//===- llvm/ADT/ilist_iterator.h - Intrusive List Iterator ------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef LLVM_ADT_ILIST_ITERATOR_H #define LLVM_ADT_ILIST_ITERATOR_H #include "llvm/ADT/ilist_node.h" #include #include #include #include namespace llvm { namespace ilist_detail { /// Find const-correct node types. template struct IteratorTraits; template struct IteratorTraits { using value_type = typename OptionsT::value_type; using pointer = typename OptionsT::pointer; using reference = typename OptionsT::reference; using node_pointer = ilist_node_impl *; using node_reference = ilist_node_impl &; }; template struct IteratorTraits { using value_type = const typename OptionsT::value_type; using pointer = typename OptionsT::const_pointer; using reference = typename OptionsT::const_reference; using node_pointer = const ilist_node_impl *; using node_reference = const ilist_node_impl &; }; template struct IteratorHelper; template <> struct IteratorHelper : ilist_detail::NodeAccess { using Access = ilist_detail::NodeAccess; template static void increment(T *&I) { I = Access::getNext(*I); } template static void decrement(T *&I) { I = Access::getPrev(*I); } }; template <> struct IteratorHelper : ilist_detail::NodeAccess { using Access = ilist_detail::NodeAccess; template static void increment(T *&I) { I = Access::getPrev(*I); } template static void decrement(T *&I) { I = Access::getNext(*I); } }; } // end namespace ilist_detail /// Iterator for intrusive lists based on ilist_node. template class ilist_iterator : ilist_detail::SpecificNodeAccess { friend ilist_iterator; friend ilist_iterator; friend ilist_iterator; using Traits = ilist_detail::IteratorTraits; using Access = ilist_detail::SpecificNodeAccess; public: using value_type = typename Traits::value_type; using pointer = typename Traits::pointer; using reference = typename Traits::reference; using difference_type = ptrdiff_t; using iterator_category = std::bidirectional_iterator_tag; using const_pointer = typename OptionsT::const_pointer; using const_reference = typename OptionsT::const_reference; private: using node_pointer = typename Traits::node_pointer; using node_reference = typename Traits::node_reference; node_pointer NodePtr = nullptr; public: /// Create from an ilist_node. explicit ilist_iterator(node_reference N) : NodePtr(&N) {} explicit ilist_iterator(pointer NP) : NodePtr(Access::getNodePtr(NP)) {} explicit ilist_iterator(reference NR) : NodePtr(Access::getNodePtr(&NR)) {} ilist_iterator() = default; // This is templated so that we can allow constructing a const iterator from // a nonconst iterator... template ilist_iterator(const ilist_iterator &RHS, std::enable_if_t = nullptr) : NodePtr(RHS.NodePtr) {} // This is templated so that we can allow assigning to a const iterator from // a nonconst iterator... template std::enable_if_t operator=(const ilist_iterator &RHS) { NodePtr = RHS.NodePtr; return *this; } /// Explicit conversion between forward/reverse iterators. /// /// Translate between forward and reverse iterators without changing range /// boundaries. The resulting iterator will dereference (and have a handle) /// to the previous node, which is somewhat unexpected; but converting the /// two endpoints in a range will give the same range in reverse. /// /// This matches std::reverse_iterator conversions. explicit ilist_iterator( const ilist_iterator &RHS) : ilist_iterator(++RHS.getReverse()) {} /// Get a reverse iterator to the same node. /// /// Gives a reverse iterator that will dereference (and have a handle) to the /// same node. Converting the endpoint iterators in a range will give a /// different range; for range operations, use the explicit conversions. ilist_iterator getReverse() const { if (NodePtr) return ilist_iterator(*NodePtr); return ilist_iterator(); } /// Const-cast. ilist_iterator getNonConst() const { if (NodePtr) return ilist_iterator( const_cast::node_reference>(*NodePtr)); return ilist_iterator(); } // Accessors... reference operator*() const { assert(!NodePtr->isKnownSentinel()); return *Access::getValuePtr(NodePtr); } pointer operator->() const { return &operator*(); } // Comparison operators friend bool operator==(const ilist_iterator &LHS, const ilist_iterator &RHS) { return LHS.NodePtr == RHS.NodePtr; } friend bool operator!=(const ilist_iterator &LHS, const ilist_iterator &RHS) { return LHS.NodePtr != RHS.NodePtr; } // Increment and decrement operators... ilist_iterator &operator--() { NodePtr = IsReverse ? NodePtr->getNext() : NodePtr->getPrev(); return *this; } ilist_iterator &operator++() { NodePtr = IsReverse ? NodePtr->getPrev() : NodePtr->getNext(); return *this; } ilist_iterator operator--(int) { ilist_iterator tmp = *this; --*this; return tmp; } ilist_iterator operator++(int) { ilist_iterator tmp = *this; ++*this; return tmp; } /// Get the underlying ilist_node. node_pointer getNodePtr() const { return static_cast(NodePtr); } /// Check for end. Only valid if ilist_sentinel_tracking. bool isEnd() const { return NodePtr ? NodePtr->isSentinel() : false; } }; /// Iterator for intrusive lists based on ilist_node. Much like ilist_iterator, /// but with the addition of two bits recording whether this position (when in /// a range) is half or fully open. template class ilist_iterator_w_bits : ilist_detail::SpecificNodeAccess { friend ilist_iterator_w_bits; friend ilist_iterator_w_bits; friend ilist_iterator; using Traits = ilist_detail::IteratorTraits; using Access = ilist_detail::SpecificNodeAccess; public: using value_type = typename Traits::value_type; using pointer = typename Traits::pointer; using reference = typename Traits::reference; using difference_type = ptrdiff_t; using iterator_category = std::bidirectional_iterator_tag; using const_pointer = typename OptionsT::const_pointer; using const_reference = typename OptionsT::const_reference; private: using node_pointer = typename Traits::node_pointer; using node_reference = typename Traits::node_reference; node_pointer NodePtr = nullptr; #ifdef EXPERIMENTAL_DEBUGINFO_ITERATORS // (Default: Off) Allow extra position-information flags to be stored // in iterators, in aid of removing debug-info intrinsics from LLVM. /// Is this position intended to contain any debug-info immediately before /// the position? mutable bool HeadInclusiveBit = false; /// Is this position intended to contain any debug-info immediately after /// the position? mutable bool TailInclusiveBit = false; #endif public: /// Create from an ilist_node. explicit ilist_iterator_w_bits(node_reference N) : NodePtr(&N) {} explicit ilist_iterator_w_bits(pointer NP) : NodePtr(Access::getNodePtr(NP)) {} explicit ilist_iterator_w_bits(reference NR) : NodePtr(Access::getNodePtr(&NR)) {} ilist_iterator_w_bits() = default; // This is templated so that we can allow constructing a const iterator from // a nonconst iterator... template ilist_iterator_w_bits( const ilist_iterator_w_bits &RHS, std::enable_if_t = nullptr) : NodePtr(RHS.NodePtr) { #ifdef EXPERIMENTAL_DEBUGINFO_ITERATORS HeadInclusiveBit = RHS.HeadInclusiveBit; TailInclusiveBit = RHS.TailInclusiveBit; #endif } // This is templated so that we can allow assigning to a const iterator from // a nonconst iterator... template std::enable_if_t operator=(const ilist_iterator_w_bits &RHS) { NodePtr = RHS.NodePtr; #ifdef EXPERIMENTAL_DEBUGINFO_ITERATORS HeadInclusiveBit = RHS.HeadInclusiveBit; TailInclusiveBit = RHS.TailInclusiveBit; #endif return *this; } /// Explicit conversion between forward/reverse iterators. /// /// Translate between forward and reverse iterators without changing range /// boundaries. The resulting iterator will dereference (and have a handle) /// to the previous node, which is somewhat unexpected; but converting the /// two endpoints in a range will give the same range in reverse. /// /// This matches std::reverse_iterator conversions. explicit ilist_iterator_w_bits( const ilist_iterator_w_bits &RHS) : ilist_iterator_w_bits(++RHS.getReverse()) {} /// Get a reverse iterator to the same node. /// /// Gives a reverse iterator that will dereference (and have a handle) to the /// same node. Converting the endpoint iterators in a range will give a /// different range; for range operations, use the explicit conversions. ilist_iterator_w_bits getReverse() const { if (NodePtr) return ilist_iterator_w_bits(*NodePtr); return ilist_iterator_w_bits(); } /// Const-cast. ilist_iterator_w_bits getNonConst() const { if (NodePtr) { auto New = ilist_iterator_w_bits( const_cast::node_reference>( *NodePtr)); #ifdef EXPERIMENTAL_DEBUGINFO_ITERATORS New.HeadInclusiveBit = HeadInclusiveBit; New.TailInclusiveBit = TailInclusiveBit; #endif return New; } return ilist_iterator_w_bits(); } // Accessors... reference operator*() const { assert(!NodePtr->isKnownSentinel()); return *Access::getValuePtr(NodePtr); } pointer operator->() const { return &operator*(); } // Comparison operators friend bool operator==(const ilist_iterator_w_bits &LHS, const ilist_iterator_w_bits &RHS) { return LHS.NodePtr == RHS.NodePtr; } friend bool operator!=(const ilist_iterator_w_bits &LHS, const ilist_iterator_w_bits &RHS) { return LHS.NodePtr != RHS.NodePtr; } // Increment and decrement operators... ilist_iterator_w_bits &operator--() { NodePtr = IsReverse ? NodePtr->getNext() : NodePtr->getPrev(); #ifdef EXPERIMENTAL_DEBUGINFO_ITERATORS HeadInclusiveBit = false; TailInclusiveBit = false; #endif return *this; } ilist_iterator_w_bits &operator++() { NodePtr = IsReverse ? NodePtr->getPrev() : NodePtr->getNext(); #ifdef EXPERIMENTAL_DEBUGINFO_ITERATORS HeadInclusiveBit = false; TailInclusiveBit = false; #endif return *this; } ilist_iterator_w_bits operator--(int) { ilist_iterator_w_bits tmp = *this; --*this; return tmp; } ilist_iterator_w_bits operator++(int) { ilist_iterator_w_bits tmp = *this; ++*this; return tmp; } /// Get the underlying ilist_node. node_pointer getNodePtr() const { return static_cast(NodePtr); } /// Check for end. Only valid if ilist_sentinel_tracking. bool isEnd() const { return NodePtr ? NodePtr->isSentinel() : false; } #ifdef EXPERIMENTAL_DEBUGINFO_ITERATORS bool getHeadBit() const { return HeadInclusiveBit; } bool getTailBit() const { return TailInclusiveBit; } void setHeadBit(bool SetBit) const { HeadInclusiveBit = SetBit; } void setTailBit(bool SetBit) const { TailInclusiveBit = SetBit; } #else // Store and return no information if we're not using this feature. bool getHeadBit() const { return false; } bool getTailBit() const { return false; } void setHeadBit(bool SetBit) const { (void)SetBit; } void setTailBit(bool SetBit) const { (void)SetBit; } #endif }; template struct simplify_type; /// Allow ilist_iterators to convert into pointers to a node automatically when /// used by the dyn_cast, cast, isa mechanisms... /// /// FIXME: remove this, since there is no implicit conversion to NodeTy. template struct simplify_type> { using iterator = ilist_iterator; using SimpleType = typename iterator::pointer; static SimpleType getSimplifiedValue(const iterator &Node) { return &*Node; } }; template struct simplify_type> : simplify_type> {}; // ilist_iterator_w_bits should also be accessible via isa/dyn_cast. template struct simplify_type> { using iterator = ilist_iterator_w_bits; using SimpleType = typename iterator::pointer; static SimpleType getSimplifiedValue(const iterator &Node) { return &*Node; } }; template struct simplify_type> : simplify_type> {}; } // end namespace llvm #endif // LLVM_ADT_ILIST_ITERATOR_H