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

 //===-- LiveIntervalUnion.cpp - Live interval union data structure --------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // LiveIntervalUnion represents a coalesced set of live intervals. This may be
 // used during coalescing to represent a congruence class, or during register
 // allocation to model liveness of a physical register.
 //
 //===----------------------------------------------------------------------===//

 #define DEBUG_TYPE "regalloc"
 #include "LiveIntervalUnion.h"
 #include "llvm/Support/Debug.h"
 #include "llvm/Support/raw_ostream.h"
 #include <algorithm>
 using namespace llvm;

 // Merge a LiveInterval's segments. Guarantee no overlaps.
 void LiveIntervalUnion::unify(LiveInterval &lvr) {
   // Add this live virtual register to the union
   LiveVirtRegs::iterator pos = std::upper_bound(lvrs_.begin(), lvrs_.end(),
                                                 &lvr, less_ptr<LiveInterval>());
   assert(pos == lvrs_.end() || *pos != &lvr && "duplicate LVR insertion");
   lvrs_.insert(pos, &lvr);
   // Insert each of the virtual register's live segments into the map
   SegmentIter segPos = segments_.begin();
   for (LiveInterval::iterator lvrI = lvr.begin(), lvrEnd = lvr.end();
        lvrI != lvrEnd; ++lvrI ) {
     LiveSegment segment(lvrI->start, lvrI->end, lvr);
     segPos = segments_.insert(segPos, segment);
     assert(*segPos == segment && "need equal val for equal key");
   }
 }

 namespace {

 // Keep LVRs sorted for fast membership test and extraction.
 struct LessReg
   : public std::binary_function<LiveInterval*, LiveInterval*, bool> {
   bool operator()(const LiveInterval *left, const LiveInterval *right) const {
     return left->reg < right->reg;
   }
 };

 // Low-level helper to find the first segment in the range [segI,segEnd) that
 // intersects with a live virtual register segment, or segI.start >= lvr.end
 //
 // This logic is tied to the underlying LiveSegments data structure. For now, we
 // use a binary search within the vector to find the nearest starting position,
 // then reverse iterate to find the first overlap.
 //
 // Upon entry we have segI.start < lvrSeg.end
 // seg   |--...
 //        \   .
 // lvr ...-|
 //
 // After binary search, we have segI.start >= lvrSeg.start:
 // seg   |--...
 //      /
 // lvr |--...
 //
 // Assuming intervals are disjoint, if an intersection exists, it must be the
 // segment found or immediately behind it. We continue reverse iterating to
 // return the first overlap.
 //
 // FIXME: support extract(), handle tombstones of extracted lvrs.
 typedef LiveIntervalUnion::SegmentIter SegmentIter;
 SegmentIter upperBound(SegmentIter segBegin,
                        SegmentIter segEnd,
                        const LiveRange &lvrSeg) {
   assert(lvrSeg.end > segBegin->start && "segment iterator precondition");
   // get the next LIU segment such that setg.start is not less than
   // lvrSeg.start
   SegmentIter segI = std::upper_bound(segBegin, segEnd, lvrSeg.start);
   while (segI != segBegin) {
     --segI;
     if (lvrSeg.start >= segI->end)
       return ++segI;
   }
   return segI;
 }
 } // end anonymous namespace

 // Private interface accessed by Query.
 //
 // Find a pair of segments that intersect, one in the live virtual register
 // (LiveInterval), and the other in this LiveIntervalUnion. The caller (Query)
 // is responsible for advancing the LiveIntervalUnion segments to find a
 // "notable" intersection, which requires query-specific logic.
 //
 // This design assumes only a fast mechanism for intersecting a single live
 // virtual register segment with a set of LiveIntervalUnion segments.  This may
 // be ok since most LVRs have very few segments.  If we had a data
 // structure that optimizd MxN intersection of segments, then we would bypass
 // the loop that advances within the LiveInterval.
 //
 // If no intersection exists, set lvrI = lvrEnd, and set segI to the first
 // segment whose start point is greater than LiveInterval's end point.
 //
 // Assumes that segments are sorted by start position in both
 // LiveInterval and LiveSegments.
 void LiveIntervalUnion::Query::findIntersection(InterferenceResult &ir) const {
   LiveInterval::iterator lvrEnd = lvr_.end();
   SegmentIter liuEnd = liu_.end();
   while (ir.liuSegI_ != liuEnd) {
     // Slowly advance the live virtual reg iterator until we surpass the next
     // segment in this union. If this is ever used for coalescing of fixed
     // registers and we have a LiveInterval with thousands of segments, then use
     // upper bound instead.
     while (ir.lvrSegI_ != lvrEnd && ir.lvrSegI_->end <= ir.liuSegI_->start)
       ++ir.lvrSegI_;
     if (ir.lvrSegI_ == lvrEnd)
       break;
     // lvrSegI_ may have advanced far beyond liuSegI_,
     // do a fast intersection test to "catch up"
     ir.liuSegI_ = upperBound(ir.liuSegI_, liuEnd, *ir.lvrSegI_);
     // Check if no liuSegI_ exists with lvrSegI_->start < liuSegI_.end
     if (ir.liuSegI_ == liuEnd)
       break;
     if (ir.liuSegI_->start < ir.lvrSegI_->end) {
       assert(overlap(*ir.lvrSegI_, *ir.liuSegI_) && "upperBound postcondition");
       break;
     }
   }
   if (ir.liuSegI_ == liuEnd)
     ir.lvrSegI_ = lvrEnd;
 }

 // Find the first intersection, and cache interference info
 // (retain segment iterators into both lvr_ and liu_).
 LiveIntervalUnion::InterferenceResult
 LiveIntervalUnion::Query::firstInterference() {
   if (firstInterference_ != LiveIntervalUnion::InterferenceResult()) {
     return firstInterference_;
   }
   firstInterference_ = InterferenceResult(lvr_.begin(), liu_.begin());
   findIntersection(firstInterference_);
   return firstInterference_;
 }

 // Treat the result as an iterator and advance to the next interfering pair
 // of segments. This is a plain iterator with no filter.
 bool LiveIntervalUnion::Query::nextInterference(InterferenceResult &ir) const {
   assert(isInterference(ir) && "iteration past end of interferences");
   // Advance either the lvr or liu segment to ensure that we visit all unique
   // overlapping pairs.
   if (ir.lvrSegI_->end < ir.liuSegI_->end) {
     if (++ir.lvrSegI_ == lvr_.end())
       return false;
   }
   else {
     if (++ir.liuSegI_ == liu_.end()) {
       ir.lvrSegI_ = lvr_.end();
       return false;
     }
   }
   if (overlap(*ir.lvrSegI_, *ir.liuSegI_))
     return true;
   // find the next intersection
   findIntersection(ir);
   return isInterference(ir);
 }
	//===-- LiveIntervalUnion.cpp - Live interval union data structure --------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// LiveIntervalUnion represents a coalesced set of live intervals. This may be
	// used during coalescing to represent a congruence class, or during register
	// allocation to model liveness of a physical register.
	//
	//===----------------------------------------------------------------------===//

	#define DEBUG_TYPE "regalloc"
	#include "LiveIntervalUnion.h"
	#include "llvm/Support/Debug.h"
	#include "llvm/Support/raw_ostream.h"
	#include <algorithm>
	using namespace llvm;

	// Merge a LiveInterval's segments. Guarantee no overlaps.
	void LiveIntervalUnion::unify(LiveInterval &lvr) {
	// Add this live virtual register to the union
	LiveVirtRegs::iterator pos = std::upper_bound(lvrs_.begin(), lvrs_.end(),
	&lvr, less_ptr<LiveInterval>());
	assert(pos == lvrs_.end() \|\| *pos != &lvr && "duplicate LVR insertion");
	lvrs_.insert(pos, &lvr);
	// Insert each of the virtual register's live segments into the map
	SegmentIter segPos = segments_.begin();
	for (LiveInterval::iterator lvrI = lvr.begin(), lvrEnd = lvr.end();
	lvrI != lvrEnd; ++lvrI ) {
	LiveSegment segment(lvrI->start, lvrI->end, lvr);
	segPos = segments_.insert(segPos, segment);
	assert(*segPos == segment && "need equal val for equal key");
	}
	}

	namespace {

	// Keep LVRs sorted for fast membership test and extraction.
	struct LessReg
	: public std::binary_function<LiveInterval, LiveInterval, bool> {
	bool operator()(const LiveInterval left, const LiveInterval right) const {
	return left->reg < right->reg;
	}
	};

	// Low-level helper to find the first segment in the range [segI,segEnd) that
	// intersects with a live virtual register segment, or segI.start >= lvr.end
	//
	// This logic is tied to the underlying LiveSegments data structure. For now, we
	// use a binary search within the vector to find the nearest starting position,
	// then reverse iterate to find the first overlap.
	//
	// Upon entry we have segI.start < lvrSeg.end
	// seg \|--...
	// \ .
	// lvr ...-\|
	//
	// After binary search, we have segI.start >= lvrSeg.start:
	// seg \|--...
	// /
	// lvr \|--...
	//
	// Assuming intervals are disjoint, if an intersection exists, it must be the
	// segment found or immediately behind it. We continue reverse iterating to
	// return the first overlap.
	//
	// FIXME: support extract(), handle tombstones of extracted lvrs.
	typedef LiveIntervalUnion::SegmentIter SegmentIter;
	SegmentIter upperBound(SegmentIter segBegin,
	SegmentIter segEnd,
	const LiveRange &lvrSeg) {
	assert(lvrSeg.end > segBegin->start && "segment iterator precondition");
	// get the next LIU segment such that setg.start is not less than
	// lvrSeg.start
	SegmentIter segI = std::upper_bound(segBegin, segEnd, lvrSeg.start);
	while (segI != segBegin) {
	--segI;
	if (lvrSeg.start >= segI->end)
	return ++segI;
	}
	return segI;
	}
	} // end anonymous namespace

	// Private interface accessed by Query.
	//
	// Find a pair of segments that intersect, one in the live virtual register
	// (LiveInterval), and the other in this LiveIntervalUnion. The caller (Query)
	// is responsible for advancing the LiveIntervalUnion segments to find a
	// "notable" intersection, which requires query-specific logic.
	//
	// This design assumes only a fast mechanism for intersecting a single live
	// virtual register segment with a set of LiveIntervalUnion segments. This may
	// be ok since most LVRs have very few segments. If we had a data
	// structure that optimizd MxN intersection of segments, then we would bypass
	// the loop that advances within the LiveInterval.
	//
	// If no intersection exists, set lvrI = lvrEnd, and set segI to the first
	// segment whose start point is greater than LiveInterval's end point.
	//
	// Assumes that segments are sorted by start position in both
	// LiveInterval and LiveSegments.
	void LiveIntervalUnion::Query::findIntersection(InterferenceResult &ir) const {
	LiveInterval::iterator lvrEnd = lvr_.end();
	SegmentIter liuEnd = liu_.end();
	while (ir.liuSegI_ != liuEnd) {
	// Slowly advance the live virtual reg iterator until we surpass the next
	// segment in this union. If this is ever used for coalescing of fixed
	// registers and we have a LiveInterval with thousands of segments, then use
	// upper bound instead.
	while (ir.lvrSegI_ != lvrEnd && ir.lvrSegI_->end <= ir.liuSegI_->start)
	++ir.lvrSegI_;
	if (ir.lvrSegI_ == lvrEnd)
	break;
	// lvrSegI_ may have advanced far beyond liuSegI_,
	// do a fast intersection test to "catch up"
	ir.liuSegI_ = upperBound(ir.liuSegI_, liuEnd, *ir.lvrSegI_);
	// Check if no liuSegI_ exists with lvrSegI_->start < liuSegI_.end
	if (ir.liuSegI_ == liuEnd)
	break;
	if (ir.liuSegI_->start < ir.lvrSegI_->end) {
	assert(overlap(ir.lvrSegI_, ir.liuSegI_) && "upperBound postcondition");
	break;
	}
	}
	if (ir.liuSegI_ == liuEnd)
	ir.lvrSegI_ = lvrEnd;
	}

	// Find the first intersection, and cache interference info
	// (retain segment iterators into both lvr_ and liu_).
	LiveIntervalUnion::InterferenceResult
	LiveIntervalUnion::Query::firstInterference() {
	if (firstInterference_ != LiveIntervalUnion::InterferenceResult()) {
	return firstInterference_;
	}
	firstInterference_ = InterferenceResult(lvr_.begin(), liu_.begin());
	findIntersection(firstInterference_);
	return firstInterference_;
	}

	// Treat the result as an iterator and advance to the next interfering pair
	// of segments. This is a plain iterator with no filter.
	bool LiveIntervalUnion::Query::nextInterference(InterferenceResult &ir) const {
	assert(isInterference(ir) && "iteration past end of interferences");
	// Advance either the lvr or liu segment to ensure that we visit all unique
	// overlapping pairs.
	if (ir.lvrSegI_->end < ir.liuSegI_->end) {
	if (++ir.lvrSegI_ == lvr_.end())
	return false;
	}
	else {
	if (++ir.liuSegI_ == liu_.end()) {
	ir.lvrSegI_ = lvr_.end();
	return false;
	}
	}
	if (overlap(ir.lvrSegI_, ir.liuSegI_))
	return true;
	// find the next intersection
	findIntersection(ir);
	return isInterference(ir);
	}