File: RISCVInstrInfoVSDPatterns.td

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//===- RISCVInstrInfoVSDPatterns.td - RVV SDNode patterns --*- tablegen -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
///
/// This file contains the required infrastructure and SDNode patterns to
/// support code generation for the standard 'V' (Vector) extension, version
/// 0.10.  This version is still experimental as the 'V' extension hasn't been
/// ratified yet.
///
/// This file is included from and depends upon RISCVInstrInfoVPseudos.td
///
/// Note: the patterns for RVV intrinsics are found in
/// RISCVInstrInfoVPseudos.td.
///
//===----------------------------------------------------------------------===//

//===----------------------------------------------------------------------===//
// Helpers to define the SDNode patterns.
//===----------------------------------------------------------------------===//

def SDTSplatI64 : SDTypeProfile<1, 1, [
  SDTCVecEltisVT<0, i64>, SDTCisVT<1, i32>
]>;

def rv32_splat_i64 : SDNode<"RISCVISD::SPLAT_VECTOR_I64", SDTSplatI64>;

def SDT_RISCVVMSETCLR_VL : SDTypeProfile<1, 1, [SDTCVecEltisVT<0, i1>,
                                                SDTCisVT<1, XLenVT>]>;
def riscv_vmclr_vl : SDNode<"RISCVISD::VMCLR_VL", SDT_RISCVVMSETCLR_VL>;
def riscv_vmset_vl : SDNode<"RISCVISD::VMSET_VL", SDT_RISCVVMSETCLR_VL>;

def rvv_vnot : PatFrag<(ops node:$in),
                       (xor node:$in, (riscv_vmset_vl (XLenVT srcvalue)))>;

// Give explicit Complexity to prefer simm5/uimm5.
def SplatPat       : ComplexPattern<vAny, 1, "selectVSplat",      [splat_vector, rv32_splat_i64], [], 1>;
def SplatPat_simm5 : ComplexPattern<vAny, 1, "selectVSplatSimm5", [splat_vector, rv32_splat_i64], [], 2>;
def SplatPat_uimm5 : ComplexPattern<vAny, 1, "selectVSplatUimm5", [splat_vector, rv32_splat_i64], [], 2>;
def SplatPat_simm5_plus1
    : ComplexPattern<vAny, 1, "selectVSplatSimm5Plus1",
                     [splat_vector, rv32_splat_i64], [], 2>;
def SplatPat_simm5_plus1_nonzero
    : ComplexPattern<vAny, 1, "selectVSplatSimm5Plus1NonZero",
                     [splat_vector, rv32_splat_i64], [], 2>;

class SwapHelper<dag Prefix, dag A, dag B, dag Suffix, bit swap> {
   dag Value = !con(Prefix, !if(swap, B, A), !if(swap, A, B), Suffix);
}

multiclass VPatUSLoadStoreSDNode<ValueType type,
                                 int log2sew,
                                 LMULInfo vlmul,
                                 OutPatFrag avl,
                                 VReg reg_class,
                                 int sew = !shl(1, log2sew)>
{
  defvar load_instr = !cast<Instruction>("PseudoVLE"#sew#"_V_"#vlmul.MX);
  defvar store_instr = !cast<Instruction>("PseudoVSE"#sew#"_V_"#vlmul.MX);
  // Load
  def : Pat<(type (load BaseAddr:$rs1)),
            (load_instr BaseAddr:$rs1, avl, log2sew)>;
  // Store
  def : Pat<(store type:$rs2, BaseAddr:$rs1),
            (store_instr reg_class:$rs2, BaseAddr:$rs1, avl, log2sew)>;
}

multiclass VPatUSLoadStoreWholeVRSDNode<ValueType type,
                                        int log2sew,
                                        LMULInfo vlmul,
                                        VReg reg_class,
                                        int sew = !shl(1, log2sew)>
{
  defvar load_instr =
    !cast<Instruction>("VL"#!substr(vlmul.MX, 1)#"RE"#sew#"_V");
  defvar store_instr =
    !cast<Instruction>("VS"#!substr(vlmul.MX, 1)#"R_V");

  // Load
  def : Pat<(type (load BaseAddr:$rs1)),
            (load_instr BaseAddr:$rs1)>;
  // Store
  def : Pat<(store type:$rs2, BaseAddr:$rs1),
            (store_instr reg_class:$rs2, BaseAddr:$rs1)>;
}

multiclass VPatUSLoadStoreMaskSDNode<MTypeInfo m>
{
  defvar load_instr = !cast<Instruction>("PseudoVLM_V_"#m.BX);
  defvar store_instr = !cast<Instruction>("PseudoVSM_V_"#m.BX);
  // Load
  def : Pat<(m.Mask (load BaseAddr:$rs1)),
            (load_instr BaseAddr:$rs1, m.AVL, m.Log2SEW)>;
  // Store
  def : Pat<(store m.Mask:$rs2, BaseAddr:$rs1),
            (store_instr VR:$rs2, BaseAddr:$rs1, m.AVL, m.Log2SEW)>;
}

class VPatBinarySDNode_VV<SDNode vop,
                          string instruction_name,
                          ValueType result_type,
                          ValueType op_type,
                          int sew,
                          LMULInfo vlmul,
                          OutPatFrag avl,
                          VReg op_reg_class> :
    Pat<(result_type (vop
                     (op_type op_reg_class:$rs1),
                     (op_type op_reg_class:$rs2))),
        (!cast<Instruction>(instruction_name#"_VV_"# vlmul.MX)
                     op_reg_class:$rs1,
                     op_reg_class:$rs2,
                     avl, sew)>;

class VPatBinarySDNode_XI<SDNode vop,
                          string instruction_name,
                          string suffix,
                          ValueType result_type,
                          ValueType vop_type,
                          int sew,
                          LMULInfo vlmul,
                          OutPatFrag avl,
                          VReg vop_reg_class,
                          ComplexPattern SplatPatKind,
                          DAGOperand xop_kind> :
    Pat<(result_type (vop
                     (vop_type vop_reg_class:$rs1),
                     (vop_type (SplatPatKind xop_kind:$rs2)))),
        (!cast<Instruction>(instruction_name#_#suffix#_# vlmul.MX)
                     vop_reg_class:$rs1,
                     xop_kind:$rs2,
                     avl, sew)>;

multiclass VPatBinarySDNode_VV_VX<SDNode vop, string instruction_name> {
  foreach vti = AllIntegerVectors in {
    def : VPatBinarySDNode_VV<vop, instruction_name,
                              vti.Vector, vti.Vector, vti.Log2SEW,
                              vti.LMul, vti.AVL, vti.RegClass>;
    def : VPatBinarySDNode_XI<vop, instruction_name, "VX",
                              vti.Vector, vti.Vector, vti.Log2SEW,
                              vti.LMul, vti.AVL, vti.RegClass,
                              SplatPat, GPR>;
  }
}

multiclass VPatBinarySDNode_VV_VX_VI<SDNode vop, string instruction_name,
                                     Operand ImmType = simm5>
    : VPatBinarySDNode_VV_VX<vop, instruction_name> {
  foreach vti = AllIntegerVectors in {
    def : VPatBinarySDNode_XI<vop, instruction_name, "VI",
                              vti.Vector, vti.Vector, vti.Log2SEW,
                              vti.LMul, vti.AVL, vti.RegClass,
                              !cast<ComplexPattern>(SplatPat#_#ImmType),
                              ImmType>;
  }
}

class VPatBinarySDNode_VF<SDNode vop,
                          string instruction_name,
                          ValueType result_type,
                          ValueType vop_type,
                          ValueType xop_type,
                          int sew,
                          LMULInfo vlmul,
                          OutPatFrag avl,
                          VReg vop_reg_class,
                          DAGOperand xop_kind> :
    Pat<(result_type (vop (vop_type vop_reg_class:$rs1),
                          (vop_type (splat_vector xop_kind:$rs2)))),
        (!cast<Instruction>(instruction_name#"_"#vlmul.MX)
                     vop_reg_class:$rs1,
                     (xop_type xop_kind:$rs2),
                     avl, sew)>;

multiclass VPatBinaryFPSDNode_VV_VF<SDNode vop, string instruction_name> {
  foreach vti = AllFloatVectors in {
    def : VPatBinarySDNode_VV<vop, instruction_name,
                              vti.Vector, vti.Vector, vti.Log2SEW,
                              vti.LMul, vti.AVL, vti.RegClass>;
    def : VPatBinarySDNode_VF<vop, instruction_name#"_V"#vti.ScalarSuffix,
                              vti.Vector, vti.Vector, vti.Scalar,
                              vti.Log2SEW, vti.LMul, vti.AVL, vti.RegClass,
                              vti.ScalarRegClass>;
  }
}

multiclass VPatBinaryFPSDNode_R_VF<SDNode vop, string instruction_name> {
  foreach fvti = AllFloatVectors in
    def : Pat<(fvti.Vector (vop (fvti.Vector (splat_vector fvti.Scalar:$rs2)),
                                (fvti.Vector fvti.RegClass:$rs1))),
              (!cast<Instruction>(instruction_name#"_V"#fvti.ScalarSuffix#"_"#fvti.LMul.MX)
                           fvti.RegClass:$rs1,
                           (fvti.Scalar fvti.ScalarRegClass:$rs2),
                           fvti.AVL, fvti.Log2SEW)>;
}

multiclass VPatIntegerSetCCSDNode_VV<CondCode cc,
                                     string instruction_name,
                                     bit swap = 0> {
  foreach vti = AllIntegerVectors in {
    defvar instruction = !cast<Instruction>(instruction_name#"_VV_"#vti.LMul.MX);
    def : Pat<(vti.Mask (setcc (vti.Vector vti.RegClass:$rs1),
                               (vti.Vector vti.RegClass:$rs2), cc)),
              SwapHelper<(instruction),
                         (instruction vti.RegClass:$rs1),
                         (instruction vti.RegClass:$rs2),
                         (instruction vti.AVL, vti.Log2SEW),
                         swap>.Value>;
  }
}

multiclass VPatIntegerSetCCSDNode_XI<CondCode cc,
                                     string instruction_name,
                                     string kind,
                                     ComplexPattern SplatPatKind,
                                     DAGOperand xop_kind,
                                     bit swap = 0> {
  foreach vti = AllIntegerVectors in {
    defvar instruction = !cast<Instruction>(instruction_name#_#kind#_#vti.LMul.MX);
    def : Pat<(vti.Mask (setcc (vti.Vector vti.RegClass:$rs1),
                               (vti.Vector (SplatPatKind xop_kind:$rs2)), cc)),
              SwapHelper<(instruction),
                         (instruction vti.RegClass:$rs1),
                         (instruction xop_kind:$rs2),
                         (instruction vti.AVL, vti.Log2SEW),
                         swap>.Value>;
  }
}

multiclass VPatIntegerSetCCSDNode_VV_VX_VI<CondCode cc,
                                           string instruction_name,
                                           bit swap = 0> {
  defm : VPatIntegerSetCCSDNode_VV<cc, instruction_name, swap>;
  defm : VPatIntegerSetCCSDNode_XI<cc, instruction_name, "VX",
                                   SplatPat, GPR, swap>;
  defm : VPatIntegerSetCCSDNode_XI<cc, instruction_name, "VI",
                                   SplatPat_simm5, simm5, swap>;
}

multiclass VPatIntegerSetCCSDNode_VV_VX<CondCode cc,
                                        string instruction_name,
                                        bit swap = 0> {
  defm : VPatIntegerSetCCSDNode_VV<cc, instruction_name, swap>;
  defm : VPatIntegerSetCCSDNode_XI<cc, instruction_name, "VX",
                                   SplatPat, GPR, swap>;
}

multiclass VPatIntegerSetCCSDNode_VX_VI<CondCode cc,
                                        string instruction_name,
                                        bit swap = 0> {
  defm : VPatIntegerSetCCSDNode_XI<cc, instruction_name, "VX",
                                   SplatPat, GPR, swap>;
  defm : VPatIntegerSetCCSDNode_XI<cc, instruction_name, "VI",
                                   SplatPat_simm5, simm5, swap>;
}

multiclass VPatIntegerSetCCSDNode_VIPlus1<CondCode cc, string instruction_name,
                                          ComplexPattern splatpat_kind> {
  foreach vti = AllIntegerVectors in {
    defvar instruction = !cast<Instruction>(instruction_name#"_VI_"#vti.LMul.MX);
    def : Pat<(vti.Mask (setcc (vti.Vector vti.RegClass:$rs1),
                               (vti.Vector (splatpat_kind simm5:$rs2)),
                               cc)),
              (instruction vti.RegClass:$rs1, (DecImm simm5:$rs2),
                           vti.AVL, vti.Log2SEW)>;
  }
}

multiclass VPatFPSetCCSDNode_VV_VF_FV<CondCode cc,
                                      string inst_name,
                                      string swapped_op_inst_name> {
  foreach fvti = AllFloatVectors in {
    def : Pat<(fvti.Mask (setcc (fvti.Vector fvti.RegClass:$rs1),
                                (fvti.Vector fvti.RegClass:$rs2),
                                cc)),
              (!cast<Instruction>(inst_name#"_VV_"#fvti.LMul.MX)
                  fvti.RegClass:$rs1, fvti.RegClass:$rs2, fvti.AVL, fvti.Log2SEW)>;
    def : Pat<(fvti.Mask (setcc (fvti.Vector fvti.RegClass:$rs1),
                                (splat_vector fvti.ScalarRegClass:$rs2),
                                cc)),
              (!cast<Instruction>(inst_name#"_V"#fvti.ScalarSuffix#"_"#fvti.LMul.MX)
                  fvti.RegClass:$rs1, fvti.ScalarRegClass:$rs2,
                  fvti.AVL, fvti.Log2SEW)>;
    def : Pat<(fvti.Mask (setcc (splat_vector fvti.ScalarRegClass:$rs2),
                                (fvti.Vector fvti.RegClass:$rs1),
                                cc)),
              (!cast<Instruction>(swapped_op_inst_name#"_V"#fvti.ScalarSuffix#"_"#fvti.LMul.MX)
                  fvti.RegClass:$rs1, fvti.ScalarRegClass:$rs2,
                  fvti.AVL, fvti.Log2SEW)>;
  }
}

multiclass VPatExtendSDNode_V<list<SDNode> ops, string inst_name, string suffix,
                              list <VTypeInfoToFraction> fraction_list> {
  foreach vtiTofti = fraction_list in {
    defvar vti = vtiTofti.Vti;
    defvar fti = vtiTofti.Fti;
    foreach op = ops in
      def : Pat<(vti.Vector (op (fti.Vector fti.RegClass:$rs2))),
                (!cast<Instruction>(inst_name#"_"#suffix#"_"#vti.LMul.MX)
                    fti.RegClass:$rs2, fti.AVL, vti.Log2SEW)>;
  }
}

multiclass VPatConvertI2FPSDNode_V<SDNode vop, string instruction_name> {
  foreach fvti = AllFloatVectors in {
    defvar ivti = GetIntVTypeInfo<fvti>.Vti;
    def : Pat<(fvti.Vector (vop (ivti.Vector ivti.RegClass:$rs1))),
              (!cast<Instruction>(instruction_name#"_"#fvti.LMul.MX)
                  ivti.RegClass:$rs1, fvti.AVL, fvti.Log2SEW)>;
  }
}

multiclass VPatConvertFP2ISDNode_V<SDNode vop, string instruction_name> {
  foreach fvti = AllFloatVectors in {
    defvar ivti = GetIntVTypeInfo<fvti>.Vti;
    def : Pat<(ivti.Vector (vop (fvti.Vector fvti.RegClass:$rs1))),
              (!cast<Instruction>(instruction_name#"_"#ivti.LMul.MX)
                  fvti.RegClass:$rs1, ivti.AVL, ivti.Log2SEW)>;
  }
}

multiclass VPatWConvertI2FPSDNode_V<SDNode vop, string instruction_name> {
  foreach vtiToWti = AllWidenableIntToFloatVectors in {
    defvar ivti = vtiToWti.Vti;
    defvar fwti = vtiToWti.Wti;
    def : Pat<(fwti.Vector (vop (ivti.Vector ivti.RegClass:$rs1))),
              (!cast<Instruction>(instruction_name#"_"#ivti.LMul.MX)
                  ivti.RegClass:$rs1, ivti.AVL, ivti.Log2SEW)>;
  }
}

multiclass VPatWConvertFP2ISDNode_V<SDNode vop, string instruction_name> {
  foreach fvtiToFWti = AllWidenableFloatVectors in {
    defvar fvti = fvtiToFWti.Vti;
    defvar iwti = GetIntVTypeInfo<fvtiToFWti.Wti>.Vti;
    def : Pat<(iwti.Vector (vop (fvti.Vector fvti.RegClass:$rs1))),
              (!cast<Instruction>(instruction_name#"_"#fvti.LMul.MX)
                  fvti.RegClass:$rs1, fvti.AVL, fvti.Log2SEW)>;
  }
}

multiclass VPatNConvertI2FPSDNode_V<SDNode vop, string instruction_name> {
  foreach fvtiToFWti = AllWidenableFloatVectors in {
    defvar fvti = fvtiToFWti.Vti;
    defvar iwti = GetIntVTypeInfo<fvtiToFWti.Wti>.Vti;
    def : Pat<(fvti.Vector (vop (iwti.Vector iwti.RegClass:$rs1))),
              (!cast<Instruction>(instruction_name#"_"#fvti.LMul.MX)
                  iwti.RegClass:$rs1, fvti.AVL, fvti.Log2SEW)>;
  }
}

multiclass VPatNConvertFP2ISDNode_V<SDNode vop, string instruction_name> {
  foreach vtiToWti = AllWidenableIntToFloatVectors in {
    defvar vti = vtiToWti.Vti;
    defvar fwti = vtiToWti.Wti;
    def : Pat<(vti.Vector (vop (fwti.Vector fwti.RegClass:$rs1))),
              (!cast<Instruction>(instruction_name#"_"#vti.LMul.MX)
                  fwti.RegClass:$rs1, vti.AVL, vti.Log2SEW)>;
  }
}

multiclass VPatWidenBinarySDNode_VV_VX_WV_WX<SDNode op, PatFrags extop, string instruction_name> {
  foreach vti = AllWidenableIntVectors in {
    def : Pat<(op (vti.Wti.Vector (extop (vti.Vti.Vector vti.Vti.RegClass:$rs2))),
                  (vti.Wti.Vector (extop (vti.Vti.Vector vti.Vti.RegClass:$rs1)))),
              (!cast<Instruction>(instruction_name#"_VV_"#vti.Vti.LMul.MX)
                 vti.Vti.RegClass:$rs2, vti.Vti.RegClass:$rs1,
                 vti.Vti.AVL, vti.Vti.Log2SEW)>;
    def : Pat<(op (vti.Wti.Vector (extop (vti.Vti.Vector vti.Vti.RegClass:$rs2))),
                  (vti.Wti.Vector (extop (vti.Vti.Vector (SplatPat GPR:$rs1))))),
              (!cast<Instruction>(instruction_name#"_VX_"#vti.Vti.LMul.MX)
                 vti.Vti.RegClass:$rs2, GPR:$rs1,
                 vti.Vti.AVL, vti.Vti.Log2SEW)>;
    def : Pat<(op (vti.Wti.Vector vti.Wti.RegClass:$rs2),
                  (vti.Wti.Vector (extop (vti.Vti.Vector vti.Vti.RegClass:$rs1)))),
              (!cast<Instruction>(instruction_name#"_WV_"#vti.Vti.LMul.MX)
                 vti.Wti.RegClass:$rs2, vti.Vti.RegClass:$rs1,
                 vti.Vti.AVL, vti.Vti.Log2SEW)>;
    def : Pat<(op (vti.Wti.Vector vti.Wti.RegClass:$rs2),
                  (vti.Wti.Vector (extop (vti.Vti.Vector (SplatPat GPR:$rs1))))),
              (!cast<Instruction>(instruction_name#"_WX_"#vti.Vti.LMul.MX)
                 vti.Wti.RegClass:$rs2, GPR:$rs1,
                 vti.Vti.AVL, vti.Vti.Log2SEW)>;
  }
}

multiclass VPatWidenMulAddSDNode_VV<PatFrags extop1, PatFrags extop2, string instruction_name> {
  foreach vti = AllWidenableIntVectors in {
    def : Pat<
      (add (vti.Wti.Vector vti.Wti.RegClass:$rd),
        (mul_oneuse (vti.Wti.Vector (extop1 (vti.Vti.Vector vti.Vti.RegClass:$rs1))),
                    (vti.Wti.Vector (extop2 (vti.Vti.Vector vti.Vti.RegClass:$rs2))))),
      (!cast<Instruction>(instruction_name#"_VV_"#vti.Vti.LMul.MX)
        vti.Wti.RegClass:$rd, vti.Vti.RegClass:$rs1, vti.Vti.RegClass:$rs2,
        vti.Vti.AVL, vti.Vti.Log2SEW, TAIL_AGNOSTIC
      )>;
  }
}
multiclass VPatWidenMulAddSDNode_VX<PatFrags extop1, PatFrags extop2, string instruction_name> {
  foreach vti = AllWidenableIntVectors in {
    def : Pat<
      (add (vti.Wti.Vector vti.Wti.RegClass:$rd),
        (mul_oneuse (vti.Wti.Vector (extop1 (vti.Vti.Vector (SplatPat GPR:$rs1)))),
                    (vti.Wti.Vector (extop2 (vti.Vti.Vector vti.Vti.RegClass:$rs2))))),
      (!cast<Instruction>(instruction_name#"_VX_"#vti.Vti.LMul.MX)
        vti.Wti.RegClass:$rd, GPR:$rs1, vti.Vti.RegClass:$rs2,
        vti.Vti.AVL, vti.Vti.Log2SEW, TAIL_AGNOSTIC
      )>;
  }
}

multiclass VPatWidenBinaryFPSDNode_VV_VF<SDNode op, string instruction_name> {
  foreach vti = AllWidenableFloatVectors in {
    def : Pat<(op (vti.Wti.Vector (fpext_oneuse (vti.Vti.Vector vti.Vti.RegClass:$rs2))),
                  (vti.Wti.Vector (fpext_oneuse (vti.Vti.Vector vti.Vti.RegClass:$rs1)))),
              (!cast<Instruction>(instruction_name#"_VV_"#vti.Vti.LMul.MX)
                 vti.Vti.RegClass:$rs2, vti.Vti.RegClass:$rs1,
                 vti.Vti.AVL, vti.Vti.Log2SEW)>;
    def : Pat<(op (vti.Wti.Vector (fpext_oneuse (vti.Vti.Vector vti.Vti.RegClass:$rs2))),
                  (vti.Wti.Vector (fpext_oneuse (vti.Vti.Vector (SplatPat vti.Vti.ScalarRegClass:$rs1))))),
              (!cast<Instruction>(instruction_name#"_V"#vti.Vti.ScalarSuffix#"_"#vti.Vti.LMul.MX)
                 vti.Vti.RegClass:$rs2, vti.Vti.ScalarRegClass:$rs1,
                 vti.Vti.AVL, vti.Vti.Log2SEW)>;
  }
}

multiclass VPatWidenBinaryFPSDNode_WV_WF<SDNode op, string instruction_name> {
  foreach vti = AllWidenableFloatVectors in {
    def : Pat<(op (vti.Wti.Vector vti.Wti.RegClass:$rs2),
                  (vti.Wti.Vector (fpext_oneuse (vti.Vti.Vector vti.Vti.RegClass:$rs1)))),
              (!cast<Instruction>(instruction_name#"_WV_"#vti.Vti.LMul.MX)
                 vti.Wti.RegClass:$rs2, vti.Vti.RegClass:$rs1,
                 vti.Vti.AVL, vti.Vti.Log2SEW)>;
    def : Pat<(op (vti.Wti.Vector vti.Wti.RegClass:$rs2),
                  (vti.Wti.Vector (fpext_oneuse (vti.Vti.Vector (SplatPat vti.Vti.ScalarRegClass:$rs1))))),
              (!cast<Instruction>(instruction_name#"_W"#vti.Vti.ScalarSuffix#"_"#vti.Vti.LMul.MX)
                 vti.Wti.RegClass:$rs2, vti.Vti.ScalarRegClass:$rs1,
                 vti.Vti.AVL, vti.Vti.Log2SEW)>;
  }
}

multiclass VPatWidenBinaryFPSDNode_VV_VF_WV_WF<SDNode op, string instruction_name> {
  defm : VPatWidenBinaryFPSDNode_VV_VF<op, instruction_name>;
  defm : VPatWidenBinaryFPSDNode_WV_WF<op, instruction_name>;
}

//===----------------------------------------------------------------------===//
// Patterns.
//===----------------------------------------------------------------------===//

let Predicates = [HasVInstructions] in {

// 7.4. Vector Unit-Stride Instructions
foreach vti = !listconcat(FractionalGroupIntegerVectors,
                          FractionalGroupFloatVectors) in
  defm : VPatUSLoadStoreSDNode<vti.Vector, vti.Log2SEW, vti.LMul,
                               vti.AVL, vti.RegClass>;
foreach vti = [VI8M1, VI16M1, VI32M1, VI64M1, VF16M1, VF32M1, VF64M1] in
  defm : VPatUSLoadStoreWholeVRSDNode<vti.Vector, vti.Log2SEW, vti.LMul,
                                      vti.RegClass>;
foreach vti = !listconcat(GroupIntegerVectors, GroupFloatVectors) in
  defm : VPatUSLoadStoreWholeVRSDNode<vti.Vector, vti.Log2SEW, vti.LMul,
                                      vti.RegClass>;
foreach mti = AllMasks in
  defm : VPatUSLoadStoreMaskSDNode<mti>;

// 12.1. Vector Single-Width Integer Add and Subtract
defm : VPatBinarySDNode_VV_VX_VI<add, "PseudoVADD">;
defm : VPatBinarySDNode_VV_VX<sub, "PseudoVSUB">;
// Handle VRSUB specially since it's the only integer binary op with reversed
// pattern operands
foreach vti = AllIntegerVectors in {
  def : Pat<(sub (vti.Vector (SplatPat GPR:$rs2)),
                 (vti.Vector vti.RegClass:$rs1)),
            (!cast<Instruction>("PseudoVRSUB_VX_"# vti.LMul.MX)
                 vti.RegClass:$rs1, GPR:$rs2, vti.AVL, vti.Log2SEW)>;
  def : Pat<(sub (vti.Vector (SplatPat_simm5 simm5:$rs2)),
                 (vti.Vector vti.RegClass:$rs1)),
            (!cast<Instruction>("PseudoVRSUB_VI_"# vti.LMul.MX)
                 vti.RegClass:$rs1, simm5:$rs2, vti.AVL, vti.Log2SEW)>;
}

// 12.2. Vector Widening Integer Add and Subtract
defm : VPatWidenBinarySDNode_VV_VX_WV_WX<add, sext_oneuse, "PseudoVWADD">;
defm : VPatWidenBinarySDNode_VV_VX_WV_WX<add, zext_oneuse, "PseudoVWADDU">;
defm : VPatWidenBinarySDNode_VV_VX_WV_WX<add, anyext_oneuse, "PseudoVWADDU">;

defm : VPatWidenBinarySDNode_VV_VX_WV_WX<sub, sext_oneuse, "PseudoVWSUB">;
defm : VPatWidenBinarySDNode_VV_VX_WV_WX<sub, zext_oneuse, "PseudoVWSUBU">;
defm : VPatWidenBinarySDNode_VV_VX_WV_WX<sub, anyext_oneuse, "PseudoVWSUBU">;

// 12.3. Vector Integer Extension
defm : VPatExtendSDNode_V<[zext, anyext], "PseudoVZEXT", "VF2",
                          AllFractionableVF2IntVectors>;
defm : VPatExtendSDNode_V<[sext],         "PseudoVSEXT", "VF2",
                          AllFractionableVF2IntVectors>;
defm : VPatExtendSDNode_V<[zext, anyext], "PseudoVZEXT", "VF4",
                          AllFractionableVF4IntVectors>;
defm : VPatExtendSDNode_V<[sext],         "PseudoVSEXT", "VF4",
                          AllFractionableVF4IntVectors>;
defm : VPatExtendSDNode_V<[zext, anyext], "PseudoVZEXT", "VF8",
                          AllFractionableVF8IntVectors>;
defm : VPatExtendSDNode_V<[sext],         "PseudoVSEXT", "VF8",
                          AllFractionableVF8IntVectors>;

// 12.5. Vector Bitwise Logical Instructions
defm : VPatBinarySDNode_VV_VX_VI<and, "PseudoVAND">;
defm : VPatBinarySDNode_VV_VX_VI<or, "PseudoVOR">;
defm : VPatBinarySDNode_VV_VX_VI<xor, "PseudoVXOR">;

// 12.6. Vector Single-Width Bit Shift Instructions
defm : VPatBinarySDNode_VV_VX_VI<shl, "PseudoVSLL", uimm5>;
defm : VPatBinarySDNode_VV_VX_VI<srl, "PseudoVSRL", uimm5>;
defm : VPatBinarySDNode_VV_VX_VI<sra, "PseudoVSRA", uimm5>;

foreach vti = AllIntegerVectors in {
  // Emit shift by 1 as an add since it might be faster.
  def : Pat<(shl (vti.Vector vti.RegClass:$rs1),
                 (vti.Vector (splat_vector (XLenVT 1)))),
            (!cast<Instruction>("PseudoVADD_VV_"# vti.LMul.MX)
                 vti.RegClass:$rs1, vti.RegClass:$rs1, vti.AVL, vti.Log2SEW)>;
}
foreach vti = [VI64M1, VI64M2, VI64M4, VI64M8] in {
  def : Pat<(shl (vti.Vector vti.RegClass:$rs1),
                 (vti.Vector (rv32_splat_i64 (XLenVT 1)))),
            (!cast<Instruction>("PseudoVADD_VV_"# vti.LMul.MX)
                 vti.RegClass:$rs1, vti.RegClass:$rs1, vti.AVL, vti.Log2SEW)>;

}

// 12.8. Vector Integer Comparison Instructions
defm : VPatIntegerSetCCSDNode_VV_VX_VI<SETEQ,  "PseudoVMSEQ">;
defm : VPatIntegerSetCCSDNode_VV_VX_VI<SETNE,  "PseudoVMSNE">;

defm : VPatIntegerSetCCSDNode_VV_VX<SETLT,  "PseudoVMSLT">;
defm : VPatIntegerSetCCSDNode_VV_VX<SETULT, "PseudoVMSLTU">;
defm : VPatIntegerSetCCSDNode_VIPlus1<SETLT, "PseudoVMSLE",
                                      SplatPat_simm5_plus1_nonzero>;
defm : VPatIntegerSetCCSDNode_VIPlus1<SETULT, "PseudoVMSLEU",
                                      SplatPat_simm5_plus1_nonzero>;

defm : VPatIntegerSetCCSDNode_VV<SETGT,  "PseudoVMSLT", /*swap*/1>;
defm : VPatIntegerSetCCSDNode_VV<SETUGT, "PseudoVMSLTU", /*swap*/1>;
defm : VPatIntegerSetCCSDNode_VX_VI<SETGT,  "PseudoVMSGT">;
defm : VPatIntegerSetCCSDNode_VX_VI<SETUGT, "PseudoVMSGTU">;

defm : VPatIntegerSetCCSDNode_VV_VX_VI<SETLE,  "PseudoVMSLE">;
defm : VPatIntegerSetCCSDNode_VV_VX_VI<SETULE, "PseudoVMSLEU">;

defm : VPatIntegerSetCCSDNode_VV<SETGE,  "PseudoVMSLE", /*swap*/1>;
defm : VPatIntegerSetCCSDNode_VV<SETUGE, "PseudoVMSLEU", /*swap*/1>;
defm : VPatIntegerSetCCSDNode_VIPlus1<SETGE, "PseudoVMSGT",
                                      SplatPat_simm5_plus1>;
defm : VPatIntegerSetCCSDNode_VIPlus1<SETUGE, "PseudoVMSGTU",
                                      SplatPat_simm5_plus1_nonzero>;

// 12.9. Vector Integer Min/Max Instructions
defm : VPatBinarySDNode_VV_VX<umin, "PseudoVMINU">;
defm : VPatBinarySDNode_VV_VX<smin, "PseudoVMIN">;
defm : VPatBinarySDNode_VV_VX<umax, "PseudoVMAXU">;
defm : VPatBinarySDNode_VV_VX<smax, "PseudoVMAX">;

// 12.10. Vector Single-Width Integer Multiply Instructions
defm : VPatBinarySDNode_VV_VX<mul, "PseudoVMUL">;
defm : VPatBinarySDNode_VV_VX<mulhs, "PseudoVMULH">;
defm : VPatBinarySDNode_VV_VX<mulhu, "PseudoVMULHU">;

// 12.11. Vector Integer Divide Instructions
defm : VPatBinarySDNode_VV_VX<udiv, "PseudoVDIVU">;
defm : VPatBinarySDNode_VV_VX<sdiv, "PseudoVDIV">;
defm : VPatBinarySDNode_VV_VX<urem, "PseudoVREMU">;
defm : VPatBinarySDNode_VV_VX<srem, "PseudoVREM">;

// 12.13 Vector Single-Width Integer Multiply-Add Instructions.
foreach vti = AllIntegerVectors in {
  // NOTE: We choose VMADD because it has the most commuting freedom. So it
  // works best with how TwoAddressInstructionPass tries commuting.
  defvar suffix = vti.LMul.MX;
  def : Pat<(vti.Vector (add vti.RegClass:$rs2,
                              (mul_oneuse vti.RegClass:$rs1, vti.RegClass:$rd))),
            (!cast<Instruction>("PseudoVMADD_VV_"# suffix)
                 vti.RegClass:$rd, vti.RegClass:$rs1, vti.RegClass:$rs2,
                 vti.AVL, vti.Log2SEW, TAIL_AGNOSTIC)>;
  def : Pat<(vti.Vector (sub vti.RegClass:$rs2,
                              (mul_oneuse vti.RegClass:$rs1, vti.RegClass:$rd))),
            (!cast<Instruction>("PseudoVNMSUB_VV_"# suffix)
                 vti.RegClass:$rd, vti.RegClass:$rs1, vti.RegClass:$rs2,
                 vti.AVL, vti.Log2SEW, TAIL_AGNOSTIC)>;

  // The choice of VMADD here is arbitrary, vmadd.vx and vmacc.vx are equally
  // commutable.
  def : Pat<(vti.Vector (add vti.RegClass:$rs2,
                              (mul_oneuse (SplatPat XLenVT:$rs1),
                                          vti.RegClass:$rd))),
            (!cast<Instruction>("PseudoVMADD_VX_" # suffix)
                 vti.RegClass:$rd, vti.ScalarRegClass:$rs1, vti.RegClass:$rs2,
                 vti.AVL, vti.Log2SEW, TAIL_AGNOSTIC)>;
  def : Pat<(vti.Vector (sub vti.RegClass:$rs2,
                              (mul_oneuse (SplatPat XLenVT:$rs1),
                                          vti.RegClass:$rd))),
            (!cast<Instruction>("PseudoVNMSUB_VX_" # suffix)
                 vti.RegClass:$rd, vti.ScalarRegClass:$rs1, vti.RegClass:$rs2,
                 vti.AVL, vti.Log2SEW, TAIL_AGNOSTIC)>;
}

// 12.14 Vector Widening Integer Multiply-Add Instructions
defm : VPatWidenMulAddSDNode_VV<sext_oneuse, sext_oneuse, "PseudoVWMACC">;
defm : VPatWidenMulAddSDNode_VX<sext_oneuse, sext_oneuse, "PseudoVWMACC">;
defm : VPatWidenMulAddSDNode_VV<zext_oneuse, zext_oneuse, "PseudoVWMACCU">;
defm : VPatWidenMulAddSDNode_VX<zext_oneuse, zext_oneuse, "PseudoVWMACCU">;
defm : VPatWidenMulAddSDNode_VV<sext_oneuse, zext_oneuse, "PseudoVWMACCSU">;
defm : VPatWidenMulAddSDNode_VX<sext_oneuse, zext_oneuse, "PseudoVWMACCSU">;
defm : VPatWidenMulAddSDNode_VX<zext_oneuse, sext_oneuse, "PseudoVWMACCUS">;

// 12.15. Vector Integer Merge Instructions
foreach vti = AllIntegerVectors in {
  def : Pat<(vti.Vector (vselect (vti.Mask V0), vti.RegClass:$rs1,
                                                      vti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVMERGE_VVM_"#vti.LMul.MX)
                 vti.RegClass:$rs2, vti.RegClass:$rs1, (vti.Mask V0),
                 vti.AVL, vti.Log2SEW)>;

  def : Pat<(vti.Vector (vselect (vti.Mask V0), (SplatPat XLenVT:$rs1),
                                                      vti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVMERGE_VXM_"#vti.LMul.MX)
                 vti.RegClass:$rs2, GPR:$rs1, (vti.Mask V0), vti.AVL, vti.Log2SEW)>;

  def : Pat<(vti.Vector (vselect (vti.Mask V0), (SplatPat_simm5 simm5:$rs1),
                                                      vti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVMERGE_VIM_"#vti.LMul.MX)
                 vti.RegClass:$rs2, simm5:$rs1, (vti.Mask V0), vti.AVL, vti.Log2SEW)>;
}

// 12.1. Vector Single-Width Saturating Add and Subtract
defm : VPatBinarySDNode_VV_VX_VI<saddsat, "PseudoVSADD">;
defm : VPatBinarySDNode_VV_VX_VI<uaddsat, "PseudoVSADDU">;
defm : VPatBinarySDNode_VV_VX<ssubsat, "PseudoVSSUB">;
defm : VPatBinarySDNode_VV_VX<usubsat, "PseudoVSSUBU">;

// 16.1. Vector Mask-Register Logical Instructions
foreach mti = AllMasks in {
  def : Pat<(mti.Mask (and VR:$rs1, VR:$rs2)),
            (!cast<Instruction>("PseudoVMAND_MM_"#mti.LMul.MX)
                 VR:$rs1, VR:$rs2, mti.AVL, mti.Log2SEW)>;
  def : Pat<(mti.Mask (or VR:$rs1, VR:$rs2)),
            (!cast<Instruction>("PseudoVMOR_MM_"#mti.LMul.MX)
                 VR:$rs1, VR:$rs2, mti.AVL, mti.Log2SEW)>;
  def : Pat<(mti.Mask (xor VR:$rs1, VR:$rs2)),
            (!cast<Instruction>("PseudoVMXOR_MM_"#mti.LMul.MX)
                 VR:$rs1, VR:$rs2, mti.AVL, mti.Log2SEW)>;

  def : Pat<(mti.Mask (rvv_vnot (and VR:$rs1, VR:$rs2))),
            (!cast<Instruction>("PseudoVMNAND_MM_"#mti.LMul.MX)
                 VR:$rs1, VR:$rs2, mti.AVL, mti.Log2SEW)>;
  def : Pat<(mti.Mask (rvv_vnot (or VR:$rs1, VR:$rs2))),
            (!cast<Instruction>("PseudoVMNOR_MM_"#mti.LMul.MX)
                 VR:$rs1, VR:$rs2, mti.AVL, mti.Log2SEW)>;
  def : Pat<(mti.Mask (rvv_vnot (xor VR:$rs1, VR:$rs2))),
            (!cast<Instruction>("PseudoVMXNOR_MM_"#mti.LMul.MX)
                 VR:$rs1, VR:$rs2, mti.AVL, mti.Log2SEW)>;

  def : Pat<(mti.Mask (and VR:$rs1, (rvv_vnot VR:$rs2))),
            (!cast<Instruction>("PseudoVMANDN_MM_"#mti.LMul.MX)
                 VR:$rs1, VR:$rs2, mti.AVL, mti.Log2SEW)>;
  def : Pat<(mti.Mask (or VR:$rs1, (rvv_vnot VR:$rs2))),
            (!cast<Instruction>("PseudoVMORN_MM_"#mti.LMul.MX)
                 VR:$rs1, VR:$rs2, mti.AVL, mti.Log2SEW)>;

  // Handle rvv_vnot the same as the vmnot.m pseudoinstruction.
  def : Pat<(mti.Mask (rvv_vnot VR:$rs)),
            (!cast<Instruction>("PseudoVMNAND_MM_"#mti.LMul.MX)
                 VR:$rs, VR:$rs, mti.AVL, mti.Log2SEW)>;
}

} // Predicates = [HasVInstructions]

let Predicates = [HasVInstructionsAnyF] in {

// 14.2. Vector Single-Width Floating-Point Add/Subtract Instructions
defm : VPatBinaryFPSDNode_VV_VF<fadd, "PseudoVFADD">;
defm : VPatBinaryFPSDNode_VV_VF<fsub, "PseudoVFSUB">;
defm : VPatBinaryFPSDNode_R_VF<fsub, "PseudoVFRSUB">;

// 14.3. Vector Widening Floating-Point Add/Subtract Instructions
defm : VPatWidenBinaryFPSDNode_VV_VF_WV_WF<fadd, "PseudoVFWADD">;
defm : VPatWidenBinaryFPSDNode_VV_VF_WV_WF<fsub, "PseudoVFWSUB">;

// 14.4. Vector Single-Width Floating-Point Multiply/Divide Instructions
defm : VPatBinaryFPSDNode_VV_VF<fmul, "PseudoVFMUL">;
defm : VPatBinaryFPSDNode_VV_VF<fdiv, "PseudoVFDIV">;
defm : VPatBinaryFPSDNode_R_VF<fdiv, "PseudoVFRDIV">;

// 14.5. Vector Widening Floating-Point Multiply Instructions
defm : VPatWidenBinaryFPSDNode_VV_VF<fmul, "PseudoVFWMUL">;

// 14.6 Vector Single-Width Floating-Point Fused Multiply-Add Instructions.
foreach fvti = AllFloatVectors in {
  // NOTE: We choose VFMADD because it has the most commuting freedom. So it
  // works best with how TwoAddressInstructionPass tries commuting.
  defvar suffix = fvti.LMul.MX;
  def : Pat<(fvti.Vector (fma fvti.RegClass:$rs1, fvti.RegClass:$rd,
                              fvti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVFMADD_VV_"# suffix)
                 fvti.RegClass:$rd, fvti.RegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;
  def : Pat<(fvti.Vector (fma fvti.RegClass:$rs1, fvti.RegClass:$rd,
                              (fneg fvti.RegClass:$rs2))),
            (!cast<Instruction>("PseudoVFMSUB_VV_"# suffix)
                 fvti.RegClass:$rd, fvti.RegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;
  def : Pat<(fvti.Vector (fma (fneg fvti.RegClass:$rs1), fvti.RegClass:$rd,
                              (fneg fvti.RegClass:$rs2))),
            (!cast<Instruction>("PseudoVFNMADD_VV_"# suffix)
                 fvti.RegClass:$rd, fvti.RegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;
  def : Pat<(fvti.Vector (fma (fneg fvti.RegClass:$rs1), fvti.RegClass:$rd,
                              fvti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVFNMSUB_VV_"# suffix)
                 fvti.RegClass:$rd, fvti.RegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;

  // The choice of VFMADD here is arbitrary, vfmadd.vf and vfmacc.vf are equally
  // commutable.
  def : Pat<(fvti.Vector (fma (splat_vector fvti.ScalarRegClass:$rs1),
                              fvti.RegClass:$rd, fvti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVFMADD_V" # fvti.ScalarSuffix # "_" # suffix)
                 fvti.RegClass:$rd, fvti.ScalarRegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;
  def : Pat<(fvti.Vector (fma (splat_vector fvti.ScalarRegClass:$rs1),
                              fvti.RegClass:$rd, (fneg fvti.RegClass:$rs2))),
            (!cast<Instruction>("PseudoVFMSUB_V" # fvti.ScalarSuffix # "_" # suffix)
                 fvti.RegClass:$rd, fvti.ScalarRegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;

  def : Pat<(fvti.Vector (fma (splat_vector fvti.ScalarRegClass:$rs1),
                              (fneg fvti.RegClass:$rd), (fneg fvti.RegClass:$rs2))),
            (!cast<Instruction>("PseudoVFNMADD_V" # fvti.ScalarSuffix # "_" # suffix)
                 fvti.RegClass:$rd, fvti.ScalarRegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;
  def : Pat<(fvti.Vector (fma (splat_vector fvti.ScalarRegClass:$rs1),
                              (fneg fvti.RegClass:$rd), fvti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVFNMSUB_V" # fvti.ScalarSuffix # "_" # suffix)
                 fvti.RegClass:$rd, fvti.ScalarRegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;

  // The splat might be negated.
  def : Pat<(fvti.Vector (fma (fneg (splat_vector fvti.ScalarRegClass:$rs1)),
                              fvti.RegClass:$rd, (fneg fvti.RegClass:$rs2))),
            (!cast<Instruction>("PseudoVFNMADD_V" # fvti.ScalarSuffix # "_" # suffix)
                 fvti.RegClass:$rd, fvti.ScalarRegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;
  def : Pat<(fvti.Vector (fma (fneg (splat_vector fvti.ScalarRegClass:$rs1)),
                              fvti.RegClass:$rd, fvti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVFNMSUB_V" # fvti.ScalarSuffix # "_" # suffix)
                 fvti.RegClass:$rd, fvti.ScalarRegClass:$rs1, fvti.RegClass:$rs2,
                 fvti.AVL, fvti.Log2SEW, TAIL_AGNOSTIC)>;
}

foreach vti = AllFloatVectors in {
  // 14.8. Vector Floating-Point Square-Root Instruction
  def : Pat<(fsqrt (vti.Vector vti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVFSQRT_V_"# vti.LMul.MX)
                 vti.RegClass:$rs2, vti.AVL, vti.Log2SEW)>;

  // 14.12. Vector Floating-Point Sign-Injection Instructions
  def : Pat<(fabs (vti.Vector vti.RegClass:$rs)),
            (!cast<Instruction>("PseudoVFSGNJX_VV_"# vti.LMul.MX)
                 vti.RegClass:$rs, vti.RegClass:$rs, vti.AVL, vti.Log2SEW)>;
  // Handle fneg with VFSGNJN using the same input for both operands.
  def : Pat<(fneg (vti.Vector vti.RegClass:$rs)),
            (!cast<Instruction>("PseudoVFSGNJN_VV_"# vti.LMul.MX)
                 vti.RegClass:$rs, vti.RegClass:$rs, vti.AVL, vti.Log2SEW)>;

  def : Pat<(vti.Vector (fcopysign (vti.Vector vti.RegClass:$rs1),
                                   (vti.Vector vti.RegClass:$rs2))),
            (!cast<Instruction>("PseudoVFSGNJ_VV_"# vti.LMul.MX)
                 vti.RegClass:$rs1, vti.RegClass:$rs2, vti.AVL, vti.Log2SEW)>;
  def : Pat<(vti.Vector (fcopysign (vti.Vector vti.RegClass:$rs1),
                                   (vti.Vector (splat_vector vti.ScalarRegClass:$rs2)))),
            (!cast<Instruction>("PseudoVFSGNJ_V"#vti.ScalarSuffix#"_"#vti.LMul.MX)
                 vti.RegClass:$rs1, vti.ScalarRegClass:$rs2, vti.AVL, vti.Log2SEW)>;

  def : Pat<(vti.Vector (fcopysign (vti.Vector vti.RegClass:$rs1),
                                   (vti.Vector (fneg vti.RegClass:$rs2)))),
            (!cast<Instruction>("PseudoVFSGNJN_VV_"# vti.LMul.MX)
                 vti.RegClass:$rs1, vti.RegClass:$rs2, vti.AVL, vti.Log2SEW)>;
  def : Pat<(vti.Vector (fcopysign (vti.Vector vti.RegClass:$rs1),
                                   (vti.Vector (fneg (splat_vector vti.ScalarRegClass:$rs2))))),
            (!cast<Instruction>("PseudoVFSGNJN_V"#vti.ScalarSuffix#"_"#vti.LMul.MX)
                 vti.RegClass:$rs1, vti.ScalarRegClass:$rs2, vti.AVL, vti.Log2SEW)>;
}

// 14.11. Vector Floating-Point MIN/MAX Instructions
defm : VPatBinaryFPSDNode_VV_VF<fminnum, "PseudoVFMIN">;
defm : VPatBinaryFPSDNode_VV_VF<fmaxnum, "PseudoVFMAX">;

// 14.13. Vector Floating-Point Compare Instructions
defm : VPatFPSetCCSDNode_VV_VF_FV<SETEQ,  "PseudoVMFEQ", "PseudoVMFEQ">;
defm : VPatFPSetCCSDNode_VV_VF_FV<SETOEQ, "PseudoVMFEQ", "PseudoVMFEQ">;

defm : VPatFPSetCCSDNode_VV_VF_FV<SETNE,  "PseudoVMFNE", "PseudoVMFNE">;
defm : VPatFPSetCCSDNode_VV_VF_FV<SETUNE, "PseudoVMFNE", "PseudoVMFNE">;

defm : VPatFPSetCCSDNode_VV_VF_FV<SETLT,  "PseudoVMFLT", "PseudoVMFGT">;
defm : VPatFPSetCCSDNode_VV_VF_FV<SETOLT, "PseudoVMFLT", "PseudoVMFGT">;

defm : VPatFPSetCCSDNode_VV_VF_FV<SETLE,  "PseudoVMFLE", "PseudoVMFGE">;
defm : VPatFPSetCCSDNode_VV_VF_FV<SETOLE, "PseudoVMFLE", "PseudoVMFGE">;

// Floating-point vselects:
// 12.15. Vector Integer Merge Instructions
// 14.15. Vector Floating-Point Merge Instruction
foreach fvti = AllFloatVectors in {
  def : Pat<(fvti.Vector (vselect (fvti.Mask V0), fvti.RegClass:$rs1,
                                                        fvti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVMERGE_VVM_"#fvti.LMul.MX)
                 fvti.RegClass:$rs2, fvti.RegClass:$rs1, (fvti.Mask V0),
                 fvti.AVL, fvti.Log2SEW)>;

  def : Pat<(fvti.Vector (vselect (fvti.Mask V0),
                                  (splat_vector fvti.ScalarRegClass:$rs1),
                                  fvti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVFMERGE_V"#fvti.ScalarSuffix#"M_"#fvti.LMul.MX)
                 fvti.RegClass:$rs2,
                 (fvti.Scalar fvti.ScalarRegClass:$rs1),
                 (fvti.Mask V0), fvti.AVL, fvti.Log2SEW)>;

  def : Pat<(fvti.Vector (vselect (fvti.Mask V0),
                                  (splat_vector (fvti.Scalar fpimm0)),
                                  fvti.RegClass:$rs2)),
            (!cast<Instruction>("PseudoVMERGE_VIM_"#fvti.LMul.MX)
                 fvti.RegClass:$rs2, 0, (fvti.Mask V0), fvti.AVL, fvti.Log2SEW)>;
}

// 14.17. Vector Single-Width Floating-Point/Integer Type-Convert Instructions
defm : VPatConvertFP2ISDNode_V<fp_to_sint, "PseudoVFCVT_RTZ_X_F_V">;
defm : VPatConvertFP2ISDNode_V<fp_to_uint, "PseudoVFCVT_RTZ_XU_F_V">;
defm : VPatConvertI2FPSDNode_V<sint_to_fp, "PseudoVFCVT_F_X_V">;
defm : VPatConvertI2FPSDNode_V<uint_to_fp, "PseudoVFCVT_F_XU_V">;

// 14.18. Widening Floating-Point/Integer Type-Convert Instructions
defm : VPatWConvertFP2ISDNode_V<fp_to_sint, "PseudoVFWCVT_RTZ_X_F_V">;
defm : VPatWConvertFP2ISDNode_V<fp_to_uint, "PseudoVFWCVT_RTZ_XU_F_V">;
defm : VPatWConvertI2FPSDNode_V<sint_to_fp, "PseudoVFWCVT_F_X_V">;
defm : VPatWConvertI2FPSDNode_V<uint_to_fp, "PseudoVFWCVT_F_XU_V">;
foreach fvtiToFWti = AllWidenableFloatVectors in {
  defvar fvti = fvtiToFWti.Vti;
  defvar fwti = fvtiToFWti.Wti;
  def : Pat<(fwti.Vector (fpextend (fvti.Vector fvti.RegClass:$rs1))),
            (!cast<Instruction>("PseudoVFWCVT_F_F_V_"#fvti.LMul.MX)
                fvti.RegClass:$rs1, fvti.AVL, fvti.Log2SEW)>;
}

// 14.19. Narrowing Floating-Point/Integer Type-Convert Instructions
defm : VPatNConvertFP2ISDNode_V<fp_to_sint, "PseudoVFNCVT_RTZ_X_F_W">;
defm : VPatNConvertFP2ISDNode_V<fp_to_uint, "PseudoVFNCVT_RTZ_XU_F_W">;
defm : VPatNConvertI2FPSDNode_V<sint_to_fp, "PseudoVFNCVT_F_X_W">;
defm : VPatNConvertI2FPSDNode_V<uint_to_fp, "PseudoVFNCVT_F_XU_W">;
foreach fvtiToFWti = AllWidenableFloatVectors in {
  defvar fvti = fvtiToFWti.Vti;
  defvar fwti = fvtiToFWti.Wti;
  def : Pat<(fvti.Vector (fpround (fwti.Vector fwti.RegClass:$rs1))),
            (!cast<Instruction>("PseudoVFNCVT_F_F_W_"#fvti.LMul.MX)
                fwti.RegClass:$rs1, fvti.AVL, fvti.Log2SEW)>;
}
} // Predicates = [HasVInstructionsAnyF]

//===----------------------------------------------------------------------===//
// Vector Splats
//===----------------------------------------------------------------------===//

let Predicates = [HasVInstructions] in {
foreach vti = AllIntegerVectors in {
  def : Pat<(vti.Vector (SplatPat GPR:$rs1)),
            (!cast<Instruction>("PseudoVMV_V_X_" # vti.LMul.MX)
              GPR:$rs1, vti.AVL, vti.Log2SEW)>;
  def : Pat<(vti.Vector (SplatPat_simm5 simm5:$rs1)),
            (!cast<Instruction>("PseudoVMV_V_I_" # vti.LMul.MX)
              simm5:$rs1, vti.AVL, vti.Log2SEW)>;
}
} // Predicates = [HasVInstructions]

let Predicates = [HasVInstructionsAnyF] in {
foreach fvti = AllFloatVectors in {
  def : Pat<(fvti.Vector (splat_vector fvti.ScalarRegClass:$rs1)),
            (!cast<Instruction>("PseudoVFMV_V_"#fvti.ScalarSuffix#"_"#fvti.LMul.MX)
              (fvti.Scalar fvti.ScalarRegClass:$rs1),
              fvti.AVL, fvti.Log2SEW)>;

  def : Pat<(fvti.Vector (splat_vector (fvti.Scalar fpimm0))),
            (!cast<Instruction>("PseudoVMV_V_I_"#fvti.LMul.MX)
              0, fvti.AVL, fvti.Log2SEW)>;
}
} // Predicates = [HasVInstructionsAnyF]

//===----------------------------------------------------------------------===//
// Vector Element Extracts
//===----------------------------------------------------------------------===//
let Predicates = [HasVInstructionsAnyF] in
foreach vti = AllFloatVectors in {
  defvar vmv_f_s_inst = !cast<Instruction>(!strconcat("PseudoVFMV_",
                                                       vti.ScalarSuffix,
                                                       "_S_", vti.LMul.MX));
  // Only pattern-match extract-element operations where the index is 0. Any
  // other index will have been custom-lowered to slide the vector correctly
  // into place.
  def : Pat<(vti.Scalar (extractelt (vti.Vector vti.RegClass:$rs2), 0)),
            (vmv_f_s_inst vti.RegClass:$rs2, vti.Log2SEW)>;
}