llvm-project/llvm/lib/Target/Hexagon/HexagonPseudo.td

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//===--- HexagonPseudo.td -------------------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
// The pat frags in the definitions below need to have a named register,
// otherwise i32 will be assumed regardless of the register class. The
// name of the register does not matter.
def I1 : PatLeaf<(i1 PredRegs:$R)>;
def I32 : PatLeaf<(i32 IntRegs:$R)>;
def I64 : PatLeaf<(i64 DoubleRegs:$R)>;
def F32 : PatLeaf<(f32 IntRegs:$R)>;
def F64 : PatLeaf<(f64 DoubleRegs:$R)>;
let PrintMethod = "printGlobalOperand" in {
def globaladdress : Operand<i32>;
def globaladdressExt : Operand<i32>;
}
let isPseudo = 1 in {
let isCodeGenOnly = 0 in
def A2_iconst : Pseudo<(outs IntRegs:$Rd32),
(ins s27_2Imm:$Ii), "${Rd32}=iconst(#${Ii})">;
def DUPLEX_Pseudo : InstHexagon<(outs),
(ins s32_0Imm:$offset), "DUPLEX", [], "", DUPLEX, TypePSEUDO>;
}
let isExtendable = 1, opExtendable = 1, opExtentBits = 6,
isAsmParserOnly = 1 in
def TFRI64_V2_ext : InstHexagon<(outs DoubleRegs:$dst),
(ins s32_0Imm:$src1, s8_0Imm:$src2),
"$dst=combine(#$src1,#$src2)", [], "",
A2_combineii.Itinerary, TypeALU32_2op>, OpcodeHexagon;
// HI/LO Instructions
let isReMaterializable = 1, isMoveImm = 1, hasSideEffects = 0,
hasNewValue = 1, opNewValue = 0 in
class REG_IMMED<string RegHalf, bit Rs, bits<3> MajOp, bit MinOp,
InstHexagon rootInst>
: InstHexagon<(outs IntRegs:$dst),
(ins u16_0Imm:$imm_value),
"$dst"#RegHalf#"=#$imm_value", [], "",
rootInst.Itinerary, rootInst.Type>, OpcodeHexagon {
bits<5> dst;
bits<32> imm_value;
let Inst{27} = Rs;
let Inst{26-24} = MajOp;
let Inst{21} = MinOp;
let Inst{20-16} = dst;
let Inst{23-22} = imm_value{15-14};
let Inst{13-0} = imm_value{13-0};
}
let isAsmParserOnly = 1 in {
def LO : REG_IMMED<".l", 0b0, 0b001, 0b1, A2_tfril>;
def HI : REG_IMMED<".h", 0b0, 0b010, 0b1, A2_tfrih>;
}
let isReMaterializable = 1, isMoveImm = 1, isAsmParserOnly = 1 in {
def CONST32 : CONSTLDInst<(outs IntRegs:$Rd), (ins i32imm:$v),
"$Rd = CONST32(#$v)", []>;
def CONST64 : CONSTLDInst<(outs DoubleRegs:$Rd), (ins i64imm:$v),
"$Rd = CONST64(#$v)", []>;
}
let hasSideEffects = 0, isReMaterializable = 1, isPseudo = 1,
isCodeGenOnly = 1 in
def PS_true : InstHexagon<(outs PredRegs:$dst), (ins), "",
[(set I1:$dst, 1)], "", C2_orn.Itinerary, TypeCR>;
let hasSideEffects = 0, isReMaterializable = 1, isPseudo = 1,
isCodeGenOnly = 1 in
def PS_false : InstHexagon<(outs PredRegs:$dst), (ins), "",
[(set I1:$dst, 0)], "", C2_andn.Itinerary, TypeCR>;
let Defs = [R29, R30], Uses = [R31, R30, R29], isPseudo = 1 in
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 21:35:13 +08:00
def ADJCALLSTACKDOWN : Pseudo<(outs), (ins i32imm:$amt1, i32imm:$amt2),
".error \"should not emit\" ", []>;
let Defs = [R29, R30, R31], Uses = [R29], isPseudo = 1 in
def ADJCALLSTACKUP : Pseudo<(outs), (ins i32imm:$amt1, i32imm:$amt2),
".error \"should not emit\" ", []>;
let isBranch = 1, isTerminator = 1, hasSideEffects = 0,
Defs = [PC, LC0], Uses = [SA0, LC0] in {
def ENDLOOP0 : Endloop<(outs), (ins b30_2Imm:$offset),
":endloop0",
[]>;
}
let isBranch = 1, isTerminator = 1, hasSideEffects = 0,
Defs = [PC, LC1], Uses = [SA1, LC1] in {
def ENDLOOP1 : Endloop<(outs), (ins b30_2Imm:$offset),
":endloop1",
[]>;
}
let isExtendable = 1, isExtentSigned = 1, opExtentBits = 9, opExtentAlign = 2,
opExtendable = 0, hasSideEffects = 0 in
class LOOP_iBase<string mnemonic, InstHexagon rootInst>
: InstHexagon <(outs), (ins b30_2Imm:$offset, u10_0Imm:$src2),
#mnemonic#"($offset,#$src2)",
[], "", rootInst.Itinerary, rootInst.Type>, OpcodeHexagon {
bits<9> offset;
bits<10> src2;
let IClass = 0b0110;
let Inst{27-22} = 0b100100;
let Inst{21} = !if (!eq(mnemonic, "loop0"), 0b0, 0b1);
let Inst{20-16} = src2{9-5};
let Inst{12-8} = offset{8-4};
let Inst{7-5} = src2{4-2};
let Inst{4-3} = offset{3-2};
let Inst{1-0} = src2{1-0};
}
let isExtendable = 1, isExtentSigned = 1, opExtentBits = 9, opExtentAlign = 2,
opExtendable = 0, hasSideEffects = 0 in
class LOOP_rBase<string mnemonic, InstHexagon rootInst>
: InstHexagon<(outs), (ins b30_2Imm:$offset, IntRegs:$src2),
#mnemonic#"($offset,$src2)",
[], "", rootInst.Itinerary, rootInst.Type>, OpcodeHexagon {
bits<9> offset;
bits<5> src2;
let IClass = 0b0110;
let Inst{27-22} = 0b000000;
let Inst{21} = !if (!eq(mnemonic, "loop0"), 0b0, 0b1);
let Inst{20-16} = src2;
let Inst{12-8} = offset{8-4};
let Inst{4-3} = offset{3-2};
}
let Defs = [SA0, LC0, USR], isCodeGenOnly = 1, isExtended = 1,
opExtendable = 0 in {
def J2_loop0iext : LOOP_iBase<"loop0", J2_loop0i>;
def J2_loop1iext : LOOP_iBase<"loop1", J2_loop1i>;
}
// Interestingly only loop0's appear to set usr.lpcfg
let Defs = [SA1, LC1], isCodeGenOnly = 1, isExtended = 1, opExtendable = 0 in {
def J2_loop0rext : LOOP_rBase<"loop0", J2_loop0r>;
def J2_loop1rext : LOOP_rBase<"loop1", J2_loop1r>;
}
let isCall = 1, hasSideEffects = 1, isPredicable = 0,
isExtended = 0, isExtendable = 1, opExtendable = 0,
isExtentSigned = 1, opExtentBits = 24, opExtentAlign = 2 in
class T_Call<string ExtStr>
: InstHexagon<(outs), (ins a30_2Imm:$dst),
"call " # ExtStr # "$dst", [], "", J2_call.Itinerary, TypeJ>,
OpcodeHexagon {
let BaseOpcode = "call";
bits<24> dst;
let IClass = 0b0101;
let Inst{27-25} = 0b101;
let Inst{24-16,13-1} = dst{23-2};
let Inst{0} = 0b0;
}
let isCodeGenOnly = 1, isCall = 1, hasSideEffects = 1, Defs = [R16],
isPredicable = 0 in
def CALLProfile : T_Call<"">;
let isCodeGenOnly = 1, isCall = 1, hasSideEffects = 1,
Defs = [PC, R31, R6, R7, P0] in
def PS_call_stk : T_Call<"">;
// Call, no return.
let isCall = 1, hasSideEffects = 1, cofMax1 = 1, isCodeGenOnly = 1 in
def PS_callr_nr: InstHexagon<(outs), (ins IntRegs:$Rs),
"callr $Rs", [], "", J2_callr.Itinerary, TypeJ>, OpcodeHexagon {
bits<5> Rs;
bits<2> Pu;
let isPredicatedFalse = 1;
let IClass = 0b0101;
let Inst{27-21} = 0b0000101;
let Inst{20-16} = Rs;
}
let isCall = 1, hasSideEffects = 1,
isExtended = 0, isExtendable = 1, opExtendable = 0, isCodeGenOnly = 1,
BaseOpcode = "PS_call_nr", isExtentSigned = 1, opExtentAlign = 2 in
class Call_nr<bits<5> nbits, bit isPred, bit isFalse, dag iops,
InstrItinClass itin>
: Pseudo<(outs), iops, "">, PredRel {
bits<2> Pu;
bits<17> dst;
let opExtentBits = nbits;
let isPredicable = 0; // !if(isPred, 0, 1);
let isPredicated = 0; // isPred;
let isPredicatedFalse = isFalse;
}
def PS_call_nr : Call_nr<24, 0, 0, (ins s32_0Imm:$Ii), J2_call.Itinerary>;
//def PS_call_nrt: Call_nr<17, 1, 0, (ins PredRegs:$Pu, s32_0Imm:$dst),
// J2_callt.Itinerary>;
//def PS_call_nrf: Call_nr<17, 1, 1, (ins PredRegs:$Pu, s32_0Imm:$dst),
// J2_callf.Itinerary>;
let isBranch = 1, isIndirectBranch = 1, isBarrier = 1, Defs = [PC],
isPredicable = 1, hasSideEffects = 0, InputType = "reg",
cofMax1 = 1 in
class T_JMPr <InstHexagon rootInst>
: InstHexagon<(outs), (ins IntRegs:$dst), "jumpr $dst", [],
"", rootInst.Itinerary, rootInst.Type>, OpcodeHexagon {
bits<5> dst;
let IClass = 0b0101;
let Inst{27-21} = 0b0010100;
let Inst{20-16} = dst;
}
// A return through builtin_eh_return.
let isReturn = 1, isTerminator = 1, isBarrier = 1, hasSideEffects = 0,
isCodeGenOnly = 1, Defs = [PC], Uses = [R28], isPredicable = 0 in
def EH_RETURN_JMPR : T_JMPr<J2_jumpr>;
// Indirect tail-call.
let isPseudo = 1, isCall = 1, isReturn = 1, isBarrier = 1, isPredicable = 0,
isTerminator = 1, isCodeGenOnly = 1 in
def PS_tailcall_r : T_JMPr<J2_jumpr>;
//
// Direct tail-calls.
let isPseudo = 1, isCall = 1, isReturn = 1, isBarrier = 1, isPredicable = 0,
isTerminator = 1, isCodeGenOnly = 1 in
def PS_tailcall_i : Pseudo<(outs), (ins a30_2Imm:$dst), "", []>;
let isCodeGenOnly = 1, isPseudo = 1, Uses = [R30], hasSideEffects = 0 in
def PS_aligna : Pseudo<(outs IntRegs:$Rd), (ins u32_0Imm:$A), "", []>;
// Generate frameindex addresses. The main reason for the offset operand is
// that every instruction that is allowed to have frame index as an operand
// will then have that operand followed by an immediate operand (the offset).
// This simplifies the frame-index elimination code.
//
let isMoveImm = 1, isAsCheapAsAMove = 1, isReMaterializable = 1,
isPseudo = 1, isCodeGenOnly = 1, hasSideEffects = 0 in {
def PS_fi : Pseudo<(outs IntRegs:$Rd),
(ins IntRegs:$fi, s32_0Imm:$off), "">;
def PS_fia : Pseudo<(outs IntRegs:$Rd),
(ins IntRegs:$Rs, IntRegs:$fi, s32_0Imm:$off), "">;
}
class CondStr<string CReg, bit True, bit New> {
string S = "if (" # !if(True,"","!") # CReg # !if(New,".new","") # ") ";
}
class JumpOpcStr<string Mnemonic, bit New, bit Taken> {
string S = Mnemonic # !if(Taken, ":t", ":nt");
}
let isBranch = 1, isIndirectBranch = 1, Defs = [PC], isPredicated = 1,
hasSideEffects = 0, InputType = "reg", cofMax1 = 1 in
class T_JMPr_c <bit PredNot, bit isPredNew, bit isTak, InstHexagon rootInst>
: InstHexagon<(outs), (ins PredRegs:$src, IntRegs:$dst),
CondStr<"$src", !if(PredNot,0,1), isPredNew>.S #
JumpOpcStr<"jumpr", isPredNew, isTak>.S # " $dst",
[], "", rootInst.Itinerary, rootInst.Type>, OpcodeHexagon {
let isTaken = isTak;
let isPredicatedFalse = PredNot;
let isPredicatedNew = isPredNew;
bits<2> src;
bits<5> dst;
let IClass = 0b0101;
let Inst{27-22} = 0b001101;
let Inst{21} = PredNot;
let Inst{20-16} = dst;
let Inst{12} = isTak;
let Inst{11} = isPredNew;
let Inst{9-8} = src;
}
let isTerminator = 1, hasSideEffects = 0, isReturn = 1, isCodeGenOnly = 1,
isBarrier = 1, BaseOpcode = "JMPret" in {
def PS_jmpret : T_JMPr<J2_jumpr>, PredNewRel;
def PS_jmprett : T_JMPr_c<0, 0, 0, J2_jumprt>, PredNewRel;
def PS_jmpretf : T_JMPr_c<1, 0, 0, J2_jumprf>, PredNewRel;
def PS_jmprettnew : T_JMPr_c<0, 1, 0, J2_jumprtnew>, PredNewRel;
def PS_jmpretfnew : T_JMPr_c<1, 1, 0, J2_jumprfnew>, PredNewRel;
def PS_jmprettnewpt : T_JMPr_c<0, 1, 1, J2_jumprtnewpt>, PredNewRel;
def PS_jmpretfnewpt : T_JMPr_c<1, 1, 1, J2_jumprfnewpt>, PredNewRel;
}
//defm V6_vtran2x2_map : HexagonMapping<(outs VectorRegs:$Vy32, VectorRegs:$Vx32), (ins VectorRegs:$Vx32in, IntRegs:$Rt32), "vtrans2x2(${Vy32},${Vx32},${Rt32})", (V6_vshuff VectorRegs:$Vy32, VectorRegs:$Vx32, VectorRegs:$Vx32in, IntRegs:$Rt32)>;
// The reason for the custom inserter is to record all ALLOCA instructions
// in MachineFunctionInfo.
let Defs = [R29], hasSideEffects = 1 in
def PS_alloca: Pseudo <(outs IntRegs:$Rd),
(ins IntRegs:$Rs, u32_0Imm:$A), "", []>;
// Load predicate.
let isExtendable = 1, opExtendable = 2, isExtentSigned = 1, opExtentBits = 13,
isCodeGenOnly = 1, isPseudo = 1, hasSideEffects = 0 in
def LDriw_pred : LDInst<(outs PredRegs:$dst),
(ins IntRegs:$addr, s32_0Imm:$off),
".error \"should not emit\"", []>;
// Load modifier.
let isExtendable = 1, opExtendable = 2, isExtentSigned = 1, opExtentBits = 13,
isCodeGenOnly = 1, isPseudo = 1, hasSideEffects = 0 in
def LDriw_mod : LDInst<(outs ModRegs:$dst),
(ins IntRegs:$addr, s32_0Imm:$off),
".error \"should not emit\"", []>;
let isCodeGenOnly = 1, isPseudo = 1 in
def PS_pselect: InstHexagon<(outs DoubleRegs:$Rd),
(ins PredRegs:$Pu, DoubleRegs:$Rs, DoubleRegs:$Rt),
".error \"should not emit\" ", [], "", A2_tfrpt.Itinerary, TypeALU32_2op>;
let isBranch = 1, isBarrier = 1, Defs = [PC], hasSideEffects = 0,
isPredicable = 1,
isExtendable = 1, opExtendable = 0, isExtentSigned = 1,
opExtentBits = 24, opExtentAlign = 2, InputType = "imm" in
class T_JMP: InstHexagon<(outs), (ins b30_2Imm:$dst),
"jump $dst",
[], "", J2_jump.Itinerary, TypeJ>, OpcodeHexagon {
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};
}
// Restore registers and dealloc return function call.
let isCall = 1, isBarrier = 1, isReturn = 1, isTerminator = 1,
Defs = [R29, R30, R31, PC], isPredicable = 0, isAsmParserOnly = 1 in {
def RESTORE_DEALLOC_RET_JMP_V4 : T_JMP;
let isExtended = 1, opExtendable = 0 in
def RESTORE_DEALLOC_RET_JMP_V4_EXT : T_JMP;
let Defs = [R14, R15, R28, R29, R30, R31, PC] in {
def RESTORE_DEALLOC_RET_JMP_V4_PIC : T_JMP;
let isExtended = 1, opExtendable = 0 in
def RESTORE_DEALLOC_RET_JMP_V4_EXT_PIC : T_JMP;
}
}
// Restore registers and dealloc frame before a tail call.
let isCall = 1, Defs = [R29, R30, R31, PC], isAsmParserOnly = 1 in {
def RESTORE_DEALLOC_BEFORE_TAILCALL_V4 : T_Call<"">, PredRel;
let isExtended = 1, opExtendable = 0 in
def RESTORE_DEALLOC_BEFORE_TAILCALL_V4_EXT : T_Call<"">, PredRel;
let Defs = [R14, R15, R28, R29, R30, R31, PC] in {
def RESTORE_DEALLOC_BEFORE_TAILCALL_V4_PIC : T_Call<"">, PredRel;
let isExtended = 1, opExtendable = 0 in
def RESTORE_DEALLOC_BEFORE_TAILCALL_V4_EXT_PIC : T_Call<"">, PredRel;
}
}
// Save registers function call.
let isCall = 1, Uses = [R29, R31], isAsmParserOnly = 1 in {
def SAVE_REGISTERS_CALL_V4 : T_Call<"">, PredRel;
let isExtended = 1, opExtendable = 0 in
def SAVE_REGISTERS_CALL_V4_EXT : T_Call<"">, PredRel;
let Defs = [P0] in
def SAVE_REGISTERS_CALL_V4STK : T_Call<"">, PredRel;
let Defs = [P0], isExtended = 1, opExtendable = 0 in
def SAVE_REGISTERS_CALL_V4STK_EXT : T_Call<"">, PredRel;
let Defs = [R14, R15, R28] in
def SAVE_REGISTERS_CALL_V4_PIC : T_Call<"">, PredRel;
let Defs = [R14, R15, R28], isExtended = 1, opExtendable = 0 in
def SAVE_REGISTERS_CALL_V4_EXT_PIC : T_Call<"">, PredRel;
let Defs = [R14, R15, R28, P0] in
def SAVE_REGISTERS_CALL_V4STK_PIC : T_Call<"">, PredRel;
let Defs = [R14, R15, R28, P0], isExtended = 1, opExtendable = 0 in
def SAVE_REGISTERS_CALL_V4STK_EXT_PIC : T_Call<"">, PredRel;
}
// Vector store pseudos
let Predicates = [HasV60T, UseHVX], isPseudo = 1, isCodeGenOnly = 1,
mayStore = 1, hasSideEffects = 0 in
class STrivv_template<RegisterClass RC, InstHexagon rootInst>
: InstHexagon<(outs), (ins IntRegs:$addr, s32_0Imm:$off, RC:$src),
"", [], "", rootInst.Itinerary, rootInst.Type>;
let accessSize = Vector64Access, Predicates = [HasV60T,UseHVXSgl] in {
def PS_vstorerw_ai: STrivv_template<VecDblRegs, V6_vS32b_ai>;
def PS_vstorerw_nt_ai: STrivv_template<VecDblRegs, V6_vS32b_nt_ai>;
def PS_vstorerwu_ai: STrivv_template<VecDblRegs, V6_vS32Ub_ai>;
}
let accessSize = Vector128Access, Predicates = [HasV60T,UseHVXDbl] in {
def PS_vstorerw_ai_128B: STrivv_template<VecDblRegs128B, V6_vS32b_ai_128B>;
def PS_vstorerw_nt_ai_128B: STrivv_template<VecDblRegs128B,
V6_vS32b_nt_ai_128B>;
def PS_vstorerwu_ai_128B: STrivv_template<VecDblRegs128B, V6_vS32Ub_ai_128B>;
}
let isPseudo = 1, isCodeGenOnly = 1, mayStore = 1, hasSideEffects = 0 in {
let accessSize = Vector64Access in
def PS_vstorerq_ai: Pseudo<(outs),
(ins IntRegs:$Rs, s32_0Imm:$Off, VecPredRegs:$Qt), "", []>,
Requires<[HasV60T,UseHVXSgl]>;
let accessSize = Vector128Access in
def PS_vstorerq_ai_128B: Pseudo<(outs),
(ins IntRegs:$Rs, s32_0Imm:$Off, VecPredRegs128B:$Qt), "", []>,
Requires<[HasV60T,UseHVXDbl]>;
}
// Vector load pseudos
let Predicates = [HasV60T, UseHVX], isPseudo = 1, isCodeGenOnly = 1,
mayLoad = 1, hasSideEffects = 0 in
class LDrivv_template<RegisterClass RC, InstHexagon rootInst>
: InstHexagon<(outs RC:$dst), (ins IntRegs:$addr, s32_0Imm:$off),
"", [], "", rootInst.Itinerary, rootInst.Type>;
let accessSize = Vector64Access, Predicates = [HasV60T,UseHVXSgl] in {
def PS_vloadrw_ai: LDrivv_template<VecDblRegs, V6_vL32b_ai>;
def PS_vloadrw_nt_ai: LDrivv_template<VecDblRegs, V6_vL32b_nt_ai>;
def PS_vloadrwu_ai: LDrivv_template<VecDblRegs, V6_vL32Ub_ai>;
}
let accessSize = Vector128Access, Predicates = [HasV60T,UseHVXDbl] in {
def PS_vloadrw_ai_128B: LDrivv_template<VecDblRegs128B, V6_vL32b_ai_128B>;
def PS_vloadrw_nt_ai_128B: LDrivv_template<VecDblRegs128B,
V6_vL32b_nt_ai_128B>;
def PS_vloadrwu_ai_128B: LDrivv_template<VecDblRegs128B, V6_vL32Ub_ai_128B>;
}
let isPseudo = 1, isCodeGenOnly = 1, mayLoad = 1, hasSideEffects = 0 in {
let accessSize = Vector64Access in
def PS_vloadrq_ai: Pseudo<(outs VecPredRegs:$Qd),
(ins IntRegs:$Rs, s32_0Imm:$Off), "", []>,
Requires<[HasV60T,UseHVXSgl]>;
let accessSize = Vector128Access in
def PS_vloadrq_ai_128B: Pseudo<(outs VecPredRegs128B:$Qd),
(ins IntRegs:$Rs, s32_0Imm:$Off), "", []>,
Requires<[HasV60T,UseHVXDbl]>;
}
let isCodeGenOnly = 1, isPseudo = 1, hasSideEffects = 0 in
class VSELInst<dag outs, dag ins, InstHexagon rootInst>
: InstHexagon<outs, ins, "", [], "", rootInst.Itinerary, rootInst.Type>;
def PS_vselect: VSELInst<(outs VectorRegs:$dst),
(ins PredRegs:$src1, VectorRegs:$src2, VectorRegs:$src3),
V6_vcmov>, Requires<[HasV60T,UseHVXSgl]>;
def PS_vselect_128B: VSELInst<(outs VectorRegs128B:$dst),
(ins PredRegs:$src1, VectorRegs128B:$src2, VectorRegs128B:$src3),
V6_vcmov>, Requires<[HasV60T,UseHVXDbl]>;
def PS_wselect: VSELInst<(outs VecDblRegs:$dst),
(ins PredRegs:$src1, VecDblRegs:$src2, VecDblRegs:$src3),
V6_vccombine>, Requires<[HasV60T,UseHVXSgl]>;
def PS_wselect_128B: VSELInst<(outs VecDblRegs128B:$dst),
(ins PredRegs:$src1, VecDblRegs128B:$src2, VecDblRegs128B:$src3),
V6_vccombine>, Requires<[HasV60T,UseHVXDbl]>;
// Store predicate.
let isExtendable = 1, opExtendable = 1, isExtentSigned = 1, opExtentBits = 13,
isCodeGenOnly = 1, isPseudo = 1, hasSideEffects = 0 in
def STriw_pred : STInst<(outs),
(ins IntRegs:$addr, s32_0Imm:$off, PredRegs:$src1),
".error \"should not emit\"", []>;
// Store modifier.
let isExtendable = 1, opExtendable = 1, isExtentSigned = 1, opExtentBits = 13,
isCodeGenOnly = 1, isPseudo = 1, hasSideEffects = 0 in
def STriw_mod : STInst<(outs),
(ins IntRegs:$addr, s32_0Imm:$off, ModRegs:$src1),
".error \"should not emit\"", []>;
let isExtendable = 1, opExtendable = 1, opExtentBits = 6,
isAsmParserOnly = 1 in
def TFRI64_V4 : InstHexagon<(outs DoubleRegs:$dst),
(ins u64_0Imm:$src1),
"$dst = #$src1", [], "",
A2_combineii.Itinerary, TypeALU32_2op>, OpcodeHexagon;
// Hexagon doesn't have a vector multiply with C semantics.
// Instead, generate a pseudo instruction that gets expaneded into two
// scalar MPYI instructions.
// This is expanded by ExpandPostRAPseudos.
let isPseudo = 1 in
def PS_vmulw : PseudoM<(outs DoubleRegs:$Rd),
(ins DoubleRegs:$Rs, DoubleRegs:$Rt), "", []>;
let isPseudo = 1 in
def PS_vmulw_acc : PseudoM<(outs DoubleRegs:$Rd),
(ins DoubleRegs:$Rx, DoubleRegs:$Rs, DoubleRegs:$Rt), "", [],
"$Rd = $Rx">;
def DuplexIClass0: InstDuplex < 0 >;
def DuplexIClass1: InstDuplex < 1 >;
def DuplexIClass2: InstDuplex < 2 >;
let isExtendable = 1 in {
def DuplexIClass3: InstDuplex < 3 >;
def DuplexIClass4: InstDuplex < 4 >;
def DuplexIClass5: InstDuplex < 5 >;
def DuplexIClass6: InstDuplex < 6 >;
def DuplexIClass7: InstDuplex < 7 >;
}
def DuplexIClass8: InstDuplex < 8 >;
def DuplexIClass9: InstDuplex < 9 >;
def DuplexIClassA: InstDuplex < 0xA >;
def DuplexIClassB: InstDuplex < 0xB >;
def DuplexIClassC: InstDuplex < 0xC >;
def DuplexIClassD: InstDuplex < 0xD >;
def DuplexIClassE: InstDuplex < 0xE >;
def DuplexIClassF: InstDuplex < 0xF >;