llvm/tools/llvm-profgen/PseudoProbe.cpp - llvm-project - Git at Google

 //===--- PseudoProbe.cpp - Pseudo probe decoding utilities  ------*- C++-*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "PseudoProbe.h"
 #include "ErrorHandling.h"
 #include "llvm/Support/Endian.h"
 #include "llvm/Support/LEB128.h"
 #include "llvm/Support/raw_ostream.h"
 #include <limits>
 #include <memory>

 using namespace llvm;
 using namespace sampleprof;
 using namespace support;

 namespace llvm {
 namespace sampleprof {

 static StringRef getProbeFNameForGUID(const GUIDProbeFunctionMap &GUID2FuncMAP,
                                       uint64_t GUID) {
   auto It = GUID2FuncMAP.find(GUID);
   assert(It != GUID2FuncMAP.end() &&
          "Probe function must exist for a valid GUID");
   return It->second.FuncName;
 }

 void PseudoProbeFuncDesc::print(raw_ostream &OS) {
   OS << "GUID: " << FuncGUID << " Name: " << FuncName << "\n";
   OS << "Hash: " << FuncHash << "\n";
 }

 void PseudoProbe::getInlineContext(SmallVectorImpl<std::string> &ContextStack,
                                    const GUIDProbeFunctionMap &GUID2FuncMAP,
                                    bool ShowName) const {
   uint32_t Begin = ContextStack.size();
   PseudoProbeInlineTree *Cur = InlineTree;
   // It will add the string of each node's inline site during iteration.
   // Note that it won't include the probe's belonging function(leaf location)
   while (Cur->hasInlineSite()) {
     std::string ContextStr;
     if (ShowName) {
       StringRef FuncName =
           getProbeFNameForGUID(GUID2FuncMAP, std::get<0>(Cur->ISite));
       ContextStr += FuncName.str();
     } else {
       ContextStr += Twine(std::get<0>(Cur->ISite)).str();
     }
     ContextStr += ":";
     ContextStr += Twine(std::get<1>(Cur->ISite)).str();
     ContextStack.emplace_back(ContextStr);
     Cur = Cur->Parent;
   }
   // Make the ContextStack in caller-callee order
   std::reverse(ContextStack.begin() + Begin, ContextStack.end());
 }

 std::string
 PseudoProbe::getInlineContextStr(const GUIDProbeFunctionMap &GUID2FuncMAP,
                                  bool ShowName) const {
   std::ostringstream OContextStr;
   SmallVector<std::string, 16> ContextStack;
   getInlineContext(ContextStack, GUID2FuncMAP, ShowName);
   for (auto &CxtStr : ContextStack) {
     if (OContextStr.str().size())
       OContextStr << " @ ";
     OContextStr << CxtStr;
   }
   return OContextStr.str();
 }

 static const char *PseudoProbeTypeStr[3] = {"Block", "IndirectCall",
                                             "DirectCall"};

 void PseudoProbe::print(raw_ostream &OS,
                         const GUIDProbeFunctionMap &GUID2FuncMAP,
                         bool ShowName) {
   OS << "FUNC: ";
   if (ShowName) {
     StringRef FuncName = getProbeFNameForGUID(GUID2FuncMAP, GUID);
     OS << FuncName.str() << " ";
   } else {
     OS << GUID << " ";
   }
   OS << "Index: " << Index << "  ";
   OS << "Type: " << PseudoProbeTypeStr[static_cast<uint8_t>(Type)] << "  ";
   if (isDangling()) {
     OS << "Dangling  ";
   }
   if (isTailCall()) {
     OS << "TailCall  ";
   }
   std::string InlineContextStr = getInlineContextStr(GUID2FuncMAP, ShowName);
   if (InlineContextStr.size()) {
     OS << "Inlined: @ ";
     OS << InlineContextStr;
   }
   OS << "\n";
 }

 template <typename T> T PseudoProbeDecoder::readUnencodedNumber() {
   if (Data + sizeof(T) > End) {
     exitWithError("Decode unencoded number error in " + SectionName +
                   " section");
   }
   T Val = endian::readNext<T, little, unaligned>(Data);
   return Val;
 }

 template <typename T> T PseudoProbeDecoder::readUnsignedNumber() {
   unsigned NumBytesRead = 0;
   uint64_t Val = decodeULEB128(Data, &NumBytesRead);
   if (Val > std::numeric_limits<T>::max() || (Data + NumBytesRead > End)) {
     exitWithError("Decode number error in " + SectionName + " section");
   }
   Data += NumBytesRead;
   return static_cast<T>(Val);
 }

 template <typename T> T PseudoProbeDecoder::readSignedNumber() {
   unsigned NumBytesRead = 0;
   int64_t Val = decodeSLEB128(Data, &NumBytesRead);
   if (Val > std::numeric_limits<T>::max() || (Data + NumBytesRead > End)) {
     exitWithError("Decode number error in " + SectionName + " section");
   }
   Data += NumBytesRead;
   return static_cast<T>(Val);
 }

 StringRef PseudoProbeDecoder::readString(uint32_t Size) {
   StringRef Str(reinterpret_cast<const char *>(Data), Size);
   if (Data + Size > End) {
     exitWithError("Decode string error in " + SectionName + " section");
   }
   Data += Size;
   return Str;
 }

 void PseudoProbeDecoder::buildGUID2FuncDescMap(const uint8_t *Start,
                                                std::size_t Size) {
   // The pseudo_probe_desc section has a format like:
   // .section .pseudo_probe_desc,"",@progbits
   // .quad -5182264717993193164   // GUID
   // .quad 4294967295             // Hash
   // .uleb 3                      // Name size
   // .ascii "foo"                 // Name
   // .quad -2624081020897602054
   // .quad 174696971957
   // .uleb 34
   // .ascii "main"
 #ifndef NDEBUG
   SectionName = "pseudo_probe_desc";
 #endif
   Data = Start;
   End = Data + Size;

   while (Data < End) {
     uint64_t GUID = readUnencodedNumber<uint64_t>();
     uint64_t Hash = readUnencodedNumber<uint64_t>();
     uint32_t NameSize = readUnsignedNumber<uint32_t>();
     StringRef Name = readString(NameSize);

     // Initialize PseudoProbeFuncDesc and populate it into GUID2FuncDescMap
     GUID2FuncDescMap.emplace(GUID, PseudoProbeFuncDesc(GUID, Hash, Name));
   }
   assert(Data == End && "Have unprocessed data in pseudo_probe_desc section");
 }

 void PseudoProbeDecoder::buildAddress2ProbeMap(const uint8_t *Start,
                                                std::size_t Size) {
   // The pseudo_probe section encodes an inline forest and each tree has a
   // format like:
   //  FUNCTION BODY (one for each uninlined function present in the text
   //  section)
   //     GUID (uint64)
   //         GUID of the function
   //     NPROBES (ULEB128)
   //         Number of probes originating from this function.
   //     NUM_INLINED_FUNCTIONS (ULEB128)
   //         Number of callees inlined into this function, aka number of
   //         first-level inlinees
   //     PROBE RECORDS
   //         A list of NPROBES entries. Each entry contains:
   //           INDEX (ULEB128)
   //           TYPE (uint4)
   //             0 - block probe, 1 - indirect call, 2 - direct call
   //           ATTRIBUTE (uint3)
   //             1 - tail call, 2 - dangling
   //           ADDRESS_TYPE (uint1)
   //             0 - code address, 1 - address delta
   //           CODE_ADDRESS (uint64 or ULEB128)
   //             code address or address delta, depending on Flag
   //     INLINED FUNCTION RECORDS
   //         A list of NUM_INLINED_FUNCTIONS entries describing each of the
   //         inlined callees.  Each record contains:
   //           INLINE SITE
   //             GUID of the inlinee (uint64)
   //             Index of the callsite probe (ULEB128)
   //           FUNCTION BODY
   //             A FUNCTION BODY entry describing the inlined function.
 #ifndef NDEBUG
   SectionName = "pseudo_probe";
 #endif
   Data = Start;
   End = Data + Size;

   PseudoProbeInlineTree *Root = &DummyInlineRoot;
   PseudoProbeInlineTree *Cur = &DummyInlineRoot;
   uint64_t LastAddr = 0;
   uint32_t Index = 0;
   // A DFS-based decoding
   while (Data < End) {
     // Read inline site for inlinees
     if (Root != Cur) {
       Index = readUnsignedNumber<uint32_t>();
     }
     // Switch/add to a new tree node(inlinee)
     Cur = Cur->getOrAddNode(std::make_tuple(Cur->GUID, Index));
     // Read guid
     Cur->GUID = readUnencodedNumber<uint64_t>();
     // Read number of probes in the current node.
     uint32_t NodeCount = readUnsignedNumber<uint32_t>();
     // Read number of direct inlinees
     Cur->ChildrenToProcess = readUnsignedNumber<uint32_t>();
     // Read all probes in this node
     for (std::size_t I = 0; I < NodeCount; I++) {
       // Read index
       uint32_t Index = readUnsignedNumber<uint32_t>();
       // Read type | flag.
       uint8_t Value = readUnencodedNumber<uint8_t>();
       uint8_t Kind = Value & 0xf;
       uint8_t Attr = (Value & 0x70) >> 4;
       // Read address
       uint64_t Addr = 0;
       if (Value & 0x80) {
         int64_t Offset = readSignedNumber<int64_t>();
         Addr = LastAddr + Offset;
       } else {
         Addr = readUnencodedNumber<int64_t>();
       }
       // Populate Address2ProbesMap
       std::vector<PseudoProbe> &ProbeVec = Address2ProbesMap[Addr];
       ProbeVec.emplace_back(Addr, Cur->GUID, Index, PseudoProbeType(Kind), Attr,
                             Cur);
       Cur->addProbes(&ProbeVec.back());
       LastAddr = Addr;
     }

     // Look for the parent for the next node by subtracting the current
     // node count from tree counts along the parent chain. The first node
     // in the chain that has a non-zero tree count is the target.
     while (Cur != Root) {
       if (Cur->ChildrenToProcess == 0) {
         Cur = Cur->Parent;
         if (Cur != Root) {
           assert(Cur->ChildrenToProcess > 0 &&
                  "Should have some unprocessed nodes");
           Cur->ChildrenToProcess -= 1;
         }
       } else {
         break;
       }
     }
   }

   assert(Data == End && "Have unprocessed data in pseudo_probe section");
   assert(Cur == Root &&
          " Cur should point to root when the forest is fully built up");
 }

 void PseudoProbeDecoder::printGUID2FuncDescMap(raw_ostream &OS) {
   OS << "Pseudo Probe Desc:\n";
   // Make the output deterministic
   std::map<uint64_t, PseudoProbeFuncDesc> OrderedMap(GUID2FuncDescMap.begin(),
                                                      GUID2FuncDescMap.end());
   for (auto &I : OrderedMap) {
     I.second.print(OS);
   }
 }

 void PseudoProbeDecoder::printProbeForAddress(raw_ostream &OS,
                                               uint64_t Address) {
   auto It = Address2ProbesMap.find(Address);
   if (It != Address2ProbesMap.end()) {
     for (auto &Probe : It->second) {
       OS << " [Probe]:\t";
       Probe.print(OS, GUID2FuncDescMap, true);
     }
   }
 }

 const PseudoProbe *
 PseudoProbeDecoder::getCallProbeForAddr(uint64_t Address) const {
   auto It = Address2ProbesMap.find(Address);
   if (It == Address2ProbesMap.end())
     return nullptr;
   const std::vector<PseudoProbe> &Probes = It->second;

   const PseudoProbe *CallProbe = nullptr;
   for (const auto &Probe : Probes) {
     if (Probe.isCall()) {
       assert(!CallProbe &&
              "There should be only one call probe corresponding to address "
              "which is a callsite.");
       CallProbe = &Probe;
     }
   }
   return CallProbe;
 }

 const PseudoProbeFuncDesc *
 PseudoProbeDecoder::getFuncDescForGUID(uint64_t GUID) const {
   auto It = GUID2FuncDescMap.find(GUID);
   assert(It != GUID2FuncDescMap.end() && "Function descriptor doesn't exist");
   return &It->second;
 }

 void PseudoProbeDecoder::getInlineContextForProbe(
     const PseudoProbe *Probe, SmallVectorImpl<std::string> &InlineContextStack,
     bool IncludeLeaf) const {
   Probe->getInlineContext(InlineContextStack, GUID2FuncDescMap, true);
   if (!IncludeLeaf)
     return;
   // Note that the context from probe doesn't include leaf frame,
   // hence we need to retrieve and prepend leaf if requested.
   const auto *FuncDesc = getFuncDescForGUID(Probe->GUID);
   InlineContextStack.emplace_back(FuncDesc->FuncName + ":" +
                                   Twine(Probe->Index).str());
 }

 const PseudoProbeFuncDesc *
 PseudoProbeDecoder::getInlinerDescForProbe(const PseudoProbe *Probe) const {
   PseudoProbeInlineTree *InlinerNode = Probe->InlineTree;
   if (!InlinerNode->hasInlineSite())
     return nullptr;
   return getFuncDescForGUID(std::get<0>(InlinerNode->ISite));
 }

 } // end namespace sampleprof
 } // end namespace llvm
	//===--- PseudoProbe.cpp - Pseudo probe decoding utilities ------- C++--===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "PseudoProbe.h"
	#include "ErrorHandling.h"
	#include "llvm/Support/Endian.h"
	#include "llvm/Support/LEB128.h"
	#include "llvm/Support/raw_ostream.h"
	#include <limits>
	#include <memory>

	using namespace llvm;
	using namespace sampleprof;
	using namespace support;

	namespace llvm {
	namespace sampleprof {

	static StringRef getProbeFNameForGUID(const GUIDProbeFunctionMap &GUID2FuncMAP,
	uint64_t GUID) {
	auto It = GUID2FuncMAP.find(GUID);
	assert(It != GUID2FuncMAP.end() &&
	"Probe function must exist for a valid GUID");
	return It->second.FuncName;
	}

	void PseudoProbeFuncDesc::print(raw_ostream &OS) {
	OS << "GUID: " << FuncGUID << " Name: " << FuncName << "\n";
	OS << "Hash: " << FuncHash << "\n";
	}

	void PseudoProbe::getInlineContext(SmallVectorImpl<std::string> &ContextStack,
	const GUIDProbeFunctionMap &GUID2FuncMAP,
	bool ShowName) const {
	uint32_t Begin = ContextStack.size();
	PseudoProbeInlineTree *Cur = InlineTree;
	// It will add the string of each node's inline site during iteration.
	// Note that it won't include the probe's belonging function(leaf location)
	while (Cur->hasInlineSite()) {
	std::string ContextStr;
	if (ShowName) {
	StringRef FuncName =
	getProbeFNameForGUID(GUID2FuncMAP, std::get<0>(Cur->ISite));
	ContextStr += FuncName.str();
	} else {
	ContextStr += Twine(std::get<0>(Cur->ISite)).str();
	}
	ContextStr += ":";
	ContextStr += Twine(std::get<1>(Cur->ISite)).str();
	ContextStack.emplace_back(ContextStr);
	Cur = Cur->Parent;
	}
	// Make the ContextStack in caller-callee order
	std::reverse(ContextStack.begin() + Begin, ContextStack.end());
	}

	std::string
	PseudoProbe::getInlineContextStr(const GUIDProbeFunctionMap &GUID2FuncMAP,
	bool ShowName) const {
	std::ostringstream OContextStr;
	SmallVector<std::string, 16> ContextStack;
	getInlineContext(ContextStack, GUID2FuncMAP, ShowName);
	for (auto &CxtStr : ContextStack) {
	if (OContextStr.str().size())
	OContextStr << " @ ";
	OContextStr << CxtStr;
	}
	return OContextStr.str();
	}

	static const char *PseudoProbeTypeStr[3] = {"Block", "IndirectCall",
	"DirectCall"};

	void PseudoProbe::print(raw_ostream &OS,
	const GUIDProbeFunctionMap &GUID2FuncMAP,
	bool ShowName) {
	OS << "FUNC: ";
	if (ShowName) {
	StringRef FuncName = getProbeFNameForGUID(GUID2FuncMAP, GUID);
	OS << FuncName.str() << " ";
	} else {
	OS << GUID << " ";
	}
	OS << "Index: " << Index << " ";
	OS << "Type: " << PseudoProbeTypeStr[static_cast<uint8_t>(Type)] << " ";
	if (isDangling()) {
	OS << "Dangling ";
	}
	if (isTailCall()) {
	OS << "TailCall ";
	}
	std::string InlineContextStr = getInlineContextStr(GUID2FuncMAP, ShowName);
	if (InlineContextStr.size()) {
	OS << "Inlined: @ ";
	OS << InlineContextStr;
	}
	OS << "\n";
	}

	template <typename T> T PseudoProbeDecoder::readUnencodedNumber() {
	if (Data + sizeof(T) > End) {
	exitWithError("Decode unencoded number error in " + SectionName +
	" section");
	}
	T Val = endian::readNext<T, little, unaligned>(Data);
	return Val;
	}

	template <typename T> T PseudoProbeDecoder::readUnsignedNumber() {
	unsigned NumBytesRead = 0;
	uint64_t Val = decodeULEB128(Data, &NumBytesRead);
	if (Val > std::numeric_limits<T>::max() \|\| (Data + NumBytesRead > End)) {
	exitWithError("Decode number error in " + SectionName + " section");
	}
	Data += NumBytesRead;
	return static_cast<T>(Val);
	}

	template <typename T> T PseudoProbeDecoder::readSignedNumber() {
	unsigned NumBytesRead = 0;
	int64_t Val = decodeSLEB128(Data, &NumBytesRead);
	if (Val > std::numeric_limits<T>::max() \|\| (Data + NumBytesRead > End)) {
	exitWithError("Decode number error in " + SectionName + " section");
	}
	Data += NumBytesRead;
	return static_cast<T>(Val);
	}

	StringRef PseudoProbeDecoder::readString(uint32_t Size) {
	StringRef Str(reinterpret_cast<const char *>(Data), Size);
	if (Data + Size > End) {
	exitWithError("Decode string error in " + SectionName + " section");
	}
	Data += Size;
	return Str;
	}

	void PseudoProbeDecoder::buildGUID2FuncDescMap(const uint8_t *Start,
	std::size_t Size) {
	// The pseudo_probe_desc section has a format like:
	// .section .pseudo_probe_desc,"",@progbits
	// .quad -5182264717993193164 // GUID
	// .quad 4294967295 // Hash
	// .uleb 3 // Name size
	// .ascii "foo" // Name
	// .quad -2624081020897602054
	// .quad 174696971957
	// .uleb 34
	// .ascii "main"
	#ifndef NDEBUG
	SectionName = "pseudo_probe_desc";
	#endif
	Data = Start;
	End = Data + Size;

	while (Data < End) {
	uint64_t GUID = readUnencodedNumber<uint64_t>();
	uint64_t Hash = readUnencodedNumber<uint64_t>();
	uint32_t NameSize = readUnsignedNumber<uint32_t>();
	StringRef Name = readString(NameSize);

	// Initialize PseudoProbeFuncDesc and populate it into GUID2FuncDescMap
	GUID2FuncDescMap.emplace(GUID, PseudoProbeFuncDesc(GUID, Hash, Name));
	}
	assert(Data == End && "Have unprocessed data in pseudo_probe_desc section");
	}

	void PseudoProbeDecoder::buildAddress2ProbeMap(const uint8_t *Start,
	std::size_t Size) {
	// The pseudo_probe section encodes an inline forest and each tree has a
	// format like:
	// FUNCTION BODY (one for each uninlined function present in the text
	// section)
	// GUID (uint64)
	// GUID of the function
	// NPROBES (ULEB128)
	// Number of probes originating from this function.
	// NUM_INLINED_FUNCTIONS (ULEB128)
	// Number of callees inlined into this function, aka number of
	// first-level inlinees
	// PROBE RECORDS
	// A list of NPROBES entries. Each entry contains:
	// INDEX (ULEB128)
	// TYPE (uint4)
	// 0 - block probe, 1 - indirect call, 2 - direct call
	// ATTRIBUTE (uint3)
	// 1 - tail call, 2 - dangling
	// ADDRESS_TYPE (uint1)
	// 0 - code address, 1 - address delta
	// CODE_ADDRESS (uint64 or ULEB128)
	// code address or address delta, depending on Flag
	// INLINED FUNCTION RECORDS
	// A list of NUM_INLINED_FUNCTIONS entries describing each of the
	// inlined callees. Each record contains:
	// INLINE SITE
	// GUID of the inlinee (uint64)
	// Index of the callsite probe (ULEB128)
	// FUNCTION BODY
	// A FUNCTION BODY entry describing the inlined function.
	#ifndef NDEBUG
	SectionName = "pseudo_probe";
	#endif
	Data = Start;
	End = Data + Size;

	PseudoProbeInlineTree *Root = &DummyInlineRoot;
	PseudoProbeInlineTree *Cur = &DummyInlineRoot;
	uint64_t LastAddr = 0;
	uint32_t Index = 0;
	// A DFS-based decoding
	while (Data < End) {
	// Read inline site for inlinees
	if (Root != Cur) {
	Index = readUnsignedNumber<uint32_t>();
	}
	// Switch/add to a new tree node(inlinee)
	Cur = Cur->getOrAddNode(std::make_tuple(Cur->GUID, Index));
	// Read guid
	Cur->GUID = readUnencodedNumber<uint64_t>();
	// Read number of probes in the current node.
	uint32_t NodeCount = readUnsignedNumber<uint32_t>();
	// Read number of direct inlinees
	Cur->ChildrenToProcess = readUnsignedNumber<uint32_t>();
	// Read all probes in this node
	for (std::size_t I = 0; I < NodeCount; I++) {
	// Read index
	uint32_t Index = readUnsignedNumber<uint32_t>();
	// Read type \| flag.
	uint8_t Value = readUnencodedNumber<uint8_t>();
	uint8_t Kind = Value & 0xf;
	uint8_t Attr = (Value & 0x70) >> 4;
	// Read address
	uint64_t Addr = 0;
	if (Value & 0x80) {
	int64_t Offset = readSignedNumber<int64_t>();
	Addr = LastAddr + Offset;
	} else {
	Addr = readUnencodedNumber<int64_t>();
	}
	// Populate Address2ProbesMap
	std::vector<PseudoProbe> &ProbeVec = Address2ProbesMap[Addr];
	ProbeVec.emplace_back(Addr, Cur->GUID, Index, PseudoProbeType(Kind), Attr,
	Cur);
	Cur->addProbes(&ProbeVec.back());
	LastAddr = Addr;
	}

	// Look for the parent for the next node by subtracting the current
	// node count from tree counts along the parent chain. The first node
	// in the chain that has a non-zero tree count is the target.
	while (Cur != Root) {
	if (Cur->ChildrenToProcess == 0) {
	Cur = Cur->Parent;
	if (Cur != Root) {
	assert(Cur->ChildrenToProcess > 0 &&
	"Should have some unprocessed nodes");
	Cur->ChildrenToProcess -= 1;
	}
	} else {
	break;
	}
	}
	}

	assert(Data == End && "Have unprocessed data in pseudo_probe section");
	assert(Cur == Root &&
	" Cur should point to root when the forest is fully built up");
	}

	void PseudoProbeDecoder::printGUID2FuncDescMap(raw_ostream &OS) {
	OS << "Pseudo Probe Desc:\n";
	// Make the output deterministic
	std::map<uint64_t, PseudoProbeFuncDesc> OrderedMap(GUID2FuncDescMap.begin(),
	GUID2FuncDescMap.end());
	for (auto &I : OrderedMap) {
	I.second.print(OS);
	}
	}

	void PseudoProbeDecoder::printProbeForAddress(raw_ostream &OS,
	uint64_t Address) {
	auto It = Address2ProbesMap.find(Address);
	if (It != Address2ProbesMap.end()) {
	for (auto &Probe : It->second) {
	OS << " [Probe]:\t";
	Probe.print(OS, GUID2FuncDescMap, true);
	}
	}
	}

	const PseudoProbe *
	PseudoProbeDecoder::getCallProbeForAddr(uint64_t Address) const {
	auto It = Address2ProbesMap.find(Address);
	if (It == Address2ProbesMap.end())
	return nullptr;
	const std::vector<PseudoProbe> &Probes = It->second;

	const PseudoProbe *CallProbe = nullptr;
	for (const auto &Probe : Probes) {
	if (Probe.isCall()) {
	assert(!CallProbe &&
	"There should be only one call probe corresponding to address "
	"which is a callsite.");
	CallProbe = &Probe;
	}
	}
	return CallProbe;
	}

	const PseudoProbeFuncDesc *
	PseudoProbeDecoder::getFuncDescForGUID(uint64_t GUID) const {
	auto It = GUID2FuncDescMap.find(GUID);
	assert(It != GUID2FuncDescMap.end() && "Function descriptor doesn't exist");
	return &It->second;
	}

	void PseudoProbeDecoder::getInlineContextForProbe(
	const PseudoProbe *Probe, SmallVectorImpl<std::string> &InlineContextStack,
	bool IncludeLeaf) const {
	Probe->getInlineContext(InlineContextStack, GUID2FuncDescMap, true);
	if (!IncludeLeaf)
	return;
	// Note that the context from probe doesn't include leaf frame,
	// hence we need to retrieve and prepend leaf if requested.
	const auto *FuncDesc = getFuncDescForGUID(Probe->GUID);
	InlineContextStack.emplace_back(FuncDesc->FuncName + ":" +
	Twine(Probe->Index).str());
	}

	const PseudoProbeFuncDesc *
	PseudoProbeDecoder::getInlinerDescForProbe(const PseudoProbe *Probe) const {
	PseudoProbeInlineTree *InlinerNode = Probe->InlineTree;
	if (!InlinerNode->hasInlineSite())
	return nullptr;
	return getFuncDescForGUID(std::get<0>(InlinerNode->ISite));
	}

	} // end namespace sampleprof
	} // end namespace llvm