lib/Target/TargetSchedInfo.cpp - llvm - Git at Google

 //===-- SchedInfo.cpp - Generic code to support target schedulers ----------==//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file was developed by the LLVM research group and is distributed under
 // the University of Illinois Open Source License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements the generic part of a Scheduler description for a
 // target.  This functionality is defined in the llvm/Target/SchedInfo.h file.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Config/alloca.h"
 #include "llvm/Target/TargetSchedInfo.h"
 #include "llvm/Target/TargetMachine.h"
 #include <algorithm>
 #include <iostream>
 using namespace llvm;

 resourceId_t llvm::CPUResource::nextId = 0;
 static std::vector<CPUResource*> *CPUResourceMap = 0;

 CPUResource::CPUResource(const std::string& resourceName, int maxUsers)
     : rname(resourceName), rid(nextId++), maxNumUsers(maxUsers) {
   if(!CPUResourceMap)
     CPUResourceMap = new std::vector<CPUResource*>;

   //Put Resource in the map
   CPUResourceMap->push_back(this);
 }

 ///Get CPUResource if you only have the resource ID
 CPUResource* CPUResource::getCPUResource(resourceId_t id) {
   return (*CPUResourceMap)[id];
 }

 // Check if fromRVec and toRVec have *any* common entries.
 // Assume the vectors are sorted in increasing order.
 // Algorithm copied from function set_intersection() for sorted ranges
 // (stl_algo.h).
 //
 inline static bool
 RUConflict(const std::vector<resourceId_t>& fromRVec,
            const std::vector<resourceId_t>& toRVec)
 {

   unsigned fN = fromRVec.size(), tN = toRVec.size();
   unsigned fi = 0, ti = 0;

   while (fi < fN && ti < tN) {
     if (fromRVec[fi] < toRVec[ti])
       ++fi;
     else if (toRVec[ti] < fromRVec[fi])
       ++ti;
     else
       return true;
   }
   return false;
 }


 static CycleCount_t
 ComputeMinGap(const InstrRUsage &fromRU,
               const InstrRUsage &toRU)
 {
   CycleCount_t minGap = 0;

   if (fromRU.numBubbles > 0)
     minGap = fromRU.numBubbles;

   if (minGap < fromRU.numCycles) {
     // only need to check from cycle `minGap' onwards
     for (CycleCount_t gap=minGap; gap <= fromRU.numCycles-1; gap++) {
       // check if instr. #2 can start executing `gap' cycles after #1
       // by checking for resource conflicts in each overlapping cycle
       CycleCount_t numOverlap =std::min(fromRU.numCycles - gap, toRU.numCycles);
       for (CycleCount_t c = 0; c <= numOverlap-1; c++)
         if (RUConflict(fromRU.resourcesByCycle[gap + c],
                        toRU.resourcesByCycle[c])) {
           // conflict found so minGap must be more than `gap'
           minGap = gap+1;
           break;
         }
     }
   }

   return minGap;
 }


 //---------------------------------------------------------------------------
 // class TargetSchedInfo
 // Interface to machine description for instruction scheduling
 //---------------------------------------------------------------------------

 TargetSchedInfo::TargetSchedInfo(const TargetMachine&    tgt,
                                  int                     NumSchedClasses,
                                  const InstrClassRUsage* ClassRUsages,
                                  const InstrRUsageDelta* UsageDeltas,
                                  const InstrIssueDelta*  IssueDeltas,
                                  unsigned NumUsageDeltas,
                                  unsigned NumIssueDeltas)
   : target(tgt),
     numSchedClasses(NumSchedClasses), mii(tgt.getInstrInfo()),
     classRUsages(ClassRUsages), usageDeltas(UsageDeltas),
     issueDeltas(IssueDeltas), numUsageDeltas(NumUsageDeltas),
     numIssueDeltas(NumIssueDeltas)
 {}

 void
 TargetSchedInfo::initializeResources()
 {
   assert(MAX_NUM_SLOTS >= (int)getMaxNumIssueTotal() &&
          "Insufficient slots for static data! Increase MAX_NUM_SLOTS");

   // First, compute common resource usage info for each class because
   // most instructions will probably behave the same as their class.
   // Cannot allocate a vector of InstrRUsage so new each one.
   //
   std::vector<InstrRUsage> instrRUForClasses;
   instrRUForClasses.resize(numSchedClasses);
   for (InstrSchedClass sc = 0; sc < numSchedClasses; sc++) {
     // instrRUForClasses.push_back(new InstrRUsage);
     instrRUForClasses[sc].setMaxSlots(getMaxNumIssueTotal());
     instrRUForClasses[sc].setTo(classRUsages[sc]);
   }

   computeInstrResources(instrRUForClasses);
   computeIssueGaps(instrRUForClasses);
 }


 void
 TargetSchedInfo::computeInstrResources(const std::vector<InstrRUsage>&
                                         instrRUForClasses) {
   int numOpCodes =  mii->getNumOpcodes();
   instrRUsages.resize(numOpCodes);

   // First get the resource usage information from the class resource usages.
   for (MachineOpCode op = 0; op < numOpCodes; ++op) {
     InstrSchedClass sc = getSchedClass(op);
     assert(sc < numSchedClasses);
     instrRUsages[op] = instrRUForClasses[sc];
   }

   // Now, modify the resource usages as specified in the deltas.
   for (unsigned i = 0; i < numUsageDeltas; ++i) {
     MachineOpCode op = usageDeltas[i].opCode;
     assert(op < numOpCodes);
     instrRUsages[op].addUsageDelta(usageDeltas[i]);
   }

   // Then modify the issue restrictions as specified in the deltas.
   for (unsigned i = 0; i < numIssueDeltas; ++i) {
     MachineOpCode op = issueDeltas[i].opCode;
     assert(op < numOpCodes);
     instrRUsages[issueDeltas[i].opCode].addIssueDelta(issueDeltas[i]);
   }
 }


 void
 TargetSchedInfo::computeIssueGaps(const std::vector<InstrRUsage>&
                                    instrRUForClasses) {
   int numOpCodes =  mii->getNumOpcodes();
   issueGaps.resize(numOpCodes);
   conflictLists.resize(numOpCodes);

   // First, compute issue gaps between pairs of classes based on common
   // resources usages for each class, because most instruction pairs will
   // usually behave the same as their class.
   //
   int* classPairGaps =
     static_cast<int*>(alloca(sizeof(int) * numSchedClasses * numSchedClasses));
   for (InstrSchedClass fromSC=0; fromSC < numSchedClasses; fromSC++)
     for (InstrSchedClass toSC=0; toSC < numSchedClasses; toSC++) {
       int classPairGap = ComputeMinGap(instrRUForClasses[fromSC],
                                        instrRUForClasses[toSC]);
       classPairGaps[fromSC*numSchedClasses + toSC] = classPairGap;
     }

   // Now, for each pair of instructions, use the class pair gap if both
   // instructions have identical resource usage as their respective classes.
   // If not, recompute the gap for the pair from scratch.

   longestIssueConflict = 0;

   for (MachineOpCode fromOp=0; fromOp < numOpCodes; fromOp++)
     for (MachineOpCode toOp=0; toOp < numOpCodes; toOp++) {
       int instrPairGap =
         (instrRUsages[fromOp].sameAsClass && instrRUsages[toOp].sameAsClass)
         ? classPairGaps[getSchedClass(fromOp)*numSchedClasses + getSchedClass(toOp)]
         : ComputeMinGap(instrRUsages[fromOp], instrRUsages[toOp]);

       if (instrPairGap > 0) {
         this->setGap(instrPairGap, fromOp, toOp);
         conflictLists[fromOp].push_back(toOp);
         longestIssueConflict=std::max(longestIssueConflict, instrPairGap);
       }
     }
 }


 void InstrRUsage::setTo(const InstrClassRUsage& classRU) {
   sameAsClass   = true;
   isSingleIssue = classRU.isSingleIssue;
   breaksGroup   = classRU.breaksGroup;
   numBubbles    = classRU.numBubbles;

   for (unsigned i=0; i < classRU.numSlots; i++) {
     unsigned slot = classRU.feasibleSlots[i];
     assert(slot < feasibleSlots.size() && "Invalid slot specified!");
     this->feasibleSlots[slot] = true;
   }

   numCycles   = classRU.totCycles;
   resourcesByCycle.resize(this->numCycles);

   for (unsigned i=0; i < classRU.numRUEntries; i++)
     for (unsigned c=classRU.V[i].startCycle, NC = c + classRU.V[i].numCycles;
          c < NC; c++)
       this->resourcesByCycle[c].push_back(classRU.V[i].resourceId);

   // Sort each resource usage vector by resourceId_t to speed up conflict
   // checking
   for (unsigned i=0; i < this->resourcesByCycle.size(); i++)
     std::sort(resourcesByCycle[i].begin(), resourcesByCycle[i].end());
 }

 // Add the extra resource usage requirements specified in the delta.
 // Note that a negative value of `numCycles' means one entry for that
 // resource should be deleted for each cycle.
 //
 void InstrRUsage::addUsageDelta(const InstrRUsageDelta &delta) {
   int NC = delta.numCycles;
   sameAsClass = false;

   // resize the resources vector if more cycles are specified
   unsigned maxCycles = this->numCycles;
   maxCycles = std::max(maxCycles, delta.startCycle + abs(NC) - 1);
   if (maxCycles > this->numCycles) {
     this->resourcesByCycle.resize(maxCycles);
     this->numCycles = maxCycles;
   }

   if (NC >= 0)
     for (unsigned c=delta.startCycle, last=c+NC-1; c <= last; c++)
       this->resourcesByCycle[c].push_back(delta.resourceId);
   else
     // Remove the resource from all NC cycles.
     for (unsigned c=delta.startCycle, last=(c-NC)-1; c <= last; c++) {
       // Look for the resource backwards so we remove the last entry
       // for that resource in each cycle.
       std::vector<resourceId_t>& rvec = this->resourcesByCycle[c];
       int r;
       for (r = rvec.size() - 1; r >= 0; r--)
         if (rvec[r] == delta.resourceId) {
           // found last entry for the resource
           rvec.erase(rvec.begin() + r);
           break;
         }
       assert(r >= 0 && "Resource to remove was unused in cycle c!");
     }
 }
	//===-- SchedInfo.cpp - Generic code to support target schedulers ----------==//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file was developed by the LLVM research group and is distributed under
	// the University of Illinois Open Source License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements the generic part of a Scheduler description for a
	// target. This functionality is defined in the llvm/Target/SchedInfo.h file.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Config/alloca.h"
	#include "llvm/Target/TargetSchedInfo.h"
	#include "llvm/Target/TargetMachine.h"
	#include <algorithm>
	#include <iostream>
	using namespace llvm;

	resourceId_t llvm::CPUResource::nextId = 0;
	static std::vector<CPUResource> CPUResourceMap = 0;

	CPUResource::CPUResource(const std::string& resourceName, int maxUsers)
	: rname(resourceName), rid(nextId++), maxNumUsers(maxUsers) {
	if(!CPUResourceMap)
	CPUResourceMap = new std::vector<CPUResource*>;

	//Put Resource in the map
	CPUResourceMap->push_back(this);
	}

	///Get CPUResource if you only have the resource ID
	CPUResource* CPUResource::getCPUResource(resourceId_t id) {
	return (*CPUResourceMap)[id];
	}

	// Check if fromRVec and toRVec have any common entries.
	// Assume the vectors are sorted in increasing order.
	// Algorithm copied from function set_intersection() for sorted ranges
	// (stl_algo.h).
	//
	inline static bool
	RUConflict(const std::vector<resourceId_t>& fromRVec,
	const std::vector<resourceId_t>& toRVec)
	{

	unsigned fN = fromRVec.size(), tN = toRVec.size();
	unsigned fi = 0, ti = 0;

	while (fi < fN && ti < tN) {
	if (fromRVec[fi] < toRVec[ti])
	++fi;
	else if (toRVec[ti] < fromRVec[fi])
	++ti;
	else
	return true;
	}
	return false;
	}


	static CycleCount_t
	ComputeMinGap(const InstrRUsage &fromRU,
	const InstrRUsage &toRU)
	{
	CycleCount_t minGap = 0;

	if (fromRU.numBubbles > 0)
	minGap = fromRU.numBubbles;

	if (minGap < fromRU.numCycles) {
	// only need to check from cycle `minGap' onwards
	for (CycleCount_t gap=minGap; gap <= fromRU.numCycles-1; gap++) {
	// check if instr. #2 can start executing `gap' cycles after #1
	// by checking for resource conflicts in each overlapping cycle
	CycleCount_t numOverlap =std::min(fromRU.numCycles - gap, toRU.numCycles);
	for (CycleCount_t c = 0; c <= numOverlap-1; c++)
	if (RUConflict(fromRU.resourcesByCycle[gap + c],
	toRU.resourcesByCycle[c])) {
	// conflict found so minGap must be more than `gap'
	minGap = gap+1;
	break;
	}
	}
	}

	return minGap;
	}


	//---------------------------------------------------------------------------
	// class TargetSchedInfo
	// Interface to machine description for instruction scheduling
	//---------------------------------------------------------------------------

	TargetSchedInfo::TargetSchedInfo(const TargetMachine& tgt,
	int NumSchedClasses,
	const InstrClassRUsage* ClassRUsages,
	const InstrRUsageDelta* UsageDeltas,
	const InstrIssueDelta* IssueDeltas,
	unsigned NumUsageDeltas,
	unsigned NumIssueDeltas)
	: target(tgt),
	numSchedClasses(NumSchedClasses), mii(tgt.getInstrInfo()),
	classRUsages(ClassRUsages), usageDeltas(UsageDeltas),
	issueDeltas(IssueDeltas), numUsageDeltas(NumUsageDeltas),
	numIssueDeltas(NumIssueDeltas)
	{}

	void
	TargetSchedInfo::initializeResources()
	{
	assert(MAX_NUM_SLOTS >= (int)getMaxNumIssueTotal() &&
	"Insufficient slots for static data! Increase MAX_NUM_SLOTS");

	// First, compute common resource usage info for each class because
	// most instructions will probably behave the same as their class.
	// Cannot allocate a vector of InstrRUsage so new each one.
	//
	std::vector<InstrRUsage> instrRUForClasses;
	instrRUForClasses.resize(numSchedClasses);
	for (InstrSchedClass sc = 0; sc < numSchedClasses; sc++) {
	// instrRUForClasses.push_back(new InstrRUsage);
	instrRUForClasses[sc].setMaxSlots(getMaxNumIssueTotal());
	instrRUForClasses[sc].setTo(classRUsages[sc]);
	}

	computeInstrResources(instrRUForClasses);
	computeIssueGaps(instrRUForClasses);
	}


	void
	TargetSchedInfo::computeInstrResources(const std::vector<InstrRUsage>&
	instrRUForClasses) {
	int numOpCodes = mii->getNumOpcodes();
	instrRUsages.resize(numOpCodes);

	// First get the resource usage information from the class resource usages.
	for (MachineOpCode op = 0; op < numOpCodes; ++op) {
	InstrSchedClass sc = getSchedClass(op);
	assert(sc < numSchedClasses);
	instrRUsages[op] = instrRUForClasses[sc];
	}

	// Now, modify the resource usages as specified in the deltas.
	for (unsigned i = 0; i < numUsageDeltas; ++i) {
	MachineOpCode op = usageDeltas[i].opCode;
	assert(op < numOpCodes);
	instrRUsages[op].addUsageDelta(usageDeltas[i]);
	}

	// Then modify the issue restrictions as specified in the deltas.
	for (unsigned i = 0; i < numIssueDeltas; ++i) {
	MachineOpCode op = issueDeltas[i].opCode;
	assert(op < numOpCodes);
	instrRUsages[issueDeltas[i].opCode].addIssueDelta(issueDeltas[i]);
	}
	}


	void
	TargetSchedInfo::computeIssueGaps(const std::vector<InstrRUsage>&
	instrRUForClasses) {
	int numOpCodes = mii->getNumOpcodes();
	issueGaps.resize(numOpCodes);
	conflictLists.resize(numOpCodes);

	// First, compute issue gaps between pairs of classes based on common
	// resources usages for each class, because most instruction pairs will
	// usually behave the same as their class.
	//
	int* classPairGaps =
	static_cast<int>(alloca(sizeof(int) numSchedClasses * numSchedClasses));
	for (InstrSchedClass fromSC=0; fromSC < numSchedClasses; fromSC++)
	for (InstrSchedClass toSC=0; toSC < numSchedClasses; toSC++) {
	int classPairGap = ComputeMinGap(instrRUForClasses[fromSC],
	instrRUForClasses[toSC]);
	classPairGaps[fromSC*numSchedClasses + toSC] = classPairGap;
	}

	// Now, for each pair of instructions, use the class pair gap if both
	// instructions have identical resource usage as their respective classes.
	// If not, recompute the gap for the pair from scratch.

	longestIssueConflict = 0;

	for (MachineOpCode fromOp=0; fromOp < numOpCodes; fromOp++)
	for (MachineOpCode toOp=0; toOp < numOpCodes; toOp++) {
	int instrPairGap =
	(instrRUsages[fromOp].sameAsClass && instrRUsages[toOp].sameAsClass)
	? classPairGaps[getSchedClass(fromOp)*numSchedClasses + getSchedClass(toOp)]
	: ComputeMinGap(instrRUsages[fromOp], instrRUsages[toOp]);

	if (instrPairGap > 0) {
	this->setGap(instrPairGap, fromOp, toOp);
	conflictLists[fromOp].push_back(toOp);
	longestIssueConflict=std::max(longestIssueConflict, instrPairGap);
	}
	}
	}


	void InstrRUsage::setTo(const InstrClassRUsage& classRU) {
	sameAsClass = true;
	isSingleIssue = classRU.isSingleIssue;
	breaksGroup = classRU.breaksGroup;
	numBubbles = classRU.numBubbles;

	for (unsigned i=0; i < classRU.numSlots; i++) {
	unsigned slot = classRU.feasibleSlots[i];
	assert(slot < feasibleSlots.size() && "Invalid slot specified!");
	this->feasibleSlots[slot] = true;
	}

	numCycles = classRU.totCycles;
	resourcesByCycle.resize(this->numCycles);

	for (unsigned i=0; i < classRU.numRUEntries; i++)
	for (unsigned c=classRU.V[i].startCycle, NC = c + classRU.V[i].numCycles;
	c < NC; c++)
	this->resourcesByCycle[c].push_back(classRU.V[i].resourceId);

	// Sort each resource usage vector by resourceId_t to speed up conflict
	// checking
	for (unsigned i=0; i < this->resourcesByCycle.size(); i++)
	std::sort(resourcesByCycle[i].begin(), resourcesByCycle[i].end());
	}

	// Add the extra resource usage requirements specified in the delta.
	// Note that a negative value of `numCycles' means one entry for that
	// resource should be deleted for each cycle.
	//
	void InstrRUsage::addUsageDelta(const InstrRUsageDelta &delta) {
	int NC = delta.numCycles;
	sameAsClass = false;

	// resize the resources vector if more cycles are specified
	unsigned maxCycles = this->numCycles;
	maxCycles = std::max(maxCycles, delta.startCycle + abs(NC) - 1);
	if (maxCycles > this->numCycles) {
	this->resourcesByCycle.resize(maxCycles);
	this->numCycles = maxCycles;
	}

	if (NC >= 0)
	for (unsigned c=delta.startCycle, last=c+NC-1; c <= last; c++)
	this->resourcesByCycle[c].push_back(delta.resourceId);
	else
	// Remove the resource from all NC cycles.
	for (unsigned c=delta.startCycle, last=(c-NC)-1; c <= last; c++) {
	// Look for the resource backwards so we remove the last entry
	// for that resource in each cycle.
	std::vector<resourceId_t>& rvec = this->resourcesByCycle[c];
	int r;
	for (r = rvec.size() - 1; r >= 0; r--)
	if (rvec[r] == delta.resourceId) {
	// found last entry for the resource
	rvec.erase(rvec.begin() + r);
	break;
	}
	assert(r >= 0 && "Resource to remove was unused in cycle c!");
	}
	}