lib/ObjectYAML/MinidumpEmitter.cpp - llvm - Git at Google

 //===- yaml2minidump.cpp - Convert a YAML file to a minidump file ---------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ObjectYAML/MinidumpYAML.h"
 #include "llvm/ObjectYAML/yaml2obj.h"
 #include "llvm/Support/ConvertUTF.h"
 #include "llvm/Support/raw_ostream.h"

 using namespace llvm;
 using namespace llvm::minidump;
 using namespace llvm::MinidumpYAML;

 namespace {
 /// A helper class to manage the placement of various structures into the final
 /// minidump binary. Space for objects can be allocated via various allocate***
 /// methods, while the final minidump file is written by calling the writeTo
 /// method. The plain versions of allocation functions take a reference to the
 /// data which is to be written (and hence the data must be available until
 /// writeTo is called), while the "New" versions allocate the data in an
 /// allocator-managed buffer, which is available until the allocator object is
 /// destroyed. For both kinds of functions, it is possible to modify the
 /// data for which the space has been "allocated" until the final writeTo call.
 /// This is useful for "linking" the allocated structures via their offsets.
 class BlobAllocator {
 public:
   size_t tell() const { return NextOffset; }

   size_t allocateCallback(size_t Size,
                           std::function<void(raw_ostream &)> Callback) {
     size_t Offset = NextOffset;
     NextOffset += Size;
     Callbacks.push_back(std::move(Callback));
     return Offset;
   }

   size_t allocateBytes(ArrayRef<uint8_t> Data) {
     return allocateCallback(
         Data.size(), [Data](raw_ostream &OS) { OS << toStringRef(Data); });
   }

   size_t allocateBytes(yaml::BinaryRef Data) {
     return allocateCallback(Data.binary_size(), [Data](raw_ostream &OS) {
       Data.writeAsBinary(OS);
     });
   }

   template <typename T> size_t allocateArray(ArrayRef<T> Data) {
     return allocateBytes({reinterpret_cast<const uint8_t *>(Data.data()),
                           sizeof(T) * Data.size()});
   }

   template <typename T, typename RangeType>
   std::pair<size_t, MutableArrayRef<T>>
   allocateNewArray(const iterator_range<RangeType> &Range);

   template <typename T> size_t allocateObject(const T &Data) {
     return allocateArray(makeArrayRef(Data));
   }

   template <typename T, typename... Types>
   std::pair<size_t, T *> allocateNewObject(Types &&... Args) {
     T *Object = new (Temporaries.Allocate<T>()) T(std::forward<Types>(Args)...);
     return {allocateObject(*Object), Object};
   }

   size_t allocateString(StringRef Str);

   void writeTo(raw_ostream &OS) const;

 private:
   size_t NextOffset = 0;

   BumpPtrAllocator Temporaries;
   std::vector<std::function<void(raw_ostream &)>> Callbacks;
 };
 } // namespace

 template <typename T, typename RangeType>
 std::pair<size_t, MutableArrayRef<T>>
 BlobAllocator::allocateNewArray(const iterator_range<RangeType> &Range) {
   size_t Num = std::distance(Range.begin(), Range.end());
   MutableArrayRef<T> Array(Temporaries.Allocate<T>(Num), Num);
   std::uninitialized_copy(Range.begin(), Range.end(), Array.begin());
   return {allocateArray(Array), Array};
 }

 size_t BlobAllocator::allocateString(StringRef Str) {
   SmallVector<UTF16, 32> WStr;
   bool OK = convertUTF8ToUTF16String(Str, WStr);
   assert(OK && "Invalid UTF8 in Str?");
   (void)OK;

   // The utf16 string is null-terminated, but the terminator is not counted in
   // the string size.
   WStr.push_back(0);
   size_t Result =
       allocateNewObject<support::ulittle32_t>(2 * (WStr.size() - 1)).first;
   allocateNewArray<support::ulittle16_t>(make_range(WStr.begin(), WStr.end()));
   return Result;
 }

 void BlobAllocator::writeTo(raw_ostream &OS) const {
   size_t BeginOffset = OS.tell();
   for (const auto &Callback : Callbacks)
     Callback(OS);
   assert(OS.tell() == BeginOffset + NextOffset &&
          "Callbacks wrote an unexpected number of bytes.");
   (void)BeginOffset;
 }

 static LocationDescriptor layout(BlobAllocator &File, yaml::BinaryRef Data) {
   return {support::ulittle32_t(Data.binary_size()),
           support::ulittle32_t(File.allocateBytes(Data))};
 }

 static size_t layout(BlobAllocator &File, MinidumpYAML::ExceptionStream &S) {
   File.allocateObject(S.MDExceptionStream);

   size_t DataEnd = File.tell();

   // Lay out the thread context data, (which is not a part of the stream).
   // TODO: This usually (always?) matches the thread context of the
   // corresponding thread, and may overlap memory regions as well.  We could
   // add a level of indirection to the MinidumpYAML format (like an array of
   // Blobs that the LocationDescriptors index into) to be able to distinguish
   // the cases where location descriptions overlap vs happen to reference
   // identical data.
   S.MDExceptionStream.ThreadContext = layout(File, S.ThreadContext);

   return DataEnd;
 }

 static void layout(BlobAllocator &File, MemoryListStream::entry_type &Range) {
   Range.Entry.Memory = layout(File, Range.Content);
 }

 static void layout(BlobAllocator &File, ModuleListStream::entry_type &M) {
   M.Entry.ModuleNameRVA = File.allocateString(M.Name);

   M.Entry.CvRecord = layout(File, M.CvRecord);
   M.Entry.MiscRecord = layout(File, M.MiscRecord);
 }

 static void layout(BlobAllocator &File, ThreadListStream::entry_type &T) {
   T.Entry.Stack.Memory = layout(File, T.Stack);
   T.Entry.Context = layout(File, T.Context);
 }

 template <typename EntryT>
 static size_t layout(BlobAllocator &File,
                      MinidumpYAML::detail::ListStream<EntryT> &S) {

   File.allocateNewObject<support::ulittle32_t>(S.Entries.size());
   for (auto &E : S.Entries)
     File.allocateObject(E.Entry);

   size_t DataEnd = File.tell();

   // Lay out the auxiliary data, (which is not a part of the stream).
   DataEnd = File.tell();
   for (auto &E : S.Entries)
     layout(File, E);

   return DataEnd;
 }

 static Directory layout(BlobAllocator &File, Stream &S) {
   Directory Result;
   Result.Type = S.Type;
   Result.Location.RVA = File.tell();
   Optional<size_t> DataEnd;
   switch (S.Kind) {
   case Stream::StreamKind::Exception:
     DataEnd = layout(File, cast<MinidumpYAML::ExceptionStream>(S));
     break;
   case Stream::StreamKind::MemoryInfoList: {
     MemoryInfoListStream &InfoList = cast<MemoryInfoListStream>(S);
     File.allocateNewObject<minidump::MemoryInfoListHeader>(
         sizeof(minidump::MemoryInfoListHeader), sizeof(minidump::MemoryInfo),
         InfoList.Infos.size());
     File.allocateArray(makeArrayRef(InfoList.Infos));
     break;
   }
   case Stream::StreamKind::MemoryList:
     DataEnd = layout(File, cast<MemoryListStream>(S));
     break;
   case Stream::StreamKind::ModuleList:
     DataEnd = layout(File, cast<ModuleListStream>(S));
     break;
   case Stream::StreamKind::RawContent: {
     RawContentStream &Raw = cast<RawContentStream>(S);
     File.allocateCallback(Raw.Size, [&Raw](raw_ostream &OS) {
       Raw.Content.writeAsBinary(OS);
       assert(Raw.Content.binary_size() <= Raw.Size);
       OS << std::string(Raw.Size - Raw.Content.binary_size(), '\0');
     });
     break;
   }
   case Stream::StreamKind::SystemInfo: {
     SystemInfoStream &SystemInfo = cast<SystemInfoStream>(S);
     File.allocateObject(SystemInfo.Info);
     // The CSD string is not a part of the stream.
     DataEnd = File.tell();
     SystemInfo.Info.CSDVersionRVA = File.allocateString(SystemInfo.CSDVersion);
     break;
   }
   case Stream::StreamKind::TextContent:
     File.allocateArray(arrayRefFromStringRef(cast<TextContentStream>(S).Text));
     break;
   case Stream::StreamKind::ThreadList:
     DataEnd = layout(File, cast<ThreadListStream>(S));
     break;
   }
   // If DataEnd is not set, we assume everything we generated is a part of the
   // stream.
   Result.Location.DataSize =
       DataEnd.getValueOr(File.tell()) - Result.Location.RVA;
   return Result;
 }

 namespace llvm {
 namespace yaml {

 bool yaml2minidump(MinidumpYAML::Object &Obj, raw_ostream &Out,
                    ErrorHandler /*EH*/) {
   BlobAllocator File;
   File.allocateObject(Obj.Header);

   std::vector<Directory> StreamDirectory(Obj.Streams.size());
   Obj.Header.StreamDirectoryRVA =
       File.allocateArray(makeArrayRef(StreamDirectory));
   Obj.Header.NumberOfStreams = StreamDirectory.size();

   for (auto &Stream : enumerate(Obj.Streams))
     StreamDirectory[Stream.index()] = layout(File, *Stream.value());

   File.writeTo(Out);
   return true;
 }

 } // namespace yaml
 } // namespace llvm
	//===- yaml2minidump.cpp - Convert a YAML file to a minidump file ---------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ObjectYAML/MinidumpYAML.h"
	#include "llvm/ObjectYAML/yaml2obj.h"
	#include "llvm/Support/ConvertUTF.h"
	#include "llvm/Support/raw_ostream.h"

	using namespace llvm;
	using namespace llvm::minidump;
	using namespace llvm::MinidumpYAML;

	namespace {
	/// A helper class to manage the placement of various structures into the final
	/// minidump binary. Space for objects can be allocated via various allocate***
	/// methods, while the final minidump file is written by calling the writeTo
	/// method. The plain versions of allocation functions take a reference to the
	/// data which is to be written (and hence the data must be available until
	/// writeTo is called), while the "New" versions allocate the data in an
	/// allocator-managed buffer, which is available until the allocator object is
	/// destroyed. For both kinds of functions, it is possible to modify the
	/// data for which the space has been "allocated" until the final writeTo call.
	/// This is useful for "linking" the allocated structures via their offsets.
	class BlobAllocator {
	public:
	size_t tell() const { return NextOffset; }

	size_t allocateCallback(size_t Size,
	std::function<void(raw_ostream &)> Callback) {
	size_t Offset = NextOffset;
	NextOffset += Size;
	Callbacks.push_back(std::move(Callback));
	return Offset;
	}

	size_t allocateBytes(ArrayRef<uint8_t> Data) {
	return allocateCallback(
	Data.size(), [Data](raw_ostream &OS) { OS << toStringRef(Data); });
	}

	size_t allocateBytes(yaml::BinaryRef Data) {
	return allocateCallback(Data.binary_size(), [Data](raw_ostream &OS) {
	Data.writeAsBinary(OS);
	});
	}

	template <typename T> size_t allocateArray(ArrayRef<T> Data) {
	return allocateBytes({reinterpret_cast<const uint8_t *>(Data.data()),
	sizeof(T) * Data.size()});
	}

	template <typename T, typename RangeType>
	std::pair<size_t, MutableArrayRef<T>>
	allocateNewArray(const iterator_range<RangeType> &Range);

	template <typename T> size_t allocateObject(const T &Data) {
	return allocateArray(makeArrayRef(Data));
	}

	template <typename T, typename... Types>
	std::pair<size_t, T *> allocateNewObject(Types &&... Args) {
	T *Object = new (Temporaries.Allocate<T>()) T(std::forward<Types>(Args)...);
	return {allocateObject(*Object), Object};
	}

	size_t allocateString(StringRef Str);

	void writeTo(raw_ostream &OS) const;

	private:
	size_t NextOffset = 0;

	BumpPtrAllocator Temporaries;
	std::vector<std::function<void(raw_ostream &)>> Callbacks;
	};
	} // namespace

	template <typename T, typename RangeType>
	std::pair<size_t, MutableArrayRef<T>>
	BlobAllocator::allocateNewArray(const iterator_range<RangeType> &Range) {
	size_t Num = std::distance(Range.begin(), Range.end());
	MutableArrayRef<T> Array(Temporaries.Allocate<T>(Num), Num);
	std::uninitialized_copy(Range.begin(), Range.end(), Array.begin());
	return {allocateArray(Array), Array};
	}

	size_t BlobAllocator::allocateString(StringRef Str) {
	SmallVector<UTF16, 32> WStr;
	bool OK = convertUTF8ToUTF16String(Str, WStr);
	assert(OK && "Invalid UTF8 in Str?");
	(void)OK;

	// The utf16 string is null-terminated, but the terminator is not counted in
	// the string size.
	WStr.push_back(0);
	size_t Result =
	allocateNewObject<support::ulittle32_t>(2 * (WStr.size() - 1)).first;
	allocateNewArray<support::ulittle16_t>(make_range(WStr.begin(), WStr.end()));
	return Result;
	}

	void BlobAllocator::writeTo(raw_ostream &OS) const {
	size_t BeginOffset = OS.tell();
	for (const auto &Callback : Callbacks)
	Callback(OS);
	assert(OS.tell() == BeginOffset + NextOffset &&
	"Callbacks wrote an unexpected number of bytes.");
	(void)BeginOffset;
	}

	static LocationDescriptor layout(BlobAllocator &File, yaml::BinaryRef Data) {
	return {support::ulittle32_t(Data.binary_size()),
	support::ulittle32_t(File.allocateBytes(Data))};
	}

	static size_t layout(BlobAllocator &File, MinidumpYAML::ExceptionStream &S) {
	File.allocateObject(S.MDExceptionStream);

	size_t DataEnd = File.tell();

	// Lay out the thread context data, (which is not a part of the stream).
	// TODO: This usually (always?) matches the thread context of the
	// corresponding thread, and may overlap memory regions as well. We could
	// add a level of indirection to the MinidumpYAML format (like an array of
	// Blobs that the LocationDescriptors index into) to be able to distinguish
	// the cases where location descriptions overlap vs happen to reference
	// identical data.
	S.MDExceptionStream.ThreadContext = layout(File, S.ThreadContext);

	return DataEnd;
	}

	static void layout(BlobAllocator &File, MemoryListStream::entry_type &Range) {
	Range.Entry.Memory = layout(File, Range.Content);
	}

	static void layout(BlobAllocator &File, ModuleListStream::entry_type &M) {
	M.Entry.ModuleNameRVA = File.allocateString(M.Name);

	M.Entry.CvRecord = layout(File, M.CvRecord);
	M.Entry.MiscRecord = layout(File, M.MiscRecord);
	}

	static void layout(BlobAllocator &File, ThreadListStream::entry_type &T) {
	T.Entry.Stack.Memory = layout(File, T.Stack);
	T.Entry.Context = layout(File, T.Context);
	}

	template <typename EntryT>
	static size_t layout(BlobAllocator &File,
	MinidumpYAML::detail::ListStream<EntryT> &S) {

	File.allocateNewObject<support::ulittle32_t>(S.Entries.size());
	for (auto &E : S.Entries)
	File.allocateObject(E.Entry);

	size_t DataEnd = File.tell();

	// Lay out the auxiliary data, (which is not a part of the stream).
	DataEnd = File.tell();
	for (auto &E : S.Entries)
	layout(File, E);

	return DataEnd;
	}

	static Directory layout(BlobAllocator &File, Stream &S) {
	Directory Result;
	Result.Type = S.Type;
	Result.Location.RVA = File.tell();
	Optional<size_t> DataEnd;
	switch (S.Kind) {
	case Stream::StreamKind::Exception:
	DataEnd = layout(File, cast<MinidumpYAML::ExceptionStream>(S));
	break;
	case Stream::StreamKind::MemoryInfoList: {
	MemoryInfoListStream &InfoList = cast<MemoryInfoListStream>(S);
	File.allocateNewObject<minidump::MemoryInfoListHeader>(
	sizeof(minidump::MemoryInfoListHeader), sizeof(minidump::MemoryInfo),
	InfoList.Infos.size());
	File.allocateArray(makeArrayRef(InfoList.Infos));
	break;
	}
	case Stream::StreamKind::MemoryList:
	DataEnd = layout(File, cast<MemoryListStream>(S));
	break;
	case Stream::StreamKind::ModuleList:
	DataEnd = layout(File, cast<ModuleListStream>(S));
	break;
	case Stream::StreamKind::RawContent: {
	RawContentStream &Raw = cast<RawContentStream>(S);
	File.allocateCallback(Raw.Size, [&Raw](raw_ostream &OS) {
	Raw.Content.writeAsBinary(OS);
	assert(Raw.Content.binary_size() <= Raw.Size);
	OS << std::string(Raw.Size - Raw.Content.binary_size(), '\0');
	});
	break;
	}
	case Stream::StreamKind::SystemInfo: {
	SystemInfoStream &SystemInfo = cast<SystemInfoStream>(S);
	File.allocateObject(SystemInfo.Info);
	// The CSD string is not a part of the stream.
	DataEnd = File.tell();
	SystemInfo.Info.CSDVersionRVA = File.allocateString(SystemInfo.CSDVersion);
	break;
	}
	case Stream::StreamKind::TextContent:
	File.allocateArray(arrayRefFromStringRef(cast<TextContentStream>(S).Text));
	break;
	case Stream::StreamKind::ThreadList:
	DataEnd = layout(File, cast<ThreadListStream>(S));
	break;
	}
	// If DataEnd is not set, we assume everything we generated is a part of the
	// stream.
	Result.Location.DataSize =
	DataEnd.getValueOr(File.tell()) - Result.Location.RVA;
	return Result;
	}

	namespace llvm {
	namespace yaml {

	bool yaml2minidump(MinidumpYAML::Object &Obj, raw_ostream &Out,
	ErrorHandler /EH/) {
	BlobAllocator File;
	File.allocateObject(Obj.Header);

	std::vector<Directory> StreamDirectory(Obj.Streams.size());
	Obj.Header.StreamDirectoryRVA =
	File.allocateArray(makeArrayRef(StreamDirectory));
	Obj.Header.NumberOfStreams = StreamDirectory.size();

	for (auto &Stream : enumerate(Obj.Streams))
	StreamDirectory[Stream.index()] = layout(File, *Stream.value());

	File.writeTo(Out);
	return true;
	}

	} // namespace yaml
	} // namespace llvm