src/Reactor/LLVMReactorDebugInfo.cpp - SwiftShader - Git at Google

 // Copyright 2019 The SwiftShader Authors. All Rights Reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //  http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #include "LLVMReactorDebugInfo.hpp"

 #ifdef ENABLE_RR_DEBUG_INFO

 #	include "LLVMReactor.hpp"
 #	include "Reactor.hpp"
 #	include "Print.hpp"

 #	include "boost/stacktrace.hpp"

 // TODO(b/143539525): Eliminate when warning has been fixed.
 #	ifdef _MSC_VER
 __pragma(warning(push))
     __pragma(warning(disable : 4146))  // unary minus operator applied to unsigned type, result still unsigned
 #	endif

 #	include "llvm/Demangle/Demangle.h"
 #	include "llvm/ExecutionEngine/JITEventListener.h"
 #	include "llvm/IR/DIBuilder.h"
 #	include "llvm/IR/IRBuilder.h"
 #	include "llvm/IR/Intrinsics.h"

 #	ifdef _MSC_VER
     __pragma(warning(pop))
 #	endif

 #	include <cctype>
 #	include <fstream>
 #	include <mutex>
 #	include <regex>
 #	include <sstream>
 #	include <string>

 #	if 0
 #		define LOG(msg, ...) printf(msg "\n", ##__VA_ARGS__)
 #	else
 #		define LOG(msg, ...)
 #	endif

         namespace
 {

 	std::pair<llvm::StringRef, llvm::StringRef> splitPath(const char *path)
 	{
 #	ifdef _WIN32
 		auto dirAndFile = llvm::StringRef(path).rsplit('\\');
 #	else
 	auto dirAndFile = llvm::StringRef(path).rsplit('/');
 #	endif
 		if(dirAndFile.second == "")
 		{
 			dirAndFile.second = "<unknown>";
 		}
 		return dirAndFile;
 	}

 	// Note: createGDBRegistrationListener() returns a pointer to a singleton.
 	// Nothing is actually created.
 	auto jitEventListener = llvm::JITEventListener::createGDBRegistrationListener();  // guarded by jitEventListenerMutex
 	std::mutex jitEventListenerMutex;

 }  // namespace

 namespace rr {

 DebugInfo::DebugInfo(
     llvm::IRBuilder<> *builder,
     llvm::LLVMContext *context,
     llvm::Module *module,
     llvm::Function *function)
     : builder(builder)
     , context(context)
     , module(module)
     , function(function)
 {
 	using namespace ::llvm;

 	auto location = getCallerLocation();

 	auto dirAndFile = splitPath(location.function.file.c_str());
 	diBuilder.reset(new llvm::DIBuilder(*module));
 	diCU = diBuilder->createCompileUnit(
 	    llvm::dwarf::DW_LANG_C,
 	    diBuilder->createFile(dirAndFile.second, dirAndFile.first),
 	    "Reactor",
 	    0, "", 0);

 	registerBasicTypes();

 	SmallVector<Metadata *, 8> EltTys;
 	auto funcTy = diBuilder->createSubroutineType(diBuilder->getOrCreateTypeArray(EltTys));

 	auto file = getOrCreateFile(location.function.file.c_str());
 	auto sp = diBuilder->createFunction(
 	    file,                           // scope
 	    "ReactorFunction",              // function name
 	    "ReactorFunction",              // linkage
 	    file,                           // file
 	    location.line,                  // line
 	    funcTy,                         // type
 	    location.line,                  // scope line
 	    DINode::FlagPrototyped,         // flags
 	    DISubprogram::SPFlagDefinition  // subprogram flags
 	);
 	diSubprogram = sp;
 	function->setSubprogram(sp);
 	diRootLocation = DILocation::get(*context, location.line, 0, sp);
 	builder->SetCurrentDebugLocation(diRootLocation);
 }

 DebugInfo::~DebugInfo() = default;

 void DebugInfo::Finalize()
 {
 	while(diScope.size() > 0)
 	{
 		emitPending(diScope.back(), builder);
 		diScope.pop_back();
 	}
 	diBuilder->finalize();
 }

 void DebugInfo::EmitLocation()
 {
 	auto const &backtrace = getCallerBacktrace();
 	syncScope(backtrace);
 	builder->SetCurrentDebugLocation(getLocation(backtrace, backtrace.size() - 1));
 	emitPrintLocation(backtrace);
 }

 void DebugInfo::Flush()
 {
 	if(!diScope.empty())
 	{
 		emitPending(diScope.back(), builder);
 	}
 }

 void DebugInfo::syncScope(Backtrace const &backtrace)
 {
 	using namespace ::llvm;

 	auto shrink = [this](size_t newsize) {
 		while(diScope.size() > newsize)
 		{
 			auto &scope = diScope.back();
 			LOG("- STACK(%d): di: %p, location: %s:%d",
 			    int(diScope.size() - 1), scope.di,
 			    scope.location.function.file.c_str(),
 			    int(scope.location.line));
 			emitPending(scope, builder);
 			diScope.pop_back();
 		}
 	};

 	if(backtrace.size() < diScope.size())
 	{
 		shrink(backtrace.size());
 	}

 	for(size_t i = 0; i < diScope.size(); i++)
 	{
 		auto &scope = diScope[i];
 		auto const &oldLocation = scope.location;
 		auto const &newLocation = backtrace[i];

 		if(oldLocation.function != newLocation.function)
 		{
 			LOG("  STACK(%d): Changed function %s -> %s", int(i),
 			    oldLocation.function.name.c_str(), newLocation.function.name.c_str());
 			shrink(i);
 			break;
 		}

 		if(oldLocation.line > newLocation.line)
 		{
 			// Create a new di block to shadow all the variables in the loop.
 			auto file = getOrCreateFile(newLocation.function.file.c_str());
 			auto di = diBuilder->createLexicalBlock(scope.di, file, newLocation.line, 0);
 			LOG("  STACK(%d): Jumped backwards %d -> %d. di: %p -> %p", int(i),
 			    oldLocation.line, newLocation.line, scope.di, di);
 			emitPending(scope, builder);
 			scope = { newLocation, di, {}, {} };
 			shrink(i + 1);
 			break;
 		}

 		scope.location = newLocation;
 	}

 	while(backtrace.size() > diScope.size())
 	{
 		auto i = diScope.size();
 		auto location = backtrace[i];
 		auto file = getOrCreateFile(location.function.file.c_str());
 		auto funcTy = diBuilder->createSubroutineType(diBuilder->getOrCreateTypeArray({}));

 		char buf[1024];
 		size_t size = sizeof(buf);
 		int status = 0;
 		llvm::itaniumDemangle(location.function.name.c_str(), buf, &size, &status);
 		auto name = "jit!" + (status == 0 ? std::string(buf) : location.function.name);

 		auto func = diBuilder->createFunction(
 		    file,                           // scope
 		    name,                           // function name
 		    "",                             // linkage
 		    file,                           // file
 		    location.line,                  // line
 		    funcTy,                         // type
 		    location.line,                  // scope line
 		    DINode::FlagPrototyped,         // flags
 		    DISubprogram::SPFlagDefinition  // subprogram flags
 		);
 		diScope.push_back({ location, func, {}, {} });
 		LOG("+ STACK(%d): di: %p, location: %s:%d", int(i), di,
 		    location.function.file.c_str(), int(location.line));
 	}
 }

 llvm::DILocation *DebugInfo::getLocation(const Backtrace &backtrace, size_t i)
 {
 	if(backtrace.size() == 0) { return nullptr; }
 	assert(backtrace.size() == diScope.size());
 	return llvm::DILocation::get(
 	    *context,
 	    backtrace[i].line,
 	    0,
 	    diScope[i].di,
 	    i > 0 ? getLocation(backtrace, i - 1) : diRootLocation);
 }

 void DebugInfo::EmitVariable(Value *variable)
 {
 	auto const &backtrace = getCallerBacktrace();
 	syncScope(backtrace);

 	for(int i = backtrace.size() - 1; i >= 0; i--)
 	{
 		auto const &location = backtrace[i];
 		auto tokens = getOrParseFileTokens(location.function.file.c_str());
 		auto tokIt = tokens->find(location.line);
 		if(tokIt == tokens->end())
 		{
 			break;
 		}
 		auto token = tokIt->second;
 		auto name = token.identifier;
 		if(token.kind == Token::Return)
 		{
 			// This is a:
 			//
 			//   return <expr>;
 			//
 			// Emit this expression as two variables -
 			// Once as a synthetic 'return_value' variable at this scope.
 			// Again by bubbling the expression value up the callstack as
 			// Return Value Optimizations (RVOs) are likely to carry across
 			// the value to a local without calling a constructor in
 			// statements like:
 			//
 			//   auto val = foo();
 			//
 			name = "return_value";
 		}

 		auto &scope = diScope[i];
 		if(scope.pending.location != location)
 		{
 			emitPending(scope, builder);
 		}

 		auto value = V(variable);
 		auto block = builder->GetInsertBlock();

 		auto insertAfter = block->size() > 0 ? &block->back() : nullptr;
 		while(insertAfter != nullptr && insertAfter->isTerminator())
 		{
 			insertAfter = insertAfter->getPrevNode();
 		}

 		scope.pending = Pending{};
 		scope.pending.name = name;
 		scope.pending.location = location;
 		scope.pending.diLocation = getLocation(backtrace, i);
 		scope.pending.value = value;
 		scope.pending.block = block;
 		scope.pending.insertAfter = insertAfter;
 		scope.pending.scope = scope.di;

 		if(token.kind == Token::Return)
 		{
 			// Insert a noop instruction so the debugger can inspect the
 			// return value before the function scope closes.
 			scope.pending.addNopOnNextLine = true;
 		}
 		else
 		{
 			break;
 		}
 	}
 }

 void DebugInfo::emitPending(Scope &scope, IRBuilder *builder)
 {
 	auto const &pending = scope.pending;
 	if(pending.value == nullptr)
 	{
 		return;
 	}

 	if(!scope.symbols.emplace(pending.name).second)
 	{
 		return;
 	}

 	bool isAlloca = llvm::isa<llvm::AllocaInst>(pending.value);

 	LOG("  EMIT(%s): di: %p, location: %s:%d, isAlloca: %s", pending.name.c_str(), scope.di,
 	    pending.location.function.file.c_str(), pending.location.line, isAlloca ? "true" : "false");

 	auto value = pending.value;

 	IRBuilder::InsertPointGuard guard(*builder);
 	if(pending.insertAfter != nullptr)
 	{
 		builder->SetInsertPoint(pending.block, ++pending.insertAfter->getIterator());
 	}
 	else
 	{
 		builder->SetInsertPoint(pending.block);
 	}
 	builder->SetCurrentDebugLocation(pending.diLocation);

 	if(!isAlloca)
 	{
 		// While insertDbgValueIntrinsic should be enough to declare a
 		// variable with no storage, variables of RValues can share the same
 		// llvm::Value, and only one can be named. Take for example:
 		//
 		//   Int a = 42;
 		//   RValue<Int> b = a;
 		//   RValue<Int> c = b;
 		//
 		// To handle this, always promote named RValues to an alloca.

 		llvm::BasicBlock &entryBlock = function->getEntryBlock();
 		auto alloca = new llvm::AllocaInst(value->getType(), 0, pending.name);
 		entryBlock.getInstList().push_front(alloca);
 		builder->CreateStore(value, alloca);
 		value = alloca;
 	}

 	value->setName(pending.name);

 	auto diFile = getOrCreateFile(pending.location.function.file.c_str());
 	auto diType = getOrCreateType(value->getType()->getPointerElementType());
 	auto diVar = diBuilder->createAutoVariable(scope.di, pending.name, diFile, pending.location.line, diType);

 	auto di = diBuilder->insertDeclare(value, diVar, diBuilder->createExpression(), pending.diLocation, pending.block);
 	if(pending.insertAfter != nullptr) { di->moveAfter(pending.insertAfter); }

 	if(pending.addNopOnNextLine)
 	{
 		builder->SetCurrentDebugLocation(llvm::DILocation::get(
 		    *context,
 		    pending.diLocation->getLine() + 1,
 		    0,
 		    pending.diLocation->getScope(),
 		    pending.diLocation->getInlinedAt()));
 		Nop();
 	}

 	scope.pending = Pending{};
 }

 void DebugInfo::NotifyObjectEmitted(uint64_t key, const llvm::object::ObjectFile &obj, const llvm::LoadedObjectInfo &l)
 {
 	std::unique_lock<std::mutex> lock(jitEventListenerMutex);
 	jitEventListener->notifyObjectLoaded(key, obj, static_cast<const llvm::RuntimeDyld::LoadedObjectInfo &>(l));
 }

 void DebugInfo::NotifyFreeingObject(uint64_t key)
 {
 	std::unique_lock<std::mutex> lock(jitEventListenerMutex);
 	jitEventListener->notifyFreeingObject(key);
 }

 void DebugInfo::registerBasicTypes()
 {
 	using namespace rr;
 	using namespace llvm;

 	auto vec4 = diBuilder->getOrCreateArray(diBuilder->getOrCreateSubrange(0, 4));
 	auto vec8 = diBuilder->getOrCreateArray(diBuilder->getOrCreateSubrange(0, 8));
 	auto vec16 = diBuilder->getOrCreateArray(diBuilder->getOrCreateSubrange(0, 16));

 	diTypes.emplace(T(Bool::type()), diBuilder->createBasicType("Bool", sizeof(bool), dwarf::DW_ATE_boolean));
 	diTypes.emplace(T(Byte::type()), diBuilder->createBasicType("Byte", 8, dwarf::DW_ATE_unsigned_char));
 	diTypes.emplace(T(SByte::type()), diBuilder->createBasicType("SByte", 8, dwarf::DW_ATE_signed_char));
 	diTypes.emplace(T(Short::type()), diBuilder->createBasicType("Short", 16, dwarf::DW_ATE_signed));
 	diTypes.emplace(T(UShort::type()), diBuilder->createBasicType("UShort", 16, dwarf::DW_ATE_unsigned));
 	diTypes.emplace(T(Int::type()), diBuilder->createBasicType("Int", 32, dwarf::DW_ATE_signed));
 	diTypes.emplace(T(UInt::type()), diBuilder->createBasicType("UInt", 32, dwarf::DW_ATE_unsigned));
 	diTypes.emplace(T(Long::type()), diBuilder->createBasicType("Long", 64, dwarf::DW_ATE_signed));
 	diTypes.emplace(T(Half::type()), diBuilder->createBasicType("Half", 16, dwarf::DW_ATE_float));
 	diTypes.emplace(T(Float::type()), diBuilder->createBasicType("Float", 32, dwarf::DW_ATE_float));

 	diTypes.emplace(T(Byte4::type()), diBuilder->createVectorType(128, 128, diTypes[T(Byte::type())], { vec16 }));
 	diTypes.emplace(T(SByte4::type()), diBuilder->createVectorType(128, 128, diTypes[T(SByte::type())], { vec16 }));
 	diTypes.emplace(T(Byte8::type()), diBuilder->createVectorType(128, 128, diTypes[T(Byte::type())], { vec16 }));
 	diTypes.emplace(T(SByte8::type()), diBuilder->createVectorType(128, 128, diTypes[T(SByte::type())], { vec16 }));
 	diTypes.emplace(T(Byte16::type()), diBuilder->createVectorType(128, 128, diTypes[T(Byte::type())], { vec16 }));
 	diTypes.emplace(T(SByte16::type()), diBuilder->createVectorType(128, 128, diTypes[T(SByte::type())], { vec16 }));
 	diTypes.emplace(T(Short2::type()), diBuilder->createVectorType(128, 128, diTypes[T(Short::type())], { vec8 }));
 	diTypes.emplace(T(UShort2::type()), diBuilder->createVectorType(128, 128, diTypes[T(UShort::type())], { vec8 }));
 	diTypes.emplace(T(Short4::type()), diBuilder->createVectorType(128, 128, diTypes[T(Short::type())], { vec8 }));
 	diTypes.emplace(T(UShort4::type()), diBuilder->createVectorType(128, 128, diTypes[T(UShort::type())], { vec8 }));
 	diTypes.emplace(T(Short8::type()), diBuilder->createVectorType(128, 128, diTypes[T(Short::type())], { vec8 }));
 	diTypes.emplace(T(UShort8::type()), diBuilder->createVectorType(128, 128, diTypes[T(UShort::type())], { vec8 }));
 	diTypes.emplace(T(Int2::type()), diBuilder->createVectorType(128, 128, diTypes[T(Int::type())], { vec4 }));
 	diTypes.emplace(T(UInt2::type()), diBuilder->createVectorType(128, 128, diTypes[T(UInt::type())], { vec4 }));
 	diTypes.emplace(T(Int4::type()), diBuilder->createVectorType(128, 128, diTypes[T(Int::type())], { vec4 }));
 	diTypes.emplace(T(UInt4::type()), diBuilder->createVectorType(128, 128, diTypes[T(UInt::type())], { vec4 }));
 	diTypes.emplace(T(Float2::type()), diBuilder->createVectorType(128, 128, diTypes[T(Float::type())], { vec4 }));
 	diTypes.emplace(T(Float4::type()), diBuilder->createVectorType(128, 128, diTypes[T(Float::type())], { vec4 }));
 }

 Location DebugInfo::getCallerLocation() const
 {
 	auto backtrace = getCallerBacktrace(1);
 	return backtrace.empty() ? Location{} : backtrace[0];
 }

 Backtrace DebugInfo::getCallerBacktrace(size_t limit /* = 0 */) const
 {
 	return rr::getCallerBacktrace(limit);
 }

 llvm::DIType *DebugInfo::getOrCreateType(llvm::Type *type)
 {
 	auto it = diTypes.find(type);
 	if(it != diTypes.end()) { return it->second; }

 	if(type->isPointerTy())
 	{
 		auto dbgTy = diBuilder->createPointerType(
 		    getOrCreateType(type->getPointerElementType()),
 		    sizeof(void *) * 8, alignof(void *) * 8);
 		diTypes.emplace(type, dbgTy);
 		return dbgTy;
 	}
 	llvm::errs() << "Unimplemented debug type: " << type << "\n";
 	assert(false);
 	return nullptr;
 }

 llvm::DIFile *DebugInfo::getOrCreateFile(const char *path)
 {
 	auto it = diFiles.find(path);
 	if(it != diFiles.end()) { return it->second; }
 	auto dirAndName = splitPath(path);
 	auto file = diBuilder->createFile(dirAndName.second, dirAndName.first);
 	diFiles.emplace(path, file);
 	return file;
 }

 DebugInfo::LineTokens const *DebugInfo::getOrParseFileTokens(const char *path)
 {
 	static std::regex reLocalDecl(
 	    "^"                                              // line start
 	    "\\s*"                                           // initial whitespace
 	    "(?:For\\s*\\(\\s*)?"                            // optional 'For('
 	    "((?:\\w+(?:<[^>]+>)?)(?:::\\w+(?:<[^>]+>)?)*)"  // type (match group 1)
 	    "\\s+"                                           // whitespace between type and name
 	    "(\\w+)"                                         // identifier (match group 2)
 	    "\\s*"                                           // whitespace after identifier
 	    "(\\[.*\\])?");                                  // optional array suffix (match group 3)

 	auto it = fileTokens.find(path);
 	if(it != fileTokens.end())
 	{
 		return it->second.get();
 	}

 	auto tokens = std::make_unique<LineTokens>();

 	std::ifstream file(path);
 	std::string line;
 	int lineCount = 0;
 	while(std::getline(file, line))
 	{
 		lineCount++;
 		std::smatch match;
 		if(std::regex_search(line, match, reLocalDecl) && match.size() > 3)
 		{
 			bool isArray = match.str(3) != "";
 			if(!isArray)  // Cannot deal with C-arrays of values.
 			{
 				if(match.str(1) == "return")
 				{
 					(*tokens)[lineCount] = Token{ Token::Return, "" };
 				}
 				else
 				{
 					(*tokens)[lineCount] = Token{ Token::Identifier, match.str(2) };
 				}
 			}
 		}
 	}

 	auto out = tokens.get();
 	fileTokens.emplace(path, std::move(tokens));
 	return out;
 }

 }  // namespace rr

 #endif  // ENABLE_RR_DEBUG_INFO
	// Copyright 2019 The SwiftShader Authors. All Rights Reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#include "LLVMReactorDebugInfo.hpp"

	#ifdef ENABLE_RR_DEBUG_INFO

	# include "LLVMReactor.hpp"
	# include "Reactor.hpp"
	# include "Print.hpp"

	# include "boost/stacktrace.hpp"

	// TODO(b/143539525): Eliminate when warning has been fixed.
	# ifdef _MSC_VER
	__pragma(warning(push))
	__pragma(warning(disable : 4146)) // unary minus operator applied to unsigned type, result still unsigned
	# endif

	# include "llvm/Demangle/Demangle.h"
	# include "llvm/ExecutionEngine/JITEventListener.h"
	# include "llvm/IR/DIBuilder.h"
	# include "llvm/IR/IRBuilder.h"
	# include "llvm/IR/Intrinsics.h"

	# ifdef _MSC_VER
	__pragma(warning(pop))
	# endif

	# include <cctype>
	# include <fstream>
	# include <mutex>
	# include <regex>
	# include <sstream>
	# include <string>

	# if 0
	# define LOG(msg, ...) printf(msg "\n", ##__VA_ARGS__)
	# else
	# define LOG(msg, ...)
	# endif

	namespace
	{

	std::pair<llvm::StringRef, llvm::StringRef> splitPath(const char *path)
	{
	# ifdef _WIN32
	auto dirAndFile = llvm::StringRef(path).rsplit('\\');
	# else
	auto dirAndFile = llvm::StringRef(path).rsplit('/');
	# endif
	if(dirAndFile.second == "")
	{
	dirAndFile.second = "<unknown>";
	}
	return dirAndFile;
	}

	// Note: createGDBRegistrationListener() returns a pointer to a singleton.
	// Nothing is actually created.
	auto jitEventListener = llvm::JITEventListener::createGDBRegistrationListener(); // guarded by jitEventListenerMutex
	std::mutex jitEventListenerMutex;

	} // namespace

	namespace rr {

	DebugInfo::DebugInfo(
	llvm::IRBuilder<> *builder,
	llvm::LLVMContext *context,
	llvm::Module *module,
	llvm::Function *function)
	: builder(builder)
	, context(context)
	, module(module)
	, function(function)
	{
	using namespace ::llvm;

	auto location = getCallerLocation();

	auto dirAndFile = splitPath(location.function.file.c_str());
	diBuilder.reset(new llvm::DIBuilder(*module));
	diCU = diBuilder->createCompileUnit(
	llvm::dwarf::DW_LANG_C,
	diBuilder->createFile(dirAndFile.second, dirAndFile.first),
	"Reactor",
	0, "", 0);

	registerBasicTypes();

	SmallVector<Metadata *, 8> EltTys;
	auto funcTy = diBuilder->createSubroutineType(diBuilder->getOrCreateTypeArray(EltTys));

	auto file = getOrCreateFile(location.function.file.c_str());
	auto sp = diBuilder->createFunction(
	file, // scope
	"ReactorFunction", // function name
	"ReactorFunction", // linkage
	file, // file
	location.line, // line
	funcTy, // type
	location.line, // scope line
	DINode::FlagPrototyped, // flags
	DISubprogram::SPFlagDefinition // subprogram flags
	);
	diSubprogram = sp;
	function->setSubprogram(sp);
	diRootLocation = DILocation::get(*context, location.line, 0, sp);
	builder->SetCurrentDebugLocation(diRootLocation);
	}

	DebugInfo::~DebugInfo() = default;

	void DebugInfo::Finalize()
	{
	while(diScope.size() > 0)
	{
	emitPending(diScope.back(), builder);
	diScope.pop_back();
	}
	diBuilder->finalize();
	}

	void DebugInfo::EmitLocation()
	{
	auto const &backtrace = getCallerBacktrace();
	syncScope(backtrace);
	builder->SetCurrentDebugLocation(getLocation(backtrace, backtrace.size() - 1));
	emitPrintLocation(backtrace);
	}

	void DebugInfo::Flush()
	{
	if(!diScope.empty())
	{
	emitPending(diScope.back(), builder);
	}
	}

	void DebugInfo::syncScope(Backtrace const &backtrace)
	{
	using namespace ::llvm;

	auto shrink = [this](size_t newsize) {
	while(diScope.size() > newsize)
	{
	auto &scope = diScope.back();
	LOG("- STACK(%d): di: %p, location: %s:%d",
	int(diScope.size() - 1), scope.di,
	scope.location.function.file.c_str(),
	int(scope.location.line));
	emitPending(scope, builder);
	diScope.pop_back();
	}
	};

	if(backtrace.size() < diScope.size())
	{
	shrink(backtrace.size());
	}

	for(size_t i = 0; i < diScope.size(); i++)
	{
	auto &scope = diScope[i];
	auto const &oldLocation = scope.location;
	auto const &newLocation = backtrace[i];

	if(oldLocation.function != newLocation.function)
	{
	LOG(" STACK(%d): Changed function %s -> %s", int(i),
	oldLocation.function.name.c_str(), newLocation.function.name.c_str());
	shrink(i);
	break;
	}

	if(oldLocation.line > newLocation.line)
	{
	// Create a new di block to shadow all the variables in the loop.
	auto file = getOrCreateFile(newLocation.function.file.c_str());
	auto di = diBuilder->createLexicalBlock(scope.di, file, newLocation.line, 0);
	LOG(" STACK(%d): Jumped backwards %d -> %d. di: %p -> %p", int(i),
	oldLocation.line, newLocation.line, scope.di, di);
	emitPending(scope, builder);
	scope = { newLocation, di, {}, {} };
	shrink(i + 1);
	break;
	}

	scope.location = newLocation;
	}

	while(backtrace.size() > diScope.size())
	{
	auto i = diScope.size();
	auto location = backtrace[i];
	auto file = getOrCreateFile(location.function.file.c_str());
	auto funcTy = diBuilder->createSubroutineType(diBuilder->getOrCreateTypeArray({}));

	char buf[1024];
	size_t size = sizeof(buf);
	int status = 0;
	llvm::itaniumDemangle(location.function.name.c_str(), buf, &size, &status);
	auto name = "jit!" + (status == 0 ? std::string(buf) : location.function.name);

	auto func = diBuilder->createFunction(
	file, // scope
	name, // function name
	"", // linkage
	file, // file
	location.line, // line
	funcTy, // type
	location.line, // scope line
	DINode::FlagPrototyped, // flags
	DISubprogram::SPFlagDefinition // subprogram flags
	);
	diScope.push_back({ location, func, {}, {} });
	LOG("+ STACK(%d): di: %p, location: %s:%d", int(i), di,
	location.function.file.c_str(), int(location.line));
	}
	}

	llvm::DILocation *DebugInfo::getLocation(const Backtrace &backtrace, size_t i)
	{
	if(backtrace.size() == 0) { return nullptr; }
	assert(backtrace.size() == diScope.size());
	return llvm::DILocation::get(
	*context,
	backtrace[i].line,
	0,
	diScope[i].di,
	i > 0 ? getLocation(backtrace, i - 1) : diRootLocation);
	}

	void DebugInfo::EmitVariable(Value *variable)
	{
	auto const &backtrace = getCallerBacktrace();
	syncScope(backtrace);

	for(int i = backtrace.size() - 1; i >= 0; i--)
	{
	auto const &location = backtrace[i];
	auto tokens = getOrParseFileTokens(location.function.file.c_str());
	auto tokIt = tokens->find(location.line);
	if(tokIt == tokens->end())
	{
	break;
	}
	auto token = tokIt->second;
	auto name = token.identifier;
	if(token.kind == Token::Return)
	{
	// This is a:
	//
	// return <expr>;
	//
	// Emit this expression as two variables -
	// Once as a synthetic 'return_value' variable at this scope.
	// Again by bubbling the expression value up the callstack as
	// Return Value Optimizations (RVOs) are likely to carry across
	// the value to a local without calling a constructor in
	// statements like:
	//
	// auto val = foo();
	//
	name = "return_value";
	}

	auto &scope = diScope[i];
	if(scope.pending.location != location)
	{
	emitPending(scope, builder);
	}

	auto value = V(variable);
	auto block = builder->GetInsertBlock();

	auto insertAfter = block->size() > 0 ? &block->back() : nullptr;
	while(insertAfter != nullptr && insertAfter->isTerminator())
	{
	insertAfter = insertAfter->getPrevNode();
	}

	scope.pending = Pending{};
	scope.pending.name = name;
	scope.pending.location = location;
	scope.pending.diLocation = getLocation(backtrace, i);
	scope.pending.value = value;
	scope.pending.block = block;
	scope.pending.insertAfter = insertAfter;
	scope.pending.scope = scope.di;

	if(token.kind == Token::Return)
	{
	// Insert a noop instruction so the debugger can inspect the
	// return value before the function scope closes.
	scope.pending.addNopOnNextLine = true;
	}
	else
	{
	break;
	}
	}
	}

	void DebugInfo::emitPending(Scope &scope, IRBuilder *builder)
	{
	auto const &pending = scope.pending;
	if(pending.value == nullptr)
	{
	return;
	}

	if(!scope.symbols.emplace(pending.name).second)
	{
	return;
	}

	bool isAlloca = llvm::isa<llvm::AllocaInst>(pending.value);

	LOG(" EMIT(%s): di: %p, location: %s:%d, isAlloca: %s", pending.name.c_str(), scope.di,
	pending.location.function.file.c_str(), pending.location.line, isAlloca ? "true" : "false");

	auto value = pending.value;

	IRBuilder::InsertPointGuard guard(*builder);
	if(pending.insertAfter != nullptr)
	{
	builder->SetInsertPoint(pending.block, ++pending.insertAfter->getIterator());
	}
	else
	{
	builder->SetInsertPoint(pending.block);
	}
	builder->SetCurrentDebugLocation(pending.diLocation);

	if(!isAlloca)
	{
	// While insertDbgValueIntrinsic should be enough to declare a
	// variable with no storage, variables of RValues can share the same
	// llvm::Value, and only one can be named. Take for example:
	//
	// Int a = 42;
	// RValue<Int> b = a;
	// RValue<Int> c = b;
	//
	// To handle this, always promote named RValues to an alloca.

	llvm::BasicBlock &entryBlock = function->getEntryBlock();
	auto alloca = new llvm::AllocaInst(value->getType(), 0, pending.name);
	entryBlock.getInstList().push_front(alloca);
	builder->CreateStore(value, alloca);
	value = alloca;
	}

	value->setName(pending.name);

	auto diFile = getOrCreateFile(pending.location.function.file.c_str());
	auto diType = getOrCreateType(value->getType()->getPointerElementType());
	auto diVar = diBuilder->createAutoVariable(scope.di, pending.name, diFile, pending.location.line, diType);

	auto di = diBuilder->insertDeclare(value, diVar, diBuilder->createExpression(), pending.diLocation, pending.block);
	if(pending.insertAfter != nullptr) { di->moveAfter(pending.insertAfter); }

	if(pending.addNopOnNextLine)
	{
	builder->SetCurrentDebugLocation(llvm::DILocation::get(
	*context,
	pending.diLocation->getLine() + 1,
	0,
	pending.diLocation->getScope(),
	pending.diLocation->getInlinedAt()));
	Nop();
	}

	scope.pending = Pending{};
	}

	void DebugInfo::NotifyObjectEmitted(uint64_t key, const llvm::object::ObjectFile &obj, const llvm::LoadedObjectInfo &l)
	{
	std::unique_lock<std::mutex> lock(jitEventListenerMutex);
	jitEventListener->notifyObjectLoaded(key, obj, static_cast<const llvm::RuntimeDyld::LoadedObjectInfo &>(l));
	}

	void DebugInfo::NotifyFreeingObject(uint64_t key)
	{
	std::unique_lock<std::mutex> lock(jitEventListenerMutex);
	jitEventListener->notifyFreeingObject(key);
	}

	void DebugInfo::registerBasicTypes()
	{
	using namespace rr;
	using namespace llvm;

	auto vec4 = diBuilder->getOrCreateArray(diBuilder->getOrCreateSubrange(0, 4));
	auto vec8 = diBuilder->getOrCreateArray(diBuilder->getOrCreateSubrange(0, 8));
	auto vec16 = diBuilder->getOrCreateArray(diBuilder->getOrCreateSubrange(0, 16));

	diTypes.emplace(T(Bool::type()), diBuilder->createBasicType("Bool", sizeof(bool), dwarf::DW_ATE_boolean));
	diTypes.emplace(T(Byte::type()), diBuilder->createBasicType("Byte", 8, dwarf::DW_ATE_unsigned_char));
	diTypes.emplace(T(SByte::type()), diBuilder->createBasicType("SByte", 8, dwarf::DW_ATE_signed_char));
	diTypes.emplace(T(Short::type()), diBuilder->createBasicType("Short", 16, dwarf::DW_ATE_signed));
	diTypes.emplace(T(UShort::type()), diBuilder->createBasicType("UShort", 16, dwarf::DW_ATE_unsigned));
	diTypes.emplace(T(Int::type()), diBuilder->createBasicType("Int", 32, dwarf::DW_ATE_signed));
	diTypes.emplace(T(UInt::type()), diBuilder->createBasicType("UInt", 32, dwarf::DW_ATE_unsigned));
	diTypes.emplace(T(Long::type()), diBuilder->createBasicType("Long", 64, dwarf::DW_ATE_signed));
	diTypes.emplace(T(Half::type()), diBuilder->createBasicType("Half", 16, dwarf::DW_ATE_float));
	diTypes.emplace(T(Float::type()), diBuilder->createBasicType("Float", 32, dwarf::DW_ATE_float));

	diTypes.emplace(T(Byte4::type()), diBuilder->createVectorType(128, 128, diTypes[T(Byte::type())], { vec16 }));
	diTypes.emplace(T(SByte4::type()), diBuilder->createVectorType(128, 128, diTypes[T(SByte::type())], { vec16 }));
	diTypes.emplace(T(Byte8::type()), diBuilder->createVectorType(128, 128, diTypes[T(Byte::type())], { vec16 }));
	diTypes.emplace(T(SByte8::type()), diBuilder->createVectorType(128, 128, diTypes[T(SByte::type())], { vec16 }));
	diTypes.emplace(T(Byte16::type()), diBuilder->createVectorType(128, 128, diTypes[T(Byte::type())], { vec16 }));
	diTypes.emplace(T(SByte16::type()), diBuilder->createVectorType(128, 128, diTypes[T(SByte::type())], { vec16 }));
	diTypes.emplace(T(Short2::type()), diBuilder->createVectorType(128, 128, diTypes[T(Short::type())], { vec8 }));
	diTypes.emplace(T(UShort2::type()), diBuilder->createVectorType(128, 128, diTypes[T(UShort::type())], { vec8 }));
	diTypes.emplace(T(Short4::type()), diBuilder->createVectorType(128, 128, diTypes[T(Short::type())], { vec8 }));
	diTypes.emplace(T(UShort4::type()), diBuilder->createVectorType(128, 128, diTypes[T(UShort::type())], { vec8 }));
	diTypes.emplace(T(Short8::type()), diBuilder->createVectorType(128, 128, diTypes[T(Short::type())], { vec8 }));
	diTypes.emplace(T(UShort8::type()), diBuilder->createVectorType(128, 128, diTypes[T(UShort::type())], { vec8 }));
	diTypes.emplace(T(Int2::type()), diBuilder->createVectorType(128, 128, diTypes[T(Int::type())], { vec4 }));
	diTypes.emplace(T(UInt2::type()), diBuilder->createVectorType(128, 128, diTypes[T(UInt::type())], { vec4 }));
	diTypes.emplace(T(Int4::type()), diBuilder->createVectorType(128, 128, diTypes[T(Int::type())], { vec4 }));
	diTypes.emplace(T(UInt4::type()), diBuilder->createVectorType(128, 128, diTypes[T(UInt::type())], { vec4 }));
	diTypes.emplace(T(Float2::type()), diBuilder->createVectorType(128, 128, diTypes[T(Float::type())], { vec4 }));
	diTypes.emplace(T(Float4::type()), diBuilder->createVectorType(128, 128, diTypes[T(Float::type())], { vec4 }));
	}

	Location DebugInfo::getCallerLocation() const
	{
	auto backtrace = getCallerBacktrace(1);
	return backtrace.empty() ? Location{} : backtrace[0];
	}

	Backtrace DebugInfo::getCallerBacktrace(size_t limit /* = 0 */) const
	{
	return rr::getCallerBacktrace(limit);
	}

	llvm::DIType DebugInfo::getOrCreateType(llvm::Type type)
	{
	auto it = diTypes.find(type);
	if(it != diTypes.end()) { return it->second; }

	if(type->isPointerTy())
	{
	auto dbgTy = diBuilder->createPointerType(
	getOrCreateType(type->getPointerElementType()),
	sizeof(void ) 8, alignof(void ) 8);
	diTypes.emplace(type, dbgTy);
	return dbgTy;
	}
	llvm::errs() << "Unimplemented debug type: " << type << "\n";
	assert(false);
	return nullptr;
	}

	llvm::DIFile DebugInfo::getOrCreateFile(const char path)
	{
	auto it = diFiles.find(path);
	if(it != diFiles.end()) { return it->second; }
	auto dirAndName = splitPath(path);
	auto file = diBuilder->createFile(dirAndName.second, dirAndName.first);
	diFiles.emplace(path, file);
	return file;
	}

	DebugInfo::LineTokens const DebugInfo::getOrParseFileTokens(const char path)
	{
	static std::regex reLocalDecl(
	"^" // line start
	"\\s*" // initial whitespace
	"(?:For\\s\\(\\s)?" // optional 'For('
	"((?:\\w+(?:<[^>]+>)?)(?:::\\w+(?:<[^>]+>)?)*)" // type (match group 1)
	"\\s+" // whitespace between type and name
	"(\\w+)" // identifier (match group 2)
	"\\s*" // whitespace after identifier
	"(\\[.*\\])?"); // optional array suffix (match group 3)

	auto it = fileTokens.find(path);
	if(it != fileTokens.end())
	{
	return it->second.get();
	}

	auto tokens = std::make_unique<LineTokens>();

	std::ifstream file(path);
	std::string line;
	int lineCount = 0;
	while(std::getline(file, line))
	{
	lineCount++;
	std::smatch match;
	if(std::regex_search(line, match, reLocalDecl) && match.size() > 3)
	{
	bool isArray = match.str(3) != "";
	if(!isArray) // Cannot deal with C-arrays of values.
	{
	if(match.str(1) == "return")
	{
	(*tokens)[lineCount] = Token{ Token::Return, "" };
	}
	else
	{
	(*tokens)[lineCount] = Token{ Token::Identifier, match.str(2) };
	}
	}
	}
	}

	auto out = tokens.get();
	fileTokens.emplace(path, std::move(tokens));
	return out;
	}

	} // namespace rr

	#endif // ENABLE_RR_DEBUG_INFO