1fa3d789dSPierre van Houtryve //===- CodeGenDAGPatterns.cpp - Read DAG patterns from .td file -----------===// 2fa3d789dSPierre van Houtryve // 3fa3d789dSPierre van Houtryve // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4fa3d789dSPierre van Houtryve // See https://llvm.org/LICENSE.txt for license information. 5fa3d789dSPierre van Houtryve // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6fa3d789dSPierre van Houtryve // 7fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 8fa3d789dSPierre van Houtryve // 9fa3d789dSPierre van Houtryve // This file implements the CodeGenDAGPatterns class, which is used to read and 10fa3d789dSPierre van Houtryve // represent the patterns present in a .td file for instructions. 11fa3d789dSPierre van Houtryve // 12fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 13fa3d789dSPierre van Houtryve 14fa3d789dSPierre van Houtryve #include "CodeGenDAGPatterns.h" 15fa3d789dSPierre van Houtryve #include "CodeGenInstruction.h" 16fa3d789dSPierre van Houtryve #include "CodeGenRegisters.h" 17fa3d789dSPierre van Houtryve #include "llvm/ADT/DenseSet.h" 18fa3d789dSPierre van Houtryve #include "llvm/ADT/MapVector.h" 19fa3d789dSPierre van Houtryve #include "llvm/ADT/STLExtras.h" 20fa3d789dSPierre van Houtryve #include "llvm/ADT/SmallSet.h" 21fa3d789dSPierre van Houtryve #include "llvm/ADT/SmallString.h" 22fa3d789dSPierre van Houtryve #include "llvm/ADT/StringExtras.h" 23fa3d789dSPierre van Houtryve #include "llvm/ADT/StringMap.h" 24fa3d789dSPierre van Houtryve #include "llvm/ADT/Twine.h" 25fa3d789dSPierre van Houtryve #include "llvm/Support/Debug.h" 26fa3d789dSPierre van Houtryve #include "llvm/Support/ErrorHandling.h" 27fa3d789dSPierre van Houtryve #include "llvm/Support/TypeSize.h" 28fa3d789dSPierre van Houtryve #include "llvm/TableGen/Error.h" 29fa3d789dSPierre van Houtryve #include "llvm/TableGen/Record.h" 30fa3d789dSPierre van Houtryve #include <algorithm> 31fa3d789dSPierre van Houtryve #include <cstdio> 32fa3d789dSPierre van Houtryve #include <iterator> 33fa3d789dSPierre van Houtryve #include <set> 34fa3d789dSPierre van Houtryve using namespace llvm; 35fa3d789dSPierre van Houtryve 36fa3d789dSPierre van Houtryve #define DEBUG_TYPE "dag-patterns" 37fa3d789dSPierre van Houtryve 38fa3d789dSPierre van Houtryve static inline bool isIntegerOrPtr(MVT VT) { 39fa3d789dSPierre van Houtryve return VT.isInteger() || VT == MVT::iPTR; 40fa3d789dSPierre van Houtryve } 41fa3d789dSPierre van Houtryve static inline bool isFloatingPoint(MVT VT) { return VT.isFloatingPoint(); } 42fa3d789dSPierre van Houtryve static inline bool isVector(MVT VT) { return VT.isVector(); } 43fa3d789dSPierre van Houtryve static inline bool isScalar(MVT VT) { return !VT.isVector(); } 44fa3d789dSPierre van Houtryve 45fa3d789dSPierre van Houtryve template <typename Predicate> 46fa3d789dSPierre van Houtryve static bool berase_if(MachineValueTypeSet &S, Predicate P) { 47fa3d789dSPierre van Houtryve bool Erased = false; 48fa3d789dSPierre van Houtryve // It is ok to iterate over MachineValueTypeSet and remove elements from it 49fa3d789dSPierre van Houtryve // at the same time. 50fa3d789dSPierre van Houtryve for (MVT T : S) { 51fa3d789dSPierre van Houtryve if (!P(T)) 52fa3d789dSPierre van Houtryve continue; 53fa3d789dSPierre van Houtryve Erased = true; 54fa3d789dSPierre van Houtryve S.erase(T); 55fa3d789dSPierre van Houtryve } 56fa3d789dSPierre van Houtryve return Erased; 57fa3d789dSPierre van Houtryve } 58fa3d789dSPierre van Houtryve 59fa3d789dSPierre van Houtryve void MachineValueTypeSet::writeToStream(raw_ostream &OS) const { 60fa3d789dSPierre van Houtryve SmallVector<MVT, 4> Types(begin(), end()); 61fa3d789dSPierre van Houtryve array_pod_sort(Types.begin(), Types.end()); 62fa3d789dSPierre van Houtryve 63fa3d789dSPierre van Houtryve OS << '['; 64fa3d789dSPierre van Houtryve ListSeparator LS(" "); 65fa3d789dSPierre van Houtryve for (const MVT &T : Types) 66fa3d789dSPierre van Houtryve OS << LS << ValueTypeByHwMode::getMVTName(T); 67fa3d789dSPierre van Houtryve OS << ']'; 68fa3d789dSPierre van Houtryve } 69fa3d789dSPierre van Houtryve 70fa3d789dSPierre van Houtryve // --- TypeSetByHwMode 71fa3d789dSPierre van Houtryve 72fa3d789dSPierre van Houtryve // This is a parameterized type-set class. For each mode there is a list 73fa3d789dSPierre van Houtryve // of types that are currently possible for a given tree node. Type 74fa3d789dSPierre van Houtryve // inference will apply to each mode separately. 75fa3d789dSPierre van Houtryve 76fa3d789dSPierre van Houtryve TypeSetByHwMode::TypeSetByHwMode(ArrayRef<ValueTypeByHwMode> VTList) { 77fa3d789dSPierre van Houtryve // Take the address space from the first type in the list. 78fa3d789dSPierre van Houtryve if (!VTList.empty()) 79fa3d789dSPierre van Houtryve AddrSpace = VTList[0].PtrAddrSpace; 80fa3d789dSPierre van Houtryve 81fa3d789dSPierre van Houtryve for (const ValueTypeByHwMode &VVT : VTList) 82fa3d789dSPierre van Houtryve insert(VVT); 83fa3d789dSPierre van Houtryve } 84fa3d789dSPierre van Houtryve 85fa3d789dSPierre van Houtryve bool TypeSetByHwMode::isValueTypeByHwMode(bool AllowEmpty) const { 86fa3d789dSPierre van Houtryve for (const auto &I : *this) { 87fa3d789dSPierre van Houtryve if (I.second.size() > 1) 88fa3d789dSPierre van Houtryve return false; 89fa3d789dSPierre van Houtryve if (!AllowEmpty && I.second.empty()) 90fa3d789dSPierre van Houtryve return false; 91fa3d789dSPierre van Houtryve } 92fa3d789dSPierre van Houtryve return true; 93fa3d789dSPierre van Houtryve } 94fa3d789dSPierre van Houtryve 95fa3d789dSPierre van Houtryve ValueTypeByHwMode TypeSetByHwMode::getValueTypeByHwMode() const { 96fa3d789dSPierre van Houtryve assert(isValueTypeByHwMode(true) && 97fa3d789dSPierre van Houtryve "The type set has multiple types for at least one HW mode"); 98fa3d789dSPierre van Houtryve ValueTypeByHwMode VVT; 99fa3d789dSPierre van Houtryve VVT.PtrAddrSpace = AddrSpace; 100fa3d789dSPierre van Houtryve 101fa3d789dSPierre van Houtryve for (const auto &I : *this) { 102fa3d789dSPierre van Houtryve MVT T = I.second.empty() ? MVT::Other : *I.second.begin(); 103fa3d789dSPierre van Houtryve VVT.getOrCreateTypeForMode(I.first, T); 104fa3d789dSPierre van Houtryve } 105fa3d789dSPierre van Houtryve return VVT; 106fa3d789dSPierre van Houtryve } 107fa3d789dSPierre van Houtryve 108fa3d789dSPierre van Houtryve bool TypeSetByHwMode::isPossible() const { 109fa3d789dSPierre van Houtryve for (const auto &I : *this) 110fa3d789dSPierre van Houtryve if (!I.second.empty()) 111fa3d789dSPierre van Houtryve return true; 112fa3d789dSPierre van Houtryve return false; 113fa3d789dSPierre van Houtryve } 114fa3d789dSPierre van Houtryve 115fa3d789dSPierre van Houtryve bool TypeSetByHwMode::insert(const ValueTypeByHwMode &VVT) { 116fa3d789dSPierre van Houtryve bool Changed = false; 117fa3d789dSPierre van Houtryve bool ContainsDefault = false; 118fa3d789dSPierre van Houtryve MVT DT = MVT::Other; 119fa3d789dSPierre van Houtryve 120fa3d789dSPierre van Houtryve for (const auto &P : VVT) { 121fa3d789dSPierre van Houtryve unsigned M = P.first; 122fa3d789dSPierre van Houtryve // Make sure there exists a set for each specific mode from VVT. 123fa3d789dSPierre van Houtryve Changed |= getOrCreate(M).insert(P.second).second; 124fa3d789dSPierre van Houtryve // Cache VVT's default mode. 125fa3d789dSPierre van Houtryve if (DefaultMode == M) { 126fa3d789dSPierre van Houtryve ContainsDefault = true; 127fa3d789dSPierre van Houtryve DT = P.second; 128fa3d789dSPierre van Houtryve } 129fa3d789dSPierre van Houtryve } 130fa3d789dSPierre van Houtryve 131fa3d789dSPierre van Houtryve // If VVT has a default mode, add the corresponding type to all 132fa3d789dSPierre van Houtryve // modes in "this" that do not exist in VVT. 133fa3d789dSPierre van Houtryve if (ContainsDefault) 134fa3d789dSPierre van Houtryve for (auto &I : *this) 135fa3d789dSPierre van Houtryve if (!VVT.hasMode(I.first)) 136fa3d789dSPierre van Houtryve Changed |= I.second.insert(DT).second; 137fa3d789dSPierre van Houtryve 138fa3d789dSPierre van Houtryve return Changed; 139fa3d789dSPierre van Houtryve } 140fa3d789dSPierre van Houtryve 141fa3d789dSPierre van Houtryve // Constrain the type set to be the intersection with VTS. 142fa3d789dSPierre van Houtryve bool TypeSetByHwMode::constrain(const TypeSetByHwMode &VTS) { 143fa3d789dSPierre van Houtryve bool Changed = false; 144fa3d789dSPierre van Houtryve if (hasDefault()) { 145fa3d789dSPierre van Houtryve for (const auto &I : VTS) { 146fa3d789dSPierre van Houtryve unsigned M = I.first; 147fa3d789dSPierre van Houtryve if (M == DefaultMode || hasMode(M)) 148fa3d789dSPierre van Houtryve continue; 149fa3d789dSPierre van Houtryve Map.insert({M, Map.at(DefaultMode)}); 150fa3d789dSPierre van Houtryve Changed = true; 151fa3d789dSPierre van Houtryve } 152fa3d789dSPierre van Houtryve } 153fa3d789dSPierre van Houtryve 154fa3d789dSPierre van Houtryve for (auto &I : *this) { 155fa3d789dSPierre van Houtryve unsigned M = I.first; 156fa3d789dSPierre van Houtryve SetType &S = I.second; 157fa3d789dSPierre van Houtryve if (VTS.hasMode(M) || VTS.hasDefault()) { 158fa3d789dSPierre van Houtryve Changed |= intersect(I.second, VTS.get(M)); 159fa3d789dSPierre van Houtryve } else if (!S.empty()) { 160fa3d789dSPierre van Houtryve S.clear(); 161fa3d789dSPierre van Houtryve Changed = true; 162fa3d789dSPierre van Houtryve } 163fa3d789dSPierre van Houtryve } 164fa3d789dSPierre van Houtryve return Changed; 165fa3d789dSPierre van Houtryve } 166fa3d789dSPierre van Houtryve 167fa3d789dSPierre van Houtryve template <typename Predicate> bool TypeSetByHwMode::constrain(Predicate P) { 168fa3d789dSPierre van Houtryve bool Changed = false; 169fa3d789dSPierre van Houtryve for (auto &I : *this) 170fa3d789dSPierre van Houtryve Changed |= berase_if(I.second, [&P](MVT VT) { return !P(VT); }); 171fa3d789dSPierre van Houtryve return Changed; 172fa3d789dSPierre van Houtryve } 173fa3d789dSPierre van Houtryve 174fa3d789dSPierre van Houtryve template <typename Predicate> 175fa3d789dSPierre van Houtryve bool TypeSetByHwMode::assign_if(const TypeSetByHwMode &VTS, Predicate P) { 176fa3d789dSPierre van Houtryve assert(empty()); 177fa3d789dSPierre van Houtryve for (const auto &I : VTS) { 178fa3d789dSPierre van Houtryve SetType &S = getOrCreate(I.first); 179fa3d789dSPierre van Houtryve for (auto J : I.second) 180fa3d789dSPierre van Houtryve if (P(J)) 181fa3d789dSPierre van Houtryve S.insert(J); 182fa3d789dSPierre van Houtryve } 183fa3d789dSPierre van Houtryve return !empty(); 184fa3d789dSPierre van Houtryve } 185fa3d789dSPierre van Houtryve 186fa3d789dSPierre van Houtryve void TypeSetByHwMode::writeToStream(raw_ostream &OS) const { 187fa3d789dSPierre van Houtryve SmallVector<unsigned, 4> Modes; 188fa3d789dSPierre van Houtryve Modes.reserve(Map.size()); 189fa3d789dSPierre van Houtryve 190fa3d789dSPierre van Houtryve for (const auto &I : *this) 191fa3d789dSPierre van Houtryve Modes.push_back(I.first); 192fa3d789dSPierre van Houtryve if (Modes.empty()) { 193fa3d789dSPierre van Houtryve OS << "{}"; 194fa3d789dSPierre van Houtryve return; 195fa3d789dSPierre van Houtryve } 196fa3d789dSPierre van Houtryve array_pod_sort(Modes.begin(), Modes.end()); 197fa3d789dSPierre van Houtryve 198fa3d789dSPierre van Houtryve OS << '{'; 199fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 200fa3d789dSPierre van Houtryve OS << ' ' << getModeName(M) << ':'; 201fa3d789dSPierre van Houtryve get(M).writeToStream(OS); 202fa3d789dSPierre van Houtryve } 203fa3d789dSPierre van Houtryve OS << " }"; 204fa3d789dSPierre van Houtryve } 205fa3d789dSPierre van Houtryve 206fa3d789dSPierre van Houtryve bool TypeSetByHwMode::operator==(const TypeSetByHwMode &VTS) const { 207fa3d789dSPierre van Houtryve // The isSimple call is much quicker than hasDefault - check this first. 208fa3d789dSPierre van Houtryve bool IsSimple = isSimple(); 209fa3d789dSPierre van Houtryve bool VTSIsSimple = VTS.isSimple(); 210fa3d789dSPierre van Houtryve if (IsSimple && VTSIsSimple) 211fa3d789dSPierre van Houtryve return getSimple() == VTS.getSimple(); 212fa3d789dSPierre van Houtryve 213fa3d789dSPierre van Houtryve // Speedup: We have a default if the set is simple. 214fa3d789dSPierre van Houtryve bool HaveDefault = IsSimple || hasDefault(); 215fa3d789dSPierre van Houtryve bool VTSHaveDefault = VTSIsSimple || VTS.hasDefault(); 216fa3d789dSPierre van Houtryve if (HaveDefault != VTSHaveDefault) 217fa3d789dSPierre van Houtryve return false; 218fa3d789dSPierre van Houtryve 219fa3d789dSPierre van Houtryve SmallSet<unsigned, 4> Modes; 220fa3d789dSPierre van Houtryve for (auto &I : *this) 221fa3d789dSPierre van Houtryve Modes.insert(I.first); 222fa3d789dSPierre van Houtryve for (const auto &I : VTS) 223fa3d789dSPierre van Houtryve Modes.insert(I.first); 224fa3d789dSPierre van Houtryve 225fa3d789dSPierre van Houtryve if (HaveDefault) { 226fa3d789dSPierre van Houtryve // Both sets have default mode. 227fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 228fa3d789dSPierre van Houtryve if (get(M) != VTS.get(M)) 229fa3d789dSPierre van Houtryve return false; 230fa3d789dSPierre van Houtryve } 231fa3d789dSPierre van Houtryve } else { 232fa3d789dSPierre van Houtryve // Neither set has default mode. 233fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 234fa3d789dSPierre van Houtryve // If there is no default mode, an empty set is equivalent to not having 235fa3d789dSPierre van Houtryve // the corresponding mode. 236fa3d789dSPierre van Houtryve bool NoModeThis = !hasMode(M) || get(M).empty(); 237fa3d789dSPierre van Houtryve bool NoModeVTS = !VTS.hasMode(M) || VTS.get(M).empty(); 238fa3d789dSPierre van Houtryve if (NoModeThis != NoModeVTS) 239fa3d789dSPierre van Houtryve return false; 240fa3d789dSPierre van Houtryve if (!NoModeThis) 241fa3d789dSPierre van Houtryve if (get(M) != VTS.get(M)) 242fa3d789dSPierre van Houtryve return false; 243fa3d789dSPierre van Houtryve } 244fa3d789dSPierre van Houtryve } 245fa3d789dSPierre van Houtryve 246fa3d789dSPierre van Houtryve return true; 247fa3d789dSPierre van Houtryve } 248fa3d789dSPierre van Houtryve 249fa3d789dSPierre van Houtryve namespace llvm { 250fa3d789dSPierre van Houtryve raw_ostream &operator<<(raw_ostream &OS, const MachineValueTypeSet &T) { 251fa3d789dSPierre van Houtryve T.writeToStream(OS); 252fa3d789dSPierre van Houtryve return OS; 253fa3d789dSPierre van Houtryve } 254fa3d789dSPierre van Houtryve raw_ostream &operator<<(raw_ostream &OS, const TypeSetByHwMode &T) { 255fa3d789dSPierre van Houtryve T.writeToStream(OS); 256fa3d789dSPierre van Houtryve return OS; 257fa3d789dSPierre van Houtryve } 258fa3d789dSPierre van Houtryve } // namespace llvm 259fa3d789dSPierre van Houtryve 260fa3d789dSPierre van Houtryve LLVM_DUMP_METHOD 261fa3d789dSPierre van Houtryve void TypeSetByHwMode::dump() const { dbgs() << *this << '\n'; } 262fa3d789dSPierre van Houtryve 263fa3d789dSPierre van Houtryve bool TypeSetByHwMode::intersect(SetType &Out, const SetType &In) { 264fa3d789dSPierre van Houtryve auto IntersectP = [&](std::optional<MVT> WildVT, function_ref<bool(MVT)> P) { 265fa3d789dSPierre van Houtryve // Complement of In within this partition. 266fa3d789dSPierre van Houtryve auto CompIn = [&](MVT T) -> bool { return !In.count(T) && P(T); }; 267fa3d789dSPierre van Houtryve 268fa3d789dSPierre van Houtryve if (!WildVT) 269fa3d789dSPierre van Houtryve return berase_if(Out, CompIn); 270fa3d789dSPierre van Houtryve 271fa3d789dSPierre van Houtryve bool OutW = Out.count(*WildVT), InW = In.count(*WildVT); 272fa3d789dSPierre van Houtryve if (OutW == InW) 273fa3d789dSPierre van Houtryve return berase_if(Out, CompIn); 274fa3d789dSPierre van Houtryve 275fa3d789dSPierre van Houtryve // Compute the intersection of scalars separately to account for only one 276fa3d789dSPierre van Houtryve // set containing WildVT. 277fa3d789dSPierre van Houtryve // The intersection of WildVT with a set of corresponding types that does 278fa3d789dSPierre van Houtryve // not include WildVT will result in the most specific type: 279fa3d789dSPierre van Houtryve // - WildVT is more specific than any set with two elements or more 280fa3d789dSPierre van Houtryve // - WildVT is less specific than any single type. 281fa3d789dSPierre van Houtryve // For example, for iPTR and scalar integer types 282fa3d789dSPierre van Houtryve // { iPTR } * { i32 } -> { i32 } 283fa3d789dSPierre van Houtryve // { iPTR } * { i32 i64 } -> { iPTR } 284fa3d789dSPierre van Houtryve // and 285fa3d789dSPierre van Houtryve // { iPTR i32 } * { i32 } -> { i32 } 286fa3d789dSPierre van Houtryve // { iPTR i32 } * { i32 i64 } -> { i32 i64 } 287fa3d789dSPierre van Houtryve // { iPTR i32 } * { i32 i64 i128 } -> { iPTR i32 } 288fa3d789dSPierre van Houtryve 289fa3d789dSPierre van Houtryve // Looking at just this partition, let In' = elements only in In, 290fa3d789dSPierre van Houtryve // Out' = elements only in Out, and IO = elements common to both. Normally 291fa3d789dSPierre van Houtryve // IO would be returned as the result of the intersection, but we need to 292fa3d789dSPierre van Houtryve // account for WildVT being a "wildcard" of sorts. Since elements in IO are 293fa3d789dSPierre van Houtryve // those that match both sets exactly, they will all belong to the output. 294fa3d789dSPierre van Houtryve // If any of the "leftovers" (i.e. In' or Out') contain WildVT, it means 295fa3d789dSPierre van Houtryve // that the other set doesn't have it, but it could have (1) a more 296fa3d789dSPierre van Houtryve // specific type, or (2) a set of types that is less specific. The 297fa3d789dSPierre van Houtryve // "leftovers" from the other set is what we want to examine more closely. 298fa3d789dSPierre van Houtryve 299fa3d789dSPierre van Houtryve auto Leftovers = [&](const SetType &A, const SetType &B) { 300fa3d789dSPierre van Houtryve SetType Diff = A; 301fa3d789dSPierre van Houtryve berase_if(Diff, [&](MVT T) { return B.count(T) || !P(T); }); 302fa3d789dSPierre van Houtryve return Diff; 303fa3d789dSPierre van Houtryve }; 304fa3d789dSPierre van Houtryve 305fa3d789dSPierre van Houtryve if (InW) { 306fa3d789dSPierre van Houtryve SetType OutLeftovers = Leftovers(Out, In); 307fa3d789dSPierre van Houtryve if (OutLeftovers.size() < 2) { 308fa3d789dSPierre van Houtryve // WildVT not added to Out. Keep the possible single leftover. 309fa3d789dSPierre van Houtryve return false; 310fa3d789dSPierre van Houtryve } 311fa3d789dSPierre van Houtryve // WildVT replaces the leftovers. 312fa3d789dSPierre van Houtryve berase_if(Out, CompIn); 313fa3d789dSPierre van Houtryve Out.insert(*WildVT); 314fa3d789dSPierre van Houtryve return true; 315fa3d789dSPierre van Houtryve } 316fa3d789dSPierre van Houtryve 317fa3d789dSPierre van Houtryve // OutW == true 318fa3d789dSPierre van Houtryve SetType InLeftovers = Leftovers(In, Out); 319fa3d789dSPierre van Houtryve unsigned SizeOut = Out.size(); 320fa3d789dSPierre van Houtryve berase_if(Out, CompIn); // This will remove at least the WildVT. 321fa3d789dSPierre van Houtryve if (InLeftovers.size() < 2) { 322fa3d789dSPierre van Houtryve // WildVT deleted from Out. Add back the possible single leftover. 323fa3d789dSPierre van Houtryve Out.insert(InLeftovers); 324fa3d789dSPierre van Houtryve return true; 325fa3d789dSPierre van Houtryve } 326fa3d789dSPierre van Houtryve 327fa3d789dSPierre van Houtryve // Keep the WildVT in Out. 328fa3d789dSPierre van Houtryve Out.insert(*WildVT); 329fa3d789dSPierre van Houtryve // If WildVT was the only element initially removed from Out, then Out 330fa3d789dSPierre van Houtryve // has not changed. 331fa3d789dSPierre van Houtryve return SizeOut != Out.size(); 332fa3d789dSPierre van Houtryve }; 333fa3d789dSPierre van Houtryve 334fa3d789dSPierre van Houtryve // Note: must be non-overlapping 335fa3d789dSPierre van Houtryve using WildPartT = std::pair<MVT, std::function<bool(MVT)>>; 336fa3d789dSPierre van Houtryve static const WildPartT WildParts[] = { 337fa3d789dSPierre van Houtryve {MVT::iPTR, [](MVT T) { return T.isScalarInteger() || T == MVT::iPTR; }}, 338fa3d789dSPierre van Houtryve }; 339fa3d789dSPierre van Houtryve 340fa3d789dSPierre van Houtryve bool Changed = false; 341fa3d789dSPierre van Houtryve for (const auto &I : WildParts) 342fa3d789dSPierre van Houtryve Changed |= IntersectP(I.first, I.second); 343fa3d789dSPierre van Houtryve 344fa3d789dSPierre van Houtryve Changed |= IntersectP(std::nullopt, [&](MVT T) { 345fa3d789dSPierre van Houtryve return !any_of(WildParts, [=](const WildPartT &I) { return I.second(T); }); 346fa3d789dSPierre van Houtryve }); 347fa3d789dSPierre van Houtryve 348fa3d789dSPierre van Houtryve return Changed; 349fa3d789dSPierre van Houtryve } 350fa3d789dSPierre van Houtryve 351fa3d789dSPierre van Houtryve bool TypeSetByHwMode::validate() const { 352fa3d789dSPierre van Houtryve if (empty()) 353fa3d789dSPierre van Houtryve return true; 354fa3d789dSPierre van Houtryve bool AllEmpty = true; 355fa3d789dSPierre van Houtryve for (const auto &I : *this) 356fa3d789dSPierre van Houtryve AllEmpty &= I.second.empty(); 357fa3d789dSPierre van Houtryve return !AllEmpty; 358fa3d789dSPierre van Houtryve } 359fa3d789dSPierre van Houtryve 360fa3d789dSPierre van Houtryve // --- TypeInfer 361fa3d789dSPierre van Houtryve 362fa3d789dSPierre van Houtryve bool TypeInfer::MergeInTypeInfo(TypeSetByHwMode &Out, 363fa3d789dSPierre van Houtryve const TypeSetByHwMode &In) const { 364fa3d789dSPierre van Houtryve ValidateOnExit _1(Out, *this); 365fa3d789dSPierre van Houtryve In.validate(); 366fa3d789dSPierre van Houtryve if (In.empty() || Out == In || TP.hasError()) 367fa3d789dSPierre van Houtryve return false; 368fa3d789dSPierre van Houtryve if (Out.empty()) { 369fa3d789dSPierre van Houtryve Out = In; 370fa3d789dSPierre van Houtryve return true; 371fa3d789dSPierre van Houtryve } 372fa3d789dSPierre van Houtryve 373fa3d789dSPierre van Houtryve bool Changed = Out.constrain(In); 374fa3d789dSPierre van Houtryve if (Changed && Out.empty()) 375fa3d789dSPierre van Houtryve TP.error("Type contradiction"); 376fa3d789dSPierre van Houtryve 377fa3d789dSPierre van Houtryve return Changed; 378fa3d789dSPierre van Houtryve } 379fa3d789dSPierre van Houtryve 380fa3d789dSPierre van Houtryve bool TypeInfer::forceArbitrary(TypeSetByHwMode &Out) { 381fa3d789dSPierre van Houtryve ValidateOnExit _1(Out, *this); 382fa3d789dSPierre van Houtryve if (TP.hasError()) 383fa3d789dSPierre van Houtryve return false; 384fa3d789dSPierre van Houtryve assert(!Out.empty() && "cannot pick from an empty set"); 385fa3d789dSPierre van Houtryve 386fa3d789dSPierre van Houtryve bool Changed = false; 387fa3d789dSPierre van Houtryve for (auto &I : Out) { 388fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &S = I.second; 389fa3d789dSPierre van Houtryve if (S.size() <= 1) 390fa3d789dSPierre van Houtryve continue; 391fa3d789dSPierre van Houtryve MVT T = *S.begin(); // Pick the first element. 392fa3d789dSPierre van Houtryve S.clear(); 393fa3d789dSPierre van Houtryve S.insert(T); 394fa3d789dSPierre van Houtryve Changed = true; 395fa3d789dSPierre van Houtryve } 396fa3d789dSPierre van Houtryve return Changed; 397fa3d789dSPierre van Houtryve } 398fa3d789dSPierre van Houtryve 399fa3d789dSPierre van Houtryve bool TypeInfer::EnforceInteger(TypeSetByHwMode &Out) { 400fa3d789dSPierre van Houtryve ValidateOnExit _1(Out, *this); 401fa3d789dSPierre van Houtryve if (TP.hasError()) 402fa3d789dSPierre van Houtryve return false; 403fa3d789dSPierre van Houtryve if (!Out.empty()) 404fa3d789dSPierre van Houtryve return Out.constrain(isIntegerOrPtr); 405fa3d789dSPierre van Houtryve 406fa3d789dSPierre van Houtryve return Out.assign_if(getLegalTypes(), isIntegerOrPtr); 407fa3d789dSPierre van Houtryve } 408fa3d789dSPierre van Houtryve 409fa3d789dSPierre van Houtryve bool TypeInfer::EnforceFloatingPoint(TypeSetByHwMode &Out) { 410fa3d789dSPierre van Houtryve ValidateOnExit _1(Out, *this); 411fa3d789dSPierre van Houtryve if (TP.hasError()) 412fa3d789dSPierre van Houtryve return false; 413fa3d789dSPierre van Houtryve if (!Out.empty()) 414fa3d789dSPierre van Houtryve return Out.constrain(isFloatingPoint); 415fa3d789dSPierre van Houtryve 416fa3d789dSPierre van Houtryve return Out.assign_if(getLegalTypes(), isFloatingPoint); 417fa3d789dSPierre van Houtryve } 418fa3d789dSPierre van Houtryve 419fa3d789dSPierre van Houtryve bool TypeInfer::EnforceScalar(TypeSetByHwMode &Out) { 420fa3d789dSPierre van Houtryve ValidateOnExit _1(Out, *this); 421fa3d789dSPierre van Houtryve if (TP.hasError()) 422fa3d789dSPierre van Houtryve return false; 423fa3d789dSPierre van Houtryve if (!Out.empty()) 424fa3d789dSPierre van Houtryve return Out.constrain(isScalar); 425fa3d789dSPierre van Houtryve 426fa3d789dSPierre van Houtryve return Out.assign_if(getLegalTypes(), isScalar); 427fa3d789dSPierre van Houtryve } 428fa3d789dSPierre van Houtryve 429fa3d789dSPierre van Houtryve bool TypeInfer::EnforceVector(TypeSetByHwMode &Out) { 430fa3d789dSPierre van Houtryve ValidateOnExit _1(Out, *this); 431fa3d789dSPierre van Houtryve if (TP.hasError()) 432fa3d789dSPierre van Houtryve return false; 433fa3d789dSPierre van Houtryve if (!Out.empty()) 434fa3d789dSPierre van Houtryve return Out.constrain(isVector); 435fa3d789dSPierre van Houtryve 436fa3d789dSPierre van Houtryve return Out.assign_if(getLegalTypes(), isVector); 437fa3d789dSPierre van Houtryve } 438fa3d789dSPierre van Houtryve 439fa3d789dSPierre van Houtryve bool TypeInfer::EnforceAny(TypeSetByHwMode &Out) { 440fa3d789dSPierre van Houtryve ValidateOnExit _1(Out, *this); 441fa3d789dSPierre van Houtryve if (TP.hasError() || !Out.empty()) 442fa3d789dSPierre van Houtryve return false; 443fa3d789dSPierre van Houtryve 444fa3d789dSPierre van Houtryve Out = getLegalTypes(); 445fa3d789dSPierre van Houtryve return true; 446fa3d789dSPierre van Houtryve } 447fa3d789dSPierre van Houtryve 448fa3d789dSPierre van Houtryve template <typename Iter, typename Pred, typename Less> 449fa3d789dSPierre van Houtryve static Iter min_if(Iter B, Iter E, Pred P, Less L) { 450fa3d789dSPierre van Houtryve if (B == E) 451fa3d789dSPierre van Houtryve return E; 452fa3d789dSPierre van Houtryve Iter Min = E; 453fa3d789dSPierre van Houtryve for (Iter I = B; I != E; ++I) { 454fa3d789dSPierre van Houtryve if (!P(*I)) 455fa3d789dSPierre van Houtryve continue; 456fa3d789dSPierre van Houtryve if (Min == E || L(*I, *Min)) 457fa3d789dSPierre van Houtryve Min = I; 458fa3d789dSPierre van Houtryve } 459fa3d789dSPierre van Houtryve return Min; 460fa3d789dSPierre van Houtryve } 461fa3d789dSPierre van Houtryve 462fa3d789dSPierre van Houtryve template <typename Iter, typename Pred, typename Less> 463fa3d789dSPierre van Houtryve static Iter max_if(Iter B, Iter E, Pred P, Less L) { 464fa3d789dSPierre van Houtryve if (B == E) 465fa3d789dSPierre van Houtryve return E; 466fa3d789dSPierre van Houtryve Iter Max = E; 467fa3d789dSPierre van Houtryve for (Iter I = B; I != E; ++I) { 468fa3d789dSPierre van Houtryve if (!P(*I)) 469fa3d789dSPierre van Houtryve continue; 470fa3d789dSPierre van Houtryve if (Max == E || L(*Max, *I)) 471fa3d789dSPierre van Houtryve Max = I; 472fa3d789dSPierre van Houtryve } 473fa3d789dSPierre van Houtryve return Max; 474fa3d789dSPierre van Houtryve } 475fa3d789dSPierre van Houtryve 476fa3d789dSPierre van Houtryve /// Make sure that for each type in Small, there exists a larger type in Big. 477fa3d789dSPierre van Houtryve bool TypeInfer::EnforceSmallerThan(TypeSetByHwMode &Small, TypeSetByHwMode &Big, 478fa3d789dSPierre van Houtryve bool SmallIsVT) { 479fa3d789dSPierre van Houtryve ValidateOnExit _1(Small, *this), _2(Big, *this); 480fa3d789dSPierre van Houtryve if (TP.hasError()) 481fa3d789dSPierre van Houtryve return false; 482fa3d789dSPierre van Houtryve bool Changed = false; 483fa3d789dSPierre van Houtryve 484fa3d789dSPierre van Houtryve assert((!SmallIsVT || !Small.empty()) && 485fa3d789dSPierre van Houtryve "Small should not be empty for SDTCisVTSmallerThanOp"); 486fa3d789dSPierre van Houtryve 487fa3d789dSPierre van Houtryve if (Small.empty()) 488fa3d789dSPierre van Houtryve Changed |= EnforceAny(Small); 489fa3d789dSPierre van Houtryve if (Big.empty()) 490fa3d789dSPierre van Houtryve Changed |= EnforceAny(Big); 491fa3d789dSPierre van Houtryve 492fa3d789dSPierre van Houtryve assert(Small.hasDefault() && Big.hasDefault()); 493fa3d789dSPierre van Houtryve 494fa3d789dSPierre van Houtryve SmallVector<unsigned, 4> Modes; 495fa3d789dSPierre van Houtryve union_modes(Small, Big, Modes); 496fa3d789dSPierre van Houtryve 497fa3d789dSPierre van Houtryve // 1. Only allow integer or floating point types and make sure that 498fa3d789dSPierre van Houtryve // both sides are both integer or both floating point. 499fa3d789dSPierre van Houtryve // 2. Make sure that either both sides have vector types, or neither 500fa3d789dSPierre van Houtryve // of them does. 501fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 502fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &S = Small.get(M); 503fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &B = Big.get(M); 504fa3d789dSPierre van Houtryve 505fa3d789dSPierre van Houtryve assert((!SmallIsVT || !S.empty()) && "Expected non-empty type"); 506fa3d789dSPierre van Houtryve 507fa3d789dSPierre van Houtryve if (any_of(S, isIntegerOrPtr) && any_of(B, isIntegerOrPtr)) { 508fa3d789dSPierre van Houtryve auto NotInt = [](MVT VT) { return !isIntegerOrPtr(VT); }; 509fa3d789dSPierre van Houtryve Changed |= berase_if(S, NotInt); 510fa3d789dSPierre van Houtryve Changed |= berase_if(B, NotInt); 511fa3d789dSPierre van Houtryve } else if (any_of(S, isFloatingPoint) && any_of(B, isFloatingPoint)) { 512fa3d789dSPierre van Houtryve auto NotFP = [](MVT VT) { return !isFloatingPoint(VT); }; 513fa3d789dSPierre van Houtryve Changed |= berase_if(S, NotFP); 514fa3d789dSPierre van Houtryve Changed |= berase_if(B, NotFP); 515fa3d789dSPierre van Houtryve } else if (SmallIsVT && B.empty()) { 516fa3d789dSPierre van Houtryve // B is empty and since S is a specific VT, it will never be empty. Don't 517fa3d789dSPierre van Houtryve // report this as a change, just clear S and continue. This prevents an 518fa3d789dSPierre van Houtryve // infinite loop. 519fa3d789dSPierre van Houtryve S.clear(); 520fa3d789dSPierre van Houtryve } else if (S.empty() || B.empty()) { 521fa3d789dSPierre van Houtryve Changed = !S.empty() || !B.empty(); 522fa3d789dSPierre van Houtryve S.clear(); 523fa3d789dSPierre van Houtryve B.clear(); 524fa3d789dSPierre van Houtryve } else { 525fa3d789dSPierre van Houtryve TP.error("Incompatible types"); 526fa3d789dSPierre van Houtryve return Changed; 527fa3d789dSPierre van Houtryve } 528fa3d789dSPierre van Houtryve 529fa3d789dSPierre van Houtryve if (none_of(S, isVector) || none_of(B, isVector)) { 530fa3d789dSPierre van Houtryve Changed |= berase_if(S, isVector); 531fa3d789dSPierre van Houtryve Changed |= berase_if(B, isVector); 532fa3d789dSPierre van Houtryve } 533fa3d789dSPierre van Houtryve } 534fa3d789dSPierre van Houtryve 535fa3d789dSPierre van Houtryve auto LT = [](MVT A, MVT B) -> bool { 536fa3d789dSPierre van Houtryve // Always treat non-scalable MVTs as smaller than scalable MVTs for the 537fa3d789dSPierre van Houtryve // purposes of ordering. 538fa3d789dSPierre van Houtryve auto ASize = std::tuple(A.isScalableVector(), A.getScalarSizeInBits(), 539fa3d789dSPierre van Houtryve A.getSizeInBits().getKnownMinValue()); 540fa3d789dSPierre van Houtryve auto BSize = std::tuple(B.isScalableVector(), B.getScalarSizeInBits(), 541fa3d789dSPierre van Houtryve B.getSizeInBits().getKnownMinValue()); 542fa3d789dSPierre van Houtryve return ASize < BSize; 543fa3d789dSPierre van Houtryve }; 544fa3d789dSPierre van Houtryve auto SameKindLE = [](MVT A, MVT B) -> bool { 545fa3d789dSPierre van Houtryve // This function is used when removing elements: when a vector is compared 546fa3d789dSPierre van Houtryve // to a non-vector or a scalable vector to any non-scalable MVT, it should 547fa3d789dSPierre van Houtryve // return false (to avoid removal). 548fa3d789dSPierre van Houtryve if (std::tuple(A.isVector(), A.isScalableVector()) != 549fa3d789dSPierre van Houtryve std::tuple(B.isVector(), B.isScalableVector())) 550fa3d789dSPierre van Houtryve return false; 551fa3d789dSPierre van Houtryve 552fa3d789dSPierre van Houtryve return std::tuple(A.getScalarSizeInBits(), 553fa3d789dSPierre van Houtryve A.getSizeInBits().getKnownMinValue()) <= 554fa3d789dSPierre van Houtryve std::tuple(B.getScalarSizeInBits(), 555fa3d789dSPierre van Houtryve B.getSizeInBits().getKnownMinValue()); 556fa3d789dSPierre van Houtryve }; 557fa3d789dSPierre van Houtryve 558fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 559fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &S = Small.get(M); 560fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &B = Big.get(M); 561fa3d789dSPierre van Houtryve // MinS = min scalar in Small, remove all scalars from Big that are 562fa3d789dSPierre van Houtryve // smaller-or-equal than MinS. 563fa3d789dSPierre van Houtryve auto MinS = min_if(S.begin(), S.end(), isScalar, LT); 564fa3d789dSPierre van Houtryve if (MinS != S.end()) 565fa3d789dSPierre van Houtryve Changed |= 566fa3d789dSPierre van Houtryve berase_if(B, std::bind(SameKindLE, std::placeholders::_1, *MinS)); 567fa3d789dSPierre van Houtryve 568fa3d789dSPierre van Houtryve // MaxS = max scalar in Big, remove all scalars from Small that are 569fa3d789dSPierre van Houtryve // larger than MaxS. 570fa3d789dSPierre van Houtryve auto MaxS = max_if(B.begin(), B.end(), isScalar, LT); 571fa3d789dSPierre van Houtryve if (MaxS != B.end()) 572fa3d789dSPierre van Houtryve Changed |= 573fa3d789dSPierre van Houtryve berase_if(S, std::bind(SameKindLE, *MaxS, std::placeholders::_1)); 574fa3d789dSPierre van Houtryve 575fa3d789dSPierre van Houtryve // MinV = min vector in Small, remove all vectors from Big that are 576fa3d789dSPierre van Houtryve // smaller-or-equal than MinV. 577fa3d789dSPierre van Houtryve auto MinV = min_if(S.begin(), S.end(), isVector, LT); 578fa3d789dSPierre van Houtryve if (MinV != S.end()) 579fa3d789dSPierre van Houtryve Changed |= 580fa3d789dSPierre van Houtryve berase_if(B, std::bind(SameKindLE, std::placeholders::_1, *MinV)); 581fa3d789dSPierre van Houtryve 582fa3d789dSPierre van Houtryve // MaxV = max vector in Big, remove all vectors from Small that are 583fa3d789dSPierre van Houtryve // larger than MaxV. 584fa3d789dSPierre van Houtryve auto MaxV = max_if(B.begin(), B.end(), isVector, LT); 585fa3d789dSPierre van Houtryve if (MaxV != B.end()) 586fa3d789dSPierre van Houtryve Changed |= 587fa3d789dSPierre van Houtryve berase_if(S, std::bind(SameKindLE, *MaxV, std::placeholders::_1)); 588fa3d789dSPierre van Houtryve } 589fa3d789dSPierre van Houtryve 590fa3d789dSPierre van Houtryve return Changed; 591fa3d789dSPierre van Houtryve } 592fa3d789dSPierre van Houtryve 593fa3d789dSPierre van Houtryve /// 1. Ensure that for each type T in Vec, T is a vector type, and that 594fa3d789dSPierre van Houtryve /// for each type U in Elem, U is a scalar type. 595fa3d789dSPierre van Houtryve /// 2. Ensure that for each (scalar) type U in Elem, there exists a (vector) 596fa3d789dSPierre van Houtryve /// type T in Vec, such that U is the element type of T. 597fa3d789dSPierre van Houtryve bool TypeInfer::EnforceVectorEltTypeIs(TypeSetByHwMode &Vec, 598fa3d789dSPierre van Houtryve TypeSetByHwMode &Elem) { 599fa3d789dSPierre van Houtryve ValidateOnExit _1(Vec, *this), _2(Elem, *this); 600fa3d789dSPierre van Houtryve if (TP.hasError()) 601fa3d789dSPierre van Houtryve return false; 602fa3d789dSPierre van Houtryve bool Changed = false; 603fa3d789dSPierre van Houtryve 604fa3d789dSPierre van Houtryve if (Vec.empty()) 605fa3d789dSPierre van Houtryve Changed |= EnforceVector(Vec); 606fa3d789dSPierre van Houtryve if (Elem.empty()) 607fa3d789dSPierre van Houtryve Changed |= EnforceScalar(Elem); 608fa3d789dSPierre van Houtryve 609fa3d789dSPierre van Houtryve SmallVector<unsigned, 4> Modes; 610fa3d789dSPierre van Houtryve union_modes(Vec, Elem, Modes); 611fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 612fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &V = Vec.get(M); 613fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &E = Elem.get(M); 614fa3d789dSPierre van Houtryve 615fa3d789dSPierre van Houtryve Changed |= berase_if(V, isScalar); // Scalar = !vector 616fa3d789dSPierre van Houtryve Changed |= berase_if(E, isVector); // Vector = !scalar 617fa3d789dSPierre van Houtryve assert(!V.empty() && !E.empty()); 618fa3d789dSPierre van Houtryve 619fa3d789dSPierre van Houtryve MachineValueTypeSet VT, ST; 620fa3d789dSPierre van Houtryve // Collect element types from the "vector" set. 621fa3d789dSPierre van Houtryve for (MVT T : V) 622fa3d789dSPierre van Houtryve VT.insert(T.getVectorElementType()); 623fa3d789dSPierre van Houtryve // Collect scalar types from the "element" set. 624fa3d789dSPierre van Houtryve for (MVT T : E) 625fa3d789dSPierre van Houtryve ST.insert(T); 626fa3d789dSPierre van Houtryve 627fa3d789dSPierre van Houtryve // Remove from V all (vector) types whose element type is not in S. 628fa3d789dSPierre van Houtryve Changed |= berase_if(V, [&ST](MVT T) -> bool { 629fa3d789dSPierre van Houtryve return !ST.count(T.getVectorElementType()); 630fa3d789dSPierre van Houtryve }); 631fa3d789dSPierre van Houtryve // Remove from E all (scalar) types, for which there is no corresponding 632fa3d789dSPierre van Houtryve // type in V. 633fa3d789dSPierre van Houtryve Changed |= berase_if(E, [&VT](MVT T) -> bool { return !VT.count(T); }); 634fa3d789dSPierre van Houtryve } 635fa3d789dSPierre van Houtryve 636fa3d789dSPierre van Houtryve return Changed; 637fa3d789dSPierre van Houtryve } 638fa3d789dSPierre van Houtryve 639fa3d789dSPierre van Houtryve bool TypeInfer::EnforceVectorEltTypeIs(TypeSetByHwMode &Vec, 640fa3d789dSPierre van Houtryve const ValueTypeByHwMode &VVT) { 641fa3d789dSPierre van Houtryve TypeSetByHwMode Tmp(VVT); 642fa3d789dSPierre van Houtryve ValidateOnExit _1(Vec, *this), _2(Tmp, *this); 643fa3d789dSPierre van Houtryve return EnforceVectorEltTypeIs(Vec, Tmp); 644fa3d789dSPierre van Houtryve } 645fa3d789dSPierre van Houtryve 646fa3d789dSPierre van Houtryve /// Ensure that for each type T in Sub, T is a vector type, and there 647fa3d789dSPierre van Houtryve /// exists a type U in Vec such that U is a vector type with the same 648fa3d789dSPierre van Houtryve /// element type as T and at least as many elements as T. 649fa3d789dSPierre van Houtryve bool TypeInfer::EnforceVectorSubVectorTypeIs(TypeSetByHwMode &Vec, 650fa3d789dSPierre van Houtryve TypeSetByHwMode &Sub) { 651fa3d789dSPierre van Houtryve ValidateOnExit _1(Vec, *this), _2(Sub, *this); 652fa3d789dSPierre van Houtryve if (TP.hasError()) 653fa3d789dSPierre van Houtryve return false; 654fa3d789dSPierre van Houtryve 655fa3d789dSPierre van Houtryve /// Return true if B is a suB-vector of P, i.e. P is a suPer-vector of B. 656fa3d789dSPierre van Houtryve auto IsSubVec = [](MVT B, MVT P) -> bool { 657fa3d789dSPierre van Houtryve if (!B.isVector() || !P.isVector()) 658fa3d789dSPierre van Houtryve return false; 659fa3d789dSPierre van Houtryve // Logically a <4 x i32> is a valid subvector of <n x 4 x i32> 660fa3d789dSPierre van Houtryve // but until there are obvious use-cases for this, keep the 661fa3d789dSPierre van Houtryve // types separate. 662fa3d789dSPierre van Houtryve if (B.isScalableVector() != P.isScalableVector()) 663fa3d789dSPierre van Houtryve return false; 664fa3d789dSPierre van Houtryve if (B.getVectorElementType() != P.getVectorElementType()) 665fa3d789dSPierre van Houtryve return false; 666fa3d789dSPierre van Houtryve return B.getVectorMinNumElements() < P.getVectorMinNumElements(); 667fa3d789dSPierre van Houtryve }; 668fa3d789dSPierre van Houtryve 669fa3d789dSPierre van Houtryve /// Return true if S has no element (vector type) that T is a sub-vector of, 670fa3d789dSPierre van Houtryve /// i.e. has the same element type as T and more elements. 671fa3d789dSPierre van Houtryve auto NoSubV = [&IsSubVec](const TypeSetByHwMode::SetType &S, MVT T) -> bool { 672fa3d789dSPierre van Houtryve for (auto I : S) 673fa3d789dSPierre van Houtryve if (IsSubVec(T, I)) 674fa3d789dSPierre van Houtryve return false; 675fa3d789dSPierre van Houtryve return true; 676fa3d789dSPierre van Houtryve }; 677fa3d789dSPierre van Houtryve 678fa3d789dSPierre van Houtryve /// Return true if S has no element (vector type) that T is a super-vector 679fa3d789dSPierre van Houtryve /// of, i.e. has the same element type as T and fewer elements. 680fa3d789dSPierre van Houtryve auto NoSupV = [&IsSubVec](const TypeSetByHwMode::SetType &S, MVT T) -> bool { 681fa3d789dSPierre van Houtryve for (auto I : S) 682fa3d789dSPierre van Houtryve if (IsSubVec(I, T)) 683fa3d789dSPierre van Houtryve return false; 684fa3d789dSPierre van Houtryve return true; 685fa3d789dSPierre van Houtryve }; 686fa3d789dSPierre van Houtryve 687fa3d789dSPierre van Houtryve bool Changed = false; 688fa3d789dSPierre van Houtryve 689fa3d789dSPierre van Houtryve if (Vec.empty()) 690fa3d789dSPierre van Houtryve Changed |= EnforceVector(Vec); 691fa3d789dSPierre van Houtryve if (Sub.empty()) 692fa3d789dSPierre van Houtryve Changed |= EnforceVector(Sub); 693fa3d789dSPierre van Houtryve 694fa3d789dSPierre van Houtryve SmallVector<unsigned, 4> Modes; 695fa3d789dSPierre van Houtryve union_modes(Vec, Sub, Modes); 696fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 697fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &S = Sub.get(M); 698fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &V = Vec.get(M); 699fa3d789dSPierre van Houtryve 700fa3d789dSPierre van Houtryve Changed |= berase_if(S, isScalar); 701fa3d789dSPierre van Houtryve 702fa3d789dSPierre van Houtryve // Erase all types from S that are not sub-vectors of a type in V. 703fa3d789dSPierre van Houtryve Changed |= berase_if(S, std::bind(NoSubV, V, std::placeholders::_1)); 704fa3d789dSPierre van Houtryve 705fa3d789dSPierre van Houtryve // Erase all types from V that are not super-vectors of a type in S. 706fa3d789dSPierre van Houtryve Changed |= berase_if(V, std::bind(NoSupV, S, std::placeholders::_1)); 707fa3d789dSPierre van Houtryve } 708fa3d789dSPierre van Houtryve 709fa3d789dSPierre van Houtryve return Changed; 710fa3d789dSPierre van Houtryve } 711fa3d789dSPierre van Houtryve 712fa3d789dSPierre van Houtryve /// 1. Ensure that V has a scalar type iff W has a scalar type. 713fa3d789dSPierre van Houtryve /// 2. Ensure that for each vector type T in V, there exists a vector 714fa3d789dSPierre van Houtryve /// type U in W, such that T and U have the same number of elements. 715fa3d789dSPierre van Houtryve /// 3. Ensure that for each vector type U in W, there exists a vector 716fa3d789dSPierre van Houtryve /// type T in V, such that T and U have the same number of elements 717fa3d789dSPierre van Houtryve /// (reverse of 2). 718fa3d789dSPierre van Houtryve bool TypeInfer::EnforceSameNumElts(TypeSetByHwMode &V, TypeSetByHwMode &W) { 719fa3d789dSPierre van Houtryve ValidateOnExit _1(V, *this), _2(W, *this); 720fa3d789dSPierre van Houtryve if (TP.hasError()) 721fa3d789dSPierre van Houtryve return false; 722fa3d789dSPierre van Houtryve 723fa3d789dSPierre van Houtryve bool Changed = false; 724fa3d789dSPierre van Houtryve if (V.empty()) 725fa3d789dSPierre van Houtryve Changed |= EnforceAny(V); 726fa3d789dSPierre van Houtryve if (W.empty()) 727fa3d789dSPierre van Houtryve Changed |= EnforceAny(W); 728fa3d789dSPierre van Houtryve 729fa3d789dSPierre van Houtryve // An actual vector type cannot have 0 elements, so we can treat scalars 730fa3d789dSPierre van Houtryve // as zero-length vectors. This way both vectors and scalars can be 731fa3d789dSPierre van Houtryve // processed identically. 732fa3d789dSPierre van Houtryve auto NoLength = [](const SmallDenseSet<ElementCount> &Lengths, 733fa3d789dSPierre van Houtryve MVT T) -> bool { 734fa3d789dSPierre van Houtryve return !Lengths.count(T.isVector() ? T.getVectorElementCount() 735fa3d789dSPierre van Houtryve : ElementCount()); 736fa3d789dSPierre van Houtryve }; 737fa3d789dSPierre van Houtryve 738fa3d789dSPierre van Houtryve SmallVector<unsigned, 4> Modes; 739fa3d789dSPierre van Houtryve union_modes(V, W, Modes); 740fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 741fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &VS = V.get(M); 742fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &WS = W.get(M); 743fa3d789dSPierre van Houtryve 744fa3d789dSPierre van Houtryve SmallDenseSet<ElementCount> VN, WN; 745fa3d789dSPierre van Houtryve for (MVT T : VS) 746fa3d789dSPierre van Houtryve VN.insert(T.isVector() ? T.getVectorElementCount() : ElementCount()); 747fa3d789dSPierre van Houtryve for (MVT T : WS) 748fa3d789dSPierre van Houtryve WN.insert(T.isVector() ? T.getVectorElementCount() : ElementCount()); 749fa3d789dSPierre van Houtryve 750fa3d789dSPierre van Houtryve Changed |= berase_if(VS, std::bind(NoLength, WN, std::placeholders::_1)); 751fa3d789dSPierre van Houtryve Changed |= berase_if(WS, std::bind(NoLength, VN, std::placeholders::_1)); 752fa3d789dSPierre van Houtryve } 753fa3d789dSPierre van Houtryve return Changed; 754fa3d789dSPierre van Houtryve } 755fa3d789dSPierre van Houtryve 756fa3d789dSPierre van Houtryve namespace { 757fa3d789dSPierre van Houtryve struct TypeSizeComparator { 758fa3d789dSPierre van Houtryve bool operator()(const TypeSize &LHS, const TypeSize &RHS) const { 759fa3d789dSPierre van Houtryve return std::tuple(LHS.isScalable(), LHS.getKnownMinValue()) < 760fa3d789dSPierre van Houtryve std::tuple(RHS.isScalable(), RHS.getKnownMinValue()); 761fa3d789dSPierre van Houtryve } 762fa3d789dSPierre van Houtryve }; 763fa3d789dSPierre van Houtryve } // end anonymous namespace 764fa3d789dSPierre van Houtryve 765fa3d789dSPierre van Houtryve /// 1. Ensure that for each type T in A, there exists a type U in B, 766fa3d789dSPierre van Houtryve /// such that T and U have equal size in bits. 767fa3d789dSPierre van Houtryve /// 2. Ensure that for each type U in B, there exists a type T in A 768fa3d789dSPierre van Houtryve /// such that T and U have equal size in bits (reverse of 1). 769fa3d789dSPierre van Houtryve bool TypeInfer::EnforceSameSize(TypeSetByHwMode &A, TypeSetByHwMode &B) { 770fa3d789dSPierre van Houtryve ValidateOnExit _1(A, *this), _2(B, *this); 771fa3d789dSPierre van Houtryve if (TP.hasError()) 772fa3d789dSPierre van Houtryve return false; 773fa3d789dSPierre van Houtryve bool Changed = false; 774fa3d789dSPierre van Houtryve if (A.empty()) 775fa3d789dSPierre van Houtryve Changed |= EnforceAny(A); 776fa3d789dSPierre van Houtryve if (B.empty()) 777fa3d789dSPierre van Houtryve Changed |= EnforceAny(B); 778fa3d789dSPierre van Houtryve 779fa3d789dSPierre van Houtryve typedef SmallSet<TypeSize, 2, TypeSizeComparator> TypeSizeSet; 780fa3d789dSPierre van Houtryve 781fa3d789dSPierre van Houtryve auto NoSize = [](const TypeSizeSet &Sizes, MVT T) -> bool { 782fa3d789dSPierre van Houtryve return !Sizes.count(T.getSizeInBits()); 783fa3d789dSPierre van Houtryve }; 784fa3d789dSPierre van Houtryve 785fa3d789dSPierre van Houtryve SmallVector<unsigned, 4> Modes; 786fa3d789dSPierre van Houtryve union_modes(A, B, Modes); 787fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 788fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &AS = A.get(M); 789fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &BS = B.get(M); 790fa3d789dSPierre van Houtryve TypeSizeSet AN, BN; 791fa3d789dSPierre van Houtryve 792fa3d789dSPierre van Houtryve for (MVT T : AS) 793fa3d789dSPierre van Houtryve AN.insert(T.getSizeInBits()); 794fa3d789dSPierre van Houtryve for (MVT T : BS) 795fa3d789dSPierre van Houtryve BN.insert(T.getSizeInBits()); 796fa3d789dSPierre van Houtryve 797fa3d789dSPierre van Houtryve Changed |= berase_if(AS, std::bind(NoSize, BN, std::placeholders::_1)); 798fa3d789dSPierre van Houtryve Changed |= berase_if(BS, std::bind(NoSize, AN, std::placeholders::_1)); 799fa3d789dSPierre van Houtryve } 800fa3d789dSPierre van Houtryve 801fa3d789dSPierre van Houtryve return Changed; 802fa3d789dSPierre van Houtryve } 803fa3d789dSPierre van Houtryve 804fa3d789dSPierre van Houtryve void TypeInfer::expandOverloads(TypeSetByHwMode &VTS) const { 805fa3d789dSPierre van Houtryve ValidateOnExit _1(VTS, *this); 806fa3d789dSPierre van Houtryve const TypeSetByHwMode &Legal = getLegalTypes(); 807fa3d789dSPierre van Houtryve assert(Legal.isSimple() && "Default-mode only expected"); 808fa3d789dSPierre van Houtryve const TypeSetByHwMode::SetType &LegalTypes = Legal.getSimple(); 809fa3d789dSPierre van Houtryve 810fa3d789dSPierre van Houtryve for (auto &I : VTS) 811fa3d789dSPierre van Houtryve expandOverloads(I.second, LegalTypes); 812fa3d789dSPierre van Houtryve } 813fa3d789dSPierre van Houtryve 814fa3d789dSPierre van Houtryve void TypeInfer::expandOverloads(TypeSetByHwMode::SetType &Out, 815fa3d789dSPierre van Houtryve const TypeSetByHwMode::SetType &Legal) const { 81694676455SJessica Clarke if (Out.count(MVT::pAny)) { 81794676455SJessica Clarke Out.erase(MVT::pAny); 818fa3d789dSPierre van Houtryve Out.insert(MVT::iPTR); 819fa3d789dSPierre van Houtryve } else if (Out.count(MVT::iAny)) { 820fa3d789dSPierre van Houtryve Out.erase(MVT::iAny); 821fa3d789dSPierre van Houtryve for (MVT T : MVT::integer_valuetypes()) 822fa3d789dSPierre van Houtryve if (Legal.count(T)) 823fa3d789dSPierre van Houtryve Out.insert(T); 824fa3d789dSPierre van Houtryve for (MVT T : MVT::integer_fixedlen_vector_valuetypes()) 825fa3d789dSPierre van Houtryve if (Legal.count(T)) 826fa3d789dSPierre van Houtryve Out.insert(T); 827fa3d789dSPierre van Houtryve for (MVT T : MVT::integer_scalable_vector_valuetypes()) 828fa3d789dSPierre van Houtryve if (Legal.count(T)) 829fa3d789dSPierre van Houtryve Out.insert(T); 830fa3d789dSPierre van Houtryve } else if (Out.count(MVT::fAny)) { 831fa3d789dSPierre van Houtryve Out.erase(MVT::fAny); 832fa3d789dSPierre van Houtryve for (MVT T : MVT::fp_valuetypes()) 833fa3d789dSPierre van Houtryve if (Legal.count(T)) 834fa3d789dSPierre van Houtryve Out.insert(T); 835fa3d789dSPierre van Houtryve for (MVT T : MVT::fp_fixedlen_vector_valuetypes()) 836fa3d789dSPierre van Houtryve if (Legal.count(T)) 837fa3d789dSPierre van Houtryve Out.insert(T); 838fa3d789dSPierre van Houtryve for (MVT T : MVT::fp_scalable_vector_valuetypes()) 839fa3d789dSPierre van Houtryve if (Legal.count(T)) 840fa3d789dSPierre van Houtryve Out.insert(T); 841fa3d789dSPierre van Houtryve } else if (Out.count(MVT::vAny)) { 842fa3d789dSPierre van Houtryve Out.erase(MVT::vAny); 843fa3d789dSPierre van Houtryve for (MVT T : MVT::vector_valuetypes()) 844fa3d789dSPierre van Houtryve if (Legal.count(T)) 845fa3d789dSPierre van Houtryve Out.insert(T); 846fa3d789dSPierre van Houtryve } else if (Out.count(MVT::Any)) { 847fa3d789dSPierre van Houtryve Out.erase(MVT::Any); 848fa3d789dSPierre van Houtryve for (MVT T : MVT::all_valuetypes()) 849fa3d789dSPierre van Houtryve if (Legal.count(T)) 850fa3d789dSPierre van Houtryve Out.insert(T); 851fa3d789dSPierre van Houtryve } 852fa3d789dSPierre van Houtryve } 853fa3d789dSPierre van Houtryve 854fa3d789dSPierre van Houtryve const TypeSetByHwMode &TypeInfer::getLegalTypes() const { 855fa3d789dSPierre van Houtryve if (!LegalTypesCached) { 856fa3d789dSPierre van Houtryve TypeSetByHwMode::SetType &LegalTypes = LegalCache.getOrCreate(DefaultMode); 857fa3d789dSPierre van Houtryve // Stuff all types from all modes into the default mode. 858fa3d789dSPierre van Houtryve const TypeSetByHwMode <S = TP.getDAGPatterns().getLegalTypes(); 859fa3d789dSPierre van Houtryve for (const auto &I : LTS) 860fa3d789dSPierre van Houtryve LegalTypes.insert(I.second); 861fa3d789dSPierre van Houtryve LegalTypesCached = true; 862fa3d789dSPierre van Houtryve } 863fa3d789dSPierre van Houtryve assert(LegalCache.isSimple() && "Default-mode only expected"); 864fa3d789dSPierre van Houtryve return LegalCache; 865fa3d789dSPierre van Houtryve } 866fa3d789dSPierre van Houtryve 867fa3d789dSPierre van Houtryve TypeInfer::ValidateOnExit::~ValidateOnExit() { 868fa3d789dSPierre van Houtryve if (Infer.Validate && !VTS.validate()) { 869fa3d789dSPierre van Houtryve #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) 870fa3d789dSPierre van Houtryve errs() << "Type set is empty for each HW mode:\n" 871fa3d789dSPierre van Houtryve "possible type contradiction in the pattern below " 872fa3d789dSPierre van Houtryve "(use -print-records with llvm-tblgen to see all " 873fa3d789dSPierre van Houtryve "expanded records).\n"; 874fa3d789dSPierre van Houtryve Infer.TP.dump(); 875fa3d789dSPierre van Houtryve errs() << "Generated from record:\n"; 876fa3d789dSPierre van Houtryve Infer.TP.getRecord()->dump(); 877fa3d789dSPierre van Houtryve #endif 878fa3d789dSPierre van Houtryve PrintFatalError(Infer.TP.getRecord()->getLoc(), 879fa3d789dSPierre van Houtryve "Type set is empty for each HW mode in '" + 880fa3d789dSPierre van Houtryve Infer.TP.getRecord()->getName() + "'"); 881fa3d789dSPierre van Houtryve } 882fa3d789dSPierre van Houtryve } 883fa3d789dSPierre van Houtryve 884fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 885fa3d789dSPierre van Houtryve // ScopedName Implementation 886fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 887fa3d789dSPierre van Houtryve 888fa3d789dSPierre van Houtryve bool ScopedName::operator==(const ScopedName &o) const { 889fa3d789dSPierre van Houtryve return Scope == o.Scope && Identifier == o.Identifier; 890fa3d789dSPierre van Houtryve } 891fa3d789dSPierre van Houtryve 892fa3d789dSPierre van Houtryve bool ScopedName::operator!=(const ScopedName &o) const { return !(*this == o); } 893fa3d789dSPierre van Houtryve 894fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 895fa3d789dSPierre van Houtryve // TreePredicateFn Implementation 896fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 897fa3d789dSPierre van Houtryve 898fa3d789dSPierre van Houtryve /// TreePredicateFn constructor. Here 'N' is a subclass of PatFrag. 899fa3d789dSPierre van Houtryve TreePredicateFn::TreePredicateFn(TreePattern *N) : PatFragRec(N) { 900fa3d789dSPierre van Houtryve assert( 901fa3d789dSPierre van Houtryve (!hasPredCode() || !hasImmCode()) && 902fa3d789dSPierre van Houtryve ".td file corrupt: can't have a node predicate *and* an imm predicate"); 903fa3d789dSPierre van Houtryve } 904fa3d789dSPierre van Houtryve 905fa3d789dSPierre van Houtryve bool TreePredicateFn::hasPredCode() const { 906d0dc29c2Sjofrn return isLoad() || isStore() || isAtomic() || hasNoUse() || hasOneUse() || 907fa3d789dSPierre van Houtryve !PatFragRec->getRecord()->getValueAsString("PredicateCode").empty(); 908fa3d789dSPierre van Houtryve } 909fa3d789dSPierre van Houtryve 910fa3d789dSPierre van Houtryve std::string TreePredicateFn::getPredCode() const { 911fa3d789dSPierre van Houtryve std::string Code; 912fa3d789dSPierre van Houtryve 9133138eb50SRahul Joshi if (!isLoad() && !isStore() && !isAtomic() && getMemoryVT()) 914fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 915fa3d789dSPierre van Houtryve "MemoryVT requires IsLoad or IsStore"); 916fa3d789dSPierre van Houtryve 917fa3d789dSPierre van Houtryve if (!isLoad() && !isStore()) { 918fa3d789dSPierre van Houtryve if (isUnindexed()) 919fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 920fa3d789dSPierre van Houtryve "IsUnindexed requires IsLoad or IsStore"); 921fa3d789dSPierre van Houtryve 9223138eb50SRahul Joshi if (getScalarMemoryVT()) 923fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 924fa3d789dSPierre van Houtryve "ScalarMemoryVT requires IsLoad or IsStore"); 925fa3d789dSPierre van Houtryve } 926fa3d789dSPierre van Houtryve 927fa3d789dSPierre van Houtryve if (isLoad() + isStore() + isAtomic() > 1) 928fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 929fa3d789dSPierre van Houtryve "IsLoad, IsStore, and IsAtomic are mutually exclusive"); 930fa3d789dSPierre van Houtryve 931fa3d789dSPierre van Houtryve if (isLoad()) { 932fa3d789dSPierre van Houtryve if (!isUnindexed() && !isNonExtLoad() && !isAnyExtLoad() && 933fa3d789dSPierre van Houtryve !isSignExtLoad() && !isZeroExtLoad() && getMemoryVT() == nullptr && 934fa3d789dSPierre van Houtryve getScalarMemoryVT() == nullptr && getAddressSpaces() == nullptr && 935fa3d789dSPierre van Houtryve getMinAlignment() < 1) 936fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 937fa3d789dSPierre van Houtryve "IsLoad cannot be used by itself"); 938fa3d789dSPierre van Houtryve } else { 939fa3d789dSPierre van Houtryve if (isNonExtLoad()) 940fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 941fa3d789dSPierre van Houtryve "IsNonExtLoad requires IsLoad"); 942fa3d789dSPierre van Houtryve if (isAnyExtLoad()) 943fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 944fa3d789dSPierre van Houtryve "IsAnyExtLoad requires IsLoad"); 945fa3d789dSPierre van Houtryve 946fa3d789dSPierre van Houtryve if (!isAtomic()) { 947fa3d789dSPierre van Houtryve if (isSignExtLoad()) 948fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 949fa3d789dSPierre van Houtryve "IsSignExtLoad requires IsLoad or IsAtomic"); 950fa3d789dSPierre van Houtryve if (isZeroExtLoad()) 951fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 952fa3d789dSPierre van Houtryve "IsZeroExtLoad requires IsLoad or IsAtomic"); 953fa3d789dSPierre van Houtryve } 954fa3d789dSPierre van Houtryve } 955fa3d789dSPierre van Houtryve 956fa3d789dSPierre van Houtryve if (isStore()) { 957fa3d789dSPierre van Houtryve if (!isUnindexed() && !isTruncStore() && !isNonTruncStore() && 958fa3d789dSPierre van Houtryve getMemoryVT() == nullptr && getScalarMemoryVT() == nullptr && 959fa3d789dSPierre van Houtryve getAddressSpaces() == nullptr && getMinAlignment() < 1) 960fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 961fa3d789dSPierre van Houtryve "IsStore cannot be used by itself"); 962fa3d789dSPierre van Houtryve } else { 963fa3d789dSPierre van Houtryve if (isNonTruncStore()) 964fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 965fa3d789dSPierre van Houtryve "IsNonTruncStore requires IsStore"); 966fa3d789dSPierre van Houtryve if (isTruncStore()) 967fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 968fa3d789dSPierre van Houtryve "IsTruncStore requires IsStore"); 969fa3d789dSPierre van Houtryve } 970fa3d789dSPierre van Houtryve 971fa3d789dSPierre van Houtryve if (isAtomic()) { 972fa3d789dSPierre van Houtryve if (getMemoryVT() == nullptr && !isAtomicOrderingMonotonic() && 973fa3d789dSPierre van Houtryve getAddressSpaces() == nullptr && 974fa3d789dSPierre van Houtryve // FIXME: Should atomic loads be IsLoad, IsAtomic, or both? 975fa3d789dSPierre van Houtryve !isZeroExtLoad() && !isSignExtLoad() && !isAtomicOrderingAcquire() && 976fa3d789dSPierre van Houtryve !isAtomicOrderingRelease() && !isAtomicOrderingAcquireRelease() && 977fa3d789dSPierre van Houtryve !isAtomicOrderingSequentiallyConsistent() && 978fa3d789dSPierre van Houtryve !isAtomicOrderingAcquireOrStronger() && 979fa3d789dSPierre van Houtryve !isAtomicOrderingReleaseOrStronger() && 980fa3d789dSPierre van Houtryve !isAtomicOrderingWeakerThanAcquire() && 981fa3d789dSPierre van Houtryve !isAtomicOrderingWeakerThanRelease()) 982fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 983fa3d789dSPierre van Houtryve "IsAtomic cannot be used by itself"); 984fa3d789dSPierre van Houtryve } else { 985fa3d789dSPierre van Houtryve if (isAtomicOrderingMonotonic()) 986fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 987fa3d789dSPierre van Houtryve "IsAtomicOrderingMonotonic requires IsAtomic"); 988fa3d789dSPierre van Houtryve if (isAtomicOrderingAcquire()) 989fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 990fa3d789dSPierre van Houtryve "IsAtomicOrderingAcquire requires IsAtomic"); 991fa3d789dSPierre van Houtryve if (isAtomicOrderingRelease()) 992fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 993fa3d789dSPierre van Houtryve "IsAtomicOrderingRelease requires IsAtomic"); 994fa3d789dSPierre van Houtryve if (isAtomicOrderingAcquireRelease()) 995fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 996fa3d789dSPierre van Houtryve "IsAtomicOrderingAcquireRelease requires IsAtomic"); 997fa3d789dSPierre van Houtryve if (isAtomicOrderingSequentiallyConsistent()) 998fa3d789dSPierre van Houtryve PrintFatalError( 999fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1000fa3d789dSPierre van Houtryve "IsAtomicOrderingSequentiallyConsistent requires IsAtomic"); 1001fa3d789dSPierre van Houtryve if (isAtomicOrderingAcquireOrStronger()) 1002fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 1003fa3d789dSPierre van Houtryve "IsAtomicOrderingAcquireOrStronger requires IsAtomic"); 1004fa3d789dSPierre van Houtryve if (isAtomicOrderingReleaseOrStronger()) 1005fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 1006fa3d789dSPierre van Houtryve "IsAtomicOrderingReleaseOrStronger requires IsAtomic"); 1007fa3d789dSPierre van Houtryve if (isAtomicOrderingWeakerThanAcquire()) 1008fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 1009fa3d789dSPierre van Houtryve "IsAtomicOrderingWeakerThanAcquire requires IsAtomic"); 1010fa3d789dSPierre van Houtryve } 1011fa3d789dSPierre van Houtryve 1012fa3d789dSPierre van Houtryve if (isLoad() || isStore() || isAtomic()) { 10133138eb50SRahul Joshi if (const ListInit *AddressSpaces = getAddressSpaces()) { 1014fa3d789dSPierre van Houtryve Code += "unsigned AddrSpace = cast<MemSDNode>(N)->getAddressSpace();\n" 1015fa3d789dSPierre van Houtryve " if ("; 1016fa3d789dSPierre van Houtryve 1017fa3d789dSPierre van Houtryve ListSeparator LS(" && "); 10183138eb50SRahul Joshi for (const Init *Val : AddressSpaces->getValues()) { 1019fa3d789dSPierre van Houtryve Code += LS; 1020fa3d789dSPierre van Houtryve 10213138eb50SRahul Joshi const IntInit *IntVal = dyn_cast<IntInit>(Val); 1022fa3d789dSPierre van Houtryve if (!IntVal) { 1023fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 1024fa3d789dSPierre van Houtryve "AddressSpaces element must be integer"); 1025fa3d789dSPierre van Houtryve } 1026fa3d789dSPierre van Houtryve 1027fa3d789dSPierre van Houtryve Code += "AddrSpace != " + utostr(IntVal->getValue()); 1028fa3d789dSPierre van Houtryve } 1029fa3d789dSPierre van Houtryve 1030fa3d789dSPierre van Houtryve Code += ")\nreturn false;\n"; 1031fa3d789dSPierre van Houtryve } 1032fa3d789dSPierre van Houtryve 1033fa3d789dSPierre van Houtryve int64_t MinAlign = getMinAlignment(); 1034fa3d789dSPierre van Houtryve if (MinAlign > 0) { 1035fa3d789dSPierre van Houtryve Code += "if (cast<MemSDNode>(N)->getAlign() < Align("; 1036fa3d789dSPierre van Houtryve Code += utostr(MinAlign); 1037fa3d789dSPierre van Houtryve Code += "))\nreturn false;\n"; 1038fa3d789dSPierre van Houtryve } 1039fa3d789dSPierre van Houtryve 10403138eb50SRahul Joshi if (const Record *MemoryVT = getMemoryVT()) 1041fa3d789dSPierre van Houtryve Code += ("if (cast<MemSDNode>(N)->getMemoryVT() != MVT::" + 1042fa3d789dSPierre van Houtryve MemoryVT->getName() + ") return false;\n") 1043fa3d789dSPierre van Houtryve .str(); 1044fa3d789dSPierre van Houtryve } 1045fa3d789dSPierre van Houtryve 1046fa3d789dSPierre van Houtryve if (isAtomic() && isAtomicOrderingMonotonic()) 1047fa3d789dSPierre van Houtryve Code += "if (cast<AtomicSDNode>(N)->getMergedOrdering() != " 1048fa3d789dSPierre van Houtryve "AtomicOrdering::Monotonic) return false;\n"; 1049fa3d789dSPierre van Houtryve if (isAtomic() && isAtomicOrderingAcquire()) 1050fa3d789dSPierre van Houtryve Code += "if (cast<AtomicSDNode>(N)->getMergedOrdering() != " 1051fa3d789dSPierre van Houtryve "AtomicOrdering::Acquire) return false;\n"; 1052fa3d789dSPierre van Houtryve if (isAtomic() && isAtomicOrderingRelease()) 1053fa3d789dSPierre van Houtryve Code += "if (cast<AtomicSDNode>(N)->getMergedOrdering() != " 1054fa3d789dSPierre van Houtryve "AtomicOrdering::Release) return false;\n"; 1055fa3d789dSPierre van Houtryve if (isAtomic() && isAtomicOrderingAcquireRelease()) 1056fa3d789dSPierre van Houtryve Code += "if (cast<AtomicSDNode>(N)->getMergedOrdering() != " 1057fa3d789dSPierre van Houtryve "AtomicOrdering::AcquireRelease) return false;\n"; 1058fa3d789dSPierre van Houtryve if (isAtomic() && isAtomicOrderingSequentiallyConsistent()) 1059fa3d789dSPierre van Houtryve Code += "if (cast<AtomicSDNode>(N)->getMergedOrdering() != " 1060fa3d789dSPierre van Houtryve "AtomicOrdering::SequentiallyConsistent) return false;\n"; 1061fa3d789dSPierre van Houtryve 1062fa3d789dSPierre van Houtryve if (isAtomic() && isAtomicOrderingAcquireOrStronger()) 1063fa3d789dSPierre van Houtryve Code += 1064fa3d789dSPierre van Houtryve "if (!isAcquireOrStronger(cast<AtomicSDNode>(N)->getMergedOrdering())) " 1065fa3d789dSPierre van Houtryve "return false;\n"; 1066fa3d789dSPierre van Houtryve if (isAtomic() && isAtomicOrderingWeakerThanAcquire()) 1067fa3d789dSPierre van Houtryve Code += 1068fa3d789dSPierre van Houtryve "if (isAcquireOrStronger(cast<AtomicSDNode>(N)->getMergedOrdering())) " 1069fa3d789dSPierre van Houtryve "return false;\n"; 1070fa3d789dSPierre van Houtryve 1071fa3d789dSPierre van Houtryve if (isAtomic() && isAtomicOrderingReleaseOrStronger()) 1072fa3d789dSPierre van Houtryve Code += 1073fa3d789dSPierre van Houtryve "if (!isReleaseOrStronger(cast<AtomicSDNode>(N)->getMergedOrdering())) " 1074fa3d789dSPierre van Houtryve "return false;\n"; 1075fa3d789dSPierre van Houtryve if (isAtomic() && isAtomicOrderingWeakerThanRelease()) 1076fa3d789dSPierre van Houtryve Code += 1077fa3d789dSPierre van Houtryve "if (isReleaseOrStronger(cast<AtomicSDNode>(N)->getMergedOrdering())) " 1078fa3d789dSPierre van Houtryve "return false;\n"; 1079fa3d789dSPierre van Houtryve 1080fa3d789dSPierre van Houtryve // TODO: Handle atomic sextload/zextload normally when ATOMIC_LOAD is removed. 1081fa3d789dSPierre van Houtryve if (isAtomic() && (isZeroExtLoad() || isSignExtLoad())) 1082fa3d789dSPierre van Houtryve Code += "return false;\n"; 1083fa3d789dSPierre van Houtryve 1084fa3d789dSPierre van Houtryve if (isLoad() || isStore()) { 1085fa3d789dSPierre van Houtryve StringRef SDNodeName = isLoad() ? "LoadSDNode" : "StoreSDNode"; 1086fa3d789dSPierre van Houtryve 1087fa3d789dSPierre van Houtryve if (isUnindexed()) 1088fa3d789dSPierre van Houtryve Code += ("if (cast<" + SDNodeName + 1089fa3d789dSPierre van Houtryve ">(N)->getAddressingMode() != ISD::UNINDEXED) " 1090fa3d789dSPierre van Houtryve "return false;\n") 1091fa3d789dSPierre van Houtryve .str(); 1092fa3d789dSPierre van Houtryve 1093fa3d789dSPierre van Houtryve if (isLoad()) { 1094fa3d789dSPierre van Houtryve if ((isNonExtLoad() + isAnyExtLoad() + isSignExtLoad() + 1095fa3d789dSPierre van Houtryve isZeroExtLoad()) > 1) 1096fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 1097fa3d789dSPierre van Houtryve "IsNonExtLoad, IsAnyExtLoad, IsSignExtLoad, and " 1098fa3d789dSPierre van Houtryve "IsZeroExtLoad are mutually exclusive"); 1099fa3d789dSPierre van Houtryve if (isNonExtLoad()) 1100fa3d789dSPierre van Houtryve Code += "if (cast<LoadSDNode>(N)->getExtensionType() != " 1101fa3d789dSPierre van Houtryve "ISD::NON_EXTLOAD) return false;\n"; 1102fa3d789dSPierre van Houtryve if (isAnyExtLoad()) 1103fa3d789dSPierre van Houtryve Code += "if (cast<LoadSDNode>(N)->getExtensionType() != ISD::EXTLOAD) " 1104fa3d789dSPierre van Houtryve "return false;\n"; 1105fa3d789dSPierre van Houtryve if (isSignExtLoad()) 1106fa3d789dSPierre van Houtryve Code += "if (cast<LoadSDNode>(N)->getExtensionType() != ISD::SEXTLOAD) " 1107fa3d789dSPierre van Houtryve "return false;\n"; 1108fa3d789dSPierre van Houtryve if (isZeroExtLoad()) 1109fa3d789dSPierre van Houtryve Code += "if (cast<LoadSDNode>(N)->getExtensionType() != ISD::ZEXTLOAD) " 1110fa3d789dSPierre van Houtryve "return false;\n"; 1111fa3d789dSPierre van Houtryve } else { 1112fa3d789dSPierre van Houtryve if ((isNonTruncStore() + isTruncStore()) > 1) 1113fa3d789dSPierre van Houtryve PrintFatalError( 1114fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1115fa3d789dSPierre van Houtryve "IsNonTruncStore, and IsTruncStore are mutually exclusive"); 1116fa3d789dSPierre van Houtryve if (isNonTruncStore()) 1117fa3d789dSPierre van Houtryve Code += 1118fa3d789dSPierre van Houtryve " if (cast<StoreSDNode>(N)->isTruncatingStore()) return false;\n"; 1119fa3d789dSPierre van Houtryve if (isTruncStore()) 1120fa3d789dSPierre van Houtryve Code += 1121fa3d789dSPierre van Houtryve " if (!cast<StoreSDNode>(N)->isTruncatingStore()) return false;\n"; 1122fa3d789dSPierre van Houtryve } 1123fa3d789dSPierre van Houtryve 11243138eb50SRahul Joshi if (const Record *ScalarMemoryVT = getScalarMemoryVT()) 1125fa3d789dSPierre van Houtryve Code += ("if (cast<" + SDNodeName + 1126fa3d789dSPierre van Houtryve ">(N)->getMemoryVT().getScalarType() != MVT::" + 1127fa3d789dSPierre van Houtryve ScalarMemoryVT->getName() + ") return false;\n") 1128fa3d789dSPierre van Houtryve .str(); 1129fa3d789dSPierre van Houtryve } 1130fa3d789dSPierre van Houtryve 1131fa3d789dSPierre van Houtryve if (hasNoUse()) 1132fa3d789dSPierre van Houtryve Code += "if (!SDValue(N, 0).use_empty()) return false;\n"; 1133d0dc29c2Sjofrn if (hasOneUse()) 1134d0dc29c2Sjofrn Code += "if (!SDValue(N, 0).hasOneUse()) return false;\n"; 1135fa3d789dSPierre van Houtryve 1136fa3d789dSPierre van Houtryve std::string PredicateCode = 1137fa3d789dSPierre van Houtryve std::string(PatFragRec->getRecord()->getValueAsString("PredicateCode")); 1138fa3d789dSPierre van Houtryve 1139fa3d789dSPierre van Houtryve Code += PredicateCode; 1140fa3d789dSPierre van Houtryve 1141fa3d789dSPierre van Houtryve if (PredicateCode.empty() && !Code.empty()) 1142fa3d789dSPierre van Houtryve Code += "return true;\n"; 1143fa3d789dSPierre van Houtryve 1144fa3d789dSPierre van Houtryve return Code; 1145fa3d789dSPierre van Houtryve } 1146fa3d789dSPierre van Houtryve 1147fa3d789dSPierre van Houtryve bool TreePredicateFn::hasImmCode() const { 1148fa3d789dSPierre van Houtryve return !PatFragRec->getRecord()->getValueAsString("ImmediateCode").empty(); 1149fa3d789dSPierre van Houtryve } 1150fa3d789dSPierre van Houtryve 1151fa3d789dSPierre van Houtryve std::string TreePredicateFn::getImmCode() const { 1152fa3d789dSPierre van Houtryve return std::string( 1153fa3d789dSPierre van Houtryve PatFragRec->getRecord()->getValueAsString("ImmediateCode")); 1154fa3d789dSPierre van Houtryve } 1155fa3d789dSPierre van Houtryve 1156fa3d789dSPierre van Houtryve bool TreePredicateFn::immCodeUsesAPInt() const { 1157fa3d789dSPierre van Houtryve return getOrigPatFragRecord()->getRecord()->getValueAsBit("IsAPInt"); 1158fa3d789dSPierre van Houtryve } 1159fa3d789dSPierre van Houtryve 1160fa3d789dSPierre van Houtryve bool TreePredicateFn::immCodeUsesAPFloat() const { 1161fa3d789dSPierre van Houtryve bool Unset; 1162fa3d789dSPierre van Houtryve // The return value will be false when IsAPFloat is unset. 1163fa3d789dSPierre van Houtryve return getOrigPatFragRecord()->getRecord()->getValueAsBitOrUnset("IsAPFloat", 1164fa3d789dSPierre van Houtryve Unset); 1165fa3d789dSPierre van Houtryve } 1166fa3d789dSPierre van Houtryve 1167fa3d789dSPierre van Houtryve bool TreePredicateFn::isPredefinedPredicateEqualTo(StringRef Field, 1168fa3d789dSPierre van Houtryve bool Value) const { 1169fa3d789dSPierre van Houtryve bool Unset; 1170fa3d789dSPierre van Houtryve bool Result = 1171fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getValueAsBitOrUnset(Field, Unset); 1172fa3d789dSPierre van Houtryve if (Unset) 1173fa3d789dSPierre van Houtryve return false; 1174fa3d789dSPierre van Houtryve return Result == Value; 1175fa3d789dSPierre van Houtryve } 1176fa3d789dSPierre van Houtryve bool TreePredicateFn::usesOperands() const { 1177fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("PredicateCodeUsesOperands", true); 1178fa3d789dSPierre van Houtryve } 1179fa3d789dSPierre van Houtryve bool TreePredicateFn::hasNoUse() const { 1180fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("HasNoUse", true); 1181fa3d789dSPierre van Houtryve } 1182d0dc29c2Sjofrn bool TreePredicateFn::hasOneUse() const { 1183d0dc29c2Sjofrn return isPredefinedPredicateEqualTo("HasOneUse", true); 1184d0dc29c2Sjofrn } 1185fa3d789dSPierre van Houtryve bool TreePredicateFn::isLoad() const { 1186fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsLoad", true); 1187fa3d789dSPierre van Houtryve } 1188fa3d789dSPierre van Houtryve bool TreePredicateFn::isStore() const { 1189fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsStore", true); 1190fa3d789dSPierre van Houtryve } 1191fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomic() const { 1192fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomic", true); 1193fa3d789dSPierre van Houtryve } 1194fa3d789dSPierre van Houtryve bool TreePredicateFn::isUnindexed() const { 1195fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsUnindexed", true); 1196fa3d789dSPierre van Houtryve } 1197fa3d789dSPierre van Houtryve bool TreePredicateFn::isNonExtLoad() const { 1198fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsNonExtLoad", true); 1199fa3d789dSPierre van Houtryve } 1200fa3d789dSPierre van Houtryve bool TreePredicateFn::isAnyExtLoad() const { 1201fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAnyExtLoad", true); 1202fa3d789dSPierre van Houtryve } 1203fa3d789dSPierre van Houtryve bool TreePredicateFn::isSignExtLoad() const { 1204fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsSignExtLoad", true); 1205fa3d789dSPierre van Houtryve } 1206fa3d789dSPierre van Houtryve bool TreePredicateFn::isZeroExtLoad() const { 1207fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsZeroExtLoad", true); 1208fa3d789dSPierre van Houtryve } 1209fa3d789dSPierre van Houtryve bool TreePredicateFn::isNonTruncStore() const { 1210fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsTruncStore", false); 1211fa3d789dSPierre van Houtryve } 1212fa3d789dSPierre van Houtryve bool TreePredicateFn::isTruncStore() const { 1213fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsTruncStore", true); 1214fa3d789dSPierre van Houtryve } 1215fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomicOrderingMonotonic() const { 1216fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomicOrderingMonotonic", true); 1217fa3d789dSPierre van Houtryve } 1218fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomicOrderingAcquire() const { 1219fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomicOrderingAcquire", true); 1220fa3d789dSPierre van Houtryve } 1221fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomicOrderingRelease() const { 1222fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomicOrderingRelease", true); 1223fa3d789dSPierre van Houtryve } 1224fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomicOrderingAcquireRelease() const { 1225fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomicOrderingAcquireRelease", true); 1226fa3d789dSPierre van Houtryve } 1227fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomicOrderingSequentiallyConsistent() const { 1228fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomicOrderingSequentiallyConsistent", 1229fa3d789dSPierre van Houtryve true); 1230fa3d789dSPierre van Houtryve } 1231fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomicOrderingAcquireOrStronger() const { 1232fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomicOrderingAcquireOrStronger", 1233fa3d789dSPierre van Houtryve true); 1234fa3d789dSPierre van Houtryve } 1235fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomicOrderingWeakerThanAcquire() const { 1236fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomicOrderingAcquireOrStronger", 1237fa3d789dSPierre van Houtryve false); 1238fa3d789dSPierre van Houtryve } 1239fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomicOrderingReleaseOrStronger() const { 1240fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomicOrderingReleaseOrStronger", 1241fa3d789dSPierre van Houtryve true); 1242fa3d789dSPierre van Houtryve } 1243fa3d789dSPierre van Houtryve bool TreePredicateFn::isAtomicOrderingWeakerThanRelease() const { 1244fa3d789dSPierre van Houtryve return isPredefinedPredicateEqualTo("IsAtomicOrderingReleaseOrStronger", 1245fa3d789dSPierre van Houtryve false); 1246fa3d789dSPierre van Houtryve } 12473138eb50SRahul Joshi const Record *TreePredicateFn::getMemoryVT() const { 124837865681SRahul Joshi const Record *R = getOrigPatFragRecord()->getRecord(); 1249fa3d789dSPierre van Houtryve if (R->isValueUnset("MemoryVT")) 1250fa3d789dSPierre van Houtryve return nullptr; 1251fa3d789dSPierre van Houtryve return R->getValueAsDef("MemoryVT"); 1252fa3d789dSPierre van Houtryve } 1253fa3d789dSPierre van Houtryve 12543138eb50SRahul Joshi const ListInit *TreePredicateFn::getAddressSpaces() const { 125537865681SRahul Joshi const Record *R = getOrigPatFragRecord()->getRecord(); 1256fa3d789dSPierre van Houtryve if (R->isValueUnset("AddressSpaces")) 1257fa3d789dSPierre van Houtryve return nullptr; 1258fa3d789dSPierre van Houtryve return R->getValueAsListInit("AddressSpaces"); 1259fa3d789dSPierre van Houtryve } 1260fa3d789dSPierre van Houtryve 1261fa3d789dSPierre van Houtryve int64_t TreePredicateFn::getMinAlignment() const { 126237865681SRahul Joshi const Record *R = getOrigPatFragRecord()->getRecord(); 1263fa3d789dSPierre van Houtryve if (R->isValueUnset("MinAlignment")) 1264fa3d789dSPierre van Houtryve return 0; 1265fa3d789dSPierre van Houtryve return R->getValueAsInt("MinAlignment"); 1266fa3d789dSPierre van Houtryve } 1267fa3d789dSPierre van Houtryve 12683138eb50SRahul Joshi const Record *TreePredicateFn::getScalarMemoryVT() const { 126937865681SRahul Joshi const Record *R = getOrigPatFragRecord()->getRecord(); 1270fa3d789dSPierre van Houtryve if (R->isValueUnset("ScalarMemoryVT")) 1271fa3d789dSPierre van Houtryve return nullptr; 1272fa3d789dSPierre van Houtryve return R->getValueAsDef("ScalarMemoryVT"); 1273fa3d789dSPierre van Houtryve } 1274fa3d789dSPierre van Houtryve bool TreePredicateFn::hasGISelPredicateCode() const { 1275fa3d789dSPierre van Houtryve return !PatFragRec->getRecord() 1276fa3d789dSPierre van Houtryve ->getValueAsString("GISelPredicateCode") 1277fa3d789dSPierre van Houtryve .empty(); 1278fa3d789dSPierre van Houtryve } 1279fa3d789dSPierre van Houtryve std::string TreePredicateFn::getGISelPredicateCode() const { 1280fa3d789dSPierre van Houtryve return std::string( 1281fa3d789dSPierre van Houtryve PatFragRec->getRecord()->getValueAsString("GISelPredicateCode")); 1282fa3d789dSPierre van Houtryve } 1283fa3d789dSPierre van Houtryve 1284fa3d789dSPierre van Houtryve StringRef TreePredicateFn::getImmType() const { 1285fa3d789dSPierre van Houtryve if (immCodeUsesAPInt()) 1286fa3d789dSPierre van Houtryve return "const APInt &"; 1287fa3d789dSPierre van Houtryve if (immCodeUsesAPFloat()) 1288fa3d789dSPierre van Houtryve return "const APFloat &"; 1289fa3d789dSPierre van Houtryve return "int64_t"; 1290fa3d789dSPierre van Houtryve } 1291fa3d789dSPierre van Houtryve 1292fa3d789dSPierre van Houtryve StringRef TreePredicateFn::getImmTypeIdentifier() const { 1293fa3d789dSPierre van Houtryve if (immCodeUsesAPInt()) 1294fa3d789dSPierre van Houtryve return "APInt"; 1295fa3d789dSPierre van Houtryve if (immCodeUsesAPFloat()) 1296fa3d789dSPierre van Houtryve return "APFloat"; 1297fa3d789dSPierre van Houtryve return "I64"; 1298fa3d789dSPierre van Houtryve } 1299fa3d789dSPierre van Houtryve 1300fa3d789dSPierre van Houtryve /// isAlwaysTrue - Return true if this is a noop predicate. 1301fa3d789dSPierre van Houtryve bool TreePredicateFn::isAlwaysTrue() const { 1302fa3d789dSPierre van Houtryve return !hasPredCode() && !hasImmCode(); 1303fa3d789dSPierre van Houtryve } 1304fa3d789dSPierre van Houtryve 1305fa3d789dSPierre van Houtryve /// Return the name to use in the generated code to reference this, this is 1306fa3d789dSPierre van Houtryve /// "Predicate_foo" if from a pattern fragment "foo". 1307fa3d789dSPierre van Houtryve std::string TreePredicateFn::getFnName() const { 1308fa3d789dSPierre van Houtryve return "Predicate_" + PatFragRec->getRecord()->getName().str(); 1309fa3d789dSPierre van Houtryve } 1310fa3d789dSPierre van Houtryve 1311fa3d789dSPierre van Houtryve /// getCodeToRunOnSDNode - Return the code for the function body that 1312fa3d789dSPierre van Houtryve /// evaluates this predicate. The argument is expected to be in "Node", 1313fa3d789dSPierre van Houtryve /// not N. This handles casting and conversion to a concrete node type as 1314fa3d789dSPierre van Houtryve /// appropriate. 1315fa3d789dSPierre van Houtryve std::string TreePredicateFn::getCodeToRunOnSDNode() const { 1316fa3d789dSPierre van Houtryve // Handle immediate predicates first. 1317fa3d789dSPierre van Houtryve std::string ImmCode = getImmCode(); 1318fa3d789dSPierre van Houtryve if (!ImmCode.empty()) { 1319fa3d789dSPierre van Houtryve if (isLoad()) 1320fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 1321fa3d789dSPierre van Houtryve "IsLoad cannot be used with ImmLeaf or its subclasses"); 1322fa3d789dSPierre van Houtryve if (isStore()) 1323fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 1324fa3d789dSPierre van Houtryve "IsStore cannot be used with ImmLeaf or its subclasses"); 1325fa3d789dSPierre van Houtryve if (isUnindexed()) 1326fa3d789dSPierre van Houtryve PrintFatalError( 1327fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1328fa3d789dSPierre van Houtryve "IsUnindexed cannot be used with ImmLeaf or its subclasses"); 1329fa3d789dSPierre van Houtryve if (isNonExtLoad()) 1330fa3d789dSPierre van Houtryve PrintFatalError( 1331fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1332fa3d789dSPierre van Houtryve "IsNonExtLoad cannot be used with ImmLeaf or its subclasses"); 1333fa3d789dSPierre van Houtryve if (isAnyExtLoad()) 1334fa3d789dSPierre van Houtryve PrintFatalError( 1335fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1336fa3d789dSPierre van Houtryve "IsAnyExtLoad cannot be used with ImmLeaf or its subclasses"); 1337fa3d789dSPierre van Houtryve if (isSignExtLoad()) 1338fa3d789dSPierre van Houtryve PrintFatalError( 1339fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1340fa3d789dSPierre van Houtryve "IsSignExtLoad cannot be used with ImmLeaf or its subclasses"); 1341fa3d789dSPierre van Houtryve if (isZeroExtLoad()) 1342fa3d789dSPierre van Houtryve PrintFatalError( 1343fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1344fa3d789dSPierre van Houtryve "IsZeroExtLoad cannot be used with ImmLeaf or its subclasses"); 1345fa3d789dSPierre van Houtryve if (isNonTruncStore()) 1346fa3d789dSPierre van Houtryve PrintFatalError( 1347fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1348fa3d789dSPierre van Houtryve "IsNonTruncStore cannot be used with ImmLeaf or its subclasses"); 1349fa3d789dSPierre van Houtryve if (isTruncStore()) 1350fa3d789dSPierre van Houtryve PrintFatalError( 1351fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1352fa3d789dSPierre van Houtryve "IsTruncStore cannot be used with ImmLeaf or its subclasses"); 1353fa3d789dSPierre van Houtryve if (getMemoryVT()) 1354fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 1355fa3d789dSPierre van Houtryve "MemoryVT cannot be used with ImmLeaf or its subclasses"); 1356fa3d789dSPierre van Houtryve if (getScalarMemoryVT()) 1357fa3d789dSPierre van Houtryve PrintFatalError( 1358fa3d789dSPierre van Houtryve getOrigPatFragRecord()->getRecord()->getLoc(), 1359fa3d789dSPierre van Houtryve "ScalarMemoryVT cannot be used with ImmLeaf or its subclasses"); 1360fa3d789dSPierre van Houtryve 1361fa3d789dSPierre van Houtryve std::string Result = (" " + getImmType() + " Imm = ").str(); 1362fa3d789dSPierre van Houtryve if (immCodeUsesAPFloat()) 1363fa3d789dSPierre van Houtryve Result += "cast<ConstantFPSDNode>(Node)->getValueAPF();\n"; 1364fa3d789dSPierre van Houtryve else if (immCodeUsesAPInt()) 1365fa3d789dSPierre van Houtryve Result += "Node->getAsAPIntVal();\n"; 1366fa3d789dSPierre van Houtryve else 1367fa3d789dSPierre van Houtryve Result += "cast<ConstantSDNode>(Node)->getSExtValue();\n"; 1368fa3d789dSPierre van Houtryve return Result + ImmCode; 1369fa3d789dSPierre van Houtryve } 1370fa3d789dSPierre van Houtryve 1371fa3d789dSPierre van Houtryve // Handle arbitrary node predicates. 1372fa3d789dSPierre van Houtryve assert(hasPredCode() && "Don't have any predicate code!"); 1373fa3d789dSPierre van Houtryve 1374fa3d789dSPierre van Houtryve // If this is using PatFrags, there are multiple trees to search. They should 1375fa3d789dSPierre van Houtryve // all have the same class. FIXME: Is there a way to find a common 1376fa3d789dSPierre van Houtryve // superclass? 1377fa3d789dSPierre van Houtryve StringRef ClassName; 1378fa3d789dSPierre van Houtryve for (const auto &Tree : PatFragRec->getTrees()) { 1379fa3d789dSPierre van Houtryve StringRef TreeClassName; 1380fa3d789dSPierre van Houtryve if (Tree->isLeaf()) 1381fa3d789dSPierre van Houtryve TreeClassName = "SDNode"; 1382fa3d789dSPierre van Houtryve else { 138337865681SRahul Joshi const Record *Op = Tree->getOperator(); 1384fa3d789dSPierre van Houtryve const SDNodeInfo &Info = PatFragRec->getDAGPatterns().getSDNodeInfo(Op); 1385fa3d789dSPierre van Houtryve TreeClassName = Info.getSDClassName(); 1386fa3d789dSPierre van Houtryve } 1387fa3d789dSPierre van Houtryve 1388fa3d789dSPierre van Houtryve if (ClassName.empty()) 1389fa3d789dSPierre van Houtryve ClassName = TreeClassName; 1390fa3d789dSPierre van Houtryve else if (ClassName != TreeClassName) { 1391fa3d789dSPierre van Houtryve PrintFatalError(getOrigPatFragRecord()->getRecord()->getLoc(), 1392fa3d789dSPierre van Houtryve "PatFrags trees do not have consistent class"); 1393fa3d789dSPierre van Houtryve } 1394fa3d789dSPierre van Houtryve } 1395fa3d789dSPierre van Houtryve 1396fa3d789dSPierre van Houtryve std::string Result; 1397fa3d789dSPierre van Houtryve if (ClassName == "SDNode") 1398fa3d789dSPierre van Houtryve Result = " SDNode *N = Node;\n"; 1399fa3d789dSPierre van Houtryve else 1400fa3d789dSPierre van Houtryve Result = " auto *N = cast<" + ClassName.str() + ">(Node);\n"; 1401fa3d789dSPierre van Houtryve 1402fa3d789dSPierre van Houtryve return (Twine(Result) + " (void)N;\n" + getPredCode()).str(); 1403fa3d789dSPierre van Houtryve } 1404fa3d789dSPierre van Houtryve 1405fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 1406fa3d789dSPierre van Houtryve // PatternToMatch implementation 1407fa3d789dSPierre van Houtryve // 1408fa3d789dSPierre van Houtryve 1409fa3d789dSPierre van Houtryve static bool isImmAllOnesAllZerosMatch(const TreePatternNode &P) { 1410fa3d789dSPierre van Houtryve if (!P.isLeaf()) 1411fa3d789dSPierre van Houtryve return false; 14123138eb50SRahul Joshi const DefInit *DI = dyn_cast<DefInit>(P.getLeafValue()); 1413fa3d789dSPierre van Houtryve if (!DI) 1414fa3d789dSPierre van Houtryve return false; 1415fa3d789dSPierre van Houtryve 14163138eb50SRahul Joshi const Record *R = DI->getDef(); 1417fa3d789dSPierre van Houtryve return R->getName() == "immAllOnesV" || R->getName() == "immAllZerosV"; 1418fa3d789dSPierre van Houtryve } 1419fa3d789dSPierre van Houtryve 1420fa3d789dSPierre van Houtryve /// getPatternSize - Return the 'size' of this pattern. We want to match large 1421fa3d789dSPierre van Houtryve /// patterns before small ones. This is used to determine the size of a 1422fa3d789dSPierre van Houtryve /// pattern. 1423fa3d789dSPierre van Houtryve static unsigned getPatternSize(const TreePatternNode &P, 1424fa3d789dSPierre van Houtryve const CodeGenDAGPatterns &CGP) { 1425fa3d789dSPierre van Houtryve unsigned Size = 3; // The node itself. 1426fa3d789dSPierre van Houtryve // If the root node is a ConstantSDNode, increases its size. 1427fa3d789dSPierre van Houtryve // e.g. (set R32:$dst, 0). 1428fa3d789dSPierre van Houtryve if (P.isLeaf() && isa<IntInit>(P.getLeafValue())) 1429fa3d789dSPierre van Houtryve Size += 2; 1430fa3d789dSPierre van Houtryve 1431fa3d789dSPierre van Houtryve if (const ComplexPattern *AM = P.getComplexPatternInfo(CGP)) { 1432fa3d789dSPierre van Houtryve Size += AM->getComplexity(); 1433fa3d789dSPierre van Houtryve // We don't want to count any children twice, so return early. 1434fa3d789dSPierre van Houtryve return Size; 1435fa3d789dSPierre van Houtryve } 1436fa3d789dSPierre van Houtryve 1437fa3d789dSPierre van Houtryve // If this node has some predicate function that must match, it adds to the 1438fa3d789dSPierre van Houtryve // complexity of this node. 1439fa3d789dSPierre van Houtryve if (!P.getPredicateCalls().empty()) 1440fa3d789dSPierre van Houtryve ++Size; 1441fa3d789dSPierre van Houtryve 1442fa3d789dSPierre van Houtryve // Count children in the count if they are also nodes. 1443d1f51c67SSergei Barannikov for (const TreePatternNode &Child : P.children()) { 1444fa3d789dSPierre van Houtryve if (!Child.isLeaf() && Child.getNumTypes()) { 1445fa3d789dSPierre van Houtryve const TypeSetByHwMode &T0 = Child.getExtType(0); 1446fa3d789dSPierre van Houtryve // At this point, all variable type sets should be simple, i.e. only 1447fa3d789dSPierre van Houtryve // have a default mode. 1448fa3d789dSPierre van Houtryve if (T0.getMachineValueType() != MVT::Other) { 1449fa3d789dSPierre van Houtryve Size += getPatternSize(Child, CGP); 1450fa3d789dSPierre van Houtryve continue; 1451fa3d789dSPierre van Houtryve } 1452fa3d789dSPierre van Houtryve } 1453fa3d789dSPierre van Houtryve if (Child.isLeaf()) { 1454fa3d789dSPierre van Houtryve if (isa<IntInit>(Child.getLeafValue())) 1455fa3d789dSPierre van Houtryve Size += 5; // Matches a ConstantSDNode (+3) and a specific value (+2). 1456fa3d789dSPierre van Houtryve else if (Child.getComplexPatternInfo(CGP)) 1457fa3d789dSPierre van Houtryve Size += getPatternSize(Child, CGP); 1458fa3d789dSPierre van Houtryve else if (isImmAllOnesAllZerosMatch(Child)) 1459fa3d789dSPierre van Houtryve Size += 4; // Matches a build_vector(+3) and a predicate (+1). 1460fa3d789dSPierre van Houtryve else if (!Child.getPredicateCalls().empty()) 1461fa3d789dSPierre van Houtryve ++Size; 1462fa3d789dSPierre van Houtryve } 1463fa3d789dSPierre van Houtryve } 1464fa3d789dSPierre van Houtryve 1465fa3d789dSPierre van Houtryve return Size; 1466fa3d789dSPierre van Houtryve } 1467fa3d789dSPierre van Houtryve 1468fa3d789dSPierre van Houtryve /// Compute the complexity metric for the input pattern. This roughly 1469fa3d789dSPierre van Houtryve /// corresponds to the number of nodes that are covered. 1470fa3d789dSPierre van Houtryve int PatternToMatch::getPatternComplexity(const CodeGenDAGPatterns &CGP) const { 1471fa3d789dSPierre van Houtryve return getPatternSize(getSrcPattern(), CGP) + getAddedComplexity(); 1472fa3d789dSPierre van Houtryve } 1473fa3d789dSPierre van Houtryve 1474fa3d789dSPierre van Houtryve void PatternToMatch::getPredicateRecords( 14753138eb50SRahul Joshi SmallVectorImpl<const Record *> &PredicateRecs) const { 14763138eb50SRahul Joshi for (const Init *I : Predicates->getValues()) { 14773138eb50SRahul Joshi if (const DefInit *Pred = dyn_cast<DefInit>(I)) { 14783138eb50SRahul Joshi const Record *Def = Pred->getDef(); 1479fa3d789dSPierre van Houtryve if (!Def->isSubClassOf("Predicate")) { 1480fa3d789dSPierre van Houtryve #ifndef NDEBUG 1481fa3d789dSPierre van Houtryve Def->dump(); 1482fa3d789dSPierre van Houtryve #endif 1483fa3d789dSPierre van Houtryve llvm_unreachable("Unknown predicate type!"); 1484fa3d789dSPierre van Houtryve } 1485fa3d789dSPierre van Houtryve PredicateRecs.push_back(Def); 1486fa3d789dSPierre van Houtryve } 1487fa3d789dSPierre van Houtryve } 1488fa3d789dSPierre van Houtryve // Sort so that different orders get canonicalized to the same string. 1489fa3d789dSPierre van Houtryve llvm::sort(PredicateRecs, LessRecord()); 1490fa3d789dSPierre van Houtryve // Remove duplicate predicates. 1491d9293519SKazu Hirata PredicateRecs.erase(llvm::unique(PredicateRecs), PredicateRecs.end()); 1492fa3d789dSPierre van Houtryve } 1493fa3d789dSPierre van Houtryve 1494fa3d789dSPierre van Houtryve /// getPredicateCheck - Return a single string containing all of this 1495fa3d789dSPierre van Houtryve /// pattern's predicates concatenated with "&&" operators. 1496fa3d789dSPierre van Houtryve /// 1497fa3d789dSPierre van Houtryve std::string PatternToMatch::getPredicateCheck() const { 14983138eb50SRahul Joshi SmallVector<const Record *, 4> PredicateRecs; 1499fa3d789dSPierre van Houtryve getPredicateRecords(PredicateRecs); 1500fa3d789dSPierre van Houtryve 1501fa3d789dSPierre van Houtryve SmallString<128> PredicateCheck; 1502fa3d789dSPierre van Houtryve raw_svector_ostream OS(PredicateCheck); 1503fa3d789dSPierre van Houtryve ListSeparator LS(" && "); 15043138eb50SRahul Joshi for (const Record *Pred : PredicateRecs) { 1505fa3d789dSPierre van Houtryve StringRef CondString = Pred->getValueAsString("CondString"); 1506fa3d789dSPierre van Houtryve if (CondString.empty()) 1507fa3d789dSPierre van Houtryve continue; 1508fa3d789dSPierre van Houtryve OS << LS << '(' << CondString << ')'; 1509fa3d789dSPierre van Houtryve } 1510fa3d789dSPierre van Houtryve 1511fa3d789dSPierre van Houtryve if (!HwModeFeatures.empty()) 1512fa3d789dSPierre van Houtryve OS << LS << HwModeFeatures; 1513fa3d789dSPierre van Houtryve 1514fa3d789dSPierre van Houtryve return std::string(PredicateCheck); 1515fa3d789dSPierre van Houtryve } 1516fa3d789dSPierre van Houtryve 1517fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 1518fa3d789dSPierre van Houtryve // SDTypeConstraint implementation 1519fa3d789dSPierre van Houtryve // 1520fa3d789dSPierre van Houtryve 152187e8b530SRahul Joshi SDTypeConstraint::SDTypeConstraint(const Record *R, const CodeGenHwModes &CGH) { 1522fa3d789dSPierre van Houtryve OperandNo = R->getValueAsInt("OperandNum"); 1523fa3d789dSPierre van Houtryve 1524fa3d789dSPierre van Houtryve if (R->isSubClassOf("SDTCisVT")) { 1525fa3d789dSPierre van Houtryve ConstraintType = SDTCisVT; 1526fa3d789dSPierre van Houtryve VVT = getValueTypeByHwMode(R->getValueAsDef("VT"), CGH); 1527fa3d789dSPierre van Houtryve for (const auto &P : VVT) 1528fa3d789dSPierre van Houtryve if (P.second == MVT::isVoid) 1529fa3d789dSPierre van Houtryve PrintFatalError(R->getLoc(), "Cannot use 'Void' as type to SDTCisVT"); 1530fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisPtrTy")) { 1531fa3d789dSPierre van Houtryve ConstraintType = SDTCisPtrTy; 1532fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisInt")) { 1533fa3d789dSPierre van Houtryve ConstraintType = SDTCisInt; 1534fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisFP")) { 1535fa3d789dSPierre van Houtryve ConstraintType = SDTCisFP; 1536fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisVec")) { 1537fa3d789dSPierre van Houtryve ConstraintType = SDTCisVec; 1538fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisSameAs")) { 1539fa3d789dSPierre van Houtryve ConstraintType = SDTCisSameAs; 1540*6aeffcdbSSergei Barannikov OtherOperandNo = R->getValueAsInt("OtherOperandNum"); 1541fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisVTSmallerThanOp")) { 1542fa3d789dSPierre van Houtryve ConstraintType = SDTCisVTSmallerThanOp; 1543*6aeffcdbSSergei Barannikov OtherOperandNo = R->getValueAsInt("OtherOperandNum"); 1544fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisOpSmallerThanOp")) { 1545fa3d789dSPierre van Houtryve ConstraintType = SDTCisOpSmallerThanOp; 1546*6aeffcdbSSergei Barannikov OtherOperandNo = R->getValueAsInt("BigOperandNum"); 1547fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisEltOfVec")) { 1548fa3d789dSPierre van Houtryve ConstraintType = SDTCisEltOfVec; 1549*6aeffcdbSSergei Barannikov OtherOperandNo = R->getValueAsInt("OtherOpNum"); 1550fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisSubVecOfVec")) { 1551fa3d789dSPierre van Houtryve ConstraintType = SDTCisSubVecOfVec; 1552*6aeffcdbSSergei Barannikov OtherOperandNo = R->getValueAsInt("OtherOpNum"); 1553fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCVecEltisVT")) { 1554fa3d789dSPierre van Houtryve ConstraintType = SDTCVecEltisVT; 1555fa3d789dSPierre van Houtryve VVT = getValueTypeByHwMode(R->getValueAsDef("VT"), CGH); 1556fa3d789dSPierre van Houtryve for (const auto &P : VVT) { 1557fa3d789dSPierre van Houtryve MVT T = P.second; 1558fa3d789dSPierre van Houtryve if (T.isVector()) 1559fa3d789dSPierre van Houtryve PrintFatalError(R->getLoc(), 1560fa3d789dSPierre van Houtryve "Cannot use vector type as SDTCVecEltisVT"); 1561fa3d789dSPierre van Houtryve if (!T.isInteger() && !T.isFloatingPoint()) 1562fa3d789dSPierre van Houtryve PrintFatalError(R->getLoc(), "Must use integer or floating point type " 1563fa3d789dSPierre van Houtryve "as SDTCVecEltisVT"); 1564fa3d789dSPierre van Houtryve } 1565fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisSameNumEltsAs")) { 1566fa3d789dSPierre van Houtryve ConstraintType = SDTCisSameNumEltsAs; 1567*6aeffcdbSSergei Barannikov OtherOperandNo = R->getValueAsInt("OtherOperandNum"); 1568fa3d789dSPierre van Houtryve } else if (R->isSubClassOf("SDTCisSameSizeAs")) { 1569fa3d789dSPierre van Houtryve ConstraintType = SDTCisSameSizeAs; 1570*6aeffcdbSSergei Barannikov OtherOperandNo = R->getValueAsInt("OtherOperandNum"); 1571fa3d789dSPierre van Houtryve } else { 1572fa3d789dSPierre van Houtryve PrintFatalError(R->getLoc(), 1573fa3d789dSPierre van Houtryve "Unrecognized SDTypeConstraint '" + R->getName() + "'!\n"); 1574fa3d789dSPierre van Houtryve } 1575fa3d789dSPierre van Houtryve } 1576fa3d789dSPierre van Houtryve 1577fa3d789dSPierre van Houtryve /// getOperandNum - Return the node corresponding to operand #OpNo in tree 1578fa3d789dSPierre van Houtryve /// N, and the result number in ResNo. 1579fa3d789dSPierre van Houtryve static TreePatternNode &getOperandNum(unsigned OpNo, TreePatternNode &N, 1580fa3d789dSPierre van Houtryve const SDNodeInfo &NodeInfo, 1581fa3d789dSPierre van Houtryve unsigned &ResNo) { 1582fa3d789dSPierre van Houtryve unsigned NumResults = NodeInfo.getNumResults(); 1583fa3d789dSPierre van Houtryve if (OpNo < NumResults) { 1584fa3d789dSPierre van Houtryve ResNo = OpNo; 1585fa3d789dSPierre van Houtryve return N; 1586fa3d789dSPierre van Houtryve } 1587fa3d789dSPierre van Houtryve 1588fa3d789dSPierre van Houtryve OpNo -= NumResults; 1589fa3d789dSPierre van Houtryve 1590fa3d789dSPierre van Houtryve if (OpNo >= N.getNumChildren()) { 15910ceffd36SRahul Joshi PrintFatalError([&N, OpNo, NumResults](raw_ostream &OS) { 15920ceffd36SRahul Joshi OS << "Invalid operand number in type constraint " << (OpNo + NumResults); 1593fa3d789dSPierre van Houtryve N.print(OS); 15940ceffd36SRahul Joshi }); 1595fa3d789dSPierre van Houtryve } 1596fa3d789dSPierre van Houtryve return N.getChild(OpNo); 1597fa3d789dSPierre van Houtryve } 1598fa3d789dSPierre van Houtryve 1599fa3d789dSPierre van Houtryve /// ApplyTypeConstraint - Given a node in a pattern, apply this type 1600fa3d789dSPierre van Houtryve /// constraint to the nodes operands. This returns true if it makes a 1601fa3d789dSPierre van Houtryve /// change, false otherwise. If a type contradiction is found, flag an error. 1602fa3d789dSPierre van Houtryve bool SDTypeConstraint::ApplyTypeConstraint(TreePatternNode &N, 1603fa3d789dSPierre van Houtryve const SDNodeInfo &NodeInfo, 1604fa3d789dSPierre van Houtryve TreePattern &TP) const { 1605fa3d789dSPierre van Houtryve if (TP.hasError()) 1606fa3d789dSPierre van Houtryve return false; 1607fa3d789dSPierre van Houtryve 1608fa3d789dSPierre van Houtryve unsigned ResNo = 0; // The result number being referenced. 1609fa3d789dSPierre van Houtryve TreePatternNode &NodeToApply = getOperandNum(OperandNo, N, NodeInfo, ResNo); 1610fa3d789dSPierre van Houtryve TypeInfer &TI = TP.getInfer(); 1611fa3d789dSPierre van Houtryve 1612fa3d789dSPierre van Houtryve switch (ConstraintType) { 1613fa3d789dSPierre van Houtryve case SDTCisVT: 1614fa3d789dSPierre van Houtryve // Operand must be a particular type. 1615fa3d789dSPierre van Houtryve return NodeToApply.UpdateNodeType(ResNo, VVT, TP); 1616fa3d789dSPierre van Houtryve case SDTCisPtrTy: 1617fa3d789dSPierre van Houtryve // Operand must be same as target pointer type. 1618fa3d789dSPierre van Houtryve return NodeToApply.UpdateNodeType(ResNo, MVT::iPTR, TP); 1619fa3d789dSPierre van Houtryve case SDTCisInt: 1620fa3d789dSPierre van Houtryve // Require it to be one of the legal integer VTs. 1621fa3d789dSPierre van Houtryve return TI.EnforceInteger(NodeToApply.getExtType(ResNo)); 1622fa3d789dSPierre van Houtryve case SDTCisFP: 1623fa3d789dSPierre van Houtryve // Require it to be one of the legal fp VTs. 1624fa3d789dSPierre van Houtryve return TI.EnforceFloatingPoint(NodeToApply.getExtType(ResNo)); 1625fa3d789dSPierre van Houtryve case SDTCisVec: 1626fa3d789dSPierre van Houtryve // Require it to be one of the legal vector VTs. 1627fa3d789dSPierre van Houtryve return TI.EnforceVector(NodeToApply.getExtType(ResNo)); 1628fa3d789dSPierre van Houtryve case SDTCisSameAs: { 1629fa3d789dSPierre van Houtryve unsigned OResNo = 0; 1630fa3d789dSPierre van Houtryve TreePatternNode &OtherNode = 1631*6aeffcdbSSergei Barannikov getOperandNum(OtherOperandNo, N, NodeInfo, OResNo); 1632fa3d789dSPierre van Houtryve return (int)NodeToApply.UpdateNodeType(ResNo, OtherNode.getExtType(OResNo), 1633fa3d789dSPierre van Houtryve TP) | 1634fa3d789dSPierre van Houtryve (int)OtherNode.UpdateNodeType(OResNo, NodeToApply.getExtType(ResNo), 1635fa3d789dSPierre van Houtryve TP); 1636fa3d789dSPierre van Houtryve } 1637fa3d789dSPierre van Houtryve case SDTCisVTSmallerThanOp: { 1638fa3d789dSPierre van Houtryve // The NodeToApply must be a leaf node that is a VT. OtherOperandNum must 1639fa3d789dSPierre van Houtryve // have an integer type that is smaller than the VT. 1640fa3d789dSPierre van Houtryve if (!NodeToApply.isLeaf() || !isa<DefInit>(NodeToApply.getLeafValue()) || 1641fa3d789dSPierre van Houtryve !cast<DefInit>(NodeToApply.getLeafValue()) 1642fa3d789dSPierre van Houtryve ->getDef() 1643fa3d789dSPierre van Houtryve ->isSubClassOf("ValueType")) { 1644fa3d789dSPierre van Houtryve TP.error(N.getOperator()->getName() + " expects a VT operand!"); 1645fa3d789dSPierre van Houtryve return false; 1646fa3d789dSPierre van Houtryve } 16473138eb50SRahul Joshi const DefInit *DI = cast<DefInit>(NodeToApply.getLeafValue()); 1648fa3d789dSPierre van Houtryve const CodeGenTarget &T = TP.getDAGPatterns().getTargetInfo(); 1649fa3d789dSPierre van Houtryve auto VVT = getValueTypeByHwMode(DI->getDef(), T.getHwModes()); 1650fa3d789dSPierre van Houtryve TypeSetByHwMode TypeListTmp(VVT); 1651fa3d789dSPierre van Houtryve 1652fa3d789dSPierre van Houtryve unsigned OResNo = 0; 1653*6aeffcdbSSergei Barannikov TreePatternNode &OtherNode = 1654*6aeffcdbSSergei Barannikov getOperandNum(OtherOperandNo, N, NodeInfo, OResNo); 1655fa3d789dSPierre van Houtryve 1656fa3d789dSPierre van Houtryve return TI.EnforceSmallerThan(TypeListTmp, OtherNode.getExtType(OResNo), 1657fa3d789dSPierre van Houtryve /*SmallIsVT*/ true); 1658fa3d789dSPierre van Houtryve } 1659fa3d789dSPierre van Houtryve case SDTCisOpSmallerThanOp: { 1660fa3d789dSPierre van Houtryve unsigned BResNo = 0; 1661*6aeffcdbSSergei Barannikov TreePatternNode &BigOperand = 1662*6aeffcdbSSergei Barannikov getOperandNum(OtherOperandNo, N, NodeInfo, BResNo); 1663fa3d789dSPierre van Houtryve return TI.EnforceSmallerThan(NodeToApply.getExtType(ResNo), 1664fa3d789dSPierre van Houtryve BigOperand.getExtType(BResNo)); 1665fa3d789dSPierre van Houtryve } 1666fa3d789dSPierre van Houtryve case SDTCisEltOfVec: { 1667fa3d789dSPierre van Houtryve unsigned VResNo = 0; 1668*6aeffcdbSSergei Barannikov TreePatternNode &VecOperand = 1669*6aeffcdbSSergei Barannikov getOperandNum(OtherOperandNo, N, NodeInfo, VResNo); 1670fa3d789dSPierre van Houtryve // Filter vector types out of VecOperand that don't have the right element 1671fa3d789dSPierre van Houtryve // type. 1672fa3d789dSPierre van Houtryve return TI.EnforceVectorEltTypeIs(VecOperand.getExtType(VResNo), 1673fa3d789dSPierre van Houtryve NodeToApply.getExtType(ResNo)); 1674fa3d789dSPierre van Houtryve } 1675fa3d789dSPierre van Houtryve case SDTCisSubVecOfVec: { 1676fa3d789dSPierre van Houtryve unsigned VResNo = 0; 1677*6aeffcdbSSergei Barannikov TreePatternNode &BigVecOperand = 1678*6aeffcdbSSergei Barannikov getOperandNum(OtherOperandNo, N, NodeInfo, VResNo); 1679fa3d789dSPierre van Houtryve 1680fa3d789dSPierre van Houtryve // Filter vector types out of BigVecOperand that don't have the 1681fa3d789dSPierre van Houtryve // right subvector type. 1682fa3d789dSPierre van Houtryve return TI.EnforceVectorSubVectorTypeIs(BigVecOperand.getExtType(VResNo), 1683fa3d789dSPierre van Houtryve NodeToApply.getExtType(ResNo)); 1684fa3d789dSPierre van Houtryve } 1685fa3d789dSPierre van Houtryve case SDTCVecEltisVT: { 1686fa3d789dSPierre van Houtryve return TI.EnforceVectorEltTypeIs(NodeToApply.getExtType(ResNo), VVT); 1687fa3d789dSPierre van Houtryve } 1688fa3d789dSPierre van Houtryve case SDTCisSameNumEltsAs: { 1689fa3d789dSPierre van Houtryve unsigned OResNo = 0; 1690*6aeffcdbSSergei Barannikov TreePatternNode &OtherNode = 1691*6aeffcdbSSergei Barannikov getOperandNum(OtherOperandNo, N, NodeInfo, OResNo); 1692fa3d789dSPierre van Houtryve return TI.EnforceSameNumElts(OtherNode.getExtType(OResNo), 1693fa3d789dSPierre van Houtryve NodeToApply.getExtType(ResNo)); 1694fa3d789dSPierre van Houtryve } 1695fa3d789dSPierre van Houtryve case SDTCisSameSizeAs: { 1696fa3d789dSPierre van Houtryve unsigned OResNo = 0; 1697*6aeffcdbSSergei Barannikov TreePatternNode &OtherNode = 1698*6aeffcdbSSergei Barannikov getOperandNum(OtherOperandNo, N, NodeInfo, OResNo); 1699fa3d789dSPierre van Houtryve return TI.EnforceSameSize(OtherNode.getExtType(OResNo), 1700fa3d789dSPierre van Houtryve NodeToApply.getExtType(ResNo)); 1701fa3d789dSPierre van Houtryve } 1702fa3d789dSPierre van Houtryve } 1703fa3d789dSPierre van Houtryve llvm_unreachable("Invalid ConstraintType!"); 1704fa3d789dSPierre van Houtryve } 1705fa3d789dSPierre van Houtryve 1706*6aeffcdbSSergei Barannikov bool llvm::operator==(const SDTypeConstraint &LHS, 1707*6aeffcdbSSergei Barannikov const SDTypeConstraint &RHS) { 1708*6aeffcdbSSergei Barannikov if (std::tie(LHS.OperandNo, LHS.ConstraintType) != 1709*6aeffcdbSSergei Barannikov std::tie(RHS.OperandNo, RHS.ConstraintType)) 1710*6aeffcdbSSergei Barannikov return false; 1711*6aeffcdbSSergei Barannikov switch (LHS.ConstraintType) { 1712*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisVT: 1713*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCVecEltisVT: 1714*6aeffcdbSSergei Barannikov return LHS.VVT == RHS.VVT; 1715*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisPtrTy: 1716*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisInt: 1717*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisFP: 1718*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisVec: 1719*6aeffcdbSSergei Barannikov break; 1720*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisSameAs: 1721*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisVTSmallerThanOp: 1722*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisOpSmallerThanOp: 1723*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisEltOfVec: 1724*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisSubVecOfVec: 1725*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisSameNumEltsAs: 1726*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisSameSizeAs: 1727*6aeffcdbSSergei Barannikov return LHS.OtherOperandNo == RHS.OtherOperandNo; 1728*6aeffcdbSSergei Barannikov } 1729*6aeffcdbSSergei Barannikov return true; 1730*6aeffcdbSSergei Barannikov } 1731*6aeffcdbSSergei Barannikov 1732*6aeffcdbSSergei Barannikov bool llvm::operator<(const SDTypeConstraint &LHS, const SDTypeConstraint &RHS) { 1733*6aeffcdbSSergei Barannikov if (std::tie(LHS.OperandNo, LHS.ConstraintType) != 1734*6aeffcdbSSergei Barannikov std::tie(RHS.OperandNo, RHS.ConstraintType)) 1735*6aeffcdbSSergei Barannikov return std::tie(LHS.OperandNo, LHS.ConstraintType) < 1736*6aeffcdbSSergei Barannikov std::tie(RHS.OperandNo, RHS.ConstraintType); 1737*6aeffcdbSSergei Barannikov switch (LHS.ConstraintType) { 1738*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisVT: 1739*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCVecEltisVT: 1740*6aeffcdbSSergei Barannikov return LHS.VVT < RHS.VVT; 1741*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisPtrTy: 1742*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisInt: 1743*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisFP: 1744*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisVec: 1745*6aeffcdbSSergei Barannikov break; 1746*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisSameAs: 1747*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisVTSmallerThanOp: 1748*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisOpSmallerThanOp: 1749*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisEltOfVec: 1750*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisSubVecOfVec: 1751*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisSameNumEltsAs: 1752*6aeffcdbSSergei Barannikov case SDTypeConstraint::SDTCisSameSizeAs: 1753*6aeffcdbSSergei Barannikov return LHS.OtherOperandNo < RHS.OtherOperandNo; 1754*6aeffcdbSSergei Barannikov } 1755*6aeffcdbSSergei Barannikov return false; 1756*6aeffcdbSSergei Barannikov } 1757*6aeffcdbSSergei Barannikov 1758fa3d789dSPierre van Houtryve // Update the node type to match an instruction operand or result as specified 1759fa3d789dSPierre van Houtryve // in the ins or outs lists on the instruction definition. Return true if the 1760fa3d789dSPierre van Houtryve // type was actually changed. 1761bdf02249SRahul Joshi bool TreePatternNode::UpdateNodeTypeFromInst(unsigned ResNo, 1762bdf02249SRahul Joshi const Record *Operand, 1763fa3d789dSPierre van Houtryve TreePattern &TP) { 1764fa3d789dSPierre van Houtryve // The 'unknown' operand indicates that types should be inferred from the 1765fa3d789dSPierre van Houtryve // context. 1766fa3d789dSPierre van Houtryve if (Operand->isSubClassOf("unknown_class")) 1767fa3d789dSPierre van Houtryve return false; 1768fa3d789dSPierre van Houtryve 1769fa3d789dSPierre van Houtryve // The Operand class specifies a type directly. 1770fa3d789dSPierre van Houtryve if (Operand->isSubClassOf("Operand")) { 17713138eb50SRahul Joshi const Record *R = Operand->getValueAsDef("Type"); 1772fa3d789dSPierre van Houtryve const CodeGenTarget &T = TP.getDAGPatterns().getTargetInfo(); 1773fa3d789dSPierre van Houtryve return UpdateNodeType(ResNo, getValueTypeByHwMode(R, T.getHwModes()), TP); 1774fa3d789dSPierre van Houtryve } 1775fa3d789dSPierre van Houtryve 1776fa3d789dSPierre van Houtryve // PointerLikeRegClass has a type that is determined at runtime. 1777fa3d789dSPierre van Houtryve if (Operand->isSubClassOf("PointerLikeRegClass")) 1778fa3d789dSPierre van Houtryve return UpdateNodeType(ResNo, MVT::iPTR, TP); 1779fa3d789dSPierre van Houtryve 1780fa3d789dSPierre van Houtryve // Both RegisterClass and RegisterOperand operands derive their types from a 1781fa3d789dSPierre van Houtryve // register class def. 1782bdf02249SRahul Joshi const Record *RC = nullptr; 1783fa3d789dSPierre van Houtryve if (Operand->isSubClassOf("RegisterClass")) 1784fa3d789dSPierre van Houtryve RC = Operand; 1785fa3d789dSPierre van Houtryve else if (Operand->isSubClassOf("RegisterOperand")) 1786fa3d789dSPierre van Houtryve RC = Operand->getValueAsDef("RegClass"); 1787fa3d789dSPierre van Houtryve 1788fa3d789dSPierre van Houtryve assert(RC && "Unknown operand type"); 1789fa3d789dSPierre van Houtryve CodeGenTarget &Tgt = TP.getDAGPatterns().getTargetInfo(); 1790fa3d789dSPierre van Houtryve return UpdateNodeType(ResNo, Tgt.getRegisterClass(RC).getValueTypes(), TP); 1791fa3d789dSPierre van Houtryve } 1792fa3d789dSPierre van Houtryve 1793fa3d789dSPierre van Houtryve bool TreePatternNode::ContainsUnresolvedType(TreePattern &TP) const { 1794fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Types.size(); i != e; ++i) 1795fa3d789dSPierre van Houtryve if (!TP.getInfer().isConcrete(Types[i], true)) 1796fa3d789dSPierre van Houtryve return true; 1797d1f51c67SSergei Barannikov for (const TreePatternNode &Child : children()) 1798d1f51c67SSergei Barannikov if (Child.ContainsUnresolvedType(TP)) 1799fa3d789dSPierre van Houtryve return true; 1800fa3d789dSPierre van Houtryve return false; 1801fa3d789dSPierre van Houtryve } 1802fa3d789dSPierre van Houtryve 1803fa3d789dSPierre van Houtryve bool TreePatternNode::hasProperTypeByHwMode() const { 1804fa3d789dSPierre van Houtryve for (const TypeSetByHwMode &S : Types) 1805fa3d789dSPierre van Houtryve if (!S.isSimple()) 1806fa3d789dSPierre van Houtryve return true; 1807fa3d789dSPierre van Houtryve for (const TreePatternNodePtr &C : Children) 1808fa3d789dSPierre van Houtryve if (C->hasProperTypeByHwMode()) 1809fa3d789dSPierre van Houtryve return true; 1810fa3d789dSPierre van Houtryve return false; 1811fa3d789dSPierre van Houtryve } 1812fa3d789dSPierre van Houtryve 1813fa3d789dSPierre van Houtryve bool TreePatternNode::hasPossibleType() const { 1814fa3d789dSPierre van Houtryve for (const TypeSetByHwMode &S : Types) 1815fa3d789dSPierre van Houtryve if (!S.isPossible()) 1816fa3d789dSPierre van Houtryve return false; 1817fa3d789dSPierre van Houtryve for (const TreePatternNodePtr &C : Children) 1818fa3d789dSPierre van Houtryve if (!C->hasPossibleType()) 1819fa3d789dSPierre van Houtryve return false; 1820fa3d789dSPierre van Houtryve return true; 1821fa3d789dSPierre van Houtryve } 1822fa3d789dSPierre van Houtryve 1823fa3d789dSPierre van Houtryve bool TreePatternNode::setDefaultMode(unsigned Mode) { 1824fa3d789dSPierre van Houtryve for (TypeSetByHwMode &S : Types) { 1825fa3d789dSPierre van Houtryve S.makeSimple(Mode); 1826fa3d789dSPierre van Houtryve // Check if the selected mode had a type conflict. 1827fa3d789dSPierre van Houtryve if (S.get(DefaultMode).empty()) 1828fa3d789dSPierre van Houtryve return false; 1829fa3d789dSPierre van Houtryve } 1830fa3d789dSPierre van Houtryve for (const TreePatternNodePtr &C : Children) 1831fa3d789dSPierre van Houtryve if (!C->setDefaultMode(Mode)) 1832fa3d789dSPierre van Houtryve return false; 1833fa3d789dSPierre van Houtryve return true; 1834fa3d789dSPierre van Houtryve } 1835fa3d789dSPierre van Houtryve 1836fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 1837fa3d789dSPierre van Houtryve // SDNodeInfo implementation 1838fa3d789dSPierre van Houtryve // 183987e8b530SRahul Joshi SDNodeInfo::SDNodeInfo(const Record *R, const CodeGenHwModes &CGH) : Def(R) { 1840fa3d789dSPierre van Houtryve EnumName = R->getValueAsString("Opcode"); 1841fa3d789dSPierre van Houtryve SDClassName = R->getValueAsString("SDClass"); 18423138eb50SRahul Joshi const Record *TypeProfile = R->getValueAsDef("TypeProfile"); 1843fa3d789dSPierre van Houtryve NumResults = TypeProfile->getValueAsInt("NumResults"); 1844fa3d789dSPierre van Houtryve NumOperands = TypeProfile->getValueAsInt("NumOperands"); 1845fa3d789dSPierre van Houtryve 1846fa3d789dSPierre van Houtryve // Parse the properties. 1847fa3d789dSPierre van Houtryve Properties = parseSDPatternOperatorProperties(R); 1848*6aeffcdbSSergei Barannikov IsStrictFP = R->getValueAsBit("IsStrictFP"); 1849*6aeffcdbSSergei Barannikov 1850*6aeffcdbSSergei Barannikov std::optional<int64_t> MaybeTSFlags = 1851*6aeffcdbSSergei Barannikov R->getValueAsBitsInit("TSFlags")->convertInitializerToInt(); 1852*6aeffcdbSSergei Barannikov if (!MaybeTSFlags) 1853*6aeffcdbSSergei Barannikov PrintFatalError(R->getLoc(), "Invalid TSFlags"); 1854*6aeffcdbSSergei Barannikov assert(isUInt<32>(*MaybeTSFlags) && "TSFlags bit width out of sync"); 1855*6aeffcdbSSergei Barannikov TSFlags = *MaybeTSFlags; 1856fa3d789dSPierre van Houtryve 1857fa3d789dSPierre van Houtryve // Parse the type constraints. 18583138eb50SRahul Joshi for (const Record *R : TypeProfile->getValueAsListOfDefs("Constraints")) 1859fa3d789dSPierre van Houtryve TypeConstraints.emplace_back(R, CGH); 1860fa3d789dSPierre van Houtryve } 1861fa3d789dSPierre van Houtryve 1862fa3d789dSPierre van Houtryve /// getKnownType - If the type constraints on this node imply a fixed type 1863fa3d789dSPierre van Houtryve /// (e.g. all stores return void, etc), then return it as an 1864fa3d789dSPierre van Houtryve /// MVT::SimpleValueType. Otherwise, return EEVT::Other. 1865fa3d789dSPierre van Houtryve MVT::SimpleValueType SDNodeInfo::getKnownType(unsigned ResNo) const { 1866fa3d789dSPierre van Houtryve unsigned NumResults = getNumResults(); 1867fa3d789dSPierre van Houtryve assert(NumResults <= 1 && 1868fa3d789dSPierre van Houtryve "We only work with nodes with zero or one result so far!"); 1869fa3d789dSPierre van Houtryve assert(ResNo == 0 && "Only handles single result nodes so far"); 1870fa3d789dSPierre van Houtryve 1871fa3d789dSPierre van Houtryve for (const SDTypeConstraint &Constraint : TypeConstraints) { 1872fa3d789dSPierre van Houtryve // Make sure that this applies to the correct node result. 1873fa3d789dSPierre van Houtryve if (Constraint.OperandNo >= NumResults) // FIXME: need value # 1874fa3d789dSPierre van Houtryve continue; 1875fa3d789dSPierre van Houtryve 1876fa3d789dSPierre van Houtryve switch (Constraint.ConstraintType) { 1877fa3d789dSPierre van Houtryve default: 1878fa3d789dSPierre van Houtryve break; 1879fa3d789dSPierre van Houtryve case SDTypeConstraint::SDTCisVT: 1880fa3d789dSPierre van Houtryve if (Constraint.VVT.isSimple()) 1881fa3d789dSPierre van Houtryve return Constraint.VVT.getSimple().SimpleTy; 1882fa3d789dSPierre van Houtryve break; 1883fa3d789dSPierre van Houtryve case SDTypeConstraint::SDTCisPtrTy: 1884fa3d789dSPierre van Houtryve return MVT::iPTR; 1885fa3d789dSPierre van Houtryve } 1886fa3d789dSPierre van Houtryve } 1887fa3d789dSPierre van Houtryve return MVT::Other; 1888fa3d789dSPierre van Houtryve } 1889fa3d789dSPierre van Houtryve 1890fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 1891fa3d789dSPierre van Houtryve // TreePatternNode implementation 1892fa3d789dSPierre van Houtryve // 1893fa3d789dSPierre van Houtryve 189437865681SRahul Joshi static unsigned GetNumNodeResults(const Record *Operator, 189537865681SRahul Joshi CodeGenDAGPatterns &CDP) { 1896501a5834SSergei Barannikov if (Operator->getName() == "set") 1897fa3d789dSPierre van Houtryve return 0; // All return nothing. 1898fa3d789dSPierre van Houtryve 1899fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("Intrinsic")) 1900fa3d789dSPierre van Houtryve return CDP.getIntrinsic(Operator).IS.RetTys.size(); 1901fa3d789dSPierre van Houtryve 1902fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("SDNode")) 1903fa3d789dSPierre van Houtryve return CDP.getSDNodeInfo(Operator).getNumResults(); 1904fa3d789dSPierre van Houtryve 1905fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("PatFrags")) { 1906fa3d789dSPierre van Houtryve // If we've already parsed this pattern fragment, get it. Otherwise, handle 1907fa3d789dSPierre van Houtryve // the forward reference case where one pattern fragment references another 1908fa3d789dSPierre van Houtryve // before it is processed. 1909fa3d789dSPierre van Houtryve if (TreePattern *PFRec = CDP.getPatternFragmentIfRead(Operator)) { 1910fa3d789dSPierre van Houtryve // The number of results of a fragment with alternative records is the 1911fa3d789dSPierre van Houtryve // maximum number of results across all alternatives. 1912fa3d789dSPierre van Houtryve unsigned NumResults = 0; 1913fa3d789dSPierre van Houtryve for (const auto &T : PFRec->getTrees()) 1914fa3d789dSPierre van Houtryve NumResults = std::max(NumResults, T->getNumTypes()); 1915fa3d789dSPierre van Houtryve return NumResults; 1916fa3d789dSPierre van Houtryve } 1917fa3d789dSPierre van Houtryve 19183138eb50SRahul Joshi const ListInit *LI = Operator->getValueAsListInit("Fragments"); 1919fa3d789dSPierre van Houtryve assert(LI && "Invalid Fragment"); 1920fa3d789dSPierre van Houtryve unsigned NumResults = 0; 19213138eb50SRahul Joshi for (const Init *I : LI->getValues()) { 19223138eb50SRahul Joshi const Record *Op = nullptr; 19233138eb50SRahul Joshi if (const DagInit *Dag = dyn_cast<DagInit>(I)) 19243138eb50SRahul Joshi if (const DefInit *DI = dyn_cast<DefInit>(Dag->getOperator())) 1925fa3d789dSPierre van Houtryve Op = DI->getDef(); 1926fa3d789dSPierre van Houtryve assert(Op && "Invalid Fragment"); 1927fa3d789dSPierre van Houtryve NumResults = std::max(NumResults, GetNumNodeResults(Op, CDP)); 1928fa3d789dSPierre van Houtryve } 1929fa3d789dSPierre van Houtryve return NumResults; 1930fa3d789dSPierre van Houtryve } 1931fa3d789dSPierre van Houtryve 1932fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("Instruction")) { 1933fa3d789dSPierre van Houtryve CodeGenInstruction &InstInfo = CDP.getTargetInfo().getInstruction(Operator); 1934fa3d789dSPierre van Houtryve 1935fa3d789dSPierre van Houtryve unsigned NumDefsToAdd = InstInfo.Operands.NumDefs; 1936fa3d789dSPierre van Houtryve 1937fa3d789dSPierre van Houtryve // Subtract any defaulted outputs. 1938fa3d789dSPierre van Houtryve for (unsigned i = 0; i != InstInfo.Operands.NumDefs; ++i) { 1939bdf02249SRahul Joshi const Record *OperandNode = InstInfo.Operands[i].Rec; 1940fa3d789dSPierre van Houtryve 1941fa3d789dSPierre van Houtryve if (OperandNode->isSubClassOf("OperandWithDefaultOps") && 1942fa3d789dSPierre van Houtryve !CDP.getDefaultOperand(OperandNode).DefaultOps.empty()) 1943fa3d789dSPierre van Houtryve --NumDefsToAdd; 1944fa3d789dSPierre van Houtryve } 1945fa3d789dSPierre van Houtryve 1946fa3d789dSPierre van Houtryve // Add on one implicit def if it has a resolvable type. 1947fa3d789dSPierre van Houtryve if (InstInfo.HasOneImplicitDefWithKnownVT(CDP.getTargetInfo()) != 1948fa3d789dSPierre van Houtryve MVT::Other) 1949fa3d789dSPierre van Houtryve ++NumDefsToAdd; 1950fa3d789dSPierre van Houtryve return NumDefsToAdd; 1951fa3d789dSPierre van Houtryve } 1952fa3d789dSPierre van Houtryve 1953fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("SDNodeXForm")) 1954fa3d789dSPierre van Houtryve return 1; // FIXME: Generalize SDNodeXForm 1955fa3d789dSPierre van Houtryve 1956fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("ValueType")) 1957fa3d789dSPierre van Houtryve return 1; // A type-cast of one result. 1958fa3d789dSPierre van Houtryve 1959fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("ComplexPattern")) 1960fa3d789dSPierre van Houtryve return 1; 1961fa3d789dSPierre van Houtryve 1962fa3d789dSPierre van Houtryve errs() << *Operator; 1963fa3d789dSPierre van Houtryve PrintFatalError("Unhandled node in GetNumNodeResults"); 1964fa3d789dSPierre van Houtryve } 1965fa3d789dSPierre van Houtryve 1966fa3d789dSPierre van Houtryve void TreePatternNode::print(raw_ostream &OS) const { 1967fa3d789dSPierre van Houtryve if (isLeaf()) 1968fa3d789dSPierre van Houtryve OS << *getLeafValue(); 1969fa3d789dSPierre van Houtryve else 1970fa3d789dSPierre van Houtryve OS << '(' << getOperator()->getName(); 1971fa3d789dSPierre van Houtryve 1972fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Types.size(); i != e; ++i) { 1973fa3d789dSPierre van Houtryve OS << ':'; 1974fa3d789dSPierre van Houtryve getExtType(i).writeToStream(OS); 1975fa3d789dSPierre van Houtryve } 1976fa3d789dSPierre van Houtryve 1977fa3d789dSPierre van Houtryve if (!isLeaf()) { 1978fa3d789dSPierre van Houtryve if (getNumChildren() != 0) { 1979fa3d789dSPierre van Houtryve OS << " "; 1980fa3d789dSPierre van Houtryve ListSeparator LS; 1981d1f51c67SSergei Barannikov for (const TreePatternNode &Child : children()) { 1982fa3d789dSPierre van Houtryve OS << LS; 1983d1f51c67SSergei Barannikov Child.print(OS); 1984fa3d789dSPierre van Houtryve } 1985fa3d789dSPierre van Houtryve } 1986fa3d789dSPierre van Houtryve OS << ")"; 1987fa3d789dSPierre van Houtryve } 1988fa3d789dSPierre van Houtryve 1989fa3d789dSPierre van Houtryve for (const TreePredicateCall &Pred : PredicateCalls) { 1990fa3d789dSPierre van Houtryve OS << "<<P:"; 1991fa3d789dSPierre van Houtryve if (Pred.Scope) 1992fa3d789dSPierre van Houtryve OS << Pred.Scope << ":"; 1993fa3d789dSPierre van Houtryve OS << Pred.Fn.getFnName() << ">>"; 1994fa3d789dSPierre van Houtryve } 1995fa3d789dSPierre van Houtryve if (TransformFn) 1996fa3d789dSPierre van Houtryve OS << "<<X:" << TransformFn->getName() << ">>"; 1997fa3d789dSPierre van Houtryve if (!getName().empty()) 1998fa3d789dSPierre van Houtryve OS << ":$" << getName(); 1999fa3d789dSPierre van Houtryve 2000fa3d789dSPierre van Houtryve for (const ScopedName &Name : NamesAsPredicateArg) 2001fa3d789dSPierre van Houtryve OS << ":$pred:" << Name.getScope() << ":" << Name.getIdentifier(); 2002fa3d789dSPierre van Houtryve } 2003fa3d789dSPierre van Houtryve void TreePatternNode::dump() const { print(errs()); } 2004fa3d789dSPierre van Houtryve 2005fa3d789dSPierre van Houtryve /// isIsomorphicTo - Return true if this node is recursively 2006fa3d789dSPierre van Houtryve /// isomorphic to the specified node. For this comparison, the node's 2007fa3d789dSPierre van Houtryve /// entire state is considered. The assigned name is ignored, since 2008fa3d789dSPierre van Houtryve /// nodes with differing names are considered isomorphic. However, if 2009fa3d789dSPierre van Houtryve /// the assigned name is present in the dependent variable set, then 2010fa3d789dSPierre van Houtryve /// the assigned name is considered significant and the node is 2011fa3d789dSPierre van Houtryve /// isomorphic if the names match. 2012fa3d789dSPierre van Houtryve bool TreePatternNode::isIsomorphicTo(const TreePatternNode &N, 2013fa3d789dSPierre van Houtryve const MultipleUseVarSet &DepVars) const { 2014fa3d789dSPierre van Houtryve if (&N == this) 2015fa3d789dSPierre van Houtryve return true; 2016fa3d789dSPierre van Houtryve if (N.isLeaf() != isLeaf()) 2017fa3d789dSPierre van Houtryve return false; 2018fa3d789dSPierre van Houtryve 2019fa3d789dSPierre van Houtryve // Check operator of non-leaves early since it can be cheaper than checking 2020fa3d789dSPierre van Houtryve // types. 2021fa3d789dSPierre van Houtryve if (!isLeaf()) 2022fa3d789dSPierre van Houtryve if (N.getOperator() != getOperator() || 2023fa3d789dSPierre van Houtryve N.getNumChildren() != getNumChildren()) 2024fa3d789dSPierre van Houtryve return false; 2025fa3d789dSPierre van Houtryve 2026fa3d789dSPierre van Houtryve if (getExtTypes() != N.getExtTypes() || 2027fa3d789dSPierre van Houtryve getPredicateCalls() != N.getPredicateCalls() || 2028fa3d789dSPierre van Houtryve getTransformFn() != N.getTransformFn()) 2029fa3d789dSPierre van Houtryve return false; 2030fa3d789dSPierre van Houtryve 2031fa3d789dSPierre van Houtryve if (isLeaf()) { 20323138eb50SRahul Joshi if (const DefInit *DI = dyn_cast<DefInit>(getLeafValue())) { 20333138eb50SRahul Joshi if (const DefInit *NDI = dyn_cast<DefInit>(N.getLeafValue())) { 2034fa3d789dSPierre van Houtryve return ((DI->getDef() == NDI->getDef()) && 2035fa3d789dSPierre van Houtryve (!DepVars.contains(getName()) || getName() == N.getName())); 2036fa3d789dSPierre van Houtryve } 2037fa3d789dSPierre van Houtryve } 2038fa3d789dSPierre van Houtryve return getLeafValue() == N.getLeafValue(); 2039fa3d789dSPierre van Houtryve } 2040fa3d789dSPierre van Houtryve 2041fa3d789dSPierre van Houtryve for (unsigned i = 0, e = getNumChildren(); i != e; ++i) 2042fa3d789dSPierre van Houtryve if (!getChild(i).isIsomorphicTo(N.getChild(i), DepVars)) 2043fa3d789dSPierre van Houtryve return false; 2044fa3d789dSPierre van Houtryve return true; 2045fa3d789dSPierre van Houtryve } 2046fa3d789dSPierre van Houtryve 2047fa3d789dSPierre van Houtryve /// clone - Make a copy of this tree and all of its children. 2048fa3d789dSPierre van Houtryve /// 2049fa3d789dSPierre van Houtryve TreePatternNodePtr TreePatternNode::clone() const { 2050fa3d789dSPierre van Houtryve TreePatternNodePtr New; 2051fa3d789dSPierre van Houtryve if (isLeaf()) { 2052fa3d789dSPierre van Houtryve New = makeIntrusiveRefCnt<TreePatternNode>(getLeafValue(), getNumTypes()); 2053fa3d789dSPierre van Houtryve } else { 2054fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> CChildren; 2055fa3d789dSPierre van Houtryve CChildren.reserve(Children.size()); 2056d1f51c67SSergei Barannikov for (const TreePatternNode &Child : children()) 2057d1f51c67SSergei Barannikov CChildren.push_back(Child.clone()); 2058fa3d789dSPierre van Houtryve New = makeIntrusiveRefCnt<TreePatternNode>( 2059fa3d789dSPierre van Houtryve getOperator(), std::move(CChildren), getNumTypes()); 2060fa3d789dSPierre van Houtryve } 2061fa3d789dSPierre van Houtryve New->setName(getName()); 2062fa3d789dSPierre van Houtryve New->setNamesAsPredicateArg(getNamesAsPredicateArg()); 2063fa3d789dSPierre van Houtryve New->Types = Types; 2064fa3d789dSPierre van Houtryve New->setPredicateCalls(getPredicateCalls()); 2065fa3d789dSPierre van Houtryve New->setGISelFlagsRecord(getGISelFlagsRecord()); 2066fa3d789dSPierre van Houtryve New->setTransformFn(getTransformFn()); 2067fa3d789dSPierre van Houtryve return New; 2068fa3d789dSPierre van Houtryve } 2069fa3d789dSPierre van Houtryve 2070fa3d789dSPierre van Houtryve /// RemoveAllTypes - Recursively strip all the types of this tree. 2071fa3d789dSPierre van Houtryve void TreePatternNode::RemoveAllTypes() { 2072fa3d789dSPierre van Houtryve // Reset to unknown type. 2073fa3d789dSPierre van Houtryve std::fill(Types.begin(), Types.end(), TypeSetByHwMode()); 2074fa3d789dSPierre van Houtryve if (isLeaf()) 2075fa3d789dSPierre van Houtryve return; 2076d1f51c67SSergei Barannikov for (TreePatternNode &Child : children()) 2077d1f51c67SSergei Barannikov Child.RemoveAllTypes(); 2078fa3d789dSPierre van Houtryve } 2079fa3d789dSPierre van Houtryve 2080fa3d789dSPierre van Houtryve /// SubstituteFormalArguments - Replace the formal arguments in this tree 2081fa3d789dSPierre van Houtryve /// with actual values specified by ArgMap. 2082fa3d789dSPierre van Houtryve void TreePatternNode::SubstituteFormalArguments( 2083fa3d789dSPierre van Houtryve std::map<std::string, TreePatternNodePtr> &ArgMap) { 2084fa3d789dSPierre van Houtryve if (isLeaf()) 2085fa3d789dSPierre van Houtryve return; 2086fa3d789dSPierre van Houtryve 2087fa3d789dSPierre van Houtryve for (unsigned i = 0, e = getNumChildren(); i != e; ++i) { 2088fa3d789dSPierre van Houtryve TreePatternNode &Child = getChild(i); 2089fa3d789dSPierre van Houtryve if (Child.isLeaf()) { 20903138eb50SRahul Joshi const Init *Val = Child.getLeafValue(); 2091fa3d789dSPierre van Houtryve // Note that, when substituting into an output pattern, Val might be an 2092fa3d789dSPierre van Houtryve // UnsetInit. 2093fa3d789dSPierre van Houtryve if (isa<UnsetInit>(Val) || 2094fa3d789dSPierre van Houtryve (isa<DefInit>(Val) && 2095fa3d789dSPierre van Houtryve cast<DefInit>(Val)->getDef()->getName() == "node")) { 2096fa3d789dSPierre van Houtryve // We found a use of a formal argument, replace it with its value. 2097fa3d789dSPierre van Houtryve TreePatternNodePtr NewChild = ArgMap[Child.getName()]; 2098fa3d789dSPierre van Houtryve assert(NewChild && "Couldn't find formal argument!"); 2099fa3d789dSPierre van Houtryve assert((Child.getPredicateCalls().empty() || 2100fa3d789dSPierre van Houtryve NewChild->getPredicateCalls() == Child.getPredicateCalls()) && 2101fa3d789dSPierre van Houtryve "Non-empty child predicate clobbered!"); 2102fa3d789dSPierre van Houtryve setChild(i, std::move(NewChild)); 2103fa3d789dSPierre van Houtryve } 2104fa3d789dSPierre van Houtryve } else { 2105fa3d789dSPierre van Houtryve getChild(i).SubstituteFormalArguments(ArgMap); 2106fa3d789dSPierre van Houtryve } 2107fa3d789dSPierre van Houtryve } 2108fa3d789dSPierre van Houtryve } 2109fa3d789dSPierre van Houtryve 2110fa3d789dSPierre van Houtryve /// InlinePatternFragments - If this pattern refers to any pattern 2111fa3d789dSPierre van Houtryve /// fragments, return the set of inlined versions (this can be more than 2112fa3d789dSPierre van Houtryve /// one if a PatFrags record has multiple alternatives). 2113fa3d789dSPierre van Houtryve void TreePatternNode::InlinePatternFragments( 2114fa3d789dSPierre van Houtryve TreePattern &TP, std::vector<TreePatternNodePtr> &OutAlternatives) { 2115fa3d789dSPierre van Houtryve 2116fa3d789dSPierre van Houtryve if (TP.hasError()) 2117fa3d789dSPierre van Houtryve return; 2118fa3d789dSPierre van Houtryve 2119fa3d789dSPierre van Houtryve if (isLeaf()) { 2120fa3d789dSPierre van Houtryve OutAlternatives.push_back(this); // nothing to do. 2121fa3d789dSPierre van Houtryve return; 2122fa3d789dSPierre van Houtryve } 2123fa3d789dSPierre van Houtryve 212437865681SRahul Joshi const Record *Op = getOperator(); 2125fa3d789dSPierre van Houtryve 2126fa3d789dSPierre van Houtryve if (!Op->isSubClassOf("PatFrags")) { 2127fa3d789dSPierre van Houtryve if (getNumChildren() == 0) { 2128fa3d789dSPierre van Houtryve OutAlternatives.push_back(this); 2129fa3d789dSPierre van Houtryve return; 2130fa3d789dSPierre van Houtryve } 2131fa3d789dSPierre van Houtryve 2132fa3d789dSPierre van Houtryve // Recursively inline children nodes. 2133fa3d789dSPierre van Houtryve std::vector<std::vector<TreePatternNodePtr>> ChildAlternatives( 2134fa3d789dSPierre van Houtryve getNumChildren()); 2135fa3d789dSPierre van Houtryve for (unsigned i = 0, e = getNumChildren(); i != e; ++i) { 2136fa3d789dSPierre van Houtryve TreePatternNodePtr Child = getChildShared(i); 2137fa3d789dSPierre van Houtryve Child->InlinePatternFragments(TP, ChildAlternatives[i]); 2138fa3d789dSPierre van Houtryve // If there are no alternatives for any child, there are no 2139fa3d789dSPierre van Houtryve // alternatives for this expression as whole. 2140fa3d789dSPierre van Houtryve if (ChildAlternatives[i].empty()) 2141fa3d789dSPierre van Houtryve return; 2142fa3d789dSPierre van Houtryve 2143fa3d789dSPierre van Houtryve assert((Child->getPredicateCalls().empty() || 2144fa3d789dSPierre van Houtryve llvm::all_of(ChildAlternatives[i], 2145fa3d789dSPierre van Houtryve [&](const TreePatternNodePtr &NewChild) { 2146fa3d789dSPierre van Houtryve return NewChild->getPredicateCalls() == 2147fa3d789dSPierre van Houtryve Child->getPredicateCalls(); 2148fa3d789dSPierre van Houtryve })) && 2149fa3d789dSPierre van Houtryve "Non-empty child predicate clobbered!"); 2150fa3d789dSPierre van Houtryve } 2151fa3d789dSPierre van Houtryve 2152fa3d789dSPierre van Houtryve // The end result is an all-pairs construction of the resultant pattern. 2153fa3d789dSPierre van Houtryve std::vector<unsigned> Idxs(ChildAlternatives.size()); 2154fa3d789dSPierre van Houtryve bool NotDone; 2155fa3d789dSPierre van Houtryve do { 2156fa3d789dSPierre van Houtryve // Create the variant and add it to the output list. 2157fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> NewChildren; 2158fa3d789dSPierre van Houtryve NewChildren.reserve(ChildAlternatives.size()); 2159fa3d789dSPierre van Houtryve for (unsigned i = 0, e = ChildAlternatives.size(); i != e; ++i) 2160fa3d789dSPierre van Houtryve NewChildren.push_back(ChildAlternatives[i][Idxs[i]]); 2161fa3d789dSPierre van Houtryve TreePatternNodePtr R = makeIntrusiveRefCnt<TreePatternNode>( 2162fa3d789dSPierre van Houtryve getOperator(), std::move(NewChildren), getNumTypes()); 2163fa3d789dSPierre van Houtryve 2164fa3d789dSPierre van Houtryve // Copy over properties. 2165fa3d789dSPierre van Houtryve R->setName(getName()); 2166fa3d789dSPierre van Houtryve R->setNamesAsPredicateArg(getNamesAsPredicateArg()); 2167fa3d789dSPierre van Houtryve R->setPredicateCalls(getPredicateCalls()); 2168fa3d789dSPierre van Houtryve R->setGISelFlagsRecord(getGISelFlagsRecord()); 2169fa3d789dSPierre van Houtryve R->setTransformFn(getTransformFn()); 2170fa3d789dSPierre van Houtryve for (unsigned i = 0, e = getNumTypes(); i != e; ++i) 2171fa3d789dSPierre van Houtryve R->setType(i, getExtType(i)); 2172fa3d789dSPierre van Houtryve for (unsigned i = 0, e = getNumResults(); i != e; ++i) 2173fa3d789dSPierre van Houtryve R->setResultIndex(i, getResultIndex(i)); 2174fa3d789dSPierre van Houtryve 2175fa3d789dSPierre van Houtryve // Register alternative. 2176fa3d789dSPierre van Houtryve OutAlternatives.push_back(R); 2177fa3d789dSPierre van Houtryve 2178fa3d789dSPierre van Houtryve // Increment indices to the next permutation by incrementing the 2179fa3d789dSPierre van Houtryve // indices from last index backward, e.g., generate the sequence 2180fa3d789dSPierre van Houtryve // [0, 0], [0, 1], [1, 0], [1, 1]. 2181fa3d789dSPierre van Houtryve int IdxsIdx; 2182fa3d789dSPierre van Houtryve for (IdxsIdx = Idxs.size() - 1; IdxsIdx >= 0; --IdxsIdx) { 2183fa3d789dSPierre van Houtryve if (++Idxs[IdxsIdx] == ChildAlternatives[IdxsIdx].size()) 2184fa3d789dSPierre van Houtryve Idxs[IdxsIdx] = 0; 2185fa3d789dSPierre van Houtryve else 2186fa3d789dSPierre van Houtryve break; 2187fa3d789dSPierre van Houtryve } 2188fa3d789dSPierre van Houtryve NotDone = (IdxsIdx >= 0); 2189fa3d789dSPierre van Houtryve } while (NotDone); 2190fa3d789dSPierre van Houtryve 2191fa3d789dSPierre van Houtryve return; 2192fa3d789dSPierre van Houtryve } 2193fa3d789dSPierre van Houtryve 2194fa3d789dSPierre van Houtryve // Otherwise, we found a reference to a fragment. First, look up its 2195fa3d789dSPierre van Houtryve // TreePattern record. 2196fa3d789dSPierre van Houtryve TreePattern *Frag = TP.getDAGPatterns().getPatternFragment(Op); 2197fa3d789dSPierre van Houtryve 2198fa3d789dSPierre van Houtryve // Verify that we are passing the right number of operands. 2199fa3d789dSPierre van Houtryve if (Frag->getNumArgs() != getNumChildren()) { 2200fa3d789dSPierre van Houtryve TP.error("'" + Op->getName() + "' fragment requires " + 2201fa3d789dSPierre van Houtryve Twine(Frag->getNumArgs()) + " operands!"); 2202fa3d789dSPierre van Houtryve return; 2203fa3d789dSPierre van Houtryve } 2204fa3d789dSPierre van Houtryve 2205fa3d789dSPierre van Houtryve TreePredicateFn PredFn(Frag); 2206fa3d789dSPierre van Houtryve unsigned Scope = 0; 2207fa3d789dSPierre van Houtryve if (TreePredicateFn(Frag).usesOperands()) 2208fa3d789dSPierre van Houtryve Scope = TP.getDAGPatterns().allocateScope(); 2209fa3d789dSPierre van Houtryve 2210fa3d789dSPierre van Houtryve // Compute the map of formal to actual arguments. 2211fa3d789dSPierre van Houtryve std::map<std::string, TreePatternNodePtr> ArgMap; 2212fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Frag->getNumArgs(); i != e; ++i) { 2213fa3d789dSPierre van Houtryve TreePatternNodePtr Child = getChildShared(i); 2214fa3d789dSPierre van Houtryve if (Scope != 0) { 2215fa3d789dSPierre van Houtryve Child = Child->clone(); 2216fa3d789dSPierre van Houtryve Child->addNameAsPredicateArg(ScopedName(Scope, Frag->getArgName(i))); 2217fa3d789dSPierre van Houtryve } 2218fa3d789dSPierre van Houtryve ArgMap[Frag->getArgName(i)] = Child; 2219fa3d789dSPierre van Houtryve } 2220fa3d789dSPierre van Houtryve 2221fa3d789dSPierre van Houtryve // Loop over all fragment alternatives. 2222fa3d789dSPierre van Houtryve for (const auto &Alternative : Frag->getTrees()) { 2223fa3d789dSPierre van Houtryve TreePatternNodePtr FragTree = Alternative->clone(); 2224fa3d789dSPierre van Houtryve 2225fa3d789dSPierre van Houtryve if (!PredFn.isAlwaysTrue()) 2226fa3d789dSPierre van Houtryve FragTree->addPredicateCall(PredFn, Scope); 2227fa3d789dSPierre van Houtryve 2228fa3d789dSPierre van Houtryve // Resolve formal arguments to their actual value. 2229fa3d789dSPierre van Houtryve if (Frag->getNumArgs()) 2230fa3d789dSPierre van Houtryve FragTree->SubstituteFormalArguments(ArgMap); 2231fa3d789dSPierre van Houtryve 2232fa3d789dSPierre van Houtryve // Transfer types. Note that the resolved alternative may have fewer 2233fa3d789dSPierre van Houtryve // (but not more) results than the PatFrags node. 2234fa3d789dSPierre van Houtryve FragTree->setName(getName()); 2235fa3d789dSPierre van Houtryve for (unsigned i = 0, e = FragTree->getNumTypes(); i != e; ++i) 2236fa3d789dSPierre van Houtryve FragTree->UpdateNodeType(i, getExtType(i), TP); 2237fa3d789dSPierre van Houtryve 2238fa3d789dSPierre van Houtryve if (Op->isSubClassOf("GISelFlags")) 2239fa3d789dSPierre van Houtryve FragTree->setGISelFlagsRecord(Op); 2240fa3d789dSPierre van Houtryve 2241fa3d789dSPierre van Houtryve // Transfer in the old predicates. 2242fa3d789dSPierre van Houtryve for (const TreePredicateCall &Pred : getPredicateCalls()) 2243fa3d789dSPierre van Houtryve FragTree->addPredicateCall(Pred); 2244fa3d789dSPierre van Houtryve 2245fa3d789dSPierre van Houtryve // The fragment we inlined could have recursive inlining that is needed. See 2246fa3d789dSPierre van Houtryve // if there are any pattern fragments in it and inline them as needed. 2247fa3d789dSPierre van Houtryve FragTree->InlinePatternFragments(TP, OutAlternatives); 2248fa3d789dSPierre van Houtryve } 2249fa3d789dSPierre van Houtryve } 2250fa3d789dSPierre van Houtryve 2251fa3d789dSPierre van Houtryve /// getImplicitType - Check to see if the specified record has an implicit 2252fa3d789dSPierre van Houtryve /// type which should be applied to it. This will infer the type of register 2253fa3d789dSPierre van Houtryve /// references from the register file information, for example. 2254fa3d789dSPierre van Houtryve /// 2255fa3d789dSPierre van Houtryve /// When Unnamed is set, return the type of a DAG operand with no name, such as 2256fa3d789dSPierre van Houtryve /// the F8RC register class argument in: 2257fa3d789dSPierre van Houtryve /// 2258fa3d789dSPierre van Houtryve /// (COPY_TO_REGCLASS GPR:$src, F8RC) 2259fa3d789dSPierre van Houtryve /// 2260fa3d789dSPierre van Houtryve /// When Unnamed is false, return the type of a named DAG operand such as the 2261fa3d789dSPierre van Houtryve /// GPR:$src operand above. 2262fa3d789dSPierre van Houtryve /// 22633138eb50SRahul Joshi static TypeSetByHwMode getImplicitType(const Record *R, unsigned ResNo, 2264fa3d789dSPierre van Houtryve bool NotRegisters, bool Unnamed, 2265fa3d789dSPierre van Houtryve TreePattern &TP) { 2266fa3d789dSPierre van Houtryve CodeGenDAGPatterns &CDP = TP.getDAGPatterns(); 2267fa3d789dSPierre van Houtryve 2268fa3d789dSPierre van Houtryve // Check to see if this is a register operand. 2269fa3d789dSPierre van Houtryve if (R->isSubClassOf("RegisterOperand")) { 2270fa3d789dSPierre van Houtryve assert(ResNo == 0 && "Regoperand ref only has one result!"); 2271fa3d789dSPierre van Houtryve if (NotRegisters) 2272fa3d789dSPierre van Houtryve return TypeSetByHwMode(); // Unknown. 22733138eb50SRahul Joshi const Record *RegClass = R->getValueAsDef("RegClass"); 2274fa3d789dSPierre van Houtryve const CodeGenTarget &T = TP.getDAGPatterns().getTargetInfo(); 2275fa3d789dSPierre van Houtryve return TypeSetByHwMode(T.getRegisterClass(RegClass).getValueTypes()); 2276fa3d789dSPierre van Houtryve } 2277fa3d789dSPierre van Houtryve 2278fa3d789dSPierre van Houtryve // Check to see if this is a register or a register class. 2279fa3d789dSPierre van Houtryve if (R->isSubClassOf("RegisterClass")) { 2280fa3d789dSPierre van Houtryve assert(ResNo == 0 && "Regclass ref only has one result!"); 2281fa3d789dSPierre van Houtryve // An unnamed register class represents itself as an i32 immediate, for 2282fa3d789dSPierre van Houtryve // example on a COPY_TO_REGCLASS instruction. 2283fa3d789dSPierre van Houtryve if (Unnamed) 2284fa3d789dSPierre van Houtryve return TypeSetByHwMode(MVT::i32); 2285fa3d789dSPierre van Houtryve 2286fa3d789dSPierre van Houtryve // In a named operand, the register class provides the possible set of 2287fa3d789dSPierre van Houtryve // types. 2288fa3d789dSPierre van Houtryve if (NotRegisters) 2289fa3d789dSPierre van Houtryve return TypeSetByHwMode(); // Unknown. 2290fa3d789dSPierre van Houtryve const CodeGenTarget &T = TP.getDAGPatterns().getTargetInfo(); 2291fa3d789dSPierre van Houtryve return TypeSetByHwMode(T.getRegisterClass(R).getValueTypes()); 2292fa3d789dSPierre van Houtryve } 2293fa3d789dSPierre van Houtryve 2294fa3d789dSPierre van Houtryve if (R->isSubClassOf("PatFrags")) { 2295fa3d789dSPierre van Houtryve assert(ResNo == 0 && "FIXME: PatFrag with multiple results?"); 2296fa3d789dSPierre van Houtryve // Pattern fragment types will be resolved when they are inlined. 2297fa3d789dSPierre van Houtryve return TypeSetByHwMode(); // Unknown. 2298fa3d789dSPierre van Houtryve } 2299fa3d789dSPierre van Houtryve 2300fa3d789dSPierre van Houtryve if (R->isSubClassOf("Register")) { 2301fa3d789dSPierre van Houtryve assert(ResNo == 0 && "Registers only produce one result!"); 2302fa3d789dSPierre van Houtryve if (NotRegisters) 2303fa3d789dSPierre van Houtryve return TypeSetByHwMode(); // Unknown. 2304fa3d789dSPierre van Houtryve const CodeGenTarget &T = TP.getDAGPatterns().getTargetInfo(); 2305fa3d789dSPierre van Houtryve return TypeSetByHwMode(T.getRegisterVTs(R)); 2306fa3d789dSPierre van Houtryve } 2307fa3d789dSPierre van Houtryve 2308fa3d789dSPierre van Houtryve if (R->isSubClassOf("SubRegIndex")) { 2309fa3d789dSPierre van Houtryve assert(ResNo == 0 && "SubRegisterIndices only produce one result!"); 2310fa3d789dSPierre van Houtryve return TypeSetByHwMode(MVT::i32); 2311fa3d789dSPierre van Houtryve } 2312fa3d789dSPierre van Houtryve 2313fa3d789dSPierre van Houtryve if (R->isSubClassOf("ValueType")) { 2314fa3d789dSPierre van Houtryve assert(ResNo == 0 && "This node only has one result!"); 2315fa3d789dSPierre van Houtryve // An unnamed VTSDNode represents itself as an MVT::Other immediate. 2316fa3d789dSPierre van Houtryve // 2317fa3d789dSPierre van Houtryve // (sext_inreg GPR:$src, i16) 2318fa3d789dSPierre van Houtryve // ~~~ 2319fa3d789dSPierre van Houtryve if (Unnamed) 2320fa3d789dSPierre van Houtryve return TypeSetByHwMode(MVT::Other); 2321fa3d789dSPierre van Houtryve // With a name, the ValueType simply provides the type of the named 2322fa3d789dSPierre van Houtryve // variable. 2323fa3d789dSPierre van Houtryve // 2324fa3d789dSPierre van Houtryve // (sext_inreg i32:$src, i16) 2325fa3d789dSPierre van Houtryve // ~~~~~~~~ 2326fa3d789dSPierre van Houtryve if (NotRegisters) 2327fa3d789dSPierre van Houtryve return TypeSetByHwMode(); // Unknown. 2328fa3d789dSPierre van Houtryve const CodeGenHwModes &CGH = CDP.getTargetInfo().getHwModes(); 2329fa3d789dSPierre van Houtryve return TypeSetByHwMode(getValueTypeByHwMode(R, CGH)); 2330fa3d789dSPierre van Houtryve } 2331fa3d789dSPierre van Houtryve 2332fa3d789dSPierre van Houtryve if (R->isSubClassOf("CondCode")) { 2333fa3d789dSPierre van Houtryve assert(ResNo == 0 && "This node only has one result!"); 2334fa3d789dSPierre van Houtryve // Using a CondCodeSDNode. 2335fa3d789dSPierre van Houtryve return TypeSetByHwMode(MVT::Other); 2336fa3d789dSPierre van Houtryve } 2337fa3d789dSPierre van Houtryve 2338fa3d789dSPierre van Houtryve if (R->isSubClassOf("ComplexPattern")) { 2339fa3d789dSPierre van Houtryve assert(ResNo == 0 && "FIXME: ComplexPattern with multiple results?"); 2340fa3d789dSPierre van Houtryve if (NotRegisters) 2341fa3d789dSPierre van Houtryve return TypeSetByHwMode(); // Unknown. 234287e8b530SRahul Joshi const Record *T = CDP.getComplexPattern(R).getValueType(); 2343fa3d789dSPierre van Houtryve const CodeGenHwModes &CGH = CDP.getTargetInfo().getHwModes(); 2344fa3d789dSPierre van Houtryve return TypeSetByHwMode(getValueTypeByHwMode(T, CGH)); 2345fa3d789dSPierre van Houtryve } 2346fa3d789dSPierre van Houtryve if (R->isSubClassOf("PointerLikeRegClass")) { 2347fa3d789dSPierre van Houtryve assert(ResNo == 0 && "Regclass can only have one result!"); 2348fa3d789dSPierre van Houtryve TypeSetByHwMode VTS(MVT::iPTR); 2349fa3d789dSPierre van Houtryve TP.getInfer().expandOverloads(VTS); 2350fa3d789dSPierre van Houtryve return VTS; 2351fa3d789dSPierre van Houtryve } 2352fa3d789dSPierre van Houtryve 2353fa3d789dSPierre van Houtryve if (R->getName() == "node" || R->getName() == "srcvalue" || 2354fa3d789dSPierre van Houtryve R->getName() == "zero_reg" || R->getName() == "immAllOnesV" || 2355fa3d789dSPierre van Houtryve R->getName() == "immAllZerosV" || R->getName() == "undef_tied_input") { 2356fa3d789dSPierre van Houtryve // Placeholder. 2357fa3d789dSPierre van Houtryve return TypeSetByHwMode(); // Unknown. 2358fa3d789dSPierre van Houtryve } 2359fa3d789dSPierre van Houtryve 2360fa3d789dSPierre van Houtryve if (R->isSubClassOf("Operand")) { 2361fa3d789dSPierre van Houtryve const CodeGenHwModes &CGH = CDP.getTargetInfo().getHwModes(); 23623138eb50SRahul Joshi const Record *T = R->getValueAsDef("Type"); 2363fa3d789dSPierre van Houtryve return TypeSetByHwMode(getValueTypeByHwMode(T, CGH)); 2364fa3d789dSPierre van Houtryve } 2365fa3d789dSPierre van Houtryve 2366fa3d789dSPierre van Houtryve TP.error("Unknown node flavor used in pattern: " + R->getName()); 2367fa3d789dSPierre van Houtryve return TypeSetByHwMode(MVT::Other); 2368fa3d789dSPierre van Houtryve } 2369fa3d789dSPierre van Houtryve 2370fa3d789dSPierre van Houtryve /// getIntrinsicInfo - If this node corresponds to an intrinsic, return the 2371fa3d789dSPierre van Houtryve /// CodeGenIntrinsic information for it, otherwise return a null pointer. 2372fa3d789dSPierre van Houtryve const CodeGenIntrinsic * 2373fa3d789dSPierre van Houtryve TreePatternNode::getIntrinsicInfo(const CodeGenDAGPatterns &CDP) const { 2374fa3d789dSPierre van Houtryve if (getOperator() != CDP.get_intrinsic_void_sdnode() && 2375fa3d789dSPierre van Houtryve getOperator() != CDP.get_intrinsic_w_chain_sdnode() && 2376fa3d789dSPierre van Houtryve getOperator() != CDP.get_intrinsic_wo_chain_sdnode()) 2377fa3d789dSPierre van Houtryve return nullptr; 2378fa3d789dSPierre van Houtryve 2379fa3d789dSPierre van Houtryve unsigned IID = cast<IntInit>(getChild(0).getLeafValue())->getValue(); 2380fa3d789dSPierre van Houtryve return &CDP.getIntrinsicInfo(IID); 2381fa3d789dSPierre van Houtryve } 2382fa3d789dSPierre van Houtryve 2383fa3d789dSPierre van Houtryve /// getComplexPatternInfo - If this node corresponds to a ComplexPattern, 2384fa3d789dSPierre van Houtryve /// return the ComplexPattern information, otherwise return null. 2385fa3d789dSPierre van Houtryve const ComplexPattern * 2386fa3d789dSPierre van Houtryve TreePatternNode::getComplexPatternInfo(const CodeGenDAGPatterns &CGP) const { 238737865681SRahul Joshi const Record *Rec; 2388fa3d789dSPierre van Houtryve if (isLeaf()) { 23893138eb50SRahul Joshi const DefInit *DI = dyn_cast<DefInit>(getLeafValue()); 2390fa3d789dSPierre van Houtryve if (!DI) 2391fa3d789dSPierre van Houtryve return nullptr; 2392fa3d789dSPierre van Houtryve Rec = DI->getDef(); 2393fa3d789dSPierre van Houtryve } else 2394fa3d789dSPierre van Houtryve Rec = getOperator(); 2395fa3d789dSPierre van Houtryve 2396fa3d789dSPierre van Houtryve if (!Rec->isSubClassOf("ComplexPattern")) 2397fa3d789dSPierre van Houtryve return nullptr; 2398fa3d789dSPierre van Houtryve return &CGP.getComplexPattern(Rec); 2399fa3d789dSPierre van Houtryve } 2400fa3d789dSPierre van Houtryve 2401fa3d789dSPierre van Houtryve unsigned TreePatternNode::getNumMIResults(const CodeGenDAGPatterns &CGP) const { 2402fa3d789dSPierre van Houtryve // A ComplexPattern specifically declares how many results it fills in. 2403fa3d789dSPierre van Houtryve if (const ComplexPattern *CP = getComplexPatternInfo(CGP)) 2404fa3d789dSPierre van Houtryve return CP->getNumOperands(); 2405fa3d789dSPierre van Houtryve 2406fa3d789dSPierre van Houtryve // If MIOperandInfo is specified, that gives the count. 2407fa3d789dSPierre van Houtryve if (isLeaf()) { 24083138eb50SRahul Joshi const DefInit *DI = dyn_cast<DefInit>(getLeafValue()); 2409fa3d789dSPierre van Houtryve if (DI && DI->getDef()->isSubClassOf("Operand")) { 24103138eb50SRahul Joshi const DagInit *MIOps = DI->getDef()->getValueAsDag("MIOperandInfo"); 2411fa3d789dSPierre van Houtryve if (MIOps->getNumArgs()) 2412fa3d789dSPierre van Houtryve return MIOps->getNumArgs(); 2413fa3d789dSPierre van Houtryve } 2414fa3d789dSPierre van Houtryve } 2415fa3d789dSPierre van Houtryve 2416fa3d789dSPierre van Houtryve // Otherwise there is just one result. 2417fa3d789dSPierre van Houtryve return 1; 2418fa3d789dSPierre van Houtryve } 2419fa3d789dSPierre van Houtryve 2420fa3d789dSPierre van Houtryve /// NodeHasProperty - Return true if this node has the specified property. 2421fa3d789dSPierre van Houtryve bool TreePatternNode::NodeHasProperty(SDNP Property, 2422fa3d789dSPierre van Houtryve const CodeGenDAGPatterns &CGP) const { 2423fa3d789dSPierre van Houtryve if (isLeaf()) { 2424fa3d789dSPierre van Houtryve if (const ComplexPattern *CP = getComplexPatternInfo(CGP)) 2425fa3d789dSPierre van Houtryve return CP->hasProperty(Property); 2426fa3d789dSPierre van Houtryve 2427fa3d789dSPierre van Houtryve return false; 2428fa3d789dSPierre van Houtryve } 2429fa3d789dSPierre van Houtryve 2430fa3d789dSPierre van Houtryve if (Property != SDNPHasChain) { 2431fa3d789dSPierre van Houtryve // The chain proprety is already present on the different intrinsic node 2432fa3d789dSPierre van Houtryve // types (intrinsic_w_chain, intrinsic_void), and is not explicitly listed 2433fa3d789dSPierre van Houtryve // on the intrinsic. Anything else is specific to the individual intrinsic. 2434fa3d789dSPierre van Houtryve if (const CodeGenIntrinsic *Int = getIntrinsicInfo(CGP)) 2435fa3d789dSPierre van Houtryve return Int->hasProperty(Property); 2436fa3d789dSPierre van Houtryve } 2437fa3d789dSPierre van Houtryve 2438fa3d789dSPierre van Houtryve if (!getOperator()->isSubClassOf("SDPatternOperator")) 2439fa3d789dSPierre van Houtryve return false; 2440fa3d789dSPierre van Houtryve 2441fa3d789dSPierre van Houtryve return CGP.getSDNodeInfo(getOperator()).hasProperty(Property); 2442fa3d789dSPierre van Houtryve } 2443fa3d789dSPierre van Houtryve 2444fa3d789dSPierre van Houtryve /// TreeHasProperty - Return true if any node in this tree has the specified 2445fa3d789dSPierre van Houtryve /// property. 2446fa3d789dSPierre van Houtryve bool TreePatternNode::TreeHasProperty(SDNP Property, 2447fa3d789dSPierre van Houtryve const CodeGenDAGPatterns &CGP) const { 2448fa3d789dSPierre van Houtryve if (NodeHasProperty(Property, CGP)) 2449fa3d789dSPierre van Houtryve return true; 2450d1f51c67SSergei Barannikov for (const TreePatternNode &Child : children()) 2451d1f51c67SSergei Barannikov if (Child.TreeHasProperty(Property, CGP)) 2452fa3d789dSPierre van Houtryve return true; 2453fa3d789dSPierre van Houtryve return false; 2454fa3d789dSPierre van Houtryve } 2455fa3d789dSPierre van Houtryve 2456fa3d789dSPierre van Houtryve /// isCommutativeIntrinsic - Return true if the node corresponds to a 2457fa3d789dSPierre van Houtryve /// commutative intrinsic. 2458fa3d789dSPierre van Houtryve bool TreePatternNode::isCommutativeIntrinsic( 2459fa3d789dSPierre van Houtryve const CodeGenDAGPatterns &CDP) const { 2460fa3d789dSPierre van Houtryve if (const CodeGenIntrinsic *Int = getIntrinsicInfo(CDP)) 2461fa3d789dSPierre van Houtryve return Int->isCommutative; 2462fa3d789dSPierre van Houtryve return false; 2463fa3d789dSPierre van Houtryve } 2464fa3d789dSPierre van Houtryve 2465fa3d789dSPierre van Houtryve static bool isOperandClass(const TreePatternNode &N, StringRef Class) { 2466fa3d789dSPierre van Houtryve if (!N.isLeaf()) 2467fa3d789dSPierre van Houtryve return N.getOperator()->isSubClassOf(Class); 2468fa3d789dSPierre van Houtryve 24693138eb50SRahul Joshi const DefInit *DI = dyn_cast<DefInit>(N.getLeafValue()); 2470fa3d789dSPierre van Houtryve if (DI && DI->getDef()->isSubClassOf(Class)) 2471fa3d789dSPierre van Houtryve return true; 2472fa3d789dSPierre van Houtryve 2473fa3d789dSPierre van Houtryve return false; 2474fa3d789dSPierre van Houtryve } 2475fa3d789dSPierre van Houtryve 2476fa3d789dSPierre van Houtryve static void emitTooManyOperandsError(TreePattern &TP, StringRef InstName, 2477fa3d789dSPierre van Houtryve unsigned Expected, unsigned Actual) { 2478fa3d789dSPierre van Houtryve TP.error("Instruction '" + InstName + "' was provided " + Twine(Actual) + 2479fa3d789dSPierre van Houtryve " operands but expected only " + Twine(Expected) + "!"); 2480fa3d789dSPierre van Houtryve } 2481fa3d789dSPierre van Houtryve 2482fa3d789dSPierre van Houtryve static void emitTooFewOperandsError(TreePattern &TP, StringRef InstName, 2483fa3d789dSPierre van Houtryve unsigned Actual) { 2484fa3d789dSPierre van Houtryve TP.error("Instruction '" + InstName + "' expects more than the provided " + 2485fa3d789dSPierre van Houtryve Twine(Actual) + " operands!"); 2486fa3d789dSPierre van Houtryve } 2487fa3d789dSPierre van Houtryve 2488fa3d789dSPierre van Houtryve /// ApplyTypeConstraints - Apply all of the type constraints relevant to 2489fa3d789dSPierre van Houtryve /// this node and its children in the tree. This returns true if it makes a 2490fa3d789dSPierre van Houtryve /// change, false otherwise. If a type contradiction is found, flag an error. 2491fa3d789dSPierre van Houtryve bool TreePatternNode::ApplyTypeConstraints(TreePattern &TP, bool NotRegisters) { 2492fa3d789dSPierre van Houtryve if (TP.hasError()) 2493fa3d789dSPierre van Houtryve return false; 2494fa3d789dSPierre van Houtryve 2495fa3d789dSPierre van Houtryve CodeGenDAGPatterns &CDP = TP.getDAGPatterns(); 2496fa3d789dSPierre van Houtryve if (isLeaf()) { 24973138eb50SRahul Joshi if (const DefInit *DI = dyn_cast<DefInit>(getLeafValue())) { 2498fa3d789dSPierre van Houtryve // If it's a regclass or something else known, include the type. 2499fa3d789dSPierre van Houtryve bool MadeChange = false; 2500fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Types.size(); i != e; ++i) 2501fa3d789dSPierre van Houtryve MadeChange |= UpdateNodeType( 2502fa3d789dSPierre van Houtryve i, getImplicitType(DI->getDef(), i, NotRegisters, !hasName(), TP), 2503fa3d789dSPierre van Houtryve TP); 2504fa3d789dSPierre van Houtryve return MadeChange; 2505fa3d789dSPierre van Houtryve } 2506fa3d789dSPierre van Houtryve 25073138eb50SRahul Joshi if (const IntInit *II = dyn_cast<IntInit>(getLeafValue())) { 2508fa3d789dSPierre van Houtryve assert(Types.size() == 1 && "Invalid IntInit"); 2509fa3d789dSPierre van Houtryve 2510fa3d789dSPierre van Houtryve // Int inits are always integers. :) 2511fa3d789dSPierre van Houtryve bool MadeChange = TP.getInfer().EnforceInteger(Types[0]); 2512fa3d789dSPierre van Houtryve 2513fa3d789dSPierre van Houtryve if (!TP.getInfer().isConcrete(Types[0], false)) 2514fa3d789dSPierre van Houtryve return MadeChange; 2515fa3d789dSPierre van Houtryve 2516fa3d789dSPierre van Houtryve ValueTypeByHwMode VVT = TP.getInfer().getConcrete(Types[0], false); 2517fa3d789dSPierre van Houtryve for (auto &P : VVT) { 2518fa3d789dSPierre van Houtryve MVT::SimpleValueType VT = P.second.SimpleTy; 2519e8b7f53fSJessica Clarke // Can only check for types of a known size 2520e8b7f53fSJessica Clarke if (VT == MVT::iPTR) 2521fa3d789dSPierre van Houtryve continue; 252297c3c323SSergei Barannikov 2523fa3d789dSPierre van Houtryve // Check that the value doesn't use more bits than we have. It must 2524fa3d789dSPierre van Houtryve // either be a sign- or zero-extended equivalent of the original. 252597c3c323SSergei Barannikov unsigned Width = MVT(VT).getFixedSizeInBits(); 252697c3c323SSergei Barannikov int64_t Val = II->getValue(); 252797c3c323SSergei Barannikov if (!isIntN(Width, Val) && !isUIntN(Width, Val)) { 252897c3c323SSergei Barannikov TP.error("Integer value '" + Twine(Val) + 2529fa3d789dSPierre van Houtryve "' is out of range for type '" + getEnumName(VT) + "'!"); 2530fa3d789dSPierre van Houtryve break; 2531fa3d789dSPierre van Houtryve } 253297c3c323SSergei Barannikov } 2533fa3d789dSPierre van Houtryve return MadeChange; 2534fa3d789dSPierre van Houtryve } 2535fa3d789dSPierre van Houtryve 2536fa3d789dSPierre van Houtryve return false; 2537fa3d789dSPierre van Houtryve } 2538fa3d789dSPierre van Houtryve 2539fa3d789dSPierre van Houtryve if (const CodeGenIntrinsic *Int = getIntrinsicInfo(CDP)) { 2540fa3d789dSPierre van Houtryve bool MadeChange = false; 2541fa3d789dSPierre van Houtryve 2542fa3d789dSPierre van Houtryve // Apply the result type to the node. 2543fa3d789dSPierre van Houtryve unsigned NumRetVTs = Int->IS.RetTys.size(); 2544fa3d789dSPierre van Houtryve unsigned NumParamVTs = Int->IS.ParamTys.size(); 2545fa3d789dSPierre van Houtryve 2546fa3d789dSPierre van Houtryve for (unsigned i = 0, e = NumRetVTs; i != e; ++i) 2547fa3d789dSPierre van Houtryve MadeChange |= UpdateNodeType( 2548fa3d789dSPierre van Houtryve i, getValueType(Int->IS.RetTys[i]->getValueAsDef("VT")), TP); 2549fa3d789dSPierre van Houtryve 2550fa3d789dSPierre van Houtryve if (getNumChildren() != NumParamVTs + 1) { 2551fa3d789dSPierre van Houtryve TP.error("Intrinsic '" + Int->Name + "' expects " + Twine(NumParamVTs) + 2552fa3d789dSPierre van Houtryve " operands, not " + Twine(getNumChildren() - 1) + " operands!"); 2553fa3d789dSPierre van Houtryve return false; 2554fa3d789dSPierre van Houtryve } 2555fa3d789dSPierre van Houtryve 2556fa3d789dSPierre van Houtryve // Apply type info to the intrinsic ID. 2557fa3d789dSPierre van Houtryve MadeChange |= getChild(0).UpdateNodeType(0, MVT::iPTR, TP); 2558fa3d789dSPierre van Houtryve 2559fa3d789dSPierre van Houtryve for (unsigned i = 0, e = getNumChildren() - 1; i != e; ++i) { 2560fa3d789dSPierre van Houtryve MadeChange |= getChild(i + 1).ApplyTypeConstraints(TP, NotRegisters); 2561fa3d789dSPierre van Houtryve 2562fa3d789dSPierre van Houtryve MVT::SimpleValueType OpVT = 2563fa3d789dSPierre van Houtryve getValueType(Int->IS.ParamTys[i]->getValueAsDef("VT")); 2564fa3d789dSPierre van Houtryve assert(getChild(i + 1).getNumTypes() == 1 && "Unhandled case"); 2565fa3d789dSPierre van Houtryve MadeChange |= getChild(i + 1).UpdateNodeType(0, OpVT, TP); 2566fa3d789dSPierre van Houtryve } 2567fa3d789dSPierre van Houtryve return MadeChange; 2568fa3d789dSPierre van Houtryve } 2569fa3d789dSPierre van Houtryve 2570fa3d789dSPierre van Houtryve if (getOperator()->isSubClassOf("SDNode")) { 2571fa3d789dSPierre van Houtryve const SDNodeInfo &NI = CDP.getSDNodeInfo(getOperator()); 2572fa3d789dSPierre van Houtryve 2573fa3d789dSPierre van Houtryve // Check that the number of operands is sane. Negative operands -> varargs. 2574fa3d789dSPierre van Houtryve if (NI.getNumOperands() >= 0 && 2575fa3d789dSPierre van Houtryve getNumChildren() != (unsigned)NI.getNumOperands()) { 2576fa3d789dSPierre van Houtryve TP.error(getOperator()->getName() + " node requires exactly " + 2577fa3d789dSPierre van Houtryve Twine(NI.getNumOperands()) + " operands!"); 2578fa3d789dSPierre van Houtryve return false; 2579fa3d789dSPierre van Houtryve } 2580fa3d789dSPierre van Houtryve 2581fa3d789dSPierre van Houtryve bool MadeChange = false; 2582d1f51c67SSergei Barannikov for (TreePatternNode &Child : children()) 2583d1f51c67SSergei Barannikov MadeChange |= Child.ApplyTypeConstraints(TP, NotRegisters); 2584fa3d789dSPierre van Houtryve MadeChange |= NI.ApplyTypeConstraints(*this, TP); 2585fa3d789dSPierre van Houtryve return MadeChange; 2586fa3d789dSPierre van Houtryve } 2587fa3d789dSPierre van Houtryve 2588fa3d789dSPierre van Houtryve if (getOperator()->isSubClassOf("Instruction")) { 2589fa3d789dSPierre van Houtryve const DAGInstruction &Inst = CDP.getInstruction(getOperator()); 2590fa3d789dSPierre van Houtryve CodeGenInstruction &InstInfo = 2591fa3d789dSPierre van Houtryve CDP.getTargetInfo().getInstruction(getOperator()); 2592fa3d789dSPierre van Houtryve 2593fa3d789dSPierre van Houtryve bool MadeChange = false; 2594fa3d789dSPierre van Houtryve 2595fa3d789dSPierre van Houtryve // Apply the result types to the node, these come from the things in the 2596fa3d789dSPierre van Houtryve // (outs) list of the instruction. 2597fa3d789dSPierre van Houtryve unsigned NumResultsToAdd = 2598fa3d789dSPierre van Houtryve std::min(InstInfo.Operands.NumDefs, Inst.getNumResults()); 2599fa3d789dSPierre van Houtryve for (unsigned ResNo = 0; ResNo != NumResultsToAdd; ++ResNo) 2600fa3d789dSPierre van Houtryve MadeChange |= UpdateNodeTypeFromInst(ResNo, Inst.getResult(ResNo), TP); 2601fa3d789dSPierre van Houtryve 2602fa3d789dSPierre van Houtryve // If the instruction has implicit defs, we apply the first one as a result. 2603fa3d789dSPierre van Houtryve // FIXME: This sucks, it should apply all implicit defs. 2604fa3d789dSPierre van Houtryve if (!InstInfo.ImplicitDefs.empty()) { 2605fa3d789dSPierre van Houtryve unsigned ResNo = NumResultsToAdd; 2606fa3d789dSPierre van Houtryve 2607fa3d789dSPierre van Houtryve // FIXME: Generalize to multiple possible types and multiple possible 2608fa3d789dSPierre van Houtryve // ImplicitDefs. 2609fa3d789dSPierre van Houtryve MVT::SimpleValueType VT = 2610fa3d789dSPierre van Houtryve InstInfo.HasOneImplicitDefWithKnownVT(CDP.getTargetInfo()); 2611fa3d789dSPierre van Houtryve 2612fa3d789dSPierre van Houtryve if (VT != MVT::Other) 2613fa3d789dSPierre van Houtryve MadeChange |= UpdateNodeType(ResNo, VT, TP); 2614fa3d789dSPierre van Houtryve } 2615fa3d789dSPierre van Houtryve 2616fa3d789dSPierre van Houtryve // If this is an INSERT_SUBREG, constrain the source and destination VTs to 2617fa3d789dSPierre van Houtryve // be the same. 2618fa3d789dSPierre van Houtryve if (getOperator()->getName() == "INSERT_SUBREG") { 2619fa3d789dSPierre van Houtryve assert(getChild(0).getNumTypes() == 1 && "FIXME: Unhandled"); 2620fa3d789dSPierre van Houtryve MadeChange |= UpdateNodeType(0, getChild(0).getExtType(0), TP); 2621fa3d789dSPierre van Houtryve MadeChange |= getChild(0).UpdateNodeType(0, getExtType(0), TP); 2622fa3d789dSPierre van Houtryve } else if (getOperator()->getName() == "REG_SEQUENCE") { 2623fa3d789dSPierre van Houtryve // We need to do extra, custom typechecking for REG_SEQUENCE since it is 2624fa3d789dSPierre van Houtryve // variadic. 2625fa3d789dSPierre van Houtryve 2626fa3d789dSPierre van Houtryve unsigned NChild = getNumChildren(); 2627fa3d789dSPierre van Houtryve if (NChild < 3) { 2628fa3d789dSPierre van Houtryve TP.error("REG_SEQUENCE requires at least 3 operands!"); 2629fa3d789dSPierre van Houtryve return false; 2630fa3d789dSPierre van Houtryve } 2631fa3d789dSPierre van Houtryve 2632fa3d789dSPierre van Houtryve if (NChild % 2 == 0) { 2633fa3d789dSPierre van Houtryve TP.error("REG_SEQUENCE requires an odd number of operands!"); 2634fa3d789dSPierre van Houtryve return false; 2635fa3d789dSPierre van Houtryve } 2636fa3d789dSPierre van Houtryve 2637fa3d789dSPierre van Houtryve if (!isOperandClass(getChild(0), "RegisterClass")) { 2638fa3d789dSPierre van Houtryve TP.error("REG_SEQUENCE requires a RegisterClass for first operand!"); 2639fa3d789dSPierre van Houtryve return false; 2640fa3d789dSPierre van Houtryve } 2641fa3d789dSPierre van Houtryve 2642fa3d789dSPierre van Houtryve for (unsigned I = 1; I < NChild; I += 2) { 2643fa3d789dSPierre van Houtryve TreePatternNode &SubIdxChild = getChild(I + 1); 2644fa3d789dSPierre van Houtryve if (!isOperandClass(SubIdxChild, "SubRegIndex")) { 2645fa3d789dSPierre van Houtryve TP.error("REG_SEQUENCE requires a SubRegIndex for operand " + 2646fa3d789dSPierre van Houtryve Twine(I + 1) + "!"); 2647fa3d789dSPierre van Houtryve return false; 2648fa3d789dSPierre van Houtryve } 2649fa3d789dSPierre van Houtryve } 2650fa3d789dSPierre van Houtryve } 2651fa3d789dSPierre van Houtryve 2652fa3d789dSPierre van Houtryve unsigned NumResults = Inst.getNumResults(); 2653fa3d789dSPierre van Houtryve unsigned NumFixedOperands = InstInfo.Operands.size(); 2654fa3d789dSPierre van Houtryve 2655fa3d789dSPierre van Houtryve // If one or more operands with a default value appear at the end of the 2656fa3d789dSPierre van Houtryve // formal operand list for an instruction, we allow them to be overridden 2657fa3d789dSPierre van Houtryve // by optional operands provided in the pattern. 2658fa3d789dSPierre van Houtryve // 2659fa3d789dSPierre van Houtryve // But if an operand B without a default appears at any point after an 2660fa3d789dSPierre van Houtryve // operand A with a default, then we don't allow A to be overridden, 2661fa3d789dSPierre van Houtryve // because there would be no way to specify whether the next operand in 2662fa3d789dSPierre van Houtryve // the pattern was intended to override A or skip it. 2663fa3d789dSPierre van Houtryve unsigned NonOverridableOperands = NumFixedOperands; 2664fa3d789dSPierre van Houtryve while (NonOverridableOperands > NumResults && 2665fa3d789dSPierre van Houtryve CDP.operandHasDefault( 2666fa3d789dSPierre van Houtryve InstInfo.Operands[NonOverridableOperands - 1].Rec)) 2667fa3d789dSPierre van Houtryve --NonOverridableOperands; 2668fa3d789dSPierre van Houtryve 2669fa3d789dSPierre van Houtryve unsigned ChildNo = 0; 2670fa3d789dSPierre van Houtryve assert(NumResults <= NumFixedOperands); 2671fa3d789dSPierre van Houtryve for (unsigned i = NumResults, e = NumFixedOperands; i != e; ++i) { 2672bdf02249SRahul Joshi const Record *OperandNode = InstInfo.Operands[i].Rec; 2673fa3d789dSPierre van Houtryve 2674fa3d789dSPierre van Houtryve // If the operand has a default value, do we use it? We must use the 2675fa3d789dSPierre van Houtryve // default if we've run out of children of the pattern DAG to consume, 2676fa3d789dSPierre van Houtryve // or if the operand is followed by a non-defaulted one. 2677fa3d789dSPierre van Houtryve if (CDP.operandHasDefault(OperandNode) && 2678fa3d789dSPierre van Houtryve (i < NonOverridableOperands || ChildNo >= getNumChildren())) 2679fa3d789dSPierre van Houtryve continue; 2680fa3d789dSPierre van Houtryve 2681fa3d789dSPierre van Houtryve // If we have run out of child nodes and there _isn't_ a default 2682fa3d789dSPierre van Houtryve // value we can use for the next operand, give an error. 2683fa3d789dSPierre van Houtryve if (ChildNo >= getNumChildren()) { 2684fa3d789dSPierre van Houtryve emitTooFewOperandsError(TP, getOperator()->getName(), getNumChildren()); 2685fa3d789dSPierre van Houtryve return false; 2686fa3d789dSPierre van Houtryve } 2687fa3d789dSPierre van Houtryve 2688fa3d789dSPierre van Houtryve TreePatternNode *Child = &getChild(ChildNo++); 2689fa3d789dSPierre van Houtryve unsigned ChildResNo = 0; // Instructions always use res #0 of their op. 2690fa3d789dSPierre van Houtryve 2691fa3d789dSPierre van Houtryve // If the operand has sub-operands, they may be provided by distinct 2692fa3d789dSPierre van Houtryve // child patterns, so attempt to match each sub-operand separately. 2693fa3d789dSPierre van Houtryve if (OperandNode->isSubClassOf("Operand")) { 269462e2c7fbSRahul Joshi const DagInit *MIOpInfo = OperandNode->getValueAsDag("MIOperandInfo"); 2695fa3d789dSPierre van Houtryve if (unsigned NumArgs = MIOpInfo->getNumArgs()) { 2696fa3d789dSPierre van Houtryve // But don't do that if the whole operand is being provided by 2697fa3d789dSPierre van Houtryve // a single ComplexPattern-related Operand. 2698fa3d789dSPierre van Houtryve 2699fa3d789dSPierre van Houtryve if (Child->getNumMIResults(CDP) < NumArgs) { 2700fa3d789dSPierre van Houtryve // Match first sub-operand against the child we already have. 27013138eb50SRahul Joshi const Record *SubRec = cast<DefInit>(MIOpInfo->getArg(0))->getDef(); 2702fa3d789dSPierre van Houtryve MadeChange |= Child->UpdateNodeTypeFromInst(ChildResNo, SubRec, TP); 2703fa3d789dSPierre van Houtryve 2704fa3d789dSPierre van Houtryve // And the remaining sub-operands against subsequent children. 2705fa3d789dSPierre van Houtryve for (unsigned Arg = 1; Arg < NumArgs; ++Arg) { 2706fa3d789dSPierre van Houtryve if (ChildNo >= getNumChildren()) { 2707fa3d789dSPierre van Houtryve emitTooFewOperandsError(TP, getOperator()->getName(), 2708fa3d789dSPierre van Houtryve getNumChildren()); 2709fa3d789dSPierre van Houtryve return false; 2710fa3d789dSPierre van Houtryve } 2711fa3d789dSPierre van Houtryve Child = &getChild(ChildNo++); 2712fa3d789dSPierre van Houtryve 2713fa3d789dSPierre van Houtryve SubRec = cast<DefInit>(MIOpInfo->getArg(Arg))->getDef(); 2714fa3d789dSPierre van Houtryve MadeChange |= 2715fa3d789dSPierre van Houtryve Child->UpdateNodeTypeFromInst(ChildResNo, SubRec, TP); 2716fa3d789dSPierre van Houtryve } 2717fa3d789dSPierre van Houtryve continue; 2718fa3d789dSPierre van Houtryve } 2719fa3d789dSPierre van Houtryve } 2720fa3d789dSPierre van Houtryve } 2721fa3d789dSPierre van Houtryve 2722fa3d789dSPierre van Houtryve // If we didn't match by pieces above, attempt to match the whole 2723fa3d789dSPierre van Houtryve // operand now. 2724fa3d789dSPierre van Houtryve MadeChange |= Child->UpdateNodeTypeFromInst(ChildResNo, OperandNode, TP); 2725fa3d789dSPierre van Houtryve } 2726fa3d789dSPierre van Houtryve 2727fa3d789dSPierre van Houtryve if (!InstInfo.Operands.isVariadic && ChildNo != getNumChildren()) { 2728fa3d789dSPierre van Houtryve emitTooManyOperandsError(TP, getOperator()->getName(), ChildNo, 2729fa3d789dSPierre van Houtryve getNumChildren()); 2730fa3d789dSPierre van Houtryve return false; 2731fa3d789dSPierre van Houtryve } 2732fa3d789dSPierre van Houtryve 2733d1f51c67SSergei Barannikov for (TreePatternNode &Child : children()) 2734d1f51c67SSergei Barannikov MadeChange |= Child.ApplyTypeConstraints(TP, NotRegisters); 2735fa3d789dSPierre van Houtryve return MadeChange; 2736fa3d789dSPierre van Houtryve } 2737fa3d789dSPierre van Houtryve 2738fa3d789dSPierre van Houtryve if (getOperator()->isSubClassOf("ComplexPattern")) { 2739fa3d789dSPierre van Houtryve bool MadeChange = false; 2740fa3d789dSPierre van Houtryve 2741fa3d789dSPierre van Houtryve if (!NotRegisters) { 2742fa3d789dSPierre van Houtryve assert(Types.size() == 1 && "ComplexPatterns only produce one result!"); 274387e8b530SRahul Joshi const Record *T = CDP.getComplexPattern(getOperator()).getValueType(); 2744fa3d789dSPierre van Houtryve const CodeGenHwModes &CGH = CDP.getTargetInfo().getHwModes(); 2745fa3d789dSPierre van Houtryve const ValueTypeByHwMode VVT = getValueTypeByHwMode(T, CGH); 2746fa3d789dSPierre van Houtryve // TODO: AArch64 and AMDGPU use ComplexPattern<untyped, ...> and then 2747fa3d789dSPierre van Houtryve // exclusively use those as non-leaf nodes with explicit type casts, so 2748fa3d789dSPierre van Houtryve // for backwards compatibility we do no inference in that case. This is 2749fa3d789dSPierre van Houtryve // not supported when the ComplexPattern is used as a leaf value, 2750fa3d789dSPierre van Houtryve // however; this inconsistency should be resolved, either by adding this 2751fa3d789dSPierre van Houtryve // case there or by altering the backends to not do this (e.g. using Any 2752fa3d789dSPierre van Houtryve // instead may work). 2753fa3d789dSPierre van Houtryve if (!VVT.isSimple() || VVT.getSimple() != MVT::Untyped) 2754fa3d789dSPierre van Houtryve MadeChange |= UpdateNodeType(0, VVT, TP); 2755fa3d789dSPierre van Houtryve } 2756fa3d789dSPierre van Houtryve 2757d1f51c67SSergei Barannikov for (TreePatternNode &Child : children()) 2758d1f51c67SSergei Barannikov MadeChange |= Child.ApplyTypeConstraints(TP, NotRegisters); 2759fa3d789dSPierre van Houtryve 2760fa3d789dSPierre van Houtryve return MadeChange; 2761fa3d789dSPierre van Houtryve } 2762fa3d789dSPierre van Houtryve 2763fa3d789dSPierre van Houtryve assert(getOperator()->isSubClassOf("SDNodeXForm") && "Unknown node type!"); 2764fa3d789dSPierre van Houtryve 2765fa3d789dSPierre van Houtryve // Node transforms always take one operand. 2766fa3d789dSPierre van Houtryve if (getNumChildren() != 1) { 2767fa3d789dSPierre van Houtryve TP.error("Node transform '" + getOperator()->getName() + 2768fa3d789dSPierre van Houtryve "' requires one operand!"); 2769fa3d789dSPierre van Houtryve return false; 2770fa3d789dSPierre van Houtryve } 2771fa3d789dSPierre van Houtryve 2772fa3d789dSPierre van Houtryve bool MadeChange = getChild(0).ApplyTypeConstraints(TP, NotRegisters); 2773fa3d789dSPierre van Houtryve return MadeChange; 2774fa3d789dSPierre van Houtryve } 2775fa3d789dSPierre van Houtryve 2776fa3d789dSPierre van Houtryve /// OnlyOnRHSOfCommutative - Return true if this value is only allowed on the 2777fa3d789dSPierre van Houtryve /// RHS of a commutative operation, not the on LHS. 2778d1f51c67SSergei Barannikov static bool OnlyOnRHSOfCommutative(const TreePatternNode &N) { 2779fa3d789dSPierre van Houtryve if (!N.isLeaf() && N.getOperator()->getName() == "imm") 2780fa3d789dSPierre van Houtryve return true; 2781fa3d789dSPierre van Houtryve if (N.isLeaf() && isa<IntInit>(N.getLeafValue())) 2782fa3d789dSPierre van Houtryve return true; 2783fa3d789dSPierre van Houtryve if (isImmAllOnesAllZerosMatch(N)) 2784fa3d789dSPierre van Houtryve return true; 2785fa3d789dSPierre van Houtryve return false; 2786fa3d789dSPierre van Houtryve } 2787fa3d789dSPierre van Houtryve 2788fa3d789dSPierre van Houtryve /// canPatternMatch - If it is impossible for this pattern to match on this 2789fa3d789dSPierre van Houtryve /// target, fill in Reason and return false. Otherwise, return true. This is 2790fa3d789dSPierre van Houtryve /// used as a sanity check for .td files (to prevent people from writing stuff 2791fa3d789dSPierre van Houtryve /// that can never possibly work), and to prevent the pattern permuter from 2792fa3d789dSPierre van Houtryve /// generating stuff that is useless. 2793fa3d789dSPierre van Houtryve bool TreePatternNode::canPatternMatch(std::string &Reason, 2794d1f51c67SSergei Barannikov const CodeGenDAGPatterns &CDP) const { 2795fa3d789dSPierre van Houtryve if (isLeaf()) 2796fa3d789dSPierre van Houtryve return true; 2797fa3d789dSPierre van Houtryve 2798d1f51c67SSergei Barannikov for (const TreePatternNode &Child : children()) 2799d1f51c67SSergei Barannikov if (!Child.canPatternMatch(Reason, CDP)) 2800fa3d789dSPierre van Houtryve return false; 2801fa3d789dSPierre van Houtryve 2802fa3d789dSPierre van Houtryve // If this is an intrinsic, handle cases that would make it not match. For 2803fa3d789dSPierre van Houtryve // example, if an operand is required to be an immediate. 2804fa3d789dSPierre van Houtryve if (getOperator()->isSubClassOf("Intrinsic")) { 2805fa3d789dSPierre van Houtryve // TODO: 2806fa3d789dSPierre van Houtryve return true; 2807fa3d789dSPierre van Houtryve } 2808fa3d789dSPierre van Houtryve 2809fa3d789dSPierre van Houtryve if (getOperator()->isSubClassOf("ComplexPattern")) 2810fa3d789dSPierre van Houtryve return true; 2811fa3d789dSPierre van Houtryve 2812fa3d789dSPierre van Houtryve // If this node is a commutative operator, check that the LHS isn't an 2813fa3d789dSPierre van Houtryve // immediate. 2814fa3d789dSPierre van Houtryve const SDNodeInfo &NodeInfo = CDP.getSDNodeInfo(getOperator()); 2815fa3d789dSPierre van Houtryve bool isCommIntrinsic = isCommutativeIntrinsic(CDP); 2816fa3d789dSPierre van Houtryve if (NodeInfo.hasProperty(SDNPCommutative) || isCommIntrinsic) { 2817fa3d789dSPierre van Houtryve // Scan all of the operands of the node and make sure that only the last one 2818fa3d789dSPierre van Houtryve // is a constant node, unless the RHS also is. 2819fa3d789dSPierre van Houtryve if (!OnlyOnRHSOfCommutative(getChild(getNumChildren() - 1))) { 2820fa3d789dSPierre van Houtryve unsigned Skip = isCommIntrinsic ? 1 : 0; // First operand is intrinsic id. 2821fa3d789dSPierre van Houtryve for (unsigned i = Skip, e = getNumChildren() - 1; i != e; ++i) 2822fa3d789dSPierre van Houtryve if (OnlyOnRHSOfCommutative(getChild(i))) { 2823fa3d789dSPierre van Houtryve Reason = 2824fa3d789dSPierre van Houtryve "Immediate value must be on the RHS of commutative operators!"; 2825fa3d789dSPierre van Houtryve return false; 2826fa3d789dSPierre van Houtryve } 2827fa3d789dSPierre van Houtryve } 2828fa3d789dSPierre van Houtryve } 2829fa3d789dSPierre van Houtryve 2830fa3d789dSPierre van Houtryve return true; 2831fa3d789dSPierre van Houtryve } 2832fa3d789dSPierre van Houtryve 2833fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 2834fa3d789dSPierre van Houtryve // TreePattern implementation 2835fa3d789dSPierre van Houtryve // 2836fa3d789dSPierre van Houtryve 28373138eb50SRahul Joshi TreePattern::TreePattern(const Record *TheRec, const ListInit *RawPat, 28383138eb50SRahul Joshi bool isInput, CodeGenDAGPatterns &cdp) 2839fa3d789dSPierre van Houtryve : TheRecord(TheRec), CDP(cdp), isInputPattern(isInput), HasError(false), 2840fa3d789dSPierre van Houtryve Infer(*this) { 284162e2c7fbSRahul Joshi for (const Init *I : RawPat->getValues()) 2842fa3d789dSPierre van Houtryve Trees.push_back(ParseTreePattern(I, "")); 2843fa3d789dSPierre van Houtryve } 2844fa3d789dSPierre van Houtryve 284562e2c7fbSRahul Joshi TreePattern::TreePattern(const Record *TheRec, const DagInit *Pat, bool isInput, 2846fa3d789dSPierre van Houtryve CodeGenDAGPatterns &cdp) 2847fa3d789dSPierre van Houtryve : TheRecord(TheRec), CDP(cdp), isInputPattern(isInput), HasError(false), 2848fa3d789dSPierre van Houtryve Infer(*this) { 2849fa3d789dSPierre van Houtryve Trees.push_back(ParseTreePattern(Pat, "")); 2850fa3d789dSPierre van Houtryve } 2851fa3d789dSPierre van Houtryve 285237865681SRahul Joshi TreePattern::TreePattern(const Record *TheRec, TreePatternNodePtr Pat, 285337865681SRahul Joshi bool isInput, CodeGenDAGPatterns &cdp) 2854fa3d789dSPierre van Houtryve : TheRecord(TheRec), CDP(cdp), isInputPattern(isInput), HasError(false), 2855fa3d789dSPierre van Houtryve Infer(*this) { 2856fa3d789dSPierre van Houtryve Trees.push_back(Pat); 2857fa3d789dSPierre van Houtryve } 2858fa3d789dSPierre van Houtryve 2859fa3d789dSPierre van Houtryve void TreePattern::error(const Twine &Msg) { 2860fa3d789dSPierre van Houtryve if (HasError) 2861fa3d789dSPierre van Houtryve return; 2862fa3d789dSPierre van Houtryve dump(); 2863fa3d789dSPierre van Houtryve PrintError(TheRecord->getLoc(), "In " + TheRecord->getName() + ": " + Msg); 2864fa3d789dSPierre van Houtryve HasError = true; 2865fa3d789dSPierre van Houtryve } 2866fa3d789dSPierre van Houtryve 2867fa3d789dSPierre van Houtryve void TreePattern::ComputeNamedNodes() { 2868fa3d789dSPierre van Houtryve for (TreePatternNodePtr &Tree : Trees) 2869fa3d789dSPierre van Houtryve ComputeNamedNodes(*Tree); 2870fa3d789dSPierre van Houtryve } 2871fa3d789dSPierre van Houtryve 2872fa3d789dSPierre van Houtryve void TreePattern::ComputeNamedNodes(TreePatternNode &N) { 2873fa3d789dSPierre van Houtryve if (!N.getName().empty()) 2874fa3d789dSPierre van Houtryve NamedNodes[N.getName()].push_back(&N); 2875fa3d789dSPierre van Houtryve 2876d1f51c67SSergei Barannikov for (TreePatternNode &Child : N.children()) 2877d1f51c67SSergei Barannikov ComputeNamedNodes(Child); 2878fa3d789dSPierre van Houtryve } 2879fa3d789dSPierre van Houtryve 288062e2c7fbSRahul Joshi TreePatternNodePtr TreePattern::ParseTreePattern(const Init *TheInit, 2881fa3d789dSPierre van Houtryve StringRef OpName) { 2882fa3d789dSPierre van Houtryve RecordKeeper &RK = TheInit->getRecordKeeper(); 28833138eb50SRahul Joshi // Here, we are creating new records (BitsInit->InitInit), so const_cast 28843138eb50SRahul Joshi // TheInit back to non-const pointer. 288562e2c7fbSRahul Joshi if (const DefInit *DI = dyn_cast<DefInit>(TheInit)) { 28863138eb50SRahul Joshi const Record *R = DI->getDef(); 2887fa3d789dSPierre van Houtryve 2888fa3d789dSPierre van Houtryve // Direct reference to a leaf DagNode or PatFrag? Turn it into a 2889fa3d789dSPierre van Houtryve // TreePatternNode of its own. For example: 2890fa3d789dSPierre van Houtryve /// (foo GPR, imm) -> (foo GPR, (imm)) 2891fa3d789dSPierre van Houtryve if (R->isSubClassOf("SDNode") || R->isSubClassOf("PatFrags")) 2892fa3d789dSPierre van Houtryve return ParseTreePattern( 289362e2c7fbSRahul Joshi DagInit::get( 289462e2c7fbSRahul Joshi DI, nullptr, 289562e2c7fbSRahul Joshi std::vector<std::pair<const Init *, const StringInit *>>()), 2896fa3d789dSPierre van Houtryve OpName); 2897fa3d789dSPierre van Houtryve 2898fa3d789dSPierre van Houtryve // Input argument? 2899fa3d789dSPierre van Houtryve TreePatternNodePtr Res = makeIntrusiveRefCnt<TreePatternNode>(DI, 1); 2900fa3d789dSPierre van Houtryve if (R->getName() == "node" && !OpName.empty()) { 2901fa3d789dSPierre van Houtryve if (OpName.empty()) 2902fa3d789dSPierre van Houtryve error("'node' argument requires a name to match with operand list"); 2903fa3d789dSPierre van Houtryve Args.push_back(std::string(OpName)); 2904fa3d789dSPierre van Houtryve } 2905fa3d789dSPierre van Houtryve 2906fa3d789dSPierre van Houtryve Res->setName(OpName); 2907fa3d789dSPierre van Houtryve return Res; 2908fa3d789dSPierre van Houtryve } 2909fa3d789dSPierre van Houtryve 2910fa3d789dSPierre van Houtryve // ?:$name or just $name. 2911fa3d789dSPierre van Houtryve if (isa<UnsetInit>(TheInit)) { 2912fa3d789dSPierre van Houtryve if (OpName.empty()) 2913fa3d789dSPierre van Houtryve error("'?' argument requires a name to match with operand list"); 2914fa3d789dSPierre van Houtryve TreePatternNodePtr Res = makeIntrusiveRefCnt<TreePatternNode>(TheInit, 1); 2915fa3d789dSPierre van Houtryve Args.push_back(std::string(OpName)); 2916fa3d789dSPierre van Houtryve Res->setName(OpName); 2917fa3d789dSPierre van Houtryve return Res; 2918fa3d789dSPierre van Houtryve } 2919fa3d789dSPierre van Houtryve 2920fa3d789dSPierre van Houtryve if (isa<IntInit>(TheInit) || isa<BitInit>(TheInit)) { 2921fa3d789dSPierre van Houtryve if (!OpName.empty()) 2922fa3d789dSPierre van Houtryve error("Constant int or bit argument should not have a name!"); 2923fa3d789dSPierre van Houtryve if (isa<BitInit>(TheInit)) 2924fa3d789dSPierre van Houtryve TheInit = TheInit->convertInitializerTo(IntRecTy::get(RK)); 2925fa3d789dSPierre van Houtryve return makeIntrusiveRefCnt<TreePatternNode>(TheInit, 1); 2926fa3d789dSPierre van Houtryve } 2927fa3d789dSPierre van Houtryve 292862e2c7fbSRahul Joshi if (const BitsInit *BI = dyn_cast<BitsInit>(TheInit)) { 2929fa3d789dSPierre van Houtryve // Turn this into an IntInit. 293062e2c7fbSRahul Joshi const Init *II = BI->convertInitializerTo(IntRecTy::get(RK)); 2931fa3d789dSPierre van Houtryve if (!II || !isa<IntInit>(II)) 2932fa3d789dSPierre van Houtryve error("Bits value must be constants!"); 2933fa3d789dSPierre van Houtryve return II ? ParseTreePattern(II, OpName) : nullptr; 2934fa3d789dSPierre van Houtryve } 2935fa3d789dSPierre van Houtryve 293662e2c7fbSRahul Joshi const DagInit *Dag = dyn_cast<DagInit>(TheInit); 2937fa3d789dSPierre van Houtryve if (!Dag) { 2938fa3d789dSPierre van Houtryve TheInit->print(errs()); 2939fa3d789dSPierre van Houtryve error("Pattern has unexpected init kind!"); 2940fa3d789dSPierre van Houtryve return nullptr; 2941fa3d789dSPierre van Houtryve } 2942ec61311eSStephen Chou 294362e2c7fbSRahul Joshi auto ParseCastOperand = [this](const DagInit *Dag, StringRef OpName) { 2944ec61311eSStephen Chou if (Dag->getNumArgs() != 1) 2945ec61311eSStephen Chou error("Type cast only takes one operand!"); 2946ec61311eSStephen Chou 2947ec61311eSStephen Chou if (!OpName.empty()) 2948ec61311eSStephen Chou error("Type cast should not have a name!"); 2949ec61311eSStephen Chou 2950ec61311eSStephen Chou return ParseTreePattern(Dag->getArg(0), Dag->getArgNameStr(0)); 2951ec61311eSStephen Chou }; 2952ec61311eSStephen Chou 295362e2c7fbSRahul Joshi if (const ListInit *LI = dyn_cast<ListInit>(Dag->getOperator())) { 2954ec61311eSStephen Chou // If the operator is a list (of value types), then this must be "type cast" 2955ec61311eSStephen Chou // of a leaf node with multiple results. 2956ec61311eSStephen Chou TreePatternNodePtr New = ParseCastOperand(Dag, OpName); 2957ec61311eSStephen Chou 2958ec61311eSStephen Chou size_t NumTypes = New->getNumTypes(); 2959ec61311eSStephen Chou if (LI->empty() || LI->size() != NumTypes) 2960ec61311eSStephen Chou error("Invalid number of type casts!"); 2961ec61311eSStephen Chou 2962ec61311eSStephen Chou // Apply the type casts. 2963ec61311eSStephen Chou const CodeGenHwModes &CGH = getDAGPatterns().getTargetInfo().getHwModes(); 2964ec61311eSStephen Chou for (unsigned i = 0; i < std::min(NumTypes, LI->size()); ++i) 2965ec61311eSStephen Chou New->UpdateNodeType( 2966ec61311eSStephen Chou i, getValueTypeByHwMode(LI->getElementAsRecord(i), CGH), *this); 2967ec61311eSStephen Chou 2968ec61311eSStephen Chou return New; 2969ec61311eSStephen Chou } 2970ec61311eSStephen Chou 297162e2c7fbSRahul Joshi const DefInit *OpDef = dyn_cast<DefInit>(Dag->getOperator()); 2972fa3d789dSPierre van Houtryve if (!OpDef) { 2973fa3d789dSPierre van Houtryve error("Pattern has unexpected operator type!"); 2974fa3d789dSPierre van Houtryve return nullptr; 2975fa3d789dSPierre van Houtryve } 29763138eb50SRahul Joshi const Record *Operator = OpDef->getDef(); 2977fa3d789dSPierre van Houtryve 2978fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("ValueType")) { 2979fa3d789dSPierre van Houtryve // If the operator is a ValueType, then this must be "type cast" of a leaf 2980fa3d789dSPierre van Houtryve // node. 2981ec61311eSStephen Chou TreePatternNodePtr New = ParseCastOperand(Dag, OpName); 2982fa3d789dSPierre van Houtryve 2983ec61311eSStephen Chou if (New->getNumTypes() != 1) 2984ec61311eSStephen Chou error("ValueType cast can only have one type!"); 2985fa3d789dSPierre van Houtryve 2986fa3d789dSPierre van Houtryve // Apply the type cast. 2987fa3d789dSPierre van Houtryve const CodeGenHwModes &CGH = getDAGPatterns().getTargetInfo().getHwModes(); 2988fa3d789dSPierre van Houtryve New->UpdateNodeType(0, getValueTypeByHwMode(Operator, CGH), *this); 2989fa3d789dSPierre van Houtryve 2990fa3d789dSPierre van Houtryve return New; 2991fa3d789dSPierre van Houtryve } 2992fa3d789dSPierre van Houtryve 2993fa3d789dSPierre van Houtryve // Verify that this is something that makes sense for an operator. 2994fa3d789dSPierre van Houtryve if (!Operator->isSubClassOf("PatFrags") && 2995fa3d789dSPierre van Houtryve !Operator->isSubClassOf("SDNode") && 2996fa3d789dSPierre van Houtryve !Operator->isSubClassOf("Instruction") && 2997fa3d789dSPierre van Houtryve !Operator->isSubClassOf("SDNodeXForm") && 2998fa3d789dSPierre van Houtryve !Operator->isSubClassOf("Intrinsic") && 2999501a5834SSergei Barannikov !Operator->isSubClassOf("ComplexPattern") && Operator->getName() != "set") 3000fa3d789dSPierre van Houtryve error("Unrecognized node '" + Operator->getName() + "'!"); 3001fa3d789dSPierre van Houtryve 3002fa3d789dSPierre van Houtryve // Check to see if this is something that is illegal in an input pattern. 3003fa3d789dSPierre van Houtryve if (isInputPattern) { 3004fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("Instruction") || 3005fa3d789dSPierre van Houtryve Operator->isSubClassOf("SDNodeXForm")) 3006fa3d789dSPierre van Houtryve error("Cannot use '" + Operator->getName() + "' in an input pattern!"); 3007fa3d789dSPierre van Houtryve } else { 3008fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("Intrinsic")) 3009fa3d789dSPierre van Houtryve error("Cannot use '" + Operator->getName() + "' in an output pattern!"); 3010fa3d789dSPierre van Houtryve 3011fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("SDNode") && Operator->getName() != "imm" && 3012fa3d789dSPierre van Houtryve Operator->getName() != "timm" && Operator->getName() != "fpimm" && 3013fa3d789dSPierre van Houtryve Operator->getName() != "tglobaltlsaddr" && 3014fa3d789dSPierre van Houtryve Operator->getName() != "tconstpool" && 3015fa3d789dSPierre van Houtryve Operator->getName() != "tjumptable" && 3016fa3d789dSPierre van Houtryve Operator->getName() != "tframeindex" && 3017fa3d789dSPierre van Houtryve Operator->getName() != "texternalsym" && 3018fa3d789dSPierre van Houtryve Operator->getName() != "tblockaddress" && 3019fa3d789dSPierre van Houtryve Operator->getName() != "tglobaladdr" && Operator->getName() != "bb" && 3020fa3d789dSPierre van Houtryve Operator->getName() != "vt" && Operator->getName() != "mcsym") 3021fa3d789dSPierre van Houtryve error("Cannot use '" + Operator->getName() + "' in an output pattern!"); 3022fa3d789dSPierre van Houtryve } 3023fa3d789dSPierre van Houtryve 3024fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> Children; 3025fa3d789dSPierre van Houtryve 3026fa3d789dSPierre van Houtryve // Parse all the operands. 3027fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Dag->getNumArgs(); i != e; ++i) 3028fa3d789dSPierre van Houtryve Children.push_back(ParseTreePattern(Dag->getArg(i), Dag->getArgNameStr(i))); 3029fa3d789dSPierre van Houtryve 3030fa3d789dSPierre van Houtryve // Get the actual number of results before Operator is converted to an 3031fa3d789dSPierre van Houtryve // intrinsic node (which is hard-coded to have either zero or one result). 3032fa3d789dSPierre van Houtryve unsigned NumResults = GetNumNodeResults(Operator, CDP); 3033fa3d789dSPierre van Houtryve 3034fa3d789dSPierre van Houtryve // If the operator is an intrinsic, then this is just syntactic sugar for 3035fa3d789dSPierre van Houtryve // (intrinsic_* <number>, ..children..). Pick the right intrinsic node, and 3036fa3d789dSPierre van Houtryve // convert the intrinsic name to a number. 3037fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("Intrinsic")) { 3038fa3d789dSPierre van Houtryve const CodeGenIntrinsic &Int = getDAGPatterns().getIntrinsic(Operator); 3039fa3d789dSPierre van Houtryve unsigned IID = getDAGPatterns().getIntrinsicID(Operator) + 1; 3040fa3d789dSPierre van Houtryve 3041fa3d789dSPierre van Houtryve // If this intrinsic returns void, it must have side-effects and thus a 3042fa3d789dSPierre van Houtryve // chain. 3043fa3d789dSPierre van Houtryve if (Int.IS.RetTys.empty()) 3044fa3d789dSPierre van Houtryve Operator = getDAGPatterns().get_intrinsic_void_sdnode(); 3045fa3d789dSPierre van Houtryve else if (!Int.ME.doesNotAccessMemory() || Int.hasSideEffects) 3046fa3d789dSPierre van Houtryve // Has side-effects, requires chain. 3047fa3d789dSPierre van Houtryve Operator = getDAGPatterns().get_intrinsic_w_chain_sdnode(); 3048fa3d789dSPierre van Houtryve else // Otherwise, no chain. 3049fa3d789dSPierre van Houtryve Operator = getDAGPatterns().get_intrinsic_wo_chain_sdnode(); 3050fa3d789dSPierre van Houtryve 3051fa3d789dSPierre van Houtryve Children.insert(Children.begin(), makeIntrusiveRefCnt<TreePatternNode>( 3052fa3d789dSPierre van Houtryve IntInit::get(RK, IID), 1)); 3053fa3d789dSPierre van Houtryve } 3054fa3d789dSPierre van Houtryve 3055fa3d789dSPierre van Houtryve if (Operator->isSubClassOf("ComplexPattern")) { 3056fa3d789dSPierre van Houtryve for (unsigned i = 0; i < Children.size(); ++i) { 3057fa3d789dSPierre van Houtryve TreePatternNodePtr Child = Children[i]; 3058fa3d789dSPierre van Houtryve 3059fa3d789dSPierre van Houtryve if (Child->getName().empty()) 3060fa3d789dSPierre van Houtryve error("All arguments to a ComplexPattern must be named"); 3061fa3d789dSPierre van Houtryve 3062fa3d789dSPierre van Houtryve // Check that the ComplexPattern uses are consistent: "(MY_PAT $a, $b)" 3063fa3d789dSPierre van Houtryve // and "(MY_PAT $b, $a)" should not be allowed in the same pattern; 3064fa3d789dSPierre van Houtryve // neither should "(MY_PAT_1 $a, $b)" and "(MY_PAT_2 $a, $b)". 30654e8c9d28SJay Foad auto OperandId = std::pair(Operator, i); 3066b0a4b5b3SKazu Hirata auto [PrevOp, Inserted] = 3067b0a4b5b3SKazu Hirata ComplexPatternOperands.try_emplace(Child->getName(), OperandId); 3068b0a4b5b3SKazu Hirata if (!Inserted && PrevOp->getValue() != OperandId) { 3069fa3d789dSPierre van Houtryve error("All ComplexPattern operands must appear consistently: " 3070fa3d789dSPierre van Houtryve "in the same order in just one ComplexPattern instance."); 3071b0a4b5b3SKazu Hirata } 3072fa3d789dSPierre van Houtryve } 3073fa3d789dSPierre van Houtryve } 3074fa3d789dSPierre van Houtryve 3075fa3d789dSPierre van Houtryve TreePatternNodePtr Result = makeIntrusiveRefCnt<TreePatternNode>( 3076fa3d789dSPierre van Houtryve Operator, std::move(Children), NumResults); 3077fa3d789dSPierre van Houtryve Result->setName(OpName); 3078fa3d789dSPierre van Houtryve 3079fa3d789dSPierre van Houtryve if (Dag->getName()) { 3080fa3d789dSPierre van Houtryve assert(Result->getName().empty()); 3081fa3d789dSPierre van Houtryve Result->setName(Dag->getNameStr()); 3082fa3d789dSPierre van Houtryve } 3083fa3d789dSPierre van Houtryve return Result; 3084fa3d789dSPierre van Houtryve } 3085fa3d789dSPierre van Houtryve 3086fa3d789dSPierre van Houtryve /// SimplifyTree - See if we can simplify this tree to eliminate something that 3087fa3d789dSPierre van Houtryve /// will never match in favor of something obvious that will. This is here 3088fa3d789dSPierre van Houtryve /// strictly as a convenience to target authors because it allows them to write 3089fa3d789dSPierre van Houtryve /// more type generic things and have useless type casts fold away. 3090fa3d789dSPierre van Houtryve /// 3091fa3d789dSPierre van Houtryve /// This returns true if any change is made. 3092fa3d789dSPierre van Houtryve static bool SimplifyTree(TreePatternNodePtr &N) { 3093fa3d789dSPierre van Houtryve if (N->isLeaf()) 3094fa3d789dSPierre van Houtryve return false; 3095fa3d789dSPierre van Houtryve 3096fa3d789dSPierre van Houtryve // If we have a bitconvert with a resolved type and if the source and 3097fa3d789dSPierre van Houtryve // destination types are the same, then the bitconvert is useless, remove it. 3098fa3d789dSPierre van Houtryve // 3099fa3d789dSPierre van Houtryve // We make an exception if the types are completely empty. This can come up 3100fa3d789dSPierre van Houtryve // when the pattern being simplified is in the Fragments list of a PatFrags, 3101fa3d789dSPierre van Houtryve // so that the operand is just an untyped "node". In that situation we leave 3102fa3d789dSPierre van Houtryve // bitconverts unsimplified, and simplify them later once the fragment is 3103fa3d789dSPierre van Houtryve // expanded into its true context. 3104fa3d789dSPierre van Houtryve if (N->getOperator()->getName() == "bitconvert" && 3105fa3d789dSPierre van Houtryve N->getExtType(0).isValueTypeByHwMode(false) && 3106fa3d789dSPierre van Houtryve !N->getExtType(0).empty() && 3107fa3d789dSPierre van Houtryve N->getExtType(0) == N->getChild(0).getExtType(0) && 3108fa3d789dSPierre van Houtryve N->getName().empty()) { 3109c727b482SYingwei Zheng if (!N->getPredicateCalls().empty()) { 3110c727b482SYingwei Zheng std::string Str; 3111c727b482SYingwei Zheng raw_string_ostream OS(Str); 3112c727b482SYingwei Zheng OS << *N 3113c727b482SYingwei Zheng << "\n trivial bitconvert node should not have predicate calls\n"; 3114c727b482SYingwei Zheng PrintFatalError(Str); 3115c727b482SYingwei Zheng return false; 3116c727b482SYingwei Zheng } 3117fa3d789dSPierre van Houtryve N = N->getChildShared(0); 3118fa3d789dSPierre van Houtryve SimplifyTree(N); 3119fa3d789dSPierre van Houtryve return true; 3120fa3d789dSPierre van Houtryve } 3121fa3d789dSPierre van Houtryve 3122fa3d789dSPierre van Houtryve // Walk all children. 3123fa3d789dSPierre van Houtryve bool MadeChange = false; 3124fa3d789dSPierre van Houtryve for (unsigned i = 0, e = N->getNumChildren(); i != e; ++i) 3125fa3d789dSPierre van Houtryve MadeChange |= SimplifyTree(N->getChildSharedPtr(i)); 3126fa3d789dSPierre van Houtryve 3127fa3d789dSPierre van Houtryve return MadeChange; 3128fa3d789dSPierre van Houtryve } 3129fa3d789dSPierre van Houtryve 3130fa3d789dSPierre van Houtryve /// InferAllTypes - Infer/propagate as many types throughout the expression 3131fa3d789dSPierre van Houtryve /// patterns as possible. Return true if all types are inferred, false 3132fa3d789dSPierre van Houtryve /// otherwise. Flags an error if a type contradiction is found. 3133fa3d789dSPierre van Houtryve bool TreePattern::InferAllTypes( 3134fa3d789dSPierre van Houtryve const StringMap<SmallVector<TreePatternNode *, 1>> *InNamedTypes) { 3135fa3d789dSPierre van Houtryve if (NamedNodes.empty()) 3136fa3d789dSPierre van Houtryve ComputeNamedNodes(); 3137fa3d789dSPierre van Houtryve 3138fa3d789dSPierre van Houtryve bool MadeChange = true; 3139fa3d789dSPierre van Houtryve while (MadeChange) { 3140fa3d789dSPierre van Houtryve MadeChange = false; 3141fa3d789dSPierre van Houtryve for (TreePatternNodePtr &Tree : Trees) { 3142fa3d789dSPierre van Houtryve MadeChange |= Tree->ApplyTypeConstraints(*this, false); 3143fa3d789dSPierre van Houtryve MadeChange |= SimplifyTree(Tree); 3144fa3d789dSPierre van Houtryve } 3145fa3d789dSPierre van Houtryve 3146fa3d789dSPierre van Houtryve // If there are constraints on our named nodes, apply them. 3147fa3d789dSPierre van Houtryve for (auto &Entry : NamedNodes) { 3148fa3d789dSPierre van Houtryve SmallVectorImpl<TreePatternNode *> &Nodes = Entry.second; 3149fa3d789dSPierre van Houtryve 3150fa3d789dSPierre van Houtryve // If we have input named node types, propagate their types to the named 3151fa3d789dSPierre van Houtryve // values here. 3152fa3d789dSPierre van Houtryve if (InNamedTypes) { 3153b0a4b5b3SKazu Hirata auto InIter = InNamedTypes->find(Entry.getKey()); 3154b0a4b5b3SKazu Hirata if (InIter == InNamedTypes->end()) { 3155fa3d789dSPierre van Houtryve error("Node '" + std::string(Entry.getKey()) + 3156fa3d789dSPierre van Houtryve "' in output pattern but not input pattern"); 3157fa3d789dSPierre van Houtryve return true; 3158fa3d789dSPierre van Houtryve } 3159fa3d789dSPierre van Houtryve 3160b0a4b5b3SKazu Hirata const SmallVectorImpl<TreePatternNode *> &InNodes = InIter->second; 3161fa3d789dSPierre van Houtryve 3162fa3d789dSPierre van Houtryve // The input types should be fully resolved by now. 3163fa3d789dSPierre van Houtryve for (TreePatternNode *Node : Nodes) { 3164fa3d789dSPierre van Houtryve // If this node is a register class, and it is the root of the pattern 3165fa3d789dSPierre van Houtryve // then we're mapping something onto an input register. We allow 3166fa3d789dSPierre van Houtryve // changing the type of the input register in this case. This allows 3167fa3d789dSPierre van Houtryve // us to match things like: 3168fa3d789dSPierre van Houtryve // def : Pat<(v1i64 (bitconvert(v2i32 DPR:$src))), (v1i64 DPR:$src)>; 3169fa3d789dSPierre van Houtryve if (Node == Trees[0].get() && Node->isLeaf()) { 31703138eb50SRahul Joshi const DefInit *DI = dyn_cast<DefInit>(Node->getLeafValue()); 3171fa3d789dSPierre van Houtryve if (DI && (DI->getDef()->isSubClassOf("RegisterClass") || 3172fa3d789dSPierre van Houtryve DI->getDef()->isSubClassOf("RegisterOperand"))) 3173fa3d789dSPierre van Houtryve continue; 3174fa3d789dSPierre van Houtryve } 3175fa3d789dSPierre van Houtryve 3176fa3d789dSPierre van Houtryve assert(Node->getNumTypes() == 1 && InNodes[0]->getNumTypes() == 1 && 3177fa3d789dSPierre van Houtryve "FIXME: cannot name multiple result nodes yet"); 3178fa3d789dSPierre van Houtryve MadeChange |= 3179fa3d789dSPierre van Houtryve Node->UpdateNodeType(0, InNodes[0]->getExtType(0), *this); 3180fa3d789dSPierre van Houtryve } 3181fa3d789dSPierre van Houtryve } 3182fa3d789dSPierre van Houtryve 3183fa3d789dSPierre van Houtryve // If there are multiple nodes with the same name, they must all have the 3184fa3d789dSPierre van Houtryve // same type. 3185fa3d789dSPierre van Houtryve if (Entry.second.size() > 1) { 3186fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Nodes.size() - 1; i != e; ++i) { 3187fa3d789dSPierre van Houtryve TreePatternNode *N1 = Nodes[i], *N2 = Nodes[i + 1]; 3188fa3d789dSPierre van Houtryve assert(N1->getNumTypes() == 1 && N2->getNumTypes() == 1 && 3189fa3d789dSPierre van Houtryve "FIXME: cannot name multiple result nodes yet"); 3190fa3d789dSPierre van Houtryve 3191fa3d789dSPierre van Houtryve MadeChange |= N1->UpdateNodeType(0, N2->getExtType(0), *this); 3192fa3d789dSPierre van Houtryve MadeChange |= N2->UpdateNodeType(0, N1->getExtType(0), *this); 3193fa3d789dSPierre van Houtryve } 3194fa3d789dSPierre van Houtryve } 3195fa3d789dSPierre van Houtryve } 3196fa3d789dSPierre van Houtryve } 3197fa3d789dSPierre van Houtryve 3198fa3d789dSPierre van Houtryve bool HasUnresolvedTypes = false; 3199fa3d789dSPierre van Houtryve for (const TreePatternNodePtr &Tree : Trees) 3200fa3d789dSPierre van Houtryve HasUnresolvedTypes |= Tree->ContainsUnresolvedType(*this); 3201fa3d789dSPierre van Houtryve return !HasUnresolvedTypes; 3202fa3d789dSPierre van Houtryve } 3203fa3d789dSPierre van Houtryve 3204fa3d789dSPierre van Houtryve void TreePattern::print(raw_ostream &OS) const { 3205fa3d789dSPierre van Houtryve OS << getRecord()->getName(); 3206fa3d789dSPierre van Houtryve if (!Args.empty()) { 3207fa3d789dSPierre van Houtryve OS << "("; 3208fa3d789dSPierre van Houtryve ListSeparator LS; 3209fa3d789dSPierre van Houtryve for (const std::string &Arg : Args) 3210fa3d789dSPierre van Houtryve OS << LS << Arg; 3211fa3d789dSPierre van Houtryve OS << ")"; 3212fa3d789dSPierre van Houtryve } 3213fa3d789dSPierre van Houtryve OS << ": "; 3214fa3d789dSPierre van Houtryve 3215fa3d789dSPierre van Houtryve if (Trees.size() > 1) 3216fa3d789dSPierre van Houtryve OS << "[\n"; 3217fa3d789dSPierre van Houtryve for (const TreePatternNodePtr &Tree : Trees) { 3218fa3d789dSPierre van Houtryve OS << "\t"; 3219fa3d789dSPierre van Houtryve Tree->print(OS); 3220fa3d789dSPierre van Houtryve OS << "\n"; 3221fa3d789dSPierre van Houtryve } 3222fa3d789dSPierre van Houtryve 3223fa3d789dSPierre van Houtryve if (Trees.size() > 1) 3224fa3d789dSPierre van Houtryve OS << "]\n"; 3225fa3d789dSPierre van Houtryve } 3226fa3d789dSPierre van Houtryve 3227fa3d789dSPierre van Houtryve void TreePattern::dump() const { print(errs()); } 3228fa3d789dSPierre van Houtryve 3229fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 3230fa3d789dSPierre van Houtryve // CodeGenDAGPatterns implementation 3231fa3d789dSPierre van Houtryve // 3232fa3d789dSPierre van Houtryve 323387e8b530SRahul Joshi CodeGenDAGPatterns::CodeGenDAGPatterns(const RecordKeeper &R, 3234fa3d789dSPierre van Houtryve PatternRewriterFn PatternRewriter) 3235660cc986SRahul Joshi : Records(R), Target(R), Intrinsics(R), 323631ce47b5Sabhishek-kaushik22 LegalVTS(Target.getLegalValueTypes()), 323731ce47b5Sabhishek-kaushik22 PatternRewriter(std::move(PatternRewriter)) { 3238fa3d789dSPierre van Houtryve ParseNodeInfo(); 3239fa3d789dSPierre van Houtryve ParseNodeTransforms(); 3240fa3d789dSPierre van Houtryve ParseComplexPatterns(); 3241fa3d789dSPierre van Houtryve ParsePatternFragments(); 3242fa3d789dSPierre van Houtryve ParseDefaultOperands(); 3243fa3d789dSPierre van Houtryve ParseInstructions(); 3244fa3d789dSPierre van Houtryve ParsePatternFragments(/*OutFrags*/ true); 3245fa3d789dSPierre van Houtryve ParsePatterns(); 3246fa3d789dSPierre van Houtryve 3247fa3d789dSPierre van Houtryve // Generate variants. For example, commutative patterns can match 3248fa3d789dSPierre van Houtryve // multiple ways. Add them to PatternsToMatch as well. 3249fa3d789dSPierre van Houtryve GenerateVariants(); 3250fa3d789dSPierre van Houtryve 3251fa3d789dSPierre van Houtryve // Break patterns with parameterized types into a series of patterns, 3252fa3d789dSPierre van Houtryve // where each one has a fixed type and is predicated on the conditions 3253fa3d789dSPierre van Houtryve // of the associated HW mode. 3254fa3d789dSPierre van Houtryve ExpandHwModeBasedTypes(); 3255fa3d789dSPierre van Houtryve 3256fa3d789dSPierre van Houtryve // Infer instruction flags. For example, we can detect loads, 3257fa3d789dSPierre van Houtryve // stores, and side effects in many cases by examining an 3258fa3d789dSPierre van Houtryve // instruction's pattern. 3259fa3d789dSPierre van Houtryve InferInstructionFlags(); 3260fa3d789dSPierre van Houtryve 3261fa3d789dSPierre van Houtryve // Verify that instruction flags match the patterns. 3262fa3d789dSPierre van Houtryve VerifyInstructionFlags(); 3263fa3d789dSPierre van Houtryve } 3264fa3d789dSPierre van Houtryve 32653138eb50SRahul Joshi const Record *CodeGenDAGPatterns::getSDNodeNamed(StringRef Name) const { 32663138eb50SRahul Joshi const Record *N = Records.getDef(Name); 3267fa3d789dSPierre van Houtryve if (!N || !N->isSubClassOf("SDNode")) 3268fa3d789dSPierre van Houtryve PrintFatalError("Error getting SDNode '" + Name + "'!"); 3269fa3d789dSPierre van Houtryve return N; 3270fa3d789dSPierre van Houtryve } 3271fa3d789dSPierre van Houtryve 3272fa3d789dSPierre van Houtryve // Parse all of the SDNode definitions for the target, populating SDNodes. 3273fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::ParseNodeInfo() { 3274fa3d789dSPierre van Houtryve const CodeGenHwModes &CGH = getTargetInfo().getHwModes(); 3275fa3d789dSPierre van Houtryve 327687e8b530SRahul Joshi for (const Record *R : reverse(Records.getAllDerivedDefinitions("SDNode"))) 32774e8c9d28SJay Foad SDNodes.try_emplace(R, SDNodeInfo(R, CGH)); 3278fa3d789dSPierre van Houtryve 3279fa3d789dSPierre van Houtryve // Get the builtin intrinsic nodes. 3280fa3d789dSPierre van Houtryve intrinsic_void_sdnode = getSDNodeNamed("intrinsic_void"); 3281fa3d789dSPierre van Houtryve intrinsic_w_chain_sdnode = getSDNodeNamed("intrinsic_w_chain"); 3282fa3d789dSPierre van Houtryve intrinsic_wo_chain_sdnode = getSDNodeNamed("intrinsic_wo_chain"); 3283fa3d789dSPierre van Houtryve } 3284fa3d789dSPierre van Houtryve 3285fa3d789dSPierre van Houtryve /// ParseNodeTransforms - Parse all SDNodeXForm instances into the SDNodeXForms 3286fa3d789dSPierre van Houtryve /// map, and emit them to the file as functions. 3287fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::ParseNodeTransforms() { 328887e8b530SRahul Joshi for (const Record *XFormNode : 328987e8b530SRahul Joshi reverse(Records.getAllDerivedDefinitions("SDNodeXForm"))) { 329087e8b530SRahul Joshi const Record *SDNode = XFormNode->getValueAsDef("Opcode"); 3291fa3d789dSPierre van Houtryve StringRef Code = XFormNode->getValueAsString("XFormFunction"); 329287e8b530SRahul Joshi SDNodeXForms.insert({XFormNode, NodeXForm(SDNode, std::string(Code))}); 3293fa3d789dSPierre van Houtryve } 3294fa3d789dSPierre van Houtryve } 3295fa3d789dSPierre van Houtryve 3296fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::ParseComplexPatterns() { 329787e8b530SRahul Joshi for (const Record *R : 329887e8b530SRahul Joshi reverse(Records.getAllDerivedDefinitions("ComplexPattern"))) 329987e8b530SRahul Joshi ComplexPatterns.insert({R, R}); 3300fa3d789dSPierre van Houtryve } 3301fa3d789dSPierre van Houtryve 3302fa3d789dSPierre van Houtryve /// ParsePatternFragments - Parse all of the PatFrag definitions in the .td 3303fa3d789dSPierre van Houtryve /// file, building up the PatternFragments map. After we've collected them all, 3304fa3d789dSPierre van Houtryve /// inline fragments together as necessary, so that there are no references left 3305fa3d789dSPierre van Houtryve /// inside a pattern fragment to a pattern fragment. 3306fa3d789dSPierre van Houtryve /// 3307fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::ParsePatternFragments(bool OutFrags) { 3308fa3d789dSPierre van Houtryve // First step, parse all of the fragments. 330987e8b530SRahul Joshi ArrayRef<const Record *> Fragments = 331087e8b530SRahul Joshi Records.getAllDerivedDefinitions("PatFrags"); 331187e8b530SRahul Joshi for (const Record *Frag : Fragments) { 3312fa3d789dSPierre van Houtryve if (OutFrags != Frag->isSubClassOf("OutPatFrag")) 3313fa3d789dSPierre van Houtryve continue; 3314fa3d789dSPierre van Houtryve 331562e2c7fbSRahul Joshi const ListInit *LI = Frag->getValueAsListInit("Fragments"); 3316fa3d789dSPierre van Houtryve TreePattern *P = (PatternFragments[Frag] = std::make_unique<TreePattern>( 3317fa3d789dSPierre van Houtryve Frag, LI, !Frag->isSubClassOf("OutPatFrag"), *this)) 3318fa3d789dSPierre van Houtryve .get(); 3319fa3d789dSPierre van Houtryve 3320fa3d789dSPierre van Houtryve // Validate the argument list, converting it to set, to discard duplicates. 3321fa3d789dSPierre van Houtryve std::vector<std::string> &Args = P->getArgList(); 3322fa3d789dSPierre van Houtryve // Copy the args so we can take StringRefs to them. 3323fa3d789dSPierre van Houtryve auto ArgsCopy = Args; 3324fa3d789dSPierre van Houtryve SmallDenseSet<StringRef, 4> OperandsSet; 3325fa3d789dSPierre van Houtryve OperandsSet.insert(ArgsCopy.begin(), ArgsCopy.end()); 3326fa3d789dSPierre van Houtryve 3327fa3d789dSPierre van Houtryve if (OperandsSet.count("")) 3328fa3d789dSPierre van Houtryve P->error("Cannot have unnamed 'node' values in pattern fragment!"); 3329fa3d789dSPierre van Houtryve 3330fa3d789dSPierre van Houtryve // Parse the operands list. 333162e2c7fbSRahul Joshi const DagInit *OpsList = Frag->getValueAsDag("Operands"); 333262e2c7fbSRahul Joshi const DefInit *OpsOp = dyn_cast<DefInit>(OpsList->getOperator()); 3333fa3d789dSPierre van Houtryve // Special cases: ops == outs == ins. Different names are used to 3334fa3d789dSPierre van Houtryve // improve readability. 3335fa3d789dSPierre van Houtryve if (!OpsOp || (OpsOp->getDef()->getName() != "ops" && 3336fa3d789dSPierre van Houtryve OpsOp->getDef()->getName() != "outs" && 3337fa3d789dSPierre van Houtryve OpsOp->getDef()->getName() != "ins")) 3338fa3d789dSPierre van Houtryve P->error("Operands list should start with '(ops ... '!"); 3339fa3d789dSPierre van Houtryve 3340fa3d789dSPierre van Houtryve // Copy over the arguments. 3341fa3d789dSPierre van Houtryve Args.clear(); 3342fa3d789dSPierre van Houtryve for (unsigned j = 0, e = OpsList->getNumArgs(); j != e; ++j) { 3343fa3d789dSPierre van Houtryve if (!isa<DefInit>(OpsList->getArg(j)) || 3344fa3d789dSPierre van Houtryve cast<DefInit>(OpsList->getArg(j))->getDef()->getName() != "node") 3345fa3d789dSPierre van Houtryve P->error("Operands list should all be 'node' values."); 3346fa3d789dSPierre van Houtryve if (!OpsList->getArgName(j)) 3347fa3d789dSPierre van Houtryve P->error("Operands list should have names for each operand!"); 3348fa3d789dSPierre van Houtryve StringRef ArgNameStr = OpsList->getArgNameStr(j); 33495b5b241eSKazu Hirata if (!OperandsSet.erase(ArgNameStr)) 3350fa3d789dSPierre van Houtryve P->error("'" + ArgNameStr + 3351fa3d789dSPierre van Houtryve "' does not occur in pattern or was multiply specified!"); 3352fa3d789dSPierre van Houtryve Args.push_back(std::string(ArgNameStr)); 3353fa3d789dSPierre van Houtryve } 3354fa3d789dSPierre van Houtryve 3355fa3d789dSPierre van Houtryve if (!OperandsSet.empty()) 3356fa3d789dSPierre van Houtryve P->error("Operands list does not contain an entry for operand '" + 3357fa3d789dSPierre van Houtryve *OperandsSet.begin() + "'!"); 3358fa3d789dSPierre van Houtryve 3359fa3d789dSPierre van Houtryve // If there is a node transformation corresponding to this, keep track of 3360fa3d789dSPierre van Houtryve // it. 33613138eb50SRahul Joshi const Record *Transform = Frag->getValueAsDef("OperandTransform"); 3362fa3d789dSPierre van Houtryve if (!getSDNodeTransform(Transform).second.empty()) // not noop xform? 3363fa3d789dSPierre van Houtryve for (const auto &T : P->getTrees()) 3364fa3d789dSPierre van Houtryve T->setTransformFn(Transform); 3365fa3d789dSPierre van Houtryve } 3366fa3d789dSPierre van Houtryve 3367fa3d789dSPierre van Houtryve // Now that we've parsed all of the tree fragments, do a closure on them so 3368fa3d789dSPierre van Houtryve // that there are not references to PatFrags left inside of them. 336987e8b530SRahul Joshi for (const Record *Frag : Fragments) { 3370fa3d789dSPierre van Houtryve if (OutFrags != Frag->isSubClassOf("OutPatFrag")) 3371fa3d789dSPierre van Houtryve continue; 3372fa3d789dSPierre van Houtryve 3373fa3d789dSPierre van Houtryve TreePattern &ThePat = *PatternFragments[Frag]; 3374fa3d789dSPierre van Houtryve ThePat.InlinePatternFragments(); 3375fa3d789dSPierre van Houtryve 3376fa3d789dSPierre van Houtryve // Infer as many types as possible. Don't worry about it if we don't infer 3377fa3d789dSPierre van Houtryve // all of them, some may depend on the inputs of the pattern. Also, don't 3378fa3d789dSPierre van Houtryve // validate type sets; validation may cause spurious failures e.g. if a 3379fa3d789dSPierre van Houtryve // fragment needs floating-point types but the current target does not have 3380fa3d789dSPierre van Houtryve // any (this is only an error if that fragment is ever used!). 3381fa3d789dSPierre van Houtryve { 3382fa3d789dSPierre van Houtryve TypeInfer::SuppressValidation SV(ThePat.getInfer()); 3383fa3d789dSPierre van Houtryve ThePat.InferAllTypes(); 3384fa3d789dSPierre van Houtryve ThePat.resetError(); 3385fa3d789dSPierre van Houtryve } 3386fa3d789dSPierre van Houtryve 3387fa3d789dSPierre van Houtryve // If debugging, print out the pattern fragment result. 3388fa3d789dSPierre van Houtryve LLVM_DEBUG(ThePat.dump()); 3389fa3d789dSPierre van Houtryve } 3390fa3d789dSPierre van Houtryve } 3391fa3d789dSPierre van Houtryve 3392fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::ParseDefaultOperands() { 339387e8b530SRahul Joshi ArrayRef<const Record *> DefaultOps = 339487e8b530SRahul Joshi Records.getAllDerivedDefinitions("OperandWithDefaultOps"); 3395fa3d789dSPierre van Houtryve 3396fa3d789dSPierre van Houtryve // Find some SDNode. 3397fa3d789dSPierre van Houtryve assert(!SDNodes.empty() && "No SDNodes parsed?"); 339862e2c7fbSRahul Joshi const Init *SomeSDNode = SDNodes.begin()->first->getDefInit(); 3399fa3d789dSPierre van Houtryve 3400fa3d789dSPierre van Houtryve for (unsigned i = 0, e = DefaultOps.size(); i != e; ++i) { 340162e2c7fbSRahul Joshi const DagInit *DefaultInfo = DefaultOps[i]->getValueAsDag("DefaultOps"); 3402fa3d789dSPierre van Houtryve 3403fa3d789dSPierre van Houtryve // Clone the DefaultInfo dag node, changing the operator from 'ops' to 3404fa3d789dSPierre van Houtryve // SomeSDnode so that we can parse this. 340562e2c7fbSRahul Joshi std::vector<std::pair<const Init *, const StringInit *>> Ops; 3406fa3d789dSPierre van Houtryve for (unsigned op = 0, e = DefaultInfo->getNumArgs(); op != e; ++op) 34074e8c9d28SJay Foad Ops.emplace_back(DefaultInfo->getArg(op), DefaultInfo->getArgName(op)); 340862e2c7fbSRahul Joshi const DagInit *DI = DagInit::get(SomeSDNode, nullptr, Ops); 3409fa3d789dSPierre van Houtryve 3410fa3d789dSPierre van Houtryve // Create a TreePattern to parse this. 3411fa3d789dSPierre van Houtryve TreePattern P(DefaultOps[i], DI, false, *this); 3412fa3d789dSPierre van Houtryve assert(P.getNumTrees() == 1 && "This ctor can only produce one tree!"); 3413fa3d789dSPierre van Houtryve 3414fa3d789dSPierre van Houtryve // Copy the operands over into a DAGDefaultOperand. 3415fa3d789dSPierre van Houtryve DAGDefaultOperand DefaultOpInfo; 3416fa3d789dSPierre van Houtryve 3417fa3d789dSPierre van Houtryve const TreePatternNodePtr &T = P.getTree(0); 3418fa3d789dSPierre van Houtryve for (unsigned op = 0, e = T->getNumChildren(); op != e; ++op) { 3419fa3d789dSPierre van Houtryve TreePatternNodePtr TPN = T->getChildShared(op); 3420fa3d789dSPierre van Houtryve while (TPN->ApplyTypeConstraints(P, false)) 3421fa3d789dSPierre van Houtryve /* Resolve all types */; 3422fa3d789dSPierre van Houtryve 3423fa3d789dSPierre van Houtryve if (TPN->ContainsUnresolvedType(P)) { 3424fa3d789dSPierre van Houtryve PrintFatalError("Value #" + Twine(i) + " of OperandWithDefaultOps '" + 3425fa3d789dSPierre van Houtryve DefaultOps[i]->getName() + 3426fa3d789dSPierre van Houtryve "' doesn't have a concrete type!"); 3427fa3d789dSPierre van Houtryve } 3428fa3d789dSPierre van Houtryve DefaultOpInfo.DefaultOps.push_back(std::move(TPN)); 3429fa3d789dSPierre van Houtryve } 3430fa3d789dSPierre van Houtryve 3431fa3d789dSPierre van Houtryve // Insert it into the DefaultOperands map so we can find it later. 3432fa3d789dSPierre van Houtryve DefaultOperands[DefaultOps[i]] = DefaultOpInfo; 3433fa3d789dSPierre van Houtryve } 3434fa3d789dSPierre van Houtryve } 3435fa3d789dSPierre van Houtryve 3436fa3d789dSPierre van Houtryve /// HandleUse - Given "Pat" a leaf in the pattern, check to see if it is an 3437fa3d789dSPierre van Houtryve /// instruction input. Return true if this is a real use. 3438fa3d789dSPierre van Houtryve static bool HandleUse(TreePattern &I, TreePatternNodePtr Pat, 3439fa3d789dSPierre van Houtryve std::map<std::string, TreePatternNodePtr> &InstInputs) { 3440fa3d789dSPierre van Houtryve // No name -> not interesting. 3441fa3d789dSPierre van Houtryve if (Pat->getName().empty()) { 3442fa3d789dSPierre van Houtryve if (Pat->isLeaf()) { 34433138eb50SRahul Joshi const DefInit *DI = dyn_cast<DefInit>(Pat->getLeafValue()); 3444fa3d789dSPierre van Houtryve if (DI && (DI->getDef()->isSubClassOf("RegisterClass") || 3445fa3d789dSPierre van Houtryve DI->getDef()->isSubClassOf("RegisterOperand"))) 3446fa3d789dSPierre van Houtryve I.error("Input " + DI->getDef()->getName() + " must be named!"); 3447fa3d789dSPierre van Houtryve } 3448fa3d789dSPierre van Houtryve return false; 3449fa3d789dSPierre van Houtryve } 3450fa3d789dSPierre van Houtryve 345137865681SRahul Joshi const Record *Rec; 3452fa3d789dSPierre van Houtryve if (Pat->isLeaf()) { 34533138eb50SRahul Joshi const DefInit *DI = dyn_cast<DefInit>(Pat->getLeafValue()); 3454fa3d789dSPierre van Houtryve if (!DI) 3455fa3d789dSPierre van Houtryve I.error("Input $" + Pat->getName() + " must be an identifier!"); 3456fa3d789dSPierre van Houtryve Rec = DI->getDef(); 3457fa3d789dSPierre van Houtryve } else { 3458fa3d789dSPierre van Houtryve Rec = Pat->getOperator(); 3459fa3d789dSPierre van Houtryve } 3460fa3d789dSPierre van Houtryve 3461fa3d789dSPierre van Houtryve // SRCVALUE nodes are ignored. 3462fa3d789dSPierre van Houtryve if (Rec->getName() == "srcvalue") 3463fa3d789dSPierre van Houtryve return false; 3464fa3d789dSPierre van Houtryve 3465fa3d789dSPierre van Houtryve TreePatternNodePtr &Slot = InstInputs[Pat->getName()]; 3466fa3d789dSPierre van Houtryve if (!Slot) { 3467fa3d789dSPierre van Houtryve Slot = Pat; 3468fa3d789dSPierre van Houtryve return true; 3469fa3d789dSPierre van Houtryve } 347037865681SRahul Joshi const Record *SlotRec; 3471fa3d789dSPierre van Houtryve if (Slot->isLeaf()) { 3472fa3d789dSPierre van Houtryve SlotRec = cast<DefInit>(Slot->getLeafValue())->getDef(); 3473fa3d789dSPierre van Houtryve } else { 3474fa3d789dSPierre van Houtryve assert(Slot->getNumChildren() == 0 && "can't be a use with children!"); 3475fa3d789dSPierre van Houtryve SlotRec = Slot->getOperator(); 3476fa3d789dSPierre van Houtryve } 3477fa3d789dSPierre van Houtryve 3478fa3d789dSPierre van Houtryve // Ensure that the inputs agree if we've already seen this input. 3479fa3d789dSPierre van Houtryve if (Rec != SlotRec) 3480fa3d789dSPierre van Houtryve I.error("All $" + Pat->getName() + " inputs must agree with each other"); 3481fa3d789dSPierre van Houtryve // Ensure that the types can agree as well. 3482fa3d789dSPierre van Houtryve Slot->UpdateNodeType(0, Pat->getExtType(0), I); 3483fa3d789dSPierre van Houtryve Pat->UpdateNodeType(0, Slot->getExtType(0), I); 3484fa3d789dSPierre van Houtryve if (Slot->getExtTypes() != Pat->getExtTypes()) 3485fa3d789dSPierre van Houtryve I.error("All $" + Pat->getName() + " inputs must agree with each other"); 3486fa3d789dSPierre van Houtryve return true; 3487fa3d789dSPierre van Houtryve } 3488fa3d789dSPierre van Houtryve 3489fa3d789dSPierre van Houtryve /// FindPatternInputsAndOutputs - Scan the specified TreePatternNode (which is 3490fa3d789dSPierre van Houtryve /// part of "I", the instruction), computing the set of inputs and outputs of 3491fa3d789dSPierre van Houtryve /// the pattern. Report errors if we see anything naughty. 3492fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::FindPatternInputsAndOutputs( 3493fa3d789dSPierre van Houtryve TreePattern &I, TreePatternNodePtr Pat, 3494fa3d789dSPierre van Houtryve std::map<std::string, TreePatternNodePtr> &InstInputs, 3495fa3d789dSPierre van Houtryve MapVector<std::string, TreePatternNodePtr, std::map<std::string, unsigned>> 3496fa3d789dSPierre van Houtryve &InstResults, 34973138eb50SRahul Joshi std::vector<const Record *> &InstImpResults) { 3498fa3d789dSPierre van Houtryve // The instruction pattern still has unresolved fragments. For *named* 3499fa3d789dSPierre van Houtryve // nodes we must resolve those here. This may not result in multiple 3500fa3d789dSPierre van Houtryve // alternatives. 3501fa3d789dSPierre van Houtryve if (!Pat->getName().empty()) { 3502fa3d789dSPierre van Houtryve TreePattern SrcPattern(I.getRecord(), Pat, true, *this); 3503fa3d789dSPierre van Houtryve SrcPattern.InlinePatternFragments(); 3504fa3d789dSPierre van Houtryve SrcPattern.InferAllTypes(); 3505fa3d789dSPierre van Houtryve Pat = SrcPattern.getOnlyTree(); 3506fa3d789dSPierre van Houtryve } 3507fa3d789dSPierre van Houtryve 3508fa3d789dSPierre van Houtryve if (Pat->isLeaf()) { 3509fa3d789dSPierre van Houtryve bool isUse = HandleUse(I, Pat, InstInputs); 3510fa3d789dSPierre van Houtryve if (!isUse && Pat->getTransformFn()) 3511fa3d789dSPierre van Houtryve I.error("Cannot specify a transform function for a non-input value!"); 3512fa3d789dSPierre van Houtryve return; 3513fa3d789dSPierre van Houtryve } 3514fa3d789dSPierre van Houtryve 3515fa3d789dSPierre van Houtryve if (Pat->getOperator()->getName() != "set") { 3516fa3d789dSPierre van Houtryve // If this is not a set, verify that the children nodes are not void typed, 3517fa3d789dSPierre van Houtryve // and recurse. 3518fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Pat->getNumChildren(); i != e; ++i) { 3519fa3d789dSPierre van Houtryve if (Pat->getChild(i).getNumTypes() == 0) 3520fa3d789dSPierre van Houtryve I.error("Cannot have void nodes inside of patterns!"); 3521fa3d789dSPierre van Houtryve FindPatternInputsAndOutputs(I, Pat->getChildShared(i), InstInputs, 3522fa3d789dSPierre van Houtryve InstResults, InstImpResults); 3523fa3d789dSPierre van Houtryve } 3524fa3d789dSPierre van Houtryve 3525fa3d789dSPierre van Houtryve // If this is a non-leaf node with no children, treat it basically as if 3526fa3d789dSPierre van Houtryve // it were a leaf. This handles nodes like (imm). 3527fa3d789dSPierre van Houtryve bool isUse = HandleUse(I, Pat, InstInputs); 3528fa3d789dSPierre van Houtryve 3529fa3d789dSPierre van Houtryve if (!isUse && Pat->getTransformFn()) 3530fa3d789dSPierre van Houtryve I.error("Cannot specify a transform function for a non-input value!"); 3531fa3d789dSPierre van Houtryve return; 3532fa3d789dSPierre van Houtryve } 3533fa3d789dSPierre van Houtryve 3534fa3d789dSPierre van Houtryve // Otherwise, this is a set, validate and collect instruction results. 3535fa3d789dSPierre van Houtryve if (Pat->getNumChildren() == 0) 3536fa3d789dSPierre van Houtryve I.error("set requires operands!"); 3537fa3d789dSPierre van Houtryve 3538fa3d789dSPierre van Houtryve if (Pat->getTransformFn()) 3539fa3d789dSPierre van Houtryve I.error("Cannot specify a transform function on a set node!"); 3540fa3d789dSPierre van Houtryve 3541fa3d789dSPierre van Houtryve // Check the set destinations. 3542fa3d789dSPierre van Houtryve unsigned NumDests = Pat->getNumChildren() - 1; 3543fa3d789dSPierre van Houtryve for (unsigned i = 0; i != NumDests; ++i) { 3544fa3d789dSPierre van Houtryve TreePatternNodePtr Dest = Pat->getChildShared(i); 3545fa3d789dSPierre van Houtryve // For set destinations we also must resolve fragments here. 3546fa3d789dSPierre van Houtryve TreePattern DestPattern(I.getRecord(), Dest, false, *this); 3547fa3d789dSPierre van Houtryve DestPattern.InlinePatternFragments(); 3548fa3d789dSPierre van Houtryve DestPattern.InferAllTypes(); 3549fa3d789dSPierre van Houtryve Dest = DestPattern.getOnlyTree(); 3550fa3d789dSPierre van Houtryve 3551fa3d789dSPierre van Houtryve if (!Dest->isLeaf()) 3552fa3d789dSPierre van Houtryve I.error("set destination should be a register!"); 3553fa3d789dSPierre van Houtryve 35543138eb50SRahul Joshi const DefInit *Val = dyn_cast<DefInit>(Dest->getLeafValue()); 3555fa3d789dSPierre van Houtryve if (!Val) { 3556fa3d789dSPierre van Houtryve I.error("set destination should be a register!"); 3557fa3d789dSPierre van Houtryve continue; 3558fa3d789dSPierre van Houtryve } 3559fa3d789dSPierre van Houtryve 3560fa3d789dSPierre van Houtryve if (Val->getDef()->isSubClassOf("RegisterClass") || 3561fa3d789dSPierre van Houtryve Val->getDef()->isSubClassOf("ValueType") || 3562fa3d789dSPierre van Houtryve Val->getDef()->isSubClassOf("RegisterOperand") || 3563fa3d789dSPierre van Houtryve Val->getDef()->isSubClassOf("PointerLikeRegClass")) { 3564fa3d789dSPierre van Houtryve if (Dest->getName().empty()) 3565fa3d789dSPierre van Houtryve I.error("set destination must have a name!"); 35660575815bSKazu Hirata if (!InstResults.insert_or_assign(Dest->getName(), Dest).second) 3567fa3d789dSPierre van Houtryve I.error("cannot set '" + Dest->getName() + "' multiple times"); 3568fa3d789dSPierre van Houtryve } else if (Val->getDef()->isSubClassOf("Register")) { 3569fa3d789dSPierre van Houtryve InstImpResults.push_back(Val->getDef()); 3570fa3d789dSPierre van Houtryve } else { 3571fa3d789dSPierre van Houtryve I.error("set destination should be a register!"); 3572fa3d789dSPierre van Houtryve } 3573fa3d789dSPierre van Houtryve } 3574fa3d789dSPierre van Houtryve 3575fa3d789dSPierre van Houtryve // Verify and collect info from the computation. 3576fa3d789dSPierre van Houtryve FindPatternInputsAndOutputs(I, Pat->getChildShared(NumDests), InstInputs, 3577fa3d789dSPierre van Houtryve InstResults, InstImpResults); 3578fa3d789dSPierre van Houtryve } 3579fa3d789dSPierre van Houtryve 3580fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 3581fa3d789dSPierre van Houtryve // Instruction Analysis 3582fa3d789dSPierre van Houtryve //===----------------------------------------------------------------------===// 3583fa3d789dSPierre van Houtryve 3584fa3d789dSPierre van Houtryve class InstAnalyzer { 3585fa3d789dSPierre van Houtryve const CodeGenDAGPatterns &CDP; 3586fa3d789dSPierre van Houtryve 3587fa3d789dSPierre van Houtryve public: 3588fa3d789dSPierre van Houtryve bool hasSideEffects; 3589fa3d789dSPierre van Houtryve bool mayStore; 3590fa3d789dSPierre van Houtryve bool mayLoad; 3591fa3d789dSPierre van Houtryve bool isBitcast; 3592fa3d789dSPierre van Houtryve bool isVariadic; 3593fa3d789dSPierre van Houtryve bool hasChain; 3594fa3d789dSPierre van Houtryve 3595fa3d789dSPierre van Houtryve InstAnalyzer(const CodeGenDAGPatterns &cdp) 3596fa3d789dSPierre van Houtryve : CDP(cdp), hasSideEffects(false), mayStore(false), mayLoad(false), 3597fa3d789dSPierre van Houtryve isBitcast(false), isVariadic(false), hasChain(false) {} 3598fa3d789dSPierre van Houtryve 3599fa3d789dSPierre van Houtryve void Analyze(const PatternToMatch &Pat) { 3600fa3d789dSPierre van Houtryve const TreePatternNode &N = Pat.getSrcPattern(); 3601fa3d789dSPierre van Houtryve AnalyzeNode(N); 3602fa3d789dSPierre van Houtryve // These properties are detected only on the root node. 3603fa3d789dSPierre van Houtryve isBitcast = IsNodeBitcast(N); 3604fa3d789dSPierre van Houtryve } 3605fa3d789dSPierre van Houtryve 3606fa3d789dSPierre van Houtryve private: 3607fa3d789dSPierre van Houtryve bool IsNodeBitcast(const TreePatternNode &N) const { 3608fa3d789dSPierre van Houtryve if (hasSideEffects || mayLoad || mayStore || isVariadic) 3609fa3d789dSPierre van Houtryve return false; 3610fa3d789dSPierre van Houtryve 3611fa3d789dSPierre van Houtryve if (N.isLeaf()) 3612fa3d789dSPierre van Houtryve return false; 3613fa3d789dSPierre van Houtryve if (N.getNumChildren() != 1 || !N.getChild(0).isLeaf()) 3614fa3d789dSPierre van Houtryve return false; 3615fa3d789dSPierre van Houtryve 3616fa3d789dSPierre van Houtryve if (N.getOperator()->isSubClassOf("ComplexPattern")) 3617fa3d789dSPierre van Houtryve return false; 3618fa3d789dSPierre van Houtryve 3619fa3d789dSPierre van Houtryve const SDNodeInfo &OpInfo = CDP.getSDNodeInfo(N.getOperator()); 3620fa3d789dSPierre van Houtryve if (OpInfo.getNumResults() != 1 || OpInfo.getNumOperands() != 1) 3621fa3d789dSPierre van Houtryve return false; 3622fa3d789dSPierre van Houtryve return OpInfo.getEnumName() == "ISD::BITCAST"; 3623fa3d789dSPierre van Houtryve } 3624fa3d789dSPierre van Houtryve 3625fa3d789dSPierre van Houtryve public: 3626fa3d789dSPierre van Houtryve void AnalyzeNode(const TreePatternNode &N) { 3627fa3d789dSPierre van Houtryve if (N.isLeaf()) { 36283138eb50SRahul Joshi if (const DefInit *DI = dyn_cast<DefInit>(N.getLeafValue())) { 36293138eb50SRahul Joshi const Record *LeafRec = DI->getDef(); 3630fa3d789dSPierre van Houtryve // Handle ComplexPattern leaves. 3631fa3d789dSPierre van Houtryve if (LeafRec->isSubClassOf("ComplexPattern")) { 3632fa3d789dSPierre van Houtryve const ComplexPattern &CP = CDP.getComplexPattern(LeafRec); 3633fa3d789dSPierre van Houtryve if (CP.hasProperty(SDNPMayStore)) 3634fa3d789dSPierre van Houtryve mayStore = true; 3635fa3d789dSPierre van Houtryve if (CP.hasProperty(SDNPMayLoad)) 3636fa3d789dSPierre van Houtryve mayLoad = true; 3637fa3d789dSPierre van Houtryve if (CP.hasProperty(SDNPSideEffect)) 3638fa3d789dSPierre van Houtryve hasSideEffects = true; 3639fa3d789dSPierre van Houtryve } 3640fa3d789dSPierre van Houtryve } 3641fa3d789dSPierre van Houtryve return; 3642fa3d789dSPierre van Houtryve } 3643fa3d789dSPierre van Houtryve 3644fa3d789dSPierre van Houtryve // Analyze children. 3645d1f51c67SSergei Barannikov for (const TreePatternNode &Child : N.children()) 3646d1f51c67SSergei Barannikov AnalyzeNode(Child); 3647fa3d789dSPierre van Houtryve 3648fa3d789dSPierre van Houtryve // Notice properties of the node. 3649fa3d789dSPierre van Houtryve if (N.NodeHasProperty(SDNPMayStore, CDP)) 3650fa3d789dSPierre van Houtryve mayStore = true; 3651fa3d789dSPierre van Houtryve if (N.NodeHasProperty(SDNPMayLoad, CDP)) 3652fa3d789dSPierre van Houtryve mayLoad = true; 3653fa3d789dSPierre van Houtryve if (N.NodeHasProperty(SDNPSideEffect, CDP)) 3654fa3d789dSPierre van Houtryve hasSideEffects = true; 3655fa3d789dSPierre van Houtryve if (N.NodeHasProperty(SDNPVariadic, CDP)) 3656fa3d789dSPierre van Houtryve isVariadic = true; 3657fa3d789dSPierre van Houtryve if (N.NodeHasProperty(SDNPHasChain, CDP)) 3658fa3d789dSPierre van Houtryve hasChain = true; 3659fa3d789dSPierre van Houtryve 3660fa3d789dSPierre van Houtryve if (const CodeGenIntrinsic *IntInfo = N.getIntrinsicInfo(CDP)) { 3661ace3bd05SJay Foad ModRefInfo MR = IntInfo->ME.getModRef(); 3662fa3d789dSPierre van Houtryve // If this is an intrinsic, analyze it. 3663fa3d789dSPierre van Houtryve if (isRefSet(MR)) 3664fa3d789dSPierre van Houtryve mayLoad = true; // These may load memory. 3665fa3d789dSPierre van Houtryve 3666fa3d789dSPierre van Houtryve if (isModSet(MR)) 3667fa3d789dSPierre van Houtryve mayStore = true; // Intrinsics that can write to memory are 'mayStore'. 3668fa3d789dSPierre van Houtryve 3669fa3d789dSPierre van Houtryve // Consider intrinsics that don't specify any restrictions on memory 3670fa3d789dSPierre van Houtryve // effects as having a side-effect. 3671fa3d789dSPierre van Houtryve if (IntInfo->ME == MemoryEffects::unknown() || IntInfo->hasSideEffects) 3672fa3d789dSPierre van Houtryve hasSideEffects = true; 3673fa3d789dSPierre van Houtryve } 3674fa3d789dSPierre van Houtryve } 3675fa3d789dSPierre van Houtryve }; 3676fa3d789dSPierre van Houtryve 3677fa3d789dSPierre van Houtryve static bool InferFromPattern(CodeGenInstruction &InstInfo, 367837865681SRahul Joshi const InstAnalyzer &PatInfo, 367937865681SRahul Joshi const Record *PatDef) { 3680fa3d789dSPierre van Houtryve bool Error = false; 3681fa3d789dSPierre van Houtryve 3682fa3d789dSPierre van Houtryve // Remember where InstInfo got its flags. 3683fa3d789dSPierre van Houtryve if (InstInfo.hasUndefFlags()) 3684fa3d789dSPierre van Houtryve InstInfo.InferredFrom = PatDef; 3685fa3d789dSPierre van Houtryve 3686fa3d789dSPierre van Houtryve // Check explicitly set flags for consistency. 3687fa3d789dSPierre van Houtryve if (InstInfo.hasSideEffects != PatInfo.hasSideEffects && 3688fa3d789dSPierre van Houtryve !InstInfo.hasSideEffects_Unset) { 3689fa3d789dSPierre van Houtryve // Allow explicitly setting hasSideEffects = 1 on instructions, even when 3690fa3d789dSPierre van Houtryve // the pattern has no side effects. That could be useful for div/rem 3691fa3d789dSPierre van Houtryve // instructions that may trap. 3692fa3d789dSPierre van Houtryve if (!InstInfo.hasSideEffects) { 3693fa3d789dSPierre van Houtryve Error = true; 3694fa3d789dSPierre van Houtryve PrintError(PatDef->getLoc(), "Pattern doesn't match hasSideEffects = " + 3695fa3d789dSPierre van Houtryve Twine(InstInfo.hasSideEffects)); 3696fa3d789dSPierre van Houtryve } 3697fa3d789dSPierre van Houtryve } 3698fa3d789dSPierre van Houtryve 3699fa3d789dSPierre van Houtryve if (InstInfo.mayStore != PatInfo.mayStore && !InstInfo.mayStore_Unset) { 3700fa3d789dSPierre van Houtryve Error = true; 3701fa3d789dSPierre van Houtryve PrintError(PatDef->getLoc(), 3702fa3d789dSPierre van Houtryve "Pattern doesn't match mayStore = " + Twine(InstInfo.mayStore)); 3703fa3d789dSPierre van Houtryve } 3704fa3d789dSPierre van Houtryve 3705fa3d789dSPierre van Houtryve if (InstInfo.mayLoad != PatInfo.mayLoad && !InstInfo.mayLoad_Unset) { 3706fa3d789dSPierre van Houtryve // Allow explicitly setting mayLoad = 1, even when the pattern has no loads. 3707fa3d789dSPierre van Houtryve // Some targets translate immediates to loads. 3708fa3d789dSPierre van Houtryve if (!InstInfo.mayLoad) { 3709fa3d789dSPierre van Houtryve Error = true; 3710fa3d789dSPierre van Houtryve PrintError(PatDef->getLoc(), 3711fa3d789dSPierre van Houtryve "Pattern doesn't match mayLoad = " + Twine(InstInfo.mayLoad)); 3712fa3d789dSPierre van Houtryve } 3713fa3d789dSPierre van Houtryve } 3714fa3d789dSPierre van Houtryve 3715fa3d789dSPierre van Houtryve // Transfer inferred flags. 3716fa3d789dSPierre van Houtryve InstInfo.hasSideEffects |= PatInfo.hasSideEffects; 3717fa3d789dSPierre van Houtryve InstInfo.mayStore |= PatInfo.mayStore; 3718fa3d789dSPierre van Houtryve InstInfo.mayLoad |= PatInfo.mayLoad; 3719fa3d789dSPierre van Houtryve 3720fa3d789dSPierre van Houtryve // These flags are silently added without any verification. 3721fa3d789dSPierre van Houtryve // FIXME: To match historical behavior of TableGen, for now add those flags 3722fa3d789dSPierre van Houtryve // only when we're inferring from the primary instruction pattern. 3723fa3d789dSPierre van Houtryve if (PatDef->isSubClassOf("Instruction")) { 3724fa3d789dSPierre van Houtryve InstInfo.isBitcast |= PatInfo.isBitcast; 3725fa3d789dSPierre van Houtryve InstInfo.hasChain |= PatInfo.hasChain; 3726fa3d789dSPierre van Houtryve InstInfo.hasChain_Inferred = true; 3727fa3d789dSPierre van Houtryve } 3728fa3d789dSPierre van Houtryve 3729fa3d789dSPierre van Houtryve // Don't infer isVariadic. This flag means something different on SDNodes and 3730fa3d789dSPierre van Houtryve // instructions. For example, a CALL SDNode is variadic because it has the 3731fa3d789dSPierre van Houtryve // call arguments as operands, but a CALL instruction is not variadic - it 3732fa3d789dSPierre van Houtryve // has argument registers as implicit, not explicit uses. 3733fa3d789dSPierre van Houtryve 3734fa3d789dSPierre van Houtryve return Error; 3735fa3d789dSPierre van Houtryve } 3736fa3d789dSPierre van Houtryve 3737fa3d789dSPierre van Houtryve /// hasNullFragReference - Return true if the DAG has any reference to the 3738fa3d789dSPierre van Houtryve /// null_frag operator. 373962e2c7fbSRahul Joshi static bool hasNullFragReference(const DagInit *DI) { 374062e2c7fbSRahul Joshi const DefInit *OpDef = dyn_cast<DefInit>(DI->getOperator()); 3741fa3d789dSPierre van Houtryve if (!OpDef) 3742fa3d789dSPierre van Houtryve return false; 3743d256b9e8SRahul Joshi const Record *Operator = OpDef->getDef(); 3744fa3d789dSPierre van Houtryve 3745fa3d789dSPierre van Houtryve // If this is the null fragment, return true. 3746fa3d789dSPierre van Houtryve if (Operator->getName() == "null_frag") 3747fa3d789dSPierre van Houtryve return true; 3748fa3d789dSPierre van Houtryve // If any of the arguments reference the null fragment, return true. 3749fa3d789dSPierre van Houtryve for (unsigned i = 0, e = DI->getNumArgs(); i != e; ++i) { 3750fa3d789dSPierre van Houtryve if (auto Arg = dyn_cast<DefInit>(DI->getArg(i))) 3751fa3d789dSPierre van Houtryve if (Arg->getDef()->getName() == "null_frag") 3752fa3d789dSPierre van Houtryve return true; 375362e2c7fbSRahul Joshi const DagInit *Arg = dyn_cast<DagInit>(DI->getArg(i)); 3754fa3d789dSPierre van Houtryve if (Arg && hasNullFragReference(Arg)) 3755fa3d789dSPierre van Houtryve return true; 3756fa3d789dSPierre van Houtryve } 3757fa3d789dSPierre van Houtryve 3758fa3d789dSPierre van Houtryve return false; 3759fa3d789dSPierre van Houtryve } 3760fa3d789dSPierre van Houtryve 3761fa3d789dSPierre van Houtryve /// hasNullFragReference - Return true if any DAG in the list references 3762fa3d789dSPierre van Houtryve /// the null_frag operator. 376362e2c7fbSRahul Joshi static bool hasNullFragReference(const ListInit *LI) { 376462e2c7fbSRahul Joshi for (const Init *I : LI->getValues()) { 376562e2c7fbSRahul Joshi const DagInit *DI = dyn_cast<DagInit>(I); 3766fa3d789dSPierre van Houtryve assert(DI && "non-dag in an instruction Pattern list?!"); 3767fa3d789dSPierre van Houtryve if (hasNullFragReference(DI)) 3768fa3d789dSPierre van Houtryve return true; 3769fa3d789dSPierre van Houtryve } 3770fa3d789dSPierre van Houtryve return false; 3771fa3d789dSPierre van Houtryve } 3772fa3d789dSPierre van Houtryve 3773fa3d789dSPierre van Houtryve /// Get all the instructions in a tree. 3774fa3d789dSPierre van Houtryve static void getInstructionsInTree(TreePatternNode &Tree, 377537865681SRahul Joshi SmallVectorImpl<const Record *> &Instrs) { 3776fa3d789dSPierre van Houtryve if (Tree.isLeaf()) 3777fa3d789dSPierre van Houtryve return; 3778fa3d789dSPierre van Houtryve if (Tree.getOperator()->isSubClassOf("Instruction")) 3779fa3d789dSPierre van Houtryve Instrs.push_back(Tree.getOperator()); 3780d1f51c67SSergei Barannikov for (TreePatternNode &Child : Tree.children()) 3781d1f51c67SSergei Barannikov getInstructionsInTree(Child, Instrs); 3782fa3d789dSPierre van Houtryve } 3783fa3d789dSPierre van Houtryve 3784fa3d789dSPierre van Houtryve /// Check the class of a pattern leaf node against the instruction operand it 3785fa3d789dSPierre van Houtryve /// represents. 37863138eb50SRahul Joshi static bool checkOperandClass(CGIOperandList::OperandInfo &OI, 37873138eb50SRahul Joshi const Record *Leaf) { 3788fa3d789dSPierre van Houtryve if (OI.Rec == Leaf) 3789fa3d789dSPierre van Houtryve return true; 3790fa3d789dSPierre van Houtryve 3791fa3d789dSPierre van Houtryve // Allow direct value types to be used in instruction set patterns. 3792fa3d789dSPierre van Houtryve // The type will be checked later. 3793fa3d789dSPierre van Houtryve if (Leaf->isSubClassOf("ValueType")) 3794fa3d789dSPierre van Houtryve return true; 3795fa3d789dSPierre van Houtryve 3796fa3d789dSPierre van Houtryve // Patterns can also be ComplexPattern instances. 3797fa3d789dSPierre van Houtryve if (Leaf->isSubClassOf("ComplexPattern")) 3798fa3d789dSPierre van Houtryve return true; 3799fa3d789dSPierre van Houtryve 3800fa3d789dSPierre van Houtryve return false; 3801fa3d789dSPierre van Houtryve } 3802fa3d789dSPierre van Houtryve 3803fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::parseInstructionPattern(CodeGenInstruction &CGI, 38043138eb50SRahul Joshi const ListInit *Pat, 3805fa3d789dSPierre van Houtryve DAGInstMap &DAGInsts) { 3806fa3d789dSPierre van Houtryve 3807fa3d789dSPierre van Houtryve assert(!DAGInsts.count(CGI.TheDef) && "Instruction already parsed!"); 3808fa3d789dSPierre van Houtryve 3809fa3d789dSPierre van Houtryve // Parse the instruction. 3810fa3d789dSPierre van Houtryve TreePattern I(CGI.TheDef, Pat, true, *this); 3811fa3d789dSPierre van Houtryve 3812fa3d789dSPierre van Houtryve // InstInputs - Keep track of all of the inputs of the instruction, along 3813fa3d789dSPierre van Houtryve // with the record they are declared as. 3814fa3d789dSPierre van Houtryve std::map<std::string, TreePatternNodePtr> InstInputs; 3815fa3d789dSPierre van Houtryve 3816fa3d789dSPierre van Houtryve // InstResults - Keep track of all the virtual registers that are 'set' 3817fa3d789dSPierre van Houtryve // in the instruction, including what reg class they are. 3818fa3d789dSPierre van Houtryve MapVector<std::string, TreePatternNodePtr, std::map<std::string, unsigned>> 3819fa3d789dSPierre van Houtryve InstResults; 3820fa3d789dSPierre van Houtryve 38213138eb50SRahul Joshi std::vector<const Record *> InstImpResults; 3822fa3d789dSPierre van Houtryve 3823fa3d789dSPierre van Houtryve // Verify that the top-level forms in the instruction are of void type, and 3824fa3d789dSPierre van Houtryve // fill in the InstResults map. 3825fa3d789dSPierre van Houtryve SmallString<32> TypesString; 3826fa3d789dSPierre van Houtryve for (unsigned j = 0, e = I.getNumTrees(); j != e; ++j) { 3827fa3d789dSPierre van Houtryve TypesString.clear(); 3828fa3d789dSPierre van Houtryve TreePatternNodePtr Pat = I.getTree(j); 3829fa3d789dSPierre van Houtryve if (Pat->getNumTypes() != 0) { 3830fa3d789dSPierre van Houtryve raw_svector_ostream OS(TypesString); 3831fa3d789dSPierre van Houtryve ListSeparator LS; 3832fa3d789dSPierre van Houtryve for (unsigned k = 0, ke = Pat->getNumTypes(); k != ke; ++k) { 3833fa3d789dSPierre van Houtryve OS << LS; 3834fa3d789dSPierre van Houtryve Pat->getExtType(k).writeToStream(OS); 3835fa3d789dSPierre van Houtryve } 3836fa3d789dSPierre van Houtryve I.error("Top-level forms in instruction pattern should have" 3837fa3d789dSPierre van Houtryve " void types, has types " + 3838fa3d789dSPierre van Houtryve OS.str()); 3839fa3d789dSPierre van Houtryve } 3840fa3d789dSPierre van Houtryve 3841fa3d789dSPierre van Houtryve // Find inputs and outputs, and verify the structure of the uses/defs. 3842fa3d789dSPierre van Houtryve FindPatternInputsAndOutputs(I, Pat, InstInputs, InstResults, 3843fa3d789dSPierre van Houtryve InstImpResults); 3844fa3d789dSPierre van Houtryve } 3845fa3d789dSPierre van Houtryve 3846fa3d789dSPierre van Houtryve // Now that we have inputs and outputs of the pattern, inspect the operands 3847fa3d789dSPierre van Houtryve // list for the instruction. This determines the order that operands are 3848fa3d789dSPierre van Houtryve // added to the machine instruction the node corresponds to. 3849fa3d789dSPierre van Houtryve unsigned NumResults = InstResults.size(); 3850fa3d789dSPierre van Houtryve 3851fa3d789dSPierre van Houtryve // Parse the operands list from the (ops) list, validating it. 3852fa3d789dSPierre van Houtryve assert(I.getArgList().empty() && "Args list should still be empty here!"); 3853fa3d789dSPierre van Houtryve 3854fa3d789dSPierre van Houtryve // Check that all of the results occur first in the list. 3855bdf02249SRahul Joshi std::vector<const Record *> Results; 3856fa3d789dSPierre van Houtryve std::vector<unsigned> ResultIndices; 3857fa3d789dSPierre van Houtryve SmallVector<TreePatternNodePtr, 2> ResNodes; 3858fa3d789dSPierre van Houtryve for (unsigned i = 0; i != NumResults; ++i) { 3859fa3d789dSPierre van Houtryve if (i == CGI.Operands.size()) { 3860fa3d789dSPierre van Houtryve const std::string &OpName = 3861fa3d789dSPierre van Houtryve llvm::find_if( 3862fa3d789dSPierre van Houtryve InstResults, 3863fa3d789dSPierre van Houtryve [](const std::pair<std::string, TreePatternNodePtr> &P) { 3864fa3d789dSPierre van Houtryve return P.second; 3865fa3d789dSPierre van Houtryve }) 3866fa3d789dSPierre van Houtryve ->first; 3867fa3d789dSPierre van Houtryve 3868fa3d789dSPierre van Houtryve I.error("'" + OpName + "' set but does not appear in operand list!"); 3869fa3d789dSPierre van Houtryve } 3870fa3d789dSPierre van Houtryve 3871fa3d789dSPierre van Houtryve const std::string &OpName = CGI.Operands[i].Name; 3872fa3d789dSPierre van Houtryve 3873fa3d789dSPierre van Houtryve // Check that it exists in InstResults. 3874fa3d789dSPierre van Houtryve auto InstResultIter = InstResults.find(OpName); 3875fa3d789dSPierre van Houtryve if (InstResultIter == InstResults.end() || !InstResultIter->second) 3876fa3d789dSPierre van Houtryve I.error("Operand $" + OpName + " does not exist in operand list!"); 3877fa3d789dSPierre van Houtryve 3878fa3d789dSPierre van Houtryve TreePatternNodePtr RNode = InstResultIter->second; 38793138eb50SRahul Joshi const Record *R = cast<DefInit>(RNode->getLeafValue())->getDef(); 3880fa3d789dSPierre van Houtryve ResNodes.push_back(std::move(RNode)); 3881fa3d789dSPierre van Houtryve if (!R) 3882fa3d789dSPierre van Houtryve I.error("Operand $" + OpName + 3883fa3d789dSPierre van Houtryve " should be a set destination: all " 3884fa3d789dSPierre van Houtryve "outputs must occur before inputs in operand list!"); 3885fa3d789dSPierre van Houtryve 3886fa3d789dSPierre van Houtryve if (!checkOperandClass(CGI.Operands[i], R)) 3887fa3d789dSPierre van Houtryve I.error("Operand $" + OpName + " class mismatch!"); 3888fa3d789dSPierre van Houtryve 3889fa3d789dSPierre van Houtryve // Remember the return type. 3890fa3d789dSPierre van Houtryve Results.push_back(CGI.Operands[i].Rec); 3891fa3d789dSPierre van Houtryve 3892fa3d789dSPierre van Houtryve // Remember the result index. 3893fa3d789dSPierre van Houtryve ResultIndices.push_back(std::distance(InstResults.begin(), InstResultIter)); 3894fa3d789dSPierre van Houtryve 3895fa3d789dSPierre van Houtryve // Okay, this one checks out. 3896fa3d789dSPierre van Houtryve InstResultIter->second = nullptr; 3897fa3d789dSPierre van Houtryve } 3898fa3d789dSPierre van Houtryve 3899fa3d789dSPierre van Houtryve // Loop over the inputs next. 3900fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> ResultNodeOperands; 3901bdf02249SRahul Joshi std::vector<const Record *> Operands; 3902fa3d789dSPierre van Houtryve for (unsigned i = NumResults, e = CGI.Operands.size(); i != e; ++i) { 3903fa3d789dSPierre van Houtryve CGIOperandList::OperandInfo &Op = CGI.Operands[i]; 3904fa3d789dSPierre van Houtryve const std::string &OpName = Op.Name; 3905cfadf3f6SShilei Tian if (OpName.empty()) { 3906fa3d789dSPierre van Houtryve I.error("Operand #" + Twine(i) + " in operands list has no name!"); 3907cfadf3f6SShilei Tian continue; 3908cfadf3f6SShilei Tian } 3909fa3d789dSPierre van Houtryve 3910b0a4b5b3SKazu Hirata auto InIter = InstInputs.find(OpName); 3911b0a4b5b3SKazu Hirata if (InIter == InstInputs.end()) { 3912fa3d789dSPierre van Houtryve // If this is an operand with a DefaultOps set filled in, we can ignore 3913fa3d789dSPierre van Houtryve // this. When we codegen it, we will do so as always executed. 3914fa3d789dSPierre van Houtryve if (Op.Rec->isSubClassOf("OperandWithDefaultOps")) { 3915fa3d789dSPierre van Houtryve // Does it have a non-empty DefaultOps field? If so, ignore this 3916fa3d789dSPierre van Houtryve // operand. 3917fa3d789dSPierre van Houtryve if (!getDefaultOperand(Op.Rec).DefaultOps.empty()) 3918fa3d789dSPierre van Houtryve continue; 3919fa3d789dSPierre van Houtryve } 3920fa3d789dSPierre van Houtryve I.error("Operand $" + OpName + 3921fa3d789dSPierre van Houtryve " does not appear in the instruction pattern"); 3922cfadf3f6SShilei Tian continue; 3923fa3d789dSPierre van Houtryve } 3924b0a4b5b3SKazu Hirata TreePatternNodePtr InVal = InIter->second; 3925b0a4b5b3SKazu Hirata InstInputs.erase(InIter); // It occurred, remove from map. 3926fa3d789dSPierre van Houtryve 3927fa3d789dSPierre van Houtryve if (InVal->isLeaf() && isa<DefInit>(InVal->getLeafValue())) { 39283138eb50SRahul Joshi const Record *InRec = cast<DefInit>(InVal->getLeafValue())->getDef(); 3929cfadf3f6SShilei Tian if (!checkOperandClass(Op, InRec)) { 3930fa3d789dSPierre van Houtryve I.error("Operand $" + OpName + 3931fa3d789dSPierre van Houtryve "'s register class disagrees" 3932fa3d789dSPierre van Houtryve " between the operand and pattern"); 3933cfadf3f6SShilei Tian continue; 3934cfadf3f6SShilei Tian } 3935fa3d789dSPierre van Houtryve } 3936fa3d789dSPierre van Houtryve Operands.push_back(Op.Rec); 3937fa3d789dSPierre van Houtryve 3938fa3d789dSPierre van Houtryve // Construct the result for the dest-pattern operand list. 3939fa3d789dSPierre van Houtryve TreePatternNodePtr OpNode = InVal->clone(); 3940fa3d789dSPierre van Houtryve 3941fa3d789dSPierre van Houtryve // No predicate is useful on the result. 3942fa3d789dSPierre van Houtryve OpNode->clearPredicateCalls(); 3943fa3d789dSPierre van Houtryve 3944fa3d789dSPierre van Houtryve // Promote the xform function to be an explicit node if set. 39453138eb50SRahul Joshi if (const Record *Xform = OpNode->getTransformFn()) { 3946fa3d789dSPierre van Houtryve OpNode->setTransformFn(nullptr); 3947fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> Children; 3948fa3d789dSPierre van Houtryve Children.push_back(OpNode); 3949fa3d789dSPierre van Houtryve OpNode = makeIntrusiveRefCnt<TreePatternNode>(Xform, std::move(Children), 3950fa3d789dSPierre van Houtryve OpNode->getNumTypes()); 3951fa3d789dSPierre van Houtryve } 3952fa3d789dSPierre van Houtryve 3953fa3d789dSPierre van Houtryve ResultNodeOperands.push_back(std::move(OpNode)); 3954fa3d789dSPierre van Houtryve } 3955fa3d789dSPierre van Houtryve 3956fa3d789dSPierre van Houtryve if (!InstInputs.empty()) 3957fa3d789dSPierre van Houtryve I.error("Input operand $" + InstInputs.begin()->first + 3958fa3d789dSPierre van Houtryve " occurs in pattern but not in operands list!"); 3959fa3d789dSPierre van Houtryve 3960fa3d789dSPierre van Houtryve TreePatternNodePtr ResultPattern = makeIntrusiveRefCnt<TreePatternNode>( 3961fa3d789dSPierre van Houtryve I.getRecord(), std::move(ResultNodeOperands), 3962fa3d789dSPierre van Houtryve GetNumNodeResults(I.getRecord(), *this)); 3963fa3d789dSPierre van Houtryve // Copy fully inferred output node types to instruction result pattern. 3964fa3d789dSPierre van Houtryve for (unsigned i = 0; i != NumResults; ++i) { 3965fa3d789dSPierre van Houtryve assert(ResNodes[i]->getNumTypes() == 1 && "FIXME: Unhandled"); 3966fa3d789dSPierre van Houtryve ResultPattern->setType(i, ResNodes[i]->getExtType(0)); 3967fa3d789dSPierre van Houtryve ResultPattern->setResultIndex(i, ResultIndices[i]); 3968fa3d789dSPierre van Houtryve } 3969fa3d789dSPierre van Houtryve 3970fa3d789dSPierre van Houtryve // FIXME: Assume only the first tree is the pattern. The others are clobber 3971fa3d789dSPierre van Houtryve // nodes. 3972fa3d789dSPierre van Houtryve TreePatternNodePtr Pattern = I.getTree(0); 3973fa3d789dSPierre van Houtryve TreePatternNodePtr SrcPattern; 3974fa3d789dSPierre van Houtryve if (Pattern->getOperator()->getName() == "set") { 3975fa3d789dSPierre van Houtryve SrcPattern = Pattern->getChild(Pattern->getNumChildren() - 1).clone(); 3976fa3d789dSPierre van Houtryve } else { 3977fa3d789dSPierre van Houtryve // Not a set (store or something?) 3978fa3d789dSPierre van Houtryve SrcPattern = Pattern; 3979fa3d789dSPierre van Houtryve } 3980fa3d789dSPierre van Houtryve 3981fa3d789dSPierre van Houtryve // Create and insert the instruction. 3982fa3d789dSPierre van Houtryve // FIXME: InstImpResults should not be part of DAGInstruction. 398337865681SRahul Joshi DAGInsts.try_emplace(I.getRecord(), std::move(Results), std::move(Operands), 3984fa3d789dSPierre van Houtryve std::move(InstImpResults), SrcPattern, ResultPattern); 3985fa3d789dSPierre van Houtryve 3986fa3d789dSPierre van Houtryve LLVM_DEBUG(I.dump()); 3987fa3d789dSPierre van Houtryve } 3988fa3d789dSPierre van Houtryve 3989fa3d789dSPierre van Houtryve /// ParseInstructions - Parse all of the instructions, inlining and resolving 3990fa3d789dSPierre van Houtryve /// any fragments involved. This populates the Instructions list with fully 3991fa3d789dSPierre van Houtryve /// resolved instructions. 3992fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::ParseInstructions() { 399387e8b530SRahul Joshi for (const Record *Instr : Records.getAllDerivedDefinitions("Instruction")) { 399462e2c7fbSRahul Joshi const ListInit *LI = nullptr; 3995fa3d789dSPierre van Houtryve 3996fa3d789dSPierre van Houtryve if (isa<ListInit>(Instr->getValueInit("Pattern"))) 3997fa3d789dSPierre van Houtryve LI = Instr->getValueAsListInit("Pattern"); 3998fa3d789dSPierre van Houtryve 3999fa3d789dSPierre van Houtryve // If there is no pattern, only collect minimal information about the 4000fa3d789dSPierre van Houtryve // instruction for its operand list. We have to assume that there is one 4001fa3d789dSPierre van Houtryve // result, as we have no detailed info. A pattern which references the 4002fa3d789dSPierre van Houtryve // null_frag operator is as-if no pattern were specified. Normally this 4003fa3d789dSPierre van Houtryve // is from a multiclass expansion w/ a SDPatternOperator passed in as 4004fa3d789dSPierre van Houtryve // null_frag. 4005fa3d789dSPierre van Houtryve if (!LI || LI->empty() || hasNullFragReference(LI)) { 4006bdf02249SRahul Joshi std::vector<const Record *> Results; 4007bdf02249SRahul Joshi std::vector<const Record *> Operands; 4008fa3d789dSPierre van Houtryve 4009fa3d789dSPierre van Houtryve CodeGenInstruction &InstInfo = Target.getInstruction(Instr); 4010fa3d789dSPierre van Houtryve 4011fa3d789dSPierre van Houtryve if (InstInfo.Operands.size() != 0) { 4012fa3d789dSPierre van Houtryve for (unsigned j = 0, e = InstInfo.Operands.NumDefs; j < e; ++j) 4013fa3d789dSPierre van Houtryve Results.push_back(InstInfo.Operands[j].Rec); 4014fa3d789dSPierre van Houtryve 4015fa3d789dSPierre van Houtryve // The rest are inputs. 4016fa3d789dSPierre van Houtryve for (unsigned j = InstInfo.Operands.NumDefs, 4017fa3d789dSPierre van Houtryve e = InstInfo.Operands.size(); 4018fa3d789dSPierre van Houtryve j < e; ++j) 4019fa3d789dSPierre van Houtryve Operands.push_back(InstInfo.Operands[j].Rec); 4020fa3d789dSPierre van Houtryve } 4021fa3d789dSPierre van Houtryve 4022fa3d789dSPierre van Houtryve // Create and insert the instruction. 4023fa3d789dSPierre van Houtryve Instructions.try_emplace(Instr, std::move(Results), std::move(Operands), 40243138eb50SRahul Joshi std::vector<const Record *>()); 4025fa3d789dSPierre van Houtryve continue; // no pattern. 4026fa3d789dSPierre van Houtryve } 4027fa3d789dSPierre van Houtryve 4028fa3d789dSPierre van Houtryve CodeGenInstruction &CGI = Target.getInstruction(Instr); 4029fa3d789dSPierre van Houtryve parseInstructionPattern(CGI, LI, Instructions); 4030fa3d789dSPierre van Houtryve } 4031fa3d789dSPierre van Houtryve 4032fa3d789dSPierre van Houtryve // If we can, convert the instructions to be patterns that are matched! 403337865681SRahul Joshi for (const auto &[Instr, TheInst] : Instructions) { 4034fa3d789dSPierre van Houtryve TreePatternNodePtr SrcPattern = TheInst.getSrcPattern(); 4035fa3d789dSPierre van Houtryve TreePatternNodePtr ResultPattern = TheInst.getResultPattern(); 4036fa3d789dSPierre van Houtryve 4037fa3d789dSPierre van Houtryve if (SrcPattern && ResultPattern) { 4038fa3d789dSPierre van Houtryve TreePattern Pattern(Instr, SrcPattern, true, *this); 4039fa3d789dSPierre van Houtryve TreePattern Result(Instr, ResultPattern, false, *this); 4040fa3d789dSPierre van Houtryve ParseOnePattern(Instr, Pattern, Result, TheInst.getImpResults()); 4041fa3d789dSPierre van Houtryve } 4042fa3d789dSPierre van Houtryve } 4043fa3d789dSPierre van Houtryve } 4044fa3d789dSPierre van Houtryve 4045fa3d789dSPierre van Houtryve typedef std::pair<TreePatternNode *, unsigned> NameRecord; 4046fa3d789dSPierre van Houtryve 4047fa3d789dSPierre van Houtryve static void FindNames(TreePatternNode &P, 4048fa3d789dSPierre van Houtryve std::map<std::string, NameRecord> &Names, 4049fa3d789dSPierre van Houtryve TreePattern *PatternTop) { 4050fa3d789dSPierre van Houtryve if (!P.getName().empty()) { 4051fa3d789dSPierre van Houtryve NameRecord &Rec = Names[P.getName()]; 4052fa3d789dSPierre van Houtryve // If this is the first instance of the name, remember the node. 4053fa3d789dSPierre van Houtryve if (Rec.second++ == 0) 4054fa3d789dSPierre van Houtryve Rec.first = &P; 4055fa3d789dSPierre van Houtryve else if (Rec.first->getExtTypes() != P.getExtTypes()) 4056fa3d789dSPierre van Houtryve PatternTop->error("repetition of value: $" + P.getName() + 4057fa3d789dSPierre van Houtryve " where different uses have different types!"); 4058fa3d789dSPierre van Houtryve } 4059fa3d789dSPierre van Houtryve 4060fa3d789dSPierre van Houtryve if (!P.isLeaf()) { 4061d1f51c67SSergei Barannikov for (TreePatternNode &Child : P.children()) 4062d1f51c67SSergei Barannikov FindNames(Child, Names, PatternTop); 4063fa3d789dSPierre van Houtryve } 4064fa3d789dSPierre van Houtryve } 4065fa3d789dSPierre van Houtryve 4066fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::AddPatternToMatch(TreePattern *Pattern, 4067fa3d789dSPierre van Houtryve PatternToMatch &&PTM) { 4068fa3d789dSPierre van Houtryve // Do some sanity checking on the pattern we're about to match. 4069fa3d789dSPierre van Houtryve std::string Reason; 4070fa3d789dSPierre van Houtryve if (!PTM.getSrcPattern().canPatternMatch(Reason, *this)) { 4071fa3d789dSPierre van Houtryve PrintWarning(Pattern->getRecord()->getLoc(), 4072fa3d789dSPierre van Houtryve Twine("Pattern can never match: ") + Reason); 4073fa3d789dSPierre van Houtryve return; 4074fa3d789dSPierre van Houtryve } 4075fa3d789dSPierre van Houtryve 4076fa3d789dSPierre van Houtryve // If the source pattern's root is a complex pattern, that complex pattern 4077fa3d789dSPierre van Houtryve // must specify the nodes it can potentially match. 4078fa3d789dSPierre van Houtryve if (const ComplexPattern *CP = 4079fa3d789dSPierre van Houtryve PTM.getSrcPattern().getComplexPatternInfo(*this)) 4080fa3d789dSPierre van Houtryve if (CP->getRootNodes().empty()) 4081fa3d789dSPierre van Houtryve Pattern->error("ComplexPattern at root must specify list of opcodes it" 4082fa3d789dSPierre van Houtryve " could match"); 4083fa3d789dSPierre van Houtryve 4084fa3d789dSPierre van Houtryve // Find all of the named values in the input and output, ensure they have the 4085fa3d789dSPierre van Houtryve // same type. 4086fa3d789dSPierre van Houtryve std::map<std::string, NameRecord> SrcNames, DstNames; 4087fa3d789dSPierre van Houtryve FindNames(PTM.getSrcPattern(), SrcNames, Pattern); 4088fa3d789dSPierre van Houtryve FindNames(PTM.getDstPattern(), DstNames, Pattern); 4089fa3d789dSPierre van Houtryve 4090fa3d789dSPierre van Houtryve // Scan all of the named values in the destination pattern, rejecting them if 4091fa3d789dSPierre van Houtryve // they don't exist in the input pattern. 4092fa3d789dSPierre van Houtryve for (const auto &Entry : DstNames) { 4093fa3d789dSPierre van Houtryve if (SrcNames[Entry.first].first == nullptr) 4094fa3d789dSPierre van Houtryve Pattern->error("Pattern has input without matching name in output: $" + 4095fa3d789dSPierre van Houtryve Entry.first); 4096fa3d789dSPierre van Houtryve } 4097fa3d789dSPierre van Houtryve 4098fa3d789dSPierre van Houtryve // Scan all of the named values in the source pattern, rejecting them if the 4099fa3d789dSPierre van Houtryve // name isn't used in the dest, and isn't used to tie two values together. 4100fa3d789dSPierre van Houtryve for (const auto &Entry : SrcNames) 4101fa3d789dSPierre van Houtryve if (DstNames[Entry.first].first == nullptr && 4102fa3d789dSPierre van Houtryve SrcNames[Entry.first].second == 1) 4103fa3d789dSPierre van Houtryve Pattern->error("Pattern has dead named input: $" + Entry.first); 4104fa3d789dSPierre van Houtryve 4105fa3d789dSPierre van Houtryve PatternsToMatch.push_back(std::move(PTM)); 4106fa3d789dSPierre van Houtryve } 4107fa3d789dSPierre van Houtryve 4108fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::InferInstructionFlags() { 4109fa3d789dSPierre van Houtryve ArrayRef<const CodeGenInstruction *> Instructions = 4110fa3d789dSPierre van Houtryve Target.getInstructionsByEnumValue(); 4111fa3d789dSPierre van Houtryve 4112fa3d789dSPierre van Houtryve unsigned Errors = 0; 4113fa3d789dSPierre van Houtryve 4114fa3d789dSPierre van Houtryve // Try to infer flags from all patterns in PatternToMatch. These include 4115fa3d789dSPierre van Houtryve // both the primary instruction patterns (which always come first) and 4116fa3d789dSPierre van Houtryve // patterns defined outside the instruction. 4117fa3d789dSPierre van Houtryve for (const PatternToMatch &PTM : ptms()) { 4118fa3d789dSPierre van Houtryve // We can only infer from single-instruction patterns, otherwise we won't 4119fa3d789dSPierre van Houtryve // know which instruction should get the flags. 412037865681SRahul Joshi SmallVector<const Record *, 8> PatInstrs; 4121fa3d789dSPierre van Houtryve getInstructionsInTree(PTM.getDstPattern(), PatInstrs); 4122fa3d789dSPierre van Houtryve if (PatInstrs.size() != 1) 4123fa3d789dSPierre van Houtryve continue; 4124fa3d789dSPierre van Houtryve 4125fa3d789dSPierre van Houtryve // Get the single instruction. 4126fa3d789dSPierre van Houtryve CodeGenInstruction &InstInfo = Target.getInstruction(PatInstrs.front()); 4127fa3d789dSPierre van Houtryve 4128fa3d789dSPierre van Houtryve // Only infer properties from the first pattern. We'll verify the others. 4129fa3d789dSPierre van Houtryve if (InstInfo.InferredFrom) 4130fa3d789dSPierre van Houtryve continue; 4131fa3d789dSPierre van Houtryve 4132fa3d789dSPierre van Houtryve InstAnalyzer PatInfo(*this); 4133fa3d789dSPierre van Houtryve PatInfo.Analyze(PTM); 4134fa3d789dSPierre van Houtryve Errors += InferFromPattern(InstInfo, PatInfo, PTM.getSrcRecord()); 4135fa3d789dSPierre van Houtryve } 4136fa3d789dSPierre van Houtryve 4137fa3d789dSPierre van Houtryve if (Errors) 4138fa3d789dSPierre van Houtryve PrintFatalError("pattern conflicts"); 4139fa3d789dSPierre van Houtryve 4140fa3d789dSPierre van Houtryve // If requested by the target, guess any undefined properties. 4141fa3d789dSPierre van Houtryve if (Target.guessInstructionProperties()) { 4142fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Instructions.size(); i != e; ++i) { 4143fa3d789dSPierre van Houtryve CodeGenInstruction *InstInfo = 4144fa3d789dSPierre van Houtryve const_cast<CodeGenInstruction *>(Instructions[i]); 4145fa3d789dSPierre van Houtryve if (InstInfo->InferredFrom) 4146fa3d789dSPierre van Houtryve continue; 4147fa3d789dSPierre van Houtryve // The mayLoad and mayStore flags default to false. 4148fa3d789dSPierre van Houtryve // Conservatively assume hasSideEffects if it wasn't explicit. 4149fa3d789dSPierre van Houtryve if (InstInfo->hasSideEffects_Unset) 4150fa3d789dSPierre van Houtryve InstInfo->hasSideEffects = true; 4151fa3d789dSPierre van Houtryve } 4152fa3d789dSPierre van Houtryve return; 4153fa3d789dSPierre van Houtryve } 4154fa3d789dSPierre van Houtryve 4155fa3d789dSPierre van Houtryve // Complain about any flags that are still undefined. 4156fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Instructions.size(); i != e; ++i) { 4157fa3d789dSPierre van Houtryve CodeGenInstruction *InstInfo = 4158fa3d789dSPierre van Houtryve const_cast<CodeGenInstruction *>(Instructions[i]); 4159fa3d789dSPierre van Houtryve if (InstInfo->InferredFrom) 4160fa3d789dSPierre van Houtryve continue; 4161fa3d789dSPierre van Houtryve if (InstInfo->hasSideEffects_Unset) 4162fa3d789dSPierre van Houtryve PrintError(InstInfo->TheDef->getLoc(), 4163fa3d789dSPierre van Houtryve "Can't infer hasSideEffects from patterns"); 4164fa3d789dSPierre van Houtryve if (InstInfo->mayStore_Unset) 4165fa3d789dSPierre van Houtryve PrintError(InstInfo->TheDef->getLoc(), 4166fa3d789dSPierre van Houtryve "Can't infer mayStore from patterns"); 4167fa3d789dSPierre van Houtryve if (InstInfo->mayLoad_Unset) 4168fa3d789dSPierre van Houtryve PrintError(InstInfo->TheDef->getLoc(), 4169fa3d789dSPierre van Houtryve "Can't infer mayLoad from patterns"); 4170fa3d789dSPierre van Houtryve } 4171fa3d789dSPierre van Houtryve } 4172fa3d789dSPierre van Houtryve 4173fa3d789dSPierre van Houtryve /// Verify instruction flags against pattern node properties. 4174fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::VerifyInstructionFlags() { 4175fa3d789dSPierre van Houtryve unsigned Errors = 0; 4176fa3d789dSPierre van Houtryve for (const PatternToMatch &PTM : ptms()) { 417737865681SRahul Joshi SmallVector<const Record *, 8> Instrs; 4178fa3d789dSPierre van Houtryve getInstructionsInTree(PTM.getDstPattern(), Instrs); 4179fa3d789dSPierre van Houtryve if (Instrs.empty()) 4180fa3d789dSPierre van Houtryve continue; 4181fa3d789dSPierre van Houtryve 4182fa3d789dSPierre van Houtryve // Count the number of instructions with each flag set. 4183fa3d789dSPierre van Houtryve unsigned NumSideEffects = 0; 4184fa3d789dSPierre van Houtryve unsigned NumStores = 0; 4185fa3d789dSPierre van Houtryve unsigned NumLoads = 0; 4186fa3d789dSPierre van Houtryve for (const Record *Instr : Instrs) { 4187fa3d789dSPierre van Houtryve const CodeGenInstruction &InstInfo = Target.getInstruction(Instr); 4188fa3d789dSPierre van Houtryve NumSideEffects += InstInfo.hasSideEffects; 4189fa3d789dSPierre van Houtryve NumStores += InstInfo.mayStore; 4190fa3d789dSPierre van Houtryve NumLoads += InstInfo.mayLoad; 4191fa3d789dSPierre van Houtryve } 4192fa3d789dSPierre van Houtryve 4193fa3d789dSPierre van Houtryve // Analyze the source pattern. 4194fa3d789dSPierre van Houtryve InstAnalyzer PatInfo(*this); 4195fa3d789dSPierre van Houtryve PatInfo.Analyze(PTM); 4196fa3d789dSPierre van Houtryve 4197fa3d789dSPierre van Houtryve // Collect error messages. 4198fa3d789dSPierre van Houtryve SmallVector<std::string, 4> Msgs; 4199fa3d789dSPierre van Houtryve 4200fa3d789dSPierre van Houtryve // Check for missing flags in the output. 4201fa3d789dSPierre van Houtryve // Permit extra flags for now at least. 4202fa3d789dSPierre van Houtryve if (PatInfo.hasSideEffects && !NumSideEffects) 4203fa3d789dSPierre van Houtryve Msgs.push_back("pattern has side effects, but hasSideEffects isn't set"); 4204fa3d789dSPierre van Houtryve 4205fa3d789dSPierre van Houtryve // Don't verify store flags on instructions with side effects. At least for 4206fa3d789dSPierre van Houtryve // intrinsics, side effects implies mayStore. 4207fa3d789dSPierre van Houtryve if (!PatInfo.hasSideEffects && PatInfo.mayStore && !NumStores) 4208fa3d789dSPierre van Houtryve Msgs.push_back("pattern may store, but mayStore isn't set"); 4209fa3d789dSPierre van Houtryve 4210fa3d789dSPierre van Houtryve // Similarly, mayStore implies mayLoad on intrinsics. 4211fa3d789dSPierre van Houtryve if (!PatInfo.mayStore && PatInfo.mayLoad && !NumLoads) 4212fa3d789dSPierre van Houtryve Msgs.push_back("pattern may load, but mayLoad isn't set"); 4213fa3d789dSPierre van Houtryve 4214fa3d789dSPierre van Houtryve // Print error messages. 4215fa3d789dSPierre van Houtryve if (Msgs.empty()) 4216fa3d789dSPierre van Houtryve continue; 4217fa3d789dSPierre van Houtryve ++Errors; 4218fa3d789dSPierre van Houtryve 4219fa3d789dSPierre van Houtryve for (const std::string &Msg : Msgs) 4220fa3d789dSPierre van Houtryve PrintError( 4221fa3d789dSPierre van Houtryve PTM.getSrcRecord()->getLoc(), 4222fa3d789dSPierre van Houtryve Twine(Msg) + " on the " + 4223fa3d789dSPierre van Houtryve (Instrs.size() == 1 ? "instruction" : "output instructions")); 4224fa3d789dSPierre van Houtryve // Provide the location of the relevant instruction definitions. 4225fa3d789dSPierre van Houtryve for (const Record *Instr : Instrs) { 4226fa3d789dSPierre van Houtryve if (Instr != PTM.getSrcRecord()) 4227fa3d789dSPierre van Houtryve PrintError(Instr->getLoc(), "defined here"); 4228fa3d789dSPierre van Houtryve const CodeGenInstruction &InstInfo = Target.getInstruction(Instr); 4229fa3d789dSPierre van Houtryve if (InstInfo.InferredFrom && InstInfo.InferredFrom != InstInfo.TheDef && 4230fa3d789dSPierre van Houtryve InstInfo.InferredFrom != PTM.getSrcRecord()) 4231fa3d789dSPierre van Houtryve PrintError(InstInfo.InferredFrom->getLoc(), "inferred from pattern"); 4232fa3d789dSPierre van Houtryve } 4233fa3d789dSPierre van Houtryve } 4234fa3d789dSPierre van Houtryve if (Errors) 4235fa3d789dSPierre van Houtryve PrintFatalError("Errors in DAG patterns"); 4236fa3d789dSPierre van Houtryve } 4237fa3d789dSPierre van Houtryve 4238fa3d789dSPierre van Houtryve /// Given a pattern result with an unresolved type, see if we can find one 4239fa3d789dSPierre van Houtryve /// instruction with an unresolved result type. Force this result type to an 4240fa3d789dSPierre van Houtryve /// arbitrary element if it's possible types to converge results. 4241fa3d789dSPierre van Houtryve static bool ForceArbitraryInstResultType(TreePatternNode &N, TreePattern &TP) { 4242fa3d789dSPierre van Houtryve if (N.isLeaf()) 4243fa3d789dSPierre van Houtryve return false; 4244fa3d789dSPierre van Houtryve 4245fa3d789dSPierre van Houtryve // Analyze children. 4246d1f51c67SSergei Barannikov for (TreePatternNode &Child : N.children()) 4247d1f51c67SSergei Barannikov if (ForceArbitraryInstResultType(Child, TP)) 4248fa3d789dSPierre van Houtryve return true; 4249fa3d789dSPierre van Houtryve 4250fa3d789dSPierre van Houtryve if (!N.getOperator()->isSubClassOf("Instruction")) 4251fa3d789dSPierre van Houtryve return false; 4252fa3d789dSPierre van Houtryve 4253fa3d789dSPierre van Houtryve // If this type is already concrete or completely unknown we can't do 4254fa3d789dSPierre van Houtryve // anything. 4255fa3d789dSPierre van Houtryve TypeInfer &TI = TP.getInfer(); 4256fa3d789dSPierre van Houtryve for (unsigned i = 0, e = N.getNumTypes(); i != e; ++i) { 4257fa3d789dSPierre van Houtryve if (N.getExtType(i).empty() || TI.isConcrete(N.getExtType(i), false)) 4258fa3d789dSPierre van Houtryve continue; 4259fa3d789dSPierre van Houtryve 4260fa3d789dSPierre van Houtryve // Otherwise, force its type to an arbitrary choice. 4261fa3d789dSPierre van Houtryve if (TI.forceArbitrary(N.getExtType(i))) 4262fa3d789dSPierre van Houtryve return true; 4263fa3d789dSPierre van Houtryve } 4264fa3d789dSPierre van Houtryve 4265fa3d789dSPierre van Houtryve return false; 4266fa3d789dSPierre van Houtryve } 4267fa3d789dSPierre van Houtryve 4268fa3d789dSPierre van Houtryve // Promote xform function to be an explicit node wherever set. 4269fa3d789dSPierre van Houtryve static TreePatternNodePtr PromoteXForms(TreePatternNodePtr N) { 42703138eb50SRahul Joshi if (const Record *Xform = N->getTransformFn()) { 4271fa3d789dSPierre van Houtryve N->setTransformFn(nullptr); 4272fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> Children; 4273fa3d789dSPierre van Houtryve Children.push_back(PromoteXForms(N)); 4274fa3d789dSPierre van Houtryve return makeIntrusiveRefCnt<TreePatternNode>(Xform, std::move(Children), 4275fa3d789dSPierre van Houtryve N->getNumTypes()); 4276fa3d789dSPierre van Houtryve } 4277fa3d789dSPierre van Houtryve 4278fa3d789dSPierre van Houtryve if (!N->isLeaf()) 4279fa3d789dSPierre van Houtryve for (unsigned i = 0, e = N->getNumChildren(); i != e; ++i) { 4280fa3d789dSPierre van Houtryve TreePatternNodePtr Child = N->getChildShared(i); 4281fa3d789dSPierre van Houtryve N->setChild(i, PromoteXForms(Child)); 4282fa3d789dSPierre van Houtryve } 4283fa3d789dSPierre van Houtryve return N; 4284fa3d789dSPierre van Houtryve } 4285fa3d789dSPierre van Houtryve 4286fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::ParseOnePattern( 428737865681SRahul Joshi const Record *TheDef, TreePattern &Pattern, TreePattern &Result, 42883138eb50SRahul Joshi ArrayRef<const Record *> InstImpResults, bool ShouldIgnore) { 4289fa3d789dSPierre van Houtryve // Inline pattern fragments and expand multiple alternatives. 4290fa3d789dSPierre van Houtryve Pattern.InlinePatternFragments(); 4291fa3d789dSPierre van Houtryve Result.InlinePatternFragments(); 4292fa3d789dSPierre van Houtryve 4293ec61311eSStephen Chou if (Result.getNumTrees() != 1) { 4294fa3d789dSPierre van Houtryve Result.error("Cannot use multi-alternative fragments in result pattern!"); 4295ec61311eSStephen Chou return; 4296ec61311eSStephen Chou } 4297fa3d789dSPierre van Houtryve 4298fa3d789dSPierre van Houtryve // Infer types. 4299fa3d789dSPierre van Houtryve bool IterateInference; 4300fa3d789dSPierre van Houtryve bool InferredAllPatternTypes, InferredAllResultTypes; 4301fa3d789dSPierre van Houtryve do { 4302fa3d789dSPierre van Houtryve // Infer as many types as possible. If we cannot infer all of them, we 4303fa3d789dSPierre van Houtryve // can never do anything with this pattern: report it to the user. 4304fa3d789dSPierre van Houtryve InferredAllPatternTypes = 4305fa3d789dSPierre van Houtryve Pattern.InferAllTypes(&Pattern.getNamedNodesMap()); 4306fa3d789dSPierre van Houtryve 4307fa3d789dSPierre van Houtryve // Infer as many types as possible. If we cannot infer all of them, we 4308fa3d789dSPierre van Houtryve // can never do anything with this pattern: report it to the user. 4309fa3d789dSPierre van Houtryve InferredAllResultTypes = Result.InferAllTypes(&Pattern.getNamedNodesMap()); 4310fa3d789dSPierre van Houtryve 4311fa3d789dSPierre van Houtryve IterateInference = false; 4312fa3d789dSPierre van Houtryve 4313fa3d789dSPierre van Houtryve // Apply the type of the result to the source pattern. This helps us 4314fa3d789dSPierre van Houtryve // resolve cases where the input type is known to be a pointer type (which 4315fa3d789dSPierre van Houtryve // is considered resolved), but the result knows it needs to be 32- or 4316fa3d789dSPierre van Houtryve // 64-bits. Infer the other way for good measure. 4317fa3d789dSPierre van Houtryve for (const auto &T : Pattern.getTrees()) 4318fa3d789dSPierre van Houtryve for (unsigned i = 0, e = std::min(Result.getOnlyTree()->getNumTypes(), 4319fa3d789dSPierre van Houtryve T->getNumTypes()); 4320fa3d789dSPierre van Houtryve i != e; ++i) { 4321fa3d789dSPierre van Houtryve IterateInference |= 4322fa3d789dSPierre van Houtryve T->UpdateNodeType(i, Result.getOnlyTree()->getExtType(i), Result); 4323fa3d789dSPierre van Houtryve IterateInference |= 4324fa3d789dSPierre van Houtryve Result.getOnlyTree()->UpdateNodeType(i, T->getExtType(i), Result); 4325fa3d789dSPierre van Houtryve } 4326fa3d789dSPierre van Houtryve 4327fa3d789dSPierre van Houtryve // If our iteration has converged and the input pattern's types are fully 4328fa3d789dSPierre van Houtryve // resolved but the result pattern is not fully resolved, we may have a 4329fa3d789dSPierre van Houtryve // situation where we have two instructions in the result pattern and 4330fa3d789dSPierre van Houtryve // the instructions require a common register class, but don't care about 4331fa3d789dSPierre van Houtryve // what actual MVT is used. This is actually a bug in our modelling: 4332fa3d789dSPierre van Houtryve // output patterns should have register classes, not MVTs. 4333fa3d789dSPierre van Houtryve // 4334fa3d789dSPierre van Houtryve // In any case, to handle this, we just go through and disambiguate some 4335fa3d789dSPierre van Houtryve // arbitrary types to the result pattern's nodes. 4336fa3d789dSPierre van Houtryve if (!IterateInference && InferredAllPatternTypes && !InferredAllResultTypes) 4337fa3d789dSPierre van Houtryve IterateInference = 4338fa3d789dSPierre van Houtryve ForceArbitraryInstResultType(*Result.getTree(0), Result); 4339fa3d789dSPierre van Houtryve } while (IterateInference); 4340fa3d789dSPierre van Houtryve 4341fa3d789dSPierre van Houtryve // Verify that we inferred enough types that we can do something with the 4342fa3d789dSPierre van Houtryve // pattern and result. If these fire the user has to add type casts. 4343fa3d789dSPierre van Houtryve if (!InferredAllPatternTypes) 4344fa3d789dSPierre van Houtryve Pattern.error("Could not infer all types in pattern!"); 4345fa3d789dSPierre van Houtryve if (!InferredAllResultTypes) { 4346fa3d789dSPierre van Houtryve Pattern.dump(); 4347fa3d789dSPierre van Houtryve Result.error("Could not infer all types in pattern result!"); 4348fa3d789dSPierre van Houtryve } 4349fa3d789dSPierre van Houtryve 4350fa3d789dSPierre van Houtryve // Promote xform function to be an explicit node wherever set. 4351fa3d789dSPierre van Houtryve TreePatternNodePtr DstShared = PromoteXForms(Result.getOnlyTree()); 4352fa3d789dSPierre van Houtryve 4353fa3d789dSPierre van Houtryve TreePattern Temp(Result.getRecord(), DstShared, false, *this); 4354fa3d789dSPierre van Houtryve Temp.InferAllTypes(); 4355fa3d789dSPierre van Houtryve 435662e2c7fbSRahul Joshi const ListInit *Preds = TheDef->getValueAsListInit("Predicates"); 4357fa3d789dSPierre van Houtryve int Complexity = TheDef->getValueAsInt("AddedComplexity"); 4358fa3d789dSPierre van Houtryve 4359fa3d789dSPierre van Houtryve if (PatternRewriter) 4360fa3d789dSPierre van Houtryve PatternRewriter(&Pattern); 4361fa3d789dSPierre van Houtryve 4362fa3d789dSPierre van Houtryve // A pattern may end up with an "impossible" type, i.e. a situation 4363fa3d789dSPierre van Houtryve // where all types have been eliminated for some node in this pattern. 4364fa3d789dSPierre van Houtryve // This could occur for intrinsics that only make sense for a specific 4365fa3d789dSPierre van Houtryve // value type, and use a specific register class. If, for some mode, 4366fa3d789dSPierre van Houtryve // that register class does not accept that type, the type inference 4367fa3d789dSPierre van Houtryve // will lead to a contradiction, which is not an error however, but 4368fa3d789dSPierre van Houtryve // a sign that this pattern will simply never match. 4369fa3d789dSPierre van Houtryve if (Temp.getOnlyTree()->hasPossibleType()) { 4370fa3d789dSPierre van Houtryve for (const auto &T : Pattern.getTrees()) { 4371fa3d789dSPierre van Houtryve if (T->hasPossibleType()) 4372fa3d789dSPierre van Houtryve AddPatternToMatch(&Pattern, 4373fa3d789dSPierre van Houtryve PatternToMatch(TheDef, Preds, T, Temp.getOnlyTree(), 4374fa3d789dSPierre van Houtryve InstImpResults, Complexity, 4375eae7554dSjofrn TheDef->getID(), ShouldIgnore)); 4376fa3d789dSPierre van Houtryve } 4377fa3d789dSPierre van Houtryve } else { 4378fa3d789dSPierre van Houtryve // Show a message about a dropped pattern with some info to make it 4379fa3d789dSPierre van Houtryve // easier to identify it in the .td files. 4380fa3d789dSPierre van Houtryve LLVM_DEBUG({ 4381fa3d789dSPierre van Houtryve dbgs() << "Dropping: "; 4382fa3d789dSPierre van Houtryve Pattern.dump(); 4383fa3d789dSPierre van Houtryve Temp.getOnlyTree()->dump(); 4384fa3d789dSPierre van Houtryve dbgs() << "\n"; 4385fa3d789dSPierre van Houtryve }); 4386fa3d789dSPierre van Houtryve } 4387fa3d789dSPierre van Houtryve } 4388fa3d789dSPierre van Houtryve 4389fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::ParsePatterns() { 439087e8b530SRahul Joshi for (const Record *CurPattern : Records.getAllDerivedDefinitions("Pattern")) { 439162e2c7fbSRahul Joshi const DagInit *Tree = CurPattern->getValueAsDag("PatternToMatch"); 4392fa3d789dSPierre van Houtryve 4393fa3d789dSPierre van Houtryve // If the pattern references the null_frag, there's nothing to do. 4394fa3d789dSPierre van Houtryve if (hasNullFragReference(Tree)) 4395fa3d789dSPierre van Houtryve continue; 4396fa3d789dSPierre van Houtryve 4397fa3d789dSPierre van Houtryve TreePattern Pattern(CurPattern, Tree, true, *this); 4398fa3d789dSPierre van Houtryve 439962e2c7fbSRahul Joshi const ListInit *LI = CurPattern->getValueAsListInit("ResultInstrs"); 4400fa3d789dSPierre van Houtryve if (LI->empty()) 4401fa3d789dSPierre van Houtryve continue; // no pattern. 4402fa3d789dSPierre van Houtryve 4403fa3d789dSPierre van Houtryve // Parse the instruction. 4404fa3d789dSPierre van Houtryve TreePattern Result(CurPattern, LI, false, *this); 4405fa3d789dSPierre van Houtryve 4406fa3d789dSPierre van Houtryve if (Result.getNumTrees() != 1) 4407fa3d789dSPierre van Houtryve Result.error("Cannot handle instructions producing instructions " 4408fa3d789dSPierre van Houtryve "with temporaries yet!"); 4409fa3d789dSPierre van Houtryve 4410fa3d789dSPierre van Houtryve // Validate that the input pattern is correct. 4411fa3d789dSPierre van Houtryve std::map<std::string, TreePatternNodePtr> InstInputs; 4412fa3d789dSPierre van Houtryve MapVector<std::string, TreePatternNodePtr, std::map<std::string, unsigned>> 4413fa3d789dSPierre van Houtryve InstResults; 44143138eb50SRahul Joshi std::vector<const Record *> InstImpResults; 4415fa3d789dSPierre van Houtryve for (unsigned j = 0, ee = Pattern.getNumTrees(); j != ee; ++j) 4416fa3d789dSPierre van Houtryve FindPatternInputsAndOutputs(Pattern, Pattern.getTree(j), InstInputs, 4417fa3d789dSPierre van Houtryve InstResults, InstImpResults); 4418fa3d789dSPierre van Houtryve 4419eae7554dSjofrn ParseOnePattern(CurPattern, Pattern, Result, InstImpResults, 4420eae7554dSjofrn CurPattern->getValueAsBit("GISelShouldIgnore")); 4421fa3d789dSPierre van Houtryve } 4422fa3d789dSPierre van Houtryve } 4423fa3d789dSPierre van Houtryve 4424fa3d789dSPierre van Houtryve static void collectModes(std::set<unsigned> &Modes, const TreePatternNode &N) { 4425fa3d789dSPierre van Houtryve for (const TypeSetByHwMode &VTS : N.getExtTypes()) 4426fa3d789dSPierre van Houtryve for (const auto &I : VTS) 4427fa3d789dSPierre van Houtryve Modes.insert(I.first); 4428fa3d789dSPierre van Houtryve 4429d1f51c67SSergei Barannikov for (const TreePatternNode &Child : N.children()) 4430d1f51c67SSergei Barannikov collectModes(Modes, Child); 4431fa3d789dSPierre van Houtryve } 4432fa3d789dSPierre van Houtryve 4433fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::ExpandHwModeBasedTypes() { 4434fa3d789dSPierre van Houtryve const CodeGenHwModes &CGH = getTargetInfo().getHwModes(); 4435fa3d789dSPierre van Houtryve if (CGH.getNumModeIds() == 1) 4436fa3d789dSPierre van Houtryve return; 4437fa3d789dSPierre van Houtryve 4438fa3d789dSPierre van Houtryve std::vector<PatternToMatch> Copy; 4439fa3d789dSPierre van Houtryve PatternsToMatch.swap(Copy); 4440fa3d789dSPierre van Houtryve 4441fa3d789dSPierre van Houtryve auto AppendPattern = [this](PatternToMatch &P, unsigned Mode, 4442fa3d789dSPierre van Houtryve StringRef Check) { 4443fa3d789dSPierre van Houtryve TreePatternNodePtr NewSrc = P.getSrcPattern().clone(); 4444fa3d789dSPierre van Houtryve TreePatternNodePtr NewDst = P.getDstPattern().clone(); 4445fa3d789dSPierre van Houtryve if (!NewSrc->setDefaultMode(Mode) || !NewDst->setDefaultMode(Mode)) { 4446fa3d789dSPierre van Houtryve return; 4447fa3d789dSPierre van Houtryve } 4448fa3d789dSPierre van Houtryve 444987e8b530SRahul Joshi PatternsToMatch.emplace_back(P.getSrcRecord(), P.getPredicates(), 445087e8b530SRahul Joshi std::move(NewSrc), std::move(NewDst), 445187e8b530SRahul Joshi P.getDstRegs(), P.getAddedComplexity(), 445287e8b530SRahul Joshi getNewUID(), P.getGISelShouldIgnore(), Check); 4453fa3d789dSPierre van Houtryve }; 4454fa3d789dSPierre van Houtryve 4455fa3d789dSPierre van Houtryve for (PatternToMatch &P : Copy) { 4456fa3d789dSPierre van Houtryve const TreePatternNode *SrcP = nullptr, *DstP = nullptr; 4457fa3d789dSPierre van Houtryve if (P.getSrcPattern().hasProperTypeByHwMode()) 4458fa3d789dSPierre van Houtryve SrcP = &P.getSrcPattern(); 4459fa3d789dSPierre van Houtryve if (P.getDstPattern().hasProperTypeByHwMode()) 4460fa3d789dSPierre van Houtryve DstP = &P.getDstPattern(); 4461fa3d789dSPierre van Houtryve if (!SrcP && !DstP) { 4462fa3d789dSPierre van Houtryve PatternsToMatch.push_back(P); 4463fa3d789dSPierre van Houtryve continue; 4464fa3d789dSPierre van Houtryve } 4465fa3d789dSPierre van Houtryve 4466fa3d789dSPierre van Houtryve std::set<unsigned> Modes; 4467fa3d789dSPierre van Houtryve if (SrcP) 4468fa3d789dSPierre van Houtryve collectModes(Modes, *SrcP); 4469fa3d789dSPierre van Houtryve if (DstP) 4470fa3d789dSPierre van Houtryve collectModes(Modes, *DstP); 4471fa3d789dSPierre van Houtryve 4472fa3d789dSPierre van Houtryve // The predicate for the default mode needs to be constructed for each 4473fa3d789dSPierre van Houtryve // pattern separately. 4474fa3d789dSPierre van Houtryve // Since not all modes must be present in each pattern, if a mode m is 4475fa3d789dSPierre van Houtryve // absent, then there is no point in constructing a check for m. If such 4476fa3d789dSPierre van Houtryve // a check was created, it would be equivalent to checking the default 4477fa3d789dSPierre van Houtryve // mode, except not all modes' predicates would be a part of the checking 4478fa3d789dSPierre van Houtryve // code. The subsequently generated check for the default mode would then 4479fa3d789dSPierre van Houtryve // have the exact same patterns, but a different predicate code. To avoid 4480fa3d789dSPierre van Houtryve // duplicated patterns with different predicate checks, construct the 4481fa3d789dSPierre van Houtryve // default check as a negation of all predicates that are actually present 4482fa3d789dSPierre van Houtryve // in the source/destination patterns. 4483fa3d789dSPierre van Houtryve SmallString<128> DefaultCheck; 4484fa3d789dSPierre van Houtryve 4485fa3d789dSPierre van Houtryve for (unsigned M : Modes) { 4486fa3d789dSPierre van Houtryve if (M == DefaultMode) 4487fa3d789dSPierre van Houtryve continue; 4488fa3d789dSPierre van Houtryve 4489fa3d789dSPierre van Houtryve // Fill the map entry for this mode. 4490fa3d789dSPierre van Houtryve const HwMode &HM = CGH.getMode(M); 4491fa3d789dSPierre van Houtryve AppendPattern(P, M, HM.Predicates); 4492fa3d789dSPierre van Houtryve 4493fa3d789dSPierre van Houtryve // Add negations of the HM's predicates to the default predicate. 4494fa3d789dSPierre van Houtryve if (!DefaultCheck.empty()) 4495fa3d789dSPierre van Houtryve DefaultCheck += " && "; 4496fa3d789dSPierre van Houtryve DefaultCheck += "!("; 4497fa3d789dSPierre van Houtryve DefaultCheck += HM.Predicates; 4498fa3d789dSPierre van Houtryve DefaultCheck += ")"; 4499fa3d789dSPierre van Houtryve } 4500fa3d789dSPierre van Houtryve 4501fa3d789dSPierre van Houtryve bool HasDefault = Modes.count(DefaultMode); 4502fa3d789dSPierre van Houtryve if (HasDefault) 4503fa3d789dSPierre van Houtryve AppendPattern(P, DefaultMode, DefaultCheck); 4504fa3d789dSPierre van Houtryve } 4505fa3d789dSPierre van Houtryve } 4506fa3d789dSPierre van Houtryve 4507fa3d789dSPierre van Houtryve /// Dependent variable map for CodeGenDAGPattern variant generation 4508fa3d789dSPierre van Houtryve typedef StringMap<int> DepVarMap; 4509fa3d789dSPierre van Houtryve 4510fa3d789dSPierre van Houtryve static void FindDepVarsOf(TreePatternNode &N, DepVarMap &DepMap) { 4511fa3d789dSPierre van Houtryve if (N.isLeaf()) { 4512fa3d789dSPierre van Houtryve if (N.hasName() && isa<DefInit>(N.getLeafValue())) 4513fa3d789dSPierre van Houtryve DepMap[N.getName()]++; 4514fa3d789dSPierre van Houtryve } else { 4515d1f51c67SSergei Barannikov for (TreePatternNode &Child : N.children()) 4516d1f51c67SSergei Barannikov FindDepVarsOf(Child, DepMap); 4517fa3d789dSPierre van Houtryve } 4518fa3d789dSPierre van Houtryve } 4519fa3d789dSPierre van Houtryve 4520fa3d789dSPierre van Houtryve /// Find dependent variables within child patterns 4521fa3d789dSPierre van Houtryve static void FindDepVars(TreePatternNode &N, MultipleUseVarSet &DepVars) { 4522fa3d789dSPierre van Houtryve DepVarMap depcounts; 4523fa3d789dSPierre van Houtryve FindDepVarsOf(N, depcounts); 4524fa3d789dSPierre van Houtryve for (const auto &Pair : depcounts) { 4525fa3d789dSPierre van Houtryve if (Pair.getValue() > 1) 4526fa3d789dSPierre van Houtryve DepVars.insert(Pair.getKey()); 4527fa3d789dSPierre van Houtryve } 4528fa3d789dSPierre van Houtryve } 4529fa3d789dSPierre van Houtryve 4530fa3d789dSPierre van Houtryve #ifndef NDEBUG 4531fa3d789dSPierre van Houtryve /// Dump the dependent variable set: 4532fa3d789dSPierre van Houtryve static void DumpDepVars(MultipleUseVarSet &DepVars) { 4533fa3d789dSPierre van Houtryve if (DepVars.empty()) { 4534fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << "<empty set>"); 4535fa3d789dSPierre van Houtryve } else { 4536fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << "[ "); 4537fa3d789dSPierre van Houtryve for (const auto &DepVar : DepVars) { 4538fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << DepVar.getKey() << " "); 4539fa3d789dSPierre van Houtryve } 4540fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << "]"); 4541fa3d789dSPierre van Houtryve } 4542fa3d789dSPierre van Houtryve } 4543fa3d789dSPierre van Houtryve #endif 4544fa3d789dSPierre van Houtryve 4545fa3d789dSPierre van Houtryve /// CombineChildVariants - Given a bunch of permutations of each child of the 4546fa3d789dSPierre van Houtryve /// 'operator' node, put them together in all possible ways. 4547fa3d789dSPierre van Houtryve static void CombineChildVariants( 4548fa3d789dSPierre van Houtryve TreePatternNodePtr Orig, 4549fa3d789dSPierre van Houtryve const std::vector<std::vector<TreePatternNodePtr>> &ChildVariants, 4550fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> &OutVariants, CodeGenDAGPatterns &CDP, 4551fa3d789dSPierre van Houtryve const MultipleUseVarSet &DepVars) { 4552fa3d789dSPierre van Houtryve // Make sure that each operand has at least one variant to choose from. 4553fa3d789dSPierre van Houtryve for (const auto &Variants : ChildVariants) 4554fa3d789dSPierre van Houtryve if (Variants.empty()) 4555fa3d789dSPierre van Houtryve return; 4556fa3d789dSPierre van Houtryve 4557fa3d789dSPierre van Houtryve // The end result is an all-pairs construction of the resultant pattern. 4558fa3d789dSPierre van Houtryve std::vector<unsigned> Idxs(ChildVariants.size()); 4559fa3d789dSPierre van Houtryve bool NotDone; 4560fa3d789dSPierre van Houtryve do { 4561fa3d789dSPierre van Houtryve #ifndef NDEBUG 4562fa3d789dSPierre van Houtryve LLVM_DEBUG(if (!Idxs.empty()) { 4563fa3d789dSPierre van Houtryve errs() << Orig->getOperator()->getName() << ": Idxs = [ "; 4564fa3d789dSPierre van Houtryve for (unsigned Idx : Idxs) { 4565fa3d789dSPierre van Houtryve errs() << Idx << " "; 4566fa3d789dSPierre van Houtryve } 4567fa3d789dSPierre van Houtryve errs() << "]\n"; 4568fa3d789dSPierre van Houtryve }); 4569fa3d789dSPierre van Houtryve #endif 4570fa3d789dSPierre van Houtryve // Create the variant and add it to the output list. 4571fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> NewChildren; 4572fa3d789dSPierre van Houtryve NewChildren.reserve(ChildVariants.size()); 4573fa3d789dSPierre van Houtryve for (unsigned i = 0, e = ChildVariants.size(); i != e; ++i) 4574fa3d789dSPierre van Houtryve NewChildren.push_back(ChildVariants[i][Idxs[i]]); 4575fa3d789dSPierre van Houtryve TreePatternNodePtr R = makeIntrusiveRefCnt<TreePatternNode>( 4576fa3d789dSPierre van Houtryve Orig->getOperator(), std::move(NewChildren), Orig->getNumTypes()); 4577fa3d789dSPierre van Houtryve 4578fa3d789dSPierre van Houtryve // Copy over properties. 4579fa3d789dSPierre van Houtryve R->setName(Orig->getName()); 4580fa3d789dSPierre van Houtryve R->setNamesAsPredicateArg(Orig->getNamesAsPredicateArg()); 4581fa3d789dSPierre van Houtryve R->setPredicateCalls(Orig->getPredicateCalls()); 4582fa3d789dSPierre van Houtryve R->setGISelFlagsRecord(Orig->getGISelFlagsRecord()); 4583fa3d789dSPierre van Houtryve R->setTransformFn(Orig->getTransformFn()); 4584fa3d789dSPierre van Houtryve for (unsigned i = 0, e = Orig->getNumTypes(); i != e; ++i) 4585fa3d789dSPierre van Houtryve R->setType(i, Orig->getExtType(i)); 4586fa3d789dSPierre van Houtryve 4587fa3d789dSPierre van Houtryve // If this pattern cannot match, do not include it as a variant. 4588fa3d789dSPierre van Houtryve std::string ErrString; 4589fa3d789dSPierre van Houtryve // Scan to see if this pattern has already been emitted. We can get 4590fa3d789dSPierre van Houtryve // duplication due to things like commuting: 4591fa3d789dSPierre van Houtryve // (and GPRC:$a, GPRC:$b) -> (and GPRC:$b, GPRC:$a) 4592fa3d789dSPierre van Houtryve // which are the same pattern. Ignore the dups. 4593fa3d789dSPierre van Houtryve if (R->canPatternMatch(ErrString, CDP) && 4594fa3d789dSPierre van Houtryve none_of(OutVariants, [&](TreePatternNodePtr Variant) { 4595fa3d789dSPierre van Houtryve return R->isIsomorphicTo(*Variant, DepVars); 4596fa3d789dSPierre van Houtryve })) 4597fa3d789dSPierre van Houtryve OutVariants.push_back(R); 4598fa3d789dSPierre van Houtryve 4599fa3d789dSPierre van Houtryve // Increment indices to the next permutation by incrementing the 4600fa3d789dSPierre van Houtryve // indices from last index backward, e.g., generate the sequence 4601fa3d789dSPierre van Houtryve // [0, 0], [0, 1], [1, 0], [1, 1]. 4602fa3d789dSPierre van Houtryve int IdxsIdx; 4603fa3d789dSPierre van Houtryve for (IdxsIdx = Idxs.size() - 1; IdxsIdx >= 0; --IdxsIdx) { 4604fa3d789dSPierre van Houtryve if (++Idxs[IdxsIdx] == ChildVariants[IdxsIdx].size()) 4605fa3d789dSPierre van Houtryve Idxs[IdxsIdx] = 0; 4606fa3d789dSPierre van Houtryve else 4607fa3d789dSPierre van Houtryve break; 4608fa3d789dSPierre van Houtryve } 4609fa3d789dSPierre van Houtryve NotDone = (IdxsIdx >= 0); 4610fa3d789dSPierre van Houtryve } while (NotDone); 4611fa3d789dSPierre van Houtryve } 4612fa3d789dSPierre van Houtryve 4613fa3d789dSPierre van Houtryve /// CombineChildVariants - A helper function for binary operators. 4614fa3d789dSPierre van Houtryve /// 4615fa3d789dSPierre van Houtryve static void CombineChildVariants(TreePatternNodePtr Orig, 4616fa3d789dSPierre van Houtryve const std::vector<TreePatternNodePtr> &LHS, 4617fa3d789dSPierre van Houtryve const std::vector<TreePatternNodePtr> &RHS, 4618fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> &OutVariants, 4619fa3d789dSPierre van Houtryve CodeGenDAGPatterns &CDP, 4620fa3d789dSPierre van Houtryve const MultipleUseVarSet &DepVars) { 4621fa3d789dSPierre van Houtryve std::vector<std::vector<TreePatternNodePtr>> ChildVariants; 4622fa3d789dSPierre van Houtryve ChildVariants.push_back(LHS); 4623fa3d789dSPierre van Houtryve ChildVariants.push_back(RHS); 4624fa3d789dSPierre van Houtryve CombineChildVariants(Orig, ChildVariants, OutVariants, CDP, DepVars); 4625fa3d789dSPierre van Houtryve } 4626fa3d789dSPierre van Houtryve 4627fa3d789dSPierre van Houtryve static void 4628fa3d789dSPierre van Houtryve GatherChildrenOfAssociativeOpcode(TreePatternNodePtr N, 4629fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> &Children) { 4630fa3d789dSPierre van Houtryve assert(N->getNumChildren() == 2 && 4631fa3d789dSPierre van Houtryve "Associative but doesn't have 2 children!"); 463237865681SRahul Joshi const Record *Operator = N->getOperator(); 4633fa3d789dSPierre van Houtryve 4634fa3d789dSPierre van Houtryve // Only permit raw nodes. 4635fa3d789dSPierre van Houtryve if (!N->getName().empty() || !N->getPredicateCalls().empty() || 4636fa3d789dSPierre van Houtryve N->getTransformFn()) { 4637fa3d789dSPierre van Houtryve Children.push_back(N); 4638fa3d789dSPierre van Houtryve return; 4639fa3d789dSPierre van Houtryve } 4640fa3d789dSPierre van Houtryve 4641fa3d789dSPierre van Houtryve if (N->getChild(0).isLeaf() || N->getChild(0).getOperator() != Operator) 4642fa3d789dSPierre van Houtryve Children.push_back(N->getChildShared(0)); 4643fa3d789dSPierre van Houtryve else 4644fa3d789dSPierre van Houtryve GatherChildrenOfAssociativeOpcode(N->getChildShared(0), Children); 4645fa3d789dSPierre van Houtryve 4646fa3d789dSPierre van Houtryve if (N->getChild(1).isLeaf() || N->getChild(1).getOperator() != Operator) 4647fa3d789dSPierre van Houtryve Children.push_back(N->getChildShared(1)); 4648fa3d789dSPierre van Houtryve else 4649fa3d789dSPierre van Houtryve GatherChildrenOfAssociativeOpcode(N->getChildShared(1), Children); 4650fa3d789dSPierre van Houtryve } 4651fa3d789dSPierre van Houtryve 4652fa3d789dSPierre van Houtryve /// GenerateVariantsOf - Given a pattern N, generate all permutations we can of 4653fa3d789dSPierre van Houtryve /// the (potentially recursive) pattern by using algebraic laws. 4654fa3d789dSPierre van Houtryve /// 4655fa3d789dSPierre van Houtryve static void GenerateVariantsOf(TreePatternNodePtr N, 4656fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> &OutVariants, 4657fa3d789dSPierre van Houtryve CodeGenDAGPatterns &CDP, 4658fa3d789dSPierre van Houtryve const MultipleUseVarSet &DepVars) { 4659fa3d789dSPierre van Houtryve // We cannot permute leaves or ComplexPattern uses. 4660fa3d789dSPierre van Houtryve if (N->isLeaf() || N->getOperator()->isSubClassOf("ComplexPattern")) { 4661fa3d789dSPierre van Houtryve OutVariants.push_back(N); 4662fa3d789dSPierre van Houtryve return; 4663fa3d789dSPierre van Houtryve } 4664fa3d789dSPierre van Houtryve 4665fa3d789dSPierre van Houtryve // Look up interesting info about the node. 4666fa3d789dSPierre van Houtryve const SDNodeInfo &NodeInfo = CDP.getSDNodeInfo(N->getOperator()); 4667fa3d789dSPierre van Houtryve 4668fa3d789dSPierre van Houtryve // If this node is associative, re-associate. 4669fa3d789dSPierre van Houtryve if (NodeInfo.hasProperty(SDNPAssociative)) { 4670fa3d789dSPierre van Houtryve // Re-associate by pulling together all of the linked operators 4671fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> MaximalChildren; 4672fa3d789dSPierre van Houtryve GatherChildrenOfAssociativeOpcode(N, MaximalChildren); 4673fa3d789dSPierre van Houtryve 4674fa3d789dSPierre van Houtryve // Only handle child sizes of 3. Otherwise we'll end up trying too many 4675fa3d789dSPierre van Houtryve // permutations. 4676fa3d789dSPierre van Houtryve if (MaximalChildren.size() == 3) { 4677fa3d789dSPierre van Houtryve // Find the variants of all of our maximal children. 4678fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> AVariants, BVariants, CVariants; 4679fa3d789dSPierre van Houtryve GenerateVariantsOf(MaximalChildren[0], AVariants, CDP, DepVars); 4680fa3d789dSPierre van Houtryve GenerateVariantsOf(MaximalChildren[1], BVariants, CDP, DepVars); 4681fa3d789dSPierre van Houtryve GenerateVariantsOf(MaximalChildren[2], CVariants, CDP, DepVars); 4682fa3d789dSPierre van Houtryve 4683fa3d789dSPierre van Houtryve // There are only two ways we can permute the tree: 4684fa3d789dSPierre van Houtryve // (A op B) op C and A op (B op C) 4685fa3d789dSPierre van Houtryve // Within these forms, we can also permute A/B/C. 4686fa3d789dSPierre van Houtryve 4687fa3d789dSPierre van Houtryve // Generate legal pair permutations of A/B/C. 4688fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> ABVariants; 4689fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> BAVariants; 4690fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> ACVariants; 4691fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> CAVariants; 4692fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> BCVariants; 4693fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> CBVariants; 4694fa3d789dSPierre van Houtryve CombineChildVariants(N, AVariants, BVariants, ABVariants, CDP, DepVars); 4695fa3d789dSPierre van Houtryve CombineChildVariants(N, BVariants, AVariants, BAVariants, CDP, DepVars); 4696fa3d789dSPierre van Houtryve CombineChildVariants(N, AVariants, CVariants, ACVariants, CDP, DepVars); 4697fa3d789dSPierre van Houtryve CombineChildVariants(N, CVariants, AVariants, CAVariants, CDP, DepVars); 4698fa3d789dSPierre van Houtryve CombineChildVariants(N, BVariants, CVariants, BCVariants, CDP, DepVars); 4699fa3d789dSPierre van Houtryve CombineChildVariants(N, CVariants, BVariants, CBVariants, CDP, DepVars); 4700fa3d789dSPierre van Houtryve 4701fa3d789dSPierre van Houtryve // Combine those into the result: (x op x) op x 4702fa3d789dSPierre van Houtryve CombineChildVariants(N, ABVariants, CVariants, OutVariants, CDP, DepVars); 4703fa3d789dSPierre van Houtryve CombineChildVariants(N, BAVariants, CVariants, OutVariants, CDP, DepVars); 4704fa3d789dSPierre van Houtryve CombineChildVariants(N, ACVariants, BVariants, OutVariants, CDP, DepVars); 4705fa3d789dSPierre van Houtryve CombineChildVariants(N, CAVariants, BVariants, OutVariants, CDP, DepVars); 4706fa3d789dSPierre van Houtryve CombineChildVariants(N, BCVariants, AVariants, OutVariants, CDP, DepVars); 4707fa3d789dSPierre van Houtryve CombineChildVariants(N, CBVariants, AVariants, OutVariants, CDP, DepVars); 4708fa3d789dSPierre van Houtryve 4709fa3d789dSPierre van Houtryve // Combine those into the result: x op (x op x) 4710fa3d789dSPierre van Houtryve CombineChildVariants(N, CVariants, ABVariants, OutVariants, CDP, DepVars); 4711fa3d789dSPierre van Houtryve CombineChildVariants(N, CVariants, BAVariants, OutVariants, CDP, DepVars); 4712fa3d789dSPierre van Houtryve CombineChildVariants(N, BVariants, ACVariants, OutVariants, CDP, DepVars); 4713fa3d789dSPierre van Houtryve CombineChildVariants(N, BVariants, CAVariants, OutVariants, CDP, DepVars); 4714fa3d789dSPierre van Houtryve CombineChildVariants(N, AVariants, BCVariants, OutVariants, CDP, DepVars); 4715fa3d789dSPierre van Houtryve CombineChildVariants(N, AVariants, CBVariants, OutVariants, CDP, DepVars); 4716fa3d789dSPierre van Houtryve return; 4717fa3d789dSPierre van Houtryve } 4718fa3d789dSPierre van Houtryve } 4719fa3d789dSPierre van Houtryve 4720fa3d789dSPierre van Houtryve // Compute permutations of all children. 4721fa3d789dSPierre van Houtryve std::vector<std::vector<TreePatternNodePtr>> ChildVariants( 4722fa3d789dSPierre van Houtryve N->getNumChildren()); 4723fa3d789dSPierre van Houtryve for (unsigned i = 0, e = N->getNumChildren(); i != e; ++i) 4724fa3d789dSPierre van Houtryve GenerateVariantsOf(N->getChildShared(i), ChildVariants[i], CDP, DepVars); 4725fa3d789dSPierre van Houtryve 4726fa3d789dSPierre van Houtryve // Build all permutations based on how the children were formed. 4727fa3d789dSPierre van Houtryve CombineChildVariants(N, ChildVariants, OutVariants, CDP, DepVars); 4728fa3d789dSPierre van Houtryve 4729fa3d789dSPierre van Houtryve // If this node is commutative, consider the commuted order. 4730fa3d789dSPierre van Houtryve bool isCommIntrinsic = N->isCommutativeIntrinsic(CDP); 4731fa3d789dSPierre van Houtryve if (NodeInfo.hasProperty(SDNPCommutative) || isCommIntrinsic) { 4732fa3d789dSPierre van Houtryve unsigned Skip = isCommIntrinsic ? 1 : 0; // First operand is intrinsic id. 4733fa3d789dSPierre van Houtryve assert(N->getNumChildren() >= (2 + Skip) && 4734fa3d789dSPierre van Houtryve "Commutative but doesn't have 2 children!"); 4735fa3d789dSPierre van Houtryve // Don't allow commuting children which are actually register references. 4736fa3d789dSPierre van Houtryve bool NoRegisters = true; 4737fa3d789dSPierre van Houtryve unsigned i = 0 + Skip; 4738fa3d789dSPierre van Houtryve unsigned e = 2 + Skip; 4739fa3d789dSPierre van Houtryve for (; i != e; ++i) { 4740fa3d789dSPierre van Houtryve TreePatternNode &Child = N->getChild(i); 4741fa3d789dSPierre van Houtryve if (Child.isLeaf()) 47423138eb50SRahul Joshi if (const DefInit *DI = dyn_cast<DefInit>(Child.getLeafValue())) { 47433138eb50SRahul Joshi const Record *RR = DI->getDef(); 4744fa3d789dSPierre van Houtryve if (RR->isSubClassOf("Register")) 4745fa3d789dSPierre van Houtryve NoRegisters = false; 4746fa3d789dSPierre van Houtryve } 4747fa3d789dSPierre van Houtryve } 4748fa3d789dSPierre van Houtryve // Consider the commuted order. 4749fa3d789dSPierre van Houtryve if (NoRegisters) { 4750fa3d789dSPierre van Houtryve // Swap the first two operands after the intrinsic id, if present. 4751fa3d789dSPierre van Houtryve unsigned i = isCommIntrinsic ? 1 : 0; 4752fa3d789dSPierre van Houtryve std::swap(ChildVariants[i], ChildVariants[i + 1]); 4753fa3d789dSPierre van Houtryve CombineChildVariants(N, ChildVariants, OutVariants, CDP, DepVars); 4754fa3d789dSPierre van Houtryve } 4755fa3d789dSPierre van Houtryve } 4756fa3d789dSPierre van Houtryve } 4757fa3d789dSPierre van Houtryve 4758fa3d789dSPierre van Houtryve // GenerateVariants - Generate variants. For example, commutative patterns can 4759fa3d789dSPierre van Houtryve // match multiple ways. Add them to PatternsToMatch as well. 4760fa3d789dSPierre van Houtryve void CodeGenDAGPatterns::GenerateVariants() { 4761fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << "Generating instruction variants.\n"); 4762fa3d789dSPierre van Houtryve 4763fa3d789dSPierre van Houtryve // Loop over all of the patterns we've collected, checking to see if we can 4764fa3d789dSPierre van Houtryve // generate variants of the instruction, through the exploitation of 4765fa3d789dSPierre van Houtryve // identities. This permits the target to provide aggressive matching without 4766fa3d789dSPierre van Houtryve // the .td file having to contain tons of variants of instructions. 4767fa3d789dSPierre van Houtryve // 4768fa3d789dSPierre van Houtryve // Note that this loop adds new patterns to the PatternsToMatch list, but we 4769fa3d789dSPierre van Houtryve // intentionally do not reconsider these. Any variants of added patterns have 4770fa3d789dSPierre van Houtryve // already been added. 4771fa3d789dSPierre van Houtryve // 4772fa3d789dSPierre van Houtryve for (unsigned i = 0, e = PatternsToMatch.size(); i != e; ++i) { 4773fa3d789dSPierre van Houtryve MultipleUseVarSet DepVars; 4774fa3d789dSPierre van Houtryve std::vector<TreePatternNodePtr> Variants; 4775fa3d789dSPierre van Houtryve FindDepVars(PatternsToMatch[i].getSrcPattern(), DepVars); 4776fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << "Dependent/multiply used variables: "); 4777fa3d789dSPierre van Houtryve LLVM_DEBUG(DumpDepVars(DepVars)); 4778fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << "\n"); 4779fa3d789dSPierre van Houtryve GenerateVariantsOf(PatternsToMatch[i].getSrcPatternShared(), Variants, 4780fa3d789dSPierre van Houtryve *this, DepVars); 4781fa3d789dSPierre van Houtryve 4782fa3d789dSPierre van Houtryve assert(PatternsToMatch[i].getHwModeFeatures().empty() && 4783fa3d789dSPierre van Houtryve "HwModes should not have been expanded yet!"); 4784fa3d789dSPierre van Houtryve 4785fa3d789dSPierre van Houtryve assert(!Variants.empty() && "Must create at least original variant!"); 4786fa3d789dSPierre van Houtryve if (Variants.size() == 1) // No additional variants for this pattern. 4787fa3d789dSPierre van Houtryve continue; 4788fa3d789dSPierre van Houtryve 4789fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << "FOUND VARIANTS OF: "; 4790fa3d789dSPierre van Houtryve PatternsToMatch[i].getSrcPattern().dump(); errs() << "\n"); 4791fa3d789dSPierre van Houtryve 4792fa3d789dSPierre van Houtryve for (unsigned v = 0, e = Variants.size(); v != e; ++v) { 4793fa3d789dSPierre van Houtryve TreePatternNodePtr Variant = Variants[v]; 4794fa3d789dSPierre van Houtryve 4795fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << " VAR#" << v << ": "; Variant->dump(); 4796fa3d789dSPierre van Houtryve errs() << "\n"); 4797fa3d789dSPierre van Houtryve 4798fa3d789dSPierre van Houtryve // Scan to see if an instruction or explicit pattern already matches this. 4799fa3d789dSPierre van Houtryve bool AlreadyExists = false; 4800fa3d789dSPierre van Houtryve for (unsigned p = 0, e = PatternsToMatch.size(); p != e; ++p) { 4801fa3d789dSPierre van Houtryve // Skip if the top level predicates do not match. 4802fa3d789dSPierre van Houtryve if ((i != p) && (PatternsToMatch[i].getPredicates() != 4803fa3d789dSPierre van Houtryve PatternsToMatch[p].getPredicates())) 4804fa3d789dSPierre van Houtryve continue; 4805fa3d789dSPierre van Houtryve // Check to see if this variant already exists. 4806fa3d789dSPierre van Houtryve if (Variant->isIsomorphicTo(PatternsToMatch[p].getSrcPattern(), 4807fa3d789dSPierre van Houtryve DepVars)) { 4808fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << " *** ALREADY EXISTS, ignoring variant.\n"); 4809fa3d789dSPierre van Houtryve AlreadyExists = true; 4810fa3d789dSPierre van Houtryve break; 4811fa3d789dSPierre van Houtryve } 4812fa3d789dSPierre van Houtryve } 4813fa3d789dSPierre van Houtryve // If we already have it, ignore the variant. 4814fa3d789dSPierre van Houtryve if (AlreadyExists) 4815fa3d789dSPierre van Houtryve continue; 4816fa3d789dSPierre van Houtryve 4817fa3d789dSPierre van Houtryve // Otherwise, add it to the list of patterns we have. 4818fa3d789dSPierre van Houtryve PatternsToMatch.emplace_back( 4819fa3d789dSPierre van Houtryve PatternsToMatch[i].getSrcRecord(), PatternsToMatch[i].getPredicates(), 4820fa3d789dSPierre van Houtryve Variant, PatternsToMatch[i].getDstPatternShared(), 4821fa3d789dSPierre van Houtryve PatternsToMatch[i].getDstRegs(), 482287e8b530SRahul Joshi PatternsToMatch[i].getAddedComplexity(), getNewUID(), 4823eae7554dSjofrn PatternsToMatch[i].getGISelShouldIgnore(), 4824fa3d789dSPierre van Houtryve PatternsToMatch[i].getHwModeFeatures()); 4825fa3d789dSPierre van Houtryve } 4826fa3d789dSPierre van Houtryve 4827fa3d789dSPierre van Houtryve LLVM_DEBUG(errs() << "\n"); 4828fa3d789dSPierre van Houtryve } 4829fa3d789dSPierre van Houtryve } 483087e8b530SRahul Joshi 483187e8b530SRahul Joshi unsigned CodeGenDAGPatterns::getNewUID() { 483287e8b530SRahul Joshi RecordKeeper &MutableRC = const_cast<RecordKeeper &>(Records); 483387e8b530SRahul Joshi return Record::getNewUID(MutableRC); 483487e8b530SRahul Joshi } 4835