compiler/optimizing/register_allocator_linear_scan.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_OPTIMIZING_REGISTER_ALLOCATOR_LINEAR_SCAN_H_
 #define ART_COMPILER_OPTIMIZING_REGISTER_ALLOCATOR_LINEAR_SCAN_H_

 #include "arch/instruction_set.h"
 #include "base/scoped_arena_containers.h"
 #include "base/macros.h"
 #include "register_allocator.h"

 namespace art {

 class CodeGenerator;
 class HBasicBlock;
 class HGraph;
 class HInstruction;
 class HParallelMove;
 class HPhi;
 class LiveInterval;
 class Location;
 class SsaLivenessAnalysis;

 /**
  * An implementation of a linear scan register allocator on an `HGraph` with SSA form.
  */
 class RegisterAllocatorLinearScan : public RegisterAllocator {
  public:
   RegisterAllocatorLinearScan(ScopedArenaAllocator* allocator,
                               CodeGenerator* codegen,
                               const SsaLivenessAnalysis& analysis);
   ~RegisterAllocatorLinearScan() override;

   void AllocateRegisters() override;

   bool Validate(bool log_fatal_on_failure) override {
     processing_core_registers_ = true;
     if (!ValidateInternal(log_fatal_on_failure)) {
       return false;
     }
     processing_core_registers_ = false;
     return ValidateInternal(log_fatal_on_failure);
   }

   size_t GetNumberOfSpillSlots() const {
     return int_spill_slots_.size()
         + long_spill_slots_.size()
         + float_spill_slots_.size()
         + double_spill_slots_.size()
         + catch_phi_spill_slots_;
   }

  private:
   // Main methods of the allocator.
   void LinearScan();
   bool TryAllocateFreeReg(LiveInterval* interval);
   bool AllocateBlockedReg(LiveInterval* interval);

   // Add `interval` in the given sorted list.
   static void AddSorted(ScopedArenaVector<LiveInterval*>* array, LiveInterval* interval);

   // Returns whether `reg` is blocked by the code generator.
   bool IsBlocked(int reg) const;

   // Update the interval for the register in `location` to cover [start, end).
   void BlockRegister(Location location, size_t start, size_t end);
   void BlockRegisters(size_t start, size_t end, bool caller_save_only = false);

   // Allocate a spill slot for the given interval. Should be called in linear
   // order of interval starting positions.
   void AllocateSpillSlotFor(LiveInterval* interval);

   // Allocate a spill slot for the given catch phi. Will allocate the same slot
   // for phis which share the same vreg. Must be called in reverse linear order
   // of lifetime positions and ascending vreg numbers for correctness.
   void AllocateSpillSlotForCatchPhi(HPhi* phi);

   // Helper methods.
   void AllocateRegistersInternal();
   void ProcessInstruction(HInstruction* instruction);
   bool ValidateInternal(bool log_fatal_on_failure) const;
   void DumpInterval(std::ostream& stream, LiveInterval* interval) const;
   void DumpAllIntervals(std::ostream& stream) const;
   int FindAvailableRegisterPair(size_t* next_use, size_t starting_at) const;
   int FindAvailableRegister(size_t* next_use, LiveInterval* current) const;
   bool IsCallerSaveRegister(int reg) const;

   // Try splitting an active non-pair or unaligned pair interval at the given `position`.
   // Returns whether it was successful at finding such an interval.
   bool TrySplitNonPairOrUnalignedPairIntervalAt(size_t position,
                                                 size_t first_register_use,
                                                 size_t* next_use);

   // List of intervals for core registers that must be processed, ordered by start
   // position. Last entry is the interval that has the lowest start position.
   // This list is initially populated before doing the linear scan.
   ScopedArenaVector<LiveInterval*> unhandled_core_intervals_;

   // List of intervals for floating-point registers. Same comments as above.
   ScopedArenaVector<LiveInterval*> unhandled_fp_intervals_;

   // Currently processed list of unhandled intervals. Either `unhandled_core_intervals_`
   // or `unhandled_fp_intervals_`.
   ScopedArenaVector<LiveInterval*>* unhandled_;

   // List of intervals that have been processed.
   ScopedArenaVector<LiveInterval*> handled_;

   // List of intervals that are currently active when processing a new live interval.
   // That is, they have a live range that spans the start of the new interval.
   ScopedArenaVector<LiveInterval*> active_;

   // List of intervals that are currently inactive when processing a new live interval.
   // That is, they have a lifetime hole that spans the start of the new interval.
   ScopedArenaVector<LiveInterval*> inactive_;

   // Fixed intervals for physical registers. Such intervals cover the positions
   // where an instruction requires a specific register.
   ScopedArenaVector<LiveInterval*> physical_core_register_intervals_;
   ScopedArenaVector<LiveInterval*> physical_fp_register_intervals_;

   // Intervals for temporaries. Such intervals cover the positions
   // where an instruction requires a temporary.
   ScopedArenaVector<LiveInterval*> temp_intervals_;

   // The spill slots allocated for live intervals. We ensure spill slots
   // are typed to avoid (1) doing moves and swaps between two different kinds
   // of registers, and (2) swapping between a single stack slot and a double
   // stack slot. This simplifies the parallel move resolver.
   ScopedArenaVector<size_t> int_spill_slots_;
   ScopedArenaVector<size_t> long_spill_slots_;
   ScopedArenaVector<size_t> float_spill_slots_;
   ScopedArenaVector<size_t> double_spill_slots_;

   // Spill slots allocated to catch phis. This category is special-cased because
   // (1) slots are allocated prior to linear scan and in reverse linear order,
   // (2) equivalent phis need to share slots despite having different types.
   size_t catch_phi_spill_slots_;

   // Instructions that need a safepoint.
   ScopedArenaVector<HInstruction*> safepoints_;

   // True if processing core registers. False if processing floating
   // point registers.
   bool processing_core_registers_;

   // Number of registers for the current register kind (core or floating point).
   size_t number_of_registers_;

   // Temporary array, allocated ahead of time for simplicity.
   size_t* registers_array_;

   // Blocked registers, as decided by the code generator.
   bool* const blocked_core_registers_;
   bool* const blocked_fp_registers_;

   // Slots reserved for out arguments.
   size_t reserved_out_slots_;

   ART_FRIEND_TEST(RegisterAllocatorTest, FreeUntil);
   ART_FRIEND_TEST(RegisterAllocatorTest, SpillInactive);

   DISALLOW_COPY_AND_ASSIGN(RegisterAllocatorLinearScan);
 };

 }  // namespace art

 #endif  // ART_COMPILER_OPTIMIZING_REGISTER_ALLOCATOR_LINEAR_SCAN_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_OPTIMIZING_REGISTER_ALLOCATOR_LINEAR_SCAN_H_
	#define ART_COMPILER_OPTIMIZING_REGISTER_ALLOCATOR_LINEAR_SCAN_H_

	#include "arch/instruction_set.h"
	#include "base/scoped_arena_containers.h"
	#include "base/macros.h"
	#include "register_allocator.h"

	namespace art {

	class CodeGenerator;
	class HBasicBlock;
	class HGraph;
	class HInstruction;
	class HParallelMove;
	class HPhi;
	class LiveInterval;
	class Location;
	class SsaLivenessAnalysis;

	/**
	* An implementation of a linear scan register allocator on an `HGraph` with SSA form.
	*/
	class RegisterAllocatorLinearScan : public RegisterAllocator {
	public:
	RegisterAllocatorLinearScan(ScopedArenaAllocator* allocator,
	CodeGenerator* codegen,
	const SsaLivenessAnalysis& analysis);
	~RegisterAllocatorLinearScan() override;

	void AllocateRegisters() override;

	bool Validate(bool log_fatal_on_failure) override {
	processing_core_registers_ = true;
	if (!ValidateInternal(log_fatal_on_failure)) {
	return false;
	}
	processing_core_registers_ = false;
	return ValidateInternal(log_fatal_on_failure);
	}

	size_t GetNumberOfSpillSlots() const {
	return int_spill_slots_.size()
	+ long_spill_slots_.size()
	+ float_spill_slots_.size()
	+ double_spill_slots_.size()
	+ catch_phi_spill_slots_;
	}

	private:
	// Main methods of the allocator.
	void LinearScan();
	bool TryAllocateFreeReg(LiveInterval* interval);
	bool AllocateBlockedReg(LiveInterval* interval);

	// Add `interval` in the given sorted list.
	static void AddSorted(ScopedArenaVector<LiveInterval> array, LiveInterval* interval);

	// Returns whether `reg` is blocked by the code generator.
	bool IsBlocked(int reg) const;

	// Update the interval for the register in `location` to cover [start, end).
	void BlockRegister(Location location, size_t start, size_t end);
	void BlockRegisters(size_t start, size_t end, bool caller_save_only = false);

	// Allocate a spill slot for the given interval. Should be called in linear
	// order of interval starting positions.
	void AllocateSpillSlotFor(LiveInterval* interval);

	// Allocate a spill slot for the given catch phi. Will allocate the same slot
	// for phis which share the same vreg. Must be called in reverse linear order
	// of lifetime positions and ascending vreg numbers for correctness.
	void AllocateSpillSlotForCatchPhi(HPhi* phi);

	// Helper methods.
	void AllocateRegistersInternal();
	void ProcessInstruction(HInstruction* instruction);
	bool ValidateInternal(bool log_fatal_on_failure) const;
	void DumpInterval(std::ostream& stream, LiveInterval* interval) const;
	void DumpAllIntervals(std::ostream& stream) const;
	int FindAvailableRegisterPair(size_t* next_use, size_t starting_at) const;
	int FindAvailableRegister(size_t* next_use, LiveInterval* current) const;
	bool IsCallerSaveRegister(int reg) const;

	// Try splitting an active non-pair or unaligned pair interval at the given `position`.
	// Returns whether it was successful at finding such an interval.
	bool TrySplitNonPairOrUnalignedPairIntervalAt(size_t position,
	size_t first_register_use,
	size_t* next_use);

	// List of intervals for core registers that must be processed, ordered by start
	// position. Last entry is the interval that has the lowest start position.
	// This list is initially populated before doing the linear scan.
	ScopedArenaVector<LiveInterval*> unhandled_core_intervals_;

	// List of intervals for floating-point registers. Same comments as above.
	ScopedArenaVector<LiveInterval*> unhandled_fp_intervals_;

	// Currently processed list of unhandled intervals. Either `unhandled_core_intervals_`
	// or `unhandled_fp_intervals_`.
	ScopedArenaVector<LiveInterval> unhandled_;

	// List of intervals that have been processed.
	ScopedArenaVector<LiveInterval*> handled_;

	// List of intervals that are currently active when processing a new live interval.
	// That is, they have a live range that spans the start of the new interval.
	ScopedArenaVector<LiveInterval*> active_;

	// List of intervals that are currently inactive when processing a new live interval.
	// That is, they have a lifetime hole that spans the start of the new interval.
	ScopedArenaVector<LiveInterval*> inactive_;

	// Fixed intervals for physical registers. Such intervals cover the positions
	// where an instruction requires a specific register.
	ScopedArenaVector<LiveInterval*> physical_core_register_intervals_;
	ScopedArenaVector<LiveInterval*> physical_fp_register_intervals_;

	// Intervals for temporaries. Such intervals cover the positions
	// where an instruction requires a temporary.
	ScopedArenaVector<LiveInterval*> temp_intervals_;

	// The spill slots allocated for live intervals. We ensure spill slots
	// are typed to avoid (1) doing moves and swaps between two different kinds
	// of registers, and (2) swapping between a single stack slot and a double
	// stack slot. This simplifies the parallel move resolver.
	ScopedArenaVector<size_t> int_spill_slots_;
	ScopedArenaVector<size_t> long_spill_slots_;
	ScopedArenaVector<size_t> float_spill_slots_;
	ScopedArenaVector<size_t> double_spill_slots_;

	// Spill slots allocated to catch phis. This category is special-cased because
	// (1) slots are allocated prior to linear scan and in reverse linear order,
	// (2) equivalent phis need to share slots despite having different types.
	size_t catch_phi_spill_slots_;

	// Instructions that need a safepoint.
	ScopedArenaVector<HInstruction*> safepoints_;

	// True if processing core registers. False if processing floating
	// point registers.
	bool processing_core_registers_;

	// Number of registers for the current register kind (core or floating point).
	size_t number_of_registers_;

	// Temporary array, allocated ahead of time for simplicity.
	size_t* registers_array_;

	// Blocked registers, as decided by the code generator.
	bool* const blocked_core_registers_;
	bool* const blocked_fp_registers_;

	// Slots reserved for out arguments.
	size_t reserved_out_slots_;

	ART_FRIEND_TEST(RegisterAllocatorTest, FreeUntil);
	ART_FRIEND_TEST(RegisterAllocatorTest, SpillInactive);

	DISALLOW_COPY_AND_ASSIGN(RegisterAllocatorLinearScan);
	};

	} // namespace art

	#endif // ART_COMPILER_OPTIMIZING_REGISTER_ALLOCATOR_LINEAR_SCAN_H_