1//===-- VEInstrFormats.td - VE Instruction Formats ---------*- tablegen -*-===// 2// 3// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4// See https://llvm.org/LICENSE.txt for license information. 5// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6// 7//===----------------------------------------------------------------------===// 8 9// SX-Aurora uses little endian, but instructions are encoded little bit 10// different manner. Therefore, we need to tranlate the address of each 11// bitfield described in ISA documentation like below. 12// 13// ISA | InstrFormats.td 14// --------------------------- 15// 0-7 => 63-56 16// 8 => 55 17// 32-63 => 31-0 18 19//===----------------------------------------------------------------------===// 20// Instruction Format 21//===----------------------------------------------------------------------===// 22 23class InstVE<dag outs, dag ins, string asmstr, list<dag> pattern> 24 : Instruction { 25 field bits<64> Inst; 26 27 let Namespace = "VE"; 28 let Size = 8; 29 30 bits<8> op; 31 let Inst{63-56} = op; 32 33 dag OutOperandList = outs; 34 dag InOperandList = ins; 35 let AsmString = asmstr; 36 let Pattern = pattern; 37 38 bits<1> VE_Vector = 0; 39 bits<1> VE_VLInUse = 0; 40 bits<3> VE_VLIndex = 0; 41 bits<1> VE_VLWithMask = 0; 42 43 /// These fields correspond to the fields in VEInstrInfo.h. Any changes to 44 /// these must be reflected there! See comments there for what these are. 45 /// 46 /// VLIndex is the index of VL register in MI's operands. The HW instruction 47 /// doesn't have that field, but we add is in MI for the ease of optimization. 48 /// For example, the index of VL of (VST $sy, $sz, $sx, $vl) is 3 (beginning 49 /// from 0), and the index of VL of (VST $sy, $sz, $sx, $vm, $vl) is 4. We 50 /// define vector instructions hierarchically, so use VE_VLIndex which is 51 /// defined by the type of instruction and VE_VLWithMask which is defined 52 /// whether the insturction use mask or not. 53 let TSFlags{0} = VE_Vector; 54 let TSFlags{1} = VE_VLInUse; 55 let TSFlags{4-2} = !add(VE_VLIndex, VE_VLWithMask); 56 57 let DecoderNamespace = "VE"; 58 field bits<64> SoftFail = 0; 59} 60 61//----------------------------------------------------------------------------- 62// Section 5.1 RM Type 63// 64// RM type has sx, sy, sz, and imm32. 65// The effective address is generated by sz + sy + imm32. 66//----------------------------------------------------------------------------- 67 68class RM<bits<8>opVal, dag outs, dag ins, string asmstr, list<dag> pattern = []> 69 : InstVE<outs, ins, asmstr, pattern> { 70 bits<1> cx = 0; 71 bits<7> sx; 72 bits<1> cy = 1; 73 bits<7> sz; // defines sz prior to sy to assign from sz 74 bits<7> sy; 75 bits<1> cz = 1; 76 bits<32> imm32; 77 let op = opVal; 78 let Inst{55} = cx; 79 let Inst{54-48} = sx; 80 let Inst{47} = cy; 81 let Inst{46-40} = sy; 82 let Inst{39} = cz; 83 let Inst{38-32} = sz; 84 let Inst{31-0} = imm32; 85} 86 87//----------------------------------------------------------------------------- 88// Section 5.2 RRM Type 89// 90// RRM type is identical to RM, but the effective address is generated 91// by sz + imm32. The sy field is used by other purposes. 92//----------------------------------------------------------------------------- 93 94class RRM<bits<8>opVal, dag outs, dag ins, string asmstr, 95 list<dag> pattern = []> 96 : RM<opVal, outs, ins, asmstr, pattern>; 97 98// RRMHM type is to load/store host memory 99// It is similar to RRM and not use sy. 100class RRMHM<bits<8>opVal, dag outs, dag ins, string asmstr, 101 list<dag> pattern = []> 102 : RRM<opVal, outs, ins, asmstr, pattern> { 103 bits<2> ry = 0; 104 let cy = 0; 105 let sy{6-2} = 0; 106 let sy{1-0} = ry; 107} 108 109//----------------------------------------------------------------------------- 110// Section 5.3 CF Type 111// 112// CF type is used for control flow. 113//----------------------------------------------------------------------------- 114 115class CF<bits<8>opVal, dag outs, dag ins, string asmstr, list<dag> pattern = []> 116 : InstVE<outs, ins, asmstr, pattern> { 117 bits<1> cx = 0; 118 bits<1> cx2 = 0; 119 bits<2> bpf = 0; 120 bits<4> cond; 121 bits<1> cy = 1; 122 bits<7> sy; 123 bits<1> cz = 1; 124 bits<7> sz; 125 bits<32> imm32; 126 let op = opVal; 127 let Inst{55} = cx; 128 let Inst{54} = cx2; 129 let Inst{53-52} = bpf; 130 let Inst{51-48} = cond; 131 let Inst{47} = cy; 132 let Inst{46-40} = sy; 133 let Inst{39} = cz; 134 let Inst{38-32} = sz; 135 let Inst{31-0} = imm32; 136} 137 138//----------------------------------------------------------------------------- 139// Section 5.4 RR Type 140// 141// RR type is for generic arithmetic instructions. 142//----------------------------------------------------------------------------- 143 144class RR<bits<8>opVal, dag outs, dag ins, string asmstr, list<dag> pattern = []> 145 : InstVE<outs, ins, asmstr, pattern> { 146 bits<1> cx = 0; 147 bits<7> sx; 148 bits<1> cy = 1; 149 bits<7> sy; 150 bits<1> cz = 1; 151 bits<7> sz; // m field places at the top sz field 152 bits<8> vx = 0; 153 bits<8> vz = 0; 154 bits<1> cw = 0; 155 bits<1> cw2 = 0; 156 bits<4> cfw = 0; 157 let op = opVal; 158 let Inst{55} = cx; 159 let Inst{54-48} = sx; 160 let Inst{47} = cy; 161 let Inst{46-40} = sy; 162 let Inst{39} = cz; 163 let Inst{38-32} = sz; 164 let Inst{31-24} = vx; 165 let Inst{23-16} = 0; 166 let Inst{15-8} = vz; 167 let Inst{7} = cw; 168 let Inst{6} = cw2; 169 let Inst{5-4} = 0; 170 let Inst{3-0} = cfw; 171} 172 173// RRFENCE type is special RR type for a FENCE instruction. 174class RRFENCE<bits<8>opVal, dag outs, dag ins, string asmstr, 175 list<dag> pattern = []> 176 : InstVE<outs, ins, asmstr, pattern> { 177 bits<1> avo = 0; 178 bits<1> lf = 0; 179 bits<1> sf = 0; 180 bits<1> c2 = 0; 181 bits<1> c1 = 0; 182 bits<1> c0 = 0; 183 let op = opVal; 184 let Inst{55} = avo; 185 let Inst{54-50} = 0; 186 let Inst{49} = lf; 187 let Inst{48} = sf; 188 let Inst{47-43} = 0; 189 let Inst{42} = c2; 190 let Inst{41} = c1; 191 let Inst{40} = c0; 192 let Inst{39-0} = 0; 193} 194 195//----------------------------------------------------------------------------- 196// Section 5.5 RW Type 197//----------------------------------------------------------------------------- 198 199//----------------------------------------------------------------------------- 200// Section 5.6 RVM Type 201// 202// RVM type is for vector transfer instructions. 203//----------------------------------------------------------------------------- 204 205class RVM<bits<8>opVal, dag outs, dag ins, string asmstr, 206 list<dag> pattern = []> 207 : InstVE<outs, ins, asmstr, pattern> { 208 bits<1> cx = 0; 209 bits<1> vc = 0; 210 bits<1> cs = 0; 211 bits<4> m = 0; 212 bits<1> cy = 1; 213 bits<7> sy; 214 bits<1> cz = 1; 215 bits<7> sz; 216 bits<8> vx; 217 bits<8> vy = 0; 218 bits<7> sw = 0; 219 let op = opVal; 220 let Inst{55} = cx; 221 let Inst{54} = vc; 222 let Inst{53} = cs; 223 let Inst{52} = 0; 224 let Inst{51-48} = m; 225 let Inst{47} = cy; 226 let Inst{46-40} = sy; 227 let Inst{39} = cz; 228 let Inst{38-32} = sz; 229 let Inst{31-24} = vx; 230 let Inst{23-16} = vy; 231 let Inst{15-8} = 0; 232 let Inst{7} = 0; 233 let Inst{6-0} = sw; 234 235 let VE_Vector = 1; 236} 237 238//----------------------------------------------------------------------------- 239// Section 5.7 RV Type 240// 241// RV type is for vector instructions. 242//----------------------------------------------------------------------------- 243 244class RV<bits<8>opVal, dag outs, dag ins, string asmstr, list<dag> pattern = []> 245 : InstVE<outs, ins, asmstr, pattern> { 246 bits<1> cx = 0; 247 bits<1> cx2 = 0; 248 bits<1> cs = 0; 249 bits<1> cs2 = 0; 250 bits<4> m = 0; 251 bits<1> cy = 1; 252 bits<7> sy; 253 bits<1> cz = 0; 254 bits<7> sz = 0; 255 bits<8> vx = 0; 256 bits<8> vy = 0; 257 bits<8> vz = 0; 258 bits<8> vw = 0; 259 let op = opVal; 260 let Inst{55} = cx; 261 let Inst{54} = cx2; 262 let Inst{53} = cs; 263 let Inst{52} = cs2; 264 let Inst{51-48} = m; 265 let Inst{47} = cy; 266 let Inst{46-40} = sy; 267 let Inst{39} = cz; 268 let Inst{38-32} = sz; 269 let Inst{31-24} = vx; 270 let Inst{23-16} = vy; 271 let Inst{15-8} = vz; 272 let Inst{7-0} = vw; 273 274 let VE_Vector = 1; 275} 276 277// Pseudo instructions. 278class Pseudo<dag outs, dag ins, string asmstr, list<dag> pattern = []> 279 : InstVE<outs, ins, asmstr, pattern> { 280 let isCodeGenOnly = 1; 281 let isPseudo = 1; 282} 283