/* * Copyright 2015 The WebRTC Project Authors. All rights reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #ifndef API_ARRAY_VIEW_H_ #define API_ARRAY_VIEW_H_ #include #include #include #include #include "rtc_base/checks.h" #include "rtc_base/type_traits.h" namespace rtc { // tl;dr: rtc::ArrayView is the same thing as gsl::span from the Guideline // Support Library. // // Many functions read from or write to arrays. The obvious way to do this is // to use two arguments, a pointer to the first element and an element count: // // bool Contains17(const int* arr, size_t size) { // for (size_t i = 0; i < size; ++i) { // if (arr[i] == 17) // return true; // } // return false; // } // // This is flexible, since it doesn't matter how the array is stored (C array, // std::vector, rtc::Buffer, ...), but it's error-prone because the caller has // to correctly specify the array length: // // Contains17(arr, arraysize(arr)); // C array // Contains17(arr.data(), arr.size()); // std::vector // Contains17(arr, size); // pointer + size // ... // // It's also kind of messy to have two separate arguments for what is // conceptually a single thing. // // Enter rtc::ArrayView. It contains a T pointer (to an array it doesn't // own) and a count, and supports the basic things you'd expect, such as // indexing and iteration. It allows us to write our function like this: // // bool Contains17(rtc::ArrayView arr) { // for (auto e : arr) { // if (e == 17) // return true; // } // return false; // } // // And even better, because a bunch of things will implicitly convert to // ArrayView, we can call it like this: // // Contains17(arr); // C array // Contains17(arr); // std::vector // Contains17(rtc::ArrayView(arr, size)); // pointer + size // Contains17(nullptr); // nullptr -> empty ArrayView // ... // // ArrayView stores both a pointer and a size, but you may also use // ArrayView, which has a size that's fixed at compile time (which means // it only has to store the pointer). // // One important point is that ArrayView and ArrayView are // different types, which allow and don't allow mutation of the array elements, // respectively. The implicit conversions work just like you'd hope, so that // e.g. vector will convert to either ArrayView or ArrayView, but const vector will convert only to ArrayView. // (ArrayView itself can be the source type in such conversions, so // ArrayView will convert to ArrayView.) // // Note: ArrayView is tiny (just a pointer and a count if variable-sized, just // a pointer if fix-sized) and trivially copyable, so it's probably cheaper to // pass it by value than by const reference. namespace impl { // Magic constant for indicating that the size of an ArrayView is variable // instead of fixed. enum : std::ptrdiff_t { kArrayViewVarSize = -4711 }; // Base class for ArrayViews of fixed nonzero size. template class ArrayViewBase { static_assert(Size > 0, "ArrayView size must be variable or non-negative"); public: ArrayViewBase(T* data, size_t size) : data_(data) {} static constexpr size_t size() { return Size; } static constexpr bool empty() { return false; } T* data() const { return data_; } protected: static constexpr bool fixed_size() { return true; } private: T* data_; }; // Specialized base class for ArrayViews of fixed zero size. template class ArrayViewBase { public: explicit ArrayViewBase(T* data, size_t size) {} static constexpr size_t size() { return 0; } static constexpr bool empty() { return true; } T* data() const { return nullptr; } protected: static constexpr bool fixed_size() { return true; } }; // Specialized base class for ArrayViews of variable size. template class ArrayViewBase { public: ArrayViewBase(T* data, size_t size) : data_(size == 0 ? nullptr : data), size_(size) {} size_t size() const { return size_; } bool empty() const { return size_ == 0; } T* data() const { return data_; } protected: static constexpr bool fixed_size() { return false; } private: T* data_; size_t size_; }; } // namespace impl template class ArrayView final : public impl::ArrayViewBase { public: using value_type = T; using const_iterator = const T*; // Construct an ArrayView from a pointer and a length. template ArrayView(U* data, size_t size) : impl::ArrayViewBase::ArrayViewBase(data, size) { RTC_DCHECK_EQ(size == 0 ? nullptr : data, this->data()); RTC_DCHECK_EQ(size, this->size()); RTC_DCHECK_EQ(!this->data(), this->size() == 0); // data is null iff size == 0. } // Construct an empty ArrayView. Note that fixed-size ArrayViews of size > 0 // cannot be empty. ArrayView() : ArrayView(nullptr, 0) {} ArrayView(std::nullptr_t) // NOLINT : ArrayView() {} ArrayView(std::nullptr_t, size_t size) : ArrayView(static_cast(nullptr), size) { static_assert(Size == 0 || Size == impl::kArrayViewVarSize, ""); RTC_DCHECK_EQ(0, size); } // Construct an ArrayView from a C-style array. template ArrayView(U (&array)[N]) // NOLINT : ArrayView(array, N) { static_assert(Size == N || Size == impl::kArrayViewVarSize, "Array size must match ArrayView size"); } // (Only if size is fixed.) Construct a fixed size ArrayView from a // non-const std::array instance. For an ArrayView with variable size, the // used ctor is ArrayView(U& u) instead. template (N)>::type* = nullptr> ArrayView(std::array& u) // NOLINT : ArrayView(u.data(), u.size()) {} // (Only if size is fixed.) Construct a fixed size ArrayView where T is // const from a const(expr) std::array instance. For an ArrayView with // variable size, the used ctor is ArrayView(U& u) instead. template (N)>::type* = nullptr> ArrayView(const std::array& u) // NOLINT : ArrayView(u.data(), u.size()) {} // (Only if size is fixed.) Construct an ArrayView from any type U that has a // static constexpr size() method whose return value is equal to Size, and a // data() method whose return value converts implicitly to T*. In particular, // this means we allow conversion from ArrayView to ArrayView, but not the other way around. We also don't allow conversion from // ArrayView to ArrayView, or from ArrayView to ArrayView when M != N. template < typename U, typename std::enable_if::value>::type* = nullptr> ArrayView(U& u) // NOLINT : ArrayView(u.data(), u.size()) { static_assert(U::size() == Size, "Sizes must match exactly"); } template < typename U, typename std::enable_if::value>::type* = nullptr> ArrayView(const U& u) // NOLINT(runtime/explicit) : ArrayView(u.data(), u.size()) { static_assert(U::size() == Size, "Sizes must match exactly"); } // (Only if size is variable.) Construct an ArrayView from any type U that // has a size() method whose return value converts implicitly to size_t, and // a data() method whose return value converts implicitly to T*. In // particular, this means we allow conversion from ArrayView to // ArrayView, but not the other way around. Other allowed // conversions include // ArrayView to ArrayView or ArrayView, // std::vector to ArrayView or ArrayView, // const std::vector to ArrayView, // rtc::Buffer to ArrayView or ArrayView, and // const rtc::Buffer to ArrayView. template < typename U, typename std::enable_if::value>::type* = nullptr> ArrayView(U& u) // NOLINT : ArrayView(u.data(), u.size()) {} template < typename U, typename std::enable_if::value>::type* = nullptr> ArrayView(const U& u) // NOLINT(runtime/explicit) : ArrayView(u.data(), u.size()) {} // Indexing and iteration. These allow mutation even if the ArrayView is // const, because the ArrayView doesn't own the array. (To prevent mutation, // use a const element type.) T& operator[](size_t idx) const { RTC_DCHECK_LT(idx, this->size()); RTC_DCHECK(this->data()); return this->data()[idx]; } T* begin() const { return this->data(); } T* end() const { return this->data() + this->size(); } const T* cbegin() const { return this->data(); } const T* cend() const { return this->data() + this->size(); } std::reverse_iterator rbegin() const { return std::make_reverse_iterator(end()); } std::reverse_iterator rend() const { return std::make_reverse_iterator(begin()); } std::reverse_iterator crbegin() const { return std::make_reverse_iterator(cend()); } std::reverse_iterator crend() const { return std::make_reverse_iterator(cbegin()); } ArrayView subview(size_t offset, size_t size) const { return offset < this->size() ? ArrayView(this->data() + offset, std::min(size, this->size() - offset)) : ArrayView(); } ArrayView subview(size_t offset) const { return subview(offset, this->size()); } }; // Comparing two ArrayViews compares their (pointer,size) pairs; it does *not* // dereference the pointers. template bool operator==(const ArrayView& a, const ArrayView& b) { return a.data() == b.data() && a.size() == b.size(); } template bool operator!=(const ArrayView& a, const ArrayView& b) { return !(a == b); } // Variable-size ArrayViews are the size of two pointers; fixed-size ArrayViews // are the size of one pointer. (And as a special case, fixed-size ArrayViews // of size 0 require no storage.) static_assert(sizeof(ArrayView) == 2 * sizeof(int*), ""); static_assert(sizeof(ArrayView) == sizeof(int*), ""); static_assert(std::is_empty>::value, ""); template inline ArrayView MakeArrayView(T* data, size_t size) { return ArrayView(data, size); } // Only for primitive types that have the same size and aligment. // Allow reinterpret cast of the array view to another primitive type of the // same size. // Template arguments order is (U, T, Size) to allow deduction of the template // arguments in client calls: reinterpret_array_view(array_view). template inline ArrayView reinterpret_array_view(ArrayView view) { static_assert(sizeof(U) == sizeof(T) && alignof(U) == alignof(T), "ArrayView reinterpret_cast is only supported for casting " "between views that represent the same chunk of memory."); static_assert( std::is_fundamental::value && std::is_fundamental::value, "ArrayView reinterpret_cast is only supported for casting between " "fundamental types."); return ArrayView(reinterpret_cast(view.data()), view.size()); } } // namespace rtc #endif // API_ARRAY_VIEW_H_