//===- unittest/ProfileData/InstrProfTest.cpp -------------------*- 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 "llvm/IR/Function.h" #include "llvm/IR/IRBuilder.h" #include "llvm/IR/LLVMContext.h" #include "llvm/IR/Module.h" #include "llvm/ProfileData/InstrProfReader.h" #include "llvm/ProfileData/InstrProfWriter.h" #include "llvm/Support/Compression.h" #include "llvm/Testing/Support/Error.h" #include "llvm/Testing/Support/SupportHelpers.h" #include "gtest/gtest.h" #include using namespace llvm; LLVM_NODISCARD static ::testing::AssertionResult ErrorEquals(instrprof_error Expected, Error E) { instrprof_error Found; std::string FoundMsg; handleAllErrors(std::move(E), [&](const InstrProfError &IPE) { Found = IPE.get(); FoundMsg = IPE.message(); }); if (Expected == Found) return ::testing::AssertionSuccess(); return ::testing::AssertionFailure() << "error: " << FoundMsg << "\n"; } namespace { struct InstrProfTest : ::testing::Test { InstrProfWriter Writer; std::unique_ptr Reader; void SetUp() override { Writer.setOutputSparse(false); } void readProfile(std::unique_ptr Profile, std::unique_ptr Remapping = nullptr) { auto ReaderOrErr = IndexedInstrProfReader::create(std::move(Profile), std::move(Remapping)); EXPECT_THAT_ERROR(ReaderOrErr.takeError(), Succeeded()); Reader = std::move(ReaderOrErr.get()); } }; struct SparseInstrProfTest : public InstrProfTest { void SetUp() override { Writer.setOutputSparse(true); } }; struct MaybeSparseInstrProfTest : public InstrProfTest, public ::testing::WithParamInterface { void SetUp() override { Writer.setOutputSparse(GetParam()); } }; TEST_P(MaybeSparseInstrProfTest, write_and_read_empty_profile) { auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); ASSERT_TRUE(Reader->begin() == Reader->end()); } static const auto Err = [](Error E) { consumeError(std::move(E)); FAIL(); }; TEST_P(MaybeSparseInstrProfTest, write_and_read_one_function) { Writer.addRecord({"foo", 0x1234, {1, 2, 3, 4}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); auto I = Reader->begin(), E = Reader->end(); ASSERT_TRUE(I != E); ASSERT_EQ(StringRef("foo"), I->Name); ASSERT_EQ(0x1234U, I->Hash); ASSERT_EQ(4U, I->Counts.size()); ASSERT_EQ(1U, I->Counts[0]); ASSERT_EQ(2U, I->Counts[1]); ASSERT_EQ(3U, I->Counts[2]); ASSERT_EQ(4U, I->Counts[3]); ASSERT_TRUE(++I == E); } TEST_P(MaybeSparseInstrProfTest, get_instr_prof_record) { Writer.addRecord({"foo", 0x1234, {1, 2}}, Err); Writer.addRecord({"foo", 0x1235, {3, 4}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); Expected R = Reader->getInstrProfRecord("foo", 0x1234); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); ASSERT_EQ(2U, R->Counts.size()); ASSERT_EQ(1U, R->Counts[0]); ASSERT_EQ(2U, R->Counts[1]); R = Reader->getInstrProfRecord("foo", 0x1235); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); ASSERT_EQ(2U, R->Counts.size()); ASSERT_EQ(3U, R->Counts[0]); ASSERT_EQ(4U, R->Counts[1]); R = Reader->getInstrProfRecord("foo", 0x5678); ASSERT_TRUE(ErrorEquals(instrprof_error::hash_mismatch, R.takeError())); R = Reader->getInstrProfRecord("bar", 0x1234); ASSERT_TRUE(ErrorEquals(instrprof_error::unknown_function, R.takeError())); } TEST_P(MaybeSparseInstrProfTest, get_function_counts) { Writer.addRecord({"foo", 0x1234, {1, 2}}, Err); Writer.addRecord({"foo", 0x1235, {3, 4}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); std::vector Counts; EXPECT_THAT_ERROR(Reader->getFunctionCounts("foo", 0x1234, Counts), Succeeded()); ASSERT_EQ(2U, Counts.size()); ASSERT_EQ(1U, Counts[0]); ASSERT_EQ(2U, Counts[1]); EXPECT_THAT_ERROR(Reader->getFunctionCounts("foo", 0x1235, Counts), Succeeded()); ASSERT_EQ(2U, Counts.size()); ASSERT_EQ(3U, Counts[0]); ASSERT_EQ(4U, Counts[1]); Error E1 = Reader->getFunctionCounts("foo", 0x5678, Counts); ASSERT_TRUE(ErrorEquals(instrprof_error::hash_mismatch, std::move(E1))); Error E2 = Reader->getFunctionCounts("bar", 0x1234, Counts); ASSERT_TRUE(ErrorEquals(instrprof_error::unknown_function, std::move(E2))); } // Profile data is copied from general.proftext TEST_F(InstrProfTest, get_profile_summary) { Writer.addRecord({"func1", 0x1234, {97531}}, Err); Writer.addRecord({"func2", 0x1234, {0, 0}}, Err); Writer.addRecord( {"func3", 0x1234, {2305843009213693952, 1152921504606846976, 576460752303423488, 288230376151711744, 144115188075855872, 72057594037927936}}, Err); Writer.addRecord({"func4", 0x1234, {0}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); auto VerifySummary = [](ProfileSummary &IPS) mutable { ASSERT_EQ(ProfileSummary::PSK_Instr, IPS.getKind()); ASSERT_EQ(2305843009213693952U, IPS.getMaxFunctionCount()); ASSERT_EQ(2305843009213693952U, IPS.getMaxCount()); ASSERT_EQ(10U, IPS.getNumCounts()); ASSERT_EQ(4539628424389557499U, IPS.getTotalCount()); std::vector &Details = IPS.getDetailedSummary(); uint32_t Cutoff = 800000; auto Predicate = [&Cutoff](const ProfileSummaryEntry &PE) { return PE.Cutoff == Cutoff; }; auto EightyPerc = find_if(Details, Predicate); Cutoff = 900000; auto NinetyPerc = find_if(Details, Predicate); Cutoff = 950000; auto NinetyFivePerc = find_if(Details, Predicate); Cutoff = 990000; auto NinetyNinePerc = find_if(Details, Predicate); ASSERT_EQ(576460752303423488U, EightyPerc->MinCount); ASSERT_EQ(288230376151711744U, NinetyPerc->MinCount); ASSERT_EQ(288230376151711744U, NinetyFivePerc->MinCount); ASSERT_EQ(72057594037927936U, NinetyNinePerc->MinCount); }; ProfileSummary &PS = Reader->getSummary(/* IsCS */ false); VerifySummary(PS); // Test that conversion of summary to and from Metadata works. LLVMContext Context; Metadata *MD = PS.getMD(Context); ASSERT_TRUE(MD); ProfileSummary *PSFromMD = ProfileSummary::getFromMD(MD); ASSERT_TRUE(PSFromMD); VerifySummary(*PSFromMD); delete PSFromMD; // Test that summary can be attached to and read back from module. Module M("my_module", Context); M.setProfileSummary(MD, ProfileSummary::PSK_Instr); MD = M.getProfileSummary(/* IsCS */ false); ASSERT_TRUE(MD); PSFromMD = ProfileSummary::getFromMD(MD); ASSERT_TRUE(PSFromMD); VerifySummary(*PSFromMD); delete PSFromMD; } TEST_F(InstrProfTest, test_writer_merge) { Writer.addRecord({"func1", 0x1234, {42}}, Err); InstrProfWriter Writer2; Writer2.addRecord({"func2", 0x1234, {0, 0}}, Err); Writer.mergeRecordsFromWriter(std::move(Writer2), Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); Expected R = Reader->getInstrProfRecord("func1", 0x1234); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); ASSERT_EQ(1U, R->Counts.size()); ASSERT_EQ(42U, R->Counts[0]); R = Reader->getInstrProfRecord("func2", 0x1234); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); ASSERT_EQ(2U, R->Counts.size()); ASSERT_EQ(0U, R->Counts[0]); ASSERT_EQ(0U, R->Counts[1]); } static const char callee1[] = "callee1"; static const char callee2[] = "callee2"; static const char callee3[] = "callee3"; static const char callee4[] = "callee4"; static const char callee5[] = "callee5"; static const char callee6[] = "callee6"; TEST_P(MaybeSparseInstrProfTest, get_icall_data_read_write) { NamedInstrProfRecord Record1("caller", 0x1234, {1, 2}); // 4 value sites. Record1.reserveSites(IPVK_IndirectCallTarget, 4); InstrProfValueData VD0[] = { {(uint64_t)callee1, 1}, {(uint64_t)callee2, 2}, {(uint64_t)callee3, 3}}; Record1.addValueData(IPVK_IndirectCallTarget, 0, VD0, 3, nullptr); // No value profile data at the second site. Record1.addValueData(IPVK_IndirectCallTarget, 1, nullptr, 0, nullptr); InstrProfValueData VD2[] = {{(uint64_t)callee1, 1}, {(uint64_t)callee2, 2}}; Record1.addValueData(IPVK_IndirectCallTarget, 2, VD2, 2, nullptr); InstrProfValueData VD3[] = {{(uint64_t)callee1, 1}}; Record1.addValueData(IPVK_IndirectCallTarget, 3, VD3, 1, nullptr); Writer.addRecord(std::move(Record1), Err); Writer.addRecord({"callee1", 0x1235, {3, 4}}, Err); Writer.addRecord({"callee2", 0x1235, {3, 4}}, Err); Writer.addRecord({"callee3", 0x1235, {3, 4}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); Expected R = Reader->getInstrProfRecord("caller", 0x1234); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); ASSERT_EQ(4U, R->getNumValueSites(IPVK_IndirectCallTarget)); ASSERT_EQ(3U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 0)); ASSERT_EQ(0U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 1)); ASSERT_EQ(2U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 2)); ASSERT_EQ(1U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 3)); uint64_t TotalC; std::unique_ptr VD = R->getValueForSite(IPVK_IndirectCallTarget, 0, &TotalC); ASSERT_EQ(3U, VD[0].Count); ASSERT_EQ(2U, VD[1].Count); ASSERT_EQ(1U, VD[2].Count); ASSERT_EQ(6U, TotalC); ASSERT_EQ(StringRef((const char *)VD[0].Value, 7), StringRef("callee3")); ASSERT_EQ(StringRef((const char *)VD[1].Value, 7), StringRef("callee2")); ASSERT_EQ(StringRef((const char *)VD[2].Value, 7), StringRef("callee1")); } TEST_P(MaybeSparseInstrProfTest, annotate_vp_data) { NamedInstrProfRecord Record("caller", 0x1234, {1, 2}); Record.reserveSites(IPVK_IndirectCallTarget, 1); InstrProfValueData VD0[] = {{1000, 1}, {2000, 2}, {3000, 3}, {5000, 5}, {4000, 4}, {6000, 6}}; Record.addValueData(IPVK_IndirectCallTarget, 0, VD0, 6, nullptr); Writer.addRecord(std::move(Record), Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); Expected R = Reader->getInstrProfRecord("caller", 0x1234); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); LLVMContext Ctx; std::unique_ptr M(new Module("MyModule", Ctx)); FunctionType *FTy = FunctionType::get(Type::getVoidTy(Ctx), /*isVarArg=*/false); Function *F = Function::Create(FTy, Function::ExternalLinkage, "caller", M.get()); BasicBlock *BB = BasicBlock::Create(Ctx, "", F); IRBuilder<> Builder(BB); BasicBlock *TBB = BasicBlock::Create(Ctx, "", F); BasicBlock *FBB = BasicBlock::Create(Ctx, "", F); // Use branch instruction to annotate with value profile data for simplicity Instruction *Inst = Builder.CreateCondBr(Builder.getTrue(), TBB, FBB); Instruction *Inst2 = Builder.CreateCondBr(Builder.getTrue(), TBB, FBB); annotateValueSite(*M, *Inst, R.get(), IPVK_IndirectCallTarget, 0); InstrProfValueData ValueData[5]; uint32_t N; uint64_t T; bool Res = getValueProfDataFromInst(*Inst, IPVK_IndirectCallTarget, 5, ValueData, N, T); ASSERT_TRUE(Res); ASSERT_EQ(3U, N); ASSERT_EQ(21U, T); // The result should be sorted already: ASSERT_EQ(6000U, ValueData[0].Value); ASSERT_EQ(6U, ValueData[0].Count); ASSERT_EQ(5000U, ValueData[1].Value); ASSERT_EQ(5U, ValueData[1].Count); ASSERT_EQ(4000U, ValueData[2].Value); ASSERT_EQ(4U, ValueData[2].Count); Res = getValueProfDataFromInst(*Inst, IPVK_IndirectCallTarget, 1, ValueData, N, T); ASSERT_TRUE(Res); ASSERT_EQ(1U, N); ASSERT_EQ(21U, T); Res = getValueProfDataFromInst(*Inst2, IPVK_IndirectCallTarget, 5, ValueData, N, T); ASSERT_FALSE(Res); // Remove the MD_prof metadata Inst->setMetadata(LLVMContext::MD_prof, 0); // Annotate 5 records this time. annotateValueSite(*M, *Inst, R.get(), IPVK_IndirectCallTarget, 0, 5); Res = getValueProfDataFromInst(*Inst, IPVK_IndirectCallTarget, 5, ValueData, N, T); ASSERT_TRUE(Res); ASSERT_EQ(5U, N); ASSERT_EQ(21U, T); ASSERT_EQ(6000U, ValueData[0].Value); ASSERT_EQ(6U, ValueData[0].Count); ASSERT_EQ(5000U, ValueData[1].Value); ASSERT_EQ(5U, ValueData[1].Count); ASSERT_EQ(4000U, ValueData[2].Value); ASSERT_EQ(4U, ValueData[2].Count); ASSERT_EQ(3000U, ValueData[3].Value); ASSERT_EQ(3U, ValueData[3].Count); ASSERT_EQ(2000U, ValueData[4].Value); ASSERT_EQ(2U, ValueData[4].Count); // Remove the MD_prof metadata Inst->setMetadata(LLVMContext::MD_prof, 0); // Annotate with 4 records. InstrProfValueData VD0Sorted[] = {{1000, 6}, {2000, 5}, {3000, 4}, {4000, 3}, {5000, 2}, {6000, 1}}; annotateValueSite(*M, *Inst, makeArrayRef(VD0Sorted).slice(2), 10, IPVK_IndirectCallTarget, 5); Res = getValueProfDataFromInst(*Inst, IPVK_IndirectCallTarget, 5, ValueData, N, T); ASSERT_TRUE(Res); ASSERT_EQ(4U, N); ASSERT_EQ(10U, T); ASSERT_EQ(3000U, ValueData[0].Value); ASSERT_EQ(4U, ValueData[0].Count); ASSERT_EQ(4000U, ValueData[1].Value); ASSERT_EQ(3U, ValueData[1].Count); ASSERT_EQ(5000U, ValueData[2].Value); ASSERT_EQ(2U, ValueData[2].Count); ASSERT_EQ(6000U, ValueData[3].Value); ASSERT_EQ(1U, ValueData[3].Count); } TEST_P(MaybeSparseInstrProfTest, get_icall_data_read_write_with_weight) { NamedInstrProfRecord Record1("caller", 0x1234, {1, 2}); // 4 value sites. Record1.reserveSites(IPVK_IndirectCallTarget, 4); InstrProfValueData VD0[] = { {(uint64_t)callee1, 1}, {(uint64_t)callee2, 2}, {(uint64_t)callee3, 3}}; Record1.addValueData(IPVK_IndirectCallTarget, 0, VD0, 3, nullptr); // No value profile data at the second site. Record1.addValueData(IPVK_IndirectCallTarget, 1, nullptr, 0, nullptr); InstrProfValueData VD2[] = {{(uint64_t)callee1, 1}, {(uint64_t)callee2, 2}}; Record1.addValueData(IPVK_IndirectCallTarget, 2, VD2, 2, nullptr); InstrProfValueData VD3[] = {{(uint64_t)callee1, 1}}; Record1.addValueData(IPVK_IndirectCallTarget, 3, VD3, 1, nullptr); Writer.addRecord(std::move(Record1), 10, Err); Writer.addRecord({"callee1", 0x1235, {3, 4}}, Err); Writer.addRecord({"callee2", 0x1235, {3, 4}}, Err); Writer.addRecord({"callee3", 0x1235, {3, 4}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); Expected R = Reader->getInstrProfRecord("caller", 0x1234); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); ASSERT_EQ(4U, R->getNumValueSites(IPVK_IndirectCallTarget)); ASSERT_EQ(3U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 0)); ASSERT_EQ(0U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 1)); ASSERT_EQ(2U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 2)); ASSERT_EQ(1U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 3)); uint64_t TotalC; std::unique_ptr VD = R->getValueForSite(IPVK_IndirectCallTarget, 0, &TotalC); ASSERT_EQ(30U, VD[0].Count); ASSERT_EQ(20U, VD[1].Count); ASSERT_EQ(10U, VD[2].Count); ASSERT_EQ(60U, TotalC); ASSERT_EQ(StringRef((const char *)VD[0].Value, 7), StringRef("callee3")); ASSERT_EQ(StringRef((const char *)VD[1].Value, 7), StringRef("callee2")); ASSERT_EQ(StringRef((const char *)VD[2].Value, 7), StringRef("callee1")); } TEST_P(MaybeSparseInstrProfTest, get_icall_data_read_write_big_endian) { NamedInstrProfRecord Record1("caller", 0x1234, {1, 2}); // 4 value sites. Record1.reserveSites(IPVK_IndirectCallTarget, 4); InstrProfValueData VD0[] = { {(uint64_t)callee1, 1}, {(uint64_t)callee2, 2}, {(uint64_t)callee3, 3}}; Record1.addValueData(IPVK_IndirectCallTarget, 0, VD0, 3, nullptr); // No value profile data at the second site. Record1.addValueData(IPVK_IndirectCallTarget, 1, nullptr, 0, nullptr); InstrProfValueData VD2[] = {{(uint64_t)callee1, 1}, {(uint64_t)callee2, 2}}; Record1.addValueData(IPVK_IndirectCallTarget, 2, VD2, 2, nullptr); InstrProfValueData VD3[] = {{(uint64_t)callee1, 1}}; Record1.addValueData(IPVK_IndirectCallTarget, 3, VD3, 1, nullptr); Writer.addRecord(std::move(Record1), Err); Writer.addRecord({"callee1", 0x1235, {3, 4}}, Err); Writer.addRecord({"callee2", 0x1235, {3, 4}}, Err); Writer.addRecord({"callee3", 0x1235, {3, 4}}, Err); // Set big endian output. Writer.setValueProfDataEndianness(support::big); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); // Set big endian input. Reader->setValueProfDataEndianness(support::big); Expected R = Reader->getInstrProfRecord("caller", 0x1234); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); ASSERT_EQ(4U, R->getNumValueSites(IPVK_IndirectCallTarget)); ASSERT_EQ(3U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 0)); ASSERT_EQ(0U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 1)); ASSERT_EQ(2U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 2)); ASSERT_EQ(1U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 3)); std::unique_ptr VD = R->getValueForSite(IPVK_IndirectCallTarget, 0); ASSERT_EQ(StringRef((const char *)VD[0].Value, 7), StringRef("callee3")); ASSERT_EQ(StringRef((const char *)VD[1].Value, 7), StringRef("callee2")); ASSERT_EQ(StringRef((const char *)VD[2].Value, 7), StringRef("callee1")); // Restore little endian default: Writer.setValueProfDataEndianness(support::little); } TEST_P(MaybeSparseInstrProfTest, get_icall_data_merge1) { static const char caller[] = "caller"; NamedInstrProfRecord Record11(caller, 0x1234, {1, 2}); NamedInstrProfRecord Record12(caller, 0x1234, {1, 2}); // 5 value sites. Record11.reserveSites(IPVK_IndirectCallTarget, 5); InstrProfValueData VD0[] = {{uint64_t(callee1), 1}, {uint64_t(callee2), 2}, {uint64_t(callee3), 3}, {uint64_t(callee4), 4}}; Record11.addValueData(IPVK_IndirectCallTarget, 0, VD0, 4, nullptr); // No value profile data at the second site. Record11.addValueData(IPVK_IndirectCallTarget, 1, nullptr, 0, nullptr); InstrProfValueData VD2[] = { {uint64_t(callee1), 1}, {uint64_t(callee2), 2}, {uint64_t(callee3), 3}}; Record11.addValueData(IPVK_IndirectCallTarget, 2, VD2, 3, nullptr); InstrProfValueData VD3[] = {{uint64_t(callee1), 1}}; Record11.addValueData(IPVK_IndirectCallTarget, 3, VD3, 1, nullptr); InstrProfValueData VD4[] = {{uint64_t(callee1), 1}, {uint64_t(callee2), 2}, {uint64_t(callee3), 3}}; Record11.addValueData(IPVK_IndirectCallTarget, 4, VD4, 3, nullptr); // A different record for the same caller. Record12.reserveSites(IPVK_IndirectCallTarget, 5); InstrProfValueData VD02[] = {{uint64_t(callee2), 5}, {uint64_t(callee3), 3}}; Record12.addValueData(IPVK_IndirectCallTarget, 0, VD02, 2, nullptr); // No value profile data at the second site. Record12.addValueData(IPVK_IndirectCallTarget, 1, nullptr, 0, nullptr); InstrProfValueData VD22[] = { {uint64_t(callee2), 1}, {uint64_t(callee3), 3}, {uint64_t(callee4), 4}}; Record12.addValueData(IPVK_IndirectCallTarget, 2, VD22, 3, nullptr); Record12.addValueData(IPVK_IndirectCallTarget, 3, nullptr, 0, nullptr); InstrProfValueData VD42[] = {{uint64_t(callee1), 1}, {uint64_t(callee2), 2}, {uint64_t(callee3), 3}}; Record12.addValueData(IPVK_IndirectCallTarget, 4, VD42, 3, nullptr); Writer.addRecord(std::move(Record11), Err); // Merge profile data. Writer.addRecord(std::move(Record12), Err); Writer.addRecord({callee1, 0x1235, {3, 4}}, Err); Writer.addRecord({callee2, 0x1235, {3, 4}}, Err); Writer.addRecord({callee3, 0x1235, {3, 4}}, Err); Writer.addRecord({callee3, 0x1235, {3, 4}}, Err); Writer.addRecord({callee4, 0x1235, {3, 5}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); Expected R = Reader->getInstrProfRecord("caller", 0x1234); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); ASSERT_EQ(5U, R->getNumValueSites(IPVK_IndirectCallTarget)); ASSERT_EQ(4U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 0)); ASSERT_EQ(0U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 1)); ASSERT_EQ(4U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 2)); ASSERT_EQ(1U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 3)); ASSERT_EQ(3U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 4)); std::unique_ptr VD = R->getValueForSite(IPVK_IndirectCallTarget, 0); ASSERT_EQ(StringRef((const char *)VD[0].Value, 7), StringRef("callee2")); ASSERT_EQ(7U, VD[0].Count); ASSERT_EQ(StringRef((const char *)VD[1].Value, 7), StringRef("callee3")); ASSERT_EQ(6U, VD[1].Count); ASSERT_EQ(StringRef((const char *)VD[2].Value, 7), StringRef("callee4")); ASSERT_EQ(4U, VD[2].Count); ASSERT_EQ(StringRef((const char *)VD[3].Value, 7), StringRef("callee1")); ASSERT_EQ(1U, VD[3].Count); std::unique_ptr VD_2( R->getValueForSite(IPVK_IndirectCallTarget, 2)); ASSERT_EQ(StringRef((const char *)VD_2[0].Value, 7), StringRef("callee3")); ASSERT_EQ(6U, VD_2[0].Count); ASSERT_EQ(StringRef((const char *)VD_2[1].Value, 7), StringRef("callee4")); ASSERT_EQ(4U, VD_2[1].Count); ASSERT_EQ(StringRef((const char *)VD_2[2].Value, 7), StringRef("callee2")); ASSERT_EQ(3U, VD_2[2].Count); ASSERT_EQ(StringRef((const char *)VD_2[3].Value, 7), StringRef("callee1")); ASSERT_EQ(1U, VD_2[3].Count); std::unique_ptr VD_3( R->getValueForSite(IPVK_IndirectCallTarget, 3)); ASSERT_EQ(StringRef((const char *)VD_3[0].Value, 7), StringRef("callee1")); ASSERT_EQ(1U, VD_3[0].Count); std::unique_ptr VD_4( R->getValueForSite(IPVK_IndirectCallTarget, 4)); ASSERT_EQ(StringRef((const char *)VD_4[0].Value, 7), StringRef("callee3")); ASSERT_EQ(6U, VD_4[0].Count); ASSERT_EQ(StringRef((const char *)VD_4[1].Value, 7), StringRef("callee2")); ASSERT_EQ(4U, VD_4[1].Count); ASSERT_EQ(StringRef((const char *)VD_4[2].Value, 7), StringRef("callee1")); ASSERT_EQ(2U, VD_4[2].Count); } TEST_P(MaybeSparseInstrProfTest, get_icall_data_merge1_saturation) { static const char bar[] = "bar"; const uint64_t Max = std::numeric_limits::max(); instrprof_error Result; auto Err = [&](Error E) { Result = InstrProfError::take(std::move(E)); }; Result = instrprof_error::success; Writer.addRecord({"foo", 0x1234, {1}}, Err); ASSERT_EQ(Result, instrprof_error::success); // Verify counter overflow. Result = instrprof_error::success; Writer.addRecord({"foo", 0x1234, {Max}}, Err); ASSERT_EQ(Result, instrprof_error::counter_overflow); Result = instrprof_error::success; Writer.addRecord({bar, 0x9012, {8}}, Err); ASSERT_EQ(Result, instrprof_error::success); NamedInstrProfRecord Record4("baz", 0x5678, {3, 4}); Record4.reserveSites(IPVK_IndirectCallTarget, 1); InstrProfValueData VD4[] = {{uint64_t(bar), 1}}; Record4.addValueData(IPVK_IndirectCallTarget, 0, VD4, 1, nullptr); Result = instrprof_error::success; Writer.addRecord(std::move(Record4), Err); ASSERT_EQ(Result, instrprof_error::success); // Verify value data counter overflow. NamedInstrProfRecord Record5("baz", 0x5678, {5, 6}); Record5.reserveSites(IPVK_IndirectCallTarget, 1); InstrProfValueData VD5[] = {{uint64_t(bar), Max}}; Record5.addValueData(IPVK_IndirectCallTarget, 0, VD5, 1, nullptr); Result = instrprof_error::success; Writer.addRecord(std::move(Record5), Err); ASSERT_EQ(Result, instrprof_error::counter_overflow); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); // Verify saturation of counts. Expected ReadRecord1 = Reader->getInstrProfRecord("foo", 0x1234); EXPECT_THAT_ERROR(ReadRecord1.takeError(), Succeeded()); ASSERT_EQ(Max, ReadRecord1->Counts[0]); Expected ReadRecord2 = Reader->getInstrProfRecord("baz", 0x5678); ASSERT_TRUE(bool(ReadRecord2)); ASSERT_EQ(1U, ReadRecord2->getNumValueSites(IPVK_IndirectCallTarget)); std::unique_ptr VD = ReadRecord2->getValueForSite(IPVK_IndirectCallTarget, 0); ASSERT_EQ(StringRef("bar"), StringRef((const char *)VD[0].Value, 3)); ASSERT_EQ(Max, VD[0].Count); } // This test tests that when there are too many values // for a given site, the merged results are properly // truncated. TEST_P(MaybeSparseInstrProfTest, get_icall_data_merge_site_trunc) { static const char caller[] = "caller"; NamedInstrProfRecord Record11(caller, 0x1234, {1, 2}); NamedInstrProfRecord Record12(caller, 0x1234, {1, 2}); // 2 value sites. Record11.reserveSites(IPVK_IndirectCallTarget, 2); InstrProfValueData VD0[255]; for (int I = 0; I < 255; I++) { VD0[I].Value = 2 * I; VD0[I].Count = 2 * I + 1000; } Record11.addValueData(IPVK_IndirectCallTarget, 0, VD0, 255, nullptr); Record11.addValueData(IPVK_IndirectCallTarget, 1, nullptr, 0, nullptr); Record12.reserveSites(IPVK_IndirectCallTarget, 2); InstrProfValueData VD1[255]; for (int I = 0; I < 255; I++) { VD1[I].Value = 2 * I + 1; VD1[I].Count = 2 * I + 1001; } Record12.addValueData(IPVK_IndirectCallTarget, 0, VD1, 255, nullptr); Record12.addValueData(IPVK_IndirectCallTarget, 1, nullptr, 0, nullptr); Writer.addRecord(std::move(Record11), Err); // Merge profile data. Writer.addRecord(std::move(Record12), Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); Expected R = Reader->getInstrProfRecord("caller", 0x1234); EXPECT_THAT_ERROR(R.takeError(), Succeeded()); std::unique_ptr VD( R->getValueForSite(IPVK_IndirectCallTarget, 0)); ASSERT_EQ(2U, R->getNumValueSites(IPVK_IndirectCallTarget)); ASSERT_EQ(255U, R->getNumValueDataForSite(IPVK_IndirectCallTarget, 0)); for (unsigned I = 0; I < 255; I++) { ASSERT_EQ(VD[I].Value, 509 - I); ASSERT_EQ(VD[I].Count, 1509 - I); } } static void addValueProfData(InstrProfRecord &Record) { Record.reserveSites(IPVK_IndirectCallTarget, 5); InstrProfValueData VD0[] = {{uint64_t(callee1), 400}, {uint64_t(callee2), 1000}, {uint64_t(callee3), 500}, {uint64_t(callee4), 300}, {uint64_t(callee5), 100}}; Record.addValueData(IPVK_IndirectCallTarget, 0, VD0, 5, nullptr); InstrProfValueData VD1[] = {{uint64_t(callee5), 800}, {uint64_t(callee3), 1000}, {uint64_t(callee2), 2500}, {uint64_t(callee1), 1300}}; Record.addValueData(IPVK_IndirectCallTarget, 1, VD1, 4, nullptr); InstrProfValueData VD2[] = {{uint64_t(callee6), 800}, {uint64_t(callee3), 1000}, {uint64_t(callee4), 5500}}; Record.addValueData(IPVK_IndirectCallTarget, 2, VD2, 3, nullptr); InstrProfValueData VD3[] = {{uint64_t(callee2), 1800}, {uint64_t(callee3), 2000}}; Record.addValueData(IPVK_IndirectCallTarget, 3, VD3, 2, nullptr); Record.addValueData(IPVK_IndirectCallTarget, 4, nullptr, 0, nullptr); } TEST_P(MaybeSparseInstrProfTest, value_prof_data_read_write) { InstrProfRecord SrcRecord({1ULL << 31, 2}); addValueProfData(SrcRecord); std::unique_ptr VPData = ValueProfData::serializeFrom(SrcRecord); InstrProfRecord Record({1ULL << 31, 2}); VPData->deserializeTo(Record, nullptr); // Now read data from Record and sanity check the data ASSERT_EQ(5U, Record.getNumValueSites(IPVK_IndirectCallTarget)); ASSERT_EQ(5U, Record.getNumValueDataForSite(IPVK_IndirectCallTarget, 0)); ASSERT_EQ(4U, Record.getNumValueDataForSite(IPVK_IndirectCallTarget, 1)); ASSERT_EQ(3U, Record.getNumValueDataForSite(IPVK_IndirectCallTarget, 2)); ASSERT_EQ(2U, Record.getNumValueDataForSite(IPVK_IndirectCallTarget, 3)); ASSERT_EQ(0U, Record.getNumValueDataForSite(IPVK_IndirectCallTarget, 4)); auto Cmp = [](const InstrProfValueData &VD1, const InstrProfValueData &VD2) { return VD1.Count > VD2.Count; }; std::unique_ptr VD_0( Record.getValueForSite(IPVK_IndirectCallTarget, 0)); llvm::sort(&VD_0[0], &VD_0[5], Cmp); ASSERT_EQ(StringRef((const char *)VD_0[0].Value, 7), StringRef("callee2")); ASSERT_EQ(1000U, VD_0[0].Count); ASSERT_EQ(StringRef((const char *)VD_0[1].Value, 7), StringRef("callee3")); ASSERT_EQ(500U, VD_0[1].Count); ASSERT_EQ(StringRef((const char *)VD_0[2].Value, 7), StringRef("callee1")); ASSERT_EQ(400U, VD_0[2].Count); ASSERT_EQ(StringRef((const char *)VD_0[3].Value, 7), StringRef("callee4")); ASSERT_EQ(300U, VD_0[3].Count); ASSERT_EQ(StringRef((const char *)VD_0[4].Value, 7), StringRef("callee5")); ASSERT_EQ(100U, VD_0[4].Count); std::unique_ptr VD_1( Record.getValueForSite(IPVK_IndirectCallTarget, 1)); llvm::sort(&VD_1[0], &VD_1[4], Cmp); ASSERT_EQ(StringRef((const char *)VD_1[0].Value, 7), StringRef("callee2")); ASSERT_EQ(2500U, VD_1[0].Count); ASSERT_EQ(StringRef((const char *)VD_1[1].Value, 7), StringRef("callee1")); ASSERT_EQ(1300U, VD_1[1].Count); ASSERT_EQ(StringRef((const char *)VD_1[2].Value, 7), StringRef("callee3")); ASSERT_EQ(1000U, VD_1[2].Count); ASSERT_EQ(StringRef((const char *)VD_1[3].Value, 7), StringRef("callee5")); ASSERT_EQ(800U, VD_1[3].Count); std::unique_ptr VD_2( Record.getValueForSite(IPVK_IndirectCallTarget, 2)); llvm::sort(&VD_2[0], &VD_2[3], Cmp); ASSERT_EQ(StringRef((const char *)VD_2[0].Value, 7), StringRef("callee4")); ASSERT_EQ(5500U, VD_2[0].Count); ASSERT_EQ(StringRef((const char *)VD_2[1].Value, 7), StringRef("callee3")); ASSERT_EQ(1000U, VD_2[1].Count); ASSERT_EQ(StringRef((const char *)VD_2[2].Value, 7), StringRef("callee6")); ASSERT_EQ(800U, VD_2[2].Count); std::unique_ptr VD_3( Record.getValueForSite(IPVK_IndirectCallTarget, 3)); llvm::sort(&VD_3[0], &VD_3[2], Cmp); ASSERT_EQ(StringRef((const char *)VD_3[0].Value, 7), StringRef("callee3")); ASSERT_EQ(2000U, VD_3[0].Count); ASSERT_EQ(StringRef((const char *)VD_3[1].Value, 7), StringRef("callee2")); ASSERT_EQ(1800U, VD_3[1].Count); } TEST_P(MaybeSparseInstrProfTest, value_prof_data_read_write_mapping) { NamedInstrProfRecord SrcRecord("caller", 0x1234, {1ULL << 31, 2}); addValueProfData(SrcRecord); std::unique_ptr VPData = ValueProfData::serializeFrom(SrcRecord); NamedInstrProfRecord Record("caller", 0x1234, {1ULL << 31, 2}); InstrProfSymtab Symtab; Symtab.mapAddress(uint64_t(callee1), 0x1000ULL); Symtab.mapAddress(uint64_t(callee2), 0x2000ULL); Symtab.mapAddress(uint64_t(callee3), 0x3000ULL); Symtab.mapAddress(uint64_t(callee4), 0x4000ULL); // Missing mapping for callee5 VPData->deserializeTo(Record, &Symtab); // Now read data from Record and sanity check the data ASSERT_EQ(5U, Record.getNumValueSites(IPVK_IndirectCallTarget)); ASSERT_EQ(5U, Record.getNumValueDataForSite(IPVK_IndirectCallTarget, 0)); auto Cmp = [](const InstrProfValueData &VD1, const InstrProfValueData &VD2) { return VD1.Count > VD2.Count; }; std::unique_ptr VD_0( Record.getValueForSite(IPVK_IndirectCallTarget, 0)); llvm::sort(&VD_0[0], &VD_0[5], Cmp); ASSERT_EQ(VD_0[0].Value, 0x2000ULL); ASSERT_EQ(1000U, VD_0[0].Count); ASSERT_EQ(VD_0[1].Value, 0x3000ULL); ASSERT_EQ(500U, VD_0[1].Count); ASSERT_EQ(VD_0[2].Value, 0x1000ULL); ASSERT_EQ(400U, VD_0[2].Count); // callee5 does not have a mapped value -- default to 0. ASSERT_EQ(VD_0[4].Value, 0ULL); } TEST_P(MaybeSparseInstrProfTest, get_max_function_count) { Writer.addRecord({"foo", 0x1234, {1ULL << 31, 2}}, Err); Writer.addRecord({"bar", 0, {1ULL << 63}}, Err); Writer.addRecord({"baz", 0x5678, {0, 0, 0, 0}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); ASSERT_EQ(1ULL << 63, Reader->getMaximumFunctionCount(/* IsCS */ false)); } TEST_P(MaybeSparseInstrProfTest, get_weighted_function_counts) { Writer.addRecord({"foo", 0x1234, {1, 2}}, 3, Err); Writer.addRecord({"foo", 0x1235, {3, 4}}, 5, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); std::vector Counts; EXPECT_THAT_ERROR(Reader->getFunctionCounts("foo", 0x1234, Counts), Succeeded()); ASSERT_EQ(2U, Counts.size()); ASSERT_EQ(3U, Counts[0]); ASSERT_EQ(6U, Counts[1]); EXPECT_THAT_ERROR(Reader->getFunctionCounts("foo", 0x1235, Counts), Succeeded()); ASSERT_EQ(2U, Counts.size()); ASSERT_EQ(15U, Counts[0]); ASSERT_EQ(20U, Counts[1]); } // Testing symtab creator interface used by indexed profile reader. TEST_P(MaybeSparseInstrProfTest, instr_prof_symtab_test) { std::vector FuncNames; FuncNames.push_back("func1"); FuncNames.push_back("func2"); FuncNames.push_back("func3"); FuncNames.push_back("bar1"); FuncNames.push_back("bar2"); FuncNames.push_back("bar3"); InstrProfSymtab Symtab; EXPECT_THAT_ERROR(Symtab.create(FuncNames), Succeeded()); StringRef R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("func1")); ASSERT_EQ(StringRef("func1"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("func2")); ASSERT_EQ(StringRef("func2"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("func3")); ASSERT_EQ(StringRef("func3"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("bar1")); ASSERT_EQ(StringRef("bar1"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("bar2")); ASSERT_EQ(StringRef("bar2"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("bar3")); ASSERT_EQ(StringRef("bar3"), R); // negative tests R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("bar4")); ASSERT_EQ(StringRef(), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("foo4")); ASSERT_EQ(StringRef(), R); // Now incrementally update the symtab EXPECT_THAT_ERROR(Symtab.addFuncName("blah_1"), Succeeded()); EXPECT_THAT_ERROR(Symtab.addFuncName("blah_2"), Succeeded()); EXPECT_THAT_ERROR(Symtab.addFuncName("blah_3"), Succeeded()); // Check again R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("blah_1")); ASSERT_EQ(StringRef("blah_1"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("blah_2")); ASSERT_EQ(StringRef("blah_2"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("blah_3")); ASSERT_EQ(StringRef("blah_3"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("func1")); ASSERT_EQ(StringRef("func1"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("func2")); ASSERT_EQ(StringRef("func2"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("func3")); ASSERT_EQ(StringRef("func3"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("bar1")); ASSERT_EQ(StringRef("bar1"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("bar2")); ASSERT_EQ(StringRef("bar2"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash("bar3")); ASSERT_EQ(StringRef("bar3"), R); } // Test that we get an error when creating a bogus symtab. TEST_P(MaybeSparseInstrProfTest, instr_prof_bogus_symtab_empty_func_name) { InstrProfSymtab Symtab; EXPECT_TRUE(ErrorEquals(instrprof_error::malformed, Symtab.addFuncName(""))); } // Testing symtab creator interface used by value profile transformer. TEST_P(MaybeSparseInstrProfTest, instr_prof_symtab_module_test) { LLVMContext Ctx; std::unique_ptr M = std::make_unique("MyModule.cpp", Ctx); FunctionType *FTy = FunctionType::get(Type::getVoidTy(Ctx), /*isVarArg=*/false); Function::Create(FTy, Function::ExternalLinkage, "Gfoo", M.get()); Function::Create(FTy, Function::ExternalLinkage, "Gblah", M.get()); Function::Create(FTy, Function::ExternalLinkage, "Gbar", M.get()); Function::Create(FTy, Function::InternalLinkage, "Ifoo", M.get()); Function::Create(FTy, Function::InternalLinkage, "Iblah", M.get()); Function::Create(FTy, Function::InternalLinkage, "Ibar", M.get()); Function::Create(FTy, Function::PrivateLinkage, "Pfoo", M.get()); Function::Create(FTy, Function::PrivateLinkage, "Pblah", M.get()); Function::Create(FTy, Function::PrivateLinkage, "Pbar", M.get()); Function::Create(FTy, Function::WeakODRLinkage, "Wfoo", M.get()); Function::Create(FTy, Function::WeakODRLinkage, "Wblah", M.get()); Function::Create(FTy, Function::WeakODRLinkage, "Wbar", M.get()); InstrProfSymtab ProfSymtab; EXPECT_THAT_ERROR(ProfSymtab.create(*M), Succeeded()); StringRef Funcs[] = {"Gfoo", "Gblah", "Gbar", "Ifoo", "Iblah", "Ibar", "Pfoo", "Pblah", "Pbar", "Wfoo", "Wblah", "Wbar"}; for (unsigned I = 0; I < sizeof(Funcs) / sizeof(*Funcs); I++) { Function *F = M->getFunction(Funcs[I]); ASSERT_TRUE(F != nullptr); std::string PGOName = getPGOFuncName(*F); uint64_t Key = IndexedInstrProf::ComputeHash(PGOName); ASSERT_EQ(StringRef(PGOName), ProfSymtab.getFuncName(Key)); ASSERT_EQ(StringRef(Funcs[I]), ProfSymtab.getOrigFuncName(Key)); } } // Testing symtab serialization and creator/deserialization interface // used by coverage map reader, and raw profile reader. TEST_P(MaybeSparseInstrProfTest, instr_prof_symtab_compression_test) { std::vector FuncNames1; std::vector FuncNames2; for (int I = 0; I < 3; I++) { std::string str; raw_string_ostream OS(str); OS << "func_" << I; FuncNames1.push_back(OS.str()); str.clear(); OS << "f oooooooooooooo_" << I; FuncNames1.push_back(OS.str()); str.clear(); OS << "BAR_" << I; FuncNames2.push_back(OS.str()); str.clear(); OS << "BlahblahBlahblahBar_" << I; FuncNames2.push_back(OS.str()); } for (bool DoCompression : {false, true}) { // Compressing: std::string FuncNameStrings1; EXPECT_THAT_ERROR(collectPGOFuncNameStrings( FuncNames1, (DoCompression && zlib::isAvailable()), FuncNameStrings1), Succeeded()); // Compressing: std::string FuncNameStrings2; EXPECT_THAT_ERROR(collectPGOFuncNameStrings( FuncNames2, (DoCompression && zlib::isAvailable()), FuncNameStrings2), Succeeded()); for (int Padding = 0; Padding < 2; Padding++) { // Join with paddings : std::string FuncNameStrings = FuncNameStrings1; for (int P = 0; P < Padding; P++) { FuncNameStrings.push_back('\0'); } FuncNameStrings += FuncNameStrings2; // Now decompress: InstrProfSymtab Symtab; EXPECT_THAT_ERROR(Symtab.create(StringRef(FuncNameStrings)), Succeeded()); // Now do the checks: // First sampling some data points: StringRef R = Symtab.getFuncName(IndexedInstrProf::ComputeHash(FuncNames1[0])); ASSERT_EQ(StringRef("func_0"), R); R = Symtab.getFuncName(IndexedInstrProf::ComputeHash(FuncNames1[1])); ASSERT_EQ(StringRef("f oooooooooooooo_0"), R); for (int I = 0; I < 3; I++) { std::string N[4]; N[0] = FuncNames1[2 * I]; N[1] = FuncNames1[2 * I + 1]; N[2] = FuncNames2[2 * I]; N[3] = FuncNames2[2 * I + 1]; for (int J = 0; J < 4; J++) { StringRef R = Symtab.getFuncName(IndexedInstrProf::ComputeHash(N[J])); ASSERT_EQ(StringRef(N[J]), R); } } } } } TEST_P(MaybeSparseInstrProfTest, remapping_test) { Writer.addRecord({"_Z3fooi", 0x1234, {1, 2, 3, 4}}, Err); Writer.addRecord({"file:_Z3barf", 0x567, {5, 6, 7}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile), llvm::MemoryBuffer::getMemBuffer(R"( type i l name 3bar 4quux )")); std::vector Counts; for (StringRef FooName : {"_Z3fooi", "_Z3fool"}) { EXPECT_THAT_ERROR(Reader->getFunctionCounts(FooName, 0x1234, Counts), Succeeded()); ASSERT_EQ(4u, Counts.size()); EXPECT_EQ(1u, Counts[0]); EXPECT_EQ(2u, Counts[1]); EXPECT_EQ(3u, Counts[2]); EXPECT_EQ(4u, Counts[3]); } for (StringRef BarName : {"file:_Z3barf", "file:_Z4quuxf"}) { EXPECT_THAT_ERROR(Reader->getFunctionCounts(BarName, 0x567, Counts), Succeeded()); ASSERT_EQ(3u, Counts.size()); EXPECT_EQ(5u, Counts[0]); EXPECT_EQ(6u, Counts[1]); EXPECT_EQ(7u, Counts[2]); } for (StringRef BadName : {"_Z3foof", "_Z4quuxi", "_Z3barl", "", "_ZZZ", "_Z3barf", "otherfile:_Z4quuxf"}) { EXPECT_THAT_ERROR(Reader->getFunctionCounts(BadName, 0x1234, Counts), Failed()); EXPECT_THAT_ERROR(Reader->getFunctionCounts(BadName, 0x567, Counts), Failed()); } } TEST_F(SparseInstrProfTest, preserve_no_records) { Writer.addRecord({"foo", 0x1234, {0}}, Err); Writer.addRecord({"bar", 0x4321, {0, 0}}, Err); Writer.addRecord({"baz", 0x4321, {0, 0, 0}}, Err); auto Profile = Writer.writeBuffer(); readProfile(std::move(Profile)); auto I = Reader->begin(), E = Reader->end(); ASSERT_TRUE(I == E); } INSTANTIATE_TEST_SUITE_P(MaybeSparse, MaybeSparseInstrProfTest, ::testing::Bool()); #if defined(_LP64) && defined(EXPENSIVE_CHECKS) TEST(ProfileReaderTest, ReadsLargeFiles) { const size_t LargeSize = 1ULL << 32; // 4GB auto RawProfile = WritableMemoryBuffer::getNewUninitMemBuffer(LargeSize); if (!RawProfile) return; auto RawProfileReaderOrErr = InstrProfReader::create(std::move(RawProfile)); ASSERT_TRUE(InstrProfError::take(RawProfileReaderOrErr.takeError()) == instrprof_error::unrecognized_format); auto IndexedProfile = WritableMemoryBuffer::getNewUninitMemBuffer(LargeSize); if (!IndexedProfile) return; auto IndexedReaderOrErr = IndexedInstrProfReader::create(std::move(IndexedProfile), nullptr); ASSERT_TRUE(InstrProfError::take(IndexedReaderOrErr.takeError()) == instrprof_error::bad_magic); } #endif } // end anonymous namespace