+// Group template arguments that can be derived from the vector type (EltNum x
+// EltVT). These are things like the register class for the writemask, etc.
+// The idea is to pass one of these as the template argument rather than the
+// individual arguments.
+class X86VectorVTInfo<int numelts, ValueType EltVT, RegisterClass rc,
+ string suffix = ""> {
+ RegisterClass RC = rc;
+ int NumElts = numelts;
+
+ // Corresponding mask register class.
+ RegisterClass KRC = !cast<RegisterClass>("VK" # NumElts);
+
+ // Corresponding write-mask register class.
+ RegisterClass KRCWM = !cast<RegisterClass>("VK" # NumElts # "WM");
+
+ // The GPR register class that can hold the write mask. Use GR8 for fewer
+ // than 8 elements. Use shift-right and equal to work around the lack of
+ // !lt in tablegen.
+ RegisterClass MRC =
+ !cast<RegisterClass>("GR" #
+ !if (!eq (!srl(NumElts, 3), 0), 8, NumElts));
+
+ // Suffix used in the instruction mnemonic.
+ string Suffix = suffix;
+
+ string VTName = "v" # NumElts # EltVT;
+
+ // The vector VT.
+ ValueType VT = !cast<ValueType>(VTName);
+
+ string EltTypeName = !cast<string>(EltVT);
+ // Size of the element type in bits, e.g. 32 for v16i32.
+ string EltSizeName = !subst("i", "", !subst("f", "", EltTypeName));
+ int EltSize = EltVT.Size;
+
+ // "i" for integer types and "f" for floating-point types
+ string TypeVariantName = !subst(EltSizeName, "", EltTypeName);
+
+ // Size of RC in bits, e.g. 512 for VR512.
+ int Size = VT.Size;
+
+ // The corresponding memory operand, e.g. i512mem for VR512.
+ X86MemOperand MemOp = !cast<X86MemOperand>(TypeVariantName # Size # "mem");
+ X86MemOperand ScalarMemOp = !cast<X86MemOperand>(EltVT # "mem");
+
+ // Load patterns
+ // Note: For 128/256-bit integer VT we choose loadv2i64/loadv4i64
+ // due to load promotion during legalization
+ PatFrag LdFrag = !cast<PatFrag>("load" #
+ !if (!eq (TypeVariantName, "i"),
+ !if (!eq (Size, 128), "v2i64",
+ !if (!eq (Size, 256), "v4i64",
+ VTName)), VTName));
+ PatFrag ScalarLdFrag = !cast<PatFrag>("load" # EltVT);
+
+ // Load patterns used for memory operands. We only have this defined in
+ // case of i64 element types for sub-512 integer vectors. For now, keep
+ // MemOpFrag undefined in these cases.
+ PatFrag MemOpFrag =
+ !if (!eq (TypeVariantName, "f"), !cast<PatFrag>("memop" # VTName),
+ !if (!eq (EltTypeName, "i64"), !cast<PatFrag>("memop" # VTName),
+ !if (!eq (VTName, "v16i32"), !cast<PatFrag>("memop" # VTName), ?)));
+
+ // The corresponding float type, e.g. v16f32 for v16i32
+ // Note: For EltSize < 32, FloatVT is illegal and TableGen
+ // fails to compile, so we choose FloatVT = VT
+ ValueType FloatVT = !cast<ValueType>(
+ !if (!eq (!srl(EltSize,5),0),
+ VTName,
+ !if (!eq(TypeVariantName, "i"),
+ "v" # NumElts # "f" # EltSize,
+ VTName)));
+
+ // The string to specify embedded broadcast in assembly.
+ string BroadcastStr = "{1to" # NumElts # "}";
+
+ // 8-bit compressed displacement tuple/subvector format. This is only
+ // defined for NumElts <= 8.
+ CD8VForm CD8TupleForm = !if (!eq (!srl(NumElts, 4), 0),
+ !cast<CD8VForm>("CD8VT" # NumElts), ?);
+
+ SubRegIndex SubRegIdx = !if (!eq (Size, 128), sub_xmm,
+ !if (!eq (Size, 256), sub_ymm, ?));
+
+ Domain ExeDomain = !if (!eq (EltTypeName, "f32"), SSEPackedSingle,
+ !if (!eq (EltTypeName, "f64"), SSEPackedDouble,
+ SSEPackedInt));
+
+ // A vector type of the same width with element type i32. This is used to
+ // create the canonical constant zero node ImmAllZerosV.
+ ValueType i32VT = !cast<ValueType>("v" # !srl(Size, 5) # "i32");
+ dag ImmAllZerosV = (VT (bitconvert (i32VT immAllZerosV)));
+}
+
+def v64i8_info : X86VectorVTInfo<64, i8, VR512, "b">;
+def v32i16_info : X86VectorVTInfo<32, i16, VR512, "w">;
+def v16i32_info : X86VectorVTInfo<16, i32, VR512, "d">;
+def v8i64_info : X86VectorVTInfo<8, i64, VR512, "q">;
+def v16f32_info : X86VectorVTInfo<16, f32, VR512, "ps">;
+def v8f64_info : X86VectorVTInfo<8, f64, VR512, "pd">;
+
+// "x" in v32i8x_info means RC = VR256X
+def v32i8x_info : X86VectorVTInfo<32, i8, VR256X, "b">;
+def v16i16x_info : X86VectorVTInfo<16, i16, VR256X, "w">;
+def v8i32x_info : X86VectorVTInfo<8, i32, VR256X, "d">;
+def v4i64x_info : X86VectorVTInfo<4, i64, VR256X, "q">;
+
+def v16i8x_info : X86VectorVTInfo<16, i8, VR128X, "b">;
+def v8i16x_info : X86VectorVTInfo<8, i16, VR128X, "w">;
+def v4i32x_info : X86VectorVTInfo<4, i32, VR128X, "d">;
+def v2i64x_info : X86VectorVTInfo<2, i64, VR128X, "q">;
+
+class AVX512VLVectorVTInfo<X86VectorVTInfo i512, X86VectorVTInfo i256,
+ X86VectorVTInfo i128> {
+ X86VectorVTInfo info512 = i512;
+ X86VectorVTInfo info256 = i256;
+ X86VectorVTInfo info128 = i128;
+}
+
+def avx512vl_i8_info : AVX512VLVectorVTInfo<v64i8_info, v32i8x_info,
+ v16i8x_info>;
+def avx512vl_i16_info : AVX512VLVectorVTInfo<v32i16_info, v16i16x_info,
+ v8i16x_info>;
+def avx512vl_i32_info : AVX512VLVectorVTInfo<v16i32_info, v8i32x_info,
+ v4i32x_info>;
+def avx512vl_i64_info : AVX512VLVectorVTInfo<v8i64_info, v4i64x_info,
+ v2i64x_info>;
+
+// This multiclass generates the masking variants from the non-masking
+// variant. It only provides the assembly pieces for the masking variants.
+// It assumes custom ISel patterns for masking which can be provided as
+// template arguments.
+multiclass AVX512_maskable_custom<bits<8> O, Format F,
+ dag Outs,
+ dag Ins, dag MaskingIns, dag ZeroMaskingIns,
+ string OpcodeStr,
+ string AttSrcAsm, string IntelSrcAsm,
+ list<dag> Pattern,
+ list<dag> MaskingPattern,
+ list<dag> ZeroMaskingPattern,
+ string MaskingConstraint = "",
+ InstrItinClass itin = NoItinerary,
+ bit IsCommutable = 0> {
+ let isCommutable = IsCommutable in
+ def NAME: AVX512<O, F, Outs, Ins,
+ OpcodeStr#"\t{"#AttSrcAsm#", $dst|"#
+ "$dst, "#IntelSrcAsm#"}",
+ Pattern, itin>;