//===----------------------------------------------------------------------===//
+//===----------------------------------------------------------------------===//
+// Compare
+//===----------------------------------------------------------------------===//
+let hasSideEffects = 0, isCompare = 1, InputType = "imm", isExtendable = 1,
+ opExtendable = 2 in
+class T_CMP <string mnemonic, bits<2> MajOp, bit isNot, Operand ImmOp>
+ : ALU32Inst <(outs PredRegs:$dst),
+ (ins IntRegs:$src1, ImmOp:$src2),
+ "$dst = "#!if(isNot, "!","")#mnemonic#"($src1, #$src2)",
+ [], "",ALU32_2op_tc_2early_SLOT0123 >, ImmRegRel {
+ bits<2> dst;
+ bits<5> src1;
+ bits<10> src2;
+ let CextOpcode = mnemonic;
+ let opExtentBits = !if(!eq(mnemonic, "cmp.gtu"), 9, 10);
+ let isExtentSigned = !if(!eq(mnemonic, "cmp.gtu"), 0, 1);
+
+ let IClass = 0b0111;
+
+ let Inst{27-24} = 0b0101;
+ let Inst{23-22} = MajOp;
+ let Inst{21} = !if(!eq(mnemonic, "cmp.gtu"), 0, src2{9});
+ let Inst{20-16} = src1;
+ let Inst{13-5} = src2{8-0};
+ let Inst{4} = isNot;
+ let Inst{3-2} = 0b00;
+ let Inst{1-0} = dst;
+ }
+
+def C2_cmpeqi : T_CMP <"cmp.eq", 0b00, 0, s10Ext>;
+def C2_cmpgti : T_CMP <"cmp.gt", 0b01, 0, s10Ext>;
+def C2_cmpgtui : T_CMP <"cmp.gtu", 0b10, 0, u9Ext>;
+
+class T_CMP_pat <InstHexagon MI, PatFrag OpNode, PatLeaf ImmPred>
+ : Pat<(i1 (OpNode (i32 IntRegs:$src1), ImmPred:$src2)),
+ (MI IntRegs:$src1, ImmPred:$src2)>;
+
+def : T_CMP_pat <C2_cmpeqi, seteq, s10ImmPred>;
+def : T_CMP_pat <C2_cmpgti, setgt, s10ImmPred>;
+def : T_CMP_pat <C2_cmpgtui, setugt, u9ImmPred>;
+
// Multi-class for logical operators.
multiclass ALU32_rr_ri<string OpcStr, SDNode OpNode> {
def rr : ALU32_rr<(outs IntRegs:$dst), (ins IntRegs:$b, IntRegs:$c),
multiclass CMP32_rr_ri_s10<string OpcStr, string CextOp, PatFrag OpNode> {
let CextOpcode = CextOp in {
- let InputType = "reg" in
- def rr : ALU32_rr<(outs PredRegs:$dst), (ins IntRegs:$b, IntRegs:$c),
- !strconcat("$dst = ", !strconcat(OpcStr, "($b, $c)")),
- [(set (i1 PredRegs:$dst),
- (OpNode (i32 IntRegs:$b), (i32 IntRegs:$c)))]>;
-
let isExtendable = 1, opExtendable = 2, isExtentSigned = 1,
opExtentBits = 10, InputType = "imm" in
def ri : ALU32_ri<(outs PredRegs:$dst), (ins IntRegs:$b, s10Ext:$c),
multiclass CMP32_rr_ri_u9<string OpcStr, string CextOp, PatFrag OpNode> {
let CextOpcode = CextOp in {
- let InputType = "reg" in
- def rr : ALU32_rr<(outs PredRegs:$dst), (ins IntRegs:$b, IntRegs:$c),
- !strconcat("$dst = ", !strconcat(OpcStr, "($b, $c)")),
- [(set (i1 PredRegs:$dst),
- (OpNode (i32 IntRegs:$b), (i32 IntRegs:$c)))]>;
-
let isExtendable = 1, opExtendable = 2, isExtentSigned = 0,
opExtentBits = 9, InputType = "imm" in
def ri : ALU32_ri<(outs PredRegs:$dst), (ins IntRegs:$b, u9Ext:$c),
def HexagonWrapperCombineRR :
SDNode<"HexagonISD::WrapperCombineRR", SDTHexagonI64I32I32>;
+let hasSideEffects = 0, hasNewValue = 1, InputType = "reg" in
+class T_ALU32_3op<string mnemonic, bits<3> MajOp, bits<3> MinOp, bit OpsRev,
+ bit IsComm>
+ : ALU32_rr<(outs IntRegs:$Rd), (ins IntRegs:$Rs, IntRegs:$Rt),
+ "$Rd = "#mnemonic#"($Rs, $Rt)",
+ [], "", ALU32_3op_tc_1_SLOT0123>, ImmRegRel, PredRel {
+ let isCommutable = IsComm;
+ let BaseOpcode = mnemonic#_rr;
+ let CextOpcode = mnemonic;
+
+ bits<5> Rs;
+ bits<5> Rt;
+ bits<5> Rd;
+
+ let IClass = 0b1111;
+ let Inst{27} = 0b0;
+ let Inst{26-24} = MajOp;
+ let Inst{23-21} = MinOp;
+ let Inst{20-16} = !if(OpsRev,Rt,Rs);
+ let Inst{12-8} = !if(OpsRev,Rs,Rt);
+ let Inst{4-0} = Rd;
+}
+
+let hasSideEffects = 0, hasNewValue = 1 in
+class T_ALU32_3op_pred<string mnemonic, bits<3> MajOp, bits<3> MinOp,
+ bit OpsRev, bit PredNot, bit PredNew>
+ : ALU32_rr<(outs IntRegs:$Rd), (ins PredRegs:$Pu, IntRegs:$Rs, IntRegs:$Rt),
+ "if ("#!if(PredNot,"!","")#"$Pu"#!if(PredNew,".new","")#") "#
+ "$Rd = "#mnemonic#"($Rs, $Rt)",
+ [], "", ALU32_3op_tc_1_SLOT0123>, ImmRegRel, PredNewRel {
+ let isPredicated = 1;
+ let isPredicatedFalse = PredNot;
+ let isPredicatedNew = PredNew;
+ let BaseOpcode = mnemonic#_rr;
+ let CextOpcode = mnemonic;
+
+ bits<2> Pu;
+ bits<5> Rs;
+ bits<5> Rt;
+ bits<5> Rd;
+
+ let IClass = 0b1111;
+ let Inst{27} = 0b1;
+ let Inst{26-24} = MajOp;
+ let Inst{23-21} = MinOp;
+ let Inst{20-16} = !if(OpsRev,Rt,Rs);
+ let Inst{13} = PredNew;
+ let Inst{12-8} = !if(OpsRev,Rs,Rt);
+ let Inst{7} = PredNot;
+ let Inst{6-5} = Pu;
+ let Inst{4-0} = Rd;
+}
+
+multiclass T_ALU32_3op_p<string mnemonic, bits<3> MajOp, bits<3> MinOp,
+ bit OpsRev> {
+ def t : T_ALU32_3op_pred<mnemonic, MajOp, MinOp, OpsRev, 0, 0>;
+ def f : T_ALU32_3op_pred<mnemonic, MajOp, MinOp, OpsRev, 1, 0>;
+ def tnew : T_ALU32_3op_pred<mnemonic, MajOp, MinOp, OpsRev, 0, 1>;
+ def fnew : T_ALU32_3op_pred<mnemonic, MajOp, MinOp, OpsRev, 1, 1>;
+}
+
+multiclass T_ALU32_3op_A2<string mnemonic, bits<3> MajOp, bits<3> MinOp,
+ bit OpsRev, bit IsComm> {
+ let isPredicable = 1 in
+ def A2_#NAME : T_ALU32_3op <mnemonic, MajOp, MinOp, OpsRev, IsComm>;
+ defm A2_p#NAME : T_ALU32_3op_p<mnemonic, MajOp, MinOp, OpsRev>;
+}
+
+let isCodeGenOnly = 0 in
+defm add : T_ALU32_3op_A2<"add", 0b011, 0b000, 0, 1>;
+defm and : T_ALU32_3op_A2<"and", 0b001, 0b000, 0, 1>;
+defm or : T_ALU32_3op_A2<"or", 0b001, 0b001, 0, 1>;
+defm sub : T_ALU32_3op_A2<"sub", 0b011, 0b001, 1, 0>;
+defm xor : T_ALU32_3op_A2<"xor", 0b001, 0b011, 0, 1>;
+
+// Pats for instruction selection.
+class BinOp32_pat<SDNode Op, InstHexagon MI, ValueType ResT>
+ : Pat<(ResT (Op (i32 IntRegs:$Rs), (i32 IntRegs:$Rt))),
+ (ResT (MI IntRegs:$Rs, IntRegs:$Rt))>;
+
+def: BinOp32_pat<add, A2_add, i32>;
+def: BinOp32_pat<and, A2_and, i32>;
+def: BinOp32_pat<or, A2_or, i32>;
+def: BinOp32_pat<sub, A2_sub, i32>;
+def: BinOp32_pat<xor, A2_xor, i32>;
+
multiclass ALU32_Pbase<string mnemonic, RegisterClass RC, bit isNot,
bit isPredNew> {
let isPredicatedNew = isPredNew in
}
}
-let InputType = "reg" in
-multiclass ALU32_base<string mnemonic, string CextOp, SDNode OpNode> {
- let CextOpcode = CextOp, BaseOpcode = CextOp#_rr in {
- let isPredicable = 1 in
- def NAME : ALU32_rr<(outs IntRegs:$dst),
- (ins IntRegs:$src1, IntRegs:$src2),
- "$dst = "#mnemonic#"($src1, $src2)",
- [(set (i32 IntRegs:$dst), (OpNode (i32 IntRegs:$src1),
- (i32 IntRegs:$src2)))]>;
+//===----------------------------------------------------------------------===//
+// template class for non-predicated alu32_2op instructions
+// - aslh, asrh, sxtb, sxth, zxth
+//===----------------------------------------------------------------------===//
+let hasNewValue = 1, opNewValue = 0 in
+class T_ALU32_2op <string mnemonic, bits<3> minOp> :
+ ALU32Inst < (outs IntRegs:$Rd), (ins IntRegs:$Rs),
+ "$Rd = "#mnemonic#"($Rs)", [] > {
+ bits<5> Rd;
+ bits<5> Rs;
- let neverHasSideEffects = 1, isPredicated = 1 in {
- defm Pt : ALU32_Pred<mnemonic, IntRegs, 0>;
- defm NotPt : ALU32_Pred<mnemonic, IntRegs, 1>;
+ let IClass = 0b0111;
+
+ let Inst{27-24} = 0b0000;
+ let Inst{23-21} = minOp;
+ let Inst{13} = 0b0;
+ let Inst{4-0} = Rd;
+ let Inst{20-16} = Rs;
+}
+
+//===----------------------------------------------------------------------===//
+// template class for predicated alu32_2op instructions
+// - aslh, asrh, sxtb, sxth, zxtb, zxth
+//===----------------------------------------------------------------------===//
+let hasSideEffects = 0, validSubTargets = HasV4SubT,
+ hasNewValue = 1, opNewValue = 0 in
+class T_ALU32_2op_Pred <string mnemonic, bits<3> minOp, bit isPredNot,
+ bit isPredNew > :
+ ALU32Inst <(outs IntRegs:$Rd), (ins PredRegs:$Pu, IntRegs:$Rs),
+ !if(isPredNot, "if (!$Pu", "if ($Pu")
+ #!if(isPredNew, ".new) ",") ")#"$Rd = "#mnemonic#"($Rs)"> {
+ bits<5> Rd;
+ bits<2> Pu;
+ bits<5> Rs;
+
+ let IClass = 0b0111;
+
+ let Inst{27-24} = 0b0000;
+ let Inst{23-21} = minOp;
+ let Inst{13} = 0b1;
+ let Inst{11} = isPredNot;
+ let Inst{10} = isPredNew;
+ let Inst{4-0} = Rd;
+ let Inst{9-8} = Pu;
+ let Inst{20-16} = Rs;
+}
+
+multiclass ALU32_2op_Pred<string mnemonic, bits<3> minOp, bit PredNot> {
+ let isPredicatedFalse = PredNot in {
+ def NAME : T_ALU32_2op_Pred<mnemonic, minOp, PredNot, 0>;
+
+ // Predicate new
+ let isPredicatedNew = 1 in
+ def NAME#new : T_ALU32_2op_Pred<mnemonic, minOp, PredNot, 1>;
+ }
+}
+
+multiclass ALU32_2op_base<string mnemonic, bits<3> minOp> {
+ let BaseOpcode = mnemonic in {
+ let isPredicable = 1, hasSideEffects = 0 in
+ def A2_#NAME : T_ALU32_2op<mnemonic, minOp>;
+
+ let validSubTargets = HasV4SubT, isPredicated = 1, hasSideEffects = 0 in {
+ defm A4_p#NAME#t : ALU32_2op_Pred<mnemonic, minOp, 0>;
+ defm A4_p#NAME#f : ALU32_2op_Pred<mnemonic, minOp, 1>;
+ }
+ }
+}
+
+defm aslh : ALU32_2op_base<"aslh", 0b000>, PredNewRel;
+defm asrh : ALU32_2op_base<"asrh", 0b001>, PredNewRel;
+defm sxtb : ALU32_2op_base<"sxtb", 0b101>, PredNewRel;
+defm sxth : ALU32_2op_base<"sxth", 0b111>, PredNewRel;
+defm zxth : ALU32_2op_base<"zxth", 0b110>, PredNewRel;
+
+// Rd=zxtb(Rs): assembler mapped to Rd=and(Rs,#255).
+// Compiler would want to generate 'zxtb' instead of 'and' becuase 'zxtb' has
+// predicated forms while 'and' doesn't. Since integrated assembler can't
+// handle 'mapped' instructions, we need to encode 'zxtb' same as 'and' where
+// immediate operand is set to '255'.
+
+let hasNewValue = 1, opNewValue = 0 in
+class T_ZXTB: ALU32Inst < (outs IntRegs:$Rd), (ins IntRegs:$Rs),
+ "$Rd = zxtb($Rs)", [] > { // Rd = and(Rs,255)
+ bits<5> Rd;
+ bits<5> Rs;
+ bits<10> s10 = 255;
+
+ let IClass = 0b0111;
+
+ let Inst{27-22} = 0b011000;
+ let Inst{4-0} = Rd;
+ let Inst{20-16} = Rs;
+ let Inst{21} = s10{9};
+ let Inst{13-5} = s10{8-0};
+}
+
+//Rd=zxtb(Rs): assembler mapped to "Rd=and(Rs,#255)
+multiclass ZXTB_base <string mnemonic, bits<3> minOp> {
+ let BaseOpcode = mnemonic in {
+ let isPredicable = 1, hasSideEffects = 0 in
+ def A2_#NAME : T_ZXTB;
+
+ let validSubTargets = HasV4SubT, isPredicated = 1, hasSideEffects = 0 in {
+ defm A4_p#NAME#t : ALU32_2op_Pred<mnemonic, minOp, 0>;
+ defm A4_p#NAME#f : ALU32_2op_Pred<mnemonic, minOp, 1>;
}
}
}
-let isCommutable = 1 in {
- defm ADD_rr : ALU32_base<"add", "ADD", add>, ImmRegRel, PredNewRel;
- defm AND_rr : ALU32_base<"and", "AND", and>, ImmRegRel, PredNewRel;
- defm XOR_rr : ALU32_base<"xor", "XOR", xor>, ImmRegRel, PredNewRel;
- defm OR_rr : ALU32_base<"or", "OR", or>, ImmRegRel, PredNewRel;
+defm zxtb : ZXTB_base<"zxtb",0b100>, PredNewRel;
+
+let CextOpcode = "MUX", InputType = "reg", hasNewValue = 1 in
+def C2_mux: ALU32_rr<(outs IntRegs:$Rd),
+ (ins PredRegs:$Pu, IntRegs:$Rs, IntRegs:$Rt),
+ "$Rd = mux($Pu, $Rs, $Rt)", [], "", ALU32_3op_tc_1_SLOT0123>, ImmRegRel {
+ bits<5> Rd;
+ bits<2> Pu;
+ bits<5> Rs;
+ bits<5> Rt;
+
+ let CextOpcode = "mux";
+ let InputType = "reg";
+ let hasSideEffects = 0;
+ let IClass = 0b1111;
+
+ let Inst{27-24} = 0b0100;
+ let Inst{20-16} = Rs;
+ let Inst{12-8} = Rt;
+ let Inst{6-5} = Pu;
+ let Inst{4-0} = Rd;
}
-defm SUB_rr : ALU32_base<"sub", "SUB", sub>, ImmRegRel, PredNewRel;
+def: Pat<(i32 (select (i1 PredRegs:$Pu), (i32 IntRegs:$Rs), (i32 IntRegs:$Rt))),
+ (C2_mux PredRegs:$Pu, IntRegs:$Rs, IntRegs:$Rt)>;
// Combines the two integer registers SRC1 and SRC2 into a double register.
let isPredicable = 1 in
s10ExtPred:$src2))]>, ImmRegRel;
// Nop.
-let neverHasSideEffects = 1 in
-def NOP : ALU32_rr<(outs), (ins),
- "nop",
- []>;
+let hasSideEffects = 0 in
+def A2_nop: ALU32Inst <(outs), (ins), "nop" > {
+ let IClass = 0b0111;
+ let Inst{27-24} = 0b1111;
+}
// Rd32=sub(#s10,Rs32)
let isExtendable = 1, opExtendable = 1, isExtentSigned = 1, opExtentBits = 10,
// ALU32/PERM +
//===----------------------------------------------------------------------===//
+let neverHasSideEffects = 1 in
+def COMBINE_ii : ALU32_ii<(outs DoubleRegs:$dst),
+ (ins s8Imm:$src1, s8Imm:$src2),
+ "$dst = combine(#$src1, #$src2)",
+ []>;
+
// Mux.
def VMUX_prr64 : ALU64_rr<(outs DoubleRegs:$dst), (ins PredRegs:$src1,
DoubleRegs:$src2,
"$dst = vmux($src1, $src2, $src3)",
[]>;
-let CextOpcode = "MUX", InputType = "reg" in
-def MUX_rr : ALU32_rr<(outs IntRegs:$dst), (ins PredRegs:$src1,
- IntRegs:$src2, IntRegs:$src3),
- "$dst = mux($src1, $src2, $src3)",
- [(set (i32 IntRegs:$dst),
- (i32 (select (i1 PredRegs:$src1), (i32 IntRegs:$src2),
- (i32 IntRegs:$src3))))]>, ImmRegRel;
-
let isExtendable = 1, opExtendable = 2, isExtentSigned = 1, opExtentBits = 8,
CextOpcode = "MUX", InputType = "imm" in
def MUX_ir : ALU32_ir<(outs IntRegs:$dst), (ins PredRegs:$src1, s8Ext:$src2,
s8ExtPred:$src2,
s8ImmPred:$src3)))]>;
-// ALU32 - aslh, asrh, sxtb, sxth, zxtb, zxth
-multiclass ALU32_2op_Pbase<string mnemonic, bit isNot, bit isPredNew> {
- let isPredicatedNew = isPredNew in
- def NAME : ALU32Inst<(outs IntRegs:$dst),
- (ins PredRegs:$src1, IntRegs:$src2),
- !if(isNot, "if (!$src1", "if ($src1")#!if(isPredNew,".new) $dst = ",
- ") $dst = ")#mnemonic#"($src2)">,
- Requires<[HasV4T]>;
-}
-
-multiclass ALU32_2op_Pred<string mnemonic, bit PredNot> {
- let isPredicatedFalse = PredNot in {
- defm _c#NAME : ALU32_2op_Pbase<mnemonic, PredNot, 0>;
- // Predicate new
- defm _cdn#NAME : ALU32_2op_Pbase<mnemonic, PredNot, 1>;
- }
-}
-
-multiclass ALU32_2op_base<string mnemonic> {
- let BaseOpcode = mnemonic in {
- let isPredicable = 1, neverHasSideEffects = 1 in
- def NAME : ALU32Inst<(outs IntRegs:$dst),
- (ins IntRegs:$src1),
- "$dst = "#mnemonic#"($src1)">;
-
- let Predicates = [HasV4T], validSubTargets = HasV4SubT, isPredicated = 1,
- neverHasSideEffects = 1 in {
- defm Pt_V4 : ALU32_2op_Pred<mnemonic, 0>;
- defm NotPt_V4 : ALU32_2op_Pred<mnemonic, 1>;
- }
- }
-}
-
-defm ASLH : ALU32_2op_base<"aslh">, PredNewRel;
-defm ASRH : ALU32_2op_base<"asrh">, PredNewRel;
-defm SXTB : ALU32_2op_base<"sxtb">, PredNewRel;
-defm SXTH : ALU32_2op_base<"sxth">, PredNewRel;
-defm ZXTB : ALU32_2op_base<"zxtb">, PredNewRel;
-defm ZXTH : ALU32_2op_base<"zxth">, PredNewRel;
-
def : Pat <(shl (i32 IntRegs:$src1), (i32 16)),
- (ASLH IntRegs:$src1)>;
+ (A2_aslh IntRegs:$src1)>;
def : Pat <(sra (i32 IntRegs:$src1), (i32 16)),
- (ASRH IntRegs:$src1)>;
+ (A2_asrh IntRegs:$src1)>;
def : Pat <(sext_inreg (i32 IntRegs:$src1), i8),
- (SXTB IntRegs:$src1)>;
+ (A2_sxtb IntRegs:$src1)>;
def : Pat <(sext_inreg (i32 IntRegs:$src1), i16),
- (SXTH IntRegs:$src1)>;
+ (A2_sxth IntRegs:$src1)>;
//===----------------------------------------------------------------------===//
// ALU32/PERM -
// ALU32/PRED +
//===----------------------------------------------------------------------===//
+
+let hasSideEffects = 0, hasNewValue = 1, isCompare = 1, InputType = "reg" in
+class T_ALU32_3op_cmp<string mnemonic, bits<2> MinOp, bit IsNeg, bit IsComm>
+ : ALU32_rr<(outs PredRegs:$Pd), (ins IntRegs:$Rs, IntRegs:$Rt),
+ "$Pd = "#mnemonic#"($Rs, $Rt)",
+ [], "", ALU32_3op_tc_1_SLOT0123>, ImmRegRel {
+ let CextOpcode = mnemonic;
+ let isCommutable = IsComm;
+ bits<5> Rs;
+ bits<5> Rt;
+ bits<2> Pd;
+
+ let IClass = 0b1111;
+ let Inst{27-24} = 0b0010;
+ let Inst{22-21} = MinOp;
+ let Inst{20-16} = Rs;
+ let Inst{12-8} = Rt;
+ let Inst{4} = IsNeg;
+ let Inst{3-2} = 0b00;
+ let Inst{1-0} = Pd;
+}
+
+let Itinerary = ALU32_3op_tc_2early_SLOT0123 in {
+ def C2_cmpeq : T_ALU32_3op_cmp< "cmp.eq", 0b00, 0, 1>;
+ def C2_cmpgt : T_ALU32_3op_cmp< "cmp.gt", 0b10, 0, 0>;
+ def C2_cmpgtu : T_ALU32_3op_cmp< "cmp.gtu", 0b11, 0, 0>;
+}
+
+// Patfrag to convert the usual comparison patfrags (e.g. setlt) to ones
+// that reverse the order of the operands.
+class RevCmp<PatFrag F> : PatFrag<(ops node:$rhs, node:$lhs), F.Fragment>;
+
+// Pats for compares. They use PatFrags as operands, not SDNodes,
+// since seteq/setgt/etc. are defined as ParFrags.
+class T_cmp32_rr_pat<InstHexagon MI, PatFrag Op, ValueType VT>
+ : Pat<(VT (Op (i32 IntRegs:$Rs), (i32 IntRegs:$Rt))),
+ (VT (MI IntRegs:$Rs, IntRegs:$Rt))>;
+
+def: T_cmp32_rr_pat<C2_cmpeq, seteq, i1>;
+def: T_cmp32_rr_pat<C2_cmpgt, setgt, i1>;
+def: T_cmp32_rr_pat<C2_cmpgtu, setugt, i1>;
+
+def: T_cmp32_rr_pat<C2_cmpgt, RevCmp<setlt>, i1>;
+def: T_cmp32_rr_pat<C2_cmpgtu, RevCmp<setult>, i1>;
+
// Compare.
defm CMPGTU : CMP32_rr_ri_u9<"cmp.gtu", "CMPGTU", setugt>, ImmRegRel;
defm CMPGT : CMP32_rr_ri_s10<"cmp.gt", "CMPGT", setgt>, ImmRegRel;
// CR -
//===----------------------------------------------------------------------===//
+def retflag : SDNode<"HexagonISD::RET_FLAG", SDTNone,
+ [SDNPHasChain, SDNPOptInGlue, SDNPVariadic]>;
+def eh_return: SDNode<"HexagonISD::EH_RETURN", SDTNone,
+ [SDNPHasChain]>;
-//===----------------------------------------------------------------------===//
-// J +
-//===----------------------------------------------------------------------===//
-// Jump to address.
-let isBranch = 1, isTerminator=1, isBarrier = 1, isPredicable = 1 in {
- def JMP : JInst< (outs),
- (ins brtarget:$offset),
- "jump $offset",
- [(br bb:$offset)]>;
-}
+def SDHexagonBR_JT: SDTypeProfile<0, 1, [SDTCisVT<0, i32>]>;
+def HexagonBR_JT: SDNode<"HexagonISD::BR_JT", SDHexagonBR_JT, [SDNPHasChain]>;
-// if (p0) jump
-let isBranch = 1, isTerminator=1, Defs = [PC],
- isPredicated = 1 in {
- def JMP_c : JInst< (outs),
- (ins PredRegs:$src, brtarget:$offset),
- "if ($src) jump $offset",
- [(brcond (i1 PredRegs:$src), bb:$offset)]>;
-}
+let InputType = "imm", isBarrier = 1, isPredicable = 1,
+Defs = [PC], isExtendable = 1, opExtendable = 0, isExtentSigned = 1,
+opExtentBits = 24, isCodeGenOnly = 0 in
+class T_JMP <dag InsDag, list<dag> JumpList = []>
+ : JInst<(outs), InsDag,
+ "jump $dst" , JumpList> {
+ bits<24> dst;
+
+ let IClass = 0b0101;
+
+ let Inst{27-25} = 0b100;
+ let Inst{24-16} = dst{23-15};
+ let Inst{13-1} = dst{14-2};
+}
+
+let InputType = "imm", isExtendable = 1, opExtendable = 1, isExtentSigned = 1,
+Defs = [PC], isPredicated = 1, opExtentBits = 17 in
+class T_JMP_c <bit PredNot, bit isPredNew, bit isTak>:
+ JInst<(outs ), (ins PredRegs:$src, brtarget:$dst),
+ !if(PredNot, "if (!$src", "if ($src")#
+ !if(isPredNew, ".new) ", ") ")#"jump"#
+ !if(isPredNew, !if(isTak, ":t ", ":nt "), " ")#"$dst"> {
+
+ let isTaken = isTak;
+ let isBrTaken = !if(isPredNew, !if(isTaken, "true", "false"), "");
+ let isPredicatedFalse = PredNot;
+ let isPredicatedNew = isPredNew;
+ bits<2> src;
+ bits<17> dst;
+
+ let IClass = 0b0101;
+
+ let Inst{27-24} = 0b1100;
+ let Inst{21} = PredNot;
+ let Inst{12} = !if(isPredNew, isTak, zero);
+ let Inst{11} = isPredNew;
+ let Inst{9-8} = src;
+ let Inst{23-22} = dst{16-15};
+ let Inst{20-16} = dst{14-10};
+ let Inst{13} = dst{9};
+ let Inst{7-1} = dst{8-2};
+ }
-// if (!p0) jump
-let isBranch = 1, isTerminator=1, neverHasSideEffects = 1, Defs = [PC],
- isPredicated = 1 in {
- def JMP_cNot : JInst< (outs),
- (ins PredRegs:$src, brtarget:$offset),
- "if (!$src) jump $offset",
- []>;
+let isBarrier = 1, Defs = [PC], isPredicable = 1, InputType = "reg" in
+class T_JMPr<dag InsDag = (ins IntRegs:$dst)>
+ : JRInst<(outs ), InsDag,
+ "jumpr $dst" ,
+ []> {
+ bits<5> dst;
+
+ let IClass = 0b0101;
+ let Inst{27-21} = 0b0010100;
+ let Inst{20-16} = dst;
}
-let isTerminator = 1, isBranch = 1, neverHasSideEffects = 1, Defs = [PC],
- isPredicated = 1 in {
- def BRCOND : JInst < (outs), (ins PredRegs:$pred, brtarget:$dst),
- "if ($pred) jump $dst",
- []>;
+let Defs = [PC], isPredicated = 1, InputType = "reg" in
+class T_JMPr_c <bit PredNot, bit isPredNew, bit isTak>:
+ JRInst <(outs ), (ins PredRegs:$src, IntRegs:$dst),
+ !if(PredNot, "if (!$src", "if ($src")#
+ !if(isPredNew, ".new) ", ") ")#"jumpr"#
+ !if(isPredNew, !if(isTak, ":t ", ":nt "), " ")#"$dst"> {
+
+ let isTaken = isTak;
+ let isBrTaken = !if(isPredNew, !if(isTaken, "true", "false"), "");
+ let isPredicatedFalse = PredNot;
+ let isPredicatedNew = isPredNew;
+ bits<2> src;
+ bits<5> dst;
+
+ let IClass = 0b0101;
+
+ let Inst{27-22} = 0b001101;
+ let Inst{21} = PredNot;
+ let Inst{20-16} = dst;
+ let Inst{12} = !if(isPredNew, isTak, zero);
+ let Inst{11} = isPredNew;
+ let Inst{9-8} = src;
+ let Predicates = !if(isPredNew, [HasV3T], [HasV2T]);
+ let validSubTargets = !if(isPredNew, HasV3SubT, HasV2SubT);
}
-// Jump to address conditioned on new predicate.
-// if (p0) jump:t
-let isBranch = 1, isTerminator=1, neverHasSideEffects = 1, Defs = [PC],
- isPredicated = 1 in {
- def JMP_cdnPt : JInst< (outs),
- (ins PredRegs:$src, brtarget:$offset),
- "if ($src.new) jump:t $offset",
- []>;
+multiclass JMP_Pred<bit PredNot> {
+ def _#NAME : T_JMP_c<PredNot, 0, 0>;
+ // Predicate new
+ def _#NAME#new_t : T_JMP_c<PredNot, 1, 1>; // taken
+ def _#NAME#new_nt : T_JMP_c<PredNot, 1, 0>; // not taken
}
-// if (!p0) jump:t
-let isBranch = 1, isTerminator=1, neverHasSideEffects = 1, Defs = [PC],
- isPredicated = 1 in {
- def JMP_cdnNotPt : JInst< (outs),
- (ins PredRegs:$src, brtarget:$offset),
- "if (!$src.new) jump:t $offset",
- []>;
+multiclass JMP_base<string BaseOp> {
+ let BaseOpcode = BaseOp in {
+ def NAME : T_JMP<(ins brtarget:$dst), [(br bb:$dst)]>;
+ defm t : JMP_Pred<0>;
+ defm f : JMP_Pred<1>;
+ }
}
-// Not taken.
-let isBranch = 1, isTerminator=1, neverHasSideEffects = 1, Defs = [PC],
- isPredicated = 1 in {
- def JMP_cdnPnt : JInst< (outs),
- (ins PredRegs:$src, brtarget:$offset),
- "if ($src.new) jump:nt $offset",
- []>;
+multiclass JMPR_Pred<bit PredNot> {
+ def NAME: T_JMPr_c<PredNot, 0, 0>;
+ // Predicate new
+ def NAME#new_tV3 : T_JMPr_c<PredNot, 1, 1>; // taken
+ def NAME#new_ntV3 : T_JMPr_c<PredNot, 1, 0>; // not taken
}
-// Not taken.
-let isBranch = 1, isTerminator=1, neverHasSideEffects = 1, Defs = [PC],
- isPredicated = 1 in {
- def JMP_cdnNotPnt : JInst< (outs),
- (ins PredRegs:$src, brtarget:$offset),
- "if (!$src.new) jump:nt $offset",
- []>;
+multiclass JMPR_base<string BaseOp> {
+ let BaseOpcode = BaseOp in {
+ def NAME : T_JMPr;
+ defm _t : JMPR_Pred<0>;
+ defm _f : JMPR_Pred<1>;
+ }
}
-//===----------------------------------------------------------------------===//
-// J -
-//===----------------------------------------------------------------------===//
-//===----------------------------------------------------------------------===//
-// JR +
-//===----------------------------------------------------------------------===//
-def retflag : SDNode<"HexagonISD::RET_FLAG", SDTNone,
- [SDNPHasChain, SDNPOptInGlue, SDNPVariadic]>;
+let isTerminator = 1, neverHasSideEffects = 1 in {
+let isBranch = 1 in
+defm JMP : JMP_base<"JMP">, PredNewRel;
-// Jump to address from register.
-let isPredicable =1, isReturn = 1, isTerminator = 1, isBarrier = 1,
- Defs = [PC], Uses = [R31] in {
- def JMPR: JRInst<(outs), (ins),
- "jumpr r31",
- [(retflag)]>;
-}
+let isBranch = 1, isIndirectBranch = 1 in
+defm JMPR : JMPR_base<"JMPr">, PredNewRel;
-// Jump to address from register.
-let isReturn = 1, isTerminator = 1, isBarrier = 1, isPredicated = 1,
- Defs = [PC], Uses = [R31] in {
- def JMPR_cPt: JRInst<(outs), (ins PredRegs:$src1),
- "if ($src1) jumpr r31",
- []>;
+let isReturn = 1, isCodeGenOnly = 1 in
+defm JMPret : JMPR_base<"JMPret">, PredNewRel;
}
-// Jump to address from register.
-let isReturn = 1, isTerminator = 1, isBarrier = 1, isPredicated = 1,
- Defs = [PC], Uses = [R31] in {
- def JMPR_cNotPt: JRInst<(outs), (ins PredRegs:$src1),
- "if (!$src1) jumpr r31",
- []>;
-}
+def : Pat<(retflag),
+ (JMPret (i32 R31))>;
+
+def : Pat <(brcond (i1 PredRegs:$src1), bb:$offset),
+ (JMP_t (i1 PredRegs:$src1), bb:$offset)>;
+
+// A return through builtin_eh_return.
+let isReturn = 1, isTerminator = 1, isBarrier = 1, neverHasSideEffects = 1,
+isCodeGenOnly = 1, Defs = [PC], Uses = [R28], isPredicable = 0 in
+def EH_RETURN_JMPR : T_JMPr;
+
+def : Pat<(eh_return),
+ (EH_RETURN_JMPR (i32 R31))>;
+
+def : Pat<(HexagonBR_JT (i32 IntRegs:$dst)),
+ (JMPR (i32 IntRegs:$dst))>;
+
+def : Pat<(brind (i32 IntRegs:$dst)),
+ (JMPR (i32 IntRegs:$dst))>;
//===----------------------------------------------------------------------===//
// JR -
}
let addrMode = BaseImmOffset, isMEMri = "true" in {
- defm LDrib: LD_MEMri < "memb", "LDrib", IntRegs, 11, 6>, AddrModeRel;
- defm LDriub: LD_MEMri < "memub" , "LDriub", IntRegs, 11, 6>, AddrModeRel;
- defm LDrih: LD_MEMri < "memh", "LDrih", IntRegs, 12, 7>, AddrModeRel;
- defm LDriuh: LD_MEMri < "memuh", "LDriuh", IntRegs, 12, 7>, AddrModeRel;
- defm LDriw: LD_MEMri < "memw", "LDriw", IntRegs, 13, 8>, AddrModeRel;
- defm LDrid: LD_MEMri < "memd", "LDrid", DoubleRegs, 14, 9>, AddrModeRel;
+ let accessSize = ByteAccess in {
+ defm LDrib: LD_MEMri < "memb", "LDrib", IntRegs, 11, 6>, AddrModeRel;
+ defm LDriub: LD_MEMri < "memub" , "LDriub", IntRegs, 11, 6>, AddrModeRel;
+ }
+
+ let accessSize = HalfWordAccess in {
+ defm LDrih: LD_MEMri < "memh", "LDrih", IntRegs, 12, 7>, AddrModeRel;
+ defm LDriuh: LD_MEMri < "memuh", "LDriuh", IntRegs, 12, 7>, AddrModeRel;
+ }
+
+ let accessSize = WordAccess in
+ defm LDriw: LD_MEMri < "memw", "LDriw", IntRegs, 13, 8>, AddrModeRel;
+
+ let accessSize = DoubleWordAccess in
+ defm LDrid: LD_MEMri < "memd", "LDrid", DoubleRegs, 14, 9>, AddrModeRel;
}
def : Pat < (i32 (sextloadi8 ADDRriS11_0:$addr)),
}
let addrMode = BaseImmOffset in {
- defm LDrib_indexed: LD_Idxd <"memb", "LDrib", IntRegs, s11_0Ext, u6_0Ext,
- 11, 6>, AddrModeRel;
- defm LDriub_indexed: LD_Idxd <"memub" , "LDriub", IntRegs, s11_0Ext, u6_0Ext,
- 11, 6>, AddrModeRel;
- defm LDrih_indexed: LD_Idxd <"memh", "LDrih", IntRegs, s11_1Ext, u6_1Ext,
- 12, 7>, AddrModeRel;
- defm LDriuh_indexed: LD_Idxd <"memuh", "LDriuh", IntRegs, s11_1Ext, u6_1Ext,
- 12, 7>, AddrModeRel;
- defm LDriw_indexed: LD_Idxd <"memw", "LDriw", IntRegs, s11_2Ext, u6_2Ext,
- 13, 8>, AddrModeRel;
- defm LDrid_indexed: LD_Idxd <"memd", "LDrid", DoubleRegs, s11_3Ext, u6_3Ext,
- 14, 9>, AddrModeRel;
+ let accessSize = ByteAccess in {
+ defm LDrib_indexed: LD_Idxd <"memb", "LDrib", IntRegs, s11_0Ext, u6_0Ext,
+ 11, 6>, AddrModeRel;
+ defm LDriub_indexed: LD_Idxd <"memub" , "LDriub", IntRegs, s11_0Ext, u6_0Ext,
+ 11, 6>, AddrModeRel;
+ }
+ let accessSize = HalfWordAccess in {
+ defm LDrih_indexed: LD_Idxd <"memh", "LDrih", IntRegs, s11_1Ext, u6_1Ext,
+ 12, 7>, AddrModeRel;
+ defm LDriuh_indexed: LD_Idxd <"memuh", "LDriuh", IntRegs, s11_1Ext, u6_1Ext,
+ 12, 7>, AddrModeRel;
+ }
+ let accessSize = WordAccess in
+ defm LDriw_indexed: LD_Idxd <"memw", "LDriw", IntRegs, s11_2Ext, u6_2Ext,
+ 13, 8>, AddrModeRel;
+
+ let accessSize = DoubleWordAccess in
+ defm LDrid_indexed: LD_Idxd <"memd", "LDrid", DoubleRegs, s11_3Ext, u6_3Ext,
+ 14, 9>, AddrModeRel;
}
let AddedComplexity = 20 in {
//===----------------------------------------------------------------------===//
// Post increment load
-// Make sure that in post increment load, the first operand is always the post
-// increment operand.
//===----------------------------------------------------------------------===//
multiclass LD_PostInc_Pbase<string mnemonic, RegisterClass RC, Operand ImmOp,
}
}
-let hasCtrlDep = 1, neverHasSideEffects = 1 in {
+let hasCtrlDep = 1, neverHasSideEffects = 1, addrMode = PostInc in {
defm POST_LDrib : LD_PostInc<"memb", "LDrib", IntRegs, s4_0Imm>,
PredNewRel;
defm POST_LDriub : LD_PostInc<"memub", "LDriub", IntRegs, s4_0Imm>,
multiclass ST_PostInc_Pred<string mnemonic, RegisterClass RC,
Operand ImmOp, bit PredNot> {
let isPredicatedFalse = PredNot in {
- defm _c#NAME# : ST_PostInc_Pbase<mnemonic, RC, ImmOp, PredNot, 0>;
+ defm _c#NAME : ST_PostInc_Pbase<mnemonic, RC, ImmOp, PredNot, 0>;
// Predicate new
let Predicates = [HasV4T], validSubTargets = HasV4SubT in
defm _cdn#NAME#_V4 : ST_PostInc_Pbase<mnemonic, RC, ImmOp, PredNot, 1>;
let isPredicable = 1 in
def NAME : STInst2PI<(outs IntRegs:$dst),
(ins IntRegs:$src1, ImmOp:$offset, RC:$src2),
- #mnemonic#"($src1++#$offset) = $src2",
+ mnemonic#"($src1++#$offset) = $src2",
[],
"$src1 = $dst">;
}
let addrMode = BaseImmOffset, isMEMri = "true" in {
- defm STrib: ST_MEMri < "memb", "STrib", IntRegs, 11, 6>, AddrModeRel;
- defm STrih: ST_MEMri < "memh", "STrih", IntRegs, 12, 7>, AddrModeRel;
- defm STriw: ST_MEMri < "memw", "STriw", IntRegs, 13, 8>, AddrModeRel;
+ let accessSize = ByteAccess in
+ defm STrib: ST_MEMri < "memb", "STrib", IntRegs, 11, 6>, AddrModeRel;
- let isNVStorable = 0 in
- defm STrid: ST_MEMri < "memd", "STrid", DoubleRegs, 14, 9>, AddrModeRel;
+ let accessSize = HalfWordAccess in
+ defm STrih: ST_MEMri < "memh", "STrih", IntRegs, 12, 7>, AddrModeRel;
+
+ let accessSize = WordAccess in
+ defm STriw: ST_MEMri < "memw", "STriw", IntRegs, 13, 8>, AddrModeRel;
+
+ let accessSize = DoubleWordAccess, isNVStorable = 0 in
+ defm STrid: ST_MEMri < "memd", "STrid", DoubleRegs, 14, 9>, AddrModeRel;
}
def : Pat<(truncstorei8 (i32 IntRegs:$src1), ADDRriS11_0:$addr),
}
let addrMode = BaseImmOffset, InputType = "reg" in {
- defm STrib_indexed: ST_Idxd < "memb", "STrib", IntRegs, s11_0Ext,
- u6_0Ext, 11, 6>, AddrModeRel, ImmRegRel;
- defm STrih_indexed: ST_Idxd < "memh", "STrih", IntRegs, s11_1Ext,
- u6_1Ext, 12, 7>, AddrModeRel, ImmRegRel;
- defm STriw_indexed: ST_Idxd < "memw", "STriw", IntRegs, s11_2Ext,
- u6_2Ext, 13, 8>, AddrModeRel, ImmRegRel;
- let isNVStorable = 0 in
- defm STrid_indexed: ST_Idxd < "memd", "STrid", DoubleRegs, s11_3Ext,
- u6_3Ext, 14, 9>, AddrModeRel;
+ let accessSize = ByteAccess in
+ defm STrib_indexed: ST_Idxd < "memb", "STrib", IntRegs, s11_0Ext,
+ u6_0Ext, 11, 6>, AddrModeRel, ImmRegRel;
+
+ let accessSize = HalfWordAccess in
+ defm STrih_indexed: ST_Idxd < "memh", "STrih", IntRegs, s11_1Ext,
+ u6_1Ext, 12, 7>, AddrModeRel, ImmRegRel;
+
+ let accessSize = WordAccess in
+ defm STriw_indexed: ST_Idxd < "memw", "STriw", IntRegs, s11_2Ext,
+ u6_2Ext, 13, 8>, AddrModeRel, ImmRegRel;
+
+ let accessSize = DoubleWordAccess, isNVStorable = 0 in
+ defm STrid_indexed: ST_Idxd < "memd", "STrid", DoubleRegs, s11_3Ext,
+ u6_3Ext, 14, 9>, AddrModeRel;
}
let AddedComplexity = 10 in {
"$dst = #$src1",
[(set (i64 DoubleRegs:$dst), s8Imm64Pred:$src1)]>;
-// Pseudo instruction to encode a set of conditional transfers.
-// This instruction is used instead of a mux and trades-off codesize
-// for performance. We conduct this transformation optimistically in
-// the hope that these instructions get promoted to dot-new transfers.
-let AddedComplexity = 100, isPredicated = 1 in
-def TFR_condset_rr : ALU32_rr<(outs IntRegs:$dst), (ins PredRegs:$src1,
- IntRegs:$src2,
- IntRegs:$src3),
- "Error; should not emit",
- [(set (i32 IntRegs:$dst),
- (i32 (select (i1 PredRegs:$src1),
- (i32 IntRegs:$src2),
- (i32 IntRegs:$src3))))]>;
let AddedComplexity = 100, isPredicated = 1 in
def TFR_condset_ri : ALU32_rr<(outs IntRegs:$dst),
(ins PredRegs:$src1, IntRegs:$src2, s12Imm:$src3),
[]>;
}
-// Tail Calls.
-let isCall = 1, isBarrier = 1, isReturn = 1, isTerminator = 1 in {
- def TCRETURNtg : JInst<(outs), (ins calltarget:$dst),
- "jump $dst // TAILCALL", []>;
-}
-let isCall = 1, isBarrier = 1, isReturn = 1, isTerminator = 1 in {
- def TCRETURNtext : JInst<(outs), (ins calltarget:$dst),
- "jump $dst // TAILCALL", []>;
-}
-let isCall = 1, isBarrier = 1, isReturn = 1, isTerminator = 1 in {
- def TCRETURNR : JInst<(outs), (ins IntRegs:$dst),
- "jumpr $dst // TAILCALL", []>;
+// Indirect tail-call.
+let isCodeGenOnly = 1, isCall = 1, isReturn = 1 in
+def TCRETURNR : T_JMPr;
+
+// Direct tail-calls.
+let isCall = 1, isReturn = 1, isBarrier = 1, isPredicable = 0,
+isTerminator = 1, isCodeGenOnly = 1 in {
+ def TCRETURNtg : T_JMP<(ins calltarget:$dst)>;
+ def TCRETURNtext : T_JMP<(ins calltarget:$dst)>;
}
+
// Map call instruction.
def : Pat<(call (i32 IntRegs:$dst)),
(CALLR (i32 IntRegs:$dst))>, Requires<[HasV2TOnly]>;
// Map from r0 = and(r1, 65535) to r0 = zxth(r1)
def : Pat <(and (i32 IntRegs:$src1), 65535),
- (ZXTH (i32 IntRegs:$src1))>;
+ (A2_zxth (i32 IntRegs:$src1))>;
// Map from r0 = and(r1, 255) to r0 = zxtb(r1).
def : Pat <(and (i32 IntRegs:$src1), 255),
- (ZXTB (i32 IntRegs:$src1))>;
+ (A2_zxtb (i32 IntRegs:$src1))>;
// Map Add(p1, true) to p1 = not(p1).
// Add(p1, false) should never be produced,
def : Pat <(add (i1 PredRegs:$src1), -1),
(NOT_p (i1 PredRegs:$src1))>;
-// Map from p0 = setlt(r0, r1) r2 = mux(p0, r3, r4) =>
-// p0 = cmp.lt(r0, r1), r0 = mux(p0, r2, r1).
-// cmp.lt(r0, r1) -> cmp.gt(r1, r0)
-def : Pat <(select (i1 (setlt (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
- (i32 IntRegs:$src3),
- (i32 IntRegs:$src4)),
- (i32 (TFR_condset_rr (CMPGTrr (i32 IntRegs:$src2), (i32 IntRegs:$src1)),
- (i32 IntRegs:$src4), (i32 IntRegs:$src3)))>,
- Requires<[HasV2TOnly]>;
-
// Map from p0 = pnot(p0); r0 = mux(p0, #i, #j) => r0 = mux(p0, #j, #i).
def : Pat <(select (not (i1 PredRegs:$src1)), s8ImmPred:$src2, s8ImmPred:$src3),
(i32 (TFR_condset_ii (i1 PredRegs:$src1), s8ImmPred:$src3,
// Map from p0 = pnot(p0); if (p0) jump => if (!p0) jump.
def : Pat <(brcond (not (i1 PredRegs:$src1)), bb:$offset),
- (JMP_cNot (i1 PredRegs:$src1), bb:$offset)>;
+ (JMP_f (i1 PredRegs:$src1), bb:$offset)>;
// Map from p2 = pnot(p2); p1 = and(p0, p2) => p1 = and(p0, !p2).
def : Pat <(and (i1 PredRegs:$src1), (not (i1 PredRegs:$src2))),
// Map from i1 loads to 32 bits. This assumes that the i1* is byte aligned.
let AddedComplexity = 10 in
def : Pat <(i32 (zextloadi1 ADDRriS11_0:$addr)),
- (i32 (AND_rr (i32 (LDrib ADDRriS11_0:$addr)), (TFRI 0x1)))>;
+ (i32 (A2_and (i32 (LDrib ADDRriS11_0:$addr)), (TFRI 0x1)))>;
// Map from Rdd = sign_extend_inreg(Rss, i32) -> Rdd = SXTW(Rss.lo).
def : Pat <(i64 (sext_inreg (i64 DoubleRegs:$src1), i32)),
// Map from Rdd = sign_extend_inreg(Rss, i16) -> Rdd = SXTW(SXTH(Rss.lo)).
def : Pat <(i64 (sext_inreg (i64 DoubleRegs:$src1), i16)),
- (i64 (SXTW (i32 (SXTH (i32 (EXTRACT_SUBREG (i64 DoubleRegs:$src1),
+ (i64 (SXTW (i32 (A2_sxth (i32 (EXTRACT_SUBREG (i64 DoubleRegs:$src1),
subreg_loreg))))))>;
// Map from Rdd = sign_extend_inreg(Rss, i8) -> Rdd = SXTW(SXTB(Rss.lo)).
def : Pat <(i64 (sext_inreg (i64 DoubleRegs:$src1), i8)),
- (i64 (SXTW (i32 (SXTB (i32 (EXTRACT_SUBREG (i64 DoubleRegs:$src1),
+ (i64 (SXTW (i32 (A2_sxtb (i32 (EXTRACT_SUBREG (i64 DoubleRegs:$src1),
subreg_loreg))))))>;
// We want to prevent emitting pnot's as much as possible.
-// Map brcond with an unsupported setcc to a JMP_cNot.
+// Map brcond with an unsupported setcc to a JMP_f.
def : Pat <(brcond (i1 (setne (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
bb:$offset),
- (JMP_cNot (CMPEQrr (i32 IntRegs:$src1), (i32 IntRegs:$src2)),
+ (JMP_f (C2_cmpeq (i32 IntRegs:$src1), (i32 IntRegs:$src2)),
bb:$offset)>;
def : Pat <(brcond (i1 (setne (i32 IntRegs:$src1), s10ImmPred:$src2)),
bb:$offset),
- (JMP_cNot (CMPEQri (i32 IntRegs:$src1), s10ImmPred:$src2), bb:$offset)>;
+ (JMP_f (CMPEQri (i32 IntRegs:$src1), s10ImmPred:$src2), bb:$offset)>;
def : Pat <(brcond (i1 (setne (i1 PredRegs:$src1), (i1 -1))), bb:$offset),
- (JMP_cNot (i1 PredRegs:$src1), bb:$offset)>;
+ (JMP_f (i1 PredRegs:$src1), bb:$offset)>;
def : Pat <(brcond (i1 (setne (i1 PredRegs:$src1), (i1 0))), bb:$offset),
- (JMP_c (i1 PredRegs:$src1), bb:$offset)>;
+ (JMP_t (i1 PredRegs:$src1), bb:$offset)>;
// cmp.lt(Rs, Imm) -> !cmp.ge(Rs, Imm) -> !cmp.gt(Rs, Imm-1)
def : Pat <(brcond (i1 (setlt (i32 IntRegs:$src1), s8ImmPred:$src2)),
bb:$offset),
- (JMP_cNot (CMPGTri (i32 IntRegs:$src1),
+ (JMP_f (CMPGTri (i32 IntRegs:$src1),
(DEC_CONST_SIGNED s8ImmPred:$src2)), bb:$offset)>;
// cmp.lt(r0, r1) -> cmp.gt(r1, r0)
def : Pat <(brcond (i1 (setlt (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
bb:$offset),
- (JMP_c (CMPGTrr (i32 IntRegs:$src2), (i32 IntRegs:$src1)), bb:$offset)>;
+ (JMP_t (C2_cmpgt (i32 IntRegs:$src2), (i32 IntRegs:$src1)), bb:$offset)>;
def : Pat <(brcond (i1 (setuge (i64 DoubleRegs:$src1), (i64 DoubleRegs:$src2))),
bb:$offset),
- (JMP_cNot (CMPGTU64rr (i64 DoubleRegs:$src2), (i64 DoubleRegs:$src1)),
+ (JMP_f (CMPGTU64rr (i64 DoubleRegs:$src2), (i64 DoubleRegs:$src1)),
bb:$offset)>;
def : Pat <(brcond (i1 (setule (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
bb:$offset),
- (JMP_cNot (CMPGTUrr (i32 IntRegs:$src1), (i32 IntRegs:$src2)),
+ (JMP_f (C2_cmpgtu (i32 IntRegs:$src1), (i32 IntRegs:$src2)),
bb:$offset)>;
def : Pat <(brcond (i1 (setule (i64 DoubleRegs:$src1), (i64 DoubleRegs:$src2))),
bb:$offset),
- (JMP_cNot (CMPGTU64rr (i64 DoubleRegs:$src1), (i64 DoubleRegs:$src2)),
+ (JMP_f (CMPGTU64rr (i64 DoubleRegs:$src1), (i64 DoubleRegs:$src2)),
bb:$offset)>;
// Map from a 64-bit select to an emulated 64-bit mux.
// Hexagon does not support 64-bit MUXes; so emulate with combines.
def : Pat <(select (i1 PredRegs:$src1), (i64 DoubleRegs:$src2),
(i64 DoubleRegs:$src3)),
- (i64 (COMBINE_rr (i32 (MUX_rr (i1 PredRegs:$src1),
+ (i64 (COMBINE_rr (i32 (C2_mux (i1 PredRegs:$src1),
(i32 (EXTRACT_SUBREG (i64 DoubleRegs:$src2),
subreg_hireg)),
(i32 (EXTRACT_SUBREG (i64 DoubleRegs:$src3),
subreg_hireg)))),
- (i32 (MUX_rr (i1 PredRegs:$src1),
+ (i32 (C2_mux (i1 PredRegs:$src1),
(i32 (EXTRACT_SUBREG (i64 DoubleRegs:$src2),
subreg_loreg)),
(i32 (EXTRACT_SUBREG (i64 DoubleRegs:$src3),
// rs <= rt -> !(rs > rt).
def : Pat<(i1 (setle (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
- (i1 (NOT_p (CMPGTrr (i32 IntRegs:$src1), (i32 IntRegs:$src2))))>;
+ (i1 (NOT_p (C2_cmpgt (i32 IntRegs:$src1), (i32 IntRegs:$src2))))>;
// Rss <= Rtt -> !(Rss > Rtt).
def : Pat<(i1 (setle (i64 DoubleRegs:$src1), (i64 DoubleRegs:$src2))),
// Map cmpne(Rs) -> !cmpeqe(Rs).
// rs != rt -> !(rs == rt).
def : Pat <(i1 (setne (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
- (i1 (NOT_p (i1 (CMPEQrr (i32 IntRegs:$src1), (i32 IntRegs:$src2)))))>;
+ (i1 (NOT_p (i1 (C2_cmpeq (i32 IntRegs:$src1), (i32 IntRegs:$src2)))))>;
// Convert setne back to xor for hexagon since we compute w/ pred registers.
def : Pat <(i1 (setne (i1 PredRegs:$src1), (i1 PredRegs:$src2))),
// Map cmpge(Rs, Rt) -> !(cmpgt(Rs, Rt).
// rs >= rt -> !(rt > rs).
def : Pat <(i1 (setge (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
- (i1 (NOT_p (i1 (CMPGTrr (i32 IntRegs:$src2), (i32 IntRegs:$src1)))))>;
+ (i1 (NOT_p (i1 (C2_cmpgt (i32 IntRegs:$src2), (i32 IntRegs:$src1)))))>;
// cmpge(Rs, Imm) -> cmpgt(Rs, Imm-1)
def : Pat <(i1 (setge (i32 IntRegs:$src1), s8ExtPred:$src2)),
// rs < rt -> rt > rs.
// We can let assembler map it, or we can do in the compiler itself.
def : Pat <(i1 (setlt (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
- (i1 (CMPGTrr (i32 IntRegs:$src2), (i32 IntRegs:$src1)))>;
+ (i1 (C2_cmpgt (i32 IntRegs:$src2), (i32 IntRegs:$src1)))>;
// Map cmplt(Rss, Rtt) -> cmpgt(Rtt, Rss).
// rss < rtt -> (rtt > rss).
// rs < rt -> rt > rs.
// We can let assembler map it, or we can do in the compiler itself.
def : Pat <(i1 (setult (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
- (i1 (CMPGTUrr (i32 IntRegs:$src2), (i32 IntRegs:$src1)))>;
+ (i1 (C2_cmpgtu (i32 IntRegs:$src2), (i32 IntRegs:$src1)))>;
// Map from cmpltu(Rss, Rdd) -> cmpgtu(Rdd, Rss).
// rs < rt -> rt > rs.
// Generate cmpgeu(Rs, #0) -> cmpeq(Rs, Rs)
def : Pat <(i1 (setuge (i32 IntRegs:$src1), 0)),
- (i1 (CMPEQrr (i32 IntRegs:$src1), (i32 IntRegs:$src1)))>;
+ (i1 (C2_cmpeq (i32 IntRegs:$src1), (i32 IntRegs:$src1)))>;
// Generate cmpgeu(Rs, #u8) -> cmpgtu(Rs, #u8 -1)
def : Pat <(i1 (setuge (i32 IntRegs:$src1), u8ExtPred:$src2)),
// Map from Rs >= Rt -> !(Rt > Rs).
// rs >= rt -> !(rt > rs).
def : Pat <(i1 (setuge (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
- (i1 (NOT_p (CMPGTUrr (i32 IntRegs:$src2), (i32 IntRegs:$src1))))>;
+ (i1 (NOT_p (C2_cmpgtu (i32 IntRegs:$src2), (i32 IntRegs:$src1))))>;
// Map from Rs >= Rt -> !(Rt > Rs).
// rs >= rt -> !(rt > rs).
// Map from cmpleu(Rs, Rt) -> !cmpgtu(Rs, Rt).
// Map from (Rs <= Rt) -> !(Rs > Rt).
def : Pat <(i1 (setule (i32 IntRegs:$src1), (i32 IntRegs:$src2))),
- (i1 (NOT_p (CMPGTUrr (i32 IntRegs:$src1), (i32 IntRegs:$src2))))>;
+ (i1 (NOT_p (C2_cmpgtu (i32 IntRegs:$src1), (i32 IntRegs:$src2))))>;
// Map from cmpleu(Rss, Rtt) -> !cmpgtu(Rss, Rtt-1).
// Map from (Rs <= Rt) -> !(Rs > Rt).
(i64 (SXTW (i32 (MUX_ii (i1 PredRegs:$src1), 1, 0))))>;
+let AddedComplexity = 100 in
+def: Pat<(i64 (or (i64 (shl (i64 DoubleRegs:$srcHigh),
+ (i32 32))),
+ (i64 (zextloadi32 (i32 (add IntRegs:$src2,
+ s11_2ExtPred:$offset2)))))),
+ (i64 (COMBINE_rr (EXTRACT_SUBREG (i64 DoubleRegs:$srcHigh), subreg_loreg),
+ (LDriw_indexed IntRegs:$src2,
+ s11_2ExtPred:$offset2)))>;
+
+def: Pat<(i64 (or (i64 (shl (i64 DoubleRegs:$srcHigh),
+ (i32 32))),
+ (i64 (zextloadi32 ADDRriS11_2:$srcLow)))),
+ (i64 (COMBINE_rr (EXTRACT_SUBREG (i64 DoubleRegs:$srcHigh), subreg_loreg),
+ (LDriw ADDRriS11_2:$srcLow)))>;
+
+def: Pat<(i64 (or (i64 (shl (i64 DoubleRegs:$srcHigh),
+ (i32 32))),
+ (i64 (zext (i32 IntRegs:$srcLow))))),
+ (i64 (COMBINE_rr (EXTRACT_SUBREG (i64 DoubleRegs:$srcHigh), subreg_loreg),
+ IntRegs:$srcLow))>;
+
let AddedComplexity = 100 in
def: Pat<(i64 (or (i64 (shl (i64 DoubleRegs:$srcHigh),
(i32 32))),
def : Pat<(i32 (sext_inreg (Hexagon_ARGEXTEND (i32 IntRegs:$src1)), i16)),
(COPY (i32 IntRegs:$src1))>;
-def SDHexagonBR_JT: SDTypeProfile<0, 1, [SDTCisVT<0, i32>]>;
-def HexagonBR_JT: SDNode<"HexagonISD::BR_JT", SDHexagonBR_JT, [SDNPHasChain]>;
-
-let isBranch=1, isIndirectBranch=1, isTerminator=1, isBarrier = 1 in
-def BR_JT : JRInst<(outs), (ins IntRegs:$src),
- "jumpr $src",
- [(HexagonBR_JT (i32 IntRegs:$src))]>;
-
-let isBranch=1, isIndirectBranch=1, isTerminator=1 in
-def BRIND : JRInst<(outs), (ins IntRegs:$src),
- "jumpr $src",
- [(brind (i32 IntRegs:$src))]>;
-
def HexagonWrapperJT: SDNode<"HexagonISD::WrapperJT", SDTIntUnaryOp>;
def : Pat<(HexagonWrapperJT tjumptable:$dst),