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| //===- llvm/unittest/DebugInfo/GSYMTest.cpp -------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/DebugInfo/GSYM/Header.h"
#include "llvm/DebugInfo/GSYM/FileEntry.h"
#include "llvm/DebugInfo/GSYM/FileWriter.h"
#include "llvm/DebugInfo/GSYM/FunctionInfo.h"
#include "llvm/DebugInfo/GSYM/GsymCreator.h"
#include "llvm/DebugInfo/GSYM/GsymReader.h"
#include "llvm/DebugInfo/GSYM/InlineInfo.h"
#include "llvm/DebugInfo/GSYM/Range.h"
#include "llvm/DebugInfo/GSYM/StringTable.h"
#include "llvm/Support/DataExtractor.h"
#include "llvm/Support/Endian.h"
#include "gtest/gtest.h"
#include <string>
using namespace llvm;
using namespace gsym;
void checkError(ArrayRef<std::string> ExpectedMsgs, Error Err) {
ASSERT_TRUE(bool(Err));
size_t WhichMsg = 0;
Error Remaining =
handleErrors(std::move(Err), [&](const ErrorInfoBase &Actual) {
ASSERT_LT(WhichMsg, ExpectedMsgs.size());
// Use .str(), because googletest doesn't visualise a StringRef
// properly.
EXPECT_EQ(Actual.message(), ExpectedMsgs[WhichMsg++]);
});
EXPECT_EQ(WhichMsg, ExpectedMsgs.size());
EXPECT_FALSE(Remaining);
}
void checkError(std::string ExpectedMsg, Error Err) {
checkError(ArrayRef<std::string>{ExpectedMsg}, std::move(Err));
}
TEST(GSYMTest, TestFileEntry) {
// Make sure default constructed GSYM FileEntry has zeroes in the
// directory and basename string table indexes.
FileEntry empty1;
FileEntry empty2;
EXPECT_EQ(empty1.Dir, 0u);
EXPECT_EQ(empty1.Base, 0u);
// Verify equality operator works
FileEntry a1(10, 30);
FileEntry a2(10, 30);
FileEntry b(10, 40);
EXPECT_EQ(empty1, empty2);
EXPECT_EQ(a1, a2);
EXPECT_NE(a1, b);
EXPECT_NE(a1, empty1);
// Test we can use llvm::gsym::FileEntry in llvm::DenseMap.
DenseMap<FileEntry, uint32_t> EntryToIndex;
constexpr uint32_t Index1 = 1;
constexpr uint32_t Index2 = 1;
auto R = EntryToIndex.insert(std::make_pair(a1, Index1));
EXPECT_TRUE(R.second);
EXPECT_EQ(R.first->second, Index1);
R = EntryToIndex.insert(std::make_pair(a1, Index1));
EXPECT_FALSE(R.second);
EXPECT_EQ(R.first->second, Index1);
R = EntryToIndex.insert(std::make_pair(b, Index2));
EXPECT_TRUE(R.second);
EXPECT_EQ(R.first->second, Index2);
R = EntryToIndex.insert(std::make_pair(a1, Index2));
EXPECT_FALSE(R.second);
EXPECT_EQ(R.first->second, Index2);
}
TEST(GSYMTest, TestFunctionInfo) {
// Test GSYM FunctionInfo structs and functionality.
FunctionInfo invalid;
EXPECT_FALSE(invalid.isValid());
EXPECT_FALSE(invalid.hasRichInfo());
const uint64_t StartAddr = 0x1000;
const uint64_t EndAddr = 0x1100;
const uint64_t Size = EndAddr - StartAddr;
const uint32_t NameOffset = 30;
FunctionInfo FI(StartAddr, Size, NameOffset);
EXPECT_TRUE(FI.isValid());
EXPECT_FALSE(FI.hasRichInfo());
EXPECT_EQ(FI.startAddress(), StartAddr);
EXPECT_EQ(FI.endAddress(), EndAddr);
EXPECT_EQ(FI.size(), Size);
const uint32_t FileIdx = 1;
const uint32_t Line = 12;
FI.OptLineTable = LineTable();
FI.OptLineTable->push(LineEntry(StartAddr,FileIdx,Line));
EXPECT_TRUE(FI.hasRichInfo());
FI.clear();
EXPECT_FALSE(FI.isValid());
EXPECT_FALSE(FI.hasRichInfo());
FunctionInfo A1(0x1000, 0x100, NameOffset);
FunctionInfo A2(0x1000, 0x100, NameOffset);
FunctionInfo B;
// Check == operator
EXPECT_EQ(A1, A2);
// Make sure things are not equal if they only differ by start address.
B = A2;
B.setStartAddress(0x2000);
EXPECT_NE(B, A2);
// Make sure things are not equal if they only differ by size.
B = A2;
B.setSize(0x101);
EXPECT_NE(B, A2);
// Make sure things are not equal if they only differ by name.
B = A2;
B.Name = 60;
EXPECT_NE(B, A2);
// Check < operator.
// Check less than where address differs.
B = A2;
B.setStartAddress(A2.startAddress() + 0x1000);
EXPECT_LT(A1, B);
// We use the < operator to take a variety of different FunctionInfo
// structs from a variety of sources: symtab, debug info, runtime info
// and we sort them and want the sorting to allow us to quickly get the
// best version of a function info.
FunctionInfo FISymtab(StartAddr, Size, NameOffset);
FunctionInfo FIWithLines(StartAddr, Size, NameOffset);
FIWithLines.OptLineTable = LineTable();
FIWithLines.OptLineTable->push(LineEntry(StartAddr,FileIdx,Line));
// Test that a FunctionInfo with just a name and size is less than one
// that has name, size and any number of line table entries
EXPECT_LT(FISymtab, FIWithLines);
FunctionInfo FIWithLinesAndInline = FIWithLines;
FIWithLinesAndInline.Inline = InlineInfo();
FIWithLinesAndInline.Inline->Ranges.insert(
AddressRange(StartAddr, StartAddr + 0x10));
// Test that a FunctionInfo with name, size, and line entries is less than
// the same one with valid inline info
EXPECT_LT(FIWithLines, FIWithLinesAndInline);
// Test if we have an entry with lines and one with more lines for the same
// range, the ones with more lines is greater than the one with less.
FunctionInfo FIWithMoreLines = FIWithLines;
FIWithMoreLines.OptLineTable->push(LineEntry(StartAddr,FileIdx,Line+5));
EXPECT_LT(FIWithLines, FIWithMoreLines);
// Test that if we have the same number of lines we compare the line entries
// in the FunctionInfo.OptLineTable.Lines vector.
FunctionInfo FIWithLinesWithHigherAddress = FIWithLines;
FIWithLinesWithHigherAddress.OptLineTable->get(0).Addr += 0x10;
EXPECT_LT(FIWithLines, FIWithLinesWithHigherAddress);
}
static void TestFunctionInfoDecodeError(llvm::support::endianness ByteOrder,
std::string Bytes,
const uint64_t BaseAddr,
std::string ExpectedErrorMsg) {
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
llvm::Expected<FunctionInfo> Decoded = FunctionInfo::decode(Data, BaseAddr);
// Make sure decoding fails.
ASSERT_FALSE((bool)Decoded);
// Make sure decoded object is the same as the one we encoded.
checkError(ExpectedErrorMsg, Decoded.takeError());
}
TEST(GSYMTest, TestFunctionInfoDecodeErrors) {
// Test decoding FunctionInfo objects that ensure we report an appropriate
// error message.
const llvm::support::endianness ByteOrder = llvm::support::little;
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
const uint64_t BaseAddr = 0x100;
TestFunctionInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000000: missing FunctionInfo Size");
FW.writeU32(0x100); // Function size.
TestFunctionInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000004: missing FunctionInfo Name");
// Write out an invalid Name string table offset of zero.
FW.writeU32(0);
TestFunctionInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000004: invalid FunctionInfo Name value 0x00000000");
// Modify the Name to be 0x00000001, which is a valid value.
FW.fixup32(0x00000001, 4);
TestFunctionInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000008: missing FunctionInfo InfoType value");
auto FixupOffset = FW.tell();
FW.writeU32(1); // InfoType::LineTableInfo.
TestFunctionInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x0000000c: missing FunctionInfo InfoType length");
FW.fixup32(4, FixupOffset); // Write an invalid InfoType enumeration value
FW.writeU32(0); // LineTableInfo InfoType data length.
TestFunctionInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000008: unsupported InfoType 4");
}
static void TestFunctionInfoEncodeError(llvm::support::endianness ByteOrder,
const FunctionInfo &FI,
std::string ExpectedErrorMsg) {
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
Expected<uint64_t> ExpectedOffset = FI.encode(FW);
ASSERT_FALSE(ExpectedOffset);
checkError(ExpectedErrorMsg, ExpectedOffset.takeError());
}
TEST(GSYMTest, TestFunctionInfoEncodeErrors) {
const uint64_t FuncAddr = 0x1000;
const uint64_t FuncSize = 0x100;
const uint32_t InvalidName = 0;
const uint32_t ValidName = 1;
FunctionInfo InvalidNameFI(FuncAddr, FuncSize, InvalidName);
TestFunctionInfoEncodeError(llvm::support::little, InvalidNameFI,
"attempted to encode invalid FunctionInfo object");
FunctionInfo InvalidLineTableFI(FuncAddr, FuncSize, ValidName);
// Empty line tables are not valid. Verify if the encoding of anything
// in our line table fails, that we see get the error propagated.
InvalidLineTableFI.OptLineTable = LineTable();
TestFunctionInfoEncodeError(llvm::support::little, InvalidLineTableFI,
"attempted to encode invalid LineTable object");
FunctionInfo InvalidInlineInfoFI(FuncAddr, FuncSize, ValidName);
// Empty line tables are not valid. Verify if the encoding of anything
// in our line table fails, that we see get the error propagated.
InvalidInlineInfoFI.Inline = InlineInfo();
TestFunctionInfoEncodeError(llvm::support::little, InvalidInlineInfoFI,
"attempted to encode invalid InlineInfo object");
}
static void TestFunctionInfoEncodeDecode(llvm::support::endianness ByteOrder,
const FunctionInfo &FI) {
// Test encoding and decoding FunctionInfo objects.
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
llvm::Expected<uint64_t> ExpectedOffset = FI.encode(FW);
ASSERT_TRUE(bool(ExpectedOffset));
// Verify we got the encoded offset back from the encode function.
ASSERT_EQ(ExpectedOffset.get(), 0ULL);
std::string Bytes(OutStrm.str());
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
llvm::Expected<FunctionInfo> Decoded = FunctionInfo::decode(Data,
FI.Range.Start);
// Make sure decoding succeeded.
ASSERT_TRUE((bool)Decoded);
// Make sure decoded object is the same as the one we encoded.
EXPECT_EQ(FI, Decoded.get());
}
static void AddLines(uint64_t FuncAddr, uint32_t FileIdx, FunctionInfo &FI) {
FI.OptLineTable = LineTable();
LineEntry Line0(FuncAddr + 0x000, FileIdx, 10);
LineEntry Line1(FuncAddr + 0x010, FileIdx, 11);
LineEntry Line2(FuncAddr + 0x100, FileIdx, 1000);
FI.OptLineTable->push(Line0);
FI.OptLineTable->push(Line1);
FI.OptLineTable->push(Line2);
}
static void AddInline(uint64_t FuncAddr, uint64_t FuncSize, FunctionInfo &FI) {
FI.Inline = InlineInfo();
FI.Inline->Ranges.insert(AddressRange(FuncAddr, FuncAddr + FuncSize));
InlineInfo Inline1;
Inline1.Ranges.insert(AddressRange(FuncAddr + 0x10, FuncAddr + 0x30));
Inline1.Name = 1;
Inline1.CallFile = 1;
Inline1.CallLine = 11;
FI.Inline->Children.push_back(Inline1);
}
TEST(GSYMTest, TestFunctionInfoEncoding) {
constexpr uint64_t FuncAddr = 0x1000;
constexpr uint64_t FuncSize = 0x100;
constexpr uint32_t FuncName = 1;
constexpr uint32_t FileIdx = 1;
// Make sure that we can encode and decode a FunctionInfo with no line table
// or inline info.
FunctionInfo FI(FuncAddr, FuncSize, FuncName);
TestFunctionInfoEncodeDecode(llvm::support::little, FI);
TestFunctionInfoEncodeDecode(llvm::support::big, FI);
// Make sure that we can encode and decode a FunctionInfo with a line table
// and no inline info.
FunctionInfo FILines(FuncAddr, FuncSize, FuncName);
AddLines(FuncAddr, FileIdx, FILines);
TestFunctionInfoEncodeDecode(llvm::support::little, FILines);
TestFunctionInfoEncodeDecode(llvm::support::big, FILines);
// Make sure that we can encode and decode a FunctionInfo with no line table
// and with inline info.
FunctionInfo FIInline(FuncAddr, FuncSize, FuncName);
AddInline(FuncAddr, FuncSize, FIInline);
TestFunctionInfoEncodeDecode(llvm::support::little, FIInline);
TestFunctionInfoEncodeDecode(llvm::support::big, FIInline);
// Make sure that we can encode and decode a FunctionInfo with no line table
// and with inline info.
FunctionInfo FIBoth(FuncAddr, FuncSize, FuncName);
AddLines(FuncAddr, FileIdx, FIBoth);
AddInline(FuncAddr, FuncSize, FIBoth);
TestFunctionInfoEncodeDecode(llvm::support::little, FIBoth);
TestFunctionInfoEncodeDecode(llvm::support::big, FIBoth);
}
static void TestInlineInfoEncodeDecode(llvm::support::endianness ByteOrder,
const InlineInfo &Inline) {
// Test encoding and decoding InlineInfo objects
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
const uint64_t BaseAddr = Inline.Ranges[0].Start;
llvm::Error Err = Inline.encode(FW, BaseAddr);
ASSERT_FALSE(Err);
std::string Bytes(OutStrm.str());
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
llvm::Expected<InlineInfo> Decoded = InlineInfo::decode(Data, BaseAddr);
// Make sure decoding succeeded.
ASSERT_TRUE((bool)Decoded);
// Make sure decoded object is the same as the one we encoded.
EXPECT_EQ(Inline, Decoded.get());
}
static void TestInlineInfoDecodeError(llvm::support::endianness ByteOrder,
std::string Bytes,
const uint64_t BaseAddr,
std::string ExpectedErrorMsg) {
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
llvm::Expected<InlineInfo> Decoded = InlineInfo::decode(Data, BaseAddr);
// Make sure decoding fails.
ASSERT_FALSE((bool)Decoded);
// Make sure decoded object is the same as the one we encoded.
checkError(ExpectedErrorMsg, Decoded.takeError());
}
static void TestInlineInfoEncodeError(llvm::support::endianness ByteOrder,
const InlineInfo &Inline,
std::string ExpectedErrorMsg) {
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
const uint64_t BaseAddr = Inline.Ranges.empty() ? 0 : Inline.Ranges[0].Start;
llvm::Error Err = Inline.encode(FW, BaseAddr);
checkError(ExpectedErrorMsg, std::move(Err));
}
TEST(GSYMTest, TestInlineInfo) {
// Test InlineInfo structs.
InlineInfo II;
EXPECT_FALSE(II.isValid());
II.Ranges.insert(AddressRange(0x1000, 0x2000));
// Make sure InlineInfo in valid with just an address range since
// top level InlineInfo objects have ranges with no name, call file
// or call line
EXPECT_TRUE(II.isValid());
// Make sure InlineInfo isn't after being cleared.
II.clear();
EXPECT_FALSE(II.isValid());
// Create an InlineInfo that contains the following data. The
// indentation of the address range indicates the parent child
// relationships of the InlineInfo objects:
//
// Variable Range and values
// =========== ====================================================
// Root [0x100-0x200) (no name, file, or line)
// Inline1 [0x150-0x160) Name = 1, File = 1, Line = 11
// Inline1Sub1 [0x152-0x155) Name = 2, File = 2, Line = 22
// Inline1Sub2 [0x157-0x158) Name = 3, File = 3, Line = 33
InlineInfo Root;
Root.Ranges.insert(AddressRange(0x100, 0x200));
InlineInfo Inline1;
Inline1.Ranges.insert(AddressRange(0x150, 0x160));
Inline1.Name = 1;
Inline1.CallFile = 1;
Inline1.CallLine = 11;
InlineInfo Inline1Sub1;
Inline1Sub1.Ranges.insert(AddressRange(0x152, 0x155));
Inline1Sub1.Name = 2;
Inline1Sub1.CallFile = 2;
Inline1Sub1.CallLine = 22;
InlineInfo Inline1Sub2;
Inline1Sub2.Ranges.insert(AddressRange(0x157, 0x158));
Inline1Sub2.Name = 3;
Inline1Sub2.CallFile = 3;
Inline1Sub2.CallLine = 33;
Inline1.Children.push_back(Inline1Sub1);
Inline1.Children.push_back(Inline1Sub2);
Root.Children.push_back(Inline1);
// Make sure an address that is out of range won't match
EXPECT_FALSE(Root.getInlineStack(0x50));
// Verify that we get no inline stacks for addresses out of [0x100-0x200)
EXPECT_FALSE(Root.getInlineStack(Root.Ranges[0].Start - 1));
EXPECT_FALSE(Root.getInlineStack(Root.Ranges[0].End));
// Verify we get no inline stack entries for addresses that are in
// [0x100-0x200) but not in [0x150-0x160)
EXPECT_FALSE(Root.getInlineStack(Inline1.Ranges[0].Start - 1));
EXPECT_FALSE(Root.getInlineStack(Inline1.Ranges[0].End));
// Verify we get one inline stack entry for addresses that are in
// [[0x150-0x160)) but not in [0x152-0x155) or [0x157-0x158)
auto InlineInfos = Root.getInlineStack(Inline1.Ranges[0].Start);
ASSERT_TRUE(InlineInfos);
ASSERT_EQ(InlineInfos->size(), 1u);
ASSERT_EQ(*InlineInfos->at(0), Inline1);
InlineInfos = Root.getInlineStack(Inline1.Ranges[0].End - 1);
EXPECT_TRUE(InlineInfos);
ASSERT_EQ(InlineInfos->size(), 1u);
ASSERT_EQ(*InlineInfos->at(0), Inline1);
// Verify we get two inline stack entries for addresses that are in
// [0x152-0x155)
InlineInfos = Root.getInlineStack(Inline1Sub1.Ranges[0].Start);
EXPECT_TRUE(InlineInfos);
ASSERT_EQ(InlineInfos->size(), 2u);
ASSERT_EQ(*InlineInfos->at(0), Inline1Sub1);
ASSERT_EQ(*InlineInfos->at(1), Inline1);
InlineInfos = Root.getInlineStack(Inline1Sub1.Ranges[0].End - 1);
EXPECT_TRUE(InlineInfos);
ASSERT_EQ(InlineInfos->size(), 2u);
ASSERT_EQ(*InlineInfos->at(0), Inline1Sub1);
ASSERT_EQ(*InlineInfos->at(1), Inline1);
// Verify we get two inline stack entries for addresses that are in
// [0x157-0x158)
InlineInfos = Root.getInlineStack(Inline1Sub2.Ranges[0].Start);
EXPECT_TRUE(InlineInfos);
ASSERT_EQ(InlineInfos->size(), 2u);
ASSERT_EQ(*InlineInfos->at(0), Inline1Sub2);
ASSERT_EQ(*InlineInfos->at(1), Inline1);
InlineInfos = Root.getInlineStack(Inline1Sub2.Ranges[0].End - 1);
EXPECT_TRUE(InlineInfos);
ASSERT_EQ(InlineInfos->size(), 2u);
ASSERT_EQ(*InlineInfos->at(0), Inline1Sub2);
ASSERT_EQ(*InlineInfos->at(1), Inline1);
// Test encoding and decoding InlineInfo objects
TestInlineInfoEncodeDecode(llvm::support::little, Root);
TestInlineInfoEncodeDecode(llvm::support::big, Root);
}
TEST(GSYMTest, TestInlineInfoEncodeErrors) {
// Test InlineInfo encoding errors.
// Test that we get an error when trying to encode an InlineInfo object
// that has no ranges.
InlineInfo Empty;
std::string EmptyErr("attempted to encode invalid InlineInfo object");
TestInlineInfoEncodeError(llvm::support::little, Empty, EmptyErr);
TestInlineInfoEncodeError(llvm::support::big, Empty, EmptyErr);
// Verify that we get an error trying to encode an InlineInfo object that has
// a child InlineInfo that has no ranges.
InlineInfo ContainsEmpty;
ContainsEmpty.Ranges.insert({0x100,200});
ContainsEmpty.Children.push_back(Empty);
TestInlineInfoEncodeError(llvm::support::little, ContainsEmpty, EmptyErr);
TestInlineInfoEncodeError(llvm::support::big, ContainsEmpty, EmptyErr);
// Verify that we get an error trying to encode an InlineInfo object that has
// a child whose address range is not contained in the parent address range.
InlineInfo ChildNotContained;
std::string ChildNotContainedErr("child range not contained in parent");
ChildNotContained.Ranges.insert({0x100,200});
InlineInfo ChildNotContainedChild;
ChildNotContainedChild.Ranges.insert({0x200,300});
ChildNotContained.Children.push_back(ChildNotContainedChild);
TestInlineInfoEncodeError(llvm::support::little, ChildNotContained,
ChildNotContainedErr);
TestInlineInfoEncodeError(llvm::support::big, ChildNotContained,
ChildNotContainedErr);
}
TEST(GSYMTest, TestInlineInfoDecodeErrors) {
// Test decoding InlineInfo objects that ensure we report an appropriate
// error message.
const llvm::support::endianness ByteOrder = llvm::support::little;
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
const uint64_t BaseAddr = 0x100;
TestInlineInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000000: missing InlineInfo address ranges data");
AddressRanges Ranges;
Ranges.insert({BaseAddr, BaseAddr+0x100});
Ranges.encode(FW, BaseAddr);
TestInlineInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000004: missing InlineInfo uint8_t indicating children");
FW.writeU8(0);
TestInlineInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000005: missing InlineInfo uint32_t for name");
FW.writeU32(0);
TestInlineInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000009: missing ULEB128 for InlineInfo call file");
FW.writeU8(0);
TestInlineInfoDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x0000000a: missing ULEB128 for InlineInfo call line");
}
TEST(GSYMTest, TestLineEntry) {
// test llvm::gsym::LineEntry structs.
const uint64_t ValidAddr = 0x1000;
const uint64_t InvalidFileIdx = 0;
const uint32_t ValidFileIdx = 1;
const uint32_t ValidLine = 5;
LineEntry Invalid;
EXPECT_FALSE(Invalid.isValid());
// Make sure that an entry is invalid if it has a bad file index.
LineEntry BadFile(ValidAddr, InvalidFileIdx, ValidLine);
EXPECT_FALSE(BadFile.isValid());
// Test operators
LineEntry E1(ValidAddr, ValidFileIdx, ValidLine);
LineEntry E2(ValidAddr, ValidFileIdx, ValidLine);
LineEntry DifferentAddr(ValidAddr + 1, ValidFileIdx, ValidLine);
LineEntry DifferentFile(ValidAddr, ValidFileIdx + 1, ValidLine);
LineEntry DifferentLine(ValidAddr, ValidFileIdx, ValidLine + 1);
EXPECT_TRUE(E1.isValid());
EXPECT_EQ(E1, E2);
EXPECT_NE(E1, DifferentAddr);
EXPECT_NE(E1, DifferentFile);
EXPECT_NE(E1, DifferentLine);
EXPECT_LT(E1, DifferentAddr);
}
TEST(GSYMTest, TestRanges) {
// test llvm::gsym::AddressRange.
const uint64_t StartAddr = 0x1000;
const uint64_t EndAddr = 0x2000;
// Verify constructor and API to ensure it takes start and end address.
const AddressRange Range(StartAddr, EndAddr);
EXPECT_EQ(Range.size(), EndAddr - StartAddr);
// Verify llvm::gsym::AddressRange::contains().
EXPECT_FALSE(Range.contains(0));
EXPECT_FALSE(Range.contains(StartAddr - 1));
EXPECT_TRUE(Range.contains(StartAddr));
EXPECT_TRUE(Range.contains(EndAddr - 1));
EXPECT_FALSE(Range.contains(EndAddr));
EXPECT_FALSE(Range.contains(UINT64_MAX));
const AddressRange RangeSame(StartAddr, EndAddr);
const AddressRange RangeDifferentStart(StartAddr + 1, EndAddr);
const AddressRange RangeDifferentEnd(StartAddr, EndAddr + 1);
const AddressRange RangeDifferentStartEnd(StartAddr + 1, EndAddr + 1);
// Test == and != with values that are the same
EXPECT_EQ(Range, RangeSame);
EXPECT_FALSE(Range != RangeSame);
// Test == and != with values that are the different
EXPECT_NE(Range, RangeDifferentStart);
EXPECT_NE(Range, RangeDifferentEnd);
EXPECT_NE(Range, RangeDifferentStartEnd);
EXPECT_FALSE(Range == RangeDifferentStart);
EXPECT_FALSE(Range == RangeDifferentEnd);
EXPECT_FALSE(Range == RangeDifferentStartEnd);
// Test "bool operator<(const AddressRange &, const AddressRange &)".
EXPECT_FALSE(Range < RangeSame);
EXPECT_FALSE(RangeSame < Range);
EXPECT_LT(Range, RangeDifferentStart);
EXPECT_LT(Range, RangeDifferentEnd);
EXPECT_LT(Range, RangeDifferentStartEnd);
// Test "bool operator<(const AddressRange &, uint64_t)"
EXPECT_LT(Range.Start, StartAddr + 1);
// Test "bool operator<(uint64_t, const AddressRange &)"
EXPECT_LT(StartAddr - 1, Range.Start);
// Verify llvm::gsym::AddressRange::isContiguousWith() and
// llvm::gsym::AddressRange::intersects().
const AddressRange EndsBeforeRangeStart(0, StartAddr - 1);
const AddressRange EndsAtRangeStart(0, StartAddr);
const AddressRange OverlapsRangeStart(StartAddr - 1, StartAddr + 1);
const AddressRange InsideRange(StartAddr + 1, EndAddr - 1);
const AddressRange OverlapsRangeEnd(EndAddr - 1, EndAddr + 1);
const AddressRange StartsAtRangeEnd(EndAddr, EndAddr + 0x100);
const AddressRange StartsAfterRangeEnd(EndAddr + 1, EndAddr + 0x100);
EXPECT_FALSE(Range.intersects(EndsBeforeRangeStart));
EXPECT_FALSE(Range.intersects(EndsAtRangeStart));
EXPECT_TRUE(Range.intersects(OverlapsRangeStart));
EXPECT_TRUE(Range.intersects(InsideRange));
EXPECT_TRUE(Range.intersects(OverlapsRangeEnd));
EXPECT_FALSE(Range.intersects(StartsAtRangeEnd));
EXPECT_FALSE(Range.intersects(StartsAfterRangeEnd));
// Test the functions that maintain GSYM address ranges:
// "bool AddressRange::contains(uint64_t Addr) const;"
// "void AddressRanges::insert(const AddressRange &R);"
AddressRanges Ranges;
Ranges.insert(AddressRange(0x1000, 0x2000));
Ranges.insert(AddressRange(0x2000, 0x3000));
Ranges.insert(AddressRange(0x4000, 0x5000));
EXPECT_FALSE(Ranges.contains(0));
EXPECT_FALSE(Ranges.contains(0x1000 - 1));
EXPECT_TRUE(Ranges.contains(0x1000));
EXPECT_TRUE(Ranges.contains(0x2000));
EXPECT_TRUE(Ranges.contains(0x4000));
EXPECT_TRUE(Ranges.contains(0x2000 - 1));
EXPECT_TRUE(Ranges.contains(0x3000 - 1));
EXPECT_FALSE(Ranges.contains(0x3000 + 1));
EXPECT_TRUE(Ranges.contains(0x5000 - 1));
EXPECT_FALSE(Ranges.contains(0x5000 + 1));
EXPECT_FALSE(Ranges.contains(UINT64_MAX));
EXPECT_FALSE(Ranges.contains(AddressRange()));
EXPECT_FALSE(Ranges.contains(AddressRange(0x1000-1, 0x1000)));
EXPECT_FALSE(Ranges.contains(AddressRange(0x1000, 0x1000)));
EXPECT_TRUE(Ranges.contains(AddressRange(0x1000, 0x1000+1)));
EXPECT_TRUE(Ranges.contains(AddressRange(0x1000, 0x2000)));
EXPECT_FALSE(Ranges.contains(AddressRange(0x1000, 0x2001)));
EXPECT_TRUE(Ranges.contains(AddressRange(0x2000, 0x3000)));
EXPECT_FALSE(Ranges.contains(AddressRange(0x2000, 0x3001)));
EXPECT_FALSE(Ranges.contains(AddressRange(0x3000, 0x3001)));
EXPECT_FALSE(Ranges.contains(AddressRange(0x1500, 0x4500)));
EXPECT_FALSE(Ranges.contains(AddressRange(0x5000, 0x5001)));
// Verify that intersecting ranges get combined
Ranges.clear();
Ranges.insert(AddressRange(0x1100, 0x1F00));
// Verify a wholy contained range that is added doesn't do anything.
Ranges.insert(AddressRange(0x1500, 0x1F00));
EXPECT_EQ(Ranges.size(), 1u);
EXPECT_EQ(Ranges[0], AddressRange(0x1100, 0x1F00));
// Verify a range that starts before and intersects gets combined.
Ranges.insert(AddressRange(0x1000, Ranges[0].Start + 1));
EXPECT_EQ(Ranges.size(), 1u);
EXPECT_EQ(Ranges[0], AddressRange(0x1000, 0x1F00));
// Verify a range that starts inside and extends ranges gets combined.
Ranges.insert(AddressRange(Ranges[0].End - 1, 0x2000));
EXPECT_EQ(Ranges.size(), 1u);
EXPECT_EQ(Ranges[0], AddressRange(0x1000, 0x2000));
// Verify that adjacent ranges don't get combined
Ranges.insert(AddressRange(0x2000, 0x3000));
EXPECT_EQ(Ranges.size(), 2u);
EXPECT_EQ(Ranges[0], AddressRange(0x1000, 0x2000));
EXPECT_EQ(Ranges[1], AddressRange(0x2000, 0x3000));
// Verify if we add an address range that intersects two ranges
// that they get combined
Ranges.insert(AddressRange(Ranges[0].End - 1, Ranges[1].Start + 1));
EXPECT_EQ(Ranges.size(), 1u);
EXPECT_EQ(Ranges[0], AddressRange(0x1000, 0x3000));
Ranges.insert(AddressRange(0x3000, 0x4000));
Ranges.insert(AddressRange(0x4000, 0x5000));
Ranges.insert(AddressRange(0x2000, 0x4500));
EXPECT_EQ(Ranges.size(), 1u);
EXPECT_EQ(Ranges[0], AddressRange(0x1000, 0x5000));
}
TEST(GSYMTest, TestStringTable) {
StringTable StrTab(StringRef("\0Hello\0World\0", 13));
// Test extracting strings from a string table.
EXPECT_EQ(StrTab.getString(0), "");
EXPECT_EQ(StrTab.getString(1), "Hello");
EXPECT_EQ(StrTab.getString(7), "World");
EXPECT_EQ(StrTab.getString(8), "orld");
// Test pointing to last NULL terminator gets empty string.
EXPECT_EQ(StrTab.getString(12), "");
// Test pointing to past end gets empty string.
EXPECT_EQ(StrTab.getString(13), "");
}
static void TestFileWriterHelper(llvm::support::endianness ByteOrder) {
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
const int64_t MinSLEB = INT64_MIN;
const int64_t MaxSLEB = INT64_MAX;
const uint64_t MinULEB = 0;
const uint64_t MaxULEB = UINT64_MAX;
const uint8_t U8 = 0x10;
const uint16_t U16 = 0x1122;
const uint32_t U32 = 0x12345678;
const uint64_t U64 = 0x33445566778899aa;
const char *Hello = "hello";
FW.writeU8(U8);
FW.writeU16(U16);
FW.writeU32(U32);
FW.writeU64(U64);
FW.alignTo(16);
const off_t FixupOffset = FW.tell();
FW.writeU32(0);
FW.writeSLEB(MinSLEB);
FW.writeSLEB(MaxSLEB);
FW.writeULEB(MinULEB);
FW.writeULEB(MaxULEB);
FW.writeNullTerminated(Hello);
// Test Seek, Tell using Fixup32.
FW.fixup32(U32, FixupOffset);
std::string Bytes(OutStrm.str());
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
uint64_t Offset = 0;
EXPECT_EQ(Data.getU8(&Offset), U8);
EXPECT_EQ(Data.getU16(&Offset), U16);
EXPECT_EQ(Data.getU32(&Offset), U32);
EXPECT_EQ(Data.getU64(&Offset), U64);
Offset = alignTo(Offset, 16);
EXPECT_EQ(Data.getU32(&Offset), U32);
EXPECT_EQ(Data.getSLEB128(&Offset), MinSLEB);
EXPECT_EQ(Data.getSLEB128(&Offset), MaxSLEB);
EXPECT_EQ(Data.getULEB128(&Offset), MinULEB);
EXPECT_EQ(Data.getULEB128(&Offset), MaxULEB);
EXPECT_EQ(Data.getCStrRef(&Offset), StringRef(Hello));
}
TEST(GSYMTest, TestFileWriter) {
TestFileWriterHelper(llvm::support::little);
TestFileWriterHelper(llvm::support::big);
}
TEST(GSYMTest, TestAddressRangeEncodeDecode) {
// Test encoding and decoding AddressRange objects. AddressRange objects
// are always stored as offsets from the a base address. The base address
// is the FunctionInfo's base address for function level ranges, and is
// the base address of the parent range for subranges.
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
const auto ByteOrder = llvm::support::endian::system_endianness();
FileWriter FW(OutStrm, ByteOrder);
const uint64_t BaseAddr = 0x1000;
const AddressRange Range1(0x1000, 0x1010);
const AddressRange Range2(0x1020, 0x1030);
Range1.encode(FW, BaseAddr);
Range2.encode(FW, BaseAddr);
std::string Bytes(OutStrm.str());
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
AddressRange DecodedRange1, DecodedRange2;
uint64_t Offset = 0;
DecodedRange1.decode(Data, BaseAddr, Offset);
DecodedRange2.decode(Data, BaseAddr, Offset);
EXPECT_EQ(Range1, DecodedRange1);
EXPECT_EQ(Range2, DecodedRange2);
}
static void TestAddressRangeEncodeDecodeHelper(const AddressRanges &Ranges,
const uint64_t BaseAddr) {
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
const auto ByteOrder = llvm::support::endian::system_endianness();
FileWriter FW(OutStrm, ByteOrder);
Ranges.encode(FW, BaseAddr);
std::string Bytes(OutStrm.str());
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
AddressRanges DecodedRanges;
uint64_t Offset = 0;
DecodedRanges.decode(Data, BaseAddr, Offset);
EXPECT_EQ(Ranges, DecodedRanges);
}
TEST(GSYMTest, TestAddressRangesEncodeDecode) {
// Test encoding and decoding AddressRanges. AddressRanges objects contain
// ranges that are stored as offsets from the a base address. The base address
// is the FunctionInfo's base address for function level ranges, and is the
// base address of the parent range for subranges.
const uint64_t BaseAddr = 0x1000;
// Test encoding and decoding with no ranges.
AddressRanges Ranges;
TestAddressRangeEncodeDecodeHelper(Ranges, BaseAddr);
// Test encoding and decoding with 1 range.
Ranges.insert(AddressRange(0x1000, 0x1010));
TestAddressRangeEncodeDecodeHelper(Ranges, BaseAddr);
// Test encoding and decoding with multiple ranges.
Ranges.insert(AddressRange(0x1020, 0x1030));
Ranges.insert(AddressRange(0x1050, 0x1070));
TestAddressRangeEncodeDecodeHelper(Ranges, BaseAddr);
}
static void TestLineTableHelper(llvm::support::endianness ByteOrder,
const LineTable <) {
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
const uint64_t BaseAddr = LT[0].Addr;
llvm::Error Err = LT.encode(FW, BaseAddr);
ASSERT_FALSE(Err);
std::string Bytes(OutStrm.str());
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
llvm::Expected<LineTable> Decoded = LineTable::decode(Data, BaseAddr);
// Make sure decoding succeeded.
ASSERT_TRUE((bool)Decoded);
// Make sure decoded object is the same as the one we encoded.
EXPECT_EQ(LT, Decoded.get());
}
TEST(GSYMTest, TestLineTable) {
const uint64_t StartAddr = 0x1000;
const uint32_t FileIdx = 1;
LineTable LT;
LineEntry Line0(StartAddr+0x000, FileIdx, 10);
LineEntry Line1(StartAddr+0x010, FileIdx, 11);
LineEntry Line2(StartAddr+0x100, FileIdx, 1000);
ASSERT_TRUE(LT.empty());
ASSERT_EQ(LT.size(), (size_t)0);
LT.push(Line0);
ASSERT_EQ(LT.size(), (size_t)1);
LT.push(Line1);
LT.push(Line2);
LT.push(LineEntry(StartAddr+0x120, FileIdx, 900));
LT.push(LineEntry(StartAddr+0x120, FileIdx, 2000));
LT.push(LineEntry(StartAddr+0x121, FileIdx, 2001));
LT.push(LineEntry(StartAddr+0x122, FileIdx, 2002));
LT.push(LineEntry(StartAddr+0x123, FileIdx, 2003));
ASSERT_FALSE(LT.empty());
ASSERT_EQ(LT.size(), (size_t)8);
// Test operator[].
ASSERT_EQ(LT[0], Line0);
ASSERT_EQ(LT[1], Line1);
ASSERT_EQ(LT[2], Line2);
// Test encoding and decoding line tables.
TestLineTableHelper(llvm::support::little, LT);
TestLineTableHelper(llvm::support::big, LT);
// Verify the clear method works as expected.
LT.clear();
ASSERT_TRUE(LT.empty());
ASSERT_EQ(LT.size(), (size_t)0);
LineTable LT1;
LineTable LT2;
// Test that two empty line tables are equal and neither are less than
// each other.
ASSERT_EQ(LT1, LT2);
ASSERT_FALSE(LT1 < LT2);
ASSERT_FALSE(LT2 < LT2);
// Test that a line table with less number of line entries is less than a
// line table with more line entries and that they are not equal.
LT2.push(Line0);
ASSERT_LT(LT1, LT2);
ASSERT_NE(LT1, LT2);
// Test that two line tables with the same entries are equal.
LT1.push(Line0);
ASSERT_EQ(LT1, LT2);
ASSERT_FALSE(LT1 < LT2);
ASSERT_FALSE(LT2 < LT2);
}
static void TestLineTableDecodeError(llvm::support::endianness ByteOrder,
std::string Bytes,
const uint64_t BaseAddr,
std::string ExpectedErrorMsg) {
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
llvm::Expected<LineTable> Decoded = LineTable::decode(Data, BaseAddr);
// Make sure decoding fails.
ASSERT_FALSE((bool)Decoded);
// Make sure decoded object is the same as the one we encoded.
checkError(ExpectedErrorMsg, Decoded.takeError());
}
TEST(GSYMTest, TestLineTableDecodeErrors) {
// Test decoding InlineInfo objects that ensure we report an appropriate
// error message.
const llvm::support::endianness ByteOrder = llvm::support::little;
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
const uint64_t BaseAddr = 0x100;
TestLineTableDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000000: missing LineTable MinDelta");
FW.writeU8(1); // MinDelta (ULEB)
TestLineTableDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000001: missing LineTable MaxDelta");
FW.writeU8(10); // MaxDelta (ULEB)
TestLineTableDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000002: missing LineTable FirstLine");
FW.writeU8(20); // FirstLine (ULEB)
TestLineTableDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000003: EOF found before EndSequence");
// Test a SetFile with the argument missing from the stream
FW.writeU8(1); // SetFile opcode (uint8_t)
TestLineTableDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000004: EOF found before SetFile value");
FW.writeU8(5); // SetFile value as index (ULEB)
// Test a AdvancePC with the argument missing from the stream
FW.writeU8(2); // AdvancePC opcode (uint8_t)
TestLineTableDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000006: EOF found before AdvancePC value");
FW.writeU8(20); // AdvancePC value as offset (ULEB)
// Test a AdvancePC with the argument missing from the stream
FW.writeU8(3); // AdvanceLine opcode (uint8_t)
TestLineTableDecodeError(ByteOrder, OutStrm.str(), BaseAddr,
"0x00000008: EOF found before AdvanceLine value");
FW.writeU8(20); // AdvanceLine value as offset (LLEB)
}
TEST(GSYMTest, TestLineTableEncodeErrors) {
const uint64_t BaseAddr = 0x1000;
const uint32_t FileIdx = 1;
const llvm::support::endianness ByteOrder = llvm::support::little;
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
LineTable LT;
checkError("attempted to encode invalid LineTable object",
LT.encode(FW, BaseAddr));
// Try to encode a line table where a line entry has an address that is less
// than BaseAddr and verify we get an appropriate error.
LineEntry Line0(BaseAddr+0x000, FileIdx, 10);
LineEntry Line1(BaseAddr+0x010, FileIdx, 11);
LT.push(Line0);
LT.push(Line1);
checkError("LineEntry has address 0x1000 which is less than the function "
"start address 0x1010", LT.encode(FW, BaseAddr+0x10));
LT.clear();
// Try to encode a line table where a line entries has an address that is less
// than BaseAddr and verify we get an appropriate error.
LT.push(Line1);
LT.push(Line0);
checkError("LineEntry in LineTable not in ascending order",
LT.encode(FW, BaseAddr));
LT.clear();
}
static void TestHeaderEncodeError(const Header &H,
std::string ExpectedErrorMsg) {
const support::endianness ByteOrder = llvm::support::little;
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
llvm::Error Err = H.encode(FW);
checkError(ExpectedErrorMsg, std::move(Err));
}
static void TestHeaderDecodeError(std::string Bytes,
std::string ExpectedErrorMsg) {
const support::endianness ByteOrder = llvm::support::little;
uint8_t AddressSize = 4;
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
llvm::Expected<Header> Decoded = Header::decode(Data);
// Make sure decoding fails.
ASSERT_FALSE((bool)Decoded);
// Make sure decoded object is the same as the one we encoded.
checkError(ExpectedErrorMsg, Decoded.takeError());
}
// Populate a GSYM header with valid values.
static void InitHeader(Header &H) {
H.Magic = GSYM_MAGIC;
H.Version = GSYM_VERSION;
H.AddrOffSize = 4;
H.UUIDSize = 16;
H.BaseAddress = 0x1000;
H.NumAddresses = 1;
H.StrtabOffset= 0x2000;
H.StrtabSize = 0x1000;
for (size_t i=0; i<GSYM_MAX_UUID_SIZE; ++i) {
if (i < H.UUIDSize)
H.UUID[i] = i;
else
H.UUID[i] = 0;
}
}
TEST(GSYMTest, TestHeaderEncodeErrors) {
Header H;
InitHeader(H);
H.Magic = 12;
TestHeaderEncodeError(H, "invalid GSYM magic 0x0000000c");
InitHeader(H);
H.Version = 12;
TestHeaderEncodeError(H, "unsupported GSYM version 12");
InitHeader(H);
H.AddrOffSize = 12;
TestHeaderEncodeError(H, "invalid address offset size 12");
InitHeader(H);
H.UUIDSize = 128;
TestHeaderEncodeError(H, "invalid UUID size 128");
}
TEST(GSYMTest, TestHeaderDecodeErrors) {
const llvm::support::endianness ByteOrder = llvm::support::little;
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
Header H;
InitHeader(H);
llvm::Error Err = H.encode(FW);
ASSERT_FALSE(Err);
FW.fixup32(12, offsetof(Header, Magic));
TestHeaderDecodeError(OutStrm.str(), "invalid GSYM magic 0x0000000c");
FW.fixup32(GSYM_MAGIC, offsetof(Header, Magic));
FW.fixup32(12, offsetof(Header, Version));
TestHeaderDecodeError(OutStrm.str(), "unsupported GSYM version 12");
FW.fixup32(GSYM_VERSION, offsetof(Header, Version));
FW.fixup32(12, offsetof(Header, AddrOffSize));
TestHeaderDecodeError(OutStrm.str(), "invalid address offset size 12");
FW.fixup32(4, offsetof(Header, AddrOffSize));
FW.fixup32(128, offsetof(Header, UUIDSize));
TestHeaderDecodeError(OutStrm.str(), "invalid UUID size 128");
}
static void TestHeaderEncodeDecode(const Header &H,
support::endianness ByteOrder) {
uint8_t AddressSize = 4;
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
llvm::Error Err = H.encode(FW);
ASSERT_FALSE(Err);
std::string Bytes(OutStrm.str());
DataExtractor Data(Bytes, ByteOrder == llvm::support::little, AddressSize);
llvm::Expected<Header> Decoded = Header::decode(Data);
// Make sure decoding succeeded.
ASSERT_TRUE((bool)Decoded);
EXPECT_EQ(H, Decoded.get());
}
TEST(GSYMTest, TestHeaderEncodeDecode) {
Header H;
InitHeader(H);
TestHeaderEncodeDecode(H, llvm::support::little);
TestHeaderEncodeDecode(H, llvm::support::big);
}
static void TestGsymCreatorEncodeError(llvm::support::endianness ByteOrder,
const GsymCreator &GC,
std::string ExpectedErrorMsg) {
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
llvm::Error Err = GC.encode(FW);
ASSERT_TRUE(bool(Err));
checkError(ExpectedErrorMsg, std::move(Err));
}
TEST(GSYMTest, TestGsymCreatorEncodeErrors) {
const uint8_t ValidUUID[] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13,
14, 15, 16};
const uint8_t InvalidUUID[] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13,
14, 15, 16, 17, 18, 19, 20, 21};
// Verify we get an error when trying to encode an GsymCreator with no
// function infos. We shouldn't be saving a GSYM file in this case since
// there is nothing inside of it.
GsymCreator GC;
TestGsymCreatorEncodeError(llvm::support::little, GC,
"no functions to encode");
const uint64_t FuncAddr = 0x1000;
const uint64_t FuncSize = 0x100;
const uint32_t FuncName = GC.insertString("foo");
// Verify we get an error trying to encode a GsymCreator that isn't
// finalized.
GC.addFunctionInfo(FunctionInfo(FuncAddr, FuncSize, FuncName));
TestGsymCreatorEncodeError(llvm::support::little, GC,
"GsymCreator wasn't finalized prior to encoding");
std::string finalizeIssues;
raw_string_ostream OS(finalizeIssues);
llvm::Error finalizeErr = GC.finalize(OS);
ASSERT_FALSE(bool(finalizeErr));
finalizeErr = GC.finalize(OS);
ASSERT_TRUE(bool(finalizeErr));
checkError("already finalized", std::move(finalizeErr));
// Verify we get an error trying to encode a GsymCreator with a UUID that is
// too long.
GC.setUUID(InvalidUUID);
TestGsymCreatorEncodeError(llvm::support::little, GC,
"invalid UUID size 21");
GC.setUUID(ValidUUID);
// Verify errors are propagated when we try to encoding an invalid line
// table.
GC.forEachFunctionInfo([](FunctionInfo &FI) -> bool {
FI.OptLineTable = LineTable(); // Invalid line table.
return false; // Stop iterating
});
TestGsymCreatorEncodeError(llvm::support::little, GC,
"attempted to encode invalid LineTable object");
// Verify errors are propagated when we try to encoding an invalid inline
// info.
GC.forEachFunctionInfo([](FunctionInfo &FI) -> bool {
FI.OptLineTable = llvm::None;
FI.Inline = InlineInfo(); // Invalid InlineInfo.
return false; // Stop iterating
});
TestGsymCreatorEncodeError(llvm::support::little, GC,
"attempted to encode invalid InlineInfo object");
}
static void Compare(const GsymCreator &GC, const GsymReader &GR) {
// Verify that all of the data in a GsymCreator is correctly decoded from
// a GsymReader. To do this, we iterator over
GC.forEachFunctionInfo([&](const FunctionInfo &FI) -> bool {
auto DecodedFI = GR.getFunctionInfo(FI.Range.Start);
EXPECT_TRUE(bool(DecodedFI));
EXPECT_EQ(FI, *DecodedFI);
return true; // Keep iterating over all FunctionInfo objects.
});
}
static void TestEncodeDecode(const GsymCreator &GC,
support::endianness ByteOrder, uint16_t Version,
uint8_t AddrOffSize, uint64_t BaseAddress,
uint32_t NumAddresses, ArrayRef<uint8_t> UUID) {
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
llvm::Error Err = GC.encode(FW);
ASSERT_FALSE((bool)Err);
Expected<GsymReader> GR = GsymReader::copyBuffer(OutStrm.str());
ASSERT_TRUE(bool(GR));
const Header &Hdr = GR->getHeader();
EXPECT_EQ(Hdr.Version, Version);
EXPECT_EQ(Hdr.AddrOffSize, AddrOffSize);
EXPECT_EQ(Hdr.UUIDSize, UUID.size());
EXPECT_EQ(Hdr.BaseAddress, BaseAddress);
EXPECT_EQ(Hdr.NumAddresses, NumAddresses);
EXPECT_EQ(ArrayRef<uint8_t>(Hdr.UUID, Hdr.UUIDSize), UUID);
Compare(GC, GR.get());
}
TEST(GSYMTest, TestGsymCreator1ByteAddrOffsets) {
uint8_t UUID[] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16};
GsymCreator GC;
GC.setUUID(UUID);
constexpr uint64_t BaseAddr = 0x1000;
constexpr uint8_t AddrOffSize = 1;
const uint32_t Func1Name = GC.insertString("foo");
const uint32_t Func2Name = GC.insertString("bar");
GC.addFunctionInfo(FunctionInfo(BaseAddr+0x00, 0x10, Func1Name));
GC.addFunctionInfo(FunctionInfo(BaseAddr+0x20, 0x10, Func2Name));
Error Err = GC.finalize(llvm::nulls());
ASSERT_FALSE(Err);
TestEncodeDecode(GC, llvm::support::little,
GSYM_VERSION,
AddrOffSize,
BaseAddr,
2, // NumAddresses
ArrayRef<uint8_t>(UUID));
TestEncodeDecode(GC, llvm::support::big,
GSYM_VERSION,
AddrOffSize,
BaseAddr,
2, // NumAddresses
ArrayRef<uint8_t>(UUID));
}
TEST(GSYMTest, TestGsymCreator2ByteAddrOffsets) {
uint8_t UUID[] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16};
GsymCreator GC;
GC.setUUID(UUID);
constexpr uint64_t BaseAddr = 0x1000;
constexpr uint8_t AddrOffSize = 2;
const uint32_t Func1Name = GC.insertString("foo");
const uint32_t Func2Name = GC.insertString("bar");
GC.addFunctionInfo(FunctionInfo(BaseAddr+0x000, 0x100, Func1Name));
GC.addFunctionInfo(FunctionInfo(BaseAddr+0x200, 0x100, Func2Name));
Error Err = GC.finalize(llvm::nulls());
ASSERT_FALSE(Err);
TestEncodeDecode(GC, llvm::support::little,
GSYM_VERSION,
AddrOffSize,
BaseAddr,
2, // NumAddresses
ArrayRef<uint8_t>(UUID));
TestEncodeDecode(GC, llvm::support::big,
GSYM_VERSION,
AddrOffSize,
BaseAddr,
2, // NumAddresses
ArrayRef<uint8_t>(UUID));
}
TEST(GSYMTest, TestGsymCreator4ByteAddrOffsets) {
uint8_t UUID[] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16};
GsymCreator GC;
GC.setUUID(UUID);
constexpr uint64_t BaseAddr = 0x1000;
constexpr uint8_t AddrOffSize = 4;
const uint32_t Func1Name = GC.insertString("foo");
const uint32_t Func2Name = GC.insertString("bar");
GC.addFunctionInfo(FunctionInfo(BaseAddr+0x000, 0x100, Func1Name));
GC.addFunctionInfo(FunctionInfo(BaseAddr+0x20000, 0x100, Func2Name));
Error Err = GC.finalize(llvm::nulls());
ASSERT_FALSE(Err);
TestEncodeDecode(GC, llvm::support::little,
GSYM_VERSION,
AddrOffSize,
BaseAddr,
2, // NumAddresses
ArrayRef<uint8_t>(UUID));
TestEncodeDecode(GC, llvm::support::big,
GSYM_VERSION,
AddrOffSize,
BaseAddr,
2, // NumAddresses
ArrayRef<uint8_t>(UUID));
}
TEST(GSYMTest, TestGsymCreator8ByteAddrOffsets) {
uint8_t UUID[] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16};
GsymCreator GC;
GC.setUUID(UUID);
constexpr uint64_t BaseAddr = 0x1000;
constexpr uint8_t AddrOffSize = 8;
const uint32_t Func1Name = GC.insertString("foo");
const uint32_t Func2Name = GC.insertString("bar");
GC.addFunctionInfo(FunctionInfo(BaseAddr+0x000, 0x100, Func1Name));
GC.addFunctionInfo(FunctionInfo(BaseAddr+0x100000000, 0x100, Func2Name));
Error Err = GC.finalize(llvm::nulls());
ASSERT_FALSE(Err);
TestEncodeDecode(GC, llvm::support::little,
GSYM_VERSION,
AddrOffSize,
BaseAddr,
2, // NumAddresses
ArrayRef<uint8_t>(UUID));
TestEncodeDecode(GC, llvm::support::big,
GSYM_VERSION,
AddrOffSize,
BaseAddr,
2, // NumAddresses
ArrayRef<uint8_t>(UUID));
}
static void VerifyFunctionInfo(const GsymReader &GR, uint64_t Addr,
const FunctionInfo &FI) {
auto ExpFI = GR.getFunctionInfo(Addr);
ASSERT_TRUE(bool(ExpFI));
ASSERT_EQ(FI, ExpFI.get());
}
static void VerifyFunctionInfoError(const GsymReader &GR, uint64_t Addr,
std::string ErrMessage) {
auto ExpFI = GR.getFunctionInfo(Addr);
ASSERT_FALSE(bool(ExpFI));
checkError(ErrMessage, ExpFI.takeError());
}
TEST(GSYMTest, TestGsymReader) {
uint8_t UUID[] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16};
GsymCreator GC;
GC.setUUID(UUID);
constexpr uint64_t BaseAddr = 0x1000;
constexpr uint64_t Func1Addr = BaseAddr;
constexpr uint64_t Func2Addr = BaseAddr+0x20;
constexpr uint64_t FuncSize = 0x10;
const uint32_t Func1Name = GC.insertString("foo");
const uint32_t Func2Name = GC.insertString("bar");
const auto ByteOrder = support::endian::system_endianness();
GC.addFunctionInfo(FunctionInfo(Func1Addr, FuncSize, Func1Name));
GC.addFunctionInfo(FunctionInfo(Func2Addr, FuncSize, Func2Name));
Error FinalizeErr = GC.finalize(llvm::nulls());
ASSERT_FALSE(FinalizeErr);
SmallString<512> Str;
raw_svector_ostream OutStrm(Str);
FileWriter FW(OutStrm, ByteOrder);
llvm::Error Err = GC.encode(FW);
ASSERT_FALSE((bool)Err);
if (auto ExpectedGR = GsymReader::copyBuffer(OutStrm.str())) {
const GsymReader &GR = ExpectedGR.get();
VerifyFunctionInfoError(GR, Func1Addr-1, "address 0xfff not in GSYM");
FunctionInfo Func1(Func1Addr, FuncSize, Func1Name);
VerifyFunctionInfo(GR, Func1Addr, Func1);
VerifyFunctionInfo(GR, Func1Addr+1, Func1);
VerifyFunctionInfo(GR, Func1Addr+FuncSize-1, Func1);
VerifyFunctionInfoError(GR, Func1Addr+FuncSize,
"address 0x1010 not in GSYM");
VerifyFunctionInfoError(GR, Func2Addr-1, "address 0x101f not in GSYM");
FunctionInfo Func2(Func2Addr, FuncSize, Func2Name);
VerifyFunctionInfo(GR, Func2Addr, Func2);
VerifyFunctionInfo(GR, Func2Addr+1, Func2);
VerifyFunctionInfo(GR, Func2Addr+FuncSize-1, Func2);
VerifyFunctionInfoError(GR, Func2Addr+FuncSize,
"address 0x1030 not in GSYM");
}
}
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