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Optimise getNetworkDistance in MLD even more (#6884)

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Siarhei Fedartsou 2024-05-23 20:46:13 +02:00 committed by GitHub
parent 24646aada9
commit 21607e0cb2
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5 changed files with 268 additions and 81 deletions
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1
CHANGELOG.md
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@ -53,6 +53,7 @@
- FIXED: Remove force-loop checks for routes with u-turns [#6858](https://github.com/Project-OSRM/osrm-backend/pull/6858) - FIXED: Remove force-loop checks for routes with u-turns [#6858](https://github.com/Project-OSRM/osrm-backend/pull/6858)
- FIXED: Correctly check runtime search conditions for forcing routing steps [#6866](https://github.com/Project-OSRM/osrm-backend/pull/6866) - FIXED: Correctly check runtime search conditions for forcing routing steps [#6866](https://github.com/Project-OSRM/osrm-backend/pull/6866)
- Map Matching: - Map Matching:
- CHANGED: Optimise path distance calculation in MLD map matching even more. [#6884](https://github.com/Project-OSRM/osrm-backend/pull/6884)
- CHANGED: Optimise path distance calculation in MLD map matching. [#6876](https://github.com/Project-OSRM/osrm-backend/pull/6876) - CHANGED: Optimise path distance calculation in MLD map matching. [#6876](https://github.com/Project-OSRM/osrm-backend/pull/6876)
- CHANGED: Optimise R-tree queries in the case of map matching. [#6881](https://github.com/Project-OSRM/osrm-backend/pull/6876) - CHANGED: Optimise R-tree queries in the case of map matching. [#6881](https://github.com/Project-OSRM/osrm-backend/pull/6876)
- Debug tiles: - Debug tiles:

260
include/engine/routing_algorithms/routing_base_mld.hpp
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@ -11,6 +11,7 @@
#include <boost/assert.hpp> #include <boost/assert.hpp>
#include <algorithm> #include <algorithm>
#include <boost/core/ignore_unused.hpp>
#include <iterator> #include <iterator>
#include <limits> #include <limits>
#include <tuple> #include <tuple>
@ -269,10 +270,29 @@ retrievePackedPathFromHeap(const SearchEngineData<Algorithm>::QueryHeap &forward
return packed_path; return packed_path;
} }
template <bool DIRECTION, typename Algorithm, typename... Args> template <typename Heap>
void insertOrUpdate(Heap &heap,
const NodeID node,
const EdgeWeight weight,
const typename Heap::DataType &data)
{
const auto heapNode = heap.GetHeapNodeIfWasInserted(node);
if (!heapNode)
{
heap.Insert(node, weight, data);
}
else if (weight < heapNode->weight)
{
heapNode->data = data;
heapNode->weight = weight;
heap.DecreaseKey(*heapNode);
}
}
template <bool DIRECTION, typename Algorithm, typename Heap, typename... Args>
void relaxOutgoingEdges(const DataFacade<Algorithm> &facade, void relaxOutgoingEdges(const DataFacade<Algorithm> &facade,
typename SearchEngineData<Algorithm>::QueryHeap &forward_heap, Heap &forward_heap,
const typename SearchEngineData<Algorithm>::QueryHeap::HeapNode &heapNode, const typename Heap::HeapNode &heapNode,
const Args &...args) const Args &...args)
{ {
const auto &partition = facade.GetMultiLevelPartition(); const auto &partition = facade.GetMultiLevelPartition();
@ -281,14 +301,31 @@ void relaxOutgoingEdges(const DataFacade<Algorithm> &facade,
const auto level = getNodeQueryLevel(partition, heapNode.node, args...); const auto level = getNodeQueryLevel(partition, heapNode.node, args...);
static constexpr auto IS_MAP_MATCHING =
std::is_same_v<typename SearchEngineData<mld::Algorithm>::MapMatchingQueryHeap, Heap>;
if (level >= 1 && !heapNode.data.from_clique_arc) if (level >= 1 && !heapNode.data.from_clique_arc)
{ {
if (DIRECTION == FORWARD_DIRECTION) if constexpr (DIRECTION == FORWARD_DIRECTION)
{ {
// Shortcuts in forward direction // Shortcuts in forward direction
const auto &cell = const auto &cell =
cells.GetCell(metric, level, partition.GetCell(level, heapNode.node)); cells.GetCell(metric, level, partition.GetCell(level, heapNode.node));
auto destination = cell.GetDestinationNodes().begin(); auto destination = cell.GetDestinationNodes().begin();
auto distance = [&cell, node = heapNode.node ]() -> auto
{
if constexpr (IS_MAP_MATCHING)
{
return cell.GetOutDistance(node).begin();
}
else
{
boost::ignore_unused(cell, node);
return 0;
}
}
();
for (auto shortcut_weight : cell.GetOutWeight(heapNode.node)) for (auto shortcut_weight : cell.GetOutWeight(heapNode.node))
{ {
BOOST_ASSERT(destination != cell.GetDestinationNodes().end()); BOOST_ASSERT(destination != cell.GetDestinationNodes().end());
@ -298,19 +335,23 @@ void relaxOutgoingEdges(const DataFacade<Algorithm> &facade,
{ {
const EdgeWeight to_weight = heapNode.weight + shortcut_weight; const EdgeWeight to_weight = heapNode.weight + shortcut_weight;
BOOST_ASSERT(to_weight >= heapNode.weight); BOOST_ASSERT(to_weight >= heapNode.weight);
const auto toHeapNode = forward_heap.GetHeapNodeIfWasInserted(to);
if (!toHeapNode) if constexpr (IS_MAP_MATCHING)
{ {
forward_heap.Insert(to, to_weight, {heapNode.node, true}); const EdgeDistance to_distance = heapNode.data.distance + *distance;
insertOrUpdate(
forward_heap, to, to_weight, {heapNode.node, true, to_distance});
} }
else if (to_weight < toHeapNode->weight) else
{ {
toHeapNode->data = {heapNode.node, true}; insertOrUpdate(forward_heap, to, to_weight, {heapNode.node, true});
toHeapNode->weight = to_weight;
forward_heap.DecreaseKey(*toHeapNode);
} }
} }
++destination; ++destination;
if constexpr (IS_MAP_MATCHING)
{
++distance;
}
} }
} }
else else
@ -319,6 +360,20 @@ void relaxOutgoingEdges(const DataFacade<Algorithm> &facade,
const auto &cell = const auto &cell =
cells.GetCell(metric, level, partition.GetCell(level, heapNode.node)); cells.GetCell(metric, level, partition.GetCell(level, heapNode.node));
auto source = cell.GetSourceNodes().begin(); auto source = cell.GetSourceNodes().begin();
auto distance = [&cell, node = heapNode.node ]() -> auto
{
if constexpr (IS_MAP_MATCHING)
{
return cell.GetInDistance(node).begin();
}
else
{
boost::ignore_unused(cell, node);
return 0;
}
}
();
for (auto shortcut_weight : cell.GetInWeight(heapNode.node)) for (auto shortcut_weight : cell.GetInWeight(heapNode.node))
{ {
BOOST_ASSERT(source != cell.GetSourceNodes().end()); BOOST_ASSERT(source != cell.GetSourceNodes().end());
@ -328,19 +383,22 @@ void relaxOutgoingEdges(const DataFacade<Algorithm> &facade,
{ {
const EdgeWeight to_weight = heapNode.weight + shortcut_weight; const EdgeWeight to_weight = heapNode.weight + shortcut_weight;
BOOST_ASSERT(to_weight >= heapNode.weight); BOOST_ASSERT(to_weight >= heapNode.weight);
const auto toHeapNode = forward_heap.GetHeapNodeIfWasInserted(to); if constexpr (IS_MAP_MATCHING)
if (!toHeapNode)
{ {
forward_heap.Insert(to, to_weight, {heapNode.node, true}); const EdgeDistance to_distance = heapNode.data.distance + *distance;
insertOrUpdate(
forward_heap, to, to_weight, {heapNode.node, true, to_distance});
} }
else if (to_weight < toHeapNode->weight) else
{ {
toHeapNode->data = {heapNode.node, true}; insertOrUpdate(forward_heap, to, to_weight, {heapNode.node, true});
toHeapNode->weight = to_weight;
forward_heap.DecreaseKey(*toHeapNode);
} }
} }
++source; ++source;
if constexpr (IS_MAP_MATCHING)
{
++distance;
}
} }
} }
} }
@ -367,26 +425,28 @@ void relaxOutgoingEdges(const DataFacade<Algorithm> &facade,
const EdgeWeight to_weight = const EdgeWeight to_weight =
heapNode.weight + node_weight + alias_cast<EdgeWeight>(turn_penalty); heapNode.weight + node_weight + alias_cast<EdgeWeight>(turn_penalty);
const auto toHeapNode = forward_heap.GetHeapNodeIfWasInserted(to); if constexpr (IS_MAP_MATCHING)
if (!toHeapNode)
{ {
forward_heap.Insert(to, to_weight, {heapNode.node, false}); const auto node_distance =
facade.GetNodeDistance(DIRECTION == FORWARD_DIRECTION ? heapNode.node : to);
const EdgeDistance to_distance = heapNode.data.distance + node_distance;
insertOrUpdate(
forward_heap, to, to_weight, {heapNode.node, false, to_distance});
} }
else if (to_weight < toHeapNode->weight) else
{ {
toHeapNode->data = {heapNode.node, false}; insertOrUpdate(forward_heap, to, to_weight, {heapNode.node, false});
toHeapNode->weight = to_weight;
forward_heap.DecreaseKey(*toHeapNode);
} }
} }
} }
} }
} }
template <bool DIRECTION, typename Algorithm, typename... Args> template <bool DIRECTION, typename Algorithm, typename Heap, typename... Args>
void routingStep(const DataFacade<Algorithm> &facade, void routingStep(const DataFacade<Algorithm> &facade,
typename SearchEngineData<Algorithm>::QueryHeap &forward_heap, Heap &forward_heap,
typename SearchEngineData<Algorithm>::QueryHeap &reverse_heap, Heap &reverse_heap,
NodeID &middle_node, NodeID &middle_node,
EdgeWeight &path_upper_bound, EdgeWeight &path_upper_bound,
const std::vector<NodeID> &force_step_nodes, const std::vector<NodeID> &force_step_nodes,
@ -429,22 +489,19 @@ using UnpackedNodes = std::vector<NodeID>;
using UnpackedEdges = std::vector<EdgeID>; using UnpackedEdges = std::vector<EdgeID>;
using UnpackedPath = std::tuple<EdgeWeight, UnpackedNodes, UnpackedEdges>; using UnpackedPath = std::tuple<EdgeWeight, UnpackedNodes, UnpackedEdges>;
template <typename Algorithm, typename... Args> template <typename Algorithm, typename Heap, typename... Args>
UnpackedPath search(SearchEngineData<Algorithm> &engine_working_data, std::optional<std::pair<NodeID, EdgeWeight>> runSearch(const DataFacade<Algorithm> &facade,
const DataFacade<Algorithm> &facade, Heap &forward_heap,
typename SearchEngineData<Algorithm>::QueryHeap &forward_heap, Heap &reverse_heap,
typename SearchEngineData<Algorithm>::QueryHeap &reverse_heap, const std::vector<NodeID> &force_step_nodes,
const std::vector<NodeID> &force_step_nodes, EdgeWeight weight_upper_bound,
EdgeWeight weight_upper_bound, const Args &...args)
const Args &...args)
{ {
if (forward_heap.Empty() || reverse_heap.Empty()) if (forward_heap.Empty() || reverse_heap.Empty())
{ {
return std::make_tuple(INVALID_EDGE_WEIGHT, std::vector<NodeID>(), std::vector<EdgeID>()); return {};
} }
const auto &partition = facade.GetMultiLevelPartition();
BOOST_ASSERT(!forward_heap.Empty() && forward_heap.MinKey() < INVALID_EDGE_WEIGHT); BOOST_ASSERT(!forward_heap.Empty() && forward_heap.MinKey() < INVALID_EDGE_WEIGHT);
BOOST_ASSERT(!reverse_heap.Empty() && reverse_heap.MinKey() < INVALID_EDGE_WEIGHT); BOOST_ASSERT(!reverse_heap.Empty() && reverse_heap.MinKey() < INVALID_EDGE_WEIGHT);
@ -474,10 +531,33 @@ UnpackedPath search(SearchEngineData<Algorithm> &engine_working_data,
// No path found for both target nodes? // No path found for both target nodes?
if (weight >= weight_upper_bound || SPECIAL_NODEID == middle) if (weight >= weight_upper_bound || SPECIAL_NODEID == middle)
{
return {};
}
return {{middle, weight}};
}
template <typename Algorithm, typename... Args>
UnpackedPath search(SearchEngineData<Algorithm> &engine_working_data,
const DataFacade<Algorithm> &facade,
typename SearchEngineData<Algorithm>::QueryHeap &forward_heap,
typename SearchEngineData<Algorithm>::QueryHeap &reverse_heap,
const std::vector<NodeID> &force_step_nodes,
EdgeWeight weight_upper_bound,
const Args &...args)
{
auto searchResult = runSearch(
facade, forward_heap, reverse_heap, force_step_nodes, weight_upper_bound, args...);
if (!searchResult)
{ {
return std::make_tuple(INVALID_EDGE_WEIGHT, std::vector<NodeID>(), std::vector<EdgeID>()); return std::make_tuple(INVALID_EDGE_WEIGHT, std::vector<NodeID>(), std::vector<EdgeID>());
} }
auto [middle, weight] = *searchResult;
const auto &partition = facade.GetMultiLevelPartition();
// Get packed path as edges {from node ID, to node ID, from_clique_arc} // Get packed path as edges {from node ID, to node ID, from_clique_arc}
auto packed_path = retrievePackedPathFromHeap(forward_heap, reverse_heap, middle); auto packed_path = retrievePackedPathFromHeap(forward_heap, reverse_heap, middle);
@ -536,6 +616,31 @@ UnpackedPath search(SearchEngineData<Algorithm> &engine_working_data,
return std::make_tuple(weight, std::move(unpacked_nodes), std::move(unpacked_edges)); return std::make_tuple(weight, std::move(unpacked_nodes), std::move(unpacked_edges));
} }
template <typename Algorithm, typename... Args>
EdgeDistance
searchDistance(SearchEngineData<Algorithm> &,
const DataFacade<Algorithm> &facade,
typename SearchEngineData<Algorithm>::MapMatchingQueryHeap &forward_heap,
typename SearchEngineData<Algorithm>::MapMatchingQueryHeap &reverse_heap,
const std::vector<NodeID> &force_step_nodes,
EdgeWeight weight_upper_bound,
const Args &...args)
{
auto searchResult = runSearch(
facade, forward_heap, reverse_heap, force_step_nodes, weight_upper_bound, args...);
if (!searchResult)
{
return INVALID_EDGE_DISTANCE;
}
auto [middle, _] = *searchResult;
auto distance = forward_heap.GetData(middle).distance + reverse_heap.GetData(middle).distance;
return distance;
}
// Alias to be compatible with the CH-based search // Alias to be compatible with the CH-based search
template <typename Algorithm, typename PhantomEndpointT> template <typename Algorithm, typename PhantomEndpointT>
inline void search(SearchEngineData<Algorithm> &engine_working_data, inline void search(SearchEngineData<Algorithm> &engine_working_data,
@ -593,8 +698,8 @@ void unpackPath(const FacadeT &facade,
template <typename Algorithm> template <typename Algorithm>
double getNetworkDistance(SearchEngineData<Algorithm> &engine_working_data, double getNetworkDistance(SearchEngineData<Algorithm> &engine_working_data,
const DataFacade<Algorithm> &facade, const DataFacade<Algorithm> &facade,
typename SearchEngineData<Algorithm>::QueryHeap &forward_heap, typename SearchEngineData<Algorithm>::MapMatchingQueryHeap &forward_heap,
typename SearchEngineData<Algorithm>::QueryHeap &reverse_heap, typename SearchEngineData<Algorithm>::MapMatchingQueryHeap &reverse_heap,
const PhantomNode &source_phantom, const PhantomNode &source_phantom,
const PhantomNode &target_phantom, const PhantomNode &target_phantom,
EdgeWeight weight_upper_bound = INVALID_EDGE_WEIGHT) EdgeWeight weight_upper_bound = INVALID_EDGE_WEIGHT)
@ -602,48 +707,49 @@ double getNetworkDistance(SearchEngineData<Algorithm> &engine_working_data,
forward_heap.Clear(); forward_heap.Clear();
reverse_heap.Clear(); reverse_heap.Clear();
const PhantomEndpoints endpoints{source_phantom, target_phantom}; if (source_phantom.IsValidForwardSource())
insertNodesInHeaps(forward_heap, reverse_heap, endpoints); {
forward_heap.Insert(source_phantom.forward_segment_id.id,
EdgeWeight{0} - source_phantom.GetForwardWeightPlusOffset(),
{source_phantom.forward_segment_id.id,
false,
EdgeDistance{0} - source_phantom.GetForwardDistance()});
}
auto [weight, unpacked_nodes, unpacked_edges] = search( if (source_phantom.IsValidReverseSource())
{
forward_heap.Insert(source_phantom.reverse_segment_id.id,
EdgeWeight{0} - source_phantom.GetReverseWeightPlusOffset(),
{source_phantom.reverse_segment_id.id,
false,
EdgeDistance{0} - source_phantom.GetReverseDistance()});
}
if (target_phantom.IsValidForwardTarget())
{
reverse_heap.Insert(
target_phantom.forward_segment_id.id,
target_phantom.GetForwardWeightPlusOffset(),
{target_phantom.forward_segment_id.id, false, target_phantom.GetForwardDistance()});
}
if (target_phantom.IsValidReverseTarget())
{
reverse_heap.Insert(
target_phantom.reverse_segment_id.id,
target_phantom.GetReverseWeightPlusOffset(),
{target_phantom.reverse_segment_id.id, false, target_phantom.GetReverseDistance()});
}
const PhantomEndpoints endpoints{source_phantom, target_phantom};
auto distance = searchDistance(
engine_working_data, facade, forward_heap, reverse_heap, {}, weight_upper_bound, endpoints); engine_working_data, facade, forward_heap, reverse_heap, {}, weight_upper_bound, endpoints);
if (weight == INVALID_EDGE_WEIGHT) if (distance == INVALID_EDGE_DISTANCE)
{ {
return std::numeric_limits<double>::max(); return std::numeric_limits<double>::max();
} }
BOOST_ASSERT(unpacked_nodes.size() >= 1);
EdgeDistance distance = {0.0};
if (source_phantom.forward_segment_id.id == unpacked_nodes.front())
{
BOOST_ASSERT(source_phantom.forward_segment_id.enabled);
distance = EdgeDistance{0} - source_phantom.GetForwardDistance();
}
else if (source_phantom.reverse_segment_id.id == unpacked_nodes.front())
{
BOOST_ASSERT(source_phantom.reverse_segment_id.enabled);
distance = EdgeDistance{0} - source_phantom.GetReverseDistance();
}
for (size_t index = 0; index < unpacked_nodes.size() - 1; ++index)
{
distance += facade.GetNodeDistance(unpacked_nodes[index]);
}
if (target_phantom.forward_segment_id.id == unpacked_nodes.back())
{
BOOST_ASSERT(target_phantom.forward_segment_id.enabled);
distance += target_phantom.GetForwardDistance();
}
else if (target_phantom.reverse_segment_id.id == unpacked_nodes.back())
{
BOOST_ASSERT(target_phantom.reverse_segment_id.enabled);
distance += target_phantom.GetReverseDistance();
}
return from_alias<double>(distance); return from_alias<double>(distance);
} }

29
include/engine/search_engine_data.hpp
View File

@ -47,6 +47,7 @@ template <> struct SearchEngineData<routing_algorithms::ch::Algorithm>
util::UnorderedMapStorage<NodeID, int>>; util::UnorderedMapStorage<NodeID, int>>;
using SearchEngineHeapPtr = boost::thread_specific_ptr<QueryHeap>; using SearchEngineHeapPtr = boost::thread_specific_ptr<QueryHeap>;
using ManyToManyHeapPtr = boost::thread_specific_ptr<ManyToManyQueryHeap>; using ManyToManyHeapPtr = boost::thread_specific_ptr<ManyToManyQueryHeap>;
static SearchEngineHeapPtr forward_heap_1; static SearchEngineHeapPtr forward_heap_1;
@ -56,6 +57,10 @@ template <> struct SearchEngineData<routing_algorithms::ch::Algorithm>
static SearchEngineHeapPtr forward_heap_3; static SearchEngineHeapPtr forward_heap_3;
static SearchEngineHeapPtr reverse_heap_3; static SearchEngineHeapPtr reverse_heap_3;
static ManyToManyHeapPtr many_to_many_heap; static ManyToManyHeapPtr many_to_many_heap;
static SearchEngineHeapPtr map_matching_forward_heap_1;
static SearchEngineHeapPtr map_matching_reverse_heap_1;
void InitializeOrClearMapMatchingThreadLocalStorage(unsigned number_of_nodes);
void InitializeOrClearFirstThreadLocalStorage(unsigned number_of_nodes); void InitializeOrClearFirstThreadLocalStorage(unsigned number_of_nodes);
@ -74,6 +79,19 @@ struct MultiLayerDijkstraHeapData
MultiLayerDijkstraHeapData(NodeID p, bool from) : parent(p), from_clique_arc(from) {} MultiLayerDijkstraHeapData(NodeID p, bool from) : parent(p), from_clique_arc(from) {}
}; };
struct MapMatchingMultiLayerDijkstraHeapData
{
NodeID parent;
bool from_clique_arc;
EdgeDistance distance = {0};
MapMatchingMultiLayerDijkstraHeapData(NodeID p) : parent(p), from_clique_arc(false) {}
MapMatchingMultiLayerDijkstraHeapData(NodeID p, bool from) : parent(p), from_clique_arc(from) {}
MapMatchingMultiLayerDijkstraHeapData(NodeID p, bool from, EdgeDistance d)
: parent(p), from_clique_arc(from), distance(d)
{
}
};
struct ManyToManyMultiLayerDijkstraHeapData : MultiLayerDijkstraHeapData struct ManyToManyMultiLayerDijkstraHeapData : MultiLayerDijkstraHeapData
{ {
EdgeDuration duration; EdgeDuration duration;
@ -104,16 +122,27 @@ template <> struct SearchEngineData<routing_algorithms::mld::Algorithm>
EdgeWeight, EdgeWeight,
ManyToManyMultiLayerDijkstraHeapData, ManyToManyMultiLayerDijkstraHeapData,
util::TwoLevelStorage<NodeID, int>>; util::TwoLevelStorage<NodeID, int>>;
using MapMatchingQueryHeap = util::QueryHeap<NodeID,
NodeID,
EdgeWeight,
MapMatchingMultiLayerDijkstraHeapData,
util::TwoLevelStorage<NodeID, int>>;
using SearchEngineHeapPtr = boost::thread_specific_ptr<QueryHeap>; using SearchEngineHeapPtr = boost::thread_specific_ptr<QueryHeap>;
using ManyToManyHeapPtr = boost::thread_specific_ptr<ManyToManyQueryHeap>; using ManyToManyHeapPtr = boost::thread_specific_ptr<ManyToManyQueryHeap>;
using MapMatchingHeapPtr = boost::thread_specific_ptr<MapMatchingQueryHeap>;
static SearchEngineHeapPtr forward_heap_1; static SearchEngineHeapPtr forward_heap_1;
static SearchEngineHeapPtr reverse_heap_1; static SearchEngineHeapPtr reverse_heap_1;
static MapMatchingHeapPtr map_matching_forward_heap_1;
static MapMatchingHeapPtr map_matching_reverse_heap_1;
static ManyToManyHeapPtr many_to_many_heap; static ManyToManyHeapPtr many_to_many_heap;
void InitializeOrClearFirstThreadLocalStorage(unsigned number_of_nodes, void InitializeOrClearFirstThreadLocalStorage(unsigned number_of_nodes,
unsigned number_of_boundary_nodes); unsigned number_of_boundary_nodes);
void InitializeOrClearMapMatchingThreadLocalStorage(unsigned number_of_nodes,
unsigned number_of_boundary_nodes);
void InitializeOrClearManyToManyThreadLocalStorage(unsigned number_of_nodes, void InitializeOrClearManyToManyThreadLocalStorage(unsigned number_of_nodes,
unsigned number_of_boundary_nodes); unsigned number_of_boundary_nodes);

9
src/engine/routing_algorithms/map_matching.cpp
View File

@ -49,7 +49,7 @@ inline void initializeHeap(SearchEngineData<Algorithm> &engine_working_data,
{ {
const auto nodes_number = facade.GetNumberOfNodes(); const auto nodes_number = facade.GetNumberOfNodes();
engine_working_data.InitializeOrClearFirstThreadLocalStorage(nodes_number); engine_working_data.InitializeOrClearMapMatchingThreadLocalStorage(nodes_number);
} }
template <> template <>
@ -59,7 +59,8 @@ inline void initializeHeap<mld::Algorithm>(SearchEngineData<mld::Algorithm> &eng
const auto nodes_number = facade.GetNumberOfNodes(); const auto nodes_number = facade.GetNumberOfNodes();
const auto border_nodes_number = facade.GetMaxBorderNodeID() + 1; const auto border_nodes_number = facade.GetMaxBorderNodeID() + 1;
engine_working_data.InitializeOrClearFirstThreadLocalStorage(nodes_number, border_nodes_number); engine_working_data.InitializeOrClearMapMatchingThreadLocalStorage(nodes_number,
border_nodes_number);
} }
} // namespace } // namespace
@ -144,8 +145,8 @@ SubMatchingList mapMatching(SearchEngineData<Algorithm> &engine_working_data,
} }
initializeHeap(engine_working_data, facade); initializeHeap(engine_working_data, facade);
auto &forward_heap = *engine_working_data.forward_heap_1; auto &forward_heap = *engine_working_data.map_matching_forward_heap_1;
auto &reverse_heap = *engine_working_data.reverse_heap_1; auto &reverse_heap = *engine_working_data.map_matching_reverse_heap_1;
std::size_t breakage_begin = map_matching::INVALID_STATE; std::size_t breakage_begin = map_matching::INVALID_STATE;
std::vector<std::size_t> split_points; std::vector<std::size_t> split_points;

50
src/engine/search_engine_data.cpp
View File

@ -11,8 +11,32 @@ SearchEngineData<CH>::SearchEngineHeapPtr SearchEngineData<CH>::forward_heap_2;
SearchEngineData<CH>::SearchEngineHeapPtr SearchEngineData<CH>::reverse_heap_2; SearchEngineData<CH>::SearchEngineHeapPtr SearchEngineData<CH>::reverse_heap_2;
SearchEngineData<CH>::SearchEngineHeapPtr SearchEngineData<CH>::forward_heap_3; SearchEngineData<CH>::SearchEngineHeapPtr SearchEngineData<CH>::forward_heap_3;
SearchEngineData<CH>::SearchEngineHeapPtr SearchEngineData<CH>::reverse_heap_3; SearchEngineData<CH>::SearchEngineHeapPtr SearchEngineData<CH>::reverse_heap_3;
SearchEngineData<CH>::SearchEngineHeapPtr SearchEngineData<CH>::map_matching_forward_heap_1;
SearchEngineData<CH>::SearchEngineHeapPtr SearchEngineData<CH>::map_matching_reverse_heap_1;
SearchEngineData<CH>::ManyToManyHeapPtr SearchEngineData<CH>::many_to_many_heap; SearchEngineData<CH>::ManyToManyHeapPtr SearchEngineData<CH>::many_to_many_heap;
void SearchEngineData<CH>::InitializeOrClearMapMatchingThreadLocalStorage(unsigned number_of_nodes)
{
if (map_matching_forward_heap_1.get())
{
map_matching_forward_heap_1->Clear();
}
else
{
map_matching_forward_heap_1.reset(new QueryHeap(number_of_nodes));
}
if (map_matching_reverse_heap_1.get())
{
map_matching_reverse_heap_1->Clear();
}
else
{
map_matching_reverse_heap_1.reset(new QueryHeap(number_of_nodes));
}
}
void SearchEngineData<CH>::InitializeOrClearFirstThreadLocalStorage(unsigned number_of_nodes) void SearchEngineData<CH>::InitializeOrClearFirstThreadLocalStorage(unsigned number_of_nodes)
{ {
if (forward_heap_1.get()) if (forward_heap_1.get())
@ -92,8 +116,34 @@ void SearchEngineData<CH>::InitializeOrClearManyToManyThreadLocalStorage(unsigne
using MLD = routing_algorithms::mld::Algorithm; using MLD = routing_algorithms::mld::Algorithm;
SearchEngineData<MLD>::SearchEngineHeapPtr SearchEngineData<MLD>::forward_heap_1; SearchEngineData<MLD>::SearchEngineHeapPtr SearchEngineData<MLD>::forward_heap_1;
SearchEngineData<MLD>::SearchEngineHeapPtr SearchEngineData<MLD>::reverse_heap_1; SearchEngineData<MLD>::SearchEngineHeapPtr SearchEngineData<MLD>::reverse_heap_1;
SearchEngineData<MLD>::MapMatchingHeapPtr SearchEngineData<MLD>::map_matching_forward_heap_1;
SearchEngineData<MLD>::MapMatchingHeapPtr SearchEngineData<MLD>::map_matching_reverse_heap_1;
SearchEngineData<MLD>::ManyToManyHeapPtr SearchEngineData<MLD>::many_to_many_heap; SearchEngineData<MLD>::ManyToManyHeapPtr SearchEngineData<MLD>::many_to_many_heap;
void SearchEngineData<MLD>::InitializeOrClearMapMatchingThreadLocalStorage(
unsigned number_of_nodes, unsigned number_of_boundary_nodes)
{
if (map_matching_forward_heap_1.get())
{
map_matching_forward_heap_1->Clear();
}
else
{
map_matching_forward_heap_1.reset(
new MapMatchingQueryHeap(number_of_nodes, number_of_boundary_nodes));
}
if (map_matching_reverse_heap_1.get())
{
map_matching_reverse_heap_1->Clear();
}
else
{
map_matching_reverse_heap_1.reset(
new MapMatchingQueryHeap(number_of_nodes, number_of_boundary_nodes));
}
}
void SearchEngineData<MLD>::InitializeOrClearFirstThreadLocalStorage( void SearchEngineData<MLD>::InitializeOrClearFirstThreadLocalStorage(
unsigned number_of_nodes, unsigned number_of_boundary_nodes) unsigned number_of_nodes, unsigned number_of_boundary_nodes)
{ {