lib/CodeGen/LiveIntervalUnion.h - fp2-dev/platform/external/llvm - Gitiles

 //===-- LiveIntervalUnion.h - Live interval union data struct --*- C++ -*--===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // LiveIntervalUnion is a union of live segments across multiple live virtual
 // registers. This may be used during coalescing to represent a congruence
 // class, or during register allocation to model liveness of a physical
 // register.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CODEGEN_LIVEINTERVALUNION
 #define LLVM_CODEGEN_LIVEINTERVALUNION

 #include "llvm/CodeGen/LiveInterval.h"
 #include <vector>
 #include <set>

 namespace llvm {

 #ifndef NDEBUG
 // forward declaration
 template <unsigned Element> class SparseBitVector;
 typedef SparseBitVector<128> LvrBitSet;
 #endif

 /// A LiveSegment is a copy of a LiveRange object used within
 /// LiveIntervalUnion. LiveSegment additionally contains a pointer to its
 /// original live virtual register (LiveInterval). This allows quick lookup of
 /// the live virtual register as we iterate over live segments in a union. Note
 /// that LiveRange is misnamed and actually represents only a single contiguous
 /// interval within a virtual register's liveness. To limit confusion, in this
 /// file we refer it as a live segment.
 ///
 /// Note: This currently represents a half-open interval [start,end).
 /// If LiveRange is modified to represent a closed interval, so should this.
 struct LiveSegment {
   SlotIndex start;
   SlotIndex end;
   LiveInterval *liveVirtReg;

   LiveSegment(SlotIndex s, SlotIndex e, LiveInterval *lvr)
     : start(s), end(e), liveVirtReg(lvr) {}

   bool operator==(const LiveSegment &ls) const {
     return start == ls.start && end == ls.end && liveVirtReg == ls.liveVirtReg;
   }

   bool operator!=(const LiveSegment &ls) const {
     return !operator==(ls);
   }

   // Order segments by starting point only--we expect them to be disjoint.
   bool operator<(const LiveSegment &ls) const { return start < ls.start; }

   void dump() const;
   void print(raw_ostream &os) const;
 };

 inline bool operator<(SlotIndex V, const LiveSegment &ls) {
   return V < ls.start;
 }

 inline bool operator<(const LiveSegment &ls, SlotIndex V) {
   return ls.start < V;
 }

 /// Compare a live virtual register segment to a LiveIntervalUnion segment.
 inline bool overlap(const LiveRange &lvrSeg, const LiveSegment &liuSeg) {
   return lvrSeg.start < liuSeg.end && liuSeg.start < lvrSeg.end;
 }

 template <> struct isPodLike<LiveSegment> { static const bool value = true; };

 raw_ostream& operator<<(raw_ostream& os, const LiveSegment &ls);

 /// Abstraction to provide info for the representative register.
 class AbstractRegisterDescription {
 public:
   virtual const char *getName(unsigned reg) const = 0;
   virtual ~AbstractRegisterDescription() {}
 };

 /// Union of live intervals that are strong candidates for coalescing into a
 /// single register (either physical or virtual depending on the context).  We
 /// expect the constituent live intervals to be disjoint, although we may
 /// eventually make exceptions to handle value-based interference.
 class LiveIntervalUnion {
   // A set of live virtual register segments that supports fast insertion,
   // intersection, and removal.
   //
   // FIXME: std::set is a placeholder until we decide how to
   // efficiently represent it. Probably need to roll our own B-tree.
   typedef std::set<LiveSegment> LiveSegments;

   // A set of live virtual registers. Elements have type LiveInterval, where
   // each element represents the liveness of a single live virtual register.
   // This is traditionally known as a live range, but we refer is as a live
   // virtual register to avoid confusing it with the misnamed LiveRange
   // class.
   typedef std::vector<LiveInterval*> LiveVirtRegs;

 public:
   // SegmentIter can advance to the next segment ordered by starting position
   // which may belong to a different live virtual register. We also must be able
   // to reach the current segment's containing virtual register.
   typedef LiveSegments::iterator SegmentIter;

   class InterferenceResult;
   class Query;

 private:
   unsigned repReg_;        // representative register number
   LiveSegments segments_;  // union of virtual reg segements

 public:
   // default ctor avoids placement new
   LiveIntervalUnion() : repReg_(0) {}

   // Initialize the union by associating it with a representative register
   // number.
   void init(unsigned repReg) { repReg_ = repReg; }

   // Iterate over all segments in the union of live virtual registers ordered
   // by their starting position.
   SegmentIter begin() { return segments_.begin(); }
   SegmentIter end() { return segments_.end(); }

   // Return an iterator to the first segment after or including begin that
   // intersects with lvrSeg.
   SegmentIter upperBound(SegmentIter begin, const LiveSegment &seg);

   // Add a live virtual register to this union and merge its segments.
   // Holds a nonconst reference to the LVR for later maniplution.
   void unify(LiveInterval &lvr);

   // Remove a live virtual register's segments from this union.
   void extract(const LiveInterval &lvr);

   void dump(const AbstractRegisterDescription *regInfo) const;

   // If tri != NULL, use it to decode repReg_
   void print(raw_ostream &os, const AbstractRegisterDescription *rdesc) const;

 #ifndef NDEBUG
   // Verify the live intervals in this union and add them to the visited set.
   void verify(LvrBitSet& visitedVRegs);
 #endif

   /// Cache a single interference test result in the form of two intersecting
   /// segments. This allows efficiently iterating over the interferences. The
   /// iteration logic is handled by LiveIntervalUnion::Query which may
   /// filter interferences depending on the type of query.
   class InterferenceResult {
     friend class Query;

     LiveInterval::iterator lvrSegI_; // current position in _lvr
     SegmentIter liuSegI_;            // current position in _liu

     // Internal ctor.
     InterferenceResult(LiveInterval::iterator lvrSegI, SegmentIter liuSegI)
       : lvrSegI_(lvrSegI), liuSegI_(liuSegI) {}

   public:
     // Public default ctor.
     InterferenceResult(): lvrSegI_(), liuSegI_() {}

     // Note: this interface provides raw access to the iterators because the
     // result has no way to tell if it's valid to dereference them.

     // Access the lvr segment.
     LiveInterval::iterator lvrSegPos() const { return lvrSegI_; }

     // Access the liu segment.
     SegmentIter liuSegPos() const { return liuSegI_; }

     bool operator==(const InterferenceResult &ir) const {
       return lvrSegI_ == ir.lvrSegI_ && liuSegI_ == ir.liuSegI_;
     }
     bool operator!=(const InterferenceResult &ir) const {
       return !operator==(ir);
     }
   };

   /// Query interferences between a single live virtual register and a live
   /// interval union.
   class Query {
     LiveIntervalUnion *liu_;
     LiveInterval *lvr_;
     InterferenceResult firstInterference_;
     SmallVector<LiveInterval*,4> interferingVRegs_;
     bool seenUnspillableVReg_;

   public:
     Query(): liu_(), lvr_() {}

     Query(LiveInterval *lvr, LiveIntervalUnion *liu):
       liu_(liu), lvr_(lvr), seenUnspillableVReg_(false) {}

     void clear() {
       liu_ = NULL;
       lvr_ = NULL;
       firstInterference_ = InterferenceResult();
       interferingVRegs_.clear();
       seenUnspillableVReg_ = false;
     }

     void init(LiveInterval *lvr, LiveIntervalUnion *liu) {
       if (lvr_ == lvr) {
         // We currently allow query objects to be reused acrossed live virtual
         // registers, but always for the same live interval union.
         assert(liu_ == liu && "inconsistent initialization");
         // Retain cached results, e.g. firstInterference.
         return;
       }
       liu_ = liu;
       lvr_ = lvr;
       // Clear cached results.
       firstInterference_ = InterferenceResult();
       interferingVRegs_.clear();
       seenUnspillableVReg_ = false;
     }

     LiveInterval &lvr() const { assert(lvr_ && "uninitialized"); return *lvr_; }

     bool isInterference(const InterferenceResult &ir) const {
       if (ir.lvrSegI_ != lvr_->end()) {
         assert(overlap(*ir.lvrSegI_, *ir.liuSegI_) &&
                "invalid segment iterators");
         return true;
       }
       return false;
     }

     // Does this live virtual register interfere with the union.
     bool checkInterference() { return isInterference(firstInterference()); }

     // Get the first pair of interfering segments, or a noninterfering result.
     // This initializes the firstInterference_ cache.
     InterferenceResult firstInterference();

     // Treat the result as an iterator and advance to the next interfering pair
     // of segments. Visiting each unique interfering pairs means that the same
     // lvr or liu segment may be visited multiple times.
     bool nextInterference(InterferenceResult &ir) const;

     // Count the virtual registers in this union that interfere with this
     // query's live virtual register, up to maxInterferingRegs.
     unsigned collectInterferingVRegs(unsigned maxInterferingRegs = UINT_MAX);

     // Was this virtual register visited during collectInterferingVRegs?
     bool isSeenInterference(LiveInterval *lvr) const;

     // Did collectInterferingVRegs encounter an unspillable vreg?
     bool seenUnspillableVReg() const {
       return seenUnspillableVReg_;
     }

     // Vector generated by collectInterferingVRegs.
     const SmallVectorImpl<LiveInterval*> &interferingVRegs() const {
       return interferingVRegs_;
     }

   private:
     Query(const Query&);          // DO NOT IMPLEMENT
     void operator=(const Query&); // DO NOT IMPLEMENT

     // Private interface for queries
     void findIntersection(InterferenceResult &ir) const;
   };
 };

 } // end namespace llvm

 #endif // !defined(LLVM_CODEGEN_LIVEINTERVALUNION)
	//===-- LiveIntervalUnion.h - Live interval union data struct --- C++ ---===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// LiveIntervalUnion is a union of live segments across multiple live virtual
	// registers. This may be used during coalescing to represent a congruence
	// class, or during register allocation to model liveness of a physical
	// register.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CODEGEN_LIVEINTERVALUNION
	#define LLVM_CODEGEN_LIVEINTERVALUNION

	#include "llvm/CodeGen/LiveInterval.h"
	#include <vector>
	#include <set>

	namespace llvm {

	#ifndef NDEBUG
	// forward declaration
	template <unsigned Element> class SparseBitVector;
	typedef SparseBitVector<128> LvrBitSet;
	#endif

	/// A LiveSegment is a copy of a LiveRange object used within
	/// LiveIntervalUnion. LiveSegment additionally contains a pointer to its
	/// original live virtual register (LiveInterval). This allows quick lookup of
	/// the live virtual register as we iterate over live segments in a union. Note
	/// that LiveRange is misnamed and actually represents only a single contiguous
	/// interval within a virtual register's liveness. To limit confusion, in this
	/// file we refer it as a live segment.
	///
	/// Note: This currently represents a half-open interval [start,end).
	/// If LiveRange is modified to represent a closed interval, so should this.
	struct LiveSegment {
	SlotIndex start;
	SlotIndex end;
	LiveInterval *liveVirtReg;

	LiveSegment(SlotIndex s, SlotIndex e, LiveInterval *lvr)
	: start(s), end(e), liveVirtReg(lvr) {}

	bool operator==(const LiveSegment &ls) const {
	return start == ls.start && end == ls.end && liveVirtReg == ls.liveVirtReg;
	}

	bool operator!=(const LiveSegment &ls) const {
	return !operator==(ls);
	}

	// Order segments by starting point only--we expect them to be disjoint.
	bool operator<(const LiveSegment &ls) const { return start < ls.start; }

	void dump() const;
	void print(raw_ostream &os) const;
	};

	inline bool operator<(SlotIndex V, const LiveSegment &ls) {
	return V < ls.start;
	}

	inline bool operator<(const LiveSegment &ls, SlotIndex V) {
	return ls.start < V;
	}

	/// Compare a live virtual register segment to a LiveIntervalUnion segment.
	inline bool overlap(const LiveRange &lvrSeg, const LiveSegment &liuSeg) {
	return lvrSeg.start < liuSeg.end && liuSeg.start < lvrSeg.end;
	}

	template <> struct isPodLike<LiveSegment> { static const bool value = true; };

	raw_ostream& operator<<(raw_ostream& os, const LiveSegment &ls);

	/// Abstraction to provide info for the representative register.
	class AbstractRegisterDescription {
	public:
	virtual const char *getName(unsigned reg) const = 0;
	virtual ~AbstractRegisterDescription() {}
	};

	/// Union of live intervals that are strong candidates for coalescing into a
	/// single register (either physical or virtual depending on the context). We
	/// expect the constituent live intervals to be disjoint, although we may
	/// eventually make exceptions to handle value-based interference.
	class LiveIntervalUnion {
	// A set of live virtual register segments that supports fast insertion,
	// intersection, and removal.
	//
	// FIXME: std::set is a placeholder until we decide how to
	// efficiently represent it. Probably need to roll our own B-tree.
	typedef std::set<LiveSegment> LiveSegments;

	// A set of live virtual registers. Elements have type LiveInterval, where
	// each element represents the liveness of a single live virtual register.
	// This is traditionally known as a live range, but we refer is as a live
	// virtual register to avoid confusing it with the misnamed LiveRange
	// class.
	typedef std::vector<LiveInterval*> LiveVirtRegs;

	public:
	// SegmentIter can advance to the next segment ordered by starting position
	// which may belong to a different live virtual register. We also must be able
	// to reach the current segment's containing virtual register.
	typedef LiveSegments::iterator SegmentIter;

	class InterferenceResult;
	class Query;

	private:
	unsigned repReg_; // representative register number
	LiveSegments segments_; // union of virtual reg segements

	public:
	// default ctor avoids placement new
	LiveIntervalUnion() : repReg_(0) {}

	// Initialize the union by associating it with a representative register
	// number.
	void init(unsigned repReg) { repReg_ = repReg; }

	// Iterate over all segments in the union of live virtual registers ordered
	// by their starting position.
	SegmentIter begin() { return segments_.begin(); }
	SegmentIter end() { return segments_.end(); }

	// Return an iterator to the first segment after or including begin that
	// intersects with lvrSeg.
	SegmentIter upperBound(SegmentIter begin, const LiveSegment &seg);

	// Add a live virtual register to this union and merge its segments.
	// Holds a nonconst reference to the LVR for later maniplution.
	void unify(LiveInterval &lvr);

	// Remove a live virtual register's segments from this union.
	void extract(const LiveInterval &lvr);

	void dump(const AbstractRegisterDescription *regInfo) const;

	// If tri != NULL, use it to decode repReg_
	void print(raw_ostream &os, const AbstractRegisterDescription *rdesc) const;

	#ifndef NDEBUG
	// Verify the live intervals in this union and add them to the visited set.
	void verify(LvrBitSet& visitedVRegs);
	#endif

	/// Cache a single interference test result in the form of two intersecting
	/// segments. This allows efficiently iterating over the interferences. The
	/// iteration logic is handled by LiveIntervalUnion::Query which may
	/// filter interferences depending on the type of query.
	class InterferenceResult {
	friend class Query;

	LiveInterval::iterator lvrSegI_; // current position in _lvr
	SegmentIter liuSegI_; // current position in _liu

	// Internal ctor.
	InterferenceResult(LiveInterval::iterator lvrSegI, SegmentIter liuSegI)
	: lvrSegI_(lvrSegI), liuSegI_(liuSegI) {}

	public:
	// Public default ctor.
	InterferenceResult(): lvrSegI_(), liuSegI_() {}

	// Note: this interface provides raw access to the iterators because the
	// result has no way to tell if it's valid to dereference them.

	// Access the lvr segment.
	LiveInterval::iterator lvrSegPos() const { return lvrSegI_; }

	// Access the liu segment.
	SegmentIter liuSegPos() const { return liuSegI_; }

	bool operator==(const InterferenceResult &ir) const {
	return lvrSegI_ == ir.lvrSegI_ && liuSegI_ == ir.liuSegI_;
	}
	bool operator!=(const InterferenceResult &ir) const {
	return !operator==(ir);
	}
	};

	/// Query interferences between a single live virtual register and a live
	/// interval union.
	class Query {
	LiveIntervalUnion *liu_;
	LiveInterval *lvr_;
	InterferenceResult firstInterference_;
	SmallVector<LiveInterval*,4> interferingVRegs_;
	bool seenUnspillableVReg_;

	public:
	Query(): liu_(), lvr_() {}

	Query(LiveInterval lvr, LiveIntervalUnion liu):
	liu_(liu), lvr_(lvr), seenUnspillableVReg_(false) {}

	void clear() {
	liu_ = NULL;
	lvr_ = NULL;
	firstInterference_ = InterferenceResult();
	interferingVRegs_.clear();
	seenUnspillableVReg_ = false;
	}

	void init(LiveInterval lvr, LiveIntervalUnion liu) {
	if (lvr_ == lvr) {
	// We currently allow query objects to be reused acrossed live virtual
	// registers, but always for the same live interval union.
	assert(liu_ == liu && "inconsistent initialization");
	// Retain cached results, e.g. firstInterference.
	return;
	}
	liu_ = liu;
	lvr_ = lvr;
	// Clear cached results.
	firstInterference_ = InterferenceResult();
	interferingVRegs_.clear();
	seenUnspillableVReg_ = false;
	}

	LiveInterval &lvr() const { assert(lvr_ && "uninitialized"); return *lvr_; }

	bool isInterference(const InterferenceResult &ir) const {
	if (ir.lvrSegI_ != lvr_->end()) {
	assert(overlap(ir.lvrSegI_, ir.liuSegI_) &&
	"invalid segment iterators");
	return true;
	}
	return false;
	}

	// Does this live virtual register interfere with the union.
	bool checkInterference() { return isInterference(firstInterference()); }

	// Get the first pair of interfering segments, or a noninterfering result.
	// This initializes the firstInterference_ cache.
	InterferenceResult firstInterference();

	// Treat the result as an iterator and advance to the next interfering pair
	// of segments. Visiting each unique interfering pairs means that the same
	// lvr or liu segment may be visited multiple times.
	bool nextInterference(InterferenceResult &ir) const;

	// Count the virtual registers in this union that interfere with this
	// query's live virtual register, up to maxInterferingRegs.
	unsigned collectInterferingVRegs(unsigned maxInterferingRegs = UINT_MAX);

	// Was this virtual register visited during collectInterferingVRegs?
	bool isSeenInterference(LiveInterval *lvr) const;

	// Did collectInterferingVRegs encounter an unspillable vreg?
	bool seenUnspillableVReg() const {
	return seenUnspillableVReg_;
	}

	// Vector generated by collectInterferingVRegs.
	const SmallVectorImpl<LiveInterval*> &interferingVRegs() const {
	return interferingVRegs_;
	}

	private:
	Query(const Query&); // DO NOT IMPLEMENT
	void operator=(const Query&); // DO NOT IMPLEMENT

	// Private interface for queries
	void findIntersection(InterferenceResult &ir) const;
	};
	};

	} // end namespace llvm

	#endif // !defined(LLVM_CODEGEN_LIVEINTERVALUNION)