llvm/include/llvm/ADT/PriorityWorklist.h - llvm-project - Git at Google

 //===- PriorityWorklist.h - Worklist with insertion priority ----*- 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
 //
 //===----------------------------------------------------------------------===//
 ///
 /// \file
 ///
 /// This file provides a priority worklist. See the class comments for details.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ADT_PRIORITYWORKLIST_H
 #define LLVM_ADT_PRIORITYWORKLIST_H

 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/Support/Compiler.h"
 #include <algorithm>
 #include <cassert>
 #include <cstddef>
 #include <iterator>
 #include <type_traits>
 #include <vector>

 namespace llvm {

 /// A FILO worklist that prioritizes on re-insertion without duplication.
 ///
 /// This is very similar to a \c SetVector with the primary difference that
 /// while re-insertion does not create a duplicate, it does adjust the
 /// visitation order to respect the last insertion point. This can be useful
 /// when the visit order needs to be prioritized based on insertion point
 /// without actually having duplicate visits.
 ///
 /// Note that this doesn't prevent re-insertion of elements which have been
 /// visited -- if you need to break cycles, a set will still be necessary.
 ///
 /// The type \c T must be default constructable to a null value that will be
 /// ignored. It is an error to insert such a value, and popping elements will
 /// never produce such a value. It is expected to be used with common nullable
 /// types like pointers or optionals.
 ///
 /// Internally this uses a vector to store the worklist and a map to identify
 /// existing elements in the worklist. Both of these may be customized, but the
 /// map must support the basic DenseMap API for mapping from a T to an integer
 /// index into the vector.
 ///
 /// A partial specialization is provided to automatically select a SmallVector
 /// and a SmallDenseMap if custom data structures are not provided.
 template <typename T, typename VectorT = std::vector<T>,
           typename MapT = DenseMap<T, ptrdiff_t>>
 class PriorityWorklist {
 public:
   using value_type = T;
   using key_type = T;
   using reference = T&;
   using const_reference = const T&;
   using size_type = typename MapT::size_type;

   /// Construct an empty PriorityWorklist
   PriorityWorklist() = default;

   /// Determine if the PriorityWorklist is empty or not.
   bool empty() const {
     return V.empty();
   }

   /// Returns the number of elements in the worklist.
   size_type size() const {
     return M.size();
   }

   /// Count the number of elements of a given key in the PriorityWorklist.
   /// \returns 0 if the element is not in the PriorityWorklist, 1 if it is.
   size_type count(const key_type &key) const {
     return M.count(key);
   }

   /// Return the last element of the PriorityWorklist.
   const T &back() const {
     assert(!empty() && "Cannot call back() on empty PriorityWorklist!");
     return V.back();
   }

   /// Insert a new element into the PriorityWorklist.
   /// \returns true if the element was inserted into the PriorityWorklist.
   bool insert(const T &X) {
     assert(X != T() && "Cannot insert a null (default constructed) value!");
     auto InsertResult = M.insert({X, V.size()});
     if (InsertResult.second) {
       // Fresh value, just append it to the vector.
       V.push_back(X);
       return true;
     }

     auto &Index = InsertResult.first->second;
     assert(V[Index] == X && "Value not actually at index in map!");
     if (Index != (ptrdiff_t)(V.size() - 1)) {
       // If the element isn't at the back, null it out and append a fresh one.
       V[Index] = T();
       Index = (ptrdiff_t)V.size();
       V.push_back(X);
     }
     return false;
   }

   /// Insert a sequence of new elements into the PriorityWorklist.
   template <typename SequenceT>
   std::enable_if_t<!std::is_convertible<SequenceT, T>::value>
   insert(SequenceT &&Input) {
     if (std::begin(Input) == std::end(Input))
       // Nothing to do for an empty input sequence.
       return;

     // First pull the input sequence into the vector as a bulk append
     // operation.
     ptrdiff_t StartIndex = V.size();
     V.insert(V.end(), std::begin(Input), std::end(Input));
     // Now walk backwards fixing up the index map and deleting any duplicates.
     for (ptrdiff_t i = V.size() - 1; i >= StartIndex; --i) {
       auto InsertResult = M.insert({V[i], i});
       if (InsertResult.second)
         continue;

       // If the existing index is before this insert's start, nuke that one and
       // move it up.
       ptrdiff_t &Index = InsertResult.first->second;
       if (Index < StartIndex) {
         V[Index] = T();
         Index = i;
         continue;
       }

       // Otherwise the existing one comes first so just clear out the value in
       // this slot.
       V[i] = T();
     }
   }

   /// Remove the last element of the PriorityWorklist.
   void pop_back() {
     assert(!empty() && "Cannot remove an element when empty!");
     assert(back() != T() && "Cannot have a null element at the back!");
     M.erase(back());
     do {
       V.pop_back();
     } while (!V.empty() && V.back() == T());
   }

   LLVM_NODISCARD T pop_back_val() {
     T Ret = back();
     pop_back();
     return Ret;
   }

   /// Erase an item from the worklist.
   ///
   /// Note that this is constant time due to the nature of the worklist implementation.
   bool erase(const T& X) {
     auto I = M.find(X);
     if (I == M.end())
       return false;

     assert(V[I->second] == X && "Value not actually at index in map!");
     if (I->second == (ptrdiff_t)(V.size() - 1)) {
       do {
         V.pop_back();
       } while (!V.empty() && V.back() == T());
     } else {
       V[I->second] = T();
     }
     M.erase(I);
     return true;
   }

   /// Erase items from the set vector based on a predicate function.
   ///
   /// This is intended to be equivalent to the following code, if we could
   /// write it:
   ///
   /// \code
   ///   V.erase(remove_if(V, P), V.end());
   /// \endcode
   ///
   /// However, PriorityWorklist doesn't expose non-const iterators, making any
   /// algorithm like remove_if impossible to use.
   ///
   /// \returns true if any element is removed.
   template <typename UnaryPredicate>
   bool erase_if(UnaryPredicate P) {
     typename VectorT::iterator E =
         remove_if(V, TestAndEraseFromMap<UnaryPredicate>(P, M));
     if (E == V.end())
       return false;
     for (auto I = V.begin(); I != E; ++I)
       if (*I != T())
         M[*I] = I - V.begin();
     V.erase(E, V.end());
     return true;
   }

   /// Reverse the items in the PriorityWorklist.
   ///
   /// This does an in-place reversal. Other kinds of reverse aren't easy to
   /// support in the face of the worklist semantics.

   /// Completely clear the PriorityWorklist
   void clear() {
     M.clear();
     V.clear();
   }

 private:
   /// A wrapper predicate designed for use with std::remove_if.
   ///
   /// This predicate wraps a predicate suitable for use with std::remove_if to
   /// call M.erase(x) on each element which is slated for removal. This just
   /// allows the predicate to be move only which we can't do with lambdas
   /// today.
   template <typename UnaryPredicateT>
   class TestAndEraseFromMap {
     UnaryPredicateT P;
     MapT &M;

   public:
     TestAndEraseFromMap(UnaryPredicateT P, MapT &M)
         : P(std::move(P)), M(M) {}

     bool operator()(const T &Arg) {
       if (Arg == T())
         // Skip null values in the PriorityWorklist.
         return false;

       if (P(Arg)) {
         M.erase(Arg);
         return true;
       }
       return false;
     }
   };

   /// The map from value to index in the vector.
   MapT M;

   /// The vector of elements in insertion order.
   VectorT V;
 };

 /// A version of \c PriorityWorklist that selects small size optimized data
 /// structures for the vector and map.
 template <typename T, unsigned N>
 class SmallPriorityWorklist
     : public PriorityWorklist<T, SmallVector<T, N>,
                               SmallDenseMap<T, ptrdiff_t>> {
 public:
   SmallPriorityWorklist() = default;
 };

 } // end namespace llvm

 #endif // LLVM_ADT_PRIORITYWORKLIST_H
	//===- PriorityWorklist.h - Worklist with insertion priority ----- 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
	//
	//===----------------------------------------------------------------------===//
	///
	/// \file
	///
	/// This file provides a priority worklist. See the class comments for details.
	///
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ADT_PRIORITYWORKLIST_H
	#define LLVM_ADT_PRIORITYWORKLIST_H

	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/Support/Compiler.h"
	#include <algorithm>
	#include <cassert>
	#include <cstddef>
	#include <iterator>
	#include <type_traits>
	#include <vector>

	namespace llvm {

	/// A FILO worklist that prioritizes on re-insertion without duplication.
	///
	/// This is very similar to a \c SetVector with the primary difference that
	/// while re-insertion does not create a duplicate, it does adjust the
	/// visitation order to respect the last insertion point. This can be useful
	/// when the visit order needs to be prioritized based on insertion point
	/// without actually having duplicate visits.
	///
	/// Note that this doesn't prevent re-insertion of elements which have been
	/// visited -- if you need to break cycles, a set will still be necessary.
	///
	/// The type \c T must be default constructable to a null value that will be
	/// ignored. It is an error to insert such a value, and popping elements will
	/// never produce such a value. It is expected to be used with common nullable
	/// types like pointers or optionals.
	///
	/// Internally this uses a vector to store the worklist and a map to identify
	/// existing elements in the worklist. Both of these may be customized, but the
	/// map must support the basic DenseMap API for mapping from a T to an integer
	/// index into the vector.
	///
	/// A partial specialization is provided to automatically select a SmallVector
	/// and a SmallDenseMap if custom data structures are not provided.
	template <typename T, typename VectorT = std::vector<T>,
	typename MapT = DenseMap<T, ptrdiff_t>>
	class PriorityWorklist {
	public:
	using value_type = T;
	using key_type = T;
	using reference = T&;
	using const_reference = const T&;
	using size_type = typename MapT::size_type;

	/// Construct an empty PriorityWorklist
	PriorityWorklist() = default;

	/// Determine if the PriorityWorklist is empty or not.
	bool empty() const {
	return V.empty();
	}

	/// Returns the number of elements in the worklist.
	size_type size() const {
	return M.size();
	}

	/// Count the number of elements of a given key in the PriorityWorklist.
	/// \returns 0 if the element is not in the PriorityWorklist, 1 if it is.
	size_type count(const key_type &key) const {
	return M.count(key);
	}

	/// Return the last element of the PriorityWorklist.
	const T &back() const {
	assert(!empty() && "Cannot call back() on empty PriorityWorklist!");
	return V.back();
	}

	/// Insert a new element into the PriorityWorklist.
	/// \returns true if the element was inserted into the PriorityWorklist.
	bool insert(const T &X) {
	assert(X != T() && "Cannot insert a null (default constructed) value!");
	auto InsertResult = M.insert({X, V.size()});
	if (InsertResult.second) {
	// Fresh value, just append it to the vector.
	V.push_back(X);
	return true;
	}

	auto &Index = InsertResult.first->second;
	assert(V[Index] == X && "Value not actually at index in map!");
	if (Index != (ptrdiff_t)(V.size() - 1)) {
	// If the element isn't at the back, null it out and append a fresh one.
	V[Index] = T();
	Index = (ptrdiff_t)V.size();
	V.push_back(X);
	}
	return false;
	}

	/// Insert a sequence of new elements into the PriorityWorklist.
	template <typename SequenceT>
	std::enable_if_t<!std::is_convertible<SequenceT, T>::value>
	insert(SequenceT &&Input) {
	if (std::begin(Input) == std::end(Input))
	// Nothing to do for an empty input sequence.
	return;

	// First pull the input sequence into the vector as a bulk append
	// operation.
	ptrdiff_t StartIndex = V.size();
	V.insert(V.end(), std::begin(Input), std::end(Input));
	// Now walk backwards fixing up the index map and deleting any duplicates.
	for (ptrdiff_t i = V.size() - 1; i >= StartIndex; --i) {
	auto InsertResult = M.insert({V[i], i});
	if (InsertResult.second)
	continue;

	// If the existing index is before this insert's start, nuke that one and
	// move it up.
	ptrdiff_t &Index = InsertResult.first->second;
	if (Index < StartIndex) {
	V[Index] = T();
	Index = i;
	continue;
	}

	// Otherwise the existing one comes first so just clear out the value in
	// this slot.
	V[i] = T();
	}
	}

	/// Remove the last element of the PriorityWorklist.
	void pop_back() {
	assert(!empty() && "Cannot remove an element when empty!");
	assert(back() != T() && "Cannot have a null element at the back!");
	M.erase(back());
	do {
	V.pop_back();
	} while (!V.empty() && V.back() == T());
	}

	LLVM_NODISCARD T pop_back_val() {
	T Ret = back();
	pop_back();
	return Ret;
	}

	/// Erase an item from the worklist.
	///
	/// Note that this is constant time due to the nature of the worklist implementation.
	bool erase(const T& X) {
	auto I = M.find(X);
	if (I == M.end())
	return false;

	assert(V[I->second] == X && "Value not actually at index in map!");
	if (I->second == (ptrdiff_t)(V.size() - 1)) {
	do {
	V.pop_back();
	} while (!V.empty() && V.back() == T());
	} else {
	V[I->second] = T();
	}
	M.erase(I);
	return true;
	}

	/// Erase items from the set vector based on a predicate function.
	///
	/// This is intended to be equivalent to the following code, if we could
	/// write it:
	///
	/// \code
	/// V.erase(remove_if(V, P), V.end());
	/// \endcode
	///
	/// However, PriorityWorklist doesn't expose non-const iterators, making any
	/// algorithm like remove_if impossible to use.
	///
	/// \returns true if any element is removed.
	template <typename UnaryPredicate>
	bool erase_if(UnaryPredicate P) {
	typename VectorT::iterator E =
	remove_if(V, TestAndEraseFromMap<UnaryPredicate>(P, M));
	if (E == V.end())
	return false;
	for (auto I = V.begin(); I != E; ++I)
	if (*I != T())
	M[*I] = I - V.begin();
	V.erase(E, V.end());
	return true;
	}

	/// Reverse the items in the PriorityWorklist.
	///
	/// This does an in-place reversal. Other kinds of reverse aren't easy to
	/// support in the face of the worklist semantics.

	/// Completely clear the PriorityWorklist
	void clear() {
	M.clear();
	V.clear();
	}

	private:
	/// A wrapper predicate designed for use with std::remove_if.
	///
	/// This predicate wraps a predicate suitable for use with std::remove_if to
	/// call M.erase(x) on each element which is slated for removal. This just
	/// allows the predicate to be move only which we can't do with lambdas
	/// today.
	template <typename UnaryPredicateT>
	class TestAndEraseFromMap {
	UnaryPredicateT P;
	MapT &M;

	public:
	TestAndEraseFromMap(UnaryPredicateT P, MapT &M)
	: P(std::move(P)), M(M) {}

	bool operator()(const T &Arg) {
	if (Arg == T())
	// Skip null values in the PriorityWorklist.
	return false;

	if (P(Arg)) {
	M.erase(Arg);
	return true;
	}
	return false;
	}
	};

	/// The map from value to index in the vector.
	MapT M;

	/// The vector of elements in insertion order.
	VectorT V;
	};

	/// A version of \c PriorityWorklist that selects small size optimized data
	/// structures for the vector and map.
	template <typename T, unsigned N>
	class SmallPriorityWorklist
	: public PriorityWorklist<T, SmallVector<T, N>,
	SmallDenseMap<T, ptrdiff_t>> {
	public:
	SmallPriorityWorklist() = default;
	};

	} // end namespace llvm

	#endif // LLVM_ADT_PRIORITYWORKLIST_H