let AsmString = "$Rd = "#mnemonic#"($Rs, ~$Rt)";
}
-let BaseOpcode = "andn_rr", CextOpcode = "andn", isCodeGenOnly = 0 in
+let BaseOpcode = "andn_rr", CextOpcode = "andn" in
def A4_andn : T_ALU32_3op_not<"and", 0b001, 0b100, 1>;
-let BaseOpcode = "orn_rr", CextOpcode = "orn", isCodeGenOnly = 0 in
+let BaseOpcode = "orn_rr", CextOpcode = "orn" in
def A4_orn : T_ALU32_3op_not<"or", 0b001, 0b101, 1>;
-let CextOpcode = "rcmp.eq", isCodeGenOnly = 0 in
+let CextOpcode = "rcmp.eq" in
def A4_rcmpeq : T_ALU32_3op<"cmp.eq", 0b011, 0b010, 0, 1>;
-let CextOpcode = "!rcmp.eq", isCodeGenOnly = 0 in
+let CextOpcode = "!rcmp.eq" in
def A4_rcmpneq : T_ALU32_3op<"!cmp.eq", 0b011, 0b011, 0, 1>;
-let isCodeGenOnly = 0 in {
def C4_cmpneq : T_ALU32_3op_cmp<"!cmp.eq", 0b00, 1, 1>;
def C4_cmplte : T_ALU32_3op_cmp<"!cmp.gt", 0b10, 1, 0>;
def C4_cmplteu : T_ALU32_3op_cmp<"!cmp.gtu", 0b11, 1, 0>;
-}
// Pats for instruction selection.
let Inst{1-0} = Pd;
}
-let isCodeGenOnly = 0 in {
def A4_cmpbeq : T_CMP_rrbh<"cmpb.eq", 0b110, 1>;
def A4_cmpbgt : T_CMP_rrbh<"cmpb.gt", 0b010, 0>;
def A4_cmpbgtu : T_CMP_rrbh<"cmpb.gtu", 0b111, 0>;
def A4_cmpheq : T_CMP_rrbh<"cmph.eq", 0b011, 1>;
def A4_cmphgt : T_CMP_rrbh<"cmph.gt", 0b100, 0>;
def A4_cmphgtu : T_CMP_rrbh<"cmph.gtu", 0b101, 0>;
-}
class T_CMP_ribh<string mnemonic, bits<2> MajOp, bit IsHalf, bit IsComm,
Operand ImmType, bit IsImmExt, bit IsImmSigned, int ImmBits>
let Inst{1-0} = Pd;
}
-let isCodeGenOnly = 0 in {
def A4_cmpbeqi : T_CMP_ribh<"cmpb.eq", 0b00, 0, 1, u8Imm, 0, 0, 8>;
def A4_cmpbgti : T_CMP_ribh<"cmpb.gt", 0b01, 0, 0, s8Imm, 0, 1, 8>;
def A4_cmpbgtui : T_CMP_ribh<"cmpb.gtu", 0b10, 0, 0, u7Ext, 1, 0, 7>;
def A4_cmpheqi : T_CMP_ribh<"cmph.eq", 0b00, 1, 1, s8Ext, 1, 1, 8>;
def A4_cmphgti : T_CMP_ribh<"cmph.gt", 0b01, 1, 0, s8Ext, 1, 1, 8>;
def A4_cmphgtui : T_CMP_ribh<"cmph.gtu", 0b10, 1, 0, u7Ext, 1, 0, 7>;
-}
+
class T_RCMP_EQ_ri<string mnemonic, bit IsNeg>
: ALU32_ri<(outs IntRegs:$Rd), (ins IntRegs:$Rs, s8Ext:$s8),
"$Rd = "#mnemonic#"($Rs, #$s8)", [], "", ALU32_2op_tc_1_SLOT0123>,
let Inst{4-0} = Rd;
}
-let isCodeGenOnly = 0 in {
def A4_rcmpeqi : T_RCMP_EQ_ri<"cmp.eq", 0>;
def A4_rcmpneqi : T_RCMP_EQ_ri<"!cmp.eq", 1>;
-}
def: Pat<(i32 (zext (i1 (seteq (i32 IntRegs:$Rs), s8ExtPred:$s8)))),
(A4_rcmpeqi IntRegs:$Rs, s8ExtPred:$s8)>;
(i32 IntRegs:$src1))), 0)))),
(C2_muxii (S2_tstbit_r IntRegs:$src1, IntRegs:$src2), 1, 0)>;
-
//===----------------------------------------------------------------------===//
// ALU32 -
//===----------------------------------------------------------------------===//
let Inst{4-0} = Rdd;
}
-let opExtendable = 2, isCodeGenOnly = 0 in
+let opExtendable = 2 in
def A4_combineri : T_Combine1<0b00, (ins IntRegs:$Rs, s8Ext:$s8),
"$Rdd = combine($Rs, #$s8)">;
-let opExtendable = 1, isCodeGenOnly = 0 in
+let opExtendable = 1 in
def A4_combineir : T_Combine1<0b01, (ins s8Ext:$s8, IntRegs:$Rs),
"$Rdd = combine(#$s8, $Rs)">;
let Inst{6-5} = addr{1-0};
}
-let accessSize = ByteAccess, hasNewValue = 1, isCodeGenOnly = 0 in {
+let accessSize = ByteAccess, hasNewValue = 1 in {
def L4_loadrb_ap : T_LD_abs_set <"memb", IntRegs, 0b1000>;
def L4_loadrub_ap : T_LD_abs_set <"memub", IntRegs, 0b1001>;
}
-let accessSize = HalfWordAccess, hasNewValue = 1, isCodeGenOnly = 0 in {
+let accessSize = HalfWordAccess, hasNewValue = 1 in {
def L4_loadrh_ap : T_LD_abs_set <"memh", IntRegs, 0b1010>;
def L4_loadruh_ap : T_LD_abs_set <"memuh", IntRegs, 0b1011>;
}
-let accessSize = WordAccess, hasNewValue = 1, isCodeGenOnly = 0 in
+let accessSize = WordAccess, hasNewValue = 1 in
def L4_loadri_ap : T_LD_abs_set <"memw", IntRegs, 0b1100>;
-let accessSize = DoubleWordAccess, isCodeGenOnly = 0 in
+let accessSize = DoubleWordAccess in
def L4_loadrd_ap : T_LD_abs_set <"memd", DoubleRegs, 0b1110>;
// Load - Indirect with long offset
let InputType = "imm", addrMode = BaseLongOffset, isExtended = 1,
let Inst{4-0} = dst;
}
-let accessSize = ByteAccess, isCodeGenOnly = 0 in {
+let accessSize = ByteAccess in {
def L4_loadrb_ur : T_LoadAbsReg<"memb", "LDrib", IntRegs, 0b1000>;
def L4_loadrub_ur : T_LoadAbsReg<"memub", "LDriub", IntRegs, 0b1001>;
def L4_loadalignb_ur : T_LoadAbsReg<"memb_fifo", "LDrib_fifo",
DoubleRegs, 0b0100>;
}
-let accessSize = HalfWordAccess, isCodeGenOnly = 0 in {
+let accessSize = HalfWordAccess in {
def L4_loadrh_ur : T_LoadAbsReg<"memh", "LDrih", IntRegs, 0b1010>;
def L4_loadruh_ur : T_LoadAbsReg<"memuh", "LDriuh", IntRegs, 0b1011>;
def L4_loadbsw2_ur : T_LoadAbsReg<"membh", "LDribh2", IntRegs, 0b0001>;
DoubleRegs, 0b0010>;
}
-let accessSize = WordAccess, isCodeGenOnly = 0 in {
+let accessSize = WordAccess in {
def L4_loadri_ur : T_LoadAbsReg<"memw", "LDriw", IntRegs, 0b1100>;
def L4_loadbsw4_ur : T_LoadAbsReg<"membh", "LDribh4", DoubleRegs, 0b0111>;
def L4_loadbzw4_ur : T_LoadAbsReg<"memubh", "LDriubh4", DoubleRegs, 0b0101>;
}
-let accessSize = DoubleWordAccess, isCodeGenOnly = 0 in
+let accessSize = DoubleWordAccess in
def L4_loadrd_ur : T_LoadAbsReg<"memd", "LDrid", DoubleRegs, 0b1110>;
}
}
-let hasNewValue = 1, accessSize = ByteAccess, isCodeGenOnly = 0 in {
+let hasNewValue = 1, accessSize = ByteAccess in {
defm loadrb : ld_idxd_shl<"memb", "LDrib", IntRegs, 0b000>;
defm loadrub : ld_idxd_shl<"memub", "LDriub", IntRegs, 0b001>;
}
-let hasNewValue = 1, accessSize = HalfWordAccess, isCodeGenOnly = 0 in {
+let hasNewValue = 1, accessSize = HalfWordAccess in {
defm loadrh : ld_idxd_shl<"memh", "LDrih", IntRegs, 0b010>;
defm loadruh : ld_idxd_shl<"memuh", "LDriuh", IntRegs, 0b011>;
}
-let hasNewValue = 1, accessSize = WordAccess, isCodeGenOnly = 0 in
+let hasNewValue = 1, accessSize = WordAccess in
defm loadri : ld_idxd_shl<"memw", "LDriw", IntRegs, 0b100>;
-let accessSize = DoubleWordAccess, isCodeGenOnly = 0 in
+let accessSize = DoubleWordAccess in
defm loadrd : ld_idxd_shl<"memd", "LDrid", DoubleRegs, 0b110>;
// 'def pats' for load instructions with base + register offset and non-zero
let Inst{5-0} = addr;
}
-let mayStore = 1, addrMode = AbsoluteSet, isCodeGenOnly = 0 in {
+let mayStore = 1, addrMode = AbsoluteSet in {
def S4_storerbnew_ap : T_ST_absset_nv <"memb", "STrib", 0b00, ByteAccess>;
def S4_storerhnew_ap : T_ST_absset_nv <"memh", "STrih", 0b01, HalfWordAccess>;
def S4_storerinew_ap : T_ST_absset_nv <"memw", "STriw", 0b10, WordAccess>;
let Inst{5-0} = src3;
}
-let isCodeGenOnly = 0 in {
def S4_storerb_ur : T_StoreAbsReg <"memb", "STrib", IntRegs, 0b000, ByteAccess>;
def S4_storerh_ur : T_StoreAbsReg <"memh", "STrih", IntRegs, 0b010,
HalfWordAccess>;
def S4_storeri_ur : T_StoreAbsReg <"memw", "STriw", IntRegs, 0b100, WordAccess>;
def S4_storerd_ur : T_StoreAbsReg <"memd", "STrid", DoubleRegs, 0b110,
DoubleWordAccess>;
-}
let AddedComplexity = 40 in
multiclass T_StoreAbsReg_Pats <InstHexagon MI, RegisterClass RC, ValueType VT,
let Inst{5-0} = src3;
}
-let isCodeGenOnly = 0 in {
def S4_storerbnew_ur : T_StoreAbsRegNV <"memb", "STrib", 0b00, ByteAccess>;
def S4_storerhnew_ur : T_StoreAbsRegNV <"memh", "STrih", 0b01, HalfWordAccess>;
def S4_storerinew_ur : T_StoreAbsRegNV <"memw", "STriw", 0b10, WordAccess>;
-}
//===----------------------------------------------------------------------===//
// Template classes for the non-predicated store instructions with
}
}
-let addrMode = BaseRegOffset, InputType = "reg", hasSideEffects = 0,
- isCodeGenOnly = 0 in {
+let addrMode = BaseRegOffset, InputType = "reg", hasSideEffects = 0 in {
let accessSize = ByteAccess in
defm storerb: ST_Idxd_shl<"memb", "STrib", IntRegs, 0b000>,
ST_Idxd_shl_nv<"memb", "STrib", IntRegs, 0b00>;
}
let hasSideEffects = 0, validSubTargets = HasV4SubT, addrMode = BaseImmOffset,
- InputType = "imm", isCodeGenOnly = 0 in {
+ InputType = "imm" in {
let accessSize = ByteAccess in
defm S4_storeirb : ST_Imm<"memb", "STrib", u6_0Imm, 0b00>;
}
}
-let addrMode = BaseImmOffset, InputType = "imm", isCodeGenOnly = 0 in {
+let addrMode = BaseImmOffset, InputType = "imm" in {
let accessSize = ByteAccess in
defm storerb: ST_Idxd_nv<"memb", "STrib", IntRegs, s11_0Ext,
u6_0Ext, 0b00>, AddrModeRel;
// Post increment loads with register offset.
//===----------------------------------------------------------------------===//
-let hasNewValue = 1, isCodeGenOnly = 0 in
+let hasNewValue = 1 in
def L2_loadbsw2_pr : T_load_pr <"membh", IntRegs, 0b0001, HalfWordAccess>;
-let isCodeGenOnly = 0 in
def L2_loadbsw4_pr : T_load_pr <"membh", DoubleRegs, 0b0111, WordAccess>;
//===----------------------------------------------------------------------===//
}
}
-let accessSize = ByteAccess, isCodeGenOnly = 0 in
+let accessSize = ByteAccess in
defm storerbnew: ST_PostInc_nv <"memb", "STrib", s4_0Imm, 0b00>;
-let accessSize = HalfWordAccess, isCodeGenOnly = 0 in
+let accessSize = HalfWordAccess in
defm storerhnew: ST_PostInc_nv <"memh", "STrih", s4_1Imm, 0b01>;
-let accessSize = WordAccess, isCodeGenOnly = 0 in
+let accessSize = WordAccess in
defm storerinew: ST_PostInc_nv <"memw", "STriw", s4_2Imm, 0b10>;
//===----------------------------------------------------------------------===//
let Inst{7} = 0b0;
}
-let isCodeGenOnly = 0 in {
def S2_storerbnew_pr : T_StorePI_RegNV<"memb", 0b00, ByteAccess>;
def S2_storerhnew_pr : T_StorePI_RegNV<"memh", 0b01, HalfWordAccess>;
def S2_storerinew_pr : T_StorePI_RegNV<"memw", 0b10, WordAccess>;
-}
// memb(Rx++#s4:0:circ(Mu))=Nt.new
// memb(Rx++I:circ(Mu))=Nt.new
let RegOp = !if(!eq(NvOpNum, 0), src2, src1);
let IClass = 0b0010;
- let Inst{26} = 0b0;
+ let Inst{27-26} = 0b00;
let Inst{25-23} = majOp;
let Inst{22} = isNegCond;
let Inst{18-16} = Ns;
multiclass NVJrr_cond<string mnemonic, bits<3> majOp, bit NvOpNum,
bit isNegCond> {
// Branch not taken:
- def _nt_V4: NVJrr_template<mnemonic, majOp, NvOpNum, isNegCond, 0>;
+ def _nt: NVJrr_template<mnemonic, majOp, NvOpNum, isNegCond, 0>;
// Branch taken:
- def _t_V4: NVJrr_template<mnemonic, majOp, NvOpNum, isNegCond, 1>;
+ def _t : NVJrr_template<mnemonic, majOp, NvOpNum, isNegCond, 1>;
}
// NvOpNum = 0 -> First Operand is a new-value Register
multiclass NVJrr_base<string mnemonic, string BaseOp, bits<3> majOp,
bit NvOpNum> {
let BaseOpcode = BaseOp#_NVJ in {
- defm _t_Jumpnv : NVJrr_cond<mnemonic, majOp, NvOpNum, 0>; // True cond
- defm _f_Jumpnv : NVJrr_cond<mnemonic, majOp, NvOpNum, 1>; // False cond
+ defm _t_jumpnv : NVJrr_cond<mnemonic, majOp, NvOpNum, 0>; // True cond
+ defm _f_jumpnv : NVJrr_cond<mnemonic, majOp, NvOpNum, 1>; // False cond
}
}
// if ([!]cmp.gtu(Rt,Ns.new)) jump:[n]t #r9:2
let isPredicated = 1, isBranch = 1, isNewValue = 1, isTerminator = 1,
- Defs = [PC], hasSideEffects = 0, validSubTargets = HasV4SubT,
- isCodeGenOnly = 0 in {
- defm CMPEQrr : NVJrr_base<"cmp.eq", "CMPEQ", 0b000, 0>, PredRel;
- defm CMPGTrr : NVJrr_base<"cmp.gt", "CMPGT", 0b001, 0>, PredRel;
- defm CMPGTUrr : NVJrr_base<"cmp.gtu", "CMPGTU", 0b010, 0>, PredRel;
- defm CMPLTrr : NVJrr_base<"cmp.gt", "CMPLT", 0b011, 1>, PredRel;
- defm CMPLTUrr : NVJrr_base<"cmp.gtu", "CMPLTU", 0b100, 1>, PredRel;
+ Defs = [PC], hasSideEffects = 0, validSubTargets = HasV4SubT in {
+ defm J4_cmpeq : NVJrr_base<"cmp.eq", "CMPEQ", 0b000, 0>, PredRel;
+ defm J4_cmpgt : NVJrr_base<"cmp.gt", "CMPGT", 0b001, 0>, PredRel;
+ defm J4_cmpgtu : NVJrr_base<"cmp.gtu", "CMPGTU", 0b010, 0>, PredRel;
+ defm J4_cmplt : NVJrr_base<"cmp.gt", "CMPLT", 0b011, 1>, PredRel;
+ defm J4_cmpltu : NVJrr_base<"cmp.gtu", "CMPLTU", 0b100, 1>, PredRel;
}
//===----------------------------------------------------------------------===//
multiclass NVJri_cond<string mnemonic, bits<3> majOp, bit isNegCond> {
// Branch not taken:
- def _nt_V4: NVJri_template<mnemonic, majOp, isNegCond, 0>;
+ def _nt: NVJri_template<mnemonic, majOp, isNegCond, 0>;
// Branch taken:
- def _t_V4: NVJri_template<mnemonic, majOp, isNegCond, 1>;
+ def _t : NVJri_template<mnemonic, majOp, isNegCond, 1>;
}
multiclass NVJri_base<string mnemonic, string BaseOp, bits<3> majOp> {
let BaseOpcode = BaseOp#_NVJri in {
- defm _t_Jumpnv : NVJri_cond<mnemonic, majOp, 0>; // True Cond
- defm _f_Jumpnv : NVJri_cond<mnemonic, majOp, 1>; // False cond
+ defm _t_jumpnv : NVJri_cond<mnemonic, majOp, 0>; // True Cond
+ defm _f_jumpnv : NVJri_cond<mnemonic, majOp, 1>; // False cond
}
}
// if ([!]cmp.gtu(Ns.new,#U5)) jump:[n]t #r9:2
let isPredicated = 1, isBranch = 1, isNewValue = 1, isTerminator = 1,
- Defs = [PC], hasSideEffects = 0, validSubTargets = HasV4SubT,
- isCodeGenOnly = 0 in {
- defm CMPEQri : NVJri_base<"cmp.eq", "CMPEQ", 0b000>, PredRel;
- defm CMPGTri : NVJri_base<"cmp.gt", "CMPGT", 0b001>, PredRel;
- defm CMPGTUri : NVJri_base<"cmp.gtu", "CMPGTU", 0b010>, PredRel;
+ Defs = [PC], hasSideEffects = 0, validSubTargets = HasV4SubT in {
+ defm J4_cmpeqi : NVJri_base<"cmp.eq", "CMPEQ", 0b000>, PredRel;
+ defm J4_cmpgti : NVJri_base<"cmp.gt", "CMPGT", 0b001>, PredRel;
+ defm J4_cmpgtui : NVJri_base<"cmp.gtu", "CMPGTU", 0b010>, PredRel;
}
//===----------------------------------------------------------------------===//
multiclass NVJ_ConstImm_cond<string mnemonic, bits<3> majOp, string ImmVal,
bit isNegCond> {
// Branch not taken:
- def _nt_V4: NVJ_ConstImm_template<mnemonic, majOp, ImmVal, isNegCond, 0>;
+ def _nt: NVJ_ConstImm_template<mnemonic, majOp, ImmVal, isNegCond, 0>;
// Branch taken:
- def _t_V4: NVJ_ConstImm_template<mnemonic, majOp, ImmVal, isNegCond, 1>;
+ def _t : NVJ_ConstImm_template<mnemonic, majOp, ImmVal, isNegCond, 1>;
}
multiclass NVJ_ConstImm_base<string mnemonic, string BaseOp, bits<3> majOp,
string ImmVal> {
let BaseOpcode = BaseOp#_NVJ_ConstImm in {
- defm _t_Jumpnv : NVJ_ConstImm_cond<mnemonic, majOp, ImmVal, 0>; // True
- defm _f_Jumpnv : NVJ_ConstImm_cond<mnemonic, majOp, ImmVal, 1>; // False
+ defm _t_jumpnv : NVJ_ConstImm_cond<mnemonic, majOp, ImmVal, 0>; // True
+ defm _f_jumpnv : NVJ_ConstImm_cond<mnemonic, majOp, ImmVal, 1>; // False
}
}
// if ([!]cmp.gt(Ns.new,#-1)) jump:[n]t #r9:2
let isPredicated = 1, isBranch = 1, isNewValue = 1, isTerminator=1,
- Defs = [PC], hasSideEffects = 0, isCodeGenOnly = 0 in {
- defm TSTBIT0 : NVJ_ConstImm_base<"tstbit", "TSTBIT", 0b011, "0">, PredRel;
- defm CMPEQn1 : NVJ_ConstImm_base<"cmp.eq", "CMPEQ", 0b100, "-1">, PredRel;
- defm CMPGTn1 : NVJ_ConstImm_base<"cmp.gt", "CMPGT", 0b101, "-1">, PredRel;
+ Defs = [PC], hasSideEffects = 0 in {
+ defm J4_tstbit0 : NVJ_ConstImm_base<"tstbit", "TSTBIT", 0b011, "0">, PredRel;
+ defm J4_cmpeqn1 : NVJ_ConstImm_base<"cmp.eq", "CMPEQ", 0b100, "-1">, PredRel;
+ defm J4_cmpgtn1 : NVJ_ConstImm_base<"cmp.gt", "CMPGT", 0b101, "-1">, PredRel;
}
// J4_hintjumpr: Hint indirect conditional jump.
-let isBranch = 1, isIndirectBranch = 1, hasSideEffects = 0, isCodeGenOnly = 0 in
+let isBranch = 1, isIndirectBranch = 1, hasSideEffects = 0 in
def J4_hintjumpr: JRInst <
(outs),
(ins IntRegs:$Rs),
// PC-relative add
let hasNewValue = 1, isExtendable = 1, opExtendable = 1,
isExtentSigned = 0, opExtentBits = 6, hasSideEffects = 0,
- Uses = [PC], validSubTargets = HasV4SubT, isCodeGenOnly = 0 in
+ Uses = [PC], validSubTargets = HasV4SubT in
def C4_addipc : CRInst <(outs IntRegs:$Rd), (ins u6Ext:$u6),
"$Rd = add(pc, #$u6)", [], "", CR_tc_2_SLOT3 > {
bits<5> Rd;
let Inst{1-0} = Pd;
}
-let isCodeGenOnly = 0 in {
def C4_and_and : T_LOGICAL_3OP<"and", "and", 0b00, 0>;
def C4_and_or : T_LOGICAL_3OP<"and", "or", 0b01, 0>;
def C4_or_and : T_LOGICAL_3OP<"or", "and", 0b10, 0>;
def C4_and_orn : T_LOGICAL_3OP<"and", "or", 0b01, 1>;
def C4_or_andn : T_LOGICAL_3OP<"or", "and", 0b10, 1>;
def C4_or_orn : T_LOGICAL_3OP<"or", "or", 0b11, 1>;
-}
//===----------------------------------------------------------------------===//
// CR -
//===----------------------------------------------------------------------===//
// Logical with-not instructions.
-let validSubTargets = HasV4SubT, isCodeGenOnly = 0 in {
+let validSubTargets = HasV4SubT in {
def A4_andnp : T_ALU64_logical<"and", 0b001, 1, 0, 1>;
def A4_ornp : T_ALU64_logical<"or", 0b011, 1, 0, 1>;
}
-let hasNewValue = 1, hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasNewValue = 1, hasSideEffects = 0 in
def S4_parity: ALU64Inst<(outs IntRegs:$Rd), (ins IntRegs:$Rs, IntRegs:$Rt),
"$Rd = parity($Rs, $Rt)", [], "", ALU64_tc_2_SLOT23> {
bits<5> Rd;
let Inst{12-8} = Rt;
let Inst{4-0} = Rd;
}
+
// Add and accumulate.
// Rd=add(Rs,add(Ru,#s6))
let isExtentSigned = 1, hasNewValue = 1, isExtendable = 1, opExtentBits = 6,
- opExtendable = 3, isCodeGenOnly = 0 in
+ opExtendable = 3 in
def S4_addaddi : ALU64Inst <(outs IntRegs:$Rd),
(ins IntRegs:$Rs, IntRegs:$Ru, s6Ext:$s6),
"$Rd = add($Rs, add($Ru, #$s6))" ,
}
let isExtentSigned = 1, hasSideEffects = 0, hasNewValue = 1, isExtendable = 1,
- opExtentBits = 6, opExtendable = 2, isCodeGenOnly = 0 in
+ opExtentBits = 6, opExtendable = 2 in
def S4_subaddi: ALU64Inst <(outs IntRegs:$Rd),
(ins IntRegs:$Rs, s6Ext:$s6, IntRegs:$Ru),
"$Rd = add($Rs, sub(#$s6, $Ru))",
let Inst{7-5} = s6{2-0};
let Inst{4-0} = Ru;
}
-
+
// Extract bitfield
// Rdd=extract(Rss,#u6,#U6)
// Rdd=extract(Rss,Rtt)
// Rd=extract(Rs,Rtt)
// Rd=extract(Rs,#u5,#U5)
-let isCodeGenOnly = 0 in {
def S4_extractp_rp : T_S3op_64 < "extract", 0b11, 0b100, 0>;
def S4_extractp : T_S2op_extract <"extract", 0b1010, DoubleRegs, u6Imm>;
-}
-let hasNewValue = 1, isCodeGenOnly = 0 in {
+let hasNewValue = 1 in {
def S4_extract_rp : T_S3op_extract<"extract", 0b01>;
def S4_extract : T_S2op_extract <"extract", 0b1101, IntRegs, u5Imm>;
}
// Complex add/sub halfwords/words
-let Defs = [USR_OVF], isCodeGenOnly = 0 in {
+let Defs = [USR_OVF] in {
def S4_vxaddsubh : T_S3op_64 < "vxaddsubh", 0b01, 0b100, 0, 1>;
def S4_vxaddsubw : T_S3op_64 < "vxaddsubw", 0b01, 0b000, 0, 1>;
def S4_vxsubaddh : T_S3op_64 < "vxsubaddh", 0b01, 0b110, 0, 1>;
def S4_vxsubaddw : T_S3op_64 < "vxsubaddw", 0b01, 0b010, 0, 1>;
}
-let Defs = [USR_OVF], isCodeGenOnly = 0 in {
+let Defs = [USR_OVF] in {
def S4_vxaddsubhr : T_S3op_64 < "vxaddsubh", 0b11, 0b000, 0, 1, 1, 1>;
def S4_vxsubaddhr : T_S3op_64 < "vxsubaddh", 0b11, 0b010, 0, 1, 1, 1>;
}
-let Itinerary = M_tc_3x_SLOT23, Defs = [USR_OVF], isCodeGenOnly = 0 in {
+let Itinerary = M_tc_3x_SLOT23, Defs = [USR_OVF] in {
def M4_mac_up_s1_sat: T_MType_acc_rr<"+= mpy", 0b011, 0b000, 0, [], 0, 1, 1>;
def M4_nac_up_s1_sat: T_MType_acc_rr<"-= mpy", 0b011, 0b001, 0, [], 0, 1, 1>;
}
// Logical xor with xor accumulation.
// Rxx^=xor(Rss,Rtt)
-let hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasSideEffects = 0 in
def M4_xor_xacc
: SInst <(outs DoubleRegs:$Rxx),
(ins DoubleRegs:$dst2, DoubleRegs:$Rss, DoubleRegs:$Rtt),
let IClass = 0b1100;
- let Inst{27-23} = 0b10101;
+ let Inst{27-22} = 0b101010;
let Inst{20-16} = Rss;
let Inst{12-8} = Rtt;
+ let Inst{7-5} = 0b000;
let Inst{4-0} = Rxx;
}
// Rotate and reduce bytes
// Rdd=vrcrotate(Rss,Rt,#u2)
-let hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasSideEffects = 0 in
def S4_vrcrotate
: SInst <(outs DoubleRegs:$Rdd),
(ins DoubleRegs:$Rss, IntRegs:$Rt, u2Imm:$u2),
// Rotate and reduce bytes with accumulation
// Rxx+=vrcrotate(Rss,Rt,#u2)
-let hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasSideEffects = 0 in
def S4_vrcrotate_acc
: SInst <(outs DoubleRegs:$Rxx),
(ins DoubleRegs:$dst2, DoubleRegs:$Rss, IntRegs:$Rt, u2Imm:$u2),
let Inst{4-0} = Rxx;
}
-
// Vector reduce conditional negate halfwords
-let hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasSideEffects = 0 in
def S2_vrcnegh
: SInst <(outs DoubleRegs:$Rxx),
(ins DoubleRegs:$dst2, DoubleRegs:$Rss, IntRegs:$Rt),
}
// Split bitfield
-let isCodeGenOnly = 0 in
def A4_bitspliti : T_S2op_2_di <"bitsplit", 0b110, 0b100>;
// Arithmetic/Convergent round
-let isCodeGenOnly = 0 in
def A4_cround_ri : T_S2op_2_ii <"cround", 0b111, 0b000>;
-let isCodeGenOnly = 0 in
def A4_round_ri : T_S2op_2_ii <"round", 0b111, 0b100>;
-let Defs = [USR_OVF], isCodeGenOnly = 0 in
+let Defs = [USR_OVF] in
def A4_round_ri_sat : T_S2op_2_ii <"round", 0b111, 0b110, 1>;
// Logical-logical words.
// Compound or-and -- Rx=or(Ru,and(Rx,#s10))
let isExtentSigned = 1, hasNewValue = 1, isExtendable = 1, opExtentBits = 10,
- opExtendable = 3, isCodeGenOnly = 0 in
+ opExtendable = 3 in
def S4_or_andix:
ALU64Inst<(outs IntRegs:$Rx),
(ins IntRegs:$Ru, IntRegs:$_src_, s10Ext:$s10),
// Miscellaneous ALU64 instructions.
//
-let hasNewValue = 1, hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasNewValue = 1, hasSideEffects = 0 in
def A4_modwrapu: ALU64Inst<(outs IntRegs:$Rd), (ins IntRegs:$Rs, IntRegs:$Rt),
"$Rd = modwrap($Rs, $Rt)", [], "", ALU64_tc_2_SLOT23> {
bits<5> Rd;
let Inst{4-0} = Rd;
}
-let hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasSideEffects = 0 in
def A4_bitsplit: ALU64Inst<(outs DoubleRegs:$Rd),
(ins IntRegs:$Rs, IntRegs:$Rt),
"$Rd = bitsplit($Rs, $Rt)", [], "", ALU64_tc_1_SLOT23> {
let Inst{4-0} = Rd;
}
-let isCodeGenOnly = 0 in {
// Rx[&|]=xor(Rs,Rt)
def M4_or_xor : T_MType_acc_rr < "|= xor", 0b110, 0b001, 0>;
def M4_and_xor : T_MType_acc_rr < "&= xor", 0b010, 0b010, 0>;
def M4_xor_andn : T_MType_acc_rr < "^= and", 0b001, 0b010, 0, [], 1>;
def M4_or_andn : T_MType_acc_rr < "|= and", 0b001, 0b000, 0, [], 1>;
def M4_and_andn : T_MType_acc_rr < "&= and", 0b001, 0b001, 0, [], 1>;
-}
// Compound or-or and or-and
let isExtentSigned = 1, InputType = "imm", hasNewValue = 1, isExtendable = 1,
let Inst{4-0} = Rx;
}
-let CextOpcode = "ORr_ANDr", isCodeGenOnly = 0 in
+let CextOpcode = "ORr_ANDr" in
def S4_or_andi : T_CompOR <"and", 0b00, and>;
-let CextOpcode = "ORr_ORr", isCodeGenOnly = 0 in
+let CextOpcode = "ORr_ORr" in
def S4_or_ori : T_CompOR <"or", 0b10, or>;
// Modulo wrap
//===----------------------------------------------------------------------===//
// Bit reverse
-let isCodeGenOnly = 0 in
def S2_brevp : T_S2op_3 <"brev", 0b11, 0b110>;
// Bit count
-let isCodeGenOnly = 0 in {
def S2_ct0p : T_COUNT_LEADING_64<"ct0", 0b111, 0b010>;
def S2_ct1p : T_COUNT_LEADING_64<"ct1", 0b111, 0b100>;
def S4_clbpnorm : T_COUNT_LEADING_64<"normamt", 0b011, 0b000>;
-}
def: Pat<(i32 (trunc (cttz (i64 DoubleRegs:$Rss)))),
(S2_ct0p (i64 DoubleRegs:$Rss))>;
def: Pat<(i32 (trunc (cttz (not (i64 DoubleRegs:$Rss))))),
(S2_ct1p (i64 DoubleRegs:$Rss))>;
-let hasSideEffects = 0, hasNewValue = 1, isCodeGenOnly = 0 in
+let hasSideEffects = 0, hasNewValue = 1 in
def S4_clbaddi : SInst<(outs IntRegs:$Rd), (ins IntRegs:$Rs, s6Imm:$s6),
"$Rd = add(clb($Rs), #$s6)", [], "", S_2op_tc_2_SLOT23> {
bits<5> Rs;
let Inst{4-0} = Rd;
}
-let hasSideEffects = 0, hasNewValue = 1, isCodeGenOnly = 0 in
+let hasSideEffects = 0, hasNewValue = 1 in
def S4_clbpaddi : SInst<(outs IntRegs:$Rd), (ins DoubleRegs:$Rs, s6Imm:$s6),
"$Rd = add(clb($Rs), #$s6)", [], "", S_2op_tc_2_SLOT23> {
bits<5> Rs;
// Bit test/set/clear
-let isCodeGenOnly = 0 in {
def S4_ntstbit_i : T_TEST_BIT_IMM<"!tstbit", 0b001>;
def S4_ntstbit_r : T_TEST_BIT_REG<"!tstbit", 1>;
-}
let AddedComplexity = 20 in { // Complexity greater than cmp reg-imm.
def: Pat<(i1 (seteq (and (shl 1, u5ImmPred:$u5), (i32 IntRegs:$Rs)), 0)),
def: Pat<(i1 (seteq (and (i32 IntRegs:$Rs), (i32 Set5ImmPred:$u5)), (i32 0))),
(S4_ntstbit_i (i32 IntRegs:$Rs), (BITPOS32 Set5ImmPred:$u5))>;
-let isCodeGenOnly = 0 in {
def C4_nbitsset : T_TEST_BITS_REG<"!bitsset", 0b01, 1>;
def C4_nbitsclr : T_TEST_BITS_REG<"!bitsclr", 0b10, 1>;
def C4_nbitsclri : T_TEST_BITS_IMM<"!bitsclr", 0b10, 1>;
-}
// Do not increase complexity of these patterns. In the DAG, "cmp i8" may be
// represented as a compare against "value & 0xFF", which is an exact match
// Rd=add(#u6,mpyi(Rs,#U6)) -- Multiply by immed and add immed.
-let hasNewValue = 1, isExtendable = 1, opExtentBits = 6, opExtendable = 1,
- isCodeGenOnly = 0 in
+let hasNewValue = 1, isExtendable = 1, opExtentBits = 6, opExtendable = 1 in
def M4_mpyri_addi : MInst<(outs IntRegs:$Rd),
(ins u6Ext:$u6, IntRegs:$Rs, u6Imm:$U6),
"$Rd = add(#$u6, mpyi($Rs, #$U6))" ,
// Rd=add(#u6,mpyi(Rs,Rt))
let CextOpcode = "ADD_MPY", InputType = "imm", hasNewValue = 1,
- isExtendable = 1, opExtentBits = 6, opExtendable = 1, isCodeGenOnly = 0 in
+ isExtendable = 1, opExtentBits = 6, opExtendable = 1 in
def M4_mpyrr_addi : MInst <(outs IntRegs:$Rd),
(ins u6Ext:$u6, IntRegs:$Rs, IntRegs:$Rt),
"$Rd = add(#$u6, mpyi($Rs, $Rt))" ,
let Inst{4-0} = src1;
}
-let isCodeGenOnly = 0 in
def M4_mpyri_addr_u2 : T_AddMpy<0b0, u6_2ImmPred,
(ins IntRegs:$src1, u6_2Imm:$src2, IntRegs:$src3)>;
let isExtendable = 1, opExtentBits = 6, opExtendable = 3,
- CextOpcode = "ADD_MPY", InputType = "imm", isCodeGenOnly = 0 in
+ CextOpcode = "ADD_MPY", InputType = "imm" in
def M4_mpyri_addr : T_AddMpy<0b1, u6ExtPred,
(ins IntRegs:$src1, IntRegs:$src3, u6Ext:$src2)>, ImmRegRel;
// Rx=add(Ru,mpyi(Rx,Rs))
let validSubTargets = HasV4SubT, CextOpcode = "ADD_MPY", InputType = "reg",
- hasNewValue = 1, isCodeGenOnly = 0 in
+ hasNewValue = 1 in
def M4_mpyrr_addr: MInst_acc <(outs IntRegs:$Rx),
(ins IntRegs:$Ru, IntRegs:$_src_, IntRegs:$Rs),
"$Rx = add($Ru, mpyi($_src_, $Rs))",
// Vector reduce multiply word by signed half (32x16)
//Rdd=vrmpyweh(Rss,Rtt)[:<<1]
-let isCodeGenOnly = 0 in {
def M4_vrmpyeh_s0 : T_M2_vmpy<"vrmpyweh", 0b010, 0b100, 0, 0, 0>;
def M4_vrmpyeh_s1 : T_M2_vmpy<"vrmpyweh", 0b110, 0b100, 1, 0, 0>;
-}
//Rdd=vrmpywoh(Rss,Rtt)[:<<1]
-let isCodeGenOnly = 0 in {
def M4_vrmpyoh_s0 : T_M2_vmpy<"vrmpywoh", 0b001, 0b010, 0, 0, 0>;
def M4_vrmpyoh_s1 : T_M2_vmpy<"vrmpywoh", 0b101, 0b010, 1, 0, 0>;
-}
+
//Rdd+=vrmpyweh(Rss,Rtt)[:<<1]
-let isCodeGenOnly = 0 in {
def M4_vrmpyeh_acc_s0: T_M2_vmpy_acc<"vrmpyweh", 0b001, 0b110, 0, 0>;
def M4_vrmpyeh_acc_s1: T_M2_vmpy_acc<"vrmpyweh", 0b101, 0b110, 1, 0>;
-}
//Rdd=vrmpywoh(Rss,Rtt)[:<<1]
-let isCodeGenOnly = 0 in {
def M4_vrmpyoh_acc_s0: T_M2_vmpy_acc<"vrmpywoh", 0b011, 0b110, 0, 0>;
def M4_vrmpyoh_acc_s1: T_M2_vmpy_acc<"vrmpywoh", 0b111, 0b110, 1, 0>;
-}
// Vector multiply halfwords, signed by unsigned
// Rdd=vmpyhsu(Rs,Rt)[:<<]:sat
-let isCodeGenOnly = 0 in {
def M2_vmpy2su_s0 : T_XTYPE_mpy64 < "vmpyhsu", 0b000, 0b111, 1, 0, 0>;
def M2_vmpy2su_s1 : T_XTYPE_mpy64 < "vmpyhsu", 0b100, 0b111, 1, 1, 0>;
-}
// Rxx+=vmpyhsu(Rs,Rt)[:<<1]:sat
-let isCodeGenOnly = 0 in {
def M2_vmac2su_s0 : T_XTYPE_mpy64_acc < "vmpyhsu", "+", 0b011, 0b101, 1, 0, 0>;
def M2_vmac2su_s1 : T_XTYPE_mpy64_acc < "vmpyhsu", "+", 0b111, 0b101, 1, 1, 0>;
-}
// Vector polynomial multiply halfwords
// Rdd=vpmpyh(Rs,Rt)
-let isCodeGenOnly = 0 in
def M4_vpmpyh : T_XTYPE_mpy64 < "vpmpyh", 0b110, 0b111, 0, 0, 0>;
// Rxx^=vpmpyh(Rs,Rt)
-let isCodeGenOnly = 0 in
def M4_vpmpyh_acc : T_XTYPE_mpy64_acc < "vpmpyh", "^", 0b101, 0b111, 0, 0, 0>;
// Polynomial multiply words
// Rdd=pmpyw(Rs,Rt)
-let isCodeGenOnly = 0 in
def M4_pmpyw : T_XTYPE_mpy64 < "pmpyw", 0b010, 0b111, 0, 0, 0>;
// Rxx^=pmpyw(Rs,Rt)
-let isCodeGenOnly = 0 in
def M4_pmpyw_acc : T_XTYPE_mpy64_acc < "pmpyw", "^", 0b001, 0b111, 0, 0, 0>;
//===----------------------------------------------------------------------===//
// XTYPE/MPY -
//===----------------------------------------------------------------------===//
-
//===----------------------------------------------------------------------===//
// ALU64/Vector compare
//===----------------------------------------------------------------------===//
}
// Vector compare bytes
-let isCodeGenOnly = 0 in
def A4_vcmpbgt : T_vcmp <"vcmpb.gt", 0b1010>;
def: T_vcmp_pat<A4_vcmpbgt, setgt, v8i8>;
let AsmString = "$Pd = any8(vcmpb.eq($Rss, $Rtt))" in
-let isCodeGenOnly = 0 in
def A4_vcmpbeq_any : T_vcmp <"any8(vcmpb.gt", 0b1000>;
-let isCodeGenOnly = 0 in {
def A4_vcmpbeqi : T_vcmpImm <"vcmpb.eq", 0b00, 0b00, u8Imm>;
def A4_vcmpbgti : T_vcmpImm <"vcmpb.gt", 0b01, 0b00, s8Imm>;
def A4_vcmpbgtui : T_vcmpImm <"vcmpb.gtu", 0b10, 0b00, u7Imm>;
-}
// Vector compare halfwords
-let isCodeGenOnly = 0 in {
def A4_vcmpheqi : T_vcmpImm <"vcmph.eq", 0b00, 0b01, s8Imm>;
def A4_vcmphgti : T_vcmpImm <"vcmph.gt", 0b01, 0b01, s8Imm>;
def A4_vcmphgtui : T_vcmpImm <"vcmph.gtu", 0b10, 0b01, u7Imm>;
-}
// Vector compare words
-let isCodeGenOnly = 0 in {
def A4_vcmpweqi : T_vcmpImm <"vcmpw.eq", 0b00, 0b10, s8Imm>;
def A4_vcmpwgti : T_vcmpImm <"vcmpw.gt", 0b01, 0b10, s8Imm>;
def A4_vcmpwgtui : T_vcmpImm <"vcmpw.gtu", 0b10, 0b10, u7Imm>;
-}
//===----------------------------------------------------------------------===//
// XTYPE/SHIFT +
def _lsr_ri : T_S4_ShiftOperate<mnemonic, "lsr", Op, srl, 1, MajOp, Itin>;
}
-let AddedComplexity = 200, isCodeGenOnly = 0 in {
+let AddedComplexity = 200 in {
defm S4_addi : T_ShiftOperate<"add", add, 0b10, ALU64_tc_2_SLOT23>;
defm S4_andi : T_ShiftOperate<"and", and, 0b00, ALU64_tc_2_SLOT23>;
}
-let AddedComplexity = 30, isCodeGenOnly = 0 in
+let AddedComplexity = 30 in
defm S4_ori : T_ShiftOperate<"or", or, 0b01, ALU64_tc_1_SLOT23>;
-let isCodeGenOnly = 0 in
defm S4_subi : T_ShiftOperate<"sub", sub, 0b11, ALU64_tc_1_SLOT23>;
// Vector conditional negate
// Rdd=vcnegh(Rss,Rt)
-let Defs = [USR_OVF], Itinerary = S_3op_tc_2_SLOT23, isCodeGenOnly = 0 in
+let Defs = [USR_OVF], Itinerary = S_3op_tc_2_SLOT23 in
def S2_vcnegh : T_S3op_shiftVect < "vcnegh", 0b11, 0b01>;
// Rd=[cround|round](Rs,Rt)
-let hasNewValue = 1, Itinerary = S_3op_tc_2_SLOT23, isCodeGenOnly = 0 in {
+let hasNewValue = 1, Itinerary = S_3op_tc_2_SLOT23 in {
def A4_cround_rr : T_S3op_3 < "cround", IntRegs, 0b11, 0b00>;
def A4_round_rr : T_S3op_3 < "round", IntRegs, 0b11, 0b10>;
}
// Rd=round(Rs,Rt):sat
-let hasNewValue = 1, Defs = [USR_OVF], Itinerary = S_3op_tc_2_SLOT23,
- isCodeGenOnly = 0 in
+let hasNewValue = 1, Defs = [USR_OVF], Itinerary = S_3op_tc_2_SLOT23 in
def A4_round_rr_sat : T_S3op_3 < "round", IntRegs, 0b11, 0b11, 1>;
// Rd=[cmpyiwh|cmpyrwh](Rss,Rt):<<1:rnd:sat
-let Defs = [USR_OVF], Itinerary = S_3op_tc_3x_SLOT23, isCodeGenOnly = 0 in {
+let Defs = [USR_OVF], Itinerary = S_3op_tc_3x_SLOT23 in {
def M4_cmpyi_wh : T_S3op_8<"cmpyiwh", 0b100, 1, 1, 1>;
def M4_cmpyr_wh : T_S3op_8<"cmpyrwh", 0b110, 1, 1, 1>;
}
let Inst{4-0} = Rdd;
}
-let isCodeGenOnly = 0 in {
def A4_addp_c : T_S3op_carry < "add", 0b110 >;
def A4_subp_c : T_S3op_carry < "sub", 0b111 >;
-}
let Itinerary = S_3op_tc_3_SLOT23, hasSideEffects = 0 in
class T_S3op_6 <string mnemonic, bits<3> MinOp, bit isUnsigned>
// Vector reduce maximum halfwords
// Rxx=vrmax[u]h(Rss,Ru)
-let isCodeGenOnly = 0 in {
def A4_vrmaxh : T_S3op_6 < "vrmaxh", 0b001, 0>;
def A4_vrmaxuh : T_S3op_6 < "vrmaxuh", 0b001, 1>;
-}
+
// Vector reduce maximum words
// Rxx=vrmax[u]w(Rss,Ru)
-let isCodeGenOnly = 0 in {
def A4_vrmaxw : T_S3op_6 < "vrmaxw", 0b010, 0>;
def A4_vrmaxuw : T_S3op_6 < "vrmaxuw", 0b010, 1>;
-}
+
// Vector reduce minimum halfwords
// Rxx=vrmin[u]h(Rss,Ru)
-let isCodeGenOnly = 0 in {
def A4_vrminh : T_S3op_6 < "vrminh", 0b101, 0>;
def A4_vrminuh : T_S3op_6 < "vrminuh", 0b101, 1>;
-}
// Vector reduce minimum words
// Rxx=vrmin[u]w(Rss,Ru)
-let isCodeGenOnly = 0 in {
def A4_vrminw : T_S3op_6 < "vrminw", 0b110, 0>;
def A4_vrminuw : T_S3op_6 < "vrminuw", 0b110, 1>;
-}
// Shift an immediate left by register amount.
-let hasNewValue = 1, hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasNewValue = 1, hasSideEffects = 0 in
def S4_lsli: SInst <(outs IntRegs:$Rd), (ins s6Imm:$s6, IntRegs:$Rt),
"$Rd = lsl(#$s6, $Rt)" ,
[(set (i32 IntRegs:$Rd), (shl s6ImmPred:$s6,
// Define MemOp instructions.
let isExtendable = 1, opExtendable = 1, isExtentSigned = 0,
validSubTargets =HasV4SubT in {
- let opExtentBits = 6, accessSize = ByteAccess, isCodeGenOnly = 0 in
+ let opExtentBits = 6, accessSize = ByteAccess in
defm memopb_io : MemOp_base <"memb", 0b00, u6_0Ext>;
- let opExtentBits = 7, accessSize = HalfWordAccess, isCodeGenOnly = 0 in
+ let opExtentBits = 7, accessSize = HalfWordAccess in
defm memoph_io : MemOp_base <"memh", 0b01, u6_1Ext>;
- let opExtentBits = 8, accessSize = WordAccess, isCodeGenOnly = 0 in
+ let opExtentBits = 8, accessSize = WordAccess in
defm memopw_io : MemOp_base <"memw", 0b10, u6_2Ext>;
}
multiclass MemOpi_u5Pats <PatFrag ldOp, PatFrag stOp, PatLeaf ExtPred,
InstHexagon MI, SDNode OpNode> {
let AddedComplexity = 180 in
- def : Pat < (stOp (OpNode (ldOp IntRegs:$addr), u5ImmPred:$addend),
- IntRegs:$addr),
- (MI IntRegs:$addr, #0, u5ImmPred:$addend )>;
+ def: Pat<(stOp (OpNode (ldOp IntRegs:$addr), u5ImmPred:$addend),
+ IntRegs:$addr),
+ (MI IntRegs:$addr, 0, u5ImmPred:$addend)>;
let AddedComplexity = 190 in
- def : Pat <(stOp (OpNode (ldOp (add IntRegs:$base, ExtPred:$offset)),
- u5ImmPred:$addend),
- (add IntRegs:$base, ExtPred:$offset)),
- (MI IntRegs:$base, ExtPred:$offset, u5ImmPred:$addend)>;
+ def: Pat<(stOp (OpNode (ldOp (add IntRegs:$base, ExtPred:$offset)),
+ u5ImmPred:$addend),
+ (add IntRegs:$base, ExtPred:$offset)),
+ (MI IntRegs:$base, ExtPred:$offset, u5ImmPred:$addend)>;
}
multiclass MemOpi_u5ALUOp<PatFrag ldOp, PatFrag stOp, PatLeaf ExtPred,
InstHexagon addMI, InstHexagon subMI> {
- defm : MemOpi_u5Pats<ldOp, stOp, ExtPred, addMI, add>;
- defm : MemOpi_u5Pats<ldOp, stOp, ExtPred, subMI, sub>;
+ defm: MemOpi_u5Pats<ldOp, stOp, ExtPred, addMI, add>;
+ defm: MemOpi_u5Pats<ldOp, stOp, ExtPred, subMI, sub>;
}
multiclass MemOpi_u5ExtType<PatFrag ldOpByte, PatFrag ldOpHalf > {
// Half Word
- defm : MemOpi_u5ALUOp <ldOpHalf, truncstorei16, u6_1ExtPred,
- L4_iadd_memoph_io, L4_isub_memoph_io>;
+ defm: MemOpi_u5ALUOp <ldOpHalf, truncstorei16, u6_1ExtPred,
+ L4_iadd_memoph_io, L4_isub_memoph_io>;
// Byte
- defm : MemOpi_u5ALUOp <ldOpByte, truncstorei8, u6ExtPred,
- L4_iadd_memopb_io, L4_isub_memopb_io>;
+ defm: MemOpi_u5ALUOp <ldOpByte, truncstorei8, u6ExtPred,
+ L4_iadd_memopb_io, L4_isub_memopb_io>;
}
let Predicates = [HasV4T, UseMEMOP] in {
- defm : MemOpi_u5ExtType<zextloadi8, zextloadi16>; // zero extend
- defm : MemOpi_u5ExtType<sextloadi8, sextloadi16>; // sign extend
- defm : MemOpi_u5ExtType<extloadi8, extloadi16>; // any extend
+ defm: MemOpi_u5ExtType<zextloadi8, zextloadi16>; // zero extend
+ defm: MemOpi_u5ExtType<sextloadi8, sextloadi16>; // sign extend
+ defm: MemOpi_u5ExtType<extloadi8, extloadi16>; // any extend
// Word
- defm : MemOpi_u5ALUOp <load, store, u6_2ExtPred, L4_iadd_memopw_io,
- L4_isub_memopw_io>;
+ defm: MemOpi_u5ALUOp <load, store, u6_2ExtPred, L4_iadd_memopw_io,
+ L4_isub_memopw_io>;
}
//===----------------------------------------------------------------------===//
PatLeaf immPred, ComplexPattern addrPred,
SDNodeXForm xformFunc, InstHexagon MI> {
let AddedComplexity = 190 in
- def : Pat <(stOp (add (ldOp IntRegs:$addr), immPred:$subend),
- IntRegs:$addr),
- (MI IntRegs:$addr, #0, (xformFunc immPred:$subend) )>;
+ def: Pat<(stOp (add (ldOp IntRegs:$addr), immPred:$subend), IntRegs:$addr),
+ (MI IntRegs:$addr, 0, (xformFunc immPred:$subend))>;
let AddedComplexity = 195 in
- def : Pat<(stOp (add (ldOp (add IntRegs:$base, extPred:$offset)),
- immPred:$subend),
- (add IntRegs:$base, extPred:$offset)),
- (MI IntRegs:$base, extPred:$offset, (xformFunc immPred:$subend))>;
+ def: Pat<(stOp (add (ldOp (add IntRegs:$base, extPred:$offset)),
+ immPred:$subend),
+ (add IntRegs:$base, extPred:$offset)),
+ (MI IntRegs:$base, extPred:$offset, (xformFunc immPred:$subend))>;
}
multiclass MemOpi_m5ExtType<PatFrag ldOpByte, PatFrag ldOpHalf > {
// Half Word
- defm : MemOpi_m5Pats <ldOpHalf, truncstorei16, u6_1ExtPred, m5HImmPred,
+ defm: MemOpi_m5Pats <ldOpHalf, truncstorei16, u6_1ExtPred, m5HImmPred,
ADDRriU6_1, MEMOPIMM_HALF, L4_isub_memoph_io>;
// Byte
- defm : MemOpi_m5Pats <ldOpByte, truncstorei8, u6ExtPred, m5BImmPred,
+ defm: MemOpi_m5Pats <ldOpByte, truncstorei8, u6ExtPred, m5BImmPred,
ADDRriU6_0, MEMOPIMM_BYTE, L4_isub_memopb_io>;
}
let Predicates = [HasV4T, UseMEMOP] in {
- defm : MemOpi_m5ExtType<zextloadi8, zextloadi16>; // zero extend
- defm : MemOpi_m5ExtType<sextloadi8, sextloadi16>; // sign extend
- defm : MemOpi_m5ExtType<extloadi8, extloadi16>; // any extend
+ defm: MemOpi_m5ExtType<zextloadi8, zextloadi16>; // zero extend
+ defm: MemOpi_m5ExtType<sextloadi8, sextloadi16>; // sign extend
+ defm: MemOpi_m5ExtType<extloadi8, extloadi16>; // any extend
// Word
- defm : MemOpi_m5Pats <load, store, u6_2ExtPred, m5ImmPred,
+ defm: MemOpi_m5Pats <load, store, u6_2ExtPred, m5ImmPred,
ADDRriU6_2, MEMOPIMM, L4_isub_memopw_io>;
}
// mem[bhw](Rs+#u6:[012]) = [clrbit|setbit](#U5)
let AddedComplexity = 250 in
- def : Pat<(stOp (OpNode (ldOp (add IntRegs:$base, extPred:$offset)),
- immPred:$bitend),
- (add IntRegs:$base, extPred:$offset)),
- (MI IntRegs:$base, extPred:$offset, (xformFunc immPred:$bitend))>;
+ def: Pat<(stOp (OpNode (ldOp (add IntRegs:$base, extPred:$offset)),
+ immPred:$bitend),
+ (add IntRegs:$base, extPred:$offset)),
+ (MI IntRegs:$base, extPred:$offset, (xformFunc immPred:$bitend))>;
// mem[bhw](Rs+#0) = [clrbit|setbit](#U5)
let AddedComplexity = 225 in
- def : Pat <(stOp (OpNode (ldOp (addrPred IntRegs:$addr, extPred:$offset)),
- immPred:$bitend),
- (addrPred (i32 IntRegs:$addr), extPred:$offset)),
- (MI IntRegs:$addr, extPred:$offset, (xformFunc immPred:$bitend))>;
+ def: Pat<(stOp (OpNode (ldOp (addrPred IntRegs:$addr, extPred:$offset)),
+ immPred:$bitend),
+ (addrPred (i32 IntRegs:$addr), extPred:$offset)),
+ (MI IntRegs:$addr, extPred:$offset, (xformFunc immPred:$bitend))>;
}
multiclass MemOpi_bitExtType<PatFrag ldOpByte, PatFrag ldOpHalf > {
// Byte - clrbit
- defm : MemOpi_bitPats<ldOpByte, truncstorei8, Clr3ImmPred, u6ExtPred,
+ defm: MemOpi_bitPats<ldOpByte, truncstorei8, Clr3ImmPred, u6ExtPred,
ADDRriU6_0, CLRMEMIMM_BYTE, L4_iand_memopb_io, and>;
// Byte - setbit
- defm : MemOpi_bitPats<ldOpByte, truncstorei8, Set3ImmPred, u6ExtPred,
+ defm: MemOpi_bitPats<ldOpByte, truncstorei8, Set3ImmPred, u6ExtPred,
ADDRriU6_0, SETMEMIMM_BYTE, L4_ior_memopb_io, or>;
// Half Word - clrbit
- defm : MemOpi_bitPats<ldOpHalf, truncstorei16, Clr4ImmPred, u6_1ExtPred,
+ defm: MemOpi_bitPats<ldOpHalf, truncstorei16, Clr4ImmPred, u6_1ExtPred,
ADDRriU6_1, CLRMEMIMM_SHORT, L4_iand_memoph_io, and>;
// Half Word - setbit
- defm : MemOpi_bitPats<ldOpHalf, truncstorei16, Set4ImmPred, u6_1ExtPred,
+ defm: MemOpi_bitPats<ldOpHalf, truncstorei16, Set4ImmPred, u6_1ExtPred,
ADDRriU6_1, SETMEMIMM_SHORT, L4_ior_memoph_io, or>;
}
let Predicates = [HasV4T, UseMEMOP] in {
// mem[bh](Rs+#0) = [clrbit|setbit](#U5)
// mem[bh](Rs+#u6:[01]) = [clrbit|setbit](#U5)
- defm : MemOpi_bitExtType<zextloadi8, zextloadi16>; // zero extend
- defm : MemOpi_bitExtType<sextloadi8, sextloadi16>; // sign extend
- defm : MemOpi_bitExtType<extloadi8, extloadi16>; // any extend
+ defm: MemOpi_bitExtType<zextloadi8, zextloadi16>; // zero extend
+ defm: MemOpi_bitExtType<sextloadi8, sextloadi16>; // sign extend
+ defm: MemOpi_bitExtType<extloadi8, extloadi16>; // any extend
// memw(Rs+#0) = [clrbit|setbit](#U5)
// memw(Rs+#u6:2) = [clrbit|setbit](#U5)
- defm : MemOpi_bitPats<load, store, Clr5ImmPred, u6_2ExtPred, ADDRriU6_2,
+ defm: MemOpi_bitPats<load, store, Clr5ImmPred, u6_2ExtPred, ADDRriU6_2,
CLRMEMIMM, L4_iand_memopw_io, and>;
- defm : MemOpi_bitPats<load, store, Set5ImmPred, u6_2ExtPred, ADDRriU6_2,
+ defm: MemOpi_bitPats<load, store, Set5ImmPred, u6_2ExtPred, ADDRriU6_2,
SETMEMIMM, L4_ior_memopw_io, or>;
}
PatLeaf extPred, InstHexagon MI, SDNode OpNode> {
let AddedComplexity = 141 in
// mem[bhw](Rs+#0) [+-&|]= Rt
- def : Pat <(stOp (OpNode (ldOp (addrPred IntRegs:$addr, extPred:$offset)),
- (i32 IntRegs:$addend)),
- (addrPred (i32 IntRegs:$addr), extPred:$offset)),
- (MI IntRegs:$addr, extPred:$offset, (i32 IntRegs:$addend) )>;
+ def: Pat<(stOp (OpNode (ldOp (addrPred IntRegs:$addr, extPred:$offset)),
+ (i32 IntRegs:$addend)),
+ (addrPred (i32 IntRegs:$addr), extPred:$offset)),
+ (MI IntRegs:$addr, extPred:$offset, (i32 IntRegs:$addend) )>;
// mem[bhw](Rs+#U6:[012]) [+-&|]= Rt
let AddedComplexity = 150 in
- def : Pat <(stOp (OpNode (ldOp (add IntRegs:$base, extPred:$offset)),
- (i32 IntRegs:$orend)),
- (add IntRegs:$base, extPred:$offset)),
- (MI IntRegs:$base, extPred:$offset, (i32 IntRegs:$orend) )>;
+ def: Pat<(stOp (OpNode (ldOp (add IntRegs:$base, extPred:$offset)),
+ (i32 IntRegs:$orend)),
+ (add IntRegs:$base, extPred:$offset)),
+ (MI IntRegs:$base, extPred:$offset, (i32 IntRegs:$orend))>;
}
multiclass MemOPr_ALUOp<PatFrag ldOp, PatFrag stOp,
InstHexagon addMI, InstHexagon subMI,
InstHexagon andMI, InstHexagon orMI > {
- defm : MemOpr_Pats <ldOp, stOp, addrPred, extPred, addMI, add>;
- defm : MemOpr_Pats <ldOp, stOp, addrPred, extPred, subMI, sub>;
- defm : MemOpr_Pats <ldOp, stOp, addrPred, extPred, andMI, and>;
- defm : MemOpr_Pats <ldOp, stOp, addrPred, extPred, orMI, or>;
+ defm: MemOpr_Pats <ldOp, stOp, addrPred, extPred, addMI, add>;
+ defm: MemOpr_Pats <ldOp, stOp, addrPred, extPred, subMI, sub>;
+ defm: MemOpr_Pats <ldOp, stOp, addrPred, extPred, andMI, and>;
+ defm: MemOpr_Pats <ldOp, stOp, addrPred, extPred, orMI, or>;
}
multiclass MemOPr_ExtType<PatFrag ldOpByte, PatFrag ldOpHalf > {
// Half Word
- defm : MemOPr_ALUOp <ldOpHalf, truncstorei16, ADDRriU6_1, u6_1ExtPred,
- L4_add_memoph_io, L4_sub_memoph_io,
- L4_and_memoph_io, L4_or_memoph_io>;
+ defm: MemOPr_ALUOp <ldOpHalf, truncstorei16, ADDRriU6_1, u6_1ExtPred,
+ L4_add_memoph_io, L4_sub_memoph_io,
+ L4_and_memoph_io, L4_or_memoph_io>;
// Byte
- defm : MemOPr_ALUOp <ldOpByte, truncstorei8, ADDRriU6_0, u6ExtPred,
- L4_add_memopb_io, L4_sub_memopb_io,
- L4_and_memopb_io, L4_or_memopb_io>;
+ defm: MemOPr_ALUOp <ldOpByte, truncstorei8, ADDRriU6_0, u6ExtPred,
+ L4_add_memopb_io, L4_sub_memopb_io,
+ L4_and_memopb_io, L4_or_memopb_io>;
}
// Define 'def Pats' for MemOps with register addend.
let Predicates = [HasV4T, UseMEMOP] in {
// Byte, Half Word
- defm : MemOPr_ExtType<zextloadi8, zextloadi16>; // zero extend
- defm : MemOPr_ExtType<sextloadi8, sextloadi16>; // sign extend
- defm : MemOPr_ExtType<extloadi8, extloadi16>; // any extend
+ defm: MemOPr_ExtType<zextloadi8, zextloadi16>; // zero extend
+ defm: MemOPr_ExtType<sextloadi8, sextloadi16>; // sign extend
+ defm: MemOPr_ExtType<extloadi8, extloadi16>; // any extend
// Word
- defm : MemOPr_ALUOp <load, store, ADDRriU6_2, u6_2ExtPred, L4_add_memopw_io,
- L4_sub_memopw_io, L4_and_memopw_io, L4_or_memopw_io >;
+ defm: MemOPr_ALUOp <load, store, ADDRriU6_2, u6_2ExtPred, L4_add_memopw_io,
+ L4_sub_memopw_io, L4_and_memopw_io, L4_or_memopw_io>;
}
//===----------------------------------------------------------------------===//
// Pd=cmpb.eq(Rs,#u8)
// p=!cmp.eq(r1,#s10)
-let isCodeGenOnly = 0 in {
def C4_cmpneqi : T_CMP <"cmp.eq", 0b00, 1, s10Ext>;
def C4_cmpltei : T_CMP <"cmp.gt", 0b01, 1, s10Ext>;
def C4_cmplteui : T_CMP <"cmp.gtu", 0b10, 1, u9Ext>;
-}
def : T_CMP_pat <C4_cmpneqi, setne, s10ExtPred>;
def : T_CMP_pat <C4_cmpltei, setle, s10ExtPred>;
// zext( setult ( and(Rs, 255), u8))
// Use the isdigit transformation below
-// Generate code of the form 'mux_ii(cmpbgtu(Rdd, C-1),0,1)'
+// Generate code of the form 'C2_muxii(cmpbgtui(Rdd, C-1),0,1)'
// for C code of the form r = ((c>='0') & (c<='9')) ? 1 : 0;.
// The isdigit transformation relies on two 'clever' aspects:
// 1) The data type is unsigned which allows us to eliminate a zero test after
// The code is transformed upstream of llvm into
// retval = (c-48) < 10 ? 1 : 0;
let AddedComplexity = 139 in
-def : Pat <(i32 (zext (i1 (setult (i32 (and (i32 IntRegs:$src1), 255)),
- u7StrictPosImmPred:$src2)))),
- (i32 (C2_muxii (i1 (A4_cmpbgtui (i32 IntRegs:$src1),
- (DEC_CONST_BYTE u7StrictPosImmPred:$src2))),
- 0, 1))>,
- Requires<[HasV4T]>;
+def: Pat<(i32 (zext (i1 (setult (i32 (and (i32 IntRegs:$src1), 255)),
+ u7StrictPosImmPred:$src2)))),
+ (C2_muxii (A4_cmpbgtui IntRegs:$src1,
+ (DEC_CONST_BYTE u7StrictPosImmPred:$src2)),
+ 0, 1)>, Requires<[HasV4T]>;
//===----------------------------------------------------------------------===//
// XTYPE/PRED -
let isReturn = 1, isTerminator = 1,
Defs = [R29, R30, R31, PC], Uses = [R30], hasSideEffects = 0,
- validSubTargets = HasV4SubT, isCodeGenOnly = 0 in
+ validSubTargets = HasV4SubT in
defm L4_return: LD_MISC_L4_RETURN <"dealloc_return">, PredNewRel;
// Restore registers and dealloc return function call.
//===----------------------------------------------------------------------===//
// Stores with absolute addressing
//===----------------------------------------------------------------------===//
-let accessSize = ByteAccess, isCodeGenOnly = 0 in
+let accessSize = ByteAccess in
defm storerb : ST_Abs <"memb", "STrib", IntRegs, u16_0Imm, 0b00>,
ST_Abs_NV <"memb", "STrib", u16_0Imm, 0b00>;
-let accessSize = HalfWordAccess, isCodeGenOnly = 0 in
+let accessSize = HalfWordAccess in
defm storerh : ST_Abs <"memh", "STrih", IntRegs, u16_1Imm, 0b01>,
ST_Abs_NV <"memh", "STrih", u16_1Imm, 0b01>;
-let accessSize = WordAccess, isCodeGenOnly = 0 in
+let accessSize = WordAccess in
defm storeri : ST_Abs <"memw", "STriw", IntRegs, u16_2Imm, 0b10>,
ST_Abs_NV <"memw", "STriw", u16_2Imm, 0b10>;
-let isNVStorable = 0, accessSize = DoubleWordAccess, isCodeGenOnly = 0 in
+let isNVStorable = 0, accessSize = DoubleWordAccess in
defm storerd : ST_Abs <"memd", "STrid", DoubleRegs, u16_3Imm, 0b11>;
-let isNVStorable = 0, accessSize = HalfWordAccess, isCodeGenOnly = 0 in
+let isNVStorable = 0, accessSize = HalfWordAccess in
defm storerf : ST_Abs <"memh", "STrif", IntRegs, u16_1Imm, 0b01, 1>;
//===----------------------------------------------------------------------===//
!if (!eq(ImmOpStr, "u16_1Imm"), 1,
/* u16_0Imm */ 0)));
}
+
//===----------------------------------------------------------------------===//
// Template class for predicated load instructions with
// absolute addressing mode.
//===----------------------------------------------------------------------===//
-let isPredicated = 1, hasNewValue = 1, opExtentBits = 6, opExtendable = 2 in
+let isPredicated = 1, opExtentBits = 6, opExtendable = 2 in
class T_LoadAbs_Pred <string mnemonic, RegisterClass RC, bits<3> MajOp,
bit isPredNot, bit isPredNew>
: LDInst <(outs RC:$dst), (ins PredRegs:$src1, u6Ext:$absaddr),
let isPredicatedNew = isPredNew;
let isPredicatedFalse = isPredNot;
+ let hasNewValue = !if (!eq(!cast<string>(RC), "DoubleRegs"), 0, 1);
let IClass = 0b1001;
}
}
-let accessSize = ByteAccess, hasNewValue = 1, isCodeGenOnly = 0 in {
+let accessSize = ByteAccess, hasNewValue = 1 in {
defm loadrb : LD_Abs<"memb", "LDrib", IntRegs, u16_0Imm, 0b000>;
defm loadrub : LD_Abs<"memub", "LDriub", IntRegs, u16_0Imm, 0b001>;
}
-let accessSize = HalfWordAccess, hasNewValue = 1, isCodeGenOnly = 0 in {
+let accessSize = HalfWordAccess, hasNewValue = 1 in {
defm loadrh : LD_Abs<"memh", "LDrih", IntRegs, u16_1Imm, 0b010>;
defm loadruh : LD_Abs<"memuh", "LDriuh", IntRegs, u16_1Imm, 0b011>;
}
-let accessSize = WordAccess, hasNewValue = 1, isCodeGenOnly = 0 in
+let accessSize = WordAccess, hasNewValue = 1 in
defm loadri : LD_Abs<"memw", "LDriw", IntRegs, u16_2Imm, 0b100>;
-let accessSize = DoubleWordAccess, isCodeGenOnly = 0 in
+let accessSize = DoubleWordAccess in
defm loadrd : LD_Abs<"memd", "LDrid", DoubleRegs, u16_3Imm, 0b110>;
//===----------------------------------------------------------------------===//
def: Loadam_pat<extloadi32, i64, addrga, Zext64, L4_loadri_abs>;
def: Loadam_pat<sextloadi32, i64, addrga, Sext64, L4_loadri_abs>;
def: Loadam_pat<zextloadi32, i64, addrga, Zext64, L4_loadri_abs>;
+}
let AddedComplexity = 100 in {
def: Loada_pat<extloadi8, i32, addrgp, L4_loadrub_abs>;
def: Loada_pat<load, i32, addrgp, L4_loadri_abs>;
def: Loada_pat<load, i64, addrgp, L4_loadrd_abs>;
}
-}
+
let AddedComplexity = 100 in {
def: Storea_pat<truncstorei8, I32, addrgp, S2_storerbabs>;
def: Storea_pat<truncstorei16, I32, addrgp, S2_storerhabs>;
//===----------------------------------------------------------------------===//
// A4_boundscheck_lo: Detect if a register is within bounds.
-let hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasSideEffects = 0 in
def A4_boundscheck_lo: ALU64Inst <
(outs PredRegs:$Pd),
(ins DoubleRegs:$Rss, DoubleRegs:$Rtt),
}
// A4_boundscheck_hi: Detect if a register is within bounds.
-let hasSideEffects = 0, isCodeGenOnly = 0 in
+let hasSideEffects = 0 in
def A4_boundscheck_hi: ALU64Inst <
(outs PredRegs:$Pd),
(ins DoubleRegs:$Rss, DoubleRegs:$Rtt),
"$Pd=boundscheck($Rs,$Rtt)">;
// A4_tlbmatch: Detect if a VA/ASID matches a TLB entry.
-let isPredicateLate = 1, hasSideEffects = 0, isCodeGenOnly = 0 in
+let isPredicateLate = 1, hasSideEffects = 0 in
def A4_tlbmatch : ALU64Inst<(outs PredRegs:$Pd),
(ins DoubleRegs:$Rs, IntRegs:$Rt),
"$Pd = tlbmatch($Rs, $Rt)",
// Use LD0Inst for dcfetch, but set "mayLoad" to 0 because this doesn't
// really do a load.
-let hasSideEffects = 1, mayLoad = 0, isCodeGenOnly = 0 in
+let hasSideEffects = 1, mayLoad = 0 in
def Y2_dcfetchbo : LD0Inst<(outs), (ins IntRegs:$Rs, u11_3Imm:$u11_3),
"dcfetch($Rs + #$u11_3)",
[(HexagonDCFETCH IntRegs:$Rs, u11_3ImmPred:$u11_3)],
let Inst{7-1} = r9_2{8-2};
}
-let Defs = [PC, P0], Uses = [P0], isCodeGenOnly = 0 in {
+let Defs = [PC, P0], Uses = [P0] in {
def J4_tstbit0_tp0_jump_nt : CJInst_tstbit_R0<"p0", 0, "nt">;
def J4_tstbit0_tp0_jump_t : CJInst_tstbit_R0<"p0", 0, "t">;
def J4_tstbit0_fp0_jump_nt : CJInst_tstbit_R0<"p0", 1, "nt">;
def J4_tstbit0_fp0_jump_t : CJInst_tstbit_R0<"p0", 1, "t">;
}
-let Defs = [PC, P1], Uses = [P1], isCodeGenOnly = 0 in {
+let Defs = [PC, P1], Uses = [P1] in {
def J4_tstbit0_tp1_jump_nt : CJInst_tstbit_R0<"p1", 0, "nt">;
def J4_tstbit0_tp1_jump_t : CJInst_tstbit_R0<"p1", 0, "t">;
def J4_tstbit0_fp1_jump_nt : CJInst_tstbit_R0<"p1", 1, "nt">;
defm J4_cmp#NAME#_f : T_tnt_CJInst_RR<op, 1>;
}
// TypeCJ Instructions compare RR and jump
-let isCodeGenOnly = 0 in {
defm eq : T_pnp_CJInst_RR<"eq">;
defm gt : T_pnp_CJInst_RR<"gt">;
defm gtu : T_pnp_CJInst_RR<"gtu">;
-}
let isBranch = 1, hasSideEffects = 0, isExtentSigned = 1,
isPredicated = 1, isPredicatedNew = 1, isExtendable = 1, opExtentBits = 11,
defm J4_cmp#NAME#i_f : T_tnt_CJInst_RU5<op, 1>;
}
// TypeCJ Instructions compare RI and jump
-let isCodeGenOnly = 0 in {
defm eq : T_pnp_CJInst_RU5<"eq">;
defm gt : T_pnp_CJInst_RU5<"gt">;
defm gtu : T_pnp_CJInst_RU5<"gtu">;
-}
let isBranch = 1, hasSideEffects = 0, isExtentSigned = 1,
isPredicated = 1, isPredicatedFalse = 1, isPredicatedNew = 1,
defm J4_cmp#NAME#n1_f : T_tnt_CJInst_Rn1<op, 1>;
}
// TypeCJ Instructions compare -1 and jump
-let isCodeGenOnly = 0 in {
defm eq : T_pnp_CJInst_Rn1<"eq">;
defm gt : T_pnp_CJInst_Rn1<"gt">;
-}
// J4_jumpseti: Direct unconditional jump and set register to immediate.
let Defs = [PC], isBranch = 1, hasSideEffects = 0, hasNewValue = 1,
isExtentSigned = 1, opNewValue = 0, isExtendable = 1, opExtentBits = 11,
- opExtentAlign = 2, opExtendable = 2, validSubTargets = HasV4SubT,
- isCodeGenOnly = 0 in
+ opExtentAlign = 2, opExtendable = 2, validSubTargets = HasV4SubT in
def J4_jumpseti: CJInst <
(outs IntRegs:$Rd),
(ins u6Imm:$U6, brtarget:$r9_2),
// J4_jumpsetr: Direct unconditional jump and transfer register.
let Defs = [PC], isBranch = 1, hasSideEffects = 0, hasNewValue = 1,
isExtentSigned = 1, opNewValue = 0, isExtendable = 1, opExtentBits = 11,
- opExtentAlign = 2, opExtendable = 2, validSubTargets = HasV4SubT,
- isCodeGenOnly = 0 in
+ opExtentAlign = 2, opExtendable = 2, validSubTargets = HasV4SubT in
def J4_jumpsetr: CJInst <
(outs IntRegs:$Rd),
(ins IntRegs:$Rs, brtarget:$r9_2),