third_party/marl/include/marl/dag.h - SwiftShader - Git at Google

 // Copyright 2020 The Marl Authors.
 //
 // 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
 //
 //     https://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.

 // marl::DAG<> provides an ahead of time, declarative, directed acyclic
 // task graph.

 #ifndef marl_dag_h
 #define marl_dag_h

 #include "containers.h"
 #include "export.h"
 #include "memory.h"
 #include "scheduler.h"
 #include "waitgroup.h"

 namespace marl {
 namespace detail {
 using DAGCounter = std::atomic<uint32_t>;
 template <typename T>
 struct DAGRunContext {
   T data;
   Allocator::unique_ptr<DAGCounter> counters;

   template <typename F>
   MARL_NO_EXPORT inline void invoke(F&& f) {
     f(data);
   }
 };
 template <>
 struct DAGRunContext<void> {
   Allocator::unique_ptr<DAGCounter> counters;

   template <typename F>
   MARL_NO_EXPORT inline void invoke(F&& f) {
     f();
   }
 };
 template <typename T>
 struct DAGWork {
   using type = std::function<void(T)>;
 };
 template <>
 struct DAGWork<void> {
   using type = std::function<void()>;
 };
 }  // namespace detail

 ///////////////////////////////////////////////////////////////////////////////
 // Forward declarations
 ///////////////////////////////////////////////////////////////////////////////
 template <typename T>
 class DAG;

 template <typename T>
 class DAGBuilder;

 template <typename T>
 class DAGNodeBuilder;

 ///////////////////////////////////////////////////////////////////////////////
 // DAGBase<T>
 ///////////////////////////////////////////////////////////////////////////////

 // DAGBase is derived by DAG<T> and DAG<void>. It has no public API.
 template <typename T>
 class DAGBase {
  protected:
   friend DAGBuilder<T>;
   friend DAGNodeBuilder<T>;

   using RunContext = detail::DAGRunContext<T>;
   using Counter = detail::DAGCounter;
   using NodeIndex = size_t;
   using Work = typename detail::DAGWork<T>::type;
   static const constexpr size_t NumReservedNodes = 32;
   static const constexpr size_t NumReservedNumOuts = 4;
   static const constexpr size_t InvalidCounterIndex = ~static_cast<size_t>(0);
   static const constexpr NodeIndex RootIndex = 0;
   static const constexpr NodeIndex InvalidNodeIndex =
       ~static_cast<NodeIndex>(0);

   // DAG work node.
   struct Node {
     MARL_NO_EXPORT inline Node() = default;
     MARL_NO_EXPORT inline Node(Work&& work);

     // The work to perform for this node in the graph.
     Work work;

     // counterIndex if valid, is the index of the counter in the RunContext for
     // this node. The counter is decremented for each completed dependency task
     // (ins), and once it reaches 0, this node will be invoked.
     size_t counterIndex = InvalidCounterIndex;

     // Indices for all downstream nodes.
     containers::vector<NodeIndex, NumReservedNumOuts> outs;
   };

   // initCounters() allocates and initializes the ctx->coutners from
   // initialCounters.
   MARL_NO_EXPORT inline void initCounters(RunContext* ctx,
                                           Allocator* allocator);

   // notify() is called each time a dependency task (ins) has completed for the
   // node with the given index.
   // If all dependency tasks have completed (or this is the root node) then
   // notify() returns true and the caller should then call invoke().
   MARL_NO_EXPORT inline bool notify(RunContext*, NodeIndex);

   // invoke() calls the work function for the node with the given index, then
   // calls notify() and possibly invoke() for all the dependee nodes.
   MARL_NO_EXPORT inline void invoke(RunContext*, NodeIndex, WaitGroup*);

   // nodes is the full list of the nodes in the graph.
   // nodes[0] is always the root node, which has no dependencies (ins).
   containers::vector<Node, NumReservedNodes> nodes;

   // initialCounters is a list of initial counter values to be copied to
   // RunContext::counters on DAG<>::run().
   // initialCounters is indexed by Node::counterIndex, and only contains counts
   // for nodes that have at least 2 dependencies (ins) - because of this the
   // number of entries in initialCounters may be fewer than nodes.
   containers::vector<uint32_t, NumReservedNodes> initialCounters;
 };

 template <typename T>
 DAGBase<T>::Node::Node(Work&& work) : work(std::move(work)) {}

 template <typename T>
 void DAGBase<T>::initCounters(RunContext* ctx, Allocator* allocator) {
   auto numCounters = initialCounters.size();
   ctx->counters = allocator->make_unique_n<Counter>(numCounters);
   for (size_t i = 0; i < numCounters; i++) {
     ctx->counters.get()[i] = {initialCounters[i]};
   }
 }

 template <typename T>
 bool DAGBase<T>::notify(RunContext* ctx, NodeIndex nodeIdx) {
   Node* node = &nodes[nodeIdx];

   // If we have multiple dependencies, decrement the counter and check whether
   // we've reached 0.
   if (node->counterIndex == InvalidCounterIndex) {
     return true;
   }
   auto counters = ctx->counters.get();
   auto counter = --counters[node->counterIndex];
   return counter == 0;
 }

 template <typename T>
 void DAGBase<T>::invoke(RunContext* ctx, NodeIndex nodeIdx, WaitGroup* wg) {
   Node* node = &nodes[nodeIdx];

   // Run this node's work.
   if (node->work) {
     ctx->invoke(node->work);
   }

   // Then call notify() on all dependees (outs), and invoke() those that
   // returned true.
   // We buffer the node to invoke (toInvoke) so we can schedule() all but the
   // last node to invoke(), and directly call the last invoke() on this thread.
   // This is done to avoid the overheads of scheduling when a direct call would
   // suffice.
   NodeIndex toInvoke = InvalidNodeIndex;
   for (NodeIndex idx : node->outs) {
     if (notify(ctx, idx)) {
       if (toInvoke != InvalidNodeIndex) {
         wg->add(1);
         // Schedule while promoting the WaitGroup capture from a pointer
         // reference to a value. This ensures that the WaitGroup isn't dropped
         // while in use.
         schedule(
             [=](WaitGroup wg) {
               invoke(ctx, toInvoke, &wg);
               wg.done();
             },
             *wg);
       }
       toInvoke = idx;
     }
   }
   if (toInvoke != InvalidNodeIndex) {
     invoke(ctx, toInvoke, wg);
   }
 }

 ///////////////////////////////////////////////////////////////////////////////
 // DAGNodeBuilder<T>
 ///////////////////////////////////////////////////////////////////////////////

 // DAGNodeBuilder is the builder interface for a DAG node.
 template <typename T>
 class DAGNodeBuilder {
   using NodeIndex = typename DAGBase<T>::NodeIndex;

  public:
   // then() builds and returns a new DAG node that will be invoked after this
   // node has completed.
   //
   // F is a function that will be called when the new DAG node is invoked, with
   // the signature:
   //   void(T)   when T is not void
   // or
   //   void()    when T is void
   template <typename F>
   MARL_NO_EXPORT inline DAGNodeBuilder then(F&&);

  private:
   friend DAGBuilder<T>;
   MARL_NO_EXPORT inline DAGNodeBuilder(DAGBuilder<T>*, NodeIndex);
   DAGBuilder<T>* builder;
   NodeIndex index;
 };

 template <typename T>
 DAGNodeBuilder<T>::DAGNodeBuilder(DAGBuilder<T>* builder, NodeIndex index)
     : builder(builder), index(index) {}

 template <typename T>
 template <typename F>
 DAGNodeBuilder<T> DAGNodeBuilder<T>::then(F&& work) {
   auto node = builder->node(std::move(work));
   builder->addDependency(*this, node);
   return node;
 }

 ///////////////////////////////////////////////////////////////////////////////
 // DAGBuilder<T>
 ///////////////////////////////////////////////////////////////////////////////
 template <typename T>
 class DAGBuilder {
  public:
   // DAGBuilder constructor
   MARL_NO_EXPORT inline DAGBuilder(Allocator* allocator = Allocator::Default);

   // root() returns the root DAG node.
   MARL_NO_EXPORT inline DAGNodeBuilder<T> root();

   // node() builds and returns a new DAG node with no initial dependencies.
   // The returned node must be attached to the graph in order to invoke F or any
   // of the dependees of this returned node.
   //
   // F is a function that will be called when the new DAG node is invoked, with
   // the signature:
   //   void(T)   when T is not void
   // or
   //   void()    when T is void
   template <typename F>
   MARL_NO_EXPORT inline DAGNodeBuilder<T> node(F&& work);

   // node() builds and returns a new DAG node that depends on all the tasks in
   // after to be completed before invoking F.
   //
   // F is a function that will be called when the new DAG node is invoked, with
   // the signature:
   //   void(T)   when T is not void
   // or
   //   void()    when T is void
   template <typename F>
   MARL_NO_EXPORT inline DAGNodeBuilder<T> node(
       F&& work,
       std::initializer_list<DAGNodeBuilder<T>> after);

   // addDependency() adds parent as dependency on child. All dependencies of
   // child must have completed before child is invoked.
   MARL_NO_EXPORT inline void addDependency(DAGNodeBuilder<T> parent,
                                            DAGNodeBuilder<T> child);

   // build() constructs and returns the DAG. No other methods of this class may
   // be called after calling build().
   MARL_NO_EXPORT inline Allocator::unique_ptr<DAG<T>> build();

  private:
   static const constexpr size_t NumReservedNumIns = 4;
   using Node = typename DAG<T>::Node;

   // The DAG being built.
   Allocator::unique_ptr<DAG<T>> dag;

   // Number of dependencies (ins) for each node in dag->nodes.
   containers::vector<uint32_t, NumReservedNumIns> numIns;
 };

 template <typename T>
 DAGBuilder<T>::DAGBuilder(Allocator* allocator /* = Allocator::Default */)
     : dag(allocator->make_unique<DAG<T>>()), numIns(allocator) {
   // Add root
   dag->nodes.emplace_back(Node{});
   numIns.emplace_back(0);
 }

 template <typename T>
 DAGNodeBuilder<T> DAGBuilder<T>::root() {
   return DAGNodeBuilder<T>{this, DAGBase<T>::RootIndex};
 }

 template <typename T>
 template <typename F>
 DAGNodeBuilder<T> DAGBuilder<T>::node(F&& work) {
   return node(std::forward<F>(work), {});
 }

 template <typename T>
 template <typename F>
 DAGNodeBuilder<T> DAGBuilder<T>::node(
     F&& work,
     std::initializer_list<DAGNodeBuilder<T>> after) {
   MARL_ASSERT(numIns.size() == dag->nodes.size(),
               "NodeBuilder vectors out of sync");
   auto index = dag->nodes.size();
   numIns.emplace_back(0);
   dag->nodes.emplace_back(Node{std::move(work)});
   auto node = DAGNodeBuilder<T>{this, index};
   for (auto in : after) {
     addDependency(in, node);
   }
   return node;
 }

 template <typename T>
 void DAGBuilder<T>::addDependency(DAGNodeBuilder<T> parent,
                                   DAGNodeBuilder<T> child) {
   numIns[child.index]++;
   dag->nodes[parent.index].outs.push_back(child.index);
 }

 template <typename T>
 Allocator::unique_ptr<DAG<T>> DAGBuilder<T>::build() {
   auto numNodes = dag->nodes.size();
   MARL_ASSERT(numIns.size() == dag->nodes.size(),
               "NodeBuilder vectors out of sync");
   for (size_t i = 0; i < numNodes; i++) {
     if (numIns[i] > 1) {
       auto& node = dag->nodes[i];
       node.counterIndex = dag->initialCounters.size();
       dag->initialCounters.push_back(numIns[i]);
     }
   }
   return std::move(dag);
 }

 ///////////////////////////////////////////////////////////////////////////////
 // DAG<T>
 ///////////////////////////////////////////////////////////////////////////////
 template <typename T = void>
 class DAG : public DAGBase<T> {
  public:
   using Builder = DAGBuilder<T>;
   using NodeBuilder = DAGNodeBuilder<T>;

   // run() invokes the function of each node in the graph of the DAG, passing
   // data to each, starting with the root node. All dependencies need to have
   // completed their function before dependees will be invoked.
   MARL_NO_EXPORT inline void run(T& data,
                                  Allocator* allocator = Allocator::Default);
 };

 template <typename T>
 void DAG<T>::run(T& arg, Allocator* allocator /* = Allocator::Default */) {
   typename DAGBase<T>::RunContext ctx{arg};
   this->initCounters(&ctx, allocator);
   WaitGroup wg;
   this->invoke(&ctx, this->RootIndex, &wg);
   wg.wait();
 }

 ///////////////////////////////////////////////////////////////////////////////
 // DAG<void>
 ///////////////////////////////////////////////////////////////////////////////
 template <>
 class DAG<void> : public DAGBase<void> {
  public:
   using Builder = DAGBuilder<void>;
   using NodeBuilder = DAGNodeBuilder<void>;

   // run() invokes the function of each node in the graph of the DAG, starting
   // with the root node. All dependencies need to have completed their function
   // before dependees will be invoked.
   MARL_NO_EXPORT inline void run(Allocator* allocator = Allocator::Default);
 };

 void DAG<void>::run(Allocator* allocator /* = Allocator::Default */) {
   typename DAGBase<void>::RunContext ctx{};
   this->initCounters(&ctx, allocator);
   WaitGroup wg;
   this->invoke(&ctx, this->RootIndex, &wg);
   wg.wait();
 }

 }  // namespace marl

 #endif  // marl_dag_h
	// Copyright 2020 The Marl Authors.
	//
	// 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
	//
	// https://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.

	// marl::DAG<> provides an ahead of time, declarative, directed acyclic
	// task graph.

	#ifndef marl_dag_h
	#define marl_dag_h

	#include "containers.h"
	#include "export.h"
	#include "memory.h"
	#include "scheduler.h"
	#include "waitgroup.h"

	namespace marl {
	namespace detail {
	using DAGCounter = std::atomic<uint32_t>;
	template <typename T>
	struct DAGRunContext {
	T data;
	Allocator::unique_ptr<DAGCounter> counters;

	template <typename F>
	MARL_NO_EXPORT inline void invoke(F&& f) {
	f(data);
	}
	};
	template <>
	struct DAGRunContext<void> {
	Allocator::unique_ptr<DAGCounter> counters;

	template <typename F>
	MARL_NO_EXPORT inline void invoke(F&& f) {
	f();
	}
	};
	template <typename T>
	struct DAGWork {
	using type = std::function<void(T)>;
	};
	template <>
	struct DAGWork<void> {
	using type = std::function<void()>;
	};
	} // namespace detail

	///////////////////////////////////////////////////////////////////////////////
	// Forward declarations
	///////////////////////////////////////////////////////////////////////////////
	template <typename T>
	class DAG;

	template <typename T>
	class DAGBuilder;

	template <typename T>
	class DAGNodeBuilder;

	///////////////////////////////////////////////////////////////////////////////
	// DAGBase<T>
	///////////////////////////////////////////////////////////////////////////////

	// DAGBase is derived by DAG<T> and DAG<void>. It has no public API.
	template <typename T>
	class DAGBase {
	protected:
	friend DAGBuilder<T>;
	friend DAGNodeBuilder<T>;

	using RunContext = detail::DAGRunContext<T>;
	using Counter = detail::DAGCounter;
	using NodeIndex = size_t;
	using Work = typename detail::DAGWork<T>::type;
	static const constexpr size_t NumReservedNodes = 32;
	static const constexpr size_t NumReservedNumOuts = 4;
	static const constexpr size_t InvalidCounterIndex = ~static_cast<size_t>(0);
	static const constexpr NodeIndex RootIndex = 0;
	static const constexpr NodeIndex InvalidNodeIndex =
	~static_cast<NodeIndex>(0);

	// DAG work node.
	struct Node {
	MARL_NO_EXPORT inline Node() = default;
	MARL_NO_EXPORT inline Node(Work&& work);

	// The work to perform for this node in the graph.
	Work work;

	// counterIndex if valid, is the index of the counter in the RunContext for
	// this node. The counter is decremented for each completed dependency task
	// (ins), and once it reaches 0, this node will be invoked.
	size_t counterIndex = InvalidCounterIndex;

	// Indices for all downstream nodes.
	containers::vector<NodeIndex, NumReservedNumOuts> outs;
	};

	// initCounters() allocates and initializes the ctx->coutners from
	// initialCounters.
	MARL_NO_EXPORT inline void initCounters(RunContext* ctx,
	Allocator* allocator);

	// notify() is called each time a dependency task (ins) has completed for the
	// node with the given index.
	// If all dependency tasks have completed (or this is the root node) then
	// notify() returns true and the caller should then call invoke().
	MARL_NO_EXPORT inline bool notify(RunContext*, NodeIndex);

	// invoke() calls the work function for the node with the given index, then
	// calls notify() and possibly invoke() for all the dependee nodes.
	MARL_NO_EXPORT inline void invoke(RunContext, NodeIndex, WaitGroup);

	// nodes is the full list of the nodes in the graph.
	// nodes[0] is always the root node, which has no dependencies (ins).
	containers::vector<Node, NumReservedNodes> nodes;

	// initialCounters is a list of initial counter values to be copied to
	// RunContext::counters on DAG<>::run().
	// initialCounters is indexed by Node::counterIndex, and only contains counts
	// for nodes that have at least 2 dependencies (ins) - because of this the
	// number of entries in initialCounters may be fewer than nodes.
	containers::vector<uint32_t, NumReservedNodes> initialCounters;
	};

	template <typename T>
	DAGBase<T>::Node::Node(Work&& work) : work(std::move(work)) {}

	template <typename T>
	void DAGBase<T>::initCounters(RunContext* ctx, Allocator* allocator) {
	auto numCounters = initialCounters.size();
	ctx->counters = allocator->make_unique_n<Counter>(numCounters);
	for (size_t i = 0; i < numCounters; i++) {
	ctx->counters.get()[i] = {initialCounters[i]};
	}
	}

	template <typename T>
	bool DAGBase<T>::notify(RunContext* ctx, NodeIndex nodeIdx) {
	Node* node = &nodes[nodeIdx];

	// If we have multiple dependencies, decrement the counter and check whether
	// we've reached 0.
	if (node->counterIndex == InvalidCounterIndex) {
	return true;
	}
	auto counters = ctx->counters.get();
	auto counter = --counters[node->counterIndex];
	return counter == 0;
	}

	template <typename T>
	void DAGBase<T>::invoke(RunContext* ctx, NodeIndex nodeIdx, WaitGroup* wg) {
	Node* node = &nodes[nodeIdx];

	// Run this node's work.
	if (node->work) {
	ctx->invoke(node->work);
	}

	// Then call notify() on all dependees (outs), and invoke() those that
	// returned true.
	// We buffer the node to invoke (toInvoke) so we can schedule() all but the
	// last node to invoke(), and directly call the last invoke() on this thread.
	// This is done to avoid the overheads of scheduling when a direct call would
	// suffice.
	NodeIndex toInvoke = InvalidNodeIndex;
	for (NodeIndex idx : node->outs) {
	if (notify(ctx, idx)) {
	if (toInvoke != InvalidNodeIndex) {
	wg->add(1);
	// Schedule while promoting the WaitGroup capture from a pointer
	// reference to a value. This ensures that the WaitGroup isn't dropped
	// while in use.
	schedule(
	[=](WaitGroup wg) {
	invoke(ctx, toInvoke, &wg);
	wg.done();
	},
	*wg);
	}
	toInvoke = idx;
	}
	}
	if (toInvoke != InvalidNodeIndex) {
	invoke(ctx, toInvoke, wg);
	}
	}

	///////////////////////////////////////////////////////////////////////////////
	// DAGNodeBuilder<T>
	///////////////////////////////////////////////////////////////////////////////

	// DAGNodeBuilder is the builder interface for a DAG node.
	template <typename T>
	class DAGNodeBuilder {
	using NodeIndex = typename DAGBase<T>::NodeIndex;

	public:
	// then() builds and returns a new DAG node that will be invoked after this
	// node has completed.
	//
	// F is a function that will be called when the new DAG node is invoked, with
	// the signature:
	// void(T) when T is not void
	// or
	// void() when T is void
	template <typename F>
	MARL_NO_EXPORT inline DAGNodeBuilder then(F&&);

	private:
	friend DAGBuilder<T>;
	MARL_NO_EXPORT inline DAGNodeBuilder(DAGBuilder<T>*, NodeIndex);
	DAGBuilder<T>* builder;
	NodeIndex index;
	};

	template <typename T>
	DAGNodeBuilder<T>::DAGNodeBuilder(DAGBuilder<T>* builder, NodeIndex index)
	: builder(builder), index(index) {}

	template <typename T>
	template <typename F>
	DAGNodeBuilder<T> DAGNodeBuilder<T>::then(F&& work) {
	auto node = builder->node(std::move(work));
	builder->addDependency(*this, node);
	return node;
	}

	///////////////////////////////////////////////////////////////////////////////
	// DAGBuilder<T>
	///////////////////////////////////////////////////////////////////////////////
	template <typename T>
	class DAGBuilder {
	public:
	// DAGBuilder constructor
	MARL_NO_EXPORT inline DAGBuilder(Allocator* allocator = Allocator::Default);

	// root() returns the root DAG node.
	MARL_NO_EXPORT inline DAGNodeBuilder<T> root();

	// node() builds and returns a new DAG node with no initial dependencies.
	// The returned node must be attached to the graph in order to invoke F or any
	// of the dependees of this returned node.
	//
	// F is a function that will be called when the new DAG node is invoked, with
	// the signature:
	// void(T) when T is not void
	// or
	// void() when T is void
	template <typename F>
	MARL_NO_EXPORT inline DAGNodeBuilder<T> node(F&& work);

	// node() builds and returns a new DAG node that depends on all the tasks in
	// after to be completed before invoking F.
	//
	// F is a function that will be called when the new DAG node is invoked, with
	// the signature:
	// void(T) when T is not void
	// or
	// void() when T is void
	template <typename F>
	MARL_NO_EXPORT inline DAGNodeBuilder<T> node(
	F&& work,
	std::initializer_list<DAGNodeBuilder<T>> after);

	// addDependency() adds parent as dependency on child. All dependencies of
	// child must have completed before child is invoked.
	MARL_NO_EXPORT inline void addDependency(DAGNodeBuilder<T> parent,
	DAGNodeBuilder<T> child);

	// build() constructs and returns the DAG. No other methods of this class may
	// be called after calling build().
	MARL_NO_EXPORT inline Allocator::unique_ptr<DAG<T>> build();

	private:
	static const constexpr size_t NumReservedNumIns = 4;
	using Node = typename DAG<T>::Node;

	// The DAG being built.
	Allocator::unique_ptr<DAG<T>> dag;

	// Number of dependencies (ins) for each node in dag->nodes.
	containers::vector<uint32_t, NumReservedNumIns> numIns;
	};

	template <typename T>
	DAGBuilder<T>::DAGBuilder(Allocator* allocator /* = Allocator::Default */)
	: dag(allocator->make_unique<DAG<T>>()), numIns(allocator) {
	// Add root
	dag->nodes.emplace_back(Node{});
	numIns.emplace_back(0);
	}

	template <typename T>
	DAGNodeBuilder<T> DAGBuilder<T>::root() {
	return DAGNodeBuilder<T>{this, DAGBase<T>::RootIndex};
	}

	template <typename T>
	template <typename F>
	DAGNodeBuilder<T> DAGBuilder<T>::node(F&& work) {
	return node(std::forward<F>(work), {});
	}

	template <typename T>
	template <typename F>
	DAGNodeBuilder<T> DAGBuilder<T>::node(
	F&& work,
	std::initializer_list<DAGNodeBuilder<T>> after) {
	MARL_ASSERT(numIns.size() == dag->nodes.size(),
	"NodeBuilder vectors out of sync");
	auto index = dag->nodes.size();
	numIns.emplace_back(0);
	dag->nodes.emplace_back(Node{std::move(work)});
	auto node = DAGNodeBuilder<T>{this, index};
	for (auto in : after) {
	addDependency(in, node);
	}
	return node;
	}

	template <typename T>
	void DAGBuilder<T>::addDependency(DAGNodeBuilder<T> parent,
	DAGNodeBuilder<T> child) {
	numIns[child.index]++;
	dag->nodes[parent.index].outs.push_back(child.index);
	}

	template <typename T>
	Allocator::unique_ptr<DAG<T>> DAGBuilder<T>::build() {
	auto numNodes = dag->nodes.size();
	MARL_ASSERT(numIns.size() == dag->nodes.size(),
	"NodeBuilder vectors out of sync");
	for (size_t i = 0; i < numNodes; i++) {
	if (numIns[i] > 1) {
	auto& node = dag->nodes[i];
	node.counterIndex = dag->initialCounters.size();
	dag->initialCounters.push_back(numIns[i]);
	}
	}
	return std::move(dag);
	}

	///////////////////////////////////////////////////////////////////////////////
	// DAG<T>
	///////////////////////////////////////////////////////////////////////////////
	template <typename T = void>
	class DAG : public DAGBase<T> {
	public:
	using Builder = DAGBuilder<T>;
	using NodeBuilder = DAGNodeBuilder<T>;

	// run() invokes the function of each node in the graph of the DAG, passing
	// data to each, starting with the root node. All dependencies need to have
	// completed their function before dependees will be invoked.
	MARL_NO_EXPORT inline void run(T& data,
	Allocator* allocator = Allocator::Default);
	};

	template <typename T>
	void DAG<T>::run(T& arg, Allocator* allocator /* = Allocator::Default */) {
	typename DAGBase<T>::RunContext ctx{arg};
	this->initCounters(&ctx, allocator);
	WaitGroup wg;
	this->invoke(&ctx, this->RootIndex, &wg);
	wg.wait();
	}

	///////////////////////////////////////////////////////////////////////////////
	// DAG<void>
	///////////////////////////////////////////////////////////////////////////////
	template <>
	class DAG<void> : public DAGBase<void> {
	public:
	using Builder = DAGBuilder<void>;
	using NodeBuilder = DAGNodeBuilder<void>;

	// run() invokes the function of each node in the graph of the DAG, starting
	// with the root node. All dependencies need to have completed their function
	// before dependees will be invoked.
	MARL_NO_EXPORT inline void run(Allocator* allocator = Allocator::Default);
	};

	void DAG<void>::run(Allocator* allocator /* = Allocator::Default */) {
	typename DAGBase<void>::RunContext ctx{};
	this->initCounters(&ctx, allocator);
	WaitGroup wg;
	this->invoke(&ctx, this->RootIndex, &wg);
	wg.wait();
	}

	} // namespace marl

	#endif // marl_dag_h