clang-r437112b/include/llvm/Analysis/InlineOrder.h - platform/prebuilts/clang/host/darwin-x86 - Git at Google

 //===- InlineOrder.h - Inlining order abstraction -*- 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_ANALYSIS_INLINEORDER_H
 #define LLVM_ANALYSIS_INLINEORDER_H

 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/IR/Function.h"
 #include "llvm/IR/Instruction.h"
 #include "llvm/IR/Instructions.h"
 #include <algorithm>
 #include <utility>

 namespace llvm {
 class CallBase;
 class Function;
 class Module;

 template <typename T> class InlineOrder {
 public:
   using reference = T &;
   using const_reference = const T &;

   virtual ~InlineOrder() {}

   virtual size_t size() = 0;

   virtual void push(const T &Elt) = 0;

   virtual T pop() = 0;

   virtual const_reference front() = 0;

   virtual void erase_if(function_ref<bool(T)> Pred) = 0;

   bool empty() { return !size(); }
 };

 template <typename T, typename Container = SmallVector<T, 16>>
 class DefaultInlineOrder : public InlineOrder<T> {
   using reference = T &;
   using const_reference = const T &;

 public:
   size_t size() override { return Calls.size() - FirstIndex; }

   void push(const T &Elt) override { Calls.push_back(Elt); }

   T pop() override {
     assert(size() > 0);
     return Calls[FirstIndex++];
   }

   const_reference front() override {
     assert(size() > 0);
     return Calls[FirstIndex];
   }

   void erase_if(function_ref<bool(T)> Pred) override {
     Calls.erase(std::remove_if(Calls.begin() + FirstIndex, Calls.end(), Pred),
                 Calls.end());
   }

 private:
   Container Calls;
   size_t FirstIndex = 0;
 };

 class InlineSizePriority {
 public:
   InlineSizePriority(int Size) : Size(Size) {}

   static bool isMoreDesirable(const InlineSizePriority &S1,
                               const InlineSizePriority &S2) {
     return S1.Size < S2.Size;
   }

   static InlineSizePriority evaluate(CallBase *CB) {
     Function *Callee = CB->getCalledFunction();
     return InlineSizePriority(Callee->getInstructionCount());
   }

   int Size;
 };

 template <typename PriorityT>
 class PriorityInlineOrder : public InlineOrder<std::pair<CallBase *, int>> {
   using T = std::pair<CallBase *, int>;
   using HeapT = std::pair<CallBase *, PriorityT>;
   using reference = T &;
   using const_reference = const T &;

   static bool cmp(const HeapT &P1, const HeapT &P2) {
     return PriorityT::isMoreDesirable(P2.second, P1.second);
   }

   // A call site could become less desirable for inlining because of the size
   // growth from prior inlining into the callee. This method is used to lazily
   // update the desirability of a call site if it's decreasing. It is only
   // called on pop() or front(), not every time the desirability changes. When
   // the desirability of the front call site decreases, an updated one would be
   // pushed right back into the heap. For simplicity, those cases where
   // the desirability of a call site increases are ignored here.
   void adjust() {
     bool Changed = false;
     do {
       CallBase *CB = Heap.front().first;
       const PriorityT PreviousGoodness = Heap.front().second;
       const PriorityT CurrentGoodness = PriorityT::evaluate(CB);
       Changed = PriorityT::isMoreDesirable(PreviousGoodness, CurrentGoodness);
       if (Changed) {
         std::pop_heap(Heap.begin(), Heap.end(), cmp);
         Heap.pop_back();
         Heap.push_back({CB, CurrentGoodness});
         std::push_heap(Heap.begin(), Heap.end(), cmp);
       }
     } while (Changed);
   }

 public:
   size_t size() override { return Heap.size(); }

   void push(const T &Elt) override {
     CallBase *CB = Elt.first;
     const int InlineHistoryID = Elt.second;
     const PriorityT Goodness = PriorityT::evaluate(CB);

     Heap.push_back({CB, Goodness});
     std::push_heap(Heap.begin(), Heap.end(), cmp);
     InlineHistoryMap[CB] = InlineHistoryID;
   }

   T pop() override {
     assert(size() > 0);
     adjust();

     CallBase *CB = Heap.front().first;
     T Result = std::make_pair(CB, InlineHistoryMap[CB]);
     InlineHistoryMap.erase(CB);
     std::pop_heap(Heap.begin(), Heap.end(), cmp);
     Heap.pop_back();
     return Result;
   }

   const_reference front() override {
     assert(size() > 0);
     adjust();

     CallBase *CB = Heap.front().first;
     return *InlineHistoryMap.find(CB);
   }

   void erase_if(function_ref<bool(T)> Pred) override {
     auto PredWrapper = [=](HeapT P) -> bool {
       return Pred(std::make_pair(P.first, 0));
     };
     Heap.erase(std::remove_if(Heap.begin(), Heap.end(), PredWrapper),
                Heap.end());
     std::make_heap(Heap.begin(), Heap.end(), cmp);
   }

 private:
   SmallVector<HeapT, 16> Heap;
   DenseMap<CallBase *, int> InlineHistoryMap;
 };
 } // namespace llvm
 #endif // LLVM_ANALYSIS_INLINEORDER_H
	//===- InlineOrder.h - Inlining order abstraction -- 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_ANALYSIS_INLINEORDER_H
	#define LLVM_ANALYSIS_INLINEORDER_H

	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/IR/Function.h"
	#include "llvm/IR/Instruction.h"
	#include "llvm/IR/Instructions.h"
	#include <algorithm>
	#include <utility>

	namespace llvm {
	class CallBase;
	class Function;
	class Module;

	template <typename T> class InlineOrder {
	public:
	using reference = T &;
	using const_reference = const T &;

	virtual ~InlineOrder() {}

	virtual size_t size() = 0;

	virtual void push(const T &Elt) = 0;

	virtual T pop() = 0;

	virtual const_reference front() = 0;

	virtual void erase_if(function_ref<bool(T)> Pred) = 0;

	bool empty() { return !size(); }
	};

	template <typename T, typename Container = SmallVector<T, 16>>
	class DefaultInlineOrder : public InlineOrder<T> {
	using reference = T &;
	using const_reference = const T &;

	public:
	size_t size() override { return Calls.size() - FirstIndex; }

	void push(const T &Elt) override { Calls.push_back(Elt); }

	T pop() override {
	assert(size() > 0);
	return Calls[FirstIndex++];
	}

	const_reference front() override {
	assert(size() > 0);
	return Calls[FirstIndex];
	}

	void erase_if(function_ref<bool(T)> Pred) override {
	Calls.erase(std::remove_if(Calls.begin() + FirstIndex, Calls.end(), Pred),
	Calls.end());
	}

	private:
	Container Calls;
	size_t FirstIndex = 0;
	};

	class InlineSizePriority {
	public:
	InlineSizePriority(int Size) : Size(Size) {}

	static bool isMoreDesirable(const InlineSizePriority &S1,
	const InlineSizePriority &S2) {
	return S1.Size < S2.Size;
	}

	static InlineSizePriority evaluate(CallBase *CB) {
	Function *Callee = CB->getCalledFunction();
	return InlineSizePriority(Callee->getInstructionCount());
	}

	int Size;
	};

	template <typename PriorityT>
	class PriorityInlineOrder : public InlineOrder<std::pair<CallBase *, int>> {
	using T = std::pair<CallBase *, int>;
	using HeapT = std::pair<CallBase *, PriorityT>;
	using reference = T &;
	using const_reference = const T &;

	static bool cmp(const HeapT &P1, const HeapT &P2) {
	return PriorityT::isMoreDesirable(P2.second, P1.second);
	}

	// A call site could become less desirable for inlining because of the size
	// growth from prior inlining into the callee. This method is used to lazily
	// update the desirability of a call site if it's decreasing. It is only
	// called on pop() or front(), not every time the desirability changes. When
	// the desirability of the front call site decreases, an updated one would be
	// pushed right back into the heap. For simplicity, those cases where
	// the desirability of a call site increases are ignored here.
	void adjust() {
	bool Changed = false;
	do {
	CallBase *CB = Heap.front().first;
	const PriorityT PreviousGoodness = Heap.front().second;
	const PriorityT CurrentGoodness = PriorityT::evaluate(CB);
	Changed = PriorityT::isMoreDesirable(PreviousGoodness, CurrentGoodness);
	if (Changed) {
	std::pop_heap(Heap.begin(), Heap.end(), cmp);
	Heap.pop_back();
	Heap.push_back({CB, CurrentGoodness});
	std::push_heap(Heap.begin(), Heap.end(), cmp);
	}
	} while (Changed);
	}

	public:
	size_t size() override { return Heap.size(); }

	void push(const T &Elt) override {
	CallBase *CB = Elt.first;
	const int InlineHistoryID = Elt.second;
	const PriorityT Goodness = PriorityT::evaluate(CB);

	Heap.push_back({CB, Goodness});
	std::push_heap(Heap.begin(), Heap.end(), cmp);
	InlineHistoryMap[CB] = InlineHistoryID;
	}

	T pop() override {
	assert(size() > 0);
	adjust();

	CallBase *CB = Heap.front().first;
	T Result = std::make_pair(CB, InlineHistoryMap[CB]);
	InlineHistoryMap.erase(CB);
	std::pop_heap(Heap.begin(), Heap.end(), cmp);
	Heap.pop_back();
	return Result;
	}

	const_reference front() override {
	assert(size() > 0);
	adjust();

	CallBase *CB = Heap.front().first;
	return *InlineHistoryMap.find(CB);
	}

	void erase_if(function_ref<bool(T)> Pred) override {
	auto PredWrapper = [=](HeapT P) -> bool {
	return Pred(std::make_pair(P.first, 0));
	};
	Heap.erase(std::remove_if(Heap.begin(), Heap.end(), PredWrapper),
	Heap.end());
	std::make_heap(Heap.begin(), Heap.end(), cmp);
	}

	private:
	SmallVector<HeapT, 16> Heap;
	DenseMap<CallBase *, int> InlineHistoryMap;
	};
	} // namespace llvm
	#endif // LLVM_ANALYSIS_INLINEORDER_H