:Rd, P+ // Expands to: // ld Rd, P+ // ld Rd+1, P+ def LDWRdPtrPi : Pseudo<(outs DREGS : $reg, PTRREGS : $base_wb), (ins PTRREGS : $ptrreg), "ldw\t$reg, $ptrreg+", []>, Requires<[HasSRAM]>; def LDRdPtrPd : FSTLD<0, 0b10, (outs GPR8 : $reg, PTRREGS : $base_wb), (ins LDSTPtrReg : $ptrreg), "ld\t$reg, -$ptrreg", []>, Requires<[HasSRAM]>; // LDW Rd+1:Rd, -P // // Expands to: // ld Rd+1, -P // ld Rd, -P def LDWRdPtrPd : Pseudo<(outs DREGS : $reg, PTRREGS : $base_wb), (ins PTRREGS : $ptrreg), "ldw\t$reg, -$ptrreg", []>, Requires<[HasSRAM]>; } // Load indirect with displacement operations. let canFoldAsLoad = 1, isReMaterializable = 1 in { def LDDRdPtrQ : FSTDLDD<0, (outs GPR8 : $reg), (ins memri : $memri), "ldd\t$reg, $memri", [(set i8 : $reg, (load addr : $memri))]>, Requires<[HasSRAM, HasNonTinyEncoding]>; // LDDW Rd+1:Rd, P+q // // Expands to: // ldd Rd, P+q // ldd Rd+1, P+q+1 // On reduced tiny cores, this instruction expands to: // subiw P, -q // ld Rd, P+ // ld Rd+1, P+ // subiw P, q+2 let Constraints = "@earlyclobber $dst" in def LDDWRdPtrQ : Pseudo<(outs DREGS : $dst), (ins memri : $memri), "lddw\t$dst, $memri", [(set i16 : $dst, (load addr : $memri))]>, Requires<[HasSRAM]>; // An identical pseudo instruction to LDDWRdPtrQ, expect restricted to the Y // register and without the @earlyclobber flag. // // Used to work around a bug caused by the register allocator not // being able to handle the expansion of a COPY into an machine instruction // that has an earlyclobber flag. This is because the register allocator will // try expand a copy from a register slot into an earlyclobber instruction. // Instructions that are earlyclobber need to be in a dedicated earlyclobber // slot. // // This pseudo instruction can be used pre-AVR pseudo expansion in order to // get a frame index load without directly using earlyclobber instructions. // // The pseudo expansion pass trivially expands this into LDDWRdPtrQ. // // This instruction may be removed once PR13375 is fixed. let mayLoad = 1, hasSideEffects = 0 in def LDDWRdYQ : Pseudo<(outs DREGS : $dst), (ins memri : $memri), "lddw\t$dst, $memri", []>, Requires<[HasSRAM]>; } class AtomicLoad : Pseudo<(outs DRC : $rd), (ins PTRRC : $rr), "atomic_op", [(set DRC : $rd, (Op i16 : $rr))]>; class AtomicStore : Pseudo<(outs), (ins PTRRC : $rd, DRC : $rr), "atomic_op", [(Op DRC:$rr, i16:$rd)]>; class AtomicLoadOp : Pseudo<(outs DRC:$rd), (ins PTRRC:$rr, DRC:$operand), "atomic_op", [(set DRC:$rd, (Op i16:$rr, DRC:$operand))]>; // Atomic instructions // =================== // // 8-bit operations can use any pointer register because // they are expanded directly into an LD/ST instruction. // // 16-bit operations use 16-bit load/store postincrement instructions, // which require PTRDISPREGS. def AtomicLoad8 : AtomicLoad; def AtomicLoad16 : AtomicLoad; def AtomicStore8 : AtomicStore; def AtomicStore16 : AtomicStore; class AtomicLoadOp8 : AtomicLoadOp; class AtomicLoadOp16 : AtomicLoadOp; let usesCustomInserter=1 in { def AtomicLoadAdd8 : AtomicLoadOp8; def AtomicLoadAdd16 : AtomicLoadOp16; def AtomicLoadSub8 : AtomicLoadOp8; def AtomicLoadSub16 : AtomicLoadOp16; def AtomicLoadAnd8 : AtomicLoadOp8; def AtomicLoadAnd16 : AtomicLoadOp16; def AtomicLoadOr8 : AtomicLoadOp8; def AtomicLoadOr16 : AtomicLoadOp16; def AtomicLoadXor8 : AtomicLoadOp8; def AtomicLoadXor16 : AtomicLoadOp16; } def AtomicFence : Pseudo<(outs), (ins), "atomic_fence", [(atomic_fence timm, timm)]>; // Indirect store from register to data space. def STSKRr : F32DM<0b1, (outs), (ins imm16 : $k, GPR8 : $rd), "sts\t$k, $rd", [(store i8 : $rd, imm : $k)]>, Requires<[HasSRAM, HasNonTinyEncoding]>; // Store from register to data space, which is only available on AVRTiny. def STSKRrTiny : FLDSSTSTINY<0b1, (outs), (ins imm7tiny:$k, LD8:$rd), "sts\t$k, $rd", [(store i8:$rd, imm:$k)]>, Requires<[HasSRAM, HasTinyEncoding]>; // STSW K+1:K, Rr+1:Rr // // Expands to: // sts Rr+1, (K+1:K) + 1 // sts Rr, (K+1:K) def STSWKRr : Pseudo<(outs), (ins i16imm : $dst, DREGS : $src), "stsw\t$dst, $src", [(store i16 : $src, imm : $dst)]>, Requires<[HasSRAM, HasNonTinyEncoding]>; // Indirect stores. // ST P, Rr // Stores the value of Rr into the location addressed by pointer P. def STPtrRr : FSTLD<1, 0b00, (outs), (ins LDSTPtrReg : $ptrreg, GPR8 : $reg), "st\t$ptrreg, $reg", [(store GPR8 : $reg, i16 : $ptrreg)]>, Requires<[HasSRAM]>; // STW P, Rr+1:Rr // Stores the value of Rr into the location addressed by pointer P. // // Expands to: // st P, Rr // std P+1, Rr+1 // On reduced tiny cores, this instruction expands to: // st P+, Rr // st P+, Rr+1 // subiw P, q+2 def STWPtrRr : Pseudo<(outs), (ins PTRDISPREGS : $ptrreg, DREGS : $reg), "stw\t$ptrreg, $reg", [(store i16 : $reg, i16 : $ptrreg)]>, Requires<[HasSRAM]>; // Indirect stores (with postincrement or predecrement). let Constraints = "$ptrreg = $base_wb,@earlyclobber $base_wb" in { // ST P+, Rr // Stores the value of Rr into the location addressed by pointer P. // Post increments P. def STPtrPiRr : FSTLD<1, 0b01, (outs LDSTPtrReg : $base_wb), (ins LDSTPtrReg : $ptrreg, GPR8 : $reg, i8imm : $offs), "st\t$ptrreg+, $reg", [(set i16 : $base_wb, (post_store GPR8 : $reg, i16 : $ptrreg, imm : $offs))]>, Requires<[HasSRAM]>; // STW P+, Rr+1:Rr // Stores the value of Rr into the location addressed by pointer P. // Post increments P. // // Expands to: // st P+, Rr // st P+, Rr+1 def STWPtrPiRr : Pseudo<(outs PTRREGS : $base_wb), (ins PTRREGS : $ptrreg, DREGS : $trh, i8imm : $offs), "stw\t$ptrreg+, $trh", [(set PTRREGS : $base_wb, (post_store DREGS : $trh, PTRREGS : $ptrreg, imm : $offs))]>, Requires<[HasSRAM]>; // ST -P, Rr // Stores the value of Rr into the location addressed by pointer P. // Pre decrements P. def STPtrPdRr : FSTLD<1, 0b10, (outs LDSTPtrReg : $base_wb), (ins LDSTPtrReg : $ptrreg, GPR8 : $reg, i8imm : $offs), "st\t-$ptrreg, $reg", [(set i16 : $base_wb, (pre_store GPR8 : $reg, i16 : $ptrreg, imm : $offs))]>, Requires<[HasSRAM]>; // STW -P, Rr+1:Rr // Stores the value of Rr into the location addressed by pointer P. // Pre decrements P. // // Expands to: // st -P, Rr+1 // st -P, Rr def STWPtrPdRr : Pseudo<(outs PTRREGS : $base_wb), (ins PTRREGS : $ptrreg, DREGS : $reg, i8imm : $offs), "stw\t-$ptrreg, $reg", [(set PTRREGS : $base_wb, (pre_store i16 : $reg, i16 : $ptrreg, imm : $offs))]>, Requires<[HasSRAM]>; } // Store indirect with displacement operations. // STD P+q, Rr // Stores the value of Rr into the location addressed by pointer P with a // displacement of q. Does not modify P. def STDPtrQRr : FSTDLDD<1, (outs), (ins memri : $memri, GPR8 : $reg), "std\t$memri, $reg", [(store i8 : $reg, addr : $memri)]>, Requires<[HasSRAM, HasNonTinyEncoding]>; // STDW P+q, Rr+1:Rr // Stores the value of Rr into the location addressed by pointer P with a // displacement of q. Does not modify P. // // Expands to: // std P+q, Rr // std P+q+1, Rr+1 // On reduced tiny cores, this instruction expands to: // subiw P, -q // st P+, Rr // st P+, Rr+1 // subiw P, q+2 def STDWPtrQRr : Pseudo<(outs), (ins memri : $memri, DREGS : $src), "stdw\t$memri, $src", [(store i16 : $src, addr : $memri)]>, Requires<[HasSRAM]>; // Load program memory operations. let canFoldAsLoad = 1, isReMaterializable = 1, mayLoad = 1, hasSideEffects = 0 in { let Defs = [R0], Uses = [R31R30] in def LPM : F16<0b1001010111001000, (outs), (ins), "lpm", []>, Requires<[HasLPM]>; // These pseudo instructions are combination of the OUT and LPM instructions. let Defs = [R0] in { def LPMBRdZ : Pseudo<(outs GPR8:$dst), (ins ZREG:$z), "lpmb\t$dst, $z", []>, Requires<[HasLPM]>; let Constraints = "@earlyclobber $dst" in def LPMWRdZ : Pseudo<(outs DREGS:$dst), (ins ZREG:$z), "lpmw\t$dst, $z", []>, Requires<[HasLPM]>; } def LPMRdZ : FLPMX<0, 0, (outs GPR8 : $rd), (ins ZREG : $z), "lpm\t$rd, $z", []>, Requires<[HasLPMX]>; // Load program memory, while postincrementing the Z register. let Defs = [R31R30] in { def LPMRdZPi : FLPMX<0, 1, (outs GPR8 : $rd), (ins ZREG : $z), "lpm\t$rd, $z+", []>, Requires<[HasLPMX]>; def LPMWRdZPi : Pseudo<(outs DREGS : $dst), (ins ZREG : $z), "lpmw\t$dst, $z+", []>, Requires<[HasLPMX]>; } } // Extended load program memory operations. let mayLoad = 1, hasSideEffects = 0 in { let Defs = [R0], Uses = [R31R30] in def ELPM : F16<0b1001010111011000, (outs), (ins), "elpm", []>, Requires<[HasELPM]>; def ELPMRdZ : FLPMX<1, 0, (outs GPR8:$rd), (ins ZREG:$z), "elpm\t$rd, $z", []>, Requires<[HasELPMX]>; let Defs = [R31R30] in { def ELPMRdZPi : FLPMX<1, 1, (outs GPR8:$rd), (ins ZREG:$z), "elpm\t$rd, $z+", []>, Requires<[HasELPMX]>; } // These pseudo instructions are combination of the OUT and ELPM instructions. let Defs = [R0] in { def ELPMBRdZ : Pseudo<(outs GPR8:$dst), (ins ZREG:$z, LD8:$p), "elpmb\t$dst, $z, $p", []>, Requires<[HasELPM]>; let Constraints = "@earlyclobber $dst" in def ELPMWRdZ : Pseudo<(outs DREGS:$dst), (ins ZREG:$z, LD8:$p), "elpmw\t$dst, $z, $p", []>, Requires<[HasELPM]>; } // These pseudos are combination of the OUT and ELPM instructions. let Defs = [R31R30], hasSideEffects = 1 in { def ELPMBRdZPi : Pseudo<(outs GPR8:$dst), (ins ZREG:$z, LD8:$p), "elpmb\t$dst, $z+, $p", []>, Requires<[HasELPMX]>; def ELPMWRdZPi : Pseudo<(outs DREGS:$dst), (ins ZREG:$z, LD8:$p), "elpmw\t$dst, $z+, $p", []>, Requires<[HasELPMX]>; } } // Store program memory operations. let Uses = [R1, R0] in { let Uses = [R31R30, R1, R0] in def SPM : F16<0b1001010111101000, (outs), (ins), "spm", []>, Requires<[HasSPM]>; let Defs = [R31R30] in def SPMZPi : F16<0b1001010111111000, (outs), (ins ZREG : $z), "spm $z+", []>, Requires<[HasSPMX]>; } // Read data from IO location operations. let canFoldAsLoad = 1, isReMaterializable = 1 in { def INRdA : FIORdA<(outs GPR8 : $rd), (ins imm_port6 : $A), "in\t$rd, $A", [(set i8 : $rd, (load ioaddr8 : $A))]>; def INWRdA : Pseudo<(outs DREGS : $dst), (ins imm_port6 : $src), "inw\t$dst, $src", [(set i16 : $dst, (load ioaddr16 : $src))]>; } // Write data to IO location operations. def OUTARr : FIOARr<(outs), (ins imm_port6 : $A, GPR8 : $rr), "out\t$A, $rr", [(store i8 : $rr, ioaddr8 : $A)]>; def OUTWARr : Pseudo<(outs), (ins imm_port6 : $dst, DREGS : $src), "outw\t$dst, $src", [(store i16 : $src, ioaddr16 : $dst)]>; // Stack push/pop operations. let Defs = [SP], Uses = [SP], hasSideEffects = 0 in { // Stack push operations. let mayStore = 1 in { def PUSHRr : FRd<0b1001, 0b0011111, (outs), (ins GPR8 : $rd), "push\t$rd", []>, Requires<[HasSRAM]>; def PUSHWRr : Pseudo<(outs), (ins DREGS : $reg), "pushw\t$reg", []>, Requires<[HasSRAM]>; } // Stack pop operations. let mayLoad = 1 in { def POPRd : FRd<0b1001, 0b0001111, (outs GPR8 : $rd), (ins), "pop\t$rd", []>, Requires<[HasSRAM]>; def POPWRd : Pseudo<(outs DREGS : $reg), (ins), "popw\t$reg", []>, Requires<[HasSRAM]>; } } // Read-Write-Modify (RMW) instructions. def XCHZRd : FZRd<0b100, (outs GPR8 : $rd), (ins ZREG : $z), "xch\t$z, $rd", []>, Requires<[SupportsRMW]>; def LASZRd : FZRd<0b101, (outs GPR8 : $rd), (ins ZREG : $z), "las\t$z, $rd", []>, Requires<[SupportsRMW]>; def LACZRd : FZRd<0b110, (outs GPR8 : $rd), (ins ZREG : $z), "lac\t$z, $rd", []>, Requires<[SupportsRMW]>; def LATZRd : FZRd<0b111, (outs GPR8 : $rd), (ins ZREG : $z), "lat\t$z, $rd", []>, Requires<[SupportsRMW]>; //===----------------------------------------------------------------------===// // Bit and bit-test instructions //===----------------------------------------------------------------------===// // Bit shift/rotate operations. let Constraints = "$src = $rd", Defs = [SREG] in { // 8-bit LSL is an alias of ADD Rd, Rd def LSLWRd : Pseudo<(outs DREGS : $rd), (ins DREGS : $src), "lslw\t$rd", [(set i16 : $rd, (AVRlsl i16 : $src)), (implicit SREG)]>; def LSLWHiRd : Pseudo<(outs DREGS:$rd), (ins DREGS:$src), "lslwhi\t$rd", [(set i16:$rd, (AVRlslhi i16:$src)), (implicit SREG)]>; def LSLWNRd : Pseudo<(outs DLDREGS : $rd), (ins DREGS : $src, imm16 : $bits), "lslwn\t$rd, $bits", [ (set i16 : $rd, (AVRlslwn i16 : $src, imm : $bits)), (implicit SREG) ]>; def LSLBNRd : Pseudo<(outs LD8 : $rd), (ins GPR8 : $src, imm_ldi8 : $bits), "lslbn\t$rd, $bits", [ (set i8 : $rd, (AVRlslbn i8 : $src, imm : $bits)), (implicit SREG) ]>; def LSRRd : FRd<0b1001, 0b0100110, (outs GPR8 : $rd), (ins GPR8 : $src), "lsr\t$rd", [(set i8 : $rd, (AVRlsr i8 : $src)), (implicit SREG)]>; def LSRWRd : Pseudo<(outs DREGS : $rd), (ins DREGS : $src), "lsrw\t$rd", [(set i16 : $rd, (AVRlsr i16 : $src)), (implicit SREG)]>; def LSRWLoRd : Pseudo<(outs DREGS:$rd), (ins DREGS:$src), "lsrwlo\t$rd", [(set i16:$rd, (AVRlsrlo i16:$src)), (implicit SREG)]>; def LSRWNRd : Pseudo<(outs DLDREGS : $rd), (ins DREGS : $src, imm16 : $bits), "lsrwn\t$rd, $bits", [ (set i16 : $rd, (AVRlsrwn i16 : $src, imm : $bits)), (implicit SREG) ]>; def LSRBNRd : Pseudo<(outs LD8 : $rd), (ins GPR8 : $src, imm_ldi8 : $bits), "lsrbn\t$rd, $bits", [ (set i8 : $rd, (AVRlsrbn i8 : $src, imm : $bits)), (implicit SREG) ]>; def ASRRd : FRd<0b1001, 0b0100101, (outs GPR8 : $rd), (ins GPR8 : $src), "asr\t$rd", [(set i8 : $rd, (AVRasr i8 : $src)), (implicit SREG)]>; def ASRWNRd : Pseudo<(outs DREGS : $rd), (ins DREGS : $src, imm16 : $bits), "asrwn\t$rd, $bits", [ (set i16 : $rd, (AVRasrwn i16 : $src, imm : $bits)), (implicit SREG) ]>; def ASRBNRd : Pseudo<(outs LD8 : $rd), (ins GPR8 : $src, imm_ldi8 : $bits), "asrbn\t$rd, $bits", [ (set i8 : $rd, (AVRasrbn i8 : $src, imm : $bits)), (implicit SREG) ]>; def ASRWRd : Pseudo<(outs DREGS : $rd), (ins DREGS : $src), "asrw\t$rd", [(set i16 : $rd, (AVRasr i16 : $src)), (implicit SREG)]>; def ASRWLoRd : Pseudo<(outs DREGS:$rd), (ins DREGS:$src), "asrwlo\t$rd", [(set i16:$rd, (AVRasrlo i16:$src)), (implicit SREG)]>; let Uses = [R1] in def ROLBRdR1 : Pseudo<(outs GPR8:$rd), (ins GPR8:$src), "rolb\t$rd", [(set i8:$rd, (AVRrol i8:$src)), (implicit SREG)]>, Requires<[HasNonTinyEncoding]>; let Uses = [R17] in def ROLBRdR17 : Pseudo<(outs GPR8:$rd), (ins GPR8:$src), "rolb\t$rd", [(set i8:$rd, (AVRrol i8:$src)), (implicit SREG)]>, Requires<[HasTinyEncoding]>; def RORBRd : Pseudo<(outs GPR8 : $rd), (ins GPR8 : $src), "rorb\t$rd", [(set i8 : $rd, (AVRror i8 : $src)), (implicit SREG)]>; // Bit rotate operations. let Uses = [SREG] in { def ROLWRd : Pseudo<(outs DREGS : $rd), (ins DREGS : $src), "rolw\t$rd", [(set i16 : $rd, (AVRrol i16 : $src)), (implicit SREG)]>; def RORRd : FRd<0b1001, 0b0100111, (outs GPR8 : $rd), (ins GPR8 : $src), "ror\t$rd", []>; def RORWRd : Pseudo<(outs DREGS : $rd), (ins DREGS : $src), "rorw\t$rd", [(set i16 : $rd, (AVRror i16 : $src)), (implicit SREG)]>; } } // SWAP Rd // Swaps the high and low nibbles in a register. let Constraints = "$src = $rd" in def SWAPRd : FRd<0b1001, 0b0100010, (outs GPR8 : $rd), (ins GPR8 : $src), "swap\t$rd", [(set i8 : $rd, (AVRSwap i8 : $src))]>; // IO register bit set/clear operations. //: TODO: add patterns when popcount(imm)==2 to be expanded with 2 sbi/cbi // instead of in+ori+out which requires one more instr. def SBIAb : FIOBIT<0b10, (outs), (ins imm_port5 : $addr, i8imm : $b), "sbi\t$addr, $b", [(store(or(i8(load lowioaddr8 : $addr)), iobitpos8 : $b), lowioaddr8 : $addr)]>; def CBIAb : FIOBIT<0b00, (outs), (ins imm_port5 : $addr, i8imm : $b), "cbi\t$addr, $b", [(store(and(i8(load lowioaddr8 : $addr)), iobitposn8 : $b), lowioaddr8 : $addr)]>; // Status register bit load/store operations. let Defs = [SREG] in def BST : FRdB<0b01, (outs), (ins GPR8 : $rd, i8imm : $b), "bst\t$rd, $b", []>; let Constraints = "$src = $rd", Uses = [SREG] in def BLD : FRdB<0b00, (outs GPR8 : $rd), (ins GPR8 : $src, i8imm : $b), "bld\t$rd, $b", []>; def CBR : InstAlias<"cbr\t$rd, $k", (ANDIRdK LD8 : $rd, imm_com8 : $k), 0>; // CLR Rd // Alias for EOR Rd, Rd // ------------- // Clears all bits in a register. def CLR : InstAlias<"clr\t$rd", (EORRdRr GPR8 : $rd, GPR8 : $rd)>; // LSL Rd // Alias for ADD Rd, Rd // -------------- // Logical shift left one bit. def LSL : InstAlias<"lsl\t$rd", (ADDRdRr GPR8 : $rd, GPR8 : $rd)>; def ROL : InstAlias<"rol\t$rd", (ADCRdRr GPR8 : $rd, GPR8 : $rd)>; // SER Rd // Alias for LDI Rd, 0xff // --------- // Sets all bits in a register. def : InstAlias<"ser\t$rd", (LDIRdK LD8 : $rd, 0xff), 0>; let hasSideEffects=1 in { let Defs = [SREG] in def BSETs : FS<0, (outs), (ins i8imm:$s), "bset\t$s", []>; let Defs = [SREG] in def BCLRs : FS<1, (outs), (ins i8imm:$s), "bclr\t$s", []>; } // Set/clear aliases for the carry (C) status flag (bit 0). def : InstAlias<"sec", (BSETs 0)>; def : InstAlias<"clc", (BCLRs 0)>; // Set/clear aliases for the zero (Z) status flag (bit 1). def : InstAlias<"sez", (BSETs 1)>; def : InstAlias<"clz", (BCLRs 1)>; // Set/clear aliases for the negative (N) status flag (bit 2). def : InstAlias<"sen", (BSETs 2)>; def : InstAlias<"cln", (BCLRs 2)>; // Set/clear aliases for the overflow (V) status flag (bit 3). def : InstAlias<"sev", (BSETs 3)>; def : InstAlias<"clv", (BCLRs 3)>; // Set/clear aliases for the signed (S) status flag (bit 4). def : InstAlias<"ses", (BSETs 4)>; def : InstAlias<"cls", (BCLRs 4)>; // Set/clear aliases for the half-carry (H) status flag (bit 5). def : InstAlias<"seh", (BSETs 5)>; def : InstAlias<"clh", (BCLRs 5)>; // Set/clear aliases for the T status flag (bit 6). def : InstAlias<"set", (BSETs 6)>; def : InstAlias<"clt", (BCLRs 6)>; // Set/clear aliases for the interrupt (I) status flag (bit 7). def : InstAlias<"sei", (BSETs 7)>; def : InstAlias<"cli", (BCLRs 7)>; //===----------------------------------------------------------------------===// // Special/Control instructions //===----------------------------------------------------------------------===// // BREAK // Breakpoint instruction // --------- // <|1001|0101|1001|1000> def BREAK : F16<0b1001010110011000, (outs), (ins), "break", []>, Requires<[HasBREAK]>; // NOP // No-operation instruction // --------- // <|0000|0000|0000|0000> def NOP : F16<0b0000000000000000, (outs), (ins), "nop", []>; // SLEEP // Sleep instruction // --------- // <|1001|0101|1000|1000> def SLEEP : F16<0b1001010110001000, (outs), (ins), "sleep", []>; // WDR // Watchdog reset // --------- // <|1001|0101|1010|1000> def WDR : F16<0b1001010110101000, (outs), (ins), "wdr", []>; //===----------------------------------------------------------------------===// // Pseudo instructions for later expansion //===----------------------------------------------------------------------===// //: TODO: Optimize this for wider types AND optimize the following code // compile int foo(char a, char b, char c, char d) {return d+b;} // looks like a missed sext_inreg opportunity. def SEXT : ExtensionPseudo<(outs DREGS : $dst), (ins GPR8 : $src), "sext\t$dst, $src", [(set i16 : $dst, (sext i8 : $src)), (implicit SREG)]>; def ZEXT : ExtensionPseudo<(outs DREGS : $dst), (ins GPR8 : $src), "zext\t$dst, $src", [(set i16 : $dst, (zext i8 : $src)), (implicit SREG)]>; // This pseudo gets expanded into a movw+adiw thus it clobbers SREG. let Defs = [SREG], hasSideEffects = 0 in def FRMIDX : Pseudo<(outs DLDREGS : $dst), (ins DLDREGS : $src, i16imm : $src2), "frmidx\t$dst, $src, $src2", []>; // This pseudo is either converted to a regular store or a push which clobbers // SP. def STDSPQRr : StorePseudo<(outs), (ins memspi : $dst, GPR8 : $src), "stdstk\t$dst, $src", [(store i8 : $src, addr : $dst)]>; // This pseudo is either converted to a regular store or a push which clobbers // SP. def STDWSPQRr : StorePseudo<(outs), (ins memspi : $dst, DREGS : $src), "stdwstk\t$dst, $src", [(store i16 : $src, addr : $dst)]>; // SP read/write pseudos. let hasSideEffects = 0 in { let Uses = [SP] in def SPREAD : Pseudo<(outs DREGS : $dst), (ins GPRSP : $src), "spread\t$dst, $src", []>; let Defs = [SP] in def SPWRITE : Pseudo<(outs GPRSP : $dst), (ins DREGS : $src), "spwrite\t$dst, $src", []>; } def Select8 : SelectPseudo<(outs GPR8 : $dst), (ins GPR8 : $src, GPR8 : $src2, i8imm : $cc), "# Select8 PSEUDO", [(set i8 : $dst, (AVRselectcc i8 : $src, i8 : $src2, imm : $cc))]>; def Select16 : SelectPseudo<(outs DREGS : $dst), (ins DREGS : $src, DREGS : $src2, i8imm : $cc), "# Select16 PSEUDO", [(set i16 : $dst, (AVRselectcc i16 : $src, i16 : $src2, imm : $cc))]>; def Lsl8 : ShiftPseudo<(outs GPR8 : $dst), (ins GPR8 : $src, GPR8 : $cnt), "# Lsl8 PSEUDO", [(set i8 : $dst, (AVRlslLoop i8 : $src, i8 : $cnt))]>; def Lsl16 : ShiftPseudo<(outs DREGS : $dst), (ins DREGS : $src, GPR8 : $cnt), "# Lsl16 PSEUDO", [(set i16 : $dst, (AVRlslLoop i16 : $src, i8 : $cnt))]>; def Lsl32 : ShiftPseudo<(outs DREGS:$dstlo, DREGS:$dsthi), (ins DREGS:$srclo, DREGS:$srchi, i8imm:$cnt), "# Lsl32 PSEUDO", [(set i16:$dstlo, i16:$dsthi, (AVRlslw i16:$srclo, i16:$srchi, i8:$cnt))]>; def Lsr8 : ShiftPseudo<(outs GPR8 : $dst), (ins GPR8 : $src, GPR8 : $cnt), "# Lsr8 PSEUDO", [(set i8 : $dst, (AVRlsrLoop i8 : $src, i8 : $cnt))]>; def Lsr16 : ShiftPseudo<(outs DREGS : $dst), (ins DREGS : $src, GPR8 : $cnt), "# Lsr16 PSEUDO", [(set i16 : $dst, (AVRlsrLoop i16 : $src, i8 : $cnt))]>; def Lsr32 : ShiftPseudo<(outs DREGS:$dstlo, DREGS:$dsthi), (ins DREGS:$srclo, DREGS:$srchi, i8imm:$cnt), "# Lsr32 PSEUDO", [(set i16:$dstlo, i16:$dsthi, (AVRlsrw i16:$srclo, i16:$srchi, i8:$cnt))]>; def Rol8 : ShiftPseudo<(outs GPR8 : $dst), (ins GPR8 : $src, GPR8 : $cnt), "# Rol8 PSEUDO", [(set i8 : $dst, (AVRrolLoop i8 : $src, i8 : $cnt))]>; def Rol16 : ShiftPseudo<(outs DREGS : $dst), (ins DREGS : $src, GPR8 : $cnt), "# Rol16 PSEUDO", [(set i16 : $dst, (AVRrolLoop i16 : $src, i8 : $cnt))]>; def Ror8 : ShiftPseudo<(outs GPR8 : $dst), (ins GPR8 : $src, GPR8 : $cnt), "# Ror8 PSEUDO", [(set i8 : $dst, (AVRrorLoop i8 : $src, i8 : $cnt))]>; def Ror16 : ShiftPseudo<(outs DREGS : $dst), (ins DREGS : $src, GPR8 : $cnt), "# Ror16 PSEUDO", [(set i16 : $dst, (AVRrorLoop i16 : $src, i8 : $cnt))]>; def Asr8 : ShiftPseudo<(outs GPR8 : $dst), (ins GPR8 : $src, GPR8 : $cnt), "# Asr8 PSEUDO", [(set i8 : $dst, (AVRasrLoop i8 : $src, i8 : $cnt))]>; def Asr16 : ShiftPseudo<(outs DREGS : $dst), (ins DREGS : $src, GPR8 : $cnt), "# Asr16 PSEUDO", [(set i16 : $dst, (AVRasrLoop i16 : $src, i8 : $cnt))]>; def Asr32 : ShiftPseudo<(outs DREGS:$dstlo, DREGS:$dsthi), (ins DREGS:$srclo, DREGS:$srchi, i8imm:$cnt), "# Asr32 PSEUDO", [(set i16:$dstlo, i16:$dsthi, (AVRasrw i16:$srclo, i16:$srchi, i8:$cnt))]>; // lowered to a copy from the zero register. let usesCustomInserter=1 in def CopyZero : Pseudo<(outs GPR8:$rd), (ins), "clrz\t$rd", [(set i8:$rd, 0)]>; //===----------------------------------------------------------------------===// // Non-Instruction Patterns //===----------------------------------------------------------------------===// //: TODO: look in x86InstrCompiler.td for odd encoding trick related to // add x, 128 -> sub x, -128. Clang is emitting an eor for this (ldi+eor) // the add instruction always writes the carry flag def : Pat<(addc i8 : $src, i8 : $src2), (ADDRdRr i8 : $src, i8 : $src2)>; def : Pat<(addc DREGS : $src, DREGS : $src2), (ADDWRdRr DREGS : $src, DREGS : $src2)>; // all sub instruction variants always writes the carry flag def : Pat<(subc i8 : $src, i8 : $src2), (SUBRdRr i8 : $src, i8 : $src2)>; def : Pat<(subc i16 : $src, i16 : $src2), (SUBWRdRr i16 : $src, i16 : $src2)>; def : Pat<(subc i8 : $src, imm : $src2), (SUBIRdK i8 : $src, imm : $src2)>; def : Pat<(subc i16 : $src, imm : $src2), (SUBIWRdK i16 : $src, imm : $src2)>; // These patterns convert add (x, -imm) to sub (x, imm) since we dont have // any add with imm instructions. Also take care of the adiw/sbiw instructions. def : Pat<(add i16 : $src1, imm0_63_neg : $src2), (SBIWRdK i16 : $src1, (imm0_63_neg : $src2))>, Requires<[HasADDSUBIW]>; def : Pat<(add i16 : $src1, imm : $src2), (SUBIWRdK i16 : $src1, (imm16_neg_XFORM imm : $src2))>; def : Pat<(addc i16 : $src1, imm : $src2), (SUBIWRdK i16 : $src1, (imm16_neg_XFORM imm : $src2))>; def : Pat<(add i8 : $src1, imm : $src2), (SUBIRdK i8 : $src1, (imm8_neg_XFORM imm : $src2))>; def : Pat<(addc i8 : $src1, imm : $src2), (SUBIRdK i8 : $src1, (imm8_neg_XFORM imm : $src2))>; def : Pat<(adde i8 : $src1, imm : $src2), (SBCIRdK i8 : $src1, (imm8_neg_XFORM imm : $src2))>; // Emit NEGWRd with an extra zero register operand. def : Pat<(ineg i16:$src), (NEGWRd i16:$src, (CopyZero))>; // Calls. let Predicates = [HasJMPCALL] in { def : Pat<(AVRcall(i16 tglobaladdr:$dst)), (CALLk tglobaladdr:$dst)>; def : Pat<(AVRcall(i16 texternalsym:$dst)), (CALLk texternalsym:$dst)>; } def : Pat<(AVRcall(i16 tglobaladdr:$dst)), (RCALLk tglobaladdr:$dst)>; def : Pat<(AVRcall(i16 texternalsym:$dst)), (RCALLk texternalsym:$dst)>; // `anyext` def : Pat<(i16(anyext i8 : $src)), (INSERT_SUBREG(i16(IMPLICIT_DEF)), i8 : $src, sub_lo)>; // `trunc` def : Pat<(i8(trunc i16 : $src)), (EXTRACT_SUBREG i16 : $src, sub_lo)>; // sext_inreg def : Pat<(sext_inreg i16 : $src, i8), (SEXT(i8(EXTRACT_SUBREG i16 : $src, sub_lo)))>; // GlobalAddress def : Pat<(i16(AVRWrapper tglobaladdr : $dst)), (LDIWRdK tglobaladdr : $dst)>; def : Pat<(add i16 : $src, (AVRWrapper tglobaladdr : $src2)), (SUBIWRdK i16 : $src, tglobaladdr : $src2)>; def : Pat<(i8(load(AVRWrapper tglobaladdr:$dst))), (LDSRdK tglobaladdr:$dst)>, Requires<[HasSRAM, HasNonTinyEncoding]>; def : Pat<(i8(load(AVRWrapper tglobaladdr:$dst))), (LDSRdKTiny tglobaladdr:$dst)>, Requires<[HasSRAM, HasTinyEncoding]>; def : Pat<(i16(load(AVRWrapper tglobaladdr:$dst))), (LDSWRdK tglobaladdr:$dst)>, Requires<[HasSRAM, HasNonTinyEncoding]>; def : Pat<(store i8:$src, (i16(AVRWrapper tglobaladdr:$dst))), (STSKRr tglobaladdr:$dst, i8:$src)>, Requires<[HasSRAM, HasNonTinyEncoding]>; def : Pat<(store i8:$src, (i16(AVRWrapper tglobaladdr:$dst))), (STSKRrTiny tglobaladdr:$dst, i8:$src)>, Requires<[HasSRAM, HasTinyEncoding]>; def : Pat<(store i16:$src, (i16(AVRWrapper tglobaladdr:$dst))), (STSWKRr tglobaladdr:$dst, i16:$src)>, Requires<[HasSRAM, HasNonTinyEncoding]>; // BlockAddress def : Pat<(i16(AVRWrapper tblockaddress : $dst)), (LDIWRdK tblockaddress : $dst)>; def : Pat<(i8(trunc(AVRlsrwn DLDREGS : $src, (i16 8)))), (EXTRACT_SUBREG DREGS : $src, sub_hi)>; // :FIXME: DAGCombiner produces an shl node after legalization from these seq: // BR_JT -> (mul x, 2) -> (shl x, 1) def : Pat<(shl i16 : $src1, (i8 1)), (LSLWRd i16 : $src1)>; // Lowering of 'tst' node to 'TST' instruction. // TST is an alias of AND Rd, Rd. def : Pat<(AVRtst i8 : $rd), (ANDRdRr GPR8 : $rd, GPR8 : $rd)>; // Lowering of 'lsl' node to 'LSL' instruction. // LSL is an alias of 'ADD Rd, Rd' def : Pat<(AVRlsl i8 : $rd), (ADDRdRr GPR8 : $rd, GPR8 : $rd)>;