third_party/llvm-project/polly/lib/Analysis/ScopGraphPrinter.cpp - cobalt - Git at Google

 //===- GraphPrinter.cpp - Create a DOT output describing the Scop. --------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // Create a DOT output describing the Scop.
 //
 // For each function a dot file is created that shows the control flow graph of
 // the function and highlights the detected Scops.
 //
 //===----------------------------------------------------------------------===//

 #include "polly/LinkAllPasses.h"
 #include "polly/ScopDetection.h"
 #include "polly/Support/ScopLocation.h"
 #include "llvm/Analysis/DOTGraphTraitsPass.h"
 #include "llvm/Analysis/RegionInfo.h"
 #include "llvm/Analysis/RegionIterator.h"
 #include "llvm/Support/CommandLine.h"

 using namespace polly;
 using namespace llvm;
 static cl::opt<std::string>
     ViewFilter("polly-view-only",
                cl::desc("Only view functions that match this pattern"),
                cl::Hidden, cl::init(""), cl::ZeroOrMore);

 static cl::opt<bool> ViewAll("polly-view-all",
                              cl::desc("Also show functions without any scops"),
                              cl::Hidden, cl::init(false), cl::ZeroOrMore);

 namespace llvm {
 template <>
 struct GraphTraits<ScopDetection *> : public GraphTraits<RegionInfo *> {
   static NodeRef getEntryNode(ScopDetection *SD) {
     return GraphTraits<RegionInfo *>::getEntryNode(SD->getRI());
   }
   static nodes_iterator nodes_begin(ScopDetection *SD) {
     return nodes_iterator::begin(getEntryNode(SD));
   }
   static nodes_iterator nodes_end(ScopDetection *SD) {
     return nodes_iterator::end(getEntryNode(SD));
   }
 };

 template <>
 struct GraphTraits<ScopDetectionWrapperPass *>
     : public GraphTraits<ScopDetection *> {
   static NodeRef getEntryNode(ScopDetectionWrapperPass *P) {
     return GraphTraits<ScopDetection *>::getEntryNode(&P->getSD());
   }
   static nodes_iterator nodes_begin(ScopDetectionWrapperPass *P) {
     return nodes_iterator::begin(getEntryNode(P));
   }
   static nodes_iterator nodes_end(ScopDetectionWrapperPass *P) {
     return nodes_iterator::end(getEntryNode(P));
   }
 };

 template <> struct DOTGraphTraits<RegionNode *> : public DefaultDOTGraphTraits {
   DOTGraphTraits(bool isSimple = false) : DefaultDOTGraphTraits(isSimple) {}

   std::string getNodeLabel(RegionNode *Node, RegionNode *Graph) {
     if (!Node->isSubRegion()) {
       BasicBlock *BB = Node->getNodeAs<BasicBlock>();

       if (isSimple())
         return DOTGraphTraits<const Function *>::getSimpleNodeLabel(
             BB, BB->getParent());
       else
         return DOTGraphTraits<const Function *>::getCompleteNodeLabel(
             BB, BB->getParent());
     }

     return "Not implemented";
   }
 };

 template <>
 struct DOTGraphTraits<ScopDetectionWrapperPass *>
     : public DOTGraphTraits<RegionNode *> {
   DOTGraphTraits(bool isSimple = false)
       : DOTGraphTraits<RegionNode *>(isSimple) {}
   static std::string getGraphName(ScopDetectionWrapperPass *SD) {
     return "Scop Graph";
   }

   std::string getEdgeAttributes(RegionNode *srcNode,
                                 GraphTraits<RegionInfo *>::ChildIteratorType CI,
                                 ScopDetectionWrapperPass *P) {
     RegionNode *destNode = *CI;
     auto *SD = &P->getSD();

     if (srcNode->isSubRegion() || destNode->isSubRegion())
       return "";

     // In case of a backedge, do not use it to define the layout of the nodes.
     BasicBlock *srcBB = srcNode->getNodeAs<BasicBlock>();
     BasicBlock *destBB = destNode->getNodeAs<BasicBlock>();

     RegionInfo *RI = SD->getRI();
     Region *R = RI->getRegionFor(destBB);

     while (R && R->getParent())
       if (R->getParent()->getEntry() == destBB)
         R = R->getParent();
       else
         break;

     if (R && R->getEntry() == destBB && R->contains(srcBB))
       return "constraint=false";

     return "";
   }

   std::string getNodeLabel(RegionNode *Node, ScopDetectionWrapperPass *P) {
     return DOTGraphTraits<RegionNode *>::getNodeLabel(
         Node, reinterpret_cast<RegionNode *>(
                   P->getSD().getRI()->getTopLevelRegion()));
   }

   static std::string escapeString(std::string String) {
     std::string Escaped;

     for (const auto &C : String) {
       if (C == '"')
         Escaped += '\\';

       Escaped += C;
     }
     return Escaped;
   }

   // Print the cluster of the subregions. This groups the single basic blocks
   // and adds a different background color for each group.
   static void printRegionCluster(const ScopDetection *SD, const Region *R,
                                  raw_ostream &O, unsigned depth = 0) {
     O.indent(2 * depth) << "subgraph cluster_" << static_cast<const void *>(R)
                         << " {\n";
     unsigned LineBegin, LineEnd;
     std::string FileName;

     getDebugLocation(R, LineBegin, LineEnd, FileName);

     std::string Location;
     if (LineBegin != (unsigned)-1) {
       Location = escapeString(FileName + ":" + std::to_string(LineBegin) + "-" +
                               std::to_string(LineEnd) + "\n");
     }

     std::string ErrorMessage = SD->regionIsInvalidBecause(R);
     ErrorMessage = escapeString(ErrorMessage);
     O.indent(2 * (depth + 1))
         << "label = \"" << Location << ErrorMessage << "\";\n";

     if (SD->isMaxRegionInScop(*R)) {
       O.indent(2 * (depth + 1)) << "style = filled;\n";

       // Set color to green.
       O.indent(2 * (depth + 1)) << "color = 3";
     } else {
       O.indent(2 * (depth + 1)) << "style = solid;\n";

       int color = (R->getDepth() * 2 % 12) + 1;

       // We do not want green again.
       if (color == 3)
         color = 6;

       O.indent(2 * (depth + 1)) << "color = " << color << "\n";
     }

     for (const auto &SubRegion : *R)
       printRegionCluster(SD, SubRegion.get(), O, depth + 1);

     RegionInfo *RI = R->getRegionInfo();

     for (const auto &BB : R->blocks())
       if (RI->getRegionFor(BB) == R)
         O.indent(2 * (depth + 1))
             << "Node"
             << static_cast<void *>(RI->getTopLevelRegion()->getBBNode(BB))
             << ";\n";

     O.indent(2 * depth) << "}\n";
   }
   static void
   addCustomGraphFeatures(const ScopDetectionWrapperPass *SD,
                          GraphWriter<ScopDetectionWrapperPass *> &GW) {
     raw_ostream &O = GW.getOStream();
     O << "\tcolorscheme = \"paired12\"\n";
     printRegionCluster(&SD->getSD(), SD->getSD().getRI()->getTopLevelRegion(),
                        O, 4);
   }
 };
 } // end namespace llvm

 struct ScopViewer
     : public DOTGraphTraitsViewer<ScopDetectionWrapperPass, false> {
   static char ID;
   ScopViewer()
       : DOTGraphTraitsViewer<ScopDetectionWrapperPass, false>("scops", ID) {}
   bool processFunction(Function &F, ScopDetectionWrapperPass &SD) override {
     if (ViewFilter != "" && !F.getName().count(ViewFilter))
       return false;

     if (ViewAll)
       return true;

     // Check that at least one scop was detected.
     return std::distance(SD.getSD().begin(), SD.getSD().end()) > 0;
   }
 };
 char ScopViewer::ID = 0;

 struct ScopOnlyViewer
     : public DOTGraphTraitsViewer<ScopDetectionWrapperPass, true> {
   static char ID;
   ScopOnlyViewer()
       : DOTGraphTraitsViewer<ScopDetectionWrapperPass, true>("scopsonly", ID) {}
 };
 char ScopOnlyViewer::ID = 0;

 struct ScopPrinter
     : public DOTGraphTraitsPrinter<ScopDetectionWrapperPass, false> {
   static char ID;
   ScopPrinter()
       : DOTGraphTraitsPrinter<ScopDetectionWrapperPass, false>("scops", ID) {}
 };
 char ScopPrinter::ID = 0;

 struct ScopOnlyPrinter
     : public DOTGraphTraitsPrinter<ScopDetectionWrapperPass, true> {
   static char ID;
   ScopOnlyPrinter()
       : DOTGraphTraitsPrinter<ScopDetectionWrapperPass, true>("scopsonly", ID) {
   }
 };
 char ScopOnlyPrinter::ID = 0;

 static RegisterPass<ScopViewer> X("view-scops",
                                   "Polly - View Scops of function");

 static RegisterPass<ScopOnlyViewer>
     Y("view-scops-only",
       "Polly - View Scops of function (with no function bodies)");

 static RegisterPass<ScopPrinter> M("dot-scops",
                                    "Polly - Print Scops of function");

 static RegisterPass<ScopOnlyPrinter>
     N("dot-scops-only",
       "Polly - Print Scops of function (with no function bodies)");

 Pass *polly::createDOTViewerPass() { return new ScopViewer(); }

 Pass *polly::createDOTOnlyViewerPass() { return new ScopOnlyViewer(); }

 Pass *polly::createDOTPrinterPass() { return new ScopPrinter(); }

 Pass *polly::createDOTOnlyPrinterPass() { return new ScopOnlyPrinter(); }
	//===- GraphPrinter.cpp - Create a DOT output describing the Scop. --------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// Create a DOT output describing the Scop.
	//
	// For each function a dot file is created that shows the control flow graph of
	// the function and highlights the detected Scops.
	//
	//===----------------------------------------------------------------------===//

	#include "polly/LinkAllPasses.h"
	#include "polly/ScopDetection.h"
	#include "polly/Support/ScopLocation.h"
	#include "llvm/Analysis/DOTGraphTraitsPass.h"
	#include "llvm/Analysis/RegionInfo.h"
	#include "llvm/Analysis/RegionIterator.h"
	#include "llvm/Support/CommandLine.h"

	using namespace polly;
	using namespace llvm;
	static cl::opt<std::string>
	ViewFilter("polly-view-only",
	cl::desc("Only view functions that match this pattern"),
	cl::Hidden, cl::init(""), cl::ZeroOrMore);

	static cl::opt<bool> ViewAll("polly-view-all",
	cl::desc("Also show functions without any scops"),
	cl::Hidden, cl::init(false), cl::ZeroOrMore);

	namespace llvm {
	template <>
	struct GraphTraits<ScopDetection > : public GraphTraits<RegionInfo > {
	static NodeRef getEntryNode(ScopDetection *SD) {
	return GraphTraits<RegionInfo *>::getEntryNode(SD->getRI());
	}
	static nodes_iterator nodes_begin(ScopDetection *SD) {
	return nodes_iterator::begin(getEntryNode(SD));
	}
	static nodes_iterator nodes_end(ScopDetection *SD) {
	return nodes_iterator::end(getEntryNode(SD));
	}
	};

	template <>
	struct GraphTraits<ScopDetectionWrapperPass *>
	: public GraphTraits<ScopDetection *> {
	static NodeRef getEntryNode(ScopDetectionWrapperPass *P) {
	return GraphTraits<ScopDetection *>::getEntryNode(&P->getSD());
	}
	static nodes_iterator nodes_begin(ScopDetectionWrapperPass *P) {
	return nodes_iterator::begin(getEntryNode(P));
	}
	static nodes_iterator nodes_end(ScopDetectionWrapperPass *P) {
	return nodes_iterator::end(getEntryNode(P));
	}
	};

	template <> struct DOTGraphTraits<RegionNode *> : public DefaultDOTGraphTraits {
	DOTGraphTraits(bool isSimple = false) : DefaultDOTGraphTraits(isSimple) {}

	std::string getNodeLabel(RegionNode Node, RegionNode Graph) {
	if (!Node->isSubRegion()) {
	BasicBlock *BB = Node->getNodeAs<BasicBlock>();

	if (isSimple())
	return DOTGraphTraits<const Function *>::getSimpleNodeLabel(
	BB, BB->getParent());
	else
	return DOTGraphTraits<const Function *>::getCompleteNodeLabel(
	BB, BB->getParent());
	}

	return "Not implemented";
	}
	};

	template <>
	struct DOTGraphTraits<ScopDetectionWrapperPass *>
	: public DOTGraphTraits<RegionNode *> {
	DOTGraphTraits(bool isSimple = false)
	: DOTGraphTraits<RegionNode *>(isSimple) {}
	static std::string getGraphName(ScopDetectionWrapperPass *SD) {
	return "Scop Graph";
	}

	std::string getEdgeAttributes(RegionNode *srcNode,
	GraphTraits<RegionInfo *>::ChildIteratorType CI,
	ScopDetectionWrapperPass *P) {
	RegionNode destNode = CI;
	auto *SD = &P->getSD();

	if (srcNode->isSubRegion() \|\| destNode->isSubRegion())
	return "";

	// In case of a backedge, do not use it to define the layout of the nodes.
	BasicBlock *srcBB = srcNode->getNodeAs<BasicBlock>();
	BasicBlock *destBB = destNode->getNodeAs<BasicBlock>();

	RegionInfo *RI = SD->getRI();
	Region *R = RI->getRegionFor(destBB);

	while (R && R->getParent())
	if (R->getParent()->getEntry() == destBB)
	R = R->getParent();
	else
	break;

	if (R && R->getEntry() == destBB && R->contains(srcBB))
	return "constraint=false";

	return "";
	}

	std::string getNodeLabel(RegionNode Node, ScopDetectionWrapperPass P) {
	return DOTGraphTraits<RegionNode *>::getNodeLabel(
	Node, reinterpret_cast<RegionNode *>(
	P->getSD().getRI()->getTopLevelRegion()));
	}

	static std::string escapeString(std::string String) {
	std::string Escaped;

	for (const auto &C : String) {
	if (C == '"')
	Escaped += '\\';

	Escaped += C;
	}
	return Escaped;
	}

	// Print the cluster of the subregions. This groups the single basic blocks
	// and adds a different background color for each group.
	static void printRegionCluster(const ScopDetection SD, const Region R,
	raw_ostream &O, unsigned depth = 0) {
	O.indent(2 * depth) << "subgraph cluster_" << static_cast<const void *>(R)
	<< " {\n";
	unsigned LineBegin, LineEnd;
	std::string FileName;

	getDebugLocation(R, LineBegin, LineEnd, FileName);

	std::string Location;
	if (LineBegin != (unsigned)-1) {
	Location = escapeString(FileName + ":" + std::to_string(LineBegin) + "-" +
	std::to_string(LineEnd) + "\n");
	}

	std::string ErrorMessage = SD->regionIsInvalidBecause(R);
	ErrorMessage = escapeString(ErrorMessage);
	O.indent(2 * (depth + 1))
	<< "label = \"" << Location << ErrorMessage << "\";\n";

	if (SD->isMaxRegionInScop(*R)) {
	O.indent(2 * (depth + 1)) << "style = filled;\n";

	// Set color to green.
	O.indent(2 * (depth + 1)) << "color = 3";
	} else {
	O.indent(2 * (depth + 1)) << "style = solid;\n";

	int color = (R->getDepth() * 2 % 12) + 1;

	// We do not want green again.
	if (color == 3)
	color = 6;

	O.indent(2 * (depth + 1)) << "color = " << color << "\n";
	}

	for (const auto &SubRegion : *R)
	printRegionCluster(SD, SubRegion.get(), O, depth + 1);

	RegionInfo *RI = R->getRegionInfo();

	for (const auto &BB : R->blocks())
	if (RI->getRegionFor(BB) == R)
	O.indent(2 * (depth + 1))
	<< "Node"
	<< static_cast<void *>(RI->getTopLevelRegion()->getBBNode(BB))
	<< ";\n";

	O.indent(2 * depth) << "}\n";
	}
	static void
	addCustomGraphFeatures(const ScopDetectionWrapperPass *SD,
	GraphWriter<ScopDetectionWrapperPass *> &GW) {
	raw_ostream &O = GW.getOStream();
	O << "\tcolorscheme = \"paired12\"\n";
	printRegionCluster(&SD->getSD(), SD->getSD().getRI()->getTopLevelRegion(),
	O, 4);
	}
	};
	} // end namespace llvm

	struct ScopViewer
	: public DOTGraphTraitsViewer<ScopDetectionWrapperPass, false> {
	static char ID;
	ScopViewer()
	: DOTGraphTraitsViewer<ScopDetectionWrapperPass, false>("scops", ID) {}
	bool processFunction(Function &F, ScopDetectionWrapperPass &SD) override {
	if (ViewFilter != "" && !F.getName().count(ViewFilter))
	return false;

	if (ViewAll)
	return true;

	// Check that at least one scop was detected.
	return std::distance(SD.getSD().begin(), SD.getSD().end()) > 0;
	}
	};
	char ScopViewer::ID = 0;

	struct ScopOnlyViewer
	: public DOTGraphTraitsViewer<ScopDetectionWrapperPass, true> {
	static char ID;
	ScopOnlyViewer()
	: DOTGraphTraitsViewer<ScopDetectionWrapperPass, true>("scopsonly", ID) {}
	};
	char ScopOnlyViewer::ID = 0;

	struct ScopPrinter
	: public DOTGraphTraitsPrinter<ScopDetectionWrapperPass, false> {
	static char ID;
	ScopPrinter()
	: DOTGraphTraitsPrinter<ScopDetectionWrapperPass, false>("scops", ID) {}
	};
	char ScopPrinter::ID = 0;

	struct ScopOnlyPrinter
	: public DOTGraphTraitsPrinter<ScopDetectionWrapperPass, true> {
	static char ID;
	ScopOnlyPrinter()
	: DOTGraphTraitsPrinter<ScopDetectionWrapperPass, true>("scopsonly", ID) {
	}
	};
	char ScopOnlyPrinter::ID = 0;

	static RegisterPass<ScopViewer> X("view-scops",
	"Polly - View Scops of function");

	static RegisterPass<ScopOnlyViewer>
	Y("view-scops-only",
	"Polly - View Scops of function (with no function bodies)");

	static RegisterPass<ScopPrinter> M("dot-scops",
	"Polly - Print Scops of function");

	static RegisterPass<ScopOnlyPrinter>
	N("dot-scops-only",
	"Polly - Print Scops of function (with no function bodies)");

	Pass *polly::createDOTViewerPass() { return new ScopViewer(); }

	Pass *polly::createDOTOnlyViewerPass() { return new ScopOnlyViewer(); }

	Pass *polly::createDOTPrinterPass() { return new ScopPrinter(); }

	Pass *polly::createDOTOnlyPrinterPass() { return new ScopOnlyPrinter(); }