// Copyright 2018 The Abseil Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // https://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // // MOTIVATION AND TUTORIAL // // If you want to put in a single heap allocation N doubles followed by M ints, // it's easy if N and M are known at compile time. // // struct S { // double a[N]; // int b[M]; // }; // // S* p = new S; // // But what if N and M are known only in run time? Class template Layout to the // rescue! It's a portable generalization of the technique known as struct hack. // // // This object will tell us everything we need to know about the memory // // layout of double[N] followed by int[M]. It's structurally identical to // // size_t[2] that stores N and M. It's very cheap to create. // const Layout<double, int> layout(N, M); // // // Allocate enough memory for both arrays. `AllocSize()` tells us how much // // memory is needed. We are free to use any allocation function we want as // // long as it returns aligned memory. // std::unique_ptr<unsigned char[]> p(new unsigned char[layout.AllocSize()]); // // // Obtain the pointer to the array of doubles. // // Equivalent to `reinterpret_cast<double*>(p.get())`. // // // // We could have written layout.Pointer<0>(p) instead. If all the types are // // unique you can use either form, but if some types are repeated you must // // use the index form. // double* a = layout.Pointer<double>(p.get()); // // // Obtain the pointer to the array of ints. // // Equivalent to `reinterpret_cast<int*>(p.get() + N * 8)`. // int* b = layout.Pointer<int>(p); // // If we are unable to specify sizes of all fields, we can pass as many sizes as // we can to `Partial()`. In return, it'll allow us to access the fields whose // locations and sizes can be computed from the provided information. // `Partial()` comes in handy when the array sizes are embedded into the // allocation. // // // size_t[1] containing N, size_t[1] containing M, double[N], int[M]. // using L = Layout<size_t, size_t, double, int>; // // unsigned char* Allocate(size_t n, size_t m) { // const L layout(1, 1, n, m); // unsigned char* p = new unsigned char[layout.AllocSize()]; // *layout.Pointer<0>(p) = n; // *layout.Pointer<1>(p) = m; // return p; // } // // void Use(unsigned char* p) { // // First, extract N and M. // // Specify that the first array has only one element. Using `prefix` we // // can access the first two arrays but not more. // constexpr auto prefix = L::Partial(1); // size_t n = *prefix.Pointer<0>(p); // size_t m = *prefix.Pointer<1>(p); // // // Now we can get pointers to the payload. // const L layout(1, 1, n, m); // double* a = layout.Pointer<double>(p); // int* b = layout.Pointer<int>(p); // } // // The layout we used above combines fixed-size with dynamically-sized fields. // This is quite common. Layout is optimized for this use case and generates // optimal code. All computations that can be performed at compile time are // indeed performed at compile time. // // Efficiency tip: The order of fields matters. In `Layout<T1, ..., TN>` try to // ensure that `alignof(T1) >= ... >= alignof(TN)`. This way you'll have no // padding in between arrays. // // You can manually override the alignment of an array by wrapping the type in // `Aligned<T, N>`. `Layout<..., Aligned<T, N>, ...>` has exactly the same API // and behavior as `Layout<..., T, ...>` except that the first element of the // array of `T` is aligned to `N` (the rest of the elements follow without // padding). `N` cannot be less than `alignof(T)`. // // `AllocSize()` and `Pointer()` are the most basic methods for dealing with // memory layouts. Check out the reference or code below to discover more. // // EXAMPLE // // // Immutable move-only string with sizeof equal to sizeof(void*). The // // string size and the characters are kept in the same heap allocation. // class CompactString { // public: // CompactString(const char* s = "") { // const size_t size = strlen(s); // // size_t[1] followed by char[size + 1]. // const L layout(1, size + 1); // p_.reset(new unsigned char[layout.AllocSize()]); // // If running under ASAN, mark the padding bytes, if any, to catch // // memory errors. // layout.PoisonPadding(p_.get()); // // Store the size in the allocation. // *layout.Pointer<size_t>(p_.get()) = size; // // Store the characters in the allocation. // memcpy(layout.Pointer<char>(p_.get()), s, size + 1); // } // // size_t size() const { // // Equivalent to reinterpret_cast<size_t&>(*p). // return *L::Partial().Pointer<size_t>(p_.get()); // } // // const char* c_str() const { // // Equivalent to reinterpret_cast<char*>(p.get() + sizeof(size_t)). // // The argument in Partial(1) specifies that we have size_t[1] in front // // of the characters. // return L::Partial(1).Pointer<char>(p_.get()); // } // // private: // // Our heap allocation contains a size_t followed by an array of chars. // using L = Layout<size_t, char>; // std::unique_ptr<unsigned char[]> p_; // }; // // int main() { // CompactString s = "hello"; // assert(s.size() == 5); // assert(strcmp(s.c_str(), "hello") == 0); // } // // DOCUMENTATION // // The interface exported by this file consists of: // - class `Layout<>` and its public members. // - The public members of class `internal_layout::LayoutImpl<>`. That class // isn't intended to be used directly, and its name and template parameter // list are internal implementation details, but the class itself provides // most of the functionality in this file. See comments on its members for // detailed documentation. // // `Layout<T1,... Tn>::Partial(count1,..., countm)` (where `m` <= `n`) returns a // `LayoutImpl<>` object. `Layout<T1,..., Tn> layout(count1,..., countn)` // creates a `Layout` object, which exposes the same functionality by inheriting // from `LayoutImpl<>`. #ifndef ABSL_CONTAINER_INTERNAL_LAYOUT_H_ #define ABSL_CONTAINER_INTERNAL_LAYOUT_H_ #include <assert.h> #include <stddef.h> #include <stdint.h> #include <ostream> #include <string> #include <tuple> #include <type_traits> #include <typeinfo> #include <utility> #include "absl/base/config.h" #include "absl/meta/type_traits.h" #include "absl/strings/str_cat.h" #include "absl/types/span.h" #include "absl/utility/utility.h" #ifdef ABSL_HAVE_ADDRESS_SANITIZER #include <sanitizer/asan_interface.h> #endif #if defined(__GXX_RTTI) #define ABSL_INTERNAL_HAS_CXA_DEMANGLE #endif #ifdef ABSL_INTERNAL_HAS_CXA_DEMANGLE #include <cxxabi.h> #endif namespace absl { ABSL_NAMESPACE_BEGIN namespace container_internal { // A type wrapper that instructs `Layout` to use the specific alignment for the // array. `Layout<..., Aligned<T, N>, ...>` has exactly the same API // and behavior as `Layout<..., T, ...>` except that the first element of the // array of `T` is aligned to `N` (the rest of the elements follow without // padding). // // Requires: `N >= alignof(T)` and `N` is a power of 2. template <class T, size_t N> struct Aligned; namespace internal_layout { template <class T> struct NotAligned {}; template <class T, size_t N> struct NotAligned<const Aligned<T, N>> { static_assert(sizeof(T) == 0, "Aligned<T, N> cannot be const-qualified"); }; template <size_t> using IntToSize = size_t; template <class> using TypeToSize = size_t; template <class T> struct Type : NotAligned<T> { using type = T; }; template <class T, size_t N> struct Type<Aligned<T, N>> { using type = T; }; template <class T> struct SizeOf : NotAligned<T>, std::integral_constant<size_t, sizeof(T)> {}; template <class T, size_t N> struct SizeOf<Aligned<T, N>> : std::integral_constant<size_t, sizeof(T)> {}; // Note: workaround for https://gcc.gnu.org/PR88115 template <class T> struct AlignOf : NotAligned<T> { static constexpr size_t value = alignof(T); }; template <class T, size_t N> struct AlignOf<Aligned<T, N>> { static_assert(N % alignof(T) == 0, "Custom alignment can't be lower than the type's alignment"); static constexpr size_t value = N; }; // Does `Ts...` contain `T`? template <class T, class... Ts> using Contains = absl::disjunction<std::is_same<T, Ts>...>; template <class From, class To> using CopyConst = typename std::conditional<std::is_const<From>::value, const To, To>::type; // Note: We're not qualifying this with absl:: because it doesn't compile under // MSVC. template <class T> using SliceType = Span<T>; // This namespace contains no types. It prevents functions defined in it from // being found by ADL. namespace adl_barrier { template <class Needle, class... Ts> constexpr size_t Find(Needle, Needle, Ts...) { static_assert(!Contains<Needle, Ts...>(), "Duplicate element type"); return 0; } template <class Needle, class T, class... Ts> constexpr size_t Find(Needle, T, Ts...) { return adl_barrier::Find(Needle(), Ts()...) + 1; } constexpr bool IsPow2(size_t n) { return !(n & (n - 1)); } // Returns `q * m` for the smallest `q` such that `q * m >= n`. // Requires: `m` is a power of two. It's enforced by IsLegalElementType below. constexpr size_t Align(size_t n, size_t m) { return (n + m - 1) & ~(m - 1); } constexpr size_t Min(size_t a, size_t b) { return b < a ? b : a; } constexpr size_t Max(size_t a) { return a; } template <class... Ts> constexpr size_t Max(size_t a, size_t b, Ts... rest) { return adl_barrier::Max(b < a ? a : b, rest...); } template <class T> std::string TypeName() { std::string out; int status = 0; char* demangled = nullptr; #ifdef ABSL_INTERNAL_HAS_CXA_DEMANGLE demangled = abi::__cxa_demangle(typeid(T).name(), nullptr, nullptr, &status); #endif if (status == 0 && demangled != nullptr) { // Demangling succeeded. absl::StrAppend(&out, "<", demangled, ">"); free(demangled); } else { #if defined(__GXX_RTTI) || defined(_CPPRTTI) absl::StrAppend(&out, "<", typeid(T).name(), ">"); #endif } return out; } } // namespace adl_barrier template <bool C> using EnableIf = typename std::enable_if<C, int>::type; // Can `T` be a template argument of `Layout`? template <class T> using IsLegalElementType = std::integral_constant< bool, !std::is_reference<T>::value && !std::is_volatile<T>::value && !std::is_reference<typename Type<T>::type>::value && !std::is_volatile<typename Type<T>::type>::value && adl_barrier::IsPow2(AlignOf<T>::value)>; template <class Elements, class SizeSeq, class OffsetSeq> class LayoutImpl; // Public base class of `Layout` and the result type of `Layout::Partial()`. // // `Elements...` contains all template arguments of `Layout` that created this // instance. // // `SizeSeq...` is `[0, NumSizes)` where `NumSizes` is the number of arguments // passed to `Layout::Partial()` or `Layout::Layout()`. // // `OffsetSeq...` is `[0, NumOffsets)` where `NumOffsets` is // `Min(sizeof...(Elements), NumSizes + 1)` (the number of arrays for which we // can compute offsets). template <class... Elements, size_t... SizeSeq, size_t... OffsetSeq> class LayoutImpl<std::tuple<Elements...>, absl::index_sequence<SizeSeq...>, absl::index_sequence<OffsetSeq...>> { private: static_assert(sizeof...(Elements) > 0, "At least one field is required"); static_assert(absl::conjunction<IsLegalElementType<Elements>...>::value, "Invalid element type (see IsLegalElementType)"); enum { NumTypes = sizeof...(Elements), NumSizes = sizeof...(SizeSeq), NumOffsets = sizeof...(OffsetSeq), }; // These are guaranteed by `Layout`. static_assert(NumOffsets == adl_barrier::Min(NumTypes, NumSizes + 1), "Internal error"); static_assert(NumTypes > 0, "Internal error"); // Returns the index of `T` in `Elements...`. Results in a compilation error // if `Elements...` doesn't contain exactly one instance of `T`. template <class T> static constexpr size_t ElementIndex() { static_assert(Contains<Type<T>, Type<typename Type<Elements>::type>...>(), "Type not found"); return adl_barrier::Find(Type<T>(), Type<typename Type<Elements>::type>()...); } template <size_t N> using ElementAlignment = AlignOf<typename std::tuple_element<N, std::tuple<Elements...>>::type>; public: // Element types of all arrays packed in a tuple. using ElementTypes = std::tuple<typename Type<Elements>::type...>; // Element type of the Nth array. template <size_t N> using ElementType = typename std::tuple_element<N, ElementTypes>::type; constexpr explicit LayoutImpl(IntToSize<SizeSeq>... sizes) : size_{sizes...} {} // Alignment of the layout, equal to the strictest alignment of all elements. // All pointers passed to the methods of layout must be aligned to this value. static constexpr size_t Alignment() { return adl_barrier::Max(AlignOf<Elements>::value...); } // Offset in bytes of the Nth array. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // assert(x.Offset<0>() == 0); // The ints starts from 0. // assert(x.Offset<1>() == 16); // The doubles starts from 16. // // Requires: `N <= NumSizes && N < sizeof...(Ts)`. template <size_t N, EnableIf<N == 0> = 0> constexpr size_t Offset() const { return 0; } template <size_t N, EnableIf<N != 0> = 0> constexpr size_t Offset() const { static_assert(N < NumOffsets, "Index out of bounds"); return adl_barrier::Align( Offset<N - 1>() + SizeOf<ElementType<N - 1>>::value * size_[N - 1], ElementAlignment<N>::value); } // Offset in bytes of the array with the specified element type. There must // be exactly one such array and its zero-based index must be at most // `NumSizes`. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // assert(x.Offset<int>() == 0); // The ints starts from 0. // assert(x.Offset<double>() == 16); // The doubles starts from 16. template <class T> constexpr size_t Offset() const { return Offset<ElementIndex<T>()>(); } // Offsets in bytes of all arrays for which the offsets are known. constexpr std::array<size_t, NumOffsets> Offsets() const { return {{Offset<OffsetSeq>()...}}; } // The number of elements in the Nth array. This is the Nth argument of // `Layout::Partial()` or `Layout::Layout()` (zero-based). // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // assert(x.Size<0>() == 3); // assert(x.Size<1>() == 4); // // Requires: `N < NumSizes`. template <size_t N> constexpr size_t Size() const { static_assert(N < NumSizes, "Index out of bounds"); return size_[N]; } // The number of elements in the array with the specified element type. // There must be exactly one such array and its zero-based index must be // at most `NumSizes`. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // assert(x.Size<int>() == 3); // assert(x.Size<double>() == 4); template <class T> constexpr size_t Size() const { return Size<ElementIndex<T>()>(); } // The number of elements of all arrays for which they are known. constexpr std::array<size_t, NumSizes> Sizes() const { return {{Size<SizeSeq>()...}}; } // Pointer to the beginning of the Nth array. // // `Char` must be `[const] [signed|unsigned] char`. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // unsigned char* p = new unsigned char[x.AllocSize()]; // int* ints = x.Pointer<0>(p); // double* doubles = x.Pointer<1>(p); // // Requires: `N <= NumSizes && N < sizeof...(Ts)`. // Requires: `p` is aligned to `Alignment()`. template <size_t N, class Char> CopyConst<Char, ElementType<N>>* Pointer(Char* p) const { using C = typename std::remove_const<Char>::type; static_assert( std::is_same<C, char>() || std::is_same<C, unsigned char>() || std::is_same<C, signed char>(), "The argument must be a pointer to [const] [signed|unsigned] char"); constexpr size_t alignment = Alignment(); (void)alignment; assert(reinterpret_cast<uintptr_t>(p) % alignment == 0); return reinterpret_cast<CopyConst<Char, ElementType<N>>*>(p + Offset<N>()); } // Pointer to the beginning of the array with the specified element type. // There must be exactly one such array and its zero-based index must be at // most `NumSizes`. // // `Char` must be `[const] [signed|unsigned] char`. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // unsigned char* p = new unsigned char[x.AllocSize()]; // int* ints = x.Pointer<int>(p); // double* doubles = x.Pointer<double>(p); // // Requires: `p` is aligned to `Alignment()`. template <class T, class Char> CopyConst<Char, T>* Pointer(Char* p) const { return Pointer<ElementIndex<T>()>(p); } // Pointers to all arrays for which pointers are known. // // `Char` must be `[const] [signed|unsigned] char`. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // unsigned char* p = new unsigned char[x.AllocSize()]; // // int* ints; // double* doubles; // std::tie(ints, doubles) = x.Pointers(p); // // Requires: `p` is aligned to `Alignment()`. // // Note: We're not using ElementType alias here because it does not compile // under MSVC. template <class Char> std::tuple<CopyConst< Char, typename std::tuple_element<OffsetSeq, ElementTypes>::type>*...> Pointers(Char* p) const { return std::tuple<CopyConst<Char, ElementType<OffsetSeq>>*...>( Pointer<OffsetSeq>(p)...); } // The Nth array. // // `Char` must be `[const] [signed|unsigned] char`. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // unsigned char* p = new unsigned char[x.AllocSize()]; // Span<int> ints = x.Slice<0>(p); // Span<double> doubles = x.Slice<1>(p); // // Requires: `N < NumSizes`. // Requires: `p` is aligned to `Alignment()`. template <size_t N, class Char> SliceType<CopyConst<Char, ElementType<N>>> Slice(Char* p) const { return SliceType<CopyConst<Char, ElementType<N>>>(Pointer<N>(p), Size<N>()); } // The array with the specified element type. There must be exactly one // such array and its zero-based index must be less than `NumSizes`. // // `Char` must be `[const] [signed|unsigned] char`. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // unsigned char* p = new unsigned char[x.AllocSize()]; // Span<int> ints = x.Slice<int>(p); // Span<double> doubles = x.Slice<double>(p); // // Requires: `p` is aligned to `Alignment()`. template <class T, class Char> SliceType<CopyConst<Char, T>> Slice(Char* p) const { return Slice<ElementIndex<T>()>(p); } // All arrays with known sizes. // // `Char` must be `[const] [signed|unsigned] char`. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // unsigned char* p = new unsigned char[x.AllocSize()]; // // Span<int> ints; // Span<double> doubles; // std::tie(ints, doubles) = x.Slices(p); // // Requires: `p` is aligned to `Alignment()`. // // Note: We're not using ElementType alias here because it does not compile // under MSVC. template <class Char> std::tuple<SliceType<CopyConst< Char, typename std::tuple_element<SizeSeq, ElementTypes>::type>>...> Slices(Char* p) const { // Workaround for https://gcc.gnu.org/bugzilla/show_bug.cgi?id=63875 (fixed // in 6.1). (void)p; return std::tuple<SliceType<CopyConst<Char, ElementType<SizeSeq>>>...>( Slice<SizeSeq>(p)...); } // The size of the allocation that fits all arrays. // // // int[3], 4 bytes of padding, double[4]. // Layout<int, double> x(3, 4); // unsigned char* p = new unsigned char[x.AllocSize()]; // 48 bytes // // Requires: `NumSizes == sizeof...(Ts)`. constexpr size_t AllocSize() const { static_assert(NumTypes == NumSizes, "You must specify sizes of all fields"); return Offset<NumTypes - 1>() + SizeOf<ElementType<NumTypes - 1>>::value * size_[NumTypes - 1]; } // If built with --config=asan, poisons padding bytes (if any) in the // allocation. The pointer must point to a memory block at least // `AllocSize()` bytes in length. // // `Char` must be `[const] [signed|unsigned] char`. // // Requires: `p` is aligned to `Alignment()`. template <class Char, size_t N = NumOffsets - 1, EnableIf<N == 0> = 0> void PoisonPadding(const Char* p) const { Pointer<0>(p); // verify the requirements on `Char` and `p` } template <class Char, size_t N = NumOffsets - 1, EnableIf<N != 0> = 0> void PoisonPadding(const Char* p) const { static_assert(N < NumOffsets, "Index out of bounds"); (void)p; #ifdef ABSL_HAVE_ADDRESS_SANITIZER PoisonPadding<Char, N - 1>(p); // The `if` is an optimization. It doesn't affect the observable behaviour. if (ElementAlignment<N - 1>::value % ElementAlignment<N>::value) { size_t start = Offset<N - 1>() + SizeOf<ElementType<N - 1>>::value * size_[N - 1]; ASAN_POISON_MEMORY_REGION(p + start, Offset<N>() - start); } #endif } // Human-readable description of the memory layout. Useful for debugging. // Slow. // // // char[5], 3 bytes of padding, int[3], 4 bytes of padding, followed // // by an unknown number of doubles. // auto x = Layout<char, int, double>::Partial(5, 3); // assert(x.DebugString() == // "@0<char>(1)[5]; @8<int>(4)[3]; @24<double>(8)"); // // Each field is in the following format: @offset<type>(sizeof)[size] (<type> // may be missing depending on the target platform). For example, // @8<int>(4)[3] means that at offset 8 we have an array of ints, where each // int is 4 bytes, and we have 3 of those ints. The size of the last field may // be missing (as in the example above). Only fields with known offsets are // described. Type names may differ across platforms: one compiler might // produce "unsigned*" where another produces "unsigned int *". std::string DebugString() const { const auto offsets = Offsets(); const size_t sizes[] = {SizeOf<ElementType<OffsetSeq>>::value...}; const std::string types[] = { adl_barrier::TypeName<ElementType<OffsetSeq>>()...}; std::string res = absl::StrCat("@0", types[0], "(", sizes[0], ")"); for (size_t i = 0; i != NumOffsets - 1; ++i) { absl::StrAppend(&res, "[", size_[i], "]; @", offsets[i + 1], types[i + 1], "(", sizes[i + 1], ")"); } // NumSizes is a constant that may be zero. Some compilers cannot see that // inside the if statement "size_[NumSizes - 1]" must be valid. int last = static_cast<int>(NumSizes) - 1; if (NumTypes == NumSizes && last >= 0) { absl::StrAppend(&res, "[", size_[last], "]"); } return res; } private: // Arguments of `Layout::Partial()` or `Layout::Layout()`. size_t size_[NumSizes > 0 ? NumSizes : 1]; }; template <size_t NumSizes, class... Ts> using LayoutType = LayoutImpl< std::tuple<Ts...>, absl::make_index_sequence<NumSizes>, absl::make_index_sequence<adl_barrier::Min(sizeof...(Ts), NumSizes + 1)>>; } // namespace internal_layout // Descriptor of arrays of various types and sizes laid out in memory one after // another. See the top of the file for documentation. // // Check out the public API of internal_layout::LayoutImpl above. The type is // internal to the library but its methods are public, and they are inherited // by `Layout`. template <class... Ts> class Layout : public internal_layout::LayoutType<sizeof...(Ts), Ts...> { public: static_assert(sizeof...(Ts) > 0, "At least one field is required"); static_assert( absl::conjunction<internal_layout::IsLegalElementType<Ts>...>::value, "Invalid element type (see IsLegalElementType)"); // The result type of `Partial()` with `NumSizes` arguments. template <size_t NumSizes> using PartialType = internal_layout::LayoutType<NumSizes, Ts...>; // `Layout` knows the element types of the arrays we want to lay out in // memory but not the number of elements in each array. // `Partial(size1, ..., sizeN)` allows us to specify the latter. The // resulting immutable object can be used to obtain pointers to the // individual arrays. // // It's allowed to pass fewer array sizes than the number of arrays. E.g., // if all you need is to the offset of the second array, you only need to // pass one argument -- the number of elements in the first array. // // // int[3] followed by 4 bytes of padding and an unknown number of // // doubles. // auto x = Layout<int, double>::Partial(3); // // doubles start at byte 16. // assert(x.Offset<1>() == 16); // // If you know the number of elements in all arrays, you can still call // `Partial()` but it's more convenient to use the constructor of `Layout`. // // Layout<int, double> x(3, 5); // // Note: The sizes of the arrays must be specified in number of elements, // not in bytes. // // Requires: `sizeof...(Sizes) <= sizeof...(Ts)`. // Requires: all arguments are convertible to `size_t`. template <class... Sizes> static constexpr PartialType<sizeof...(Sizes)> Partial(Sizes&&... sizes) { static_assert(sizeof...(Sizes) <= sizeof...(Ts), ""); return PartialType<sizeof...(Sizes)>(absl::forward<Sizes>(sizes)...); } // Creates a layout with the sizes of all arrays specified. If you know // only the sizes of the first N arrays (where N can be zero), you can use // `Partial()` defined above. The constructor is essentially equivalent to // calling `Partial()` and passing in all array sizes; the constructor is // provided as a convenient abbreviation. // // Note: The sizes of the arrays must be specified in number of elements, // not in bytes. constexpr explicit Layout(internal_layout::TypeToSize<Ts>... sizes) : internal_layout::LayoutType<sizeof...(Ts), Ts...>(sizes...) {} }; } // namespace container_internal ABSL_NAMESPACE_END } // namespace absl #endif // ABSL_CONTAINER_INTERNAL_LAYOUT_H_