lib/Support/DAGDeltaAlgorithm.cpp - chromiumos/third_party/llvm - Git at Google

 //===--- DAGDeltaAlgorithm.cpp - A DAG Minimization Algorithm --*- C++ -*--===//
 //
 // 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
 //===----------------------------------------------------------------------===//
 //
 // The algorithm we use attempts to exploit the dependency information by
 // minimizing top-down. We start by constructing an initial root set R, and
 // then iteratively:
 //
 //   1. Minimize the set R using the test predicate:
 //       P'(S) = P(S union pred*(S))
 //
 //   2. Extend R to R' = R union pred(R).
 //
 // until a fixed point is reached.
 //
 // The idea is that we want to quickly prune entire portions of the graph, so we
 // try to find high-level nodes that can be eliminated with all of their
 // dependents.
 //
 // FIXME: The current algorithm doesn't actually provide a strong guarantee
 // about the minimality of the result. The problem is that after adding nodes to
 // the required set, we no longer consider them for elimination. For strictly
 // well formed predicates, this doesn't happen, but it commonly occurs in
 // practice when there are unmodelled dependencies. I believe we can resolve
 // this by allowing the required set to be minimized as well, but need more test
 // cases first.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ADT/DAGDeltaAlgorithm.h"
 #include "llvm/ADT/DeltaAlgorithm.h"
 #include "llvm/Support/Debug.h"
 #include "llvm/Support/Format.h"
 #include "llvm/Support/raw_ostream.h"
 #include <algorithm>
 #include <cassert>
 #include <iterator>
 #include <map>
 using namespace llvm;

 #define DEBUG_TYPE "dag-delta"

 namespace {

 class DAGDeltaAlgorithmImpl {
   friend class DeltaActiveSetHelper;

 public:
   typedef DAGDeltaAlgorithm::change_ty change_ty;
   typedef DAGDeltaAlgorithm::changeset_ty changeset_ty;
   typedef DAGDeltaAlgorithm::changesetlist_ty changesetlist_ty;
   typedef DAGDeltaAlgorithm::edge_ty edge_ty;

 private:
   typedef std::vector<change_ty>::iterator pred_iterator_ty;
   typedef std::vector<change_ty>::iterator succ_iterator_ty;
   typedef std::set<change_ty>::iterator pred_closure_iterator_ty;
   typedef std::set<change_ty>::iterator succ_closure_iterator_ty;

   DAGDeltaAlgorithm &DDA;

   std::vector<change_ty> Roots;

   /// Cache of failed test results. Successful test results are never cached
   /// since we always reduce following a success. We maintain an independent
   /// cache from that used by the individual delta passes because we may get
   /// hits across multiple individual delta invocations.
   mutable std::set<changeset_ty> FailedTestsCache;

   // FIXME: Gross.
   std::map<change_ty, std::vector<change_ty> > Predecessors;
   std::map<change_ty, std::vector<change_ty> > Successors;

   std::map<change_ty, std::set<change_ty> > PredClosure;
   std::map<change_ty, std::set<change_ty> > SuccClosure;

 private:
   pred_iterator_ty pred_begin(change_ty Node) {
     assert(Predecessors.count(Node) && "Invalid node!");
     return Predecessors[Node].begin();
   }
   pred_iterator_ty pred_end(change_ty Node) {
     assert(Predecessors.count(Node) && "Invalid node!");
     return Predecessors[Node].end();
   }

   pred_closure_iterator_ty pred_closure_begin(change_ty Node) {
     assert(PredClosure.count(Node) && "Invalid node!");
     return PredClosure[Node].begin();
   }
   pred_closure_iterator_ty pred_closure_end(change_ty Node) {
     assert(PredClosure.count(Node) && "Invalid node!");
     return PredClosure[Node].end();
   }

   succ_iterator_ty succ_begin(change_ty Node) {
     assert(Successors.count(Node) && "Invalid node!");
     return Successors[Node].begin();
   }
   succ_iterator_ty succ_end(change_ty Node) {
     assert(Successors.count(Node) && "Invalid node!");
     return Successors[Node].end();
   }

   succ_closure_iterator_ty succ_closure_begin(change_ty Node) {
     assert(SuccClosure.count(Node) && "Invalid node!");
     return SuccClosure[Node].begin();
   }
   succ_closure_iterator_ty succ_closure_end(change_ty Node) {
     assert(SuccClosure.count(Node) && "Invalid node!");
     return SuccClosure[Node].end();
   }

   void UpdatedSearchState(const changeset_ty &Changes,
                           const changesetlist_ty &Sets,
                           const changeset_ty &Required) {
     DDA.UpdatedSearchState(Changes, Sets, Required);
   }

   /// ExecuteOneTest - Execute a single test predicate on the change set \p S.
   bool ExecuteOneTest(const changeset_ty &S) {
     // Check dependencies invariant.
     LLVM_DEBUG({
       for (changeset_ty::const_iterator it = S.begin(), ie = S.end(); it != ie;
            ++it)
         for (succ_iterator_ty it2 = succ_begin(*it), ie2 = succ_end(*it);
              it2 != ie2; ++it2)
           assert(S.count(*it2) && "Attempt to run invalid changeset!");
     });

     return DDA.ExecuteOneTest(S);
   }

 public:
   DAGDeltaAlgorithmImpl(DAGDeltaAlgorithm &DDA, const changeset_ty &Changes,
                         const std::vector<edge_ty> &Dependencies);

   changeset_ty Run();

   /// GetTestResult - Get the test result for the active set \p Changes with
   /// \p Required changes from the cache, executing the test if necessary.
   ///
   /// \param Changes - The set of active changes being minimized, which should
   /// have their pred closure included in the test.
   /// \param Required - The set of changes which have previously been
   /// established to be required.
   /// \return - The test result.
   bool GetTestResult(const changeset_ty &Changes, const changeset_ty &Required);
 };

 /// Helper object for minimizing an active set of changes.
 class DeltaActiveSetHelper : public DeltaAlgorithm {
   DAGDeltaAlgorithmImpl &DDAI;

   const changeset_ty &Required;

 protected:
   /// UpdatedSearchState - Callback used when the search state changes.
   void UpdatedSearchState(const changeset_ty &Changes,
                                   const changesetlist_ty &Sets) override {
     DDAI.UpdatedSearchState(Changes, Sets, Required);
   }

   bool ExecuteOneTest(const changeset_ty &S) override {
     return DDAI.GetTestResult(S, Required);
   }

 public:
   DeltaActiveSetHelper(DAGDeltaAlgorithmImpl &DDAI,
                        const changeset_ty &Required)
       : DDAI(DDAI), Required(Required) {}
 };

 }

 DAGDeltaAlgorithmImpl::DAGDeltaAlgorithmImpl(
     DAGDeltaAlgorithm &DDA, const changeset_ty &Changes,
     const std::vector<edge_ty> &Dependencies)
     : DDA(DDA) {
   for (changeset_ty::const_iterator it = Changes.begin(),
          ie = Changes.end(); it != ie; ++it) {
     Predecessors.insert(std::make_pair(*it, std::vector<change_ty>()));
     Successors.insert(std::make_pair(*it, std::vector<change_ty>()));
   }
   for (std::vector<edge_ty>::const_iterator it = Dependencies.begin(),
          ie = Dependencies.end(); it != ie; ++it) {
     Predecessors[it->second].push_back(it->first);
     Successors[it->first].push_back(it->second);
   }

   // Compute the roots.
   for (changeset_ty::const_iterator it = Changes.begin(),
          ie = Changes.end(); it != ie; ++it)
     if (succ_begin(*it) == succ_end(*it))
       Roots.push_back(*it);

   // Pre-compute the closure of the successor relation.
   std::vector<change_ty> Worklist(Roots.begin(), Roots.end());
   while (!Worklist.empty()) {
     change_ty Change = Worklist.back();
     Worklist.pop_back();

     std::set<change_ty> &ChangeSuccs = SuccClosure[Change];
     for (pred_iterator_ty it = pred_begin(Change),
            ie = pred_end(Change); it != ie; ++it) {
       SuccClosure[*it].insert(Change);
       SuccClosure[*it].insert(ChangeSuccs.begin(), ChangeSuccs.end());
       Worklist.push_back(*it);
     }
   }

   // Invert to form the predecessor closure map.
   for (changeset_ty::const_iterator it = Changes.begin(),
          ie = Changes.end(); it != ie; ++it)
     PredClosure.insert(std::make_pair(*it, std::set<change_ty>()));
   for (changeset_ty::const_iterator it = Changes.begin(),
          ie = Changes.end(); it != ie; ++it)
     for (succ_closure_iterator_ty it2 = succ_closure_begin(*it),
            ie2 = succ_closure_end(*it); it2 != ie2; ++it2)
       PredClosure[*it2].insert(*it);

   // Dump useful debug info.
   LLVM_DEBUG({
     llvm::errs() << "-- DAGDeltaAlgorithmImpl --\n";
     llvm::errs() << "Changes: [";
     for (changeset_ty::const_iterator it = Changes.begin(), ie = Changes.end();
          it != ie; ++it) {
       if (it != Changes.begin())
         llvm::errs() << ", ";
       llvm::errs() << *it;

       if (succ_begin(*it) != succ_end(*it)) {
         llvm::errs() << "(";
         for (succ_iterator_ty it2 = succ_begin(*it), ie2 = succ_end(*it);
              it2 != ie2; ++it2) {
           if (it2 != succ_begin(*it))
             llvm::errs() << ", ";
           llvm::errs() << "->" << *it2;
         }
         llvm::errs() << ")";
       }
     }
     llvm::errs() << "]\n";

     llvm::errs() << "Roots: [";
     for (std::vector<change_ty>::const_iterator it = Roots.begin(),
                                                 ie = Roots.end();
          it != ie; ++it) {
       if (it != Roots.begin())
         llvm::errs() << ", ";
       llvm::errs() << *it;
     }
     llvm::errs() << "]\n";

     llvm::errs() << "Predecessor Closure:\n";
     for (changeset_ty::const_iterator it = Changes.begin(), ie = Changes.end();
          it != ie; ++it) {
       llvm::errs() << format("  %-4d: [", *it);
       for (pred_closure_iterator_ty it2 = pred_closure_begin(*it),
                                     ie2 = pred_closure_end(*it);
            it2 != ie2; ++it2) {
         if (it2 != pred_closure_begin(*it))
           llvm::errs() << ", ";
         llvm::errs() << *it2;
       }
       llvm::errs() << "]\n";
     }

     llvm::errs() << "Successor Closure:\n";
     for (changeset_ty::const_iterator it = Changes.begin(), ie = Changes.end();
          it != ie; ++it) {
       llvm::errs() << format("  %-4d: [", *it);
       for (succ_closure_iterator_ty it2 = succ_closure_begin(*it),
                                     ie2 = succ_closure_end(*it);
            it2 != ie2; ++it2) {
         if (it2 != succ_closure_begin(*it))
           llvm::errs() << ", ";
         llvm::errs() << *it2;
       }
       llvm::errs() << "]\n";
     }

     llvm::errs() << "\n\n";
   });
 }

 bool DAGDeltaAlgorithmImpl::GetTestResult(const changeset_ty &Changes,
                                           const changeset_ty &Required) {
   changeset_ty Extended(Required);
   Extended.insert(Changes.begin(), Changes.end());
   for (changeset_ty::const_iterator it = Changes.begin(),
          ie = Changes.end(); it != ie; ++it)
     Extended.insert(pred_closure_begin(*it), pred_closure_end(*it));

   if (FailedTestsCache.count(Extended))
     return false;

   bool Result = ExecuteOneTest(Extended);
   if (!Result)
     FailedTestsCache.insert(Extended);

   return Result;
 }

 DAGDeltaAlgorithm::changeset_ty
 DAGDeltaAlgorithmImpl::Run() {
   // The current set of changes we are minimizing, starting at the roots.
   changeset_ty CurrentSet(Roots.begin(), Roots.end());

   // The set of required changes.
   changeset_ty Required;

   // Iterate until the active set of changes is empty. Convergence is guaranteed
   // assuming input was a DAG.
   //
   // Invariant:  CurrentSet intersect Required == {}
   // Invariant:  Required == (Required union succ*(Required))
   while (!CurrentSet.empty()) {
     LLVM_DEBUG({
       llvm::errs() << "DAG_DD - " << CurrentSet.size() << " active changes, "
                    << Required.size() << " required changes\n";
     });

     // Minimize the current set of changes.
     DeltaActiveSetHelper Helper(*this, Required);
     changeset_ty CurrentMinSet = Helper.Run(CurrentSet);

     // Update the set of required changes. Since
     //   CurrentMinSet subset CurrentSet
     // and after the last iteration,
     //   succ(CurrentSet) subset Required
     // then
     //   succ(CurrentMinSet) subset Required
     // and our invariant on Required is maintained.
     Required.insert(CurrentMinSet.begin(), CurrentMinSet.end());

     // Replace the current set with the predecssors of the minimized set of
     // active changes.
     CurrentSet.clear();
     for (changeset_ty::const_iterator it = CurrentMinSet.begin(),
            ie = CurrentMinSet.end(); it != ie; ++it)
       CurrentSet.insert(pred_begin(*it), pred_end(*it));

     // FIXME: We could enforce CurrentSet intersect Required == {} here if we
     // wanted to protect against cyclic graphs.
   }

   return Required;
 }

 void DAGDeltaAlgorithm::anchor() {
 }

 DAGDeltaAlgorithm::changeset_ty
 DAGDeltaAlgorithm::Run(const changeset_ty &Changes,
                        const std::vector<edge_ty> &Dependencies) {
   return DAGDeltaAlgorithmImpl(*this, Changes, Dependencies).Run();
 }
	//===--- DAGDeltaAlgorithm.cpp - A DAG Minimization Algorithm --- C++ ---===//
	//
	// 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
	//===----------------------------------------------------------------------===//
	//
	// The algorithm we use attempts to exploit the dependency information by
	// minimizing top-down. We start by constructing an initial root set R, and
	// then iteratively:
	//
	// 1. Minimize the set R using the test predicate:
	// P'(S) = P(S union pred*(S))
	//
	// 2. Extend R to R' = R union pred(R).
	//
	// until a fixed point is reached.
	//
	// The idea is that we want to quickly prune entire portions of the graph, so we
	// try to find high-level nodes that can be eliminated with all of their
	// dependents.
	//
	// FIXME: The current algorithm doesn't actually provide a strong guarantee
	// about the minimality of the result. The problem is that after adding nodes to
	// the required set, we no longer consider them for elimination. For strictly
	// well formed predicates, this doesn't happen, but it commonly occurs in
	// practice when there are unmodelled dependencies. I believe we can resolve
	// this by allowing the required set to be minimized as well, but need more test
	// cases first.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ADT/DAGDeltaAlgorithm.h"
	#include "llvm/ADT/DeltaAlgorithm.h"
	#include "llvm/Support/Debug.h"
	#include "llvm/Support/Format.h"
	#include "llvm/Support/raw_ostream.h"
	#include <algorithm>
	#include <cassert>
	#include <iterator>
	#include <map>
	using namespace llvm;

	#define DEBUG_TYPE "dag-delta"

	namespace {

	class DAGDeltaAlgorithmImpl {
	friend class DeltaActiveSetHelper;

	public:
	typedef DAGDeltaAlgorithm::change_ty change_ty;
	typedef DAGDeltaAlgorithm::changeset_ty changeset_ty;
	typedef DAGDeltaAlgorithm::changesetlist_ty changesetlist_ty;
	typedef DAGDeltaAlgorithm::edge_ty edge_ty;

	private:
	typedef std::vector<change_ty>::iterator pred_iterator_ty;
	typedef std::vector<change_ty>::iterator succ_iterator_ty;
	typedef std::set<change_ty>::iterator pred_closure_iterator_ty;
	typedef std::set<change_ty>::iterator succ_closure_iterator_ty;

	DAGDeltaAlgorithm &DDA;

	std::vector<change_ty> Roots;

	/// Cache of failed test results. Successful test results are never cached
	/// since we always reduce following a success. We maintain an independent
	/// cache from that used by the individual delta passes because we may get
	/// hits across multiple individual delta invocations.
	mutable std::set<changeset_ty> FailedTestsCache;

	// FIXME: Gross.
	std::map<change_ty, std::vector<change_ty> > Predecessors;
	std::map<change_ty, std::vector<change_ty> > Successors;

	std::map<change_ty, std::set<change_ty> > PredClosure;
	std::map<change_ty, std::set<change_ty> > SuccClosure;

	private:
	pred_iterator_ty pred_begin(change_ty Node) {
	assert(Predecessors.count(Node) && "Invalid node!");
	return Predecessors[Node].begin();
	}
	pred_iterator_ty pred_end(change_ty Node) {
	assert(Predecessors.count(Node) && "Invalid node!");
	return Predecessors[Node].end();
	}

	pred_closure_iterator_ty pred_closure_begin(change_ty Node) {
	assert(PredClosure.count(Node) && "Invalid node!");
	return PredClosure[Node].begin();
	}
	pred_closure_iterator_ty pred_closure_end(change_ty Node) {
	assert(PredClosure.count(Node) && "Invalid node!");
	return PredClosure[Node].end();
	}

	succ_iterator_ty succ_begin(change_ty Node) {
	assert(Successors.count(Node) && "Invalid node!");
	return Successors[Node].begin();
	}
	succ_iterator_ty succ_end(change_ty Node) {
	assert(Successors.count(Node) && "Invalid node!");
	return Successors[Node].end();
	}

	succ_closure_iterator_ty succ_closure_begin(change_ty Node) {
	assert(SuccClosure.count(Node) && "Invalid node!");
	return SuccClosure[Node].begin();
	}
	succ_closure_iterator_ty succ_closure_end(change_ty Node) {
	assert(SuccClosure.count(Node) && "Invalid node!");
	return SuccClosure[Node].end();
	}

	void UpdatedSearchState(const changeset_ty &Changes,
	const changesetlist_ty &Sets,
	const changeset_ty &Required) {
	DDA.UpdatedSearchState(Changes, Sets, Required);
	}

	/// ExecuteOneTest - Execute a single test predicate on the change set \p S.
	bool ExecuteOneTest(const changeset_ty &S) {
	// Check dependencies invariant.
	LLVM_DEBUG({
	for (changeset_ty::const_iterator it = S.begin(), ie = S.end(); it != ie;
	++it)
	for (succ_iterator_ty it2 = succ_begin(it), ie2 = succ_end(it);
	it2 != ie2; ++it2)
	assert(S.count(*it2) && "Attempt to run invalid changeset!");
	});

	return DDA.ExecuteOneTest(S);
	}

	public:
	DAGDeltaAlgorithmImpl(DAGDeltaAlgorithm &DDA, const changeset_ty &Changes,
	const std::vector<edge_ty> &Dependencies);

	changeset_ty Run();

	/// GetTestResult - Get the test result for the active set \p Changes with
	/// \p Required changes from the cache, executing the test if necessary.
	///
	/// \param Changes - The set of active changes being minimized, which should
	/// have their pred closure included in the test.
	/// \param Required - The set of changes which have previously been
	/// established to be required.
	/// \return - The test result.
	bool GetTestResult(const changeset_ty &Changes, const changeset_ty &Required);
	};

	/// Helper object for minimizing an active set of changes.
	class DeltaActiveSetHelper : public DeltaAlgorithm {
	DAGDeltaAlgorithmImpl &DDAI;

	const changeset_ty &Required;

	protected:
	/// UpdatedSearchState - Callback used when the search state changes.
	void UpdatedSearchState(const changeset_ty &Changes,
	const changesetlist_ty &Sets) override {
	DDAI.UpdatedSearchState(Changes, Sets, Required);
	}

	bool ExecuteOneTest(const changeset_ty &S) override {
	return DDAI.GetTestResult(S, Required);
	}

	public:
	DeltaActiveSetHelper(DAGDeltaAlgorithmImpl &DDAI,
	const changeset_ty &Required)
	: DDAI(DDAI), Required(Required) {}
	};

	}

	DAGDeltaAlgorithmImpl::DAGDeltaAlgorithmImpl(
	DAGDeltaAlgorithm &DDA, const changeset_ty &Changes,
	const std::vector<edge_ty> &Dependencies)
	: DDA(DDA) {
	for (changeset_ty::const_iterator it = Changes.begin(),
	ie = Changes.end(); it != ie; ++it) {
	Predecessors.insert(std::make_pair(*it, std::vector<change_ty>()));
	Successors.insert(std::make_pair(*it, std::vector<change_ty>()));
	}
	for (std::vector<edge_ty>::const_iterator it = Dependencies.begin(),
	ie = Dependencies.end(); it != ie; ++it) {
	Predecessors[it->second].push_back(it->first);
	Successors[it->first].push_back(it->second);
	}

	// Compute the roots.
	for (changeset_ty::const_iterator it = Changes.begin(),
	ie = Changes.end(); it != ie; ++it)
	if (succ_begin(it) == succ_end(it))
	Roots.push_back(*it);

	// Pre-compute the closure of the successor relation.
	std::vector<change_ty> Worklist(Roots.begin(), Roots.end());
	while (!Worklist.empty()) {
	change_ty Change = Worklist.back();
	Worklist.pop_back();

	std::set<change_ty> &ChangeSuccs = SuccClosure[Change];
	for (pred_iterator_ty it = pred_begin(Change),
	ie = pred_end(Change); it != ie; ++it) {
	SuccClosure[*it].insert(Change);
	SuccClosure[*it].insert(ChangeSuccs.begin(), ChangeSuccs.end());
	Worklist.push_back(*it);
	}
	}

	// Invert to form the predecessor closure map.
	for (changeset_ty::const_iterator it = Changes.begin(),
	ie = Changes.end(); it != ie; ++it)
	PredClosure.insert(std::make_pair(*it, std::set<change_ty>()));
	for (changeset_ty::const_iterator it = Changes.begin(),
	ie = Changes.end(); it != ie; ++it)
	for (succ_closure_iterator_ty it2 = succ_closure_begin(*it),
	ie2 = succ_closure_end(*it); it2 != ie2; ++it2)
	PredClosure[it2].insert(it);

	// Dump useful debug info.
	LLVM_DEBUG({
	llvm::errs() << "-- DAGDeltaAlgorithmImpl --\n";
	llvm::errs() << "Changes: [";
	for (changeset_ty::const_iterator it = Changes.begin(), ie = Changes.end();
	it != ie; ++it) {
	if (it != Changes.begin())
	llvm::errs() << ", ";
	llvm::errs() << *it;

	if (succ_begin(it) != succ_end(it)) {
	llvm::errs() << "(";
	for (succ_iterator_ty it2 = succ_begin(it), ie2 = succ_end(it);
	it2 != ie2; ++it2) {
	if (it2 != succ_begin(*it))
	llvm::errs() << ", ";
	llvm::errs() << "->" << *it2;
	}
	llvm::errs() << ")";
	}
	}
	llvm::errs() << "]\n";

	llvm::errs() << "Roots: [";
	for (std::vector<change_ty>::const_iterator it = Roots.begin(),
	ie = Roots.end();
	it != ie; ++it) {
	if (it != Roots.begin())
	llvm::errs() << ", ";
	llvm::errs() << *it;
	}
	llvm::errs() << "]\n";

	llvm::errs() << "Predecessor Closure:\n";
	for (changeset_ty::const_iterator it = Changes.begin(), ie = Changes.end();
	it != ie; ++it) {
	llvm::errs() << format(" %-4d: [", *it);
	for (pred_closure_iterator_ty it2 = pred_closure_begin(*it),
	ie2 = pred_closure_end(*it);
	it2 != ie2; ++it2) {
	if (it2 != pred_closure_begin(*it))
	llvm::errs() << ", ";
	llvm::errs() << *it2;
	}
	llvm::errs() << "]\n";
	}

	llvm::errs() << "Successor Closure:\n";
	for (changeset_ty::const_iterator it = Changes.begin(), ie = Changes.end();
	it != ie; ++it) {
	llvm::errs() << format(" %-4d: [", *it);
	for (succ_closure_iterator_ty it2 = succ_closure_begin(*it),
	ie2 = succ_closure_end(*it);
	it2 != ie2; ++it2) {
	if (it2 != succ_closure_begin(*it))
	llvm::errs() << ", ";
	llvm::errs() << *it2;
	}
	llvm::errs() << "]\n";
	}

	llvm::errs() << "\n\n";
	});
	}

	bool DAGDeltaAlgorithmImpl::GetTestResult(const changeset_ty &Changes,
	const changeset_ty &Required) {
	changeset_ty Extended(Required);
	Extended.insert(Changes.begin(), Changes.end());
	for (changeset_ty::const_iterator it = Changes.begin(),
	ie = Changes.end(); it != ie; ++it)
	Extended.insert(pred_closure_begin(it), pred_closure_end(it));

	if (FailedTestsCache.count(Extended))
	return false;

	bool Result = ExecuteOneTest(Extended);
	if (!Result)
	FailedTestsCache.insert(Extended);

	return Result;
	}

	DAGDeltaAlgorithm::changeset_ty
	DAGDeltaAlgorithmImpl::Run() {
	// The current set of changes we are minimizing, starting at the roots.
	changeset_ty CurrentSet(Roots.begin(), Roots.end());

	// The set of required changes.
	changeset_ty Required;

	// Iterate until the active set of changes is empty. Convergence is guaranteed
	// assuming input was a DAG.
	//
	// Invariant: CurrentSet intersect Required == {}
	// Invariant: Required == (Required union succ*(Required))
	while (!CurrentSet.empty()) {
	LLVM_DEBUG({
	llvm::errs() << "DAG_DD - " << CurrentSet.size() << " active changes, "
	<< Required.size() << " required changes\n";
	});

	// Minimize the current set of changes.
	DeltaActiveSetHelper Helper(*this, Required);
	changeset_ty CurrentMinSet = Helper.Run(CurrentSet);

	// Update the set of required changes. Since
	// CurrentMinSet subset CurrentSet
	// and after the last iteration,
	// succ(CurrentSet) subset Required
	// then
	// succ(CurrentMinSet) subset Required
	// and our invariant on Required is maintained.
	Required.insert(CurrentMinSet.begin(), CurrentMinSet.end());

	// Replace the current set with the predecssors of the minimized set of
	// active changes.
	CurrentSet.clear();
	for (changeset_ty::const_iterator it = CurrentMinSet.begin(),
	ie = CurrentMinSet.end(); it != ie; ++it)
	CurrentSet.insert(pred_begin(it), pred_end(it));

	// FIXME: We could enforce CurrentSet intersect Required == {} here if we
	// wanted to protect against cyclic graphs.
	}

	return Required;
	}

	void DAGDeltaAlgorithm::anchor() {
	}

	DAGDeltaAlgorithm::changeset_ty
	DAGDeltaAlgorithm::Run(const changeset_ty &Changes,
	const std::vector<edge_ty> &Dependencies) {
	return DAGDeltaAlgorithmImpl(*this, Changes, Dependencies).Run();
	}