cycle_breaker.cc - platform/system/update_engine - Gitiles

 // Copyright (c) 2012 The Chromium OS Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "update_engine/cycle_breaker.h"
 #include <inttypes.h>
 #include <set>
 #include <utility>
 #include <base/strings/string_util.h>
 #include <base/strings/stringprintf.h>
 #include "update_engine/graph_utils.h"
 #include "update_engine/tarjan.h"
 #include "update_engine/utils.h"

 using std::make_pair;
 using std::set;
 using std::vector;

 namespace chromeos_update_engine {

 // This is the outer function from the original paper.
 void CycleBreaker::BreakCycles(const Graph& graph, set<Edge>* out_cut_edges) {
   cut_edges_.clear();

   // Make a copy, which we will modify by removing edges. Thus, in each
   // iteration subgraph_ is the current subgraph or the original with
   // vertices we desire. This variable was "A_K" in the original paper.
   subgraph_ = graph;

   // The paper calls for the "adjacency structure (i.e., graph) of
   // strong (-ly connected) component K with least vertex in subgraph
   // induced by {s, s + 1, ..., n}".
   // We arbitrarily order each vertex by its index in the graph. Thus,
   // each iteration, we are looking at the subgraph {s, s + 1, ..., n}
   // and looking for the strongly connected component with vertex s.

   TarjanAlgorithm tarjan;
   skipped_ops_ = 0;

   for (Graph::size_type i = 0; i < subgraph_.size(); i++) {
     DeltaArchiveManifest_InstallOperation_Type op_type = graph[i].op.type();
     if (op_type == DeltaArchiveManifest_InstallOperation_Type_REPLACE ||
         op_type == DeltaArchiveManifest_InstallOperation_Type_REPLACE_BZ) {
       skipped_ops_++;
       continue;
     }

     if (i > 0) {
       // Erase node (i - 1) from subgraph_. First, erase what it points to
       subgraph_[i - 1].out_edges.clear();
       // Now, erase any pointers to node (i - 1)
       for (Graph::size_type j = i; j < subgraph_.size(); j++) {
         subgraph_[j].out_edges.erase(i - 1);
       }
     }

     // Calculate SCC (strongly connected component) with vertex i.
     vector<Vertex::Index> component_indexes;
     tarjan.Execute(i, &subgraph_, &component_indexes);

     // Set subgraph edges for the components in the SCC.
     for (vector<Vertex::Index>::iterator it = component_indexes.begin();
          it != component_indexes.end(); ++it) {
       subgraph_[*it].subgraph_edges.clear();
       for (vector<Vertex::Index>::iterator jt = component_indexes.begin();
            jt != component_indexes.end(); ++jt) {
         // If there's a link from *it -> *jt in the graph,
         // add a subgraph_ edge
         if (utils::MapContainsKey(subgraph_[*it].out_edges, *jt))
           subgraph_[*it].subgraph_edges.insert(*jt);
       }
     }

     current_vertex_ = i;
     blocked_.clear();
     blocked_.resize(subgraph_.size());
     blocked_graph_.clear();
     blocked_graph_.resize(subgraph_.size());
     Circuit(current_vertex_, 0);
   }

   out_cut_edges->swap(cut_edges_);
   LOG(INFO) << "Cycle breaker skipped " << skipped_ops_ << " ops.";
   DCHECK(stack_.empty());
 }

 static const size_t kMaxEdgesToConsider = 2;

 void CycleBreaker::HandleCircuit() {
   stack_.push_back(current_vertex_);
   CHECK_GE(stack_.size(),
            static_cast<std::vector<Vertex::Index>::size_type>(2));
   Edge min_edge = make_pair(stack_[0], stack_[1]);
   uint64_t min_edge_weight = kuint64max;
   size_t edges_considered = 0;
   for (vector<Vertex::Index>::const_iterator it = stack_.begin();
        it != (stack_.end() - 1); ++it) {
     Edge edge = make_pair(*it, *(it + 1));
     if (cut_edges_.find(edge) != cut_edges_.end()) {
       stack_.pop_back();
       return;
     }
     uint64_t edge_weight = graph_utils::EdgeWeight(subgraph_, edge);
     if (edge_weight < min_edge_weight) {
       min_edge_weight = edge_weight;
       min_edge = edge;
     }
     edges_considered++;
     if (edges_considered == kMaxEdgesToConsider)
       break;
   }
   cut_edges_.insert(min_edge);
   stack_.pop_back();
 }

 void CycleBreaker::Unblock(Vertex::Index u) {
   blocked_[u] = false;

   for (Vertex::EdgeMap::iterator it = blocked_graph_[u].out_edges.begin();
        it != blocked_graph_[u].out_edges.end(); ) {
     Vertex::Index w = it->first;
     blocked_graph_[u].out_edges.erase(it++);
     if (blocked_[w])
       Unblock(w);
   }
 }

 bool CycleBreaker::StackContainsCutEdge() const {
   for (std::vector<Vertex::Index>::const_iterator it = ++stack_.begin(),
            e = stack_.end(); it != e; ++it) {
     Edge edge = make_pair(*(it - 1), *it);
     if (utils::SetContainsKey(cut_edges_, edge)) {
       return true;
     }
   }
   return false;
 }

 bool CycleBreaker::Circuit(Vertex::Index vertex, Vertex::Index depth) {
   // "vertex" was "v" in the original paper.
   bool found = false;  // Was "f" in the original paper.
   stack_.push_back(vertex);
   blocked_[vertex] = true;
   {
     static int counter = 0;
     counter++;
     if (counter == 10000) {
       counter = 0;
       std::string stack_str;
       for (vector<Vertex::Index>::const_iterator it = stack_.begin();
            it != stack_.end(); ++it) {
         stack_str += base::StringPrintf("%lu -> ",
                                         static_cast<long unsigned int>(*it));
       }
       LOG(INFO) << "stack: " << stack_str;
     }
   }

   for (Vertex::SubgraphEdgeMap::iterator w =
            subgraph_[vertex].subgraph_edges.begin();
        w != subgraph_[vertex].subgraph_edges.end(); ++w) {
     if (*w == current_vertex_) {
       // The original paper called for printing stack_ followed by
       // current_vertex_ here, which is a cycle. Instead, we call
       // HandleCircuit() to break it.
       HandleCircuit();
       found = true;
     } else if (!blocked_[*w]) {
       if (Circuit(*w, depth + 1)) {
         found = true;
         if ((depth > kMaxEdgesToConsider) || StackContainsCutEdge())
           break;
       }
     }
   }

   if (found) {
     Unblock(vertex);
   } else {
     for (Vertex::SubgraphEdgeMap::iterator w =
              subgraph_[vertex].subgraph_edges.begin();
          w != subgraph_[vertex].subgraph_edges.end(); ++w) {
       if (blocked_graph_[*w].out_edges.find(vertex) ==
           blocked_graph_[*w].out_edges.end()) {
         blocked_graph_[*w].out_edges.insert(make_pair(vertex,
                                                       EdgeProperties()));
       }
     }
   }
   CHECK_EQ(vertex, stack_.back());
   stack_.pop_back();
   return found;
 }

 }  // namespace chromeos_update_engine
	// Copyright (c) 2012 The Chromium OS Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "update_engine/cycle_breaker.h"
	#include <inttypes.h>
	#include <set>
	#include <utility>
	#include <base/strings/string_util.h>
	#include <base/strings/stringprintf.h>
	#include "update_engine/graph_utils.h"
	#include "update_engine/tarjan.h"
	#include "update_engine/utils.h"

	using std::make_pair;
	using std::set;
	using std::vector;

	namespace chromeos_update_engine {

	// This is the outer function from the original paper.
	void CycleBreaker::BreakCycles(const Graph& graph, set<Edge>* out_cut_edges) {
	cut_edges_.clear();

	// Make a copy, which we will modify by removing edges. Thus, in each
	// iteration subgraph_ is the current subgraph or the original with
	// vertices we desire. This variable was "A_K" in the original paper.
	subgraph_ = graph;

	// The paper calls for the "adjacency structure (i.e., graph) of
	// strong (-ly connected) component K with least vertex in subgraph
	// induced by {s, s + 1, ..., n}".
	// We arbitrarily order each vertex by its index in the graph. Thus,
	// each iteration, we are looking at the subgraph {s, s + 1, ..., n}
	// and looking for the strongly connected component with vertex s.

	TarjanAlgorithm tarjan;
	skipped_ops_ = 0;

	for (Graph::size_type i = 0; i < subgraph_.size(); i++) {
	DeltaArchiveManifest_InstallOperation_Type op_type = graph[i].op.type();
	if (op_type == DeltaArchiveManifest_InstallOperation_Type_REPLACE \|\|
	op_type == DeltaArchiveManifest_InstallOperation_Type_REPLACE_BZ) {
	skipped_ops_++;
	continue;
	}

	if (i > 0) {
	// Erase node (i - 1) from subgraph_. First, erase what it points to
	subgraph_[i - 1].out_edges.clear();
	// Now, erase any pointers to node (i - 1)
	for (Graph::size_type j = i; j < subgraph_.size(); j++) {
	subgraph_[j].out_edges.erase(i - 1);
	}
	}

	// Calculate SCC (strongly connected component) with vertex i.
	vector<Vertex::Index> component_indexes;
	tarjan.Execute(i, &subgraph_, &component_indexes);

	// Set subgraph edges for the components in the SCC.
	for (vector<Vertex::Index>::iterator it = component_indexes.begin();
	it != component_indexes.end(); ++it) {
	subgraph_[*it].subgraph_edges.clear();
	for (vector<Vertex::Index>::iterator jt = component_indexes.begin();
	jt != component_indexes.end(); ++jt) {
	// If there's a link from it -> jt in the graph,
	// add a subgraph_ edge
	if (utils::MapContainsKey(subgraph_[it].out_edges, jt))
	subgraph_[it].subgraph_edges.insert(jt);
	}
	}

	current_vertex_ = i;
	blocked_.clear();
	blocked_.resize(subgraph_.size());
	blocked_graph_.clear();
	blocked_graph_.resize(subgraph_.size());
	Circuit(current_vertex_, 0);
	}

	out_cut_edges->swap(cut_edges_);
	LOG(INFO) << "Cycle breaker skipped " << skipped_ops_ << " ops.";
	DCHECK(stack_.empty());
	}

	static const size_t kMaxEdgesToConsider = 2;

	void CycleBreaker::HandleCircuit() {
	stack_.push_back(current_vertex_);
	CHECK_GE(stack_.size(),
	static_cast<std::vector<Vertex::Index>::size_type>(2));
	Edge min_edge = make_pair(stack_[0], stack_[1]);
	uint64_t min_edge_weight = kuint64max;
	size_t edges_considered = 0;
	for (vector<Vertex::Index>::const_iterator it = stack_.begin();
	it != (stack_.end() - 1); ++it) {
	Edge edge = make_pair(it, (it + 1));
	if (cut_edges_.find(edge) != cut_edges_.end()) {
	stack_.pop_back();
	return;
	}
	uint64_t edge_weight = graph_utils::EdgeWeight(subgraph_, edge);
	if (edge_weight < min_edge_weight) {
	min_edge_weight = edge_weight;
	min_edge = edge;
	}
	edges_considered++;
	if (edges_considered == kMaxEdgesToConsider)
	break;
	}
	cut_edges_.insert(min_edge);
	stack_.pop_back();
	}

	void CycleBreaker::Unblock(Vertex::Index u) {
	blocked_[u] = false;

	for (Vertex::EdgeMap::iterator it = blocked_graph_[u].out_edges.begin();
	it != blocked_graph_[u].out_edges.end(); ) {
	Vertex::Index w = it->first;
	blocked_graph_[u].out_edges.erase(it++);
	if (blocked_[w])
	Unblock(w);
	}
	}

	bool CycleBreaker::StackContainsCutEdge() const {
	for (std::vector<Vertex::Index>::const_iterator it = ++stack_.begin(),
	e = stack_.end(); it != e; ++it) {
	Edge edge = make_pair((it - 1), it);
	if (utils::SetContainsKey(cut_edges_, edge)) {
	return true;
	}
	}
	return false;
	}

	bool CycleBreaker::Circuit(Vertex::Index vertex, Vertex::Index depth) {
	// "vertex" was "v" in the original paper.
	bool found = false; // Was "f" in the original paper.
	stack_.push_back(vertex);
	blocked_[vertex] = true;
	{
	static int counter = 0;
	counter++;
	if (counter == 10000) {
	counter = 0;
	std::string stack_str;
	for (vector<Vertex::Index>::const_iterator it = stack_.begin();
	it != stack_.end(); ++it) {
	stack_str += base::StringPrintf("%lu -> ",
	static_cast<long unsigned int>(*it));
	}
	LOG(INFO) << "stack: " << stack_str;
	}
	}

	for (Vertex::SubgraphEdgeMap::iterator w =
	subgraph_[vertex].subgraph_edges.begin();
	w != subgraph_[vertex].subgraph_edges.end(); ++w) {
	if (*w == current_vertex_) {
	// The original paper called for printing stack_ followed by
	// current_vertex_ here, which is a cycle. Instead, we call
	// HandleCircuit() to break it.
	HandleCircuit();
	found = true;
	} else if (!blocked_[*w]) {
	if (Circuit(*w, depth + 1)) {
	found = true;
	if ((depth > kMaxEdgesToConsider) \|\| StackContainsCutEdge())
	break;
	}
	}
	}

	if (found) {
	Unblock(vertex);
	} else {
	for (Vertex::SubgraphEdgeMap::iterator w =
	subgraph_[vertex].subgraph_edges.begin();
	w != subgraph_[vertex].subgraph_edges.end(); ++w) {
	if (blocked_graph_[*w].out_edges.find(vertex) ==
	blocked_graph_[*w].out_edges.end()) {
	blocked_graph_[*w].out_edges.insert(make_pair(vertex,
	EdgeProperties()));
	}
	}
	}
	CHECK_EQ(vertex, stack_.back());
	stack_.pop_back();
	return found;
	}

	} // namespace chromeos_update_engine