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llvm-mirror/lib/Target/AVR/AVRInstrInfo.td

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//===-- AVRInstrInfo.td - AVR Instruction defs -------------*- tablegen -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file describes the AVR instructions in TableGen format.
//
//===----------------------------------------------------------------------===//
include "AVRInstrFormats.td"
//===----------------------------------------------------------------------===//
// AVR Type Profiles
//===----------------------------------------------------------------------===//
Add extra operand to CALLSEQ_START to keep frame part set up previously Using arguments with attribute inalloca creates problems for verification of machine representation. This attribute instructs the backend that the argument is prepared in stack prior to CALLSEQ_START..CALLSEQ_END sequence (see http://llvm.org/docs/InAlloca.htm for details). Frame size stored in CALLSEQ_START in this case does not count the size of this argument. However CALLSEQ_END still keeps total frame size, as caller can be responsible for cleanup of entire frame. So CALLSEQ_START and CALLSEQ_END keep different frame size and the difference is treated by MachineVerifier as stack error. Currently there is no way to distinguish this case from actual errors. This patch adds additional argument to CALLSEQ_START and its target-specific counterparts to keep size of stack that is set up prior to the call frame sequence. This argument allows MachineVerifier to calculate actual frame size associated with frame setup instruction and correctly process the case of inalloca arguments. The changes made by the patch are: - Frame setup instructions get the second mandatory argument. It affects all targets that use frame pseudo instructions and touched many files although the changes are uniform. - Access to frame properties are implemented using special instructions rather than calls getOperand(N).getImm(). For X86 and ARM such replacement was made previously. - Changes that reflect appearance of additional argument of frame setup instruction. These involve proper instruction initialization and methods that access instruction arguments. - MachineVerifier retrieves frame size using method, which reports sum of frame parts initialized inside frame instruction pair and outside it. The patch implements approach proposed by Quentin Colombet in https://bugs.llvm.org/show_bug.cgi?id=27481#c1. It fixes 9 tests failed with machine verifier enabled and listed in PR27481. Differential Revision: https://reviews.llvm.org/D32394 llvm-svn: 302527
2017-05-09 15:35:13 +02:00
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 AVRretflag : SDNode<"AVRISD::RET_FLAG", SDTNone,
[SDNPHasChain, SDNPOptInGlue, SDNPVariadic]>;
def AVRretiflag : SDNode<"AVRISD::RETI_FLAG", 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>;
// 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>;
//===----------------------------------------------------------------------===//
// AVR Operands, Complex Patterns and Transformations Definitions.
//===----------------------------------------------------------------------===//
def imm8_neg_XFORM : SDNodeXForm<imm,
[{
return CurDAG->getTargetConstant(-N->getAPIntValue(), SDLoc(N), MVT::i8);
}]>;
def imm16_neg_XFORM : SDNodeXForm<imm,
[{
return CurDAG->getTargetConstant(-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()); }]>;
def ioaddr_XFORM : SDNodeXForm<imm,
[{
return CurDAG->getTargetConstant(uint8_t(N->getZExtValue()) - 0x20, SDLoc(N), MVT::i8);
}]>;
def iobitpos8_XFORM : SDNodeXForm<imm,
[{
return CurDAG->getTargetConstant(Log2_32(uint8_t(N->getZExtValue())),
SDLoc(N), MVT::i8);
}]>;
def iobitposn8_XFORM : SDNodeXForm<imm,
[{
return CurDAG->getTargetConstant(Log2_32(uint8_t(~N->getZExtValue())),
SDLoc(N), MVT::i8);
}]>;
def ioaddr8 : PatLeaf<(imm),
[{
uint64_t val = N->getZExtValue();
return val >= 0x20 && val < 0x60;
}], ioaddr_XFORM>;
def lowioaddr8 : PatLeaf<(imm),
[{
uint64_t val = N->getZExtValue();
return val >= 0x20 && val < 0x40;
}], ioaddr_XFORM>;
def ioaddr16 : PatLeaf<(imm),
[{
uint64_t val = N->getZExtValue();
return val >= 0x20 && val < 0x5f;
}], 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<iPTR>
{
let MIOperandInfo = (ops PTRDISPREGS, i16imm);
let PrintMethod = "printMemri";
let EncoderMethod = "encodeMemri";
let ParserMatchClass = MemriAsmOperand;
}
// Address operand for `SP+imm` used by STD{W}SPQRr
def memspi : Operand<iPTR>
{
let MIOperandInfo = (ops GPRSP, i16imm);
}
def imm_com8 : Operand<i8>
{
let EncoderMethod = "encodeComplement";
let MIOperandInfo = (ops i8imm);
}
def relbrtarget_7 : Operand<OtherVT>
{
let PrintMethod = "printPCRelImm";
let EncoderMethod = "encodeRelCondBrTarget<AVR::fixup_7_pcrel>";
}
def brtarget_13 : Operand<OtherVT>
{
let PrintMethod = "printPCRelImm";
let EncoderMethod = "encodeRelCondBrTarget<AVR::fixup_13_pcrel>";
}
// The target of a 22 or 16-bit call/jmp instruction.
def call_target : Operand<iPTR>
{
let EncoderMethod = "encodeCallTarget";
}
// A 16-bit address (which can lead to an R_AVR_16 relocation).
def imm16 : Operand<i16>
{
let EncoderMethod = "encodeImm<AVR::fixup_16, 2>";
}
/// A 6-bit immediate used in the ADIW/SBIW instructions.
def imm_arith6 : Operand<i16>
{
let EncoderMethod = "encodeImm<AVR::fixup_6_adiw, 0>";
}
/// An 8-bit immediate inside an instruction with the same format
/// as the `LDI` instruction (the `FRdK` format).
def imm_ldi8 : Operand<i8>
{
let EncoderMethod = "encodeImm<AVR::fixup_ldi, 0>";
}
/// A 5-bit port number used in SBIC and friends (the `FIOBIT` format).
def imm_port5 : Operand<i8>
{
let EncoderMethod = "encodeImm<AVR::fixup_port5, 0>";
}
/// A 6-bit port number used in the `IN` instruction and friends (the
/// `FIORdA` format.
def imm_port6 : Operand<i8>
{
let EncoderMethod = "encodeImm<AVR::fixup_port6, 0>";
}
// Addressing mode pattern reg+imm6
def addr : ComplexPattern<iPTR, 2, "SelectAddr", [], [SDNPWantRoot]>;
// 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<i16>
{
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<i16>
{
let MIOperandInfo = (ops PTRDISPREGS);
let EncoderMethod = "encodeLDSTPtrReg";
let ParserMatchClass = PtrRegAsmOperand;
}
//===----------------------------------------------------------------------===//
// AVR predicates for subtarget features
//===----------------------------------------------------------------------===//
def HasSRAM : Predicate<"Subtarget->hasSRAM()">,
AssemblerPredicate<"FeatureSRAM">;
def HasJMPCALL : Predicate<"Subtarget->hasJMPCALL()">,
AssemblerPredicate<"FeatureJMPCALL">;
def HasIJMPCALL : Predicate<"Subtarget->hasIJMPCALL()">,
AssemblerPredicate<"FeatureIJMPCALL">;
def HasEIJMPCALL : Predicate<"Subtarget->hasEIJMPCALL()">,
AssemblerPredicate<"FeatureEIJMPCALL">;
def HasADDSUBIW : Predicate<"Subtarget->hasADDSUBIW()">,
AssemblerPredicate<"FeatureADDSUBIW">;
def HasSmallStack : Predicate<"Subtarget->HasSmallStack()">,
AssemblerPredicate<"FeatureSmallStack">;
def HasMOVW : Predicate<"Subtarget->hasMOVW()">,
AssemblerPredicate<"FeatureMOVW">;
def HasLPM : Predicate<"Subtarget->hasLPM()">,
AssemblerPredicate<"FeatureLPM">;
def HasLPMX : Predicate<"Subtarget->hasLPMX()">,
AssemblerPredicate<"FeatureLPMX">;
def HasELPM : Predicate<"Subtarget->hasELPM()">,
AssemblerPredicate<"FeatureELPM">;
def HasELPMX : Predicate<"Subtarget->hasELPMX()">,
AssemblerPredicate<"FeatureELPMX">;
def HasSPM : Predicate<"Subtarget->hasSPM()">,
AssemblerPredicate<"FeatureSPM">;
def HasSPMX : Predicate<"Subtarget->hasSPMX()">,
AssemblerPredicate<"FeatureSPMX">;
def HasDES : Predicate<"Subtarget->hasDES()">,
AssemblerPredicate<"FeatureDES">;
def SupportsRMW : Predicate<"Subtarget->supportsRMW()">,
AssemblerPredicate<"FeatureRMW">;
def SupportsMultiplication : Predicate<"Subtarget->supportsMultiplication()">,
AssemblerPredicate<"FeatureMultiplication">;
def HasBREAK : Predicate<"Subtarget->hasBREAK()">,
AssemblerPredicate<"FeatureBREAK">;
def HasTinyEncoding : Predicate<"Subtarget->hasTinyEncoding()">,
AssemblerPredicate<"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),
Add extra operand to CALLSEQ_START to keep frame part set up previously Using arguments with attribute inalloca creates problems for verification of machine representation. This attribute instructs the backend that the argument is prepared in stack prior to CALLSEQ_START..CALLSEQ_END sequence (see http://llvm.org/docs/InAlloca.htm for details). Frame size stored in CALLSEQ_START in this case does not count the size of this argument. However CALLSEQ_END still keeps total frame size, as caller can be responsible for cleanup of entire frame. So CALLSEQ_START and CALLSEQ_END keep different frame size and the difference is treated by MachineVerifier as stack error. Currently there is no way to distinguish this case from actual errors. This patch adds additional argument to CALLSEQ_START and its target-specific counterparts to keep size of stack that is set up prior to the call frame sequence. This argument allows MachineVerifier to calculate actual frame size associated with frame setup instruction and correctly process the case of inalloca arguments. The changes made by the patch are: - Frame setup instructions get the second mandatory argument. It affects all targets that use frame pseudo instructions and touched many files although the changes are uniform. - Access to frame properties are implemented using special instructions rather than calls getOperand(N).getImm(). For X86 and ARM such replacement was made previously. - Changes that reflect appearance of additional argument of frame setup instruction. These involve proper instruction initialization and methods that access instruction arguments. - MachineVerifier retrieves frame size using method, which reports sum of frame parts initialized inside frame instruction pair and outside it. The patch implements approach proposed by Quentin Colombet in https://bugs.llvm.org/show_bug.cgi?id=27481#c1. It fixes 9 tests failed with machine verifier enabled and listed in PR27481. Differential Revision: https://reviews.llvm.org/D32394 llvm-svn: 302527
2017-05-09 15:35:13 +02:00
(ins i16imm:$amt, i16imm:$amt2),
"#ADJCALLSTACKDOWN",
Add extra operand to CALLSEQ_START to keep frame part set up previously Using arguments with attribute inalloca creates problems for verification of machine representation. This attribute instructs the backend that the argument is prepared in stack prior to CALLSEQ_START..CALLSEQ_END sequence (see http://llvm.org/docs/InAlloca.htm for details). Frame size stored in CALLSEQ_START in this case does not count the size of this argument. However CALLSEQ_END still keeps total frame size, as caller can be responsible for cleanup of entire frame. So CALLSEQ_START and CALLSEQ_END keep different frame size and the difference is treated by MachineVerifier as stack error. Currently there is no way to distinguish this case from actual errors. This patch adds additional argument to CALLSEQ_START and its target-specific counterparts to keep size of stack that is set up prior to the call frame sequence. This argument allows MachineVerifier to calculate actual frame size associated with frame setup instruction and correctly process the case of inalloca arguments. The changes made by the patch are: - Frame setup instructions get the second mandatory argument. It affects all targets that use frame pseudo instructions and touched many files although the changes are uniform. - Access to frame properties are implemented using special instructions rather than calls getOperand(N).getImm(). For X86 and ARM such replacement was made previously. - Changes that reflect appearance of additional argument of frame setup instruction. These involve proper instruction initialization and methods that access instruction arguments. - MachineVerifier retrieves frame size using method, which reports sum of frame parts initialized inside frame instruction pair and outside it. The patch implements approach proposed by Quentin Colombet in https://bugs.llvm.org/show_bug.cgi?id=27481#c1. It fixes 9 tests failed with machine verifier enabled and listed in PR27481. Differential Revision: https://reviews.llvm.org/D32394 llvm-svn: 302527
2017-05-09 15:35:13 +02:00
[(AVRcallseq_start timm:$amt, timm:$amt2)]>;
// R31R30 is used to update SP, since it is a scratch reg and this instruction
// is placed after the function call then R31R30 should be always free.
//let Defs = [R31R30],
//Uses = [R31R30] in
//:TODO: if we enable this, the pseudo is killed because it looks dead
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 = "$src = $rd",
Defs = [SREG] in
{
// SUB Rd, Rr
// Subtracts the 8-bit value of Rr from Rd and places the value in Rd.
def SUBRdRr : FRdRr<0b0001,
0b10,
(outs GPR8:$rd),
(ins GPR8:$src, GPR8:$rr),
"sub\t$rd, $rr",
[(set i8:$rd, (sub i8:$src, i8:$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:$rd),
(ins DREGS:$src, DREGS:$rr),
"subw\t$rd, $rr",
[(set i16:$rd, (sub i16:$src, i16:$rr)),
(implicit SREG)]>;
def SUBIRdK : FRdK<0b0101,
(outs LD8:$rd),
(ins LD8:$src, imm_ldi8:$k),
"subi\t$rd, $k",
[(set i8:$rd, (sub i8:$src, imm:$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:$rd),
(ins DLDREGS:$src, i16imm:$rr),
"subiw\t$rd, $rr",
[(set i16:$rd, (sub i16:$src, imm:$rr)),
(implicit SREG)]>;
def SBIWRdK : FWRdK<0b1,
(outs IWREGS:$rd),
(ins IWREGS:$src, imm_arith6:$k),
"sbiw\t$rd, $k",
[(set i16:$rd, (sub i16:$src, uimm6:$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:$rd),
(ins GPR8:$src, GPR8:$rr),
"sbc\t$rd, $rr",
[(set i8:$rd, (sube i8:$src, i8:$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:$rd),
(ins DREGS:$src, DREGS:$rr),
"sbcw\t$rd, $rr",
[(set i16:$rd, (sube i16:$src, i16:$rr)),
(implicit SREG)]>;
def SBCIRdK : FRdK<0b0100,
(outs LD8:$rd),
(ins LD8:$src, imm_ldi8:$k),
"sbci\t$rd, $k",
[(set i8:$rd, (sube i8:$src, imm:$k)),
(implicit SREG)]>;
// SBCIW Rd+1:Rd, K+1:K
// sbci Rd, K
// sbci Rd+1, K+1
def SBCIWRdK : Pseudo<(outs DLDREGS:$rd),
(ins DLDREGS:$src, i16imm:$rr),
"sbciw\t$rd, $rr",
[(set i16:$rd, (sube i16:$src, imm:$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:$src, -1)), (implicit SREG)]>;
}
//===----------------------------------------------------------------------===//
// Multiplication
//===----------------------------------------------------------------------===//
let isCommutable = 1,
Defs = [R1, R0, SREG] in
{
// MUL Rd, Rr
// Multiplies Rd by Rr and places the result into R1:R0.
let usesCustomInserter = 1 in {
def MULRdRr : FRdRr<0b1001, 0b11,
(outs),
(ins GPR8:$lhs, GPR8:$rhs),
"mul\t$lhs, $rhs",
[/*(set R1, R0, (smullohi i8:$lhs, i8:$rhs))*/]>,
Requires<[SupportsMultiplication]>;
def MULSRdRr : FMUL2RdRr<0,
(outs),
(ins GPR8:$lhs, GPR8:$rhs),
"muls\t$lhs, $rhs",
[]>,
Requires<[SupportsMultiplication]>;
}
def MULSURdRr : FMUL2RdRr<1,
(outs),
(ins GPR8:$lhs, GPR8:$rhs),
"mulsu\t$lhs, $rhs",
[]>,
Requires<[SupportsMultiplication]>;
def FMUL : FFMULRdRr<0b01,
(outs),
(ins GPR8:$lhs, GPR8:$rhs),
"fmul\t$lhs, $rhs",
[]>,
Requires<[SupportsMultiplication]>;
def FMULS : FFMULRdRr<0b10,
(outs),
(ins GPR8:$lhs, GPR8:$rhs),
"fmuls\t$lhs, $rhs",
[]>,
Requires<[SupportsMultiplication]>;
def FMULSU : FFMULRdRr<0b11,
(outs),
(ins GPR8:$lhs, GPR8:$rhs),
"fmulsu\t$lhs, $rhs",
[]>,
Requires<[SupportsMultiplication]>;
}
let Defs = [R15, R14, R13, R12, R11, R10, R9,
R8, R7, R6, R5, R4, R3, R2, R1, R0] in
def DESK : FDES<(outs),
(ins i8imm:$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:$src)), (implicit SREG)]>;
//:TODO: optimize NEG for wider types
def NEGRd : FRd<0b1001,
0b0100001,
(outs GPR8:$rd),
(ins GPR8:$src),
"neg\t$rd",
[(set i8:$rd, (ineg i8:$src)), (implicit SREG)]>;
}
// 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:$k),
/* Disable display, so we don't override ORI */ 0>;
//===----------------------------------------------------------------------===//
// Jump instructions
//===----------------------------------------------------------------------===//
let isBarrier = 1,
isBranch = 1,
isTerminator = 1 in
{
def RJMPk : FBRk<0,
(outs),
(ins brtarget_13:$target),
"rjmp\t$target",
[(br bb:$target)]>;
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 brtarget_13:$target),
"rcall\t$target",
[]>;
// 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:$k)]>,
Requires<[HasJMPCALL]>;
}
//===----------------------------------------------------------------------===//
// Return instructions.
//===----------------------------------------------------------------------===//
let isTerminator = 1,
isReturn = 1,
isBarrier = 1 in
{
def RET : F16<0b1001010100001000,
(outs),
(ins),
"ret",
[(AVRretflag)]>;
def RETI : F16<0b1001010100011000,
(outs),
(ins),
"reti",
[(AVRretiflag)]>;
}
//===----------------------------------------------------------------------===//
// Compare operations.
//===----------------------------------------------------------------------===//
let Defs = [SREG] in
{
// CPSE Rd, Rr
// Compare Rd and Rr, skipping the next instruction if they are equal.
let isBarrier = 1,
isBranch = 1,
isTerminator = 1 in
def CPSE : FRdRr<0b0001,
0b00,
(outs),
(ins GPR8:$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:$k), (implicit SREG)]>;
}
//===----------------------------------------------------------------------===//
// Register conditional skipping/branching operations.
//===----------------------------------------------------------------------===//
let isBranch = 1,
isTerminator = 1 in
{
// Conditional skipping on GPR register bits, and
// conditional skipping on IO register bits.
let isBarrier = 1 in
{
def SBRCRrB : FRdB<0b10,
(outs),
(ins GPR8:$rr, i8imm:$b),
"sbrc\t$rr, $b",
[]>;
def SBRSRrB : FRdB<0b11,
(outs),
(ins GPR8:$rr, i8imm:$b),
"sbrs\t$rr, $b",
[]>;
def SBICAb : FIOBIT<0b01,
(outs),
(ins imm_port5:$a, i8imm:$b),
"sbic\t$a, $b",
[]>;
def SBISAb : FIOBIT<0b11,
(outs),
(ins imm_port5:$a, i8imm:$b),
"sbis\t$a, $b",
[]>;
}
// Relative branches on status flag bits.
let Uses = [SREG] in
{
// BRBS s, k
// Branch if `s` flag in status register is set.
def BRBSsk : FSK<0,
(outs),
(ins i8imm:$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:$k)>;
//===----------------------------------------------------------------------===//
// PC-relative conditional branches
//===----------------------------------------------------------------------===//
// Based on status register. We cannot simplify these into instruction aliases
// because we also need to be able to specify a pattern to match for ISel.
let isBranch = 1,
isTerminator = 1,
Uses = [SREG] in
{
def BREQk : FBRsk<0,
0b001,
(outs),
(ins relbrtarget_7:$target),
"breq\t$target",
[(AVRbrcond bb:$target, AVR_COND_EQ)]>;
def BRNEk : FBRsk<1,
0b001,
(outs),
(ins relbrtarget_7:$target),
"brne\t$target",
[(AVRbrcond bb:$target, AVR_COND_NE)]>;
def BRSHk : FBRsk<1,
0b000,
(outs),
(ins relbrtarget_7:$target),
"brsh\t$target",
[(AVRbrcond bb:$target, AVR_COND_SH)]>;
def BRLOk : FBRsk<0,
0b000,
(outs),
(ins relbrtarget_7:$target),
"brlo\t$target",
[(AVRbrcond bb:$target, AVR_COND_LO)]>;
def BRMIk : FBRsk<0,
0b010,
(outs),
(ins relbrtarget_7:$target),
"brmi\t$target",
[(AVRbrcond bb:$target, AVR_COND_MI)]>;
def BRPLk : FBRsk<1,
0b010,
(outs),
(ins relbrtarget_7:$target),
"brpl\t$target",
[(AVRbrcond bb:$target, AVR_COND_PL)]>;
def BRGEk : FBRsk<1,
0b100,
(outs),
(ins relbrtarget_7:$target),
"brge\t$target",
[(AVRbrcond bb:$target, AVR_COND_GE)]>;
def BRLTk : FBRsk<0,
0b100,
(outs),
(ins relbrtarget_7:$target),
"brlt\t$target",
[(AVRbrcond bb:$target, AVR_COND_LT)]>;
}
//===----------------------------------------------------------------------===//
// Data transfer instructions
//===----------------------------------------------------------------------===//
// 8 and 16-bit register move instructions.
let hasSideEffects = 0 in
{
def MOVRdRr : FRdRr<0b0010,
0b11,
(outs GPR8:$rd),
(ins GPR8:$rr),
"mov\t$rd, $rr",
[]>;
def MOVWRdRr : FMOVWRdRr<(outs DREGS:$dst),
(ins DREGS:$src),
"movw\t$dst, $src",
[]>,
Requires<[HasMOVW]>;
}
// Load immediate values into registers.
let isReMaterializable = 1 in
{
def LDIRdK : FRdK<0b1110,
(outs LD8:$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:$k))]>,
Requires<[HasSRAM]>;
// LDSW Rd+1:Rd, K+1:K
//
// Expands to:
// lds Rd, (K+1:K)
// lds Rd+1 (K+1:K) + 1
def LDSWRdK : Pseudo<(outs DREGS:$dst),
(ins i16imm:$src),
"ldsw\t$dst, $src",
[(set i16:$dst, (load imm:$src))]>,
Requires<[HasSRAM]>;
}
// Indirect loads.
let canFoldAsLoad = 1,
isReMaterializable = 1 in
{
def LDRdPtr : FSTLD<0,
0b00,
(outs GPR8:$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+
// ld Rd+1, P
let Constraints = "@earlyclobber $reg" in
def LDWRdPtr : Pseudo<(outs DREGS:$reg),
(ins PTRREGS:$ptrreg),
"ldw\t$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
{
let Constraints = "@earlyclobber $reg" in
def LDDRdPtrQ : FSTDLDD<0,
(outs GPR8:$reg),
(ins memri:$memri),
"ldd\t$reg, $memri",
[(set i8:$reg, (load addr:$memri))]>,
Requires<[HasSRAM]>;
// LDDW Rd+1:Rd, P+q
//
// Expands to:
// ldd Rd, P+q
// ldd Rd+1, P+q+1
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, $memri",
[]>,
Requires<[HasSRAM]>;
}
class AtomicLoad<PatFrag Op, RegisterClass DRC,
RegisterClass PTRRC> :
Pseudo<(outs DRC:$rd), (ins PTRRC:$rr), "atomic_op",
[(set DRC:$rd, (Op i16:$rr))]>;
class AtomicStore<PatFrag Op, RegisterClass DRC,
RegisterClass PTRRC> :
Pseudo<(outs), (ins PTRRC:$rd, DRC:$rr), "atomic_op",
[(Op i16:$rd, DRC:$rr)]>;
class AtomicLoadOp<PatFrag Op, RegisterClass DRC,
RegisterClass PTRRC> :
Pseudo<(outs DRC:$rd), (ins PTRRC:$rr, DRC:$operand),
"atomic_op",
[(set DRC:$rd, (Op i16:$rr, DRC:$operand))]>;
// FIXME: I think 16-bit atomic binary ops need to mark
// r0 as clobbered.
// Atomic instructions
// ===================
//
// These are all expanded by AVRExpandPseudoInsts
//
// 8-bit operations can use any pointer register because
// they are expanded directly into an LD/ST instruction.
//
// 16-bit operations use 16-bit load/store postincrement instructions,
// which require PTRDISPREGS.
def AtomicLoad8 : AtomicLoad<atomic_load_8, GPR8, PTRREGS>;
def AtomicLoad16 : AtomicLoad<atomic_load_16, DREGS, PTRDISPREGS>;
def AtomicStore8 : AtomicStore<atomic_store_8, GPR8, PTRREGS>;
def AtomicStore16 : AtomicStore<atomic_store_16, DREGS, PTRDISPREGS>;
class AtomicLoadOp8<PatFrag Op> : AtomicLoadOp<Op, GPR8, PTRREGS>;
class AtomicLoadOp16<PatFrag Op> : AtomicLoadOp<Op, DREGS, PTRDISPREGS>;
def AtomicLoadAdd8 : AtomicLoadOp8<atomic_load_add_8>;
def AtomicLoadAdd16 : AtomicLoadOp16<atomic_load_add_16>;
def AtomicLoadSub8 : AtomicLoadOp8<atomic_load_sub_8>;
def AtomicLoadSub16 : AtomicLoadOp16<atomic_load_sub_16>;
def AtomicLoadAnd8 : AtomicLoadOp8<atomic_load_and_8>;
def AtomicLoadAnd16 : AtomicLoadOp16<atomic_load_and_16>;
def AtomicLoadOr8 : AtomicLoadOp8<atomic_load_or_8>;
def AtomicLoadOr16 : AtomicLoadOp16<atomic_load_or_16>;
def AtomicLoadXor8 : AtomicLoadOp8<atomic_load_xor_8>;
def AtomicLoadXor16 : AtomicLoadOp16<atomic_load_xor_16>;
def AtomicFence : Pseudo<(outs), (ins), "atomic_fence",
[(atomic_fence imm, imm)]>;
// Indirect store from register to data space.
def STSKRr : F32DM<0b1,
(outs),
(ins imm16:$k, GPR8:$rd),
"sts\t$k, $rd",
[(store i8:$rd, imm:$k)]>,
Requires<[HasSRAM]>;
// STSW K+1:K, Rr+1:Rr
//
// Expands to:
// sts Rr+1, (K+1:K) + 1
// sts Rr, (K+1:K)
def STSWKRr : Pseudo<(outs),
(ins i16imm:$dst, DREGS:$src),
"stsw\t$dst, $src",
[(store i16:$src, imm:$dst)]>,
Requires<[HasSRAM]>;
// Indirect stores.
// ST P, Rr
// Stores the value of Rr into the location addressed by pointer P.
def STPtrRr : FSTLD<1,
0b00,
(outs),
(ins LDSTPtrReg:$ptrreg, GPR8:$reg),
"st\t$ptrreg, $reg",
[(store GPR8:$reg, i16:$ptrreg)]>,
Requires<[HasSRAM]>;
// STW P, Rr+1:Rr
// Stores the value of Rr into the location addressed by pointer P.
//
// Expands to:
// st P, Rr
// std P+1, Rr+1
def STWPtrRr : Pseudo<(outs),
(ins PTRDISPREGS:$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:$memri)]>,
Requires<[HasSRAM]>;
// STDW P+q, Rr+1:Rr
// Stores the value of Rr into the location addressed by pointer P with a
// displacement of q. Does not modify P.
//
// Expands to:
// std P+q, Rr
// std P+q+1, Rr+1
def STDWPtrQRr : Pseudo<(outs),
(ins memri:$memri, DREGS:$src),
"stdw\t$memri, $src",
[(store i16:$src, addr:$memri)]>,
Requires<[HasSRAM]>;
// Load program memory operations.
let canFoldAsLoad = 1,
isReMaterializable = 1,
mayLoad = 1,
hasSideEffects = 0 in
{
let Defs = [R0],
Uses = [R31R30] in
def LPM : F16<0b1001010111001000,
(outs),
(ins),
"lpm",
[]>,
Requires<[HasLPM]>;
def LPMRdZ : FLPMX<0,
0,
(outs GPR8:$dst),
(ins ZREG:$z),
"lpm\t$dst, $z",
[]>,
Requires<[HasLPMX]>;
// Load program memory, while postincrementing the Z register.
let Defs = [R31R30] in
{
def LPMRdZPi : FLPMX<0,
1,
(outs GPR8:$dst),
(ins ZREG:$z),
"lpm\t$dst, $z+",
[]>,
Requires<[HasLPMX]>;
def LPMWRdZ : Pseudo<(outs DREGS:$dst),
(ins ZREG:$z),
"lpmw\t$dst, $z",
[]>,
Requires<[HasLPMX]>;
def LPMWRdZPi : Pseudo<(outs DREGS:$dst),
(ins ZREG:$z),
"lpmw\t$dst, $z+",
[]>,
Requires<[HasLPMX]>;
}
}
// Extended load program memory operations.
let mayLoad = 1,
hasSideEffects = 0 in
{
let Defs = [R0],
Uses = [R31R30] in
def ELPM : F16<0b1001010111011000,
(outs),
(ins),
"elpm",
[]>,
Requires<[HasELPM]>;
def ELPMRdZ : FLPMX<1,
0,
(outs GPR8:$dst),
(ins ZREG:$z),
"elpm\t$dst, $z",
[]>,
Requires<[HasELPMX]>;
let Defs = [R31R30] in
def ELPMRdZPi : FLPMX<1,
1,
(outs GPR8:$dst),
(ins ZREG: $z),
"elpm\t$dst, $z+",
[]>,
Requires<[HasELPMX]>;
}
// Store program memory operations.
let Uses = [R1, R0] in
{
let Uses = [R31R30, R1, R0] in
def SPM : F16<0b1001010111101000,
(outs),
(ins),
"spm",
[]>,
Requires<[HasSPM]>;
let Defs = [R31R30] in
def SPMZPi : F16<0b1001010111111000,
(outs),
(ins ZREG:$z),
"spm $z+",
[]>,
Requires<[HasSPMX]>;
}
// Read data from IO location operations.
let canFoldAsLoad = 1,
isReMaterializable = 1 in
{
def INRdA : FIORdA<(outs GPR8:$dst),
(ins imm_port6:$src),
"in\t$dst, $src",
[(set i8:$dst, (load ioaddr8:$src))]>;
def INWRdA : Pseudo<(outs DREGS:$dst),
(ins imm_port6:$src),
"inw\t$dst, $src",
[(set i16:$dst, (load ioaddr16:$src))]>;
}
// Write data to IO location operations.
def OUTARr : FIOARr<(outs),
(ins imm_port6:$dst, GPR8:$src),
"out\t$dst, $src",
[(store i8:$src, ioaddr8:$dst)]>;
def OUTWARr : Pseudo<(outs),
(ins imm_port6:$dst, DREGS:$src),
"outw\t$dst, $src",
[(store i16:$src, ioaddr16:$dst)]>;
// Stack push/pop operations.
let Defs = [SP],
Uses = [SP],
hasSideEffects = 0 in
{
// Stack push operations.
let mayStore = 1 in
{
def PUSHRr : FRd<0b1001,
0b0011111,
(outs),
(ins GPR8:$reg),
"push\t$reg",
[]>,
Requires<[HasSRAM]>;
def PUSHWRr : Pseudo<(outs),
(ins DREGS:$reg),
"pushw\t$reg",
[]>,
Requires<[HasSRAM]>;
}
// Stack pop operations.
let mayLoad = 1 in
{
def POPRd : FRd<0b1001,
0b0001111,
(outs GPR8:$reg),
(ins),
"pop\t$reg",
[]>,
Requires<[HasSRAM]>;
def POPWRd : Pseudo<(outs DREGS:$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 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 ASRRd : FRd<0b1001,
0b0100101,
(outs GPR8:$rd),
(ins GPR8:$src),
"asr\t$rd",
[(set i8:$rd, (AVRasr i8:$src)), (implicit SREG)]>;
def ASRWRd : Pseudo<(outs DREGS:$rd),
(ins DREGS:$src),
"asrw\t$rd",
[(set i16:$rd, (AVRasr i16:$src)), (implicit SREG)]>;
// Bit rotate operations.
let Uses = [SREG] in
{
// 8-bit ROL is an alias of ADC Rd, Rd
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",
[(set i8:$rd, (AVRror i8:$src)), (implicit SREG)]>;
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:$rd, (bswap i8:$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:$addr, i8imm:$bit),
"sbi\t$addr, $bit",
[(store (or (i8 (load lowioaddr8:$addr)), iobitpos8:$bit),
lowioaddr8:$addr)]>;
def CBIAb : FIOBIT<0b00,
(outs),
(ins imm_port5:$addr, i8imm:$bit),
"cbi\t$addr, $bit",
[(store (and (i8 (load lowioaddr8:$addr)), iobitposn8:$bit),
lowioaddr8:$addr)]>;
// Status register bit load/store operations.
let Defs = [SREG] in
def BST : FRdB<0b01,
(outs),
(ins GPR8:$rd, i8imm:$b),
"bst\t$rd, $b",
[]>;
let Uses = [SREG] in
def BLD : FRdB<0b00,
(outs),
(ins GPR8:$rd, i8imm:$b),
"bld\t$rd, $b",
[]>;
// Set/clear bit in register operations.
let Constraints = "$src = $rd",
Defs = [SREG] in
{
// CBR Rd, K
// Alias for `ANDI Rd, COM(K)` where COM(K) is the complement of K.
// FIXME: This uses the 'complement' encoder. We need it to also use the
// imm_ldi8 encoder. This will cause no fixups to be created on this instruction.
def CBRRdK : FRdK<0b0111,
(outs LD8:$rd),
(ins LD8:$src, imm_com8:$k),
"cbr\t$rd, $k",
[]>;
}
// CLR Rd
// Alias for EOR Rd, Rd
// -------------
// Clears all bits in a register.
def CLR : InstAlias<"clr\t$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 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:$cnt))]
>;
def Lsr8 : ShiftPseudo<
(outs GPR8:$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:$cnt))]
>;
def Rol8 : ShiftPseudo<
(outs GPR8:$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:$cnt))]
>;
//===----------------------------------------------------------------------===//
// Non-Instruction Patterns
//===----------------------------------------------------------------------===//
//:TODO: look in x86InstrCompiler.td for odd encoding trick related to
// add x, 128 -> sub x, -128. Clang is emitting an eor for this (ldi+eor)
// the add instruction always writes the carry flag
def : Pat<(addc i8:$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:$src2))>;
def : Pat<(add i16:$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:$src2))>;
def : Pat<(adde i16:$src1, imm:$src2),
(SBCIWRdK i16:$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:$src2))>;
// Calls.
def : Pat<(AVRcall (i16 tglobaladdr:$dst)),
(CALLk tglobaladdr:$dst)>;
def : Pat<(AVRcall (i16 texternalsym:$dst)),
(CALLk 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:$dst)>;
def : Pat<(i16 (load (AVRWrapper tglobaladdr:$dst))),
(LDSWRdK tglobaladdr:$dst)>;
def : Pat<(store i8:$src, (i16 (AVRWrapper tglobaladdr:$dst))),
(STSKRr tglobaladdr:$dst, i8:$src)>;
def : Pat<(store i16:$src, (i16 (AVRWrapper tglobaladdr:$dst))),
(STSWKRr tglobaladdr:$dst, i16:$src)>;
// BlockAddress
def : Pat<(i16 (AVRWrapper tblockaddress:$dst)),
(LDIWRdK tblockaddress:$dst)>;
// hi-reg truncation : trunc(int16 >> 8)
//:FIXME: i think it's better to emit an extract subreg node in the DAG than
// all this mess once we get optimal shift code
// lol... I think so, too. [@agnat]
def : Pat<(i8 (trunc (AVRlsr (AVRlsr (AVRlsr (AVRlsr (AVRlsr (AVRlsr (AVRlsr
(AVRlsr DREGS:$src)))))))))),
(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)>;