//===-- llvm/CodeGen/RenderMachineFunction.cpp - MF->HTML -----s-----------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #define DEBUG_TYPE "rendermf" #include "RenderMachineFunction.h" #include "VirtRegMap.h" #include "llvm/Function.h" #include "llvm/Module.h" #include "llvm/ADT/SmallVector.h" #include "llvm/CodeGen/LiveIntervalAnalysis.h" #include "llvm/CodeGen/MachineFunction.h" #include "llvm/CodeGen/MachineInstr.h" #include "llvm/CodeGen/MachineRegisterInfo.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Support/raw_ostream.h" #include "llvm/Target/TargetMachine.h" #include using namespace llvm; char RenderMachineFunction::ID = 0; INITIALIZE_PASS_BEGIN(RenderMachineFunction, "rendermf", "Render machine functions (and related info) to HTML pages", false, false) INITIALIZE_PASS_DEPENDENCY(SlotIndexes) INITIALIZE_PASS_DEPENDENCY(LiveIntervals) INITIALIZE_PASS_END(RenderMachineFunction, "rendermf", "Render machine functions (and related info) to HTML pages", false, false) static cl::opt outputFileSuffix("rmf-file-suffix", cl::desc("Appended to function name to get output file name " "(default: \".html\")"), cl::init(".html"), cl::Hidden); static cl::opt machineFuncsToRender("rmf-funcs", cl::desc("Coma seperated list of functions to render" ", or \"*\"."), cl::init(""), cl::Hidden); static cl::opt pressureClasses("rmf-classes", cl::desc("Register classes to render pressure for."), cl::init(""), cl::Hidden); static cl::opt showIntervals("rmf-intervals", cl::desc("Live intervals to show alongside code."), cl::init(""), cl::Hidden); static cl::opt filterEmpty("rmf-filter-empty-intervals", cl::desc("Don't display empty intervals."), cl::init(true), cl::Hidden); static cl::opt showEmptyIndexes("rmf-empty-indexes", cl::desc("Render indexes not associated with instructions or " "MBB starts."), cl::init(false), cl::Hidden); static cl::opt useFancyVerticals("rmf-fancy-verts", cl::desc("Use SVG for vertical text."), cl::init(true), cl::Hidden); static cl::opt prettyHTML("rmf-pretty-html", cl::desc("Pretty print HTML. For debugging the renderer only.."), cl::init(false), cl::Hidden); namespace llvm { bool MFRenderingOptions::renderingOptionsProcessed; std::set MFRenderingOptions::mfNamesToRender; bool MFRenderingOptions::renderAllMFs = false; std::set MFRenderingOptions::classNamesToRender; bool MFRenderingOptions::renderAllClasses = false; std::set > MFRenderingOptions::intervalNumsToRender; unsigned MFRenderingOptions::intervalTypesToRender = ExplicitOnly; template void MFRenderingOptions::splitComaSeperatedList(const std::string &s, OutputItr outItr) { std::string::const_iterator curPos = s.begin(); std::string::const_iterator nextComa = std::find(curPos, s.end(), ','); while (nextComa != s.end()) { std::string elem; std::copy(curPos, nextComa, std::back_inserter(elem)); *outItr = elem; ++outItr; curPos = llvm::next(nextComa); nextComa = std::find(curPos, s.end(), ','); } if (curPos != s.end()) { std::string elem; std::copy(curPos, s.end(), std::back_inserter(elem)); *outItr = elem; ++outItr; } } void MFRenderingOptions::processOptions() { if (!renderingOptionsProcessed) { processFuncNames(); processRegClassNames(); processIntervalNumbers(); renderingOptionsProcessed = true; } } void MFRenderingOptions::processFuncNames() { if (machineFuncsToRender == "*") { renderAllMFs = true; } else { splitComaSeperatedList(machineFuncsToRender, std::inserter(mfNamesToRender, mfNamesToRender.begin())); } } void MFRenderingOptions::processRegClassNames() { if (pressureClasses == "*") { renderAllClasses = true; } else { splitComaSeperatedList(pressureClasses, std::inserter(classNamesToRender, classNamesToRender.begin())); } } void MFRenderingOptions::processIntervalNumbers() { std::set intervalRanges; splitComaSeperatedList(showIntervals, std::inserter(intervalRanges, intervalRanges.begin())); std::for_each(intervalRanges.begin(), intervalRanges.end(), processIntervalRange); } void MFRenderingOptions::processIntervalRange( const std::string &intervalRangeStr) { if (intervalRangeStr == "*") { intervalTypesToRender |= All; } else if (intervalRangeStr == "virt-nospills*") { intervalTypesToRender |= VirtNoSpills; } else if (intervalRangeStr == "spills*") { intervalTypesToRender |= VirtSpills; } else if (intervalRangeStr == "virt*") { intervalTypesToRender |= AllVirt; } else if (intervalRangeStr == "phys*") { intervalTypesToRender |= AllPhys; } else { std::istringstream iss(intervalRangeStr); unsigned reg1, reg2; if ((iss >> reg1 >> std::ws)) { if (iss.eof()) { intervalNumsToRender.insert(std::make_pair(reg1, reg1 + 1)); } else { char c; iss >> c; if (c == '-' && (iss >> reg2)) { intervalNumsToRender.insert(std::make_pair(reg1, reg2 + 1)); } else { dbgs() << "Warning: Invalid interval range \"" << intervalRangeStr << "\" in -rmf-intervals. Skipping.\n"; } } } else { dbgs() << "Warning: Invalid interval number \"" << intervalRangeStr << "\" in -rmf-intervals. Skipping.\n"; } } } void MFRenderingOptions::setup(MachineFunction *mf, const TargetRegisterInfo *tri, LiveIntervals *lis, const RenderMachineFunction *rmf) { this->mf = mf; this->tri = tri; this->lis = lis; this->rmf = rmf; clear(); } void MFRenderingOptions::clear() { regClassesTranslatedToCurrentFunction = false; regClassSet.clear(); intervalsTranslatedToCurrentFunction = false; intervalSet.clear(); } void MFRenderingOptions::resetRenderSpecificOptions() { intervalSet.clear(); intervalsTranslatedToCurrentFunction = false; } bool MFRenderingOptions::shouldRenderCurrentMachineFunction() const { processOptions(); return (renderAllMFs || mfNamesToRender.find(mf->getFunction()->getName()) != mfNamesToRender.end()); } const MFRenderingOptions::RegClassSet& MFRenderingOptions::regClasses() const{ translateRegClassNamesToCurrentFunction(); return regClassSet; } const MFRenderingOptions::IntervalSet& MFRenderingOptions::intervals() const { translateIntervalNumbersToCurrentFunction(); return intervalSet; } bool MFRenderingOptions::renderEmptyIndexes() const { return showEmptyIndexes; } bool MFRenderingOptions::fancyVerticals() const { return useFancyVerticals; } void MFRenderingOptions::translateRegClassNamesToCurrentFunction() const { if (!regClassesTranslatedToCurrentFunction) { processOptions(); for (TargetRegisterInfo::regclass_iterator rcItr = tri->regclass_begin(), rcEnd = tri->regclass_end(); rcItr != rcEnd; ++rcItr) { const TargetRegisterClass *trc = *rcItr; if (renderAllClasses || classNamesToRender.find(trc->getName()) != classNamesToRender.end()) { regClassSet.insert(trc); } } regClassesTranslatedToCurrentFunction = true; } } void MFRenderingOptions::translateIntervalNumbersToCurrentFunction() const { if (!intervalsTranslatedToCurrentFunction) { processOptions(); // If we're not just doing explicit then do a copy over all matching // types. if (intervalTypesToRender != ExplicitOnly) { for (LiveIntervals::iterator liItr = lis->begin(), liEnd = lis->end(); liItr != liEnd; ++liItr) { LiveInterval *li = liItr->second; if (filterEmpty && li->empty()) continue; if ((TargetRegisterInfo::isPhysicalRegister(li->reg) && (intervalTypesToRender & AllPhys))) { intervalSet.insert(li); } else if (TargetRegisterInfo::isVirtualRegister(li->reg)) { if (((intervalTypesToRender & VirtNoSpills) && !rmf->isSpill(li)) || ((intervalTypesToRender & VirtSpills) && rmf->isSpill(li))) { intervalSet.insert(li); } } } } // If we need to process the explicit list... if (intervalTypesToRender != All) { for (std::set >::const_iterator regRangeItr = intervalNumsToRender.begin(), regRangeEnd = intervalNumsToRender.end(); regRangeItr != regRangeEnd; ++regRangeItr) { const std::pair &range = *regRangeItr; for (unsigned reg = range.first; reg != range.second; ++reg) { if (lis->hasInterval(reg)) { intervalSet.insert(&lis->getInterval(reg)); } } } } intervalsTranslatedToCurrentFunction = true; } } // ---------- TargetRegisterExtraInformation implementation ---------- TargetRegisterExtraInfo::TargetRegisterExtraInfo() : mapsPopulated(false) { } void TargetRegisterExtraInfo::setup(MachineFunction *mf, MachineRegisterInfo *mri, const TargetRegisterInfo *tri, LiveIntervals *lis) { this->mf = mf; this->mri = mri; this->tri = tri; this->lis = lis; } void TargetRegisterExtraInfo::reset() { if (!mapsPopulated) { initWorst(); //initBounds(); initCapacity(); mapsPopulated = true; } resetPressureAndLiveStates(); } void TargetRegisterExtraInfo::clear() { prWorst.clear(); vrWorst.clear(); capacityMap.clear(); pressureMap.clear(); //liveStatesMap.clear(); mapsPopulated = false; } void TargetRegisterExtraInfo::initWorst() { assert(!mapsPopulated && prWorst.empty() && vrWorst.empty() && "Worst map already initialised?"); // Start with the physical registers. for (unsigned preg = 1; preg < tri->getNumRegs(); ++preg) { WorstMapLine &pregLine = prWorst[preg]; for (TargetRegisterInfo::regclass_iterator rcItr = tri->regclass_begin(), rcEnd = tri->regclass_end(); rcItr != rcEnd; ++rcItr) { const TargetRegisterClass *trc = *rcItr; unsigned numOverlaps = 0; for (TargetRegisterClass::iterator rItr = trc->begin(), rEnd = trc->end(); rItr != rEnd; ++rItr) { unsigned trcPReg = *rItr; if (tri->regsOverlap(preg, trcPReg)) ++numOverlaps; } pregLine[trc] = numOverlaps; } } // Now the register classes. for (TargetRegisterInfo::regclass_iterator rc1Itr = tri->regclass_begin(), rcEnd = tri->regclass_end(); rc1Itr != rcEnd; ++rc1Itr) { const TargetRegisterClass *trc1 = *rc1Itr; WorstMapLine &classLine = vrWorst[trc1]; for (TargetRegisterInfo::regclass_iterator rc2Itr = tri->regclass_begin(); rc2Itr != rcEnd; ++rc2Itr) { const TargetRegisterClass *trc2 = *rc2Itr; unsigned worst = 0; for (TargetRegisterClass::iterator trc1Itr = trc1->begin(), trc1End = trc1->end(); trc1Itr != trc1End; ++trc1Itr) { unsigned trc1Reg = *trc1Itr; unsigned trc1RegWorst = 0; for (TargetRegisterClass::iterator trc2Itr = trc2->begin(), trc2End = trc2->end(); trc2Itr != trc2End; ++trc2Itr) { unsigned trc2Reg = *trc2Itr; if (tri->regsOverlap(trc1Reg, trc2Reg)) ++trc1RegWorst; } if (trc1RegWorst > worst) { worst = trc1RegWorst; } } if (worst != 0) { classLine[trc2] = worst; } } } } unsigned TargetRegisterExtraInfo::getWorst( unsigned reg, const TargetRegisterClass *trc) const { const WorstMapLine *wml = 0; if (TargetRegisterInfo::isPhysicalRegister(reg)) { PRWorstMap::const_iterator prwItr = prWorst.find(reg); assert(prwItr != prWorst.end() && "Missing prWorst entry."); wml = &prwItr->second; } else { const TargetRegisterClass *regTRC = mri->getRegClass(reg); VRWorstMap::const_iterator vrwItr = vrWorst.find(regTRC); assert(vrwItr != vrWorst.end() && "Missing vrWorst entry."); wml = &vrwItr->second; } WorstMapLine::const_iterator wmlItr = wml->find(trc); if (wmlItr == wml->end()) return 0; return wmlItr->second; } void TargetRegisterExtraInfo::initCapacity() { assert(!mapsPopulated && capacityMap.empty() && "Capacity map already initialised?"); for (TargetRegisterInfo::regclass_iterator rcItr = tri->regclass_begin(), rcEnd = tri->regclass_end(); rcItr != rcEnd; ++rcItr) { const TargetRegisterClass *trc = *rcItr; unsigned capacity = std::distance(trc->allocation_order_begin(*mf), trc->allocation_order_end(*mf)); if (capacity != 0) capacityMap[trc] = capacity; } } unsigned TargetRegisterExtraInfo::getCapacity( const TargetRegisterClass *trc) const { CapacityMap::const_iterator cmItr = capacityMap.find(trc); assert(cmItr != capacityMap.end() && "vreg with unallocable register class"); return cmItr->second; } void TargetRegisterExtraInfo::resetPressureAndLiveStates() { pressureMap.clear(); //liveStatesMap.clear(); // Iterate over all slots. // Iterate over all live intervals. for (LiveIntervals::iterator liItr = lis->begin(), liEnd = lis->end(); liItr != liEnd; ++liItr) { LiveInterval *li = liItr->second; const TargetRegisterClass *liTRC; if (TargetRegisterInfo::isPhysicalRegister(li->reg)) continue; liTRC = mri->getRegClass(li->reg); // For all ranges in the current interal. for (LiveInterval::iterator lrItr = li->begin(), lrEnd = li->end(); lrItr != lrEnd; ++lrItr) { LiveRange *lr = &*lrItr; // For all slots in the current range. for (SlotIndex i = lr->start; i != lr->end; i = i.getNextSlot()) { // Record increased pressure at index for all overlapping classes. for (TargetRegisterInfo::regclass_iterator rcItr = tri->regclass_begin(), rcEnd = tri->regclass_end(); rcItr != rcEnd; ++rcItr) { const TargetRegisterClass *trc = *rcItr; if (trc->allocation_order_begin(*mf) == trc->allocation_order_end(*mf)) continue; unsigned worstAtI = getWorst(li->reg, trc); if (worstAtI != 0) { pressureMap[i][trc] += worstAtI; } } } } } } unsigned TargetRegisterExtraInfo::getPressureAtSlot( const TargetRegisterClass *trc, SlotIndex i) const { PressureMap::const_iterator pmItr = pressureMap.find(i); if (pmItr == pressureMap.end()) return 0; const PressureMapLine &pmLine = pmItr->second; PressureMapLine::const_iterator pmlItr = pmLine.find(trc); if (pmlItr == pmLine.end()) return 0; return pmlItr->second; } bool TargetRegisterExtraInfo::classOverCapacityAtSlot( const TargetRegisterClass *trc, SlotIndex i) const { return (getPressureAtSlot(trc, i) > getCapacity(trc)); } // ---------- MachineFunctionRenderer implementation ---------- void RenderMachineFunction::Spacer::print(raw_ostream &os) const { if (!prettyHTML) return; for (unsigned i = 0; i < ns; ++i) { os << " "; } } RenderMachineFunction::Spacer RenderMachineFunction::s(unsigned ns) const { return Spacer(ns); } raw_ostream& operator<<(raw_ostream &os, const RenderMachineFunction::Spacer &s) { s.print(os); return os; } template std::string RenderMachineFunction::escapeChars(Iterator sBegin, Iterator sEnd) const { std::string r; for (Iterator sItr = sBegin; sItr != sEnd; ++sItr) { char c = *sItr; switch (c) { case '<': r.append("<"); break; case '>': r.append(">"); break; case '&': r.append("&"); break; case ' ': r.append(" "); break; case '\"': r.append("""); break; default: r.push_back(c); break; } } return r; } RenderMachineFunction::LiveState RenderMachineFunction::getLiveStateAt(const LiveInterval *li, SlotIndex i) const { const MachineInstr *mi = sis->getInstructionFromIndex(i); // For uses/defs recorded use/def indexes override current liveness and // instruction operands (Only for the interval which records the indexes). if (i.isUse() || i.isDef()) { UseDefs::const_iterator udItr = useDefs.find(li); if (udItr != useDefs.end()) { const SlotSet &slotSet = udItr->second; if (slotSet.count(i)) { if (i.isUse()) { return Used; } // else return Defined; } } } // If the slot is a load/store, or there's no info in the use/def set then // use liveness and instruction operand info. if (li->liveAt(i)) { if (mi == 0) { if (vrm == 0 || (vrm->getStackSlot(li->reg) == VirtRegMap::NO_STACK_SLOT)) { return AliveReg; } else { return AliveStack; } } else { if (i.isDef() && mi->definesRegister(li->reg, tri)) { return Defined; } else if (i.isUse() && mi->readsRegister(li->reg)) { return Used; } else { if (vrm == 0 || (vrm->getStackSlot(li->reg) == VirtRegMap::NO_STACK_SLOT)) { return AliveReg; } else { return AliveStack; } } } } return Dead; } RenderMachineFunction::PressureState RenderMachineFunction::getPressureStateAt(const TargetRegisterClass *trc, SlotIndex i) const { if (trei.getPressureAtSlot(trc, i) == 0) { return Zero; } else if (trei.classOverCapacityAtSlot(trc, i)){ return High; } return Low; } /// \brief Render a machine instruction. void RenderMachineFunction::renderMachineInstr(raw_ostream &os, const MachineInstr *mi) const { std::string s; raw_string_ostream oss(s); oss << *mi; os << escapeChars(oss.str()); } template void RenderMachineFunction::renderVertical(const Spacer &indent, raw_ostream &os, const T &t) const { if (ro.fancyVerticals()) { os << indent << "\n" << indent + s(6) << "" << t << "\n" << indent + s(4) << "\">\n" << indent << "\n"; } else { std::ostringstream oss; oss << t; std::string tStr(oss.str()); os << indent; for (std::string::iterator tStrItr = tStr.begin(), tStrEnd = tStr.end(); tStrItr != tStrEnd; ++tStrItr) { os << *tStrItr << "
"; } os << "\n"; } } void RenderMachineFunction::insertCSS(const Spacer &indent, raw_ostream &os) const { os << indent << "\n"; } void RenderMachineFunction::renderFunctionSummary( const Spacer &indent, raw_ostream &os, const char * const renderContextStr) const { os << indent << "

Function: " << mf->getFunction()->getName() << "

\n" << indent << "

Rendering context: " << renderContextStr << "

\n"; } void RenderMachineFunction::renderPressureTableLegend( const Spacer &indent, raw_ostream &os) const { os << indent << "

Rendering Pressure Legend:

\n" << indent << "\n" << indent + s(2) << "\n" << indent + s(4) << "" "\n" << indent + s(2) << "\n" << indent + s(2) << "\n" << indent + s(4) << "" "" "\n" << indent + s(2) << "\n" << indent + s(2) << "\n" << indent + s(4) << "" "" "\n" << indent + s(2) << "\n" << indent + s(2) << "\n" << indent + s(4) << "" "" "\n" << indent + s(2) << "\n" << indent << "
PressureDescriptionAppearance
No PressureNo physical registers of this class requested.  
Low PressureSufficient physical registers to meet demand.  
High PressurePotentially insufficient physical registers to meet demand.  
\n"; } template void RenderMachineFunction::renderCellsWithRLE( const Spacer &indent, raw_ostream &os, const std::pair &rleAccumulator, const std::map &cellTypeStrs) const { if (rleAccumulator.second == 0) return; typename std::map::const_iterator ctsItr = cellTypeStrs.find(rleAccumulator.first); assert(ctsItr != cellTypeStrs.end() && "No string for given cell type."); os << indent + s(4) << "second << "\""; if (rleAccumulator.second > 1) os << " colspan=" << rleAccumulator.second; os << ">\n"; } void RenderMachineFunction::renderCodeTablePlusPI(const Spacer &indent, raw_ostream &os) const { std::map lsStrs; lsStrs[Dead] = "l-n"; lsStrs[Defined] = "l-d"; lsStrs[Used] = "l-u"; lsStrs[AliveReg] = "l-r"; lsStrs[AliveStack] = "l-s"; std::map psStrs; psStrs[Zero] = "p-z"; psStrs[Low] = "p-l"; psStrs[High] = "p-h"; // Open the table... os << indent << "\n" << indent + s(2) << "\n"; // Render the header row... os << indent + s(4) << "\n" << indent + s(4) << "\n"; // Render class names if necessary... if (!ro.regClasses().empty()) { for (MFRenderingOptions::RegClassSet::const_iterator rcItr = ro.regClasses().begin(), rcEnd = ro.regClasses().end(); rcItr != rcEnd; ++rcItr) { const TargetRegisterClass *trc = *rcItr; os << indent + s(4) << "\n"; } } // FIXME: Is there a nicer way to insert space between columns in HTML? if (!ro.regClasses().empty() && !ro.intervals().empty()) os << indent + s(4) << "\n"; // Render interval numbers if necessary... if (!ro.intervals().empty()) { for (MFRenderingOptions::IntervalSet::const_iterator liItr = ro.intervals().begin(), liEnd = ro.intervals().end(); liItr != liEnd; ++liItr) { const LiveInterval *li = *liItr; os << indent + s(4) << "\n"; } } os << indent + s(2) << "\n"; // End header row, start with the data rows... MachineInstr *mi = 0; // Data rows: for (SlotIndex i = sis->getZeroIndex(); i != sis->getLastIndex(); i = i.getNextSlot()) { // Render the slot column. os << indent + s(2) << "\n"; // Render the code column. if (i.isLoad()) { MachineBasicBlock *mbb = sis->getMBBFromIndex(i); mi = sis->getInstructionFromIndex(i); if (i == sis->getMBBStartIdx(mbb) || mi != 0 || ro.renderEmptyIndexes()) { os << indent + s(4) << "\n" << indent + s(4) << "\n"; } else { i = i.getStoreIndex(); // <- Will be incremented to the next index. continue; } } // Render the class columns. if (!ro.regClasses().empty()) { std::pair psRLEAccumulator(Zero, 0); for (MFRenderingOptions::RegClassSet::const_iterator rcItr = ro.regClasses().begin(), rcEnd = ro.regClasses().end(); rcItr != rcEnd; ++rcItr) { const TargetRegisterClass *trc = *rcItr; PressureState newPressure = getPressureStateAt(trc, i); if (newPressure == psRLEAccumulator.first) { ++psRLEAccumulator.second; } else { renderCellsWithRLE(indent + s(4), os, psRLEAccumulator, psStrs); psRLEAccumulator.first = newPressure; psRLEAccumulator.second = 1; } } renderCellsWithRLE(indent + s(4), os, psRLEAccumulator, psStrs); } // FIXME: Is there a nicer way to insert space between columns in HTML? if (!ro.regClasses().empty() && !ro.intervals().empty()) os << indent + s(4) << "\n"; if (!ro.intervals().empty()) { std::pair lsRLEAccumulator(Dead, 0); for (MFRenderingOptions::IntervalSet::const_iterator liItr = ro.intervals().begin(), liEnd = ro.intervals().end(); liItr != liEnd; ++liItr) { const LiveInterval *li = *liItr; LiveState newLiveness = getLiveStateAt(li, i); if (newLiveness == lsRLEAccumulator.first) { ++lsRLEAccumulator.second; } else { renderCellsWithRLE(indent + s(4), os, lsRLEAccumulator, lsStrs); lsRLEAccumulator.first = newLiveness; lsRLEAccumulator.second = 1; } } renderCellsWithRLE(indent + s(4), os, lsRLEAccumulator, lsStrs); } os << indent + s(2) << "\n"; } os << indent << "
indexinstr\n"; renderVertical(indent + s(6), os, trc->getName()); os << indent + s(4) << "  \n"; renderVertical(indent + s(6), os, li->reg); os << indent + s(4) << "
" << i << " \n"; if (i == sis->getMBBStartIdx(mbb)) { os << indent + s(6) << "BB#" << mbb->getNumber() << ": \n"; } else if (mi != 0) { os << indent + s(6) << "  "; renderMachineInstr(os, mi); } else { // Empty interval - leave blank. } os << indent + s(4) << "
\n"; if (!ro.regClasses().empty()) renderPressureTableLegend(indent, os); } void RenderMachineFunction::renderFunctionPage( raw_ostream &os, const char * const renderContextStr) const { os << "\n" << s(2) << "\n" << s(4) << "" << fqn << "\n"; insertCSS(s(4), os); os << s(2) << "\n" << s(2) << "\n"; renderFunctionSummary(s(4), os, renderContextStr); os << s(4) << "


\n"; //renderLiveIntervalInfoTable(" ", os); os << s(4) << "


\n"; renderCodeTablePlusPI(s(4), os); os << s(2) << "\n" << "\n"; } void RenderMachineFunction::getAnalysisUsage(AnalysisUsage &au) const { au.addRequired(); au.addRequired(); au.setPreservesAll(); MachineFunctionPass::getAnalysisUsage(au); } bool RenderMachineFunction::runOnMachineFunction(MachineFunction &fn) { mf = &fn; mri = &mf->getRegInfo(); tri = mf->getTarget().getRegisterInfo(); lis = &getAnalysis(); sis = &getAnalysis(); trei.setup(mf, mri, tri, lis); ro.setup(mf, tri, lis, this); spillIntervals.clear(); spillFor.clear(); useDefs.clear(); fqn = mf->getFunction()->getParent()->getModuleIdentifier() + "." + mf->getFunction()->getName().str(); return false; } void RenderMachineFunction::releaseMemory() { trei.clear(); ro.clear(); spillIntervals.clear(); spillFor.clear(); useDefs.clear(); } void RenderMachineFunction::rememberUseDefs(const LiveInterval *li) { if (!ro.shouldRenderCurrentMachineFunction()) return; for (MachineRegisterInfo::reg_iterator rItr = mri->reg_begin(li->reg), rEnd = mri->reg_end(); rItr != rEnd; ++rItr) { const MachineInstr *mi = &*rItr; if (mi->readsRegister(li->reg)) { useDefs[li].insert(lis->getInstructionIndex(mi).getUseIndex()); } if (mi->definesRegister(li->reg)) { useDefs[li].insert(lis->getInstructionIndex(mi).getDefIndex()); } } } void RenderMachineFunction::rememberSpills( const LiveInterval *li, const std::vector &spills) { if (!ro.shouldRenderCurrentMachineFunction()) return; for (std::vector::const_iterator siItr = spills.begin(), siEnd = spills.end(); siItr != siEnd; ++siItr) { const LiveInterval *spill = *siItr; spillIntervals[li].insert(spill); spillFor[spill] = li; } } bool RenderMachineFunction::isSpill(const LiveInterval *li) const { SpillForMap::const_iterator sfItr = spillFor.find(li); if (sfItr == spillFor.end()) return false; return true; } void RenderMachineFunction::renderMachineFunction( const char *renderContextStr, const VirtRegMap *vrm, const char *renderSuffix) { if (!ro.shouldRenderCurrentMachineFunction()) return; this->vrm = vrm; trei.reset(); std::string rpFileName(mf->getFunction()->getName().str() + (renderSuffix ? renderSuffix : "") + outputFileSuffix); std::string errMsg; raw_fd_ostream outFile(rpFileName.c_str(), errMsg, raw_fd_ostream::F_Binary); renderFunctionPage(outFile, renderContextStr); ro.resetRenderSpecificOptions(); } std::string RenderMachineFunction::escapeChars(const std::string &s) const { return escapeChars(s.begin(), s.end()); } }