src/third_party/llvm-project/clang/lib/Driver/Action.cpp - cobalt - Git at Google

 //===- Action.cpp - Abstract compilation steps ----------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Driver/Action.h"
 #include "llvm/Support/ErrorHandling.h"
 #include <cassert>
 #include <string>

 using namespace clang;
 using namespace driver;
 using namespace llvm::opt;

 Action::~Action() = default;

 const char *Action::getClassName(ActionClass AC) {
   switch (AC) {
   case InputClass: return "input";
   case BindArchClass: return "bind-arch";
   case OffloadClass:
     return "offload";
   case PreprocessJobClass: return "preprocessor";
   case PrecompileJobClass: return "precompiler";
   case AnalyzeJobClass: return "analyzer";
   case MigrateJobClass: return "migrator";
   case CompileJobClass: return "compiler";
   case BackendJobClass: return "backend";
   case AssembleJobClass: return "assembler";
   case LinkJobClass: return "linker";
   case LipoJobClass: return "lipo";
   case DsymutilJobClass: return "dsymutil";
   case VerifyDebugInfoJobClass: return "verify-debug-info";
   case VerifyPCHJobClass: return "verify-pch";
   case OffloadBundlingJobClass:
     return "clang-offload-bundler";
   case OffloadUnbundlingJobClass:
     return "clang-offload-unbundler";
   }

   llvm_unreachable("invalid class");
 }

 void Action::propagateDeviceOffloadInfo(OffloadKind OKind, const char *OArch) {
   // Offload action set its own kinds on their dependences.
   if (Kind == OffloadClass)
     return;
   // Unbundling actions use the host kinds.
   if (Kind == OffloadUnbundlingJobClass)
     return;

   assert((OffloadingDeviceKind == OKind || OffloadingDeviceKind == OFK_None) &&
          "Setting device kind to a different device??");
   assert(!ActiveOffloadKindMask && "Setting a device kind in a host action??");
   OffloadingDeviceKind = OKind;
   OffloadingArch = OArch;

   for (auto *A : Inputs)
     A->propagateDeviceOffloadInfo(OffloadingDeviceKind, OArch);
 }

 void Action::propagateHostOffloadInfo(unsigned OKinds, const char *OArch) {
   // Offload action set its own kinds on their dependences.
   if (Kind == OffloadClass)
     return;

   assert(OffloadingDeviceKind == OFK_None &&
          "Setting a host kind in a device action.");
   ActiveOffloadKindMask |= OKinds;
   OffloadingArch = OArch;

   for (auto *A : Inputs)
     A->propagateHostOffloadInfo(ActiveOffloadKindMask, OArch);
 }

 void Action::propagateOffloadInfo(const Action *A) {
   if (unsigned HK = A->getOffloadingHostActiveKinds())
     propagateHostOffloadInfo(HK, A->getOffloadingArch());
   else
     propagateDeviceOffloadInfo(A->getOffloadingDeviceKind(),
                                A->getOffloadingArch());
 }

 std::string Action::getOffloadingKindPrefix() const {
   switch (OffloadingDeviceKind) {
   case OFK_None:
     break;
   case OFK_Host:
     llvm_unreachable("Host kind is not an offloading device kind.");
     break;
   case OFK_Cuda:
     return "device-cuda";
   case OFK_OpenMP:
     return "device-openmp";
   case OFK_HIP:
     return "device-hip";

     // TODO: Add other programming models here.
   }

   if (!ActiveOffloadKindMask)
     return {};

   std::string Res("host");
   assert(!((ActiveOffloadKindMask & OFK_Cuda) &&
            (ActiveOffloadKindMask & OFK_HIP)) &&
          "Cannot offload CUDA and HIP at the same time");
   if (ActiveOffloadKindMask & OFK_Cuda)
     Res += "-cuda";
   if (ActiveOffloadKindMask & OFK_HIP)
     Res += "-hip";
   if (ActiveOffloadKindMask & OFK_OpenMP)
     Res += "-openmp";

   // TODO: Add other programming models here.

   return Res;
 }

 /// Return a string that can be used as prefix in order to generate unique files
 /// for each offloading kind.
 std::string
 Action::GetOffloadingFileNamePrefix(OffloadKind Kind,
                                     StringRef NormalizedTriple,
                                     bool CreatePrefixForHost) {
   // Don't generate prefix for host actions unless required.
   if (!CreatePrefixForHost && (Kind == OFK_None || Kind == OFK_Host))
     return {};

   std::string Res("-");
   Res += GetOffloadKindName(Kind);
   Res += "-";
   Res += NormalizedTriple;
   return Res;
 }

 /// Return a string with the offload kind name. If that is not defined, we
 /// assume 'host'.
 StringRef Action::GetOffloadKindName(OffloadKind Kind) {
   switch (Kind) {
   case OFK_None:
   case OFK_Host:
     return "host";
   case OFK_Cuda:
     return "cuda";
   case OFK_OpenMP:
     return "openmp";
   case OFK_HIP:
     return "hip";

     // TODO: Add other programming models here.
   }

   llvm_unreachable("invalid offload kind");
 }

 void InputAction::anchor() {}

 InputAction::InputAction(const Arg &_Input, types::ID _Type)
     : Action(InputClass, _Type), Input(_Input) {}

 void BindArchAction::anchor() {}

 BindArchAction::BindArchAction(Action *Input, StringRef ArchName)
     : Action(BindArchClass, Input), ArchName(ArchName) {}

 void OffloadAction::anchor() {}

 OffloadAction::OffloadAction(const HostDependence &HDep)
     : Action(OffloadClass, HDep.getAction()), HostTC(HDep.getToolChain()) {
   OffloadingArch = HDep.getBoundArch();
   ActiveOffloadKindMask = HDep.getOffloadKinds();
   HDep.getAction()->propagateHostOffloadInfo(HDep.getOffloadKinds(),
                                              HDep.getBoundArch());
 }

 OffloadAction::OffloadAction(const DeviceDependences &DDeps, types::ID Ty)
     : Action(OffloadClass, DDeps.getActions(), Ty),
       DevToolChains(DDeps.getToolChains()) {
   auto &OKinds = DDeps.getOffloadKinds();
   auto &BArchs = DDeps.getBoundArchs();

   // If all inputs agree on the same kind, use it also for this action.
   if (llvm::all_of(OKinds, [&](OffloadKind K) { return K == OKinds.front(); }))
     OffloadingDeviceKind = OKinds.front();

   // If we have a single dependency, inherit the architecture from it.
   if (OKinds.size() == 1)
     OffloadingArch = BArchs.front();

   // Propagate info to the dependencies.
   for (unsigned i = 0, e = getInputs().size(); i != e; ++i)
     getInputs()[i]->propagateDeviceOffloadInfo(OKinds[i], BArchs[i]);
 }

 OffloadAction::OffloadAction(const HostDependence &HDep,
                              const DeviceDependences &DDeps)
     : Action(OffloadClass, HDep.getAction()), HostTC(HDep.getToolChain()),
       DevToolChains(DDeps.getToolChains()) {
   // We use the kinds of the host dependence for this action.
   OffloadingArch = HDep.getBoundArch();
   ActiveOffloadKindMask = HDep.getOffloadKinds();
   HDep.getAction()->propagateHostOffloadInfo(HDep.getOffloadKinds(),
                                              HDep.getBoundArch());

   // Add device inputs and propagate info to the device actions. Do work only if
   // we have dependencies.
   for (unsigned i = 0, e = DDeps.getActions().size(); i != e; ++i)
     if (auto *A = DDeps.getActions()[i]) {
       getInputs().push_back(A);
       A->propagateDeviceOffloadInfo(DDeps.getOffloadKinds()[i],
                                     DDeps.getBoundArchs()[i]);
     }
 }

 void OffloadAction::doOnHostDependence(const OffloadActionWorkTy &Work) const {
   if (!HostTC)
     return;
   assert(!getInputs().empty() && "No dependencies for offload action??");
   auto *A = getInputs().front();
   Work(A, HostTC, A->getOffloadingArch());
 }

 void OffloadAction::doOnEachDeviceDependence(
     const OffloadActionWorkTy &Work) const {
   auto I = getInputs().begin();
   auto E = getInputs().end();
   if (I == E)
     return;

   // We expect to have the same number of input dependences and device tool
   // chains, except if we also have a host dependence. In that case we have one
   // more dependence than we have device tool chains.
   assert(getInputs().size() == DevToolChains.size() + (HostTC ? 1 : 0) &&
          "Sizes of action dependences and toolchains are not consistent!");

   // Skip host action
   if (HostTC)
     ++I;

   auto TI = DevToolChains.begin();
   for (; I != E; ++I, ++TI)
     Work(*I, *TI, (*I)->getOffloadingArch());
 }

 void OffloadAction::doOnEachDependence(const OffloadActionWorkTy &Work) const {
   doOnHostDependence(Work);
   doOnEachDeviceDependence(Work);
 }

 void OffloadAction::doOnEachDependence(bool IsHostDependence,
                                        const OffloadActionWorkTy &Work) const {
   if (IsHostDependence)
     doOnHostDependence(Work);
   else
     doOnEachDeviceDependence(Work);
 }

 bool OffloadAction::hasHostDependence() const { return HostTC != nullptr; }

 Action *OffloadAction::getHostDependence() const {
   assert(hasHostDependence() && "Host dependence does not exist!");
   assert(!getInputs().empty() && "No dependencies for offload action??");
   return HostTC ? getInputs().front() : nullptr;
 }

 bool OffloadAction::hasSingleDeviceDependence(
     bool DoNotConsiderHostActions) const {
   if (DoNotConsiderHostActions)
     return getInputs().size() == (HostTC ? 2 : 1);
   return !HostTC && getInputs().size() == 1;
 }

 Action *
 OffloadAction::getSingleDeviceDependence(bool DoNotConsiderHostActions) const {
   assert(hasSingleDeviceDependence(DoNotConsiderHostActions) &&
          "Single device dependence does not exist!");
   // The previous assert ensures the number of entries in getInputs() is
   // consistent with what we are doing here.
   return HostTC ? getInputs()[1] : getInputs().front();
 }

 void OffloadAction::DeviceDependences::add(Action &A, const ToolChain &TC,
                                            const char *BoundArch,
                                            OffloadKind OKind) {
   DeviceActions.push_back(&A);
   DeviceToolChains.push_back(&TC);
   DeviceBoundArchs.push_back(BoundArch);
   DeviceOffloadKinds.push_back(OKind);
 }

 OffloadAction::HostDependence::HostDependence(Action &A, const ToolChain &TC,
                                               const char *BoundArch,
                                               const DeviceDependences &DDeps)
     : HostAction(A), HostToolChain(TC), HostBoundArch(BoundArch) {
   for (auto K : DDeps.getOffloadKinds())
     HostOffloadKinds |= K;
 }

 void JobAction::anchor() {}

 JobAction::JobAction(ActionClass Kind, Action *Input, types::ID Type)
     : Action(Kind, Input, Type) {}

 JobAction::JobAction(ActionClass Kind, const ActionList &Inputs, types::ID Type)
     : Action(Kind, Inputs, Type) {}

 void PreprocessJobAction::anchor() {}

 PreprocessJobAction::PreprocessJobAction(Action *Input, types::ID OutputType)
     : JobAction(PreprocessJobClass, Input, OutputType) {}

 void PrecompileJobAction::anchor() {}

 PrecompileJobAction::PrecompileJobAction(Action *Input, types::ID OutputType)
     : JobAction(PrecompileJobClass, Input, OutputType) {}

 void AnalyzeJobAction::anchor() {}

 AnalyzeJobAction::AnalyzeJobAction(Action *Input, types::ID OutputType)
     : JobAction(AnalyzeJobClass, Input, OutputType) {}

 void MigrateJobAction::anchor() {}

 MigrateJobAction::MigrateJobAction(Action *Input, types::ID OutputType)
     : JobAction(MigrateJobClass, Input, OutputType) {}

 void CompileJobAction::anchor() {}

 CompileJobAction::CompileJobAction(Action *Input, types::ID OutputType)
     : JobAction(CompileJobClass, Input, OutputType) {}

 void BackendJobAction::anchor() {}

 BackendJobAction::BackendJobAction(Action *Input, types::ID OutputType)
     : JobAction(BackendJobClass, Input, OutputType) {}

 void AssembleJobAction::anchor() {}

 AssembleJobAction::AssembleJobAction(Action *Input, types::ID OutputType)
     : JobAction(AssembleJobClass, Input, OutputType) {}

 void LinkJobAction::anchor() {}

 LinkJobAction::LinkJobAction(ActionList &Inputs, types::ID Type)
     : JobAction(LinkJobClass, Inputs, Type) {}

 void LipoJobAction::anchor() {}

 LipoJobAction::LipoJobAction(ActionList &Inputs, types::ID Type)
     : JobAction(LipoJobClass, Inputs, Type) {}

 void DsymutilJobAction::anchor() {}

 DsymutilJobAction::DsymutilJobAction(ActionList &Inputs, types::ID Type)
     : JobAction(DsymutilJobClass, Inputs, Type) {}

 void VerifyJobAction::anchor() {}

 VerifyJobAction::VerifyJobAction(ActionClass Kind, Action *Input,
                                  types::ID Type)
     : JobAction(Kind, Input, Type) {
   assert((Kind == VerifyDebugInfoJobClass || Kind == VerifyPCHJobClass) &&
          "ActionClass is not a valid VerifyJobAction");
 }

 void VerifyDebugInfoJobAction::anchor() {}

 VerifyDebugInfoJobAction::VerifyDebugInfoJobAction(Action *Input,
                                                    types::ID Type)
     : VerifyJobAction(VerifyDebugInfoJobClass, Input, Type) {}

 void VerifyPCHJobAction::anchor() {}

 VerifyPCHJobAction::VerifyPCHJobAction(Action *Input, types::ID Type)
     : VerifyJobAction(VerifyPCHJobClass, Input, Type) {}

 void OffloadBundlingJobAction::anchor() {}

 OffloadBundlingJobAction::OffloadBundlingJobAction(ActionList &Inputs)
     : JobAction(OffloadBundlingJobClass, Inputs, Inputs.front()->getType()) {}

 void OffloadUnbundlingJobAction::anchor() {}

 OffloadUnbundlingJobAction::OffloadUnbundlingJobAction(Action *Input)
     : JobAction(OffloadUnbundlingJobClass, Input, Input->getType()) {}
	//===- Action.cpp - Abstract compilation steps ----------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Driver/Action.h"
	#include "llvm/Support/ErrorHandling.h"
	#include <cassert>
	#include <string>

	using namespace clang;
	using namespace driver;
	using namespace llvm::opt;

	Action::~Action() = default;

	const char *Action::getClassName(ActionClass AC) {
	switch (AC) {
	case InputClass: return "input";
	case BindArchClass: return "bind-arch";
	case OffloadClass:
	return "offload";
	case PreprocessJobClass: return "preprocessor";
	case PrecompileJobClass: return "precompiler";
	case AnalyzeJobClass: return "analyzer";
	case MigrateJobClass: return "migrator";
	case CompileJobClass: return "compiler";
	case BackendJobClass: return "backend";
	case AssembleJobClass: return "assembler";
	case LinkJobClass: return "linker";
	case LipoJobClass: return "lipo";
	case DsymutilJobClass: return "dsymutil";
	case VerifyDebugInfoJobClass: return "verify-debug-info";
	case VerifyPCHJobClass: return "verify-pch";
	case OffloadBundlingJobClass:
	return "clang-offload-bundler";
	case OffloadUnbundlingJobClass:
	return "clang-offload-unbundler";
	}

	llvm_unreachable("invalid class");
	}

	void Action::propagateDeviceOffloadInfo(OffloadKind OKind, const char *OArch) {
	// Offload action set its own kinds on their dependences.
	if (Kind == OffloadClass)
	return;
	// Unbundling actions use the host kinds.
	if (Kind == OffloadUnbundlingJobClass)
	return;

	assert((OffloadingDeviceKind == OKind \|\| OffloadingDeviceKind == OFK_None) &&
	"Setting device kind to a different device??");
	assert(!ActiveOffloadKindMask && "Setting a device kind in a host action??");
	OffloadingDeviceKind = OKind;
	OffloadingArch = OArch;

	for (auto *A : Inputs)
	A->propagateDeviceOffloadInfo(OffloadingDeviceKind, OArch);
	}

	void Action::propagateHostOffloadInfo(unsigned OKinds, const char *OArch) {
	// Offload action set its own kinds on their dependences.
	if (Kind == OffloadClass)
	return;

	assert(OffloadingDeviceKind == OFK_None &&
	"Setting a host kind in a device action.");
	ActiveOffloadKindMask \|= OKinds;
	OffloadingArch = OArch;

	for (auto *A : Inputs)
	A->propagateHostOffloadInfo(ActiveOffloadKindMask, OArch);
	}

	void Action::propagateOffloadInfo(const Action *A) {
	if (unsigned HK = A->getOffloadingHostActiveKinds())
	propagateHostOffloadInfo(HK, A->getOffloadingArch());
	else
	propagateDeviceOffloadInfo(A->getOffloadingDeviceKind(),
	A->getOffloadingArch());
	}

	std::string Action::getOffloadingKindPrefix() const {
	switch (OffloadingDeviceKind) {
	case OFK_None:
	break;
	case OFK_Host:
	llvm_unreachable("Host kind is not an offloading device kind.");
	break;
	case OFK_Cuda:
	return "device-cuda";
	case OFK_OpenMP:
	return "device-openmp";
	case OFK_HIP:
	return "device-hip";

	// TODO: Add other programming models here.
	}

	if (!ActiveOffloadKindMask)
	return {};

	std::string Res("host");
	assert(!((ActiveOffloadKindMask & OFK_Cuda) &&
	(ActiveOffloadKindMask & OFK_HIP)) &&
	"Cannot offload CUDA and HIP at the same time");
	if (ActiveOffloadKindMask & OFK_Cuda)
	Res += "-cuda";
	if (ActiveOffloadKindMask & OFK_HIP)
	Res += "-hip";
	if (ActiveOffloadKindMask & OFK_OpenMP)
	Res += "-openmp";

	// TODO: Add other programming models here.

	return Res;
	}

	/// Return a string that can be used as prefix in order to generate unique files
	/// for each offloading kind.
	std::string
	Action::GetOffloadingFileNamePrefix(OffloadKind Kind,
	StringRef NormalizedTriple,
	bool CreatePrefixForHost) {
	// Don't generate prefix for host actions unless required.
	if (!CreatePrefixForHost && (Kind == OFK_None \|\| Kind == OFK_Host))
	return {};

	std::string Res("-");
	Res += GetOffloadKindName(Kind);
	Res += "-";
	Res += NormalizedTriple;
	return Res;
	}

	/// Return a string with the offload kind name. If that is not defined, we
	/// assume 'host'.
	StringRef Action::GetOffloadKindName(OffloadKind Kind) {
	switch (Kind) {
	case OFK_None:
	case OFK_Host:
	return "host";
	case OFK_Cuda:
	return "cuda";
	case OFK_OpenMP:
	return "openmp";
	case OFK_HIP:
	return "hip";

	// TODO: Add other programming models here.
	}

	llvm_unreachable("invalid offload kind");
	}

	void InputAction::anchor() {}

	InputAction::InputAction(const Arg &_Input, types::ID _Type)
	: Action(InputClass, _Type), Input(_Input) {}

	void BindArchAction::anchor() {}

	BindArchAction::BindArchAction(Action *Input, StringRef ArchName)
	: Action(BindArchClass, Input), ArchName(ArchName) {}

	void OffloadAction::anchor() {}

	OffloadAction::OffloadAction(const HostDependence &HDep)
	: Action(OffloadClass, HDep.getAction()), HostTC(HDep.getToolChain()) {
	OffloadingArch = HDep.getBoundArch();
	ActiveOffloadKindMask = HDep.getOffloadKinds();
	HDep.getAction()->propagateHostOffloadInfo(HDep.getOffloadKinds(),
	HDep.getBoundArch());
	}

	OffloadAction::OffloadAction(const DeviceDependences &DDeps, types::ID Ty)
	: Action(OffloadClass, DDeps.getActions(), Ty),
	DevToolChains(DDeps.getToolChains()) {
	auto &OKinds = DDeps.getOffloadKinds();
	auto &BArchs = DDeps.getBoundArchs();

	// If all inputs agree on the same kind, use it also for this action.
	if (llvm::all_of(OKinds, [&](OffloadKind K) { return K == OKinds.front(); }))
	OffloadingDeviceKind = OKinds.front();

	// If we have a single dependency, inherit the architecture from it.
	if (OKinds.size() == 1)
	OffloadingArch = BArchs.front();

	// Propagate info to the dependencies.
	for (unsigned i = 0, e = getInputs().size(); i != e; ++i)
	getInputs()[i]->propagateDeviceOffloadInfo(OKinds[i], BArchs[i]);
	}

	OffloadAction::OffloadAction(const HostDependence &HDep,
	const DeviceDependences &DDeps)
	: Action(OffloadClass, HDep.getAction()), HostTC(HDep.getToolChain()),
	DevToolChains(DDeps.getToolChains()) {
	// We use the kinds of the host dependence for this action.
	OffloadingArch = HDep.getBoundArch();
	ActiveOffloadKindMask = HDep.getOffloadKinds();
	HDep.getAction()->propagateHostOffloadInfo(HDep.getOffloadKinds(),
	HDep.getBoundArch());

	// Add device inputs and propagate info to the device actions. Do work only if
	// we have dependencies.
	for (unsigned i = 0, e = DDeps.getActions().size(); i != e; ++i)
	if (auto *A = DDeps.getActions()[i]) {
	getInputs().push_back(A);
	A->propagateDeviceOffloadInfo(DDeps.getOffloadKinds()[i],
	DDeps.getBoundArchs()[i]);
	}
	}

	void OffloadAction::doOnHostDependence(const OffloadActionWorkTy &Work) const {
	if (!HostTC)
	return;
	assert(!getInputs().empty() && "No dependencies for offload action??");
	auto *A = getInputs().front();
	Work(A, HostTC, A->getOffloadingArch());
	}

	void OffloadAction::doOnEachDeviceDependence(
	const OffloadActionWorkTy &Work) const {
	auto I = getInputs().begin();
	auto E = getInputs().end();
	if (I == E)
	return;

	// We expect to have the same number of input dependences and device tool
	// chains, except if we also have a host dependence. In that case we have one
	// more dependence than we have device tool chains.
	assert(getInputs().size() == DevToolChains.size() + (HostTC ? 1 : 0) &&
	"Sizes of action dependences and toolchains are not consistent!");

	// Skip host action
	if (HostTC)
	++I;

	auto TI = DevToolChains.begin();
	for (; I != E; ++I, ++TI)
	Work(I, TI, (*I)->getOffloadingArch());
	}

	void OffloadAction::doOnEachDependence(const OffloadActionWorkTy &Work) const {
	doOnHostDependence(Work);
	doOnEachDeviceDependence(Work);
	}

	void OffloadAction::doOnEachDependence(bool IsHostDependence,
	const OffloadActionWorkTy &Work) const {
	if (IsHostDependence)
	doOnHostDependence(Work);
	else
	doOnEachDeviceDependence(Work);
	}

	bool OffloadAction::hasHostDependence() const { return HostTC != nullptr; }

	Action *OffloadAction::getHostDependence() const {
	assert(hasHostDependence() && "Host dependence does not exist!");
	assert(!getInputs().empty() && "No dependencies for offload action??");
	return HostTC ? getInputs().front() : nullptr;
	}

	bool OffloadAction::hasSingleDeviceDependence(
	bool DoNotConsiderHostActions) const {
	if (DoNotConsiderHostActions)
	return getInputs().size() == (HostTC ? 2 : 1);
	return !HostTC && getInputs().size() == 1;
	}

	Action *
	OffloadAction::getSingleDeviceDependence(bool DoNotConsiderHostActions) const {
	assert(hasSingleDeviceDependence(DoNotConsiderHostActions) &&
	"Single device dependence does not exist!");
	// The previous assert ensures the number of entries in getInputs() is
	// consistent with what we are doing here.
	return HostTC ? getInputs()[1] : getInputs().front();
	}

	void OffloadAction::DeviceDependences::add(Action &A, const ToolChain &TC,
	const char *BoundArch,
	OffloadKind OKind) {
	DeviceActions.push_back(&A);
	DeviceToolChains.push_back(&TC);
	DeviceBoundArchs.push_back(BoundArch);
	DeviceOffloadKinds.push_back(OKind);
	}

	OffloadAction::HostDependence::HostDependence(Action &A, const ToolChain &TC,
	const char *BoundArch,
	const DeviceDependences &DDeps)
	: HostAction(A), HostToolChain(TC), HostBoundArch(BoundArch) {
	for (auto K : DDeps.getOffloadKinds())
	HostOffloadKinds \|= K;
	}

	void JobAction::anchor() {}

	JobAction::JobAction(ActionClass Kind, Action *Input, types::ID Type)
	: Action(Kind, Input, Type) {}

	JobAction::JobAction(ActionClass Kind, const ActionList &Inputs, types::ID Type)
	: Action(Kind, Inputs, Type) {}

	void PreprocessJobAction::anchor() {}

	PreprocessJobAction::PreprocessJobAction(Action *Input, types::ID OutputType)
	: JobAction(PreprocessJobClass, Input, OutputType) {}

	void PrecompileJobAction::anchor() {}

	PrecompileJobAction::PrecompileJobAction(Action *Input, types::ID OutputType)
	: JobAction(PrecompileJobClass, Input, OutputType) {}

	void AnalyzeJobAction::anchor() {}

	AnalyzeJobAction::AnalyzeJobAction(Action *Input, types::ID OutputType)
	: JobAction(AnalyzeJobClass, Input, OutputType) {}

	void MigrateJobAction::anchor() {}

	MigrateJobAction::MigrateJobAction(Action *Input, types::ID OutputType)
	: JobAction(MigrateJobClass, Input, OutputType) {}

	void CompileJobAction::anchor() {}

	CompileJobAction::CompileJobAction(Action *Input, types::ID OutputType)
	: JobAction(CompileJobClass, Input, OutputType) {}

	void BackendJobAction::anchor() {}

	BackendJobAction::BackendJobAction(Action *Input, types::ID OutputType)
	: JobAction(BackendJobClass, Input, OutputType) {}

	void AssembleJobAction::anchor() {}

	AssembleJobAction::AssembleJobAction(Action *Input, types::ID OutputType)
	: JobAction(AssembleJobClass, Input, OutputType) {}

	void LinkJobAction::anchor() {}

	LinkJobAction::LinkJobAction(ActionList &Inputs, types::ID Type)
	: JobAction(LinkJobClass, Inputs, Type) {}

	void LipoJobAction::anchor() {}

	LipoJobAction::LipoJobAction(ActionList &Inputs, types::ID Type)
	: JobAction(LipoJobClass, Inputs, Type) {}

	void DsymutilJobAction::anchor() {}

	DsymutilJobAction::DsymutilJobAction(ActionList &Inputs, types::ID Type)
	: JobAction(DsymutilJobClass, Inputs, Type) {}

	void VerifyJobAction::anchor() {}

	VerifyJobAction::VerifyJobAction(ActionClass Kind, Action *Input,
	types::ID Type)
	: JobAction(Kind, Input, Type) {
	assert((Kind == VerifyDebugInfoJobClass \|\| Kind == VerifyPCHJobClass) &&
	"ActionClass is not a valid VerifyJobAction");
	}

	void VerifyDebugInfoJobAction::anchor() {}

	VerifyDebugInfoJobAction::VerifyDebugInfoJobAction(Action *Input,
	types::ID Type)
	: VerifyJobAction(VerifyDebugInfoJobClass, Input, Type) {}

	void VerifyPCHJobAction::anchor() {}

	VerifyPCHJobAction::VerifyPCHJobAction(Action *Input, types::ID Type)
	: VerifyJobAction(VerifyPCHJobClass, Input, Type) {}

	void OffloadBundlingJobAction::anchor() {}

	OffloadBundlingJobAction::OffloadBundlingJobAction(ActionList &Inputs)
	: JobAction(OffloadBundlingJobClass, Inputs, Inputs.front()->getType()) {}

	void OffloadUnbundlingJobAction::anchor() {}

	OffloadUnbundlingJobAction::OffloadUnbundlingJobAction(Action *Input)
	: JobAction(OffloadUnbundlingJobClass, Input, Input->getType()) {}