compiler/dex/post_opt_passes.h - platform/art - Git at Google

 /*
  * Copyright (C) 2014 The Android Open Source Project
  *
  * 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
  *
  *      http://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.
  */

 #ifndef ART_COMPILER_DEX_POST_OPT_PASSES_H_
 #define ART_COMPILER_DEX_POST_OPT_PASSES_H_

 #include "base/casts.h"
 #include "base/logging.h"
 #include "compiler_ir.h"
 #include "dex_flags.h"
 #include "mir_graph.h"
 #include "pass_me.h"

 namespace art {

 /**
  * @class PassMEMirSsaRep
  * @brief Convenience class for passes that check MIRGraph::MirSsaRepUpToDate().
  */
 class PassMEMirSsaRep : public PassME {
  public:
   PassMEMirSsaRep(const char* name, DataFlowAnalysisMode type = kAllNodes)
       : PassME(name, type) {
   }

   bool Gate(const PassDataHolder* data) const OVERRIDE {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<const PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     return !c_unit->mir_graph->MirSsaRepUpToDate();
   }
 };

 /**
  * @class InitializeSSATransformation
  * @brief There is some data that needs to be initialized before performing
  * the post optimization passes.
  */
 class InitializeSSATransformation : public PassMEMirSsaRep {
  public:
   InitializeSSATransformation() : PassMEMirSsaRep("InitializeSSATransformation", kNoNodes) {
   }

   void Start(PassDataHolder* data) const {
     // New blocks may have been inserted so the first thing we do is ensure that
     // the c_unit's number of blocks matches the actual count of basic blocks.
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     c_unit->mir_graph->SSATransformationStart();
     c_unit->mir_graph->CompilerInitializeSSAConversion();
   }
 };

 /**
  * @class ClearPhiInformation
  * @brief Clear the PHI nodes from the CFG.
  */
 class ClearPhiInstructions : public PassMEMirSsaRep {
  public:
   ClearPhiInstructions() : PassMEMirSsaRep("ClearPhiInstructions") {
   }

   bool Worker(PassDataHolder* data) const;
 };

 /**
  * @class CalculatePredecessors
  * @brief Calculate the predecessor BitVector of each Basicblock.
  */
 class CalculatePredecessors : public PassME {
  public:
   CalculatePredecessors() : PassME("CalculatePredecessors", kNoNodes) {
   }

   void Start(PassDataHolder* data) const;
 };

 /**
  * @class DFSOrders
  * @brief Compute the DFS order of the MIR graph
  */
 class DFSOrders : public PassME {
  public:
   DFSOrders() : PassME("DFSOrders", kNoNodes) {
   }

   bool Gate(const PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<const PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     return !c_unit->mir_graph->DfsOrdersUpToDate();
   }

   void Start(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     c_unit->mir_graph.get()->ComputeDFSOrders();
   }
 };

 /**
  * @class BuildDomination
  * @brief Build the domination information of the MIR Graph
  */
 class BuildDomination : public PassME {
  public:
   BuildDomination() : PassME("BuildDomination", kNoNodes) {
   }

   bool Gate(const PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<const PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     return !c_unit->mir_graph->DominationUpToDate();
   }

   void Start(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     c_unit->mir_graph->ComputeDominators();
   }

   void End(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     // Verify the dataflow information after the pass.
     if (c_unit->enable_debug & (1 << kDebugVerifyDataflow)) {
       c_unit->mir_graph->VerifyDataflow();
     }
   }
 };

 /**
  * @class TopologicalSortOrders
  * @brief Compute the topological sort order of the MIR graph
  */
 class TopologicalSortOrders : public PassME {
  public:
   TopologicalSortOrders() : PassME("TopologicalSortOrders", kNoNodes) {
   }

   bool Gate(const PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<const PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     return !c_unit->mir_graph->TopologicalOrderUpToDate();
   }

   void Start(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     c_unit->mir_graph.get()->ComputeTopologicalSortOrder();
   }
 };

 /**
  * @class DefBlockMatrix
  * @brief Calculate the matrix of definition per basic block
  */
 class DefBlockMatrix : public PassMEMirSsaRep {
  public:
   DefBlockMatrix() : PassMEMirSsaRep("DefBlockMatrix", kNoNodes) {
   }

   void Start(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     c_unit->mir_graph.get()->ComputeDefBlockMatrix();
   }
 };

 /**
  * @class FindPhiNodeBlocksPass
  * @brief Pass to find out where we need to insert the phi nodes for the SSA conversion.
  */
 class FindPhiNodeBlocksPass : public PassMEMirSsaRep {
  public:
   FindPhiNodeBlocksPass() : PassMEMirSsaRep("FindPhiNodeBlocks", kNoNodes) {
   }

   void Start(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     c_unit->mir_graph.get()->FindPhiNodeBlocks();
   }
 };

 /**
  * @class SSAConversion
  * @brief Pass for SSA conversion of MIRs
  */
 class SSAConversion : public PassMEMirSsaRep {
  public:
   SSAConversion() : PassMEMirSsaRep("SSAConversion", kNoNodes) {
   }

   void Start(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     MIRGraph *mir_graph = c_unit->mir_graph.get();
     mir_graph->ClearAllVisitedFlags();
     mir_graph->DoDFSPreOrderSSARename(mir_graph->GetEntryBlock());
   }
 };

 /**
  * @class PhiNodeOperands
  * @brief Pass to insert the Phi node operands to basic blocks
  */
 class PhiNodeOperands : public PassMEMirSsaRep {
  public:
   PhiNodeOperands() : PassMEMirSsaRep("PhiNodeOperands", kPreOrderDFSTraversal) {
   }

   bool Worker(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     BasicBlock* bb = down_cast<PassMEDataHolder*>(data)->bb;
     DCHECK(bb != nullptr);
     c_unit->mir_graph->InsertPhiNodeOperands(bb);
     // No need of repeating, so just return false.
     return false;
   }
 };

 /**
  * @class InitRegLocations
  * @brief Initialize Register Locations.
  */
 class PerformInitRegLocations : public PassMEMirSsaRep {
  public:
   PerformInitRegLocations() : PassMEMirSsaRep("PerformInitRegLocation", kNoNodes) {
   }

   void Start(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     c_unit->mir_graph->InitRegLocations();
   }
 };

 /**
  * @class TypeInference
  * @brief Type inference pass.
  */
 class TypeInference : public PassMEMirSsaRep {
  public:
   TypeInference() : PassMEMirSsaRep("TypeInference", kRepeatingPreOrderDFSTraversal) {
   }

   bool Worker(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     PassMEDataHolder* pass_me_data_holder = down_cast<PassMEDataHolder*>(data);
     CompilationUnit* c_unit = pass_me_data_holder->c_unit;
     DCHECK(c_unit != nullptr);
     BasicBlock* bb = pass_me_data_holder->bb;
     DCHECK(bb != nullptr);
     return c_unit->mir_graph->InferTypes(bb);
   }
 };

 /**
  * @class FinishSSATransformation
  * @brief There is some data that needs to be freed after performing the post optimization passes.
  */
 class FinishSSATransformation : public PassMEMirSsaRep {
  public:
   FinishSSATransformation() : PassMEMirSsaRep("FinishSSATransformation", kNoNodes) {
   }

   void End(PassDataHolder* data) const {
     DCHECK(data != nullptr);
     CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
     DCHECK(c_unit != nullptr);
     c_unit->mir_graph.get()->SSATransformationEnd();
   }
 };

 }  // namespace art

 #endif  // ART_COMPILER_DEX_POST_OPT_PASSES_H_
	/*
	* Copyright (C) 2014 The Android Open Source Project
	*
	* 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
	*
	* http://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.
	*/

	#ifndef ART_COMPILER_DEX_POST_OPT_PASSES_H_
	#define ART_COMPILER_DEX_POST_OPT_PASSES_H_

	#include "base/casts.h"
	#include "base/logging.h"
	#include "compiler_ir.h"
	#include "dex_flags.h"
	#include "mir_graph.h"
	#include "pass_me.h"

	namespace art {

	/**
	* @class PassMEMirSsaRep
	* @brief Convenience class for passes that check MIRGraph::MirSsaRepUpToDate().
	*/
	class PassMEMirSsaRep : public PassME {
	public:
	PassMEMirSsaRep(const char* name, DataFlowAnalysisMode type = kAllNodes)
	: PassME(name, type) {
	}

	bool Gate(const PassDataHolder* data) const OVERRIDE {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<const PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	return !c_unit->mir_graph->MirSsaRepUpToDate();
	}
	};

	/**
	* @class InitializeSSATransformation
	* @brief There is some data that needs to be initialized before performing
	* the post optimization passes.
	*/
	class InitializeSSATransformation : public PassMEMirSsaRep {
	public:
	InitializeSSATransformation() : PassMEMirSsaRep("InitializeSSATransformation", kNoNodes) {
	}

	void Start(PassDataHolder* data) const {
	// New blocks may have been inserted so the first thing we do is ensure that
	// the c_unit's number of blocks matches the actual count of basic blocks.
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	c_unit->mir_graph->SSATransformationStart();
	c_unit->mir_graph->CompilerInitializeSSAConversion();
	}
	};

	/**
	* @class ClearPhiInformation
	* @brief Clear the PHI nodes from the CFG.
	*/
	class ClearPhiInstructions : public PassMEMirSsaRep {
	public:
	ClearPhiInstructions() : PassMEMirSsaRep("ClearPhiInstructions") {
	}

	bool Worker(PassDataHolder* data) const;
	};

	/**
	* @class CalculatePredecessors
	* @brief Calculate the predecessor BitVector of each Basicblock.
	*/
	class CalculatePredecessors : public PassME {
	public:
	CalculatePredecessors() : PassME("CalculatePredecessors", kNoNodes) {
	}

	void Start(PassDataHolder* data) const;
	};

	/**
	* @class DFSOrders
	* @brief Compute the DFS order of the MIR graph
	*/
	class DFSOrders : public PassME {
	public:
	DFSOrders() : PassME("DFSOrders", kNoNodes) {
	}

	bool Gate(const PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<const PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	return !c_unit->mir_graph->DfsOrdersUpToDate();
	}

	void Start(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	c_unit->mir_graph.get()->ComputeDFSOrders();
	}
	};

	/**
	* @class BuildDomination
	* @brief Build the domination information of the MIR Graph
	*/
	class BuildDomination : public PassME {
	public:
	BuildDomination() : PassME("BuildDomination", kNoNodes) {
	}

	bool Gate(const PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<const PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	return !c_unit->mir_graph->DominationUpToDate();
	}

	void Start(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	c_unit->mir_graph->ComputeDominators();
	}

	void End(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	// Verify the dataflow information after the pass.
	if (c_unit->enable_debug & (1 << kDebugVerifyDataflow)) {
	c_unit->mir_graph->VerifyDataflow();
	}
	}
	};

	/**
	* @class TopologicalSortOrders
	* @brief Compute the topological sort order of the MIR graph
	*/
	class TopologicalSortOrders : public PassME {
	public:
	TopologicalSortOrders() : PassME("TopologicalSortOrders", kNoNodes) {
	}

	bool Gate(const PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<const PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	return !c_unit->mir_graph->TopologicalOrderUpToDate();
	}

	void Start(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	c_unit->mir_graph.get()->ComputeTopologicalSortOrder();
	}
	};

	/**
	* @class DefBlockMatrix
	* @brief Calculate the matrix of definition per basic block
	*/
	class DefBlockMatrix : public PassMEMirSsaRep {
	public:
	DefBlockMatrix() : PassMEMirSsaRep("DefBlockMatrix", kNoNodes) {
	}

	void Start(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	c_unit->mir_graph.get()->ComputeDefBlockMatrix();
	}
	};

	/**
	* @class FindPhiNodeBlocksPass
	* @brief Pass to find out where we need to insert the phi nodes for the SSA conversion.
	*/
	class FindPhiNodeBlocksPass : public PassMEMirSsaRep {
	public:
	FindPhiNodeBlocksPass() : PassMEMirSsaRep("FindPhiNodeBlocks", kNoNodes) {
	}

	void Start(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	c_unit->mir_graph.get()->FindPhiNodeBlocks();
	}
	};

	/**
	* @class SSAConversion
	* @brief Pass for SSA conversion of MIRs
	*/
	class SSAConversion : public PassMEMirSsaRep {
	public:
	SSAConversion() : PassMEMirSsaRep("SSAConversion", kNoNodes) {
	}

	void Start(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	MIRGraph *mir_graph = c_unit->mir_graph.get();
	mir_graph->ClearAllVisitedFlags();
	mir_graph->DoDFSPreOrderSSARename(mir_graph->GetEntryBlock());
	}
	};

	/**
	* @class PhiNodeOperands
	* @brief Pass to insert the Phi node operands to basic blocks
	*/
	class PhiNodeOperands : public PassMEMirSsaRep {
	public:
	PhiNodeOperands() : PassMEMirSsaRep("PhiNodeOperands", kPreOrderDFSTraversal) {
	}

	bool Worker(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	BasicBlock* bb = down_cast<PassMEDataHolder*>(data)->bb;
	DCHECK(bb != nullptr);
	c_unit->mir_graph->InsertPhiNodeOperands(bb);
	// No need of repeating, so just return false.
	return false;
	}
	};

	/**
	* @class InitRegLocations
	* @brief Initialize Register Locations.
	*/
	class PerformInitRegLocations : public PassMEMirSsaRep {
	public:
	PerformInitRegLocations() : PassMEMirSsaRep("PerformInitRegLocation", kNoNodes) {
	}

	void Start(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	c_unit->mir_graph->InitRegLocations();
	}
	};

	/**
	* @class TypeInference
	* @brief Type inference pass.
	*/
	class TypeInference : public PassMEMirSsaRep {
	public:
	TypeInference() : PassMEMirSsaRep("TypeInference", kRepeatingPreOrderDFSTraversal) {
	}

	bool Worker(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	PassMEDataHolder* pass_me_data_holder = down_cast<PassMEDataHolder*>(data);
	CompilationUnit* c_unit = pass_me_data_holder->c_unit;
	DCHECK(c_unit != nullptr);
	BasicBlock* bb = pass_me_data_holder->bb;
	DCHECK(bb != nullptr);
	return c_unit->mir_graph->InferTypes(bb);
	}
	};

	/**
	* @class FinishSSATransformation
	* @brief There is some data that needs to be freed after performing the post optimization passes.
	*/
	class FinishSSATransformation : public PassMEMirSsaRep {
	public:
	FinishSSATransformation() : PassMEMirSsaRep("FinishSSATransformation", kNoNodes) {
	}

	void End(PassDataHolder* data) const {
	DCHECK(data != nullptr);
	CompilationUnit* c_unit = down_cast<PassMEDataHolder*>(data)->c_unit;
	DCHECK(c_unit != nullptr);
	c_unit->mir_graph.get()->SSATransformationEnd();
	}
	};

	} // namespace art

	#endif // ART_COMPILER_DEX_POST_OPT_PASSES_H_