1 //===--- TrailingObjects.h - Variable-length classes ------------*- C++ -*-===// 2 // 3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4 // See https://llvm.org/LICENSE.txt for license information. 5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6 // 7 //===----------------------------------------------------------------------===// 8 /// 9 /// \file 10 /// This header defines support for implementing classes that have 11 /// some trailing object (or arrays of objects) appended to them. The 12 /// main purpose is to make it obvious where this idiom is being used, 13 /// and to make the usage more idiomatic and more difficult to get 14 /// wrong. 15 /// 16 /// The TrailingObject template abstracts away the reinterpret_cast, 17 /// pointer arithmetic, and size calculations used for the allocation 18 /// and access of appended arrays of objects, and takes care that they 19 /// are all allocated at their required alignment. Additionally, it 20 /// ensures that the base type is final -- deriving from a class that 21 /// expects data appended immediately after it is typically not safe. 22 /// 23 /// Users are expected to derive from this template, and provide 24 /// numTrailingObjects implementations for each trailing type except 25 /// the last, e.g. like this sample: 26 /// 27 /// \code 28 /// class VarLengthObj : private TrailingObjects<VarLengthObj, int, double> { 29 /// friend TrailingObjects; 30 /// 31 /// unsigned NumInts, NumDoubles; 32 /// size_t numTrailingObjects(OverloadToken<int>) const { return NumInts; } 33 /// }; 34 /// \endcode 35 /// 36 /// You can access the appended arrays via 'getTrailingObjects', and 37 /// determine the size needed for allocation via 38 /// 'additionalSizeToAlloc' and 'totalSizeToAlloc'. 39 /// 40 /// All the methods implemented by this class are are intended for use 41 /// by the implementation of the class, not as part of its interface 42 /// (thus, private inheritance is suggested). 43 /// 44 //===----------------------------------------------------------------------===// 45 46 #ifndef LLVM_SUPPORT_TRAILINGOBJECTS_H 47 #define LLVM_SUPPORT_TRAILINGOBJECTS_H 48 49 #include "llvm/Support/AlignOf.h" 50 #include "llvm/Support/Alignment.h" 51 #include "llvm/Support/Compiler.h" 52 #include "llvm/Support/MathExtras.h" 53 #include "llvm/Support/type_traits.h" 54 #include <new> 55 #include <type_traits> 56 57 namespace llvm { 58 59 namespace trailing_objects_internal { 60 /// Helper template to calculate the max alignment requirement for a set of 61 /// objects. 62 template <typename First, typename... Rest> class AlignmentCalcHelper { 63 private: 64 enum { 65 FirstAlignment = alignof(First), 66 RestAlignment = AlignmentCalcHelper<Rest...>::Alignment, 67 }; 68 69 public: 70 enum { 71 Alignment = FirstAlignment > RestAlignment ? FirstAlignment : RestAlignment 72 }; 73 }; 74 75 template <typename First> class AlignmentCalcHelper<First> { 76 public: 77 enum { Alignment = alignof(First) }; 78 }; 79 80 /// The base class for TrailingObjects* classes. 81 class TrailingObjectsBase { 82 protected: 83 /// OverloadToken's purpose is to allow specifying function overloads 84 /// for different types, without actually taking the types as 85 /// parameters. (Necessary because member function templates cannot 86 /// be specialized, so overloads must be used instead of 87 /// specialization.) 88 template <typename T> struct OverloadToken {}; 89 }; 90 91 // Just a little helper for transforming a type pack into the same 92 // number of a different type. e.g.: 93 // ExtractSecondType<Foo..., int>::type 94 template <typename Ty1, typename Ty2> struct ExtractSecondType { 95 typedef Ty2 type; 96 }; 97 98 // TrailingObjectsImpl is somewhat complicated, because it is a 99 // recursively inheriting template, in order to handle the template 100 // varargs. Each level of inheritance picks off a single trailing type 101 // then recurses on the rest. The "Align", "BaseTy", and 102 // "TopTrailingObj" arguments are passed through unchanged through the 103 // recursion. "PrevTy" is, at each level, the type handled by the 104 // level right above it. 105 106 template <int Align, typename BaseTy, typename TopTrailingObj, typename PrevTy, 107 typename... MoreTys> 108 class TrailingObjectsImpl { 109 // The main template definition is never used -- the two 110 // specializations cover all possibilities. 111 }; 112 113 template <int Align, typename BaseTy, typename TopTrailingObj, typename PrevTy, 114 typename NextTy, typename... MoreTys> 115 class TrailingObjectsImpl<Align, BaseTy, TopTrailingObj, PrevTy, NextTy, 116 MoreTys...> 117 : public TrailingObjectsImpl<Align, BaseTy, TopTrailingObj, NextTy, 118 MoreTys...> { 119 120 typedef TrailingObjectsImpl<Align, BaseTy, TopTrailingObj, NextTy, MoreTys...> 121 ParentType; 122 123 struct RequiresRealignment { 124 static const bool value = alignof(PrevTy) < alignof(NextTy); 125 }; 126 127 static constexpr bool requiresRealignment() { 128 return RequiresRealignment::value; 129 } 130 131 protected: 132 // Ensure the inherited getTrailingObjectsImpl is not hidden. 133 using ParentType::getTrailingObjectsImpl; 134 135 // These two functions are helper functions for 136 // TrailingObjects::getTrailingObjects. They recurse to the left -- 137 // the result for each type in the list of trailing types depends on 138 // the result of calling the function on the type to the 139 // left. However, the function for the type to the left is 140 // implemented by a *subclass* of this class, so we invoke it via 141 // the TopTrailingObj, which is, via the 142 // curiously-recurring-template-pattern, the most-derived type in 143 // this recursion, and thus, contains all the overloads. 144 static const NextTy * 145 getTrailingObjectsImpl(const BaseTy *Obj, 146 TrailingObjectsBase::OverloadToken<NextTy>) { 147 auto *Ptr = TopTrailingObj::getTrailingObjectsImpl( 148 Obj, TrailingObjectsBase::OverloadToken<PrevTy>()) + 149 TopTrailingObj::callNumTrailingObjects( 150 Obj, TrailingObjectsBase::OverloadToken<PrevTy>()); 151 152 if (requiresRealignment()) 153 return reinterpret_cast<const NextTy *>( 154 alignAddr(Ptr, Align::Of<NextTy>())); 155 else 156 return reinterpret_cast<const NextTy *>(Ptr); 157 } 158 159 static NextTy * 160 getTrailingObjectsImpl(BaseTy *Obj, 161 TrailingObjectsBase::OverloadToken<NextTy>) { 162 auto *Ptr = TopTrailingObj::getTrailingObjectsImpl( 163 Obj, TrailingObjectsBase::OverloadToken<PrevTy>()) + 164 TopTrailingObj::callNumTrailingObjects( 165 Obj, TrailingObjectsBase::OverloadToken<PrevTy>()); 166 167 if (requiresRealignment()) 168 return reinterpret_cast<NextTy *>(alignAddr(Ptr, Align::Of<NextTy>())); 169 else 170 return reinterpret_cast<NextTy *>(Ptr); 171 } 172 173 // Helper function for TrailingObjects::additionalSizeToAlloc: this 174 // function recurses to superclasses, each of which requires one 175 // fewer size_t argument, and adds its own size. 176 static constexpr size_t additionalSizeToAllocImpl( 177 size_t SizeSoFar, size_t Count1, 178 typename ExtractSecondType<MoreTys, size_t>::type... MoreCounts) { 179 return ParentType::additionalSizeToAllocImpl( 180 (requiresRealignment() ? llvm::alignTo<alignof(NextTy)>(SizeSoFar) 181 : SizeSoFar) + 182 sizeof(NextTy) * Count1, 183 MoreCounts...); 184 } 185 }; 186 187 // The base case of the TrailingObjectsImpl inheritance recursion, 188 // when there's no more trailing types. 189 template <int Align, typename BaseTy, typename TopTrailingObj, typename PrevTy> 190 class alignas(Align) TrailingObjectsImpl<Align, BaseTy, TopTrailingObj, PrevTy> 191 : public TrailingObjectsBase { 192 protected: 193 // This is a dummy method, only here so the "using" doesn't fail -- 194 // it will never be called, because this function recurses backwards 195 // up the inheritance chain to subclasses. 196 static void getTrailingObjectsImpl(); 197 198 static constexpr size_t additionalSizeToAllocImpl(size_t SizeSoFar) { 199 return SizeSoFar; 200 } 201 202 template <bool CheckAlignment> static void verifyTrailingObjectsAlignment() {} 203 }; 204 205 } // end namespace trailing_objects_internal 206 207 // Finally, the main type defined in this file, the one intended for users... 208 209 /// See the file comment for details on the usage of the 210 /// TrailingObjects type. 211 template <typename BaseTy, typename... TrailingTys> 212 class TrailingObjects : private trailing_objects_internal::TrailingObjectsImpl< 213 trailing_objects_internal::AlignmentCalcHelper< 214 TrailingTys...>::Alignment, 215 BaseTy, TrailingObjects<BaseTy, TrailingTys...>, 216 BaseTy, TrailingTys...> { 217 218 template <int A, typename B, typename T, typename P, typename... M> 219 friend class trailing_objects_internal::TrailingObjectsImpl; 220 221 template <typename... Tys> class Foo {}; 222 223 typedef trailing_objects_internal::TrailingObjectsImpl< 224 trailing_objects_internal::AlignmentCalcHelper<TrailingTys...>::Alignment, 225 BaseTy, TrailingObjects<BaseTy, TrailingTys...>, BaseTy, TrailingTys...> 226 ParentType; 227 using TrailingObjectsBase = trailing_objects_internal::TrailingObjectsBase; 228 229 using ParentType::getTrailingObjectsImpl; 230 231 // This function contains only a static_assert BaseTy is final. The 232 // static_assert must be in a function, and not at class-level 233 // because BaseTy isn't complete at class instantiation time, but 234 // will be by the time this function is instantiated. 235 static void verifyTrailingObjectsAssertions() { 236 static_assert(std::is_final<BaseTy>(), "BaseTy must be final."); 237 } 238 239 // These two methods are the base of the recursion for this method. 240 static const BaseTy * 241 getTrailingObjectsImpl(const BaseTy *Obj, 242 TrailingObjectsBase::OverloadToken<BaseTy>) { 243 return Obj; 244 } 245 246 static BaseTy * 247 getTrailingObjectsImpl(BaseTy *Obj, 248 TrailingObjectsBase::OverloadToken<BaseTy>) { 249 return Obj; 250 } 251 252 // callNumTrailingObjects simply calls numTrailingObjects on the 253 // provided Obj -- except when the type being queried is BaseTy 254 // itself. There is always only one of the base object, so that case 255 // is handled here. (An additional benefit of indirecting through 256 // this function is that consumers only say "friend 257 // TrailingObjects", and thus, only this class itself can call the 258 // numTrailingObjects function.) 259 static size_t 260 callNumTrailingObjects(const BaseTy *Obj, 261 TrailingObjectsBase::OverloadToken<BaseTy>) { 262 return 1; 263 } 264 265 template <typename T> 266 static size_t callNumTrailingObjects(const BaseTy *Obj, 267 TrailingObjectsBase::OverloadToken<T>) { 268 return Obj->numTrailingObjects(TrailingObjectsBase::OverloadToken<T>()); 269 } 270 271 public: 272 // Make this (privately inherited) member public. 273 #ifndef _MSC_VER 274 using ParentType::OverloadToken; 275 #else 276 // An MSVC bug prevents the above from working, (last tested at CL version 277 // 19.28). "Class5" in TrailingObjectsTest.cpp tests the problematic case. 278 template <typename T> 279 using OverloadToken = typename ParentType::template OverloadToken<T>; 280 #endif 281 282 /// Returns a pointer to the trailing object array of the given type 283 /// (which must be one of those specified in the class template). The 284 /// array may have zero or more elements in it. 285 template <typename T> const T *getTrailingObjects() const { 286 verifyTrailingObjectsAssertions(); 287 // Forwards to an impl function with overloads, since member 288 // function templates can't be specialized. 289 return this->getTrailingObjectsImpl( 290 static_cast<const BaseTy *>(this), 291 TrailingObjectsBase::OverloadToken<T>()); 292 } 293 294 /// Returns a pointer to the trailing object array of the given type 295 /// (which must be one of those specified in the class template). The 296 /// array may have zero or more elements in it. 297 template <typename T> T *getTrailingObjects() { 298 verifyTrailingObjectsAssertions(); 299 // Forwards to an impl function with overloads, since member 300 // function templates can't be specialized. 301 return this->getTrailingObjectsImpl( 302 static_cast<BaseTy *>(this), TrailingObjectsBase::OverloadToken<T>()); 303 } 304 305 /// Returns the size of the trailing data, if an object were 306 /// allocated with the given counts (The counts are in the same order 307 /// as the template arguments). This does not include the size of the 308 /// base object. The template arguments must be the same as those 309 /// used in the class; they are supplied here redundantly only so 310 /// that it's clear what the counts are counting in callers. 311 template <typename... Tys> 312 static constexpr std::enable_if_t< 313 std::is_same<Foo<TrailingTys...>, Foo<Tys...>>::value, size_t> 314 additionalSizeToAlloc(typename trailing_objects_internal::ExtractSecondType< 315 TrailingTys, size_t>::type... Counts) { 316 return ParentType::additionalSizeToAllocImpl(0, Counts...); 317 } 318 319 /// Returns the total size of an object if it were allocated with the 320 /// given trailing object counts. This is the same as 321 /// additionalSizeToAlloc, except it *does* include the size of the base 322 /// object. 323 template <typename... Tys> 324 static constexpr std::enable_if_t< 325 std::is_same<Foo<TrailingTys...>, Foo<Tys...>>::value, size_t> 326 totalSizeToAlloc(typename trailing_objects_internal::ExtractSecondType< 327 TrailingTys, size_t>::type... Counts) { 328 return sizeof(BaseTy) + ParentType::additionalSizeToAllocImpl(0, Counts...); 329 } 330 331 TrailingObjects() = default; 332 TrailingObjects(const TrailingObjects &) = delete; 333 TrailingObjects(TrailingObjects &&) = delete; 334 TrailingObjects &operator=(const TrailingObjects &) = delete; 335 TrailingObjects &operator=(TrailingObjects &&) = delete; 336 337 /// A type where its ::with_counts template member has a ::type member 338 /// suitable for use as uninitialized storage for an object with the given 339 /// trailing object counts. The template arguments are similar to those 340 /// of additionalSizeToAlloc. 341 /// 342 /// Use with FixedSizeStorageOwner, e.g.: 343 /// 344 /// \code{.cpp} 345 /// 346 /// MyObj::FixedSizeStorage<void *>::with_counts<1u>::type myStackObjStorage; 347 /// MyObj::FixedSizeStorageOwner 348 /// myStackObjOwner(new ((void *)&myStackObjStorage) MyObj); 349 /// MyObj *const myStackObjPtr = myStackObjOwner.get(); 350 /// 351 /// \endcode 352 template <typename... Tys> struct FixedSizeStorage { 353 template <size_t... Counts> struct with_counts { 354 enum { Size = totalSizeToAlloc<Tys...>(Counts...) }; 355 struct type { 356 alignas(BaseTy) char buffer[Size]; 357 }; 358 }; 359 }; 360 361 /// A type that acts as the owner for an object placed into fixed storage. 362 class FixedSizeStorageOwner { 363 public: 364 FixedSizeStorageOwner(BaseTy *p) : p(p) {} 365 ~FixedSizeStorageOwner() { 366 assert(p && "FixedSizeStorageOwner owns null?"); 367 p->~BaseTy(); 368 } 369 370 BaseTy *get() { return p; } 371 const BaseTy *get() const { return p; } 372 373 private: 374 FixedSizeStorageOwner(const FixedSizeStorageOwner &) = delete; 375 FixedSizeStorageOwner(FixedSizeStorageOwner &&) = delete; 376 FixedSizeStorageOwner &operator=(const FixedSizeStorageOwner &) = delete; 377 FixedSizeStorageOwner &operator=(FixedSizeStorageOwner &&) = delete; 378 379 BaseTy *const p; 380 }; 381 }; 382 383 } // end namespace llvm 384 385 #endif 386
Indexes created Tue Feb 24 08:35:24 UTC 2026