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gerrit-public.fairphone.software / toolchain / llvm-project / e3932eeea4d10d6835fef10e13b15144fedec6fb / . / clang / lib / CodeGen / CoverageMappingGen.cpp
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//===--- CoverageMappingGen.cpp - Coverage mapping generation ---*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// Instrumentation-based code coverage mapping generator
//
//===----------------------------------------------------------------------===//
#include "CoverageMappingGen.h"
#include "CodeGenFunction.h"
#include "clang/AST/StmtVisitor.h"
#include "clang/Lex/Lexer.h"
#include "llvm/ADT/SmallSet.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ProfileData/Coverage/CoverageMapping.h"
#include "llvm/ProfileData/Coverage/CoverageMappingReader.h"
#include "llvm/ProfileData/Coverage/CoverageMappingWriter.h"
#include "llvm/ProfileData/InstrProfReader.h"
#include "llvm/Support/FileSystem.h"
#include "llvm/Support/Path.h"
using namespace clang;
using namespace CodeGen;
using namespace llvm::coverage;
void CoverageSourceInfo::SourceRangeSkipped(SourceRange Range, SourceLocation) {
SkippedRanges.push_back(Range);
}
namespace {
/// A region of source code that can be mapped to a counter.
class SourceMappingRegion {
Counter Count;
/// The region's starting location.
Optional<SourceLocation> LocStart;
/// The region's ending location.
Optional<SourceLocation> LocEnd;
/// Whether this region should be emitted after its parent is emitted.
bool DeferRegion;
/// Whether this region is a gap region. The count from a gap region is set
/// as the line execution count if there are no other regions on the line.
bool GapRegion;
public:
SourceMappingRegion(Counter Count, Optional<SourceLocation> LocStart,
Optional<SourceLocation> LocEnd, bool DeferRegion = false,
bool GapRegion = false)
: Count(Count), LocStart(LocStart), LocEnd(LocEnd),
DeferRegion(DeferRegion), GapRegion(GapRegion) {}
const Counter &getCounter() const { return Count; }
void setCounter(Counter C) { Count = C; }
bool hasStartLoc() const { return LocStart.hasValue(); }
void setStartLoc(SourceLocation Loc) { LocStart = Loc; }
SourceLocation getBeginLoc() const {
assert(LocStart && "Region has no start location");
return *LocStart;
}
bool hasEndLoc() const { return LocEnd.hasValue(); }
void setEndLoc(SourceLocation Loc) {
assert(Loc.isValid() && "Setting an invalid end location");
LocEnd = Loc;
}
SourceLocation getEndLoc() const {
assert(LocEnd && "Region has no end location");
return *LocEnd;
}
bool isDeferred() const { return DeferRegion; }
void setDeferred(bool Deferred) { DeferRegion = Deferred; }
bool isGap() const { return GapRegion; }
void setGap(bool Gap) { GapRegion = Gap; }
};
/// Spelling locations for the start and end of a source region.
struct SpellingRegion {
/// The line where the region starts.
unsigned LineStart;
/// The column where the region starts.
unsigned ColumnStart;
/// The line where the region ends.
unsigned LineEnd;
/// The column where the region ends.
unsigned ColumnEnd;
SpellingRegion(SourceManager &SM, SourceLocation LocStart,
SourceLocation LocEnd) {
LineStart = SM.getSpellingLineNumber(LocStart);
ColumnStart = SM.getSpellingColumnNumber(LocStart);
LineEnd = SM.getSpellingLineNumber(LocEnd);
ColumnEnd = SM.getSpellingColumnNumber(LocEnd);
}
SpellingRegion(SourceManager &SM, SourceMappingRegion &R)
: SpellingRegion(SM, R.getBeginLoc(), R.getEndLoc()) {}
/// Check if the start and end locations appear in source order, i.e
/// top->bottom, left->right.
bool isInSourceOrder() const {
return (LineStart < LineEnd) ||
(LineStart == LineEnd && ColumnStart <= ColumnEnd);
}
};
/// Provides the common functionality for the different
/// coverage mapping region builders.
class CoverageMappingBuilder {
public:
CoverageMappingModuleGen &CVM;
SourceManager &SM;
const LangOptions &LangOpts;
private:
/// Map of clang's FileIDs to IDs used for coverage mapping.
llvm::SmallDenseMap<FileID, std::pair<unsigned, SourceLocation>, 8>
FileIDMapping;
public:
/// The coverage mapping regions for this function
llvm::SmallVector<CounterMappingRegion, 32> MappingRegions;
/// The source mapping regions for this function.
std::vector<SourceMappingRegion> SourceRegions;
/// A set of regions which can be used as a filter.
///
/// It is produced by emitExpansionRegions() and is used in
/// emitSourceRegions() to suppress producing code regions if
/// the same area is covered by expansion regions.
typedef llvm::SmallSet<std::pair<SourceLocation, SourceLocation>, 8>
SourceRegionFilter;
CoverageMappingBuilder(CoverageMappingModuleGen &CVM, SourceManager &SM,
const LangOptions &LangOpts)
: CVM(CVM), SM(SM), LangOpts(LangOpts) {}
/// Return the precise end location for the given token.
SourceLocation getPreciseTokenLocEnd(SourceLocation Loc) {
// We avoid getLocForEndOfToken here, because it doesn't do what we want for
// macro locations, which we just treat as expanded files.
unsigned TokLen =
Lexer::MeasureTokenLength(SM.getSpellingLoc(Loc), SM, LangOpts);
return Loc.getLocWithOffset(TokLen);
}
/// Return the start location of an included file or expanded macro.
SourceLocation getStartOfFileOrMacro(SourceLocation Loc) {
if (Loc.isMacroID())
return Loc.getLocWithOffset(-SM.getFileOffset(Loc));
return SM.getLocForStartOfFile(SM.getFileID(Loc));
}
/// Return the end location of an included file or expanded macro.
SourceLocation getEndOfFileOrMacro(SourceLocation Loc) {
if (Loc.isMacroID())
return Loc.getLocWithOffset(SM.getFileIDSize(SM.getFileID(Loc)) -
SM.getFileOffset(Loc));
return SM.getLocForEndOfFile(SM.getFileID(Loc));
}
/// Find out where the current file is included or macro is expanded.
SourceLocation getIncludeOrExpansionLoc(SourceLocation Loc) {
return Loc.isMacroID() ? SM.getImmediateExpansionRange(Loc).getBegin()
: SM.getIncludeLoc(SM.getFileID(Loc));
}
/// Return true if \c Loc is a location in a built-in macro.
bool isInBuiltin(SourceLocation Loc) {
return SM.getBufferName(SM.getSpellingLoc(Loc)) == "<built-in>";
}
/// Check whether \c Loc is included or expanded from \c Parent.
bool isNestedIn(SourceLocation Loc, FileID Parent) {
do {
Loc = getIncludeOrExpansionLoc(Loc);
if (Loc.isInvalid())
return false;
} while (!SM.isInFileID(Loc, Parent));
return true;
}
/// Get the start of \c S ignoring macro arguments and builtin macros.
SourceLocation getStart(const Stmt *S) {
SourceLocation Loc = S->getBeginLoc();
while (SM.isMacroArgExpansion(Loc) || isInBuiltin(Loc))
Loc = SM.getImmediateExpansionRange(Loc).getBegin();
return Loc;
}
/// Get the end of \c S ignoring macro arguments and builtin macros.
SourceLocation getEnd(const Stmt *S) {
SourceLocation Loc = S->getEndLoc();
while (SM.isMacroArgExpansion(Loc) || isInBuiltin(Loc))
Loc = SM.getImmediateExpansionRange(Loc).getBegin();
return getPreciseTokenLocEnd(Loc);
}
/// Find the set of files we have regions for and assign IDs
///
/// Fills \c Mapping with the virtual file mapping needed to write out
/// coverage and collects the necessary file information to emit source and
/// expansion regions.
void gatherFileIDs(SmallVectorImpl<unsigned> &Mapping) {
FileIDMapping.clear();
llvm::SmallSet<FileID, 8> Visited;
SmallVector<std::pair<SourceLocation, unsigned>, 8> FileLocs;
for (const auto &Region : SourceRegions) {
SourceLocation Loc = Region.getBeginLoc();
FileID File = SM.getFileID(Loc);
if (!Visited.insert(File).second)
continue;
// Do not map FileID's associated with system headers.
if (SM.isInSystemHeader(SM.getSpellingLoc(Loc)))
continue;
unsigned Depth = 0;
for (SourceLocation Parent = getIncludeOrExpansionLoc(Loc);
Parent.isValid(); Parent = getIncludeOrExpansionLoc(Parent))
++Depth;
FileLocs.push_back(std::make_pair(Loc, Depth));
}
std::stable_sort(FileLocs.begin(), FileLocs.end(), llvm::less_second());
for (const auto &FL : FileLocs) {
SourceLocation Loc = FL.first;
FileID SpellingFile = SM.getDecomposedSpellingLoc(Loc).first;
auto Entry = SM.getFileEntryForID(SpellingFile);
if (!Entry)
continue;
FileIDMapping[SM.getFileID(Loc)] = std::make_pair(Mapping.size(), Loc);
Mapping.push_back(CVM.getFileID(Entry));
}
}
/// Get the coverage mapping file ID for \c Loc.
///
/// If such file id doesn't exist, return None.
Optional<unsigned> getCoverageFileID(SourceLocation Loc) {
auto Mapping = FileIDMapping.find(SM.getFileID(Loc));
if (Mapping != FileIDMapping.end())
return Mapping->second.first;
return None;
}
/// Gather all the regions that were skipped by the preprocessor
/// using the constructs like #if.
void gatherSkippedRegions() {
/// An array of the minimum lineStarts and the maximum lineEnds
/// for mapping regions from the appropriate source files.
llvm::SmallVector<std::pair<unsigned, unsigned>, 8> FileLineRanges;
FileLineRanges.resize(
FileIDMapping.size(),
std::make_pair(std::numeric_limits<unsigned>::max(), 0));
for (const auto &R : MappingRegions) {
FileLineRanges[R.FileID].first =
std::min(FileLineRanges[R.FileID].first, R.LineStart);
FileLineRanges[R.FileID].second =
std::max(FileLineRanges[R.FileID].second, R.LineEnd);
}
auto SkippedRanges = CVM.getSourceInfo().getSkippedRanges();
for (const auto &I : SkippedRanges) {
auto LocStart = I.getBegin();
auto LocEnd = I.getEnd();
assert(SM.isWrittenInSameFile(LocStart, LocEnd) &&
"region spans multiple files");
auto CovFileID = getCoverageFileID(LocStart);
if (!CovFileID)
continue;
SpellingRegion SR{SM, LocStart, LocEnd};
auto Region = CounterMappingRegion::makeSkipped(
*CovFileID, SR.LineStart, SR.ColumnStart, SR.LineEnd, SR.ColumnEnd);
// Make sure that we only collect the regions that are inside
// the source code of this function.
if (Region.LineStart >= FileLineRanges[*CovFileID].first &&
Region.LineEnd <= FileLineRanges[*CovFileID].second)
MappingRegions.push_back(Region);
}
}
/// Generate the coverage counter mapping regions from collected
/// source regions.
void emitSourceRegions(const SourceRegionFilter &Filter) {
for (const auto &Region : SourceRegions) {
assert(Region.hasEndLoc() && "incomplete region");
SourceLocation LocStart = Region.getBeginLoc();
assert(SM.getFileID(LocStart).isValid() && "region in invalid file");
// Ignore regions from system headers.
if (SM.isInSystemHeader(SM.getSpellingLoc(LocStart)))
continue;
auto CovFileID = getCoverageFileID(LocStart);
// Ignore regions that don't have a file, such as builtin macros.
if (!CovFileID)
continue;
SourceLocation LocEnd = Region.getEndLoc();
assert(SM.isWrittenInSameFile(LocStart, LocEnd) &&
"region spans multiple files");
// Don't add code regions for the area covered by expansion regions.
// This not only suppresses redundant regions, but sometimes prevents
// creating regions with wrong counters if, for example, a statement's
// body ends at the end of a nested macro.
if (Filter.count(std::make_pair(LocStart, LocEnd)))
continue;
// Find the spelling locations for the mapping region.
SpellingRegion SR{SM, LocStart, LocEnd};
assert(SR.isInSourceOrder() && "region start and end out of order");
if (Region.isGap()) {
MappingRegions.push_back(CounterMappingRegion::makeGapRegion(
Region.getCounter(), *CovFileID, SR.LineStart, SR.ColumnStart,
SR.LineEnd, SR.ColumnEnd));
} else {
MappingRegions.push_back(CounterMappingRegion::makeRegion(
Region.getCounter(), *CovFileID, SR.LineStart, SR.ColumnStart,
SR.LineEnd, SR.ColumnEnd));
}
}
}
/// Generate expansion regions for each virtual file we've seen.
SourceRegionFilter emitExpansionRegions() {
SourceRegionFilter Filter;
for (const auto &FM : FileIDMapping) {
SourceLocation ExpandedLoc = FM.second.second;
SourceLocation ParentLoc = getIncludeOrExpansionLoc(ExpandedLoc);
if (ParentLoc.isInvalid())
continue;
auto ParentFileID = getCoverageFileID(ParentLoc);
if (!ParentFileID)
continue;
auto ExpandedFileID = getCoverageFileID(ExpandedLoc);
assert(ExpandedFileID && "expansion in uncovered file");
SourceLocation LocEnd = getPreciseTokenLocEnd(ParentLoc);
assert(SM.isWrittenInSameFile(ParentLoc, LocEnd) &&
"region spans multiple files");
Filter.insert(std::make_pair(ParentLoc, LocEnd));
SpellingRegion SR{SM, ParentLoc, LocEnd};
assert(SR.isInSourceOrder() && "region start and end out of order");
MappingRegions.push_back(CounterMappingRegion::makeExpansion(
*ParentFileID, *ExpandedFileID, SR.LineStart, SR.ColumnStart,
SR.LineEnd, SR.ColumnEnd));
}
return Filter;
}
};
/// Creates unreachable coverage regions for the functions that
/// are not emitted.
struct EmptyCoverageMappingBuilder : public CoverageMappingBuilder {
EmptyCoverageMappingBuilder(CoverageMappingModuleGen &CVM, SourceManager &SM,
const LangOptions &LangOpts)
: CoverageMappingBuilder(CVM, SM, LangOpts) {}
void VisitDecl(const Decl *D) {
if (!D->hasBody())
return;
auto Body = D->getBody();
SourceLocation Start = getStart(Body);
SourceLocation End = getEnd(Body);
if (!SM.isWrittenInSameFile(Start, End)) {
// Walk up to find the common ancestor.
// Correct the locations accordingly.
FileID StartFileID = SM.getFileID(Start);
FileID EndFileID = SM.getFileID(End);
while (StartFileID != EndFileID && !isNestedIn(End, StartFileID)) {
Start = getIncludeOrExpansionLoc(Start);
assert(Start.isValid() &&
"Declaration start location not nested within a known region");
StartFileID = SM.getFileID(Start);
}
while (StartFileID != EndFileID) {
End = getPreciseTokenLocEnd(getIncludeOrExpansionLoc(End));
assert(End.isValid() &&
"Declaration end location not nested within a known region");
EndFileID = SM.getFileID(End);
}
}
SourceRegions.emplace_back(Counter(), Start, End);
}
/// Write the mapping data to the output stream
void write(llvm::raw_ostream &OS) {
SmallVector<unsigned, 16> FileIDMapping;
gatherFileIDs(FileIDMapping);
emitSourceRegions(SourceRegionFilter());
if (MappingRegions.empty())
return;
CoverageMappingWriter Writer(FileIDMapping, None, MappingRegions);
Writer.write(OS);
}
};
/// A StmtVisitor that creates coverage mapping regions which map
/// from the source code locations to the PGO counters.
struct CounterCoverageMappingBuilder
: public CoverageMappingBuilder,
public ConstStmtVisitor<CounterCoverageMappingBuilder> {
/// The map of statements to count values.
llvm::DenseMap<const Stmt *, unsigned> &CounterMap;
/// A stack of currently live regions.
std::vector<SourceMappingRegion> RegionStack;
/// The currently deferred region: its end location and count can be set once
/// its parent has been popped from the region stack.
Optional<SourceMappingRegion> DeferredRegion;
CounterExpressionBuilder Builder;
/// A location in the most recently visited file or macro.
///
/// This is used to adjust the active source regions appropriately when
/// expressions cross file or macro boundaries.
SourceLocation MostRecentLocation;
/// Location of the last terminated region.
Optional<std::pair<SourceLocation, size_t>> LastTerminatedRegion;
/// Return a counter for the subtraction of \c RHS from \c LHS
Counter subtractCounters(Counter LHS, Counter RHS) {
return Builder.subtract(LHS, RHS);
}
/// Return a counter for the sum of \c LHS and \c RHS.
Counter addCounters(Counter LHS, Counter RHS) {
return Builder.add(LHS, RHS);
}
Counter addCounters(Counter C1, Counter C2, Counter C3) {
return addCounters(addCounters(C1, C2), C3);
}
/// Return the region counter for the given statement.
///
/// This should only be called on statements that have a dedicated counter.
Counter getRegionCounter(const Stmt *S) {
return Counter::getCounter(CounterMap[S]);
}
/// Push a region onto the stack.
///
/// Returns the index on the stack where the region was pushed. This can be
/// used with popRegions to exit a "scope", ending the region that was pushed.
size_t pushRegion(Counter Count, Optional<SourceLocation> StartLoc = None,
Optional<SourceLocation> EndLoc = None) {
if (StartLoc) {
MostRecentLocation = *StartLoc;
completeDeferred(Count, MostRecentLocation);
}
RegionStack.emplace_back(Count, StartLoc, EndLoc);
return RegionStack.size() - 1;
}
/// Complete any pending deferred region by setting its end location and
/// count, and then pushing it onto the region stack.
size_t completeDeferred(Counter Count, SourceLocation DeferredEndLoc) {
size_t Index = RegionStack.size();
if (!DeferredRegion)
return Index;
// Consume the pending region.
SourceMappingRegion DR = DeferredRegion.getValue();
DeferredRegion = None;
// If the region ends in an expansion, find the expansion site.
FileID StartFile = SM.getFileID(DR.getBeginLoc());
if (SM.getFileID(DeferredEndLoc) != StartFile) {
if (isNestedIn(DeferredEndLoc, StartFile)) {
do {
DeferredEndLoc = getIncludeOrExpansionLoc(DeferredEndLoc);
} while (StartFile != SM.getFileID(DeferredEndLoc));
} else {
return Index;
}
}
// The parent of this deferred region ends where the containing decl ends,
// so the region isn't useful.
if (DR.getBeginLoc() == DeferredEndLoc)
return Index;
// If we're visiting statements in non-source order (e.g switch cases or
// a loop condition) we can't construct a sensible deferred region.
if (!SpellingRegion(SM, DR.getBeginLoc(), DeferredEndLoc).isInSourceOrder())
return Index;
DR.setGap(true);
DR.setCounter(Count);
DR.setEndLoc(DeferredEndLoc);
handleFileExit(DeferredEndLoc);
RegionStack.push_back(DR);
return Index;
}
/// Complete a deferred region created after a terminated region at the
/// top-level.
void completeTopLevelDeferredRegion(Counter Count,
SourceLocation DeferredEndLoc) {
if (DeferredRegion || !LastTerminatedRegion)
return;
if (LastTerminatedRegion->second != RegionStack.size())
return;
SourceLocation Start = LastTerminatedRegion->first;
if (SM.getFileID(Start) != SM.getMainFileID())
return;
SourceMappingRegion DR = RegionStack.back();
DR.setStartLoc(Start);
DR.setDeferred(false);
DeferredRegion = DR;
completeDeferred(Count, DeferredEndLoc);
}
/// Pop regions from the stack into the function's list of regions.
///
/// Adds all regions from \c ParentIndex to the top of the stack to the
/// function's \c SourceRegions.
void popRegions(size_t ParentIndex) {
assert(RegionStack.size() >= ParentIndex && "parent not in stack");
bool ParentOfDeferredRegion = false;
while (RegionStack.size() > ParentIndex) {
SourceMappingRegion &Region = RegionStack.back();
if (Region.hasStartLoc()) {
SourceLocation StartLoc = Region.getBeginLoc();
SourceLocation EndLoc = Region.hasEndLoc()
? Region.getEndLoc()
: RegionStack[ParentIndex].getEndLoc();
while (!SM.isWrittenInSameFile(StartLoc, EndLoc)) {
// The region ends in a nested file or macro expansion. Create a
// separate region for each expansion.
SourceLocation NestedLoc = getStartOfFileOrMacro(EndLoc);
assert(SM.isWrittenInSameFile(NestedLoc, EndLoc));
if (!isRegionAlreadyAdded(NestedLoc, EndLoc))
SourceRegions.emplace_back(Region.getCounter(), NestedLoc, EndLoc);
EndLoc = getPreciseTokenLocEnd(getIncludeOrExpansionLoc(EndLoc));
if (EndLoc.isInvalid())
llvm::report_fatal_error("File exit not handled before popRegions");
}
Region.setEndLoc(EndLoc);
MostRecentLocation = EndLoc;
// If this region happens to span an entire expansion, we need to make
// sure we don't overlap the parent region with it.
if (StartLoc == getStartOfFileOrMacro(StartLoc) &&
EndLoc == getEndOfFileOrMacro(EndLoc))
MostRecentLocation = getIncludeOrExpansionLoc(EndLoc);
assert(SM.isWrittenInSameFile(Region.getBeginLoc(), EndLoc));
assert(SpellingRegion(SM, Region).isInSourceOrder());
SourceRegions.push_back(Region);
if (ParentOfDeferredRegion) {
ParentOfDeferredRegion = false;
// If there's an existing deferred region, keep the old one, because
// it means there are two consecutive returns (or a similar pattern).
if (!DeferredRegion.hasValue() &&
// File IDs aren't gathered within macro expansions, so it isn't
// useful to try and create a deferred region inside of one.
!EndLoc.isMacroID())
DeferredRegion =
SourceMappingRegion(Counter::getZero(), EndLoc, None);
}
} else if (Region.isDeferred()) {
assert(!ParentOfDeferredRegion && "Consecutive deferred regions");
ParentOfDeferredRegion = true;
}
RegionStack.pop_back();
// If the zero region pushed after the last terminated region no longer
// exists, clear its cached information.
if (LastTerminatedRegion &&
RegionStack.size() < LastTerminatedRegion->second)
LastTerminatedRegion = None;
}
assert(!ParentOfDeferredRegion && "Deferred region with no parent");
}
/// Return the currently active region.
SourceMappingRegion &getRegion() {
assert(!RegionStack.empty() && "statement has no region");
return RegionStack.back();
}
/// Propagate counts through the children of \c S.
Counter propagateCounts(Counter TopCount, const Stmt *S) {
SourceLocation StartLoc = getStart(S);
SourceLocation EndLoc = getEnd(S);
size_t Index = pushRegion(TopCount, StartLoc, EndLoc);
Visit(S);
Counter ExitCount = getRegion().getCounter();
popRegions(Index);
// The statement may be spanned by an expansion. Make sure we handle a file
// exit out of this expansion before moving to the next statement.
if (SM.isBeforeInTranslationUnit(StartLoc, S->getBeginLoc()))
MostRecentLocation = EndLoc;
return ExitCount;
}
/// Check whether a region with bounds \c StartLoc and \c EndLoc
/// is already added to \c SourceRegions.
bool isRegionAlreadyAdded(SourceLocation StartLoc, SourceLocation EndLoc) {
return SourceRegions.rend() !=
std::find_if(SourceRegions.rbegin(), SourceRegions.rend(),
[&](const SourceMappingRegion &Region) {
return Region.getBeginLoc() == StartLoc &&
Region.getEndLoc() == EndLoc;
});
}
/// Adjust the most recently visited location to \c EndLoc.
///
/// This should be used after visiting any statements in non-source order.
void adjustForOutOfOrderTraversal(SourceLocation EndLoc) {
MostRecentLocation = EndLoc;
// The code region for a whole macro is created in handleFileExit() when
// it detects exiting of the virtual file of that macro. If we visited
// statements in non-source order, we might already have such a region
// added, for example, if a body of a loop is divided among multiple
// macros. Avoid adding duplicate regions in such case.
if (getRegion().hasEndLoc() &&
MostRecentLocation == getEndOfFileOrMacro(MostRecentLocation) &&
isRegionAlreadyAdded(getStartOfFileOrMacro(MostRecentLocation),
MostRecentLocation))
MostRecentLocation = getIncludeOrExpansionLoc(MostRecentLocation);
}
/// Adjust regions and state when \c NewLoc exits a file.
///
/// If moving from our most recently tracked location to \c NewLoc exits any
/// files, this adjusts our current region stack and creates the file regions
/// for the exited file.
void handleFileExit(SourceLocation NewLoc) {
if (NewLoc.isInvalid() ||
SM.isWrittenInSameFile(MostRecentLocation, NewLoc))
return;
// If NewLoc is not in a file that contains MostRecentLocation, walk up to
// find the common ancestor.
SourceLocation LCA = NewLoc;
FileID ParentFile = SM.getFileID(LCA);
while (!isNestedIn(MostRecentLocation, ParentFile)) {
LCA = getIncludeOrExpansionLoc(LCA);
if (LCA.isInvalid() || SM.isWrittenInSameFile(LCA, MostRecentLocation)) {
// Since there isn't a common ancestor, no file was exited. We just need
// to adjust our location to the new file.
MostRecentLocation = NewLoc;
return;
}
ParentFile = SM.getFileID(LCA);
}
llvm::SmallSet<SourceLocation, 8> StartLocs;
Optional<Counter> ParentCounter;
for (SourceMappingRegion &I : llvm::reverse(RegionStack)) {
if (!I.hasStartLoc())
continue;
SourceLocation Loc = I.getBeginLoc();
if (!isNestedIn(Loc, ParentFile)) {
ParentCounter = I.getCounter();
break;
}
while (!SM.isInFileID(Loc, ParentFile)) {
// The most nested region for each start location is the one with the
// correct count. We avoid creating redundant regions by stopping once
// we've seen this region.
if (StartLocs.insert(Loc).second)
SourceRegions.emplace_back(I.getCounter(), Loc,
getEndOfFileOrMacro(Loc));
Loc = getIncludeOrExpansionLoc(Loc);
}
I.setStartLoc(getPreciseTokenLocEnd(Loc));
}
if (ParentCounter) {
// If the file is contained completely by another region and doesn't
// immediately start its own region, the whole file gets a region
// corresponding to the parent.
SourceLocation Loc = MostRecentLocation;
while (isNestedIn(Loc, ParentFile)) {
SourceLocation FileStart = getStartOfFileOrMacro(Loc);
if (StartLocs.insert(FileStart).second) {
SourceRegions.emplace_back(*ParentCounter, FileStart,
getEndOfFileOrMacro(Loc));
assert(SpellingRegion(SM, SourceRegions.back()).isInSourceOrder());
}
Loc = getIncludeOrExpansionLoc(Loc);
}
}
MostRecentLocation = NewLoc;
}
/// Ensure that \c S is included in the current region.
void extendRegion(const Stmt *S) {
SourceMappingRegion &Region = getRegion();
SourceLocation StartLoc = getStart(S);
handleFileExit(StartLoc);
if (!Region.hasStartLoc())
Region.setStartLoc(StartLoc);
completeDeferred(Region.getCounter(), StartLoc);
}
/// Mark \c S as a terminator, starting a zero region.
void terminateRegion(const Stmt *S) {
extendRegion(S);
SourceMappingRegion &Region = getRegion();
SourceLocation EndLoc = getEnd(S);
if (!Region.hasEndLoc())
Region.setEndLoc(EndLoc);
pushRegion(Counter::getZero());
auto &ZeroRegion = getRegion();
ZeroRegion.setDeferred(true);
LastTerminatedRegion = {EndLoc, RegionStack.size()};
}
/// Find a valid gap range between \p AfterLoc and \p BeforeLoc.
Optional<SourceRange> findGapAreaBetween(SourceLocation AfterLoc,
SourceLocation BeforeLoc) {
// If the start and end locations of the gap are both within the same macro
// file, the range may not be in source order.
if (AfterLoc.isMacroID() || BeforeLoc.isMacroID())
return None;
if (!SM.isWrittenInSameFile(AfterLoc, BeforeLoc))
return None;
return {{AfterLoc, BeforeLoc}};
}
/// Find the source range after \p AfterStmt and before \p BeforeStmt.
Optional<SourceRange> findGapAreaBetween(const Stmt *AfterStmt,
const Stmt *BeforeStmt) {
return findGapAreaBetween(getPreciseTokenLocEnd(getEnd(AfterStmt)),
getStart(BeforeStmt));
}
/// Emit a gap region between \p StartLoc and \p EndLoc with the given count.
void fillGapAreaWithCount(SourceLocation StartLoc, SourceLocation EndLoc,
Counter Count) {
if (StartLoc == EndLoc)
return;
assert(SpellingRegion(SM, StartLoc, EndLoc).isInSourceOrder());
handleFileExit(StartLoc);
size_t Index = pushRegion(Count, StartLoc, EndLoc);
getRegion().setGap(true);
handleFileExit(EndLoc);
popRegions(Index);
}
/// Keep counts of breaks and continues inside loops.
struct BreakContinue {
Counter BreakCount;
Counter ContinueCount;
};
SmallVector<BreakContinue, 8> BreakContinueStack;
CounterCoverageMappingBuilder(
CoverageMappingModuleGen &CVM,
llvm::DenseMap<const Stmt *, unsigned> &CounterMap, SourceManager &SM,
const LangOptions &LangOpts)
: CoverageMappingBuilder(CVM, SM, LangOpts), CounterMap(CounterMap),
DeferredRegion(None) {}
/// Write the mapping data to the output stream
void write(llvm::raw_ostream &OS) {
llvm::SmallVector<unsigned, 8> VirtualFileMapping;
gatherFileIDs(VirtualFileMapping);
SourceRegionFilter Filter = emitExpansionRegions();
assert(!DeferredRegion && "Deferred region never completed");
emitSourceRegions(Filter);
gatherSkippedRegions();
if (MappingRegions.empty())
return;
CoverageMappingWriter Writer(VirtualFileMapping, Builder.getExpressions(),
MappingRegions);
Writer.write(OS);
}
void VisitStmt(const Stmt *S) {
if (S->getBeginLoc().isValid())
extendRegion(S);
for (const Stmt *Child : S->children())
if (Child)
this->Visit(Child);
handleFileExit(getEnd(S));
}
void VisitDecl(const Decl *D) {
assert(!DeferredRegion && "Deferred region never completed");
Stmt *Body = D->getBody();
// Do not propagate region counts into system headers.
if (Body && SM.isInSystemHeader(SM.getSpellingLoc(getStart(Body))))
return;
propagateCounts(getRegionCounter(Body), Body);
assert(RegionStack.empty() && "Regions entered but never exited");
// Discard the last uncompleted deferred region in a decl, if one exists.
// This prevents lines at the end of a function containing only whitespace
// or closing braces from being marked as uncovered.
DeferredRegion = None;
}
void VisitReturnStmt(const ReturnStmt *S) {
extendRegion(S);
if (S->getRetValue())
Visit(S->getRetValue());
terminateRegion(S);
}
void VisitCXXThrowExpr(const CXXThrowExpr *E) {
extendRegion(E);
if (E->getSubExpr())
Visit(E->getSubExpr());
terminateRegion(E);
}
void VisitGotoStmt(const GotoStmt *S) { terminateRegion(S); }
void VisitLabelStmt(const LabelStmt *S) {
Counter LabelCount = getRegionCounter(S);
SourceLocation Start = getStart(S);
completeTopLevelDeferredRegion(LabelCount, Start);
completeDeferred(LabelCount, Start);
// We can't extendRegion here or we risk overlapping with our new region.
handleFileExit(Start);
pushRegion(LabelCount, Start);
Visit(S->getSubStmt());
}
void VisitBreakStmt(const BreakStmt *S) {
assert(!BreakContinueStack.empty() && "break not in a loop or switch!");
BreakContinueStack.back().BreakCount = addCounters(
BreakContinueStack.back().BreakCount, getRegion().getCounter());
// FIXME: a break in a switch should terminate regions for all preceding
// case statements, not just the most recent one.
terminateRegion(S);
}
void VisitContinueStmt(const ContinueStmt *S) {
assert(!BreakContinueStack.empty() && "continue stmt not in a loop!");
BreakContinueStack.back().ContinueCount = addCounters(
BreakContinueStack.back().ContinueCount, getRegion().getCounter());
terminateRegion(S);
}
void VisitCallExpr(const CallExpr *E) {
VisitStmt(E);
// Terminate the region when we hit a noreturn function.
// (This is helpful dealing with switch statements.)
QualType CalleeType = E->getCallee()->getType();
if (getFunctionExtInfo(*CalleeType).getNoReturn())
terminateRegion(E);
}
void VisitWhileStmt(const WhileStmt *S) {
extendRegion(S);
Counter ParentCount = getRegion().getCounter();
Counter BodyCount = getRegionCounter(S);
// Handle the body first so that we can get the backedge count.
BreakContinueStack.push_back(BreakContinue());
extendRegion(S->getBody());
Counter BackedgeCount = propagateCounts(BodyCount, S->getBody());
BreakContinue BC = BreakContinueStack.pop_back_val();
// Go back to handle the condition.
Counter CondCount =
addCounters(ParentCount, BackedgeCount, BC.ContinueCount);
propagateCounts(CondCount, S->getCond());
adjustForOutOfOrderTraversal(getEnd(S));
// The body count applies to the area immediately after the increment.
auto Gap = findGapAreaBetween(S->getCond(), S->getBody());
if (Gap)
fillGapAreaWithCount(Gap->getBegin(), Gap->getEnd(), BodyCount);
Counter OutCount =
addCounters(BC.BreakCount, subtractCounters(CondCount, BodyCount));
if (OutCount != ParentCount)
pushRegion(OutCount);
}
void VisitDoStmt(const DoStmt *S) {
extendRegion(S);
Counter ParentCount = getRegion().getCounter();
Counter BodyCount = getRegionCounter(S);
BreakContinueStack.push_back(BreakContinue());
extendRegion(S->getBody());
Counter BackedgeCount =
propagateCounts(addCounters(ParentCount, BodyCount), S->getBody());
BreakContinue BC = BreakContinueStack.pop_back_val();
Counter CondCount = addCounters(BackedgeCount, BC.ContinueCount);
propagateCounts(CondCount, S->getCond());
Counter OutCount =
addCounters(BC.BreakCount, subtractCounters(CondCount, BodyCount));
if (OutCount != ParentCount)
pushRegion(OutCount);
}
void VisitForStmt(const ForStmt *S) {
extendRegion(S);
if (S->getInit())
Visit(S->getInit());
Counter ParentCount = getRegion().getCounter();
Counter BodyCount = getRegionCounter(S);
// The loop increment may contain a break or continue.
if (S->getInc())
BreakContinueStack.emplace_back();
// Handle the body first so that we can get the backedge count.
BreakContinueStack.emplace_back();
extendRegion(S->getBody());
Counter BackedgeCount = propagateCounts(BodyCount, S->getBody());
BreakContinue BodyBC = BreakContinueStack.pop_back_val();
// The increment is essentially part of the body but it needs to include
// the count for all the continue statements.
BreakContinue IncrementBC;
if (const Stmt *Inc = S->getInc()) {
propagateCounts(addCounters(BackedgeCount, BodyBC.ContinueCount), Inc);
IncrementBC = BreakContinueStack.pop_back_val();
}
// Go back to handle the condition.
Counter CondCount = addCounters(
addCounters(ParentCount, BackedgeCount, BodyBC.ContinueCount),
IncrementBC.ContinueCount);
if (const Expr *Cond = S->getCond()) {
propagateCounts(CondCount, Cond);
adjustForOutOfOrderTraversal(getEnd(S));
}
// The body count applies to the area immediately after the increment.
auto Gap = findGapAreaBetween(getPreciseTokenLocEnd(S->getRParenLoc()),
getStart(S->getBody()));
if (Gap)
fillGapAreaWithCount(Gap->getBegin(), Gap->getEnd(), BodyCount);
Counter OutCount = addCounters(BodyBC.BreakCount, IncrementBC.BreakCount,
subtractCounters(CondCount, BodyCount));
if (OutCount != ParentCount)
pushRegion(OutCount);
}
void VisitCXXForRangeStmt(const CXXForRangeStmt *S) {
extendRegion(S);
if (S->getInit())
Visit(S->getInit());
Visit(S->getLoopVarStmt());
Visit(S->getRangeStmt());
Counter ParentCount = getRegion().getCounter();
Counter BodyCount = getRegionCounter(S);
BreakContinueStack.push_back(BreakContinue());
extendRegion(S->getBody());
Counter BackedgeCount = propagateCounts(BodyCount, S->getBody());
BreakContinue BC = BreakContinueStack.pop_back_val();
// The body count applies to the area immediately after the range.
auto Gap = findGapAreaBetween(getPreciseTokenLocEnd(S->getRParenLoc()),
getStart(S->getBody()));
if (Gap)
fillGapAreaWithCount(Gap->getBegin(), Gap->getEnd(), BodyCount);
Counter LoopCount =
addCounters(ParentCount, BackedgeCount, BC.ContinueCount);
Counter OutCount =
addCounters(BC.BreakCount, subtractCounters(LoopCount, BodyCount));
if (OutCount != ParentCount)
pushRegion(OutCount);
}
void VisitObjCForCollectionStmt(const ObjCForCollectionStmt *S) {
extendRegion(S);
Visit(S->getElement());
Counter ParentCount = getRegion().getCounter();
Counter BodyCount = getRegionCounter(S);
BreakContinueStack.push_back(BreakContinue());
extendRegion(S->getBody());
Counter BackedgeCount = propagateCounts(BodyCount, S->getBody());
BreakContinue BC = BreakContinueStack.pop_back_val();
// The body count applies to the area immediately after the collection.
auto Gap = findGapAreaBetween(getPreciseTokenLocEnd(S->getRParenLoc()),
getStart(S->getBody()));
if (Gap)
fillGapAreaWithCount(Gap->getBegin(), Gap->getEnd(), BodyCount);
Counter LoopCount =
addCounters(ParentCount, BackedgeCount, BC.ContinueCount);
Counter OutCount =
addCounters(BC.BreakCount, subtractCounters(LoopCount, BodyCount));
if (OutCount != ParentCount)
pushRegion(OutCount);
}
void VisitSwitchStmt(const SwitchStmt *S) {
extendRegion(S);
if (S->getInit())
Visit(S->getInit());
Visit(S->getCond());
BreakContinueStack.push_back(BreakContinue());
const Stmt *Body = S->getBody();
extendRegion(Body);
if (const auto *CS = dyn_cast<CompoundStmt>(Body)) {
if (!CS->body_empty()) {
// Make a region for the body of the switch. If the body starts with
// a case, that case will reuse this region; otherwise, this covers
// the unreachable code at the beginning of the switch body.
size_t Index =
pushRegion(Counter::getZero(), getStart(CS->body_front()));
for (const auto *Child : CS->children())
Visit(Child);
// Set the end for the body of the switch, if it isn't already set.
for (size_t i = RegionStack.size(); i != Index; --i) {
if (!RegionStack[i - 1].hasEndLoc())
RegionStack[i - 1].setEndLoc(getEnd(CS->body_back()));
}
popRegions(Index);
}
} else
propagateCounts(Counter::getZero(), Body);
BreakContinue BC = BreakContinueStack.pop_back_val();
if (!BreakContinueStack.empty())
BreakContinueStack.back().ContinueCount = addCounters(
BreakContinueStack.back().ContinueCount, BC.ContinueCount);
Counter ExitCount = getRegionCounter(S);
SourceLocation ExitLoc = getEnd(S);
pushRegion(ExitCount);
// Ensure that handleFileExit recognizes when the end location is located
// in a different file.
MostRecentLocation = getStart(S);
handleFileExit(ExitLoc);
}
void VisitSwitchCase(const SwitchCase *S) {
extendRegion(S);
SourceMappingRegion &Parent = getRegion();
Counter Count = addCounters(Parent.getCounter(), getRegionCounter(S));
// Reuse the existing region if it starts at our label. This is typical of
// the first case in a switch.
if (Parent.hasStartLoc() && Parent.getBeginLoc() == getStart(S))
Parent.setCounter(Count);
else
pushRegion(Count, getStart(S));
if (const auto *CS = dyn_cast<CaseStmt>(S)) {
Visit(CS->getLHS());
if (const Expr *RHS = CS->getRHS())
Visit(RHS);
}
Visit(S->getSubStmt());
}
void VisitIfStmt(const IfStmt *S) {
extendRegion(S);
if (S->getInit())
Visit(S->getInit());
// Extend into the condition before we propagate through it below - this is
// needed to handle macros that generate the "if" but not the condition.
extendRegion(S->getCond());
Counter ParentCount = getRegion().getCounter();
Counter ThenCount = getRegionCounter(S);
// Emitting a counter for the condition makes it easier to interpret the
// counter for the body when looking at the coverage.
propagateCounts(ParentCount, S->getCond());
// The 'then' count applies to the area immediately after the condition.
auto Gap = findGapAreaBetween(S->getCond(), S->getThen());
if (Gap)
fillGapAreaWithCount(Gap->getBegin(), Gap->getEnd(), ThenCount);
extendRegion(S->getThen());
Counter OutCount = propagateCounts(ThenCount, S->getThen());
Counter ElseCount = subtractCounters(ParentCount, ThenCount);
if (const Stmt *Else = S->getElse()) {
// The 'else' count applies to the area immediately after the 'then'.
Gap = findGapAreaBetween(S->getThen(), Else);
if (Gap)
fillGapAreaWithCount(Gap->getBegin(), Gap->getEnd(), ElseCount);
extendRegion(Else);
OutCount = addCounters(OutCount, propagateCounts(ElseCount, Else));
} else
OutCount = addCounters(OutCount, ElseCount);
if (OutCount != ParentCount)
pushRegion(OutCount);
}
void VisitCXXTryStmt(const CXXTryStmt *S) {
extendRegion(S);
// Handle macros that generate the "try" but not the rest.
extendRegion(S->getTryBlock());
Counter ParentCount = getRegion().getCounter();
propagateCounts(ParentCount, S->getTryBlock());
for (unsigned I = 0, E = S->getNumHandlers(); I < E; ++I)
Visit(S->getHandler(I));
Counter ExitCount = getRegionCounter(S);
pushRegion(ExitCount);
}
void VisitCXXCatchStmt(const CXXCatchStmt *S) {
propagateCounts(getRegionCounter(S), S->getHandlerBlock());
}
void VisitAbstractConditionalOperator(const AbstractConditionalOperator *E) {
extendRegion(E);
Counter ParentCount = getRegion().getCounter();
Counter TrueCount = getRegionCounter(E);
Visit(E->getCond());
if (!isa<BinaryConditionalOperator>(E)) {
// The 'then' count applies to the area immediately after the condition.
auto Gap =
findGapAreaBetween(E->getQuestionLoc(), getStart(E->getTrueExpr()));
if (Gap)
fillGapAreaWithCount(Gap->getBegin(), Gap->getEnd(), TrueCount);
extendRegion(E->getTrueExpr());
propagateCounts(TrueCount, E->getTrueExpr());
}
extendRegion(E->getFalseExpr());
propagateCounts(subtractCounters(ParentCount, TrueCount),
E->getFalseExpr());
}
void VisitBinLAnd(const BinaryOperator *E) {
extendRegion(E->getLHS());
propagateCounts(getRegion().getCounter(), E->getLHS());
handleFileExit(getEnd(E->getLHS()));
extendRegion(E->getRHS());
propagateCounts(getRegionCounter(E), E->getRHS());
}
void VisitBinLOr(const BinaryOperator *E) {
extendRegion(E->getLHS());
propagateCounts(getRegion().getCounter(), E->getLHS());
handleFileExit(getEnd(E->getLHS()));
extendRegion(E->getRHS());
propagateCounts(getRegionCounter(E), E->getRHS());
}
void VisitLambdaExpr(const LambdaExpr *LE) {
// Lambdas are treated as their own functions for now, so we shouldn't
// propagate counts into them.
}
};
std::string getCoverageSection(const CodeGenModule &CGM) {
return llvm::getInstrProfSectionName(
llvm::IPSK_covmap,
CGM.getContext().getTargetInfo().getTriple().getObjectFormat());
}
std::string normalizeFilename(StringRef Filename) {
llvm::SmallString<256> Path(Filename);
llvm::sys::fs::make_absolute(Path);
llvm::sys::path::remove_dots(Path, /*remove_dot_dots=*/true);
return Path.str().str();
}
} // end anonymous namespace
static void dump(llvm::raw_ostream &OS, StringRef FunctionName,
ArrayRef<CounterExpression> Expressions,
ArrayRef<CounterMappingRegion> Regions) {
OS << FunctionName << ":\n";
CounterMappingContext Ctx(Expressions);
for (const auto &R : Regions) {
OS.indent(2);
switch (R.Kind) {
case CounterMappingRegion::CodeRegion:
break;
case CounterMappingRegion::ExpansionRegion:
OS << "Expansion,";
break;
case CounterMappingRegion::SkippedRegion:
OS << "Skipped,";
break;
case CounterMappingRegion::GapRegion:
OS << "Gap,";
break;
}
OS << "File " << R.FileID << ", " << R.LineStart << ":" << R.ColumnStart
<< " -> " << R.LineEnd << ":" << R.ColumnEnd << " = ";
Ctx.dump(R.Count, OS);
if (R.Kind == CounterMappingRegion::ExpansionRegion)
OS << " (Expanded file = " << R.ExpandedFileID << ")";
OS << "\n";
}
}
void CoverageMappingModuleGen::addFunctionMappingRecord(
llvm::GlobalVariable *NamePtr, StringRef NameValue, uint64_t FuncHash,
const std::string &CoverageMapping, bool IsUsed) {
llvm::LLVMContext &Ctx = CGM.getLLVMContext();
if (!FunctionRecordTy) {
#define COVMAP_FUNC_RECORD(Type, LLVMType, Name, Init) LLVMType,
llvm::Type *FunctionRecordTypes[] = {
#include "llvm/ProfileData/InstrProfData.inc"
};
FunctionRecordTy =
llvm::StructType::get(Ctx, makeArrayRef(FunctionRecordTypes),
/*isPacked=*/true);
}
#define COVMAP_FUNC_RECORD(Type, LLVMType, Name, Init) Init,
llvm::Constant *FunctionRecordVals[] = {
#include "llvm/ProfileData/InstrProfData.inc"
};
FunctionRecords.push_back(llvm::ConstantStruct::get(
FunctionRecordTy, makeArrayRef(FunctionRecordVals)));
if (!IsUsed)
FunctionNames.push_back(
llvm::ConstantExpr::getBitCast(NamePtr, llvm::Type::getInt8PtrTy(Ctx)));
CoverageMappings.push_back(CoverageMapping);
if (CGM.getCodeGenOpts().DumpCoverageMapping) {
// Dump the coverage mapping data for this function by decoding the
// encoded data. This allows us to dump the mapping regions which were
// also processed by the CoverageMappingWriter which performs
// additional minimization operations such as reducing the number of
// expressions.
std::vector<StringRef> Filenames;
std::vector<CounterExpression> Expressions;
std::vector<CounterMappingRegion> Regions;
llvm::SmallVector<std::string, 16> FilenameStrs;
llvm::SmallVector<StringRef, 16> FilenameRefs;
FilenameStrs.resize(FileEntries.size());
FilenameRefs.resize(FileEntries.size());
for (const auto &Entry : FileEntries) {
auto I = Entry.second;
FilenameStrs[I] = normalizeFilename(Entry.first->getName());
FilenameRefs[I] = FilenameStrs[I];
}
RawCoverageMappingReader Reader(CoverageMapping, FilenameRefs, Filenames,
Expressions, Regions);
if (Reader.read())
return;
dump(llvm::outs(), NameValue, Expressions, Regions);
}
}
void CoverageMappingModuleGen::emit() {
if (FunctionRecords.empty())
return;
llvm::LLVMContext &Ctx = CGM.getLLVMContext();
auto *Int32Ty = llvm::Type::getInt32Ty(Ctx);
// Create the filenames and merge them with coverage mappings
llvm::SmallVector<std::string, 16> FilenameStrs;
llvm::SmallVector<StringRef, 16> FilenameRefs;
FilenameStrs.resize(FileEntries.size());
FilenameRefs.resize(FileEntries.size());
for (const auto &Entry : FileEntries) {
auto I = Entry.second;
FilenameStrs[I] = normalizeFilename(Entry.first->getName());
FilenameRefs[I] = FilenameStrs[I];
}
std::string FilenamesAndCoverageMappings;
llvm::raw_string_ostream OS(FilenamesAndCoverageMappings);
CoverageFilenamesSectionWriter(FilenameRefs).write(OS);
std::string RawCoverageMappings =
llvm::join(CoverageMappings.begin(), CoverageMappings.end(), "");
OS << RawCoverageMappings;
size_t CoverageMappingSize = RawCoverageMappings.size();
size_t FilenamesSize = OS.str().size() - CoverageMappingSize;
// Append extra zeroes if necessary to ensure that the size of the filenames
// and coverage mappings is a multiple of 8.
if (size_t Rem = OS.str().size() % 8) {
CoverageMappingSize += 8 - Rem;
OS.write_zeros(8 - Rem);
}
auto *FilenamesAndMappingsVal =
llvm::ConstantDataArray::getString(Ctx, OS.str(), false);
// Create the deferred function records array
auto RecordsTy =
llvm::ArrayType::get(FunctionRecordTy, FunctionRecords.size());
auto RecordsVal = llvm::ConstantArray::get(RecordsTy, FunctionRecords);
llvm::Type *CovDataHeaderTypes[] = {
#define COVMAP_HEADER(Type, LLVMType, Name, Init) LLVMType,
#include "llvm/ProfileData/InstrProfData.inc"
};
auto CovDataHeaderTy =
llvm::StructType::get(Ctx, makeArrayRef(CovDataHeaderTypes));
llvm::Constant *CovDataHeaderVals[] = {
#define COVMAP_HEADER(Type, LLVMType, Name, Init) Init,
#include "llvm/ProfileData/InstrProfData.inc"
};
auto CovDataHeaderVal = llvm::ConstantStruct::get(
CovDataHeaderTy, makeArrayRef(CovDataHeaderVals));
// Create the coverage data record
llvm::Type *CovDataTypes[] = {CovDataHeaderTy, RecordsTy,
FilenamesAndMappingsVal->getType()};
auto CovDataTy = llvm::StructType::get(Ctx, makeArrayRef(CovDataTypes));
llvm::Constant *TUDataVals[] = {CovDataHeaderVal, RecordsVal,
FilenamesAndMappingsVal};
auto CovDataVal =
llvm::ConstantStruct::get(CovDataTy, makeArrayRef(TUDataVals));
auto CovData = new llvm::GlobalVariable(
CGM.getModule(), CovDataTy, true, llvm::GlobalValue::InternalLinkage,
CovDataVal, llvm::getCoverageMappingVarName());
CovData->setSection(getCoverageSection(CGM));
CovData->setAlignment(8);
// Make sure the data doesn't get deleted.
CGM.addUsedGlobal(CovData);
// Create the deferred function records array
if (!FunctionNames.empty()) {
auto NamesArrTy = llvm::ArrayType::get(llvm::Type::getInt8PtrTy(Ctx),
FunctionNames.size());
auto NamesArrVal = llvm::ConstantArray::get(NamesArrTy, FunctionNames);
// This variable will *NOT* be emitted to the object file. It is used
// to pass the list of names referenced to codegen.
new llvm::GlobalVariable(CGM.getModule(), NamesArrTy, true,
llvm::GlobalValue::InternalLinkage, NamesArrVal,
llvm::getCoverageUnusedNamesVarName());
}
}
unsigned CoverageMappingModuleGen::getFileID(const FileEntry *File) {
auto It = FileEntries.find(File);
if (It != FileEntries.end())
return It->second;
unsigned FileID = FileEntries.size();
FileEntries.insert(std::make_pair(File, FileID));
return FileID;
}
void CoverageMappingGen::emitCounterMapping(const Decl *D,
llvm::raw_ostream &OS) {
assert(CounterMap);
CounterCoverageMappingBuilder Walker(CVM, *CounterMap, SM, LangOpts);
Walker.VisitDecl(D);
Walker.write(OS);
}
void CoverageMappingGen::emitEmptyMapping(const Decl *D,
llvm::raw_ostream &OS) {
EmptyCoverageMappingBuilder Walker(CVM, SM, LangOpts);
Walker.VisitDecl(D);
Walker.write(OS);
}