// main solver functions
- bool matchNodes(const Graph &needle, int needleNodeIdx, const Graph &haystack, int haystackNodeIdx) const
+ bool matchNodePorts(const Graph &needle, int needleNodeIdx, const Graph &haystack, int haystackNodeIdx, const std::map<std::string, std::string> &swaps) const
{
- // Rules for matching nodes:
- //
- // 1. their typeId must be identical or compatible
- // (this is checked before calling this function)
- //
- // 2. they must have the same ports and the haystack port
- // widths must match the needle port width range
- //
- // 3. All edges from the needle must match the haystack:
- // a) if the needle edge is extern:
- // - the haystack edge must have at least as many components as the needle edge
- // b) if the needle edge is not extern:
- // - the haystack edge must have the same number of components as the needle edge
- // - the haystack edge must not be extern
-
const Graph::Node &nn = needle.nodes[needleNodeIdx];
const Graph::Node &hn = haystack.nodes[haystackNodeIdx];
-
- assert(nn.typeId == hn.typeId || (compatibleTypes.count(nn.typeId) > 0 && compatibleTypes.at(nn.typeId).count(hn.typeId) > 0));
-
- if (nn.ports.size() != hn.ports.size())
- return false;
+ assert(nn.ports.size() == hn.ports.size());
for (int i = 0; i < int(nn.ports.size()); i++)
{
- if (hn.portMap.count(nn.ports[i].portId) == 0)
+ std::string hnPortId = nn.ports[i].portId;
+ if (swaps.count(hnPortId) > 0)
+ hnPortId = swaps.at(hnPortId);
+
+ if (hn.portMap.count(hnPortId) == 0)
return false;
const Graph::Port &np = nn.ports[i];
- const Graph::Port &hp = hn.ports[hn.portMap.at(nn.ports[i].portId)];
+ const Graph::Port &hp = hn.ports[hn.portMap.at(hnPortId)];
if (int(hp.bits.size()) < np.minWidth || hp.bits.size() > np.bits.size())
return false;
return true;
}
+ bool matchNodes(const Graph &needle, int needleNodeIdx, const Graph &haystack, int haystackNodeIdx) const
+ {
+ // Rules for matching nodes:
+ //
+ // 1. their typeId must be identical or compatible
+ // (this is checked before calling this function)
+ //
+ // 2. they must have the same ports and the haystack port
+ // widths must match the needle port width range
+ //
+ // 3. All edges from the needle must match the haystack:
+ // a) if the needle edge is extern:
+ // - the haystack edge must have at least as many components as the needle edge
+ // b) if the needle edge is not extern:
+ // - the haystack edge must have the same number of components as the needle edge
+ // - the haystack edge must not be extern
+
+ const Graph::Node &nn = needle.nodes[needleNodeIdx];
+ const Graph::Node &hn = haystack.nodes[haystackNodeIdx];
+
+ assert(nn.typeId == hn.typeId || (compatibleTypes.count(nn.typeId) > 0 && compatibleTypes.at(nn.typeId).count(hn.typeId) > 0));
+
+ if (nn.ports.size() != hn.ports.size())
+ return false;
+
+ std::map<std::string, std::string> currentCandidate;
+
+ for (const auto &port : needle.nodes[needleNodeIdx].ports)
+ currentCandidate[port.portId] = port.portId;
+
+ if (swapPorts.count(needle.nodes[needleNodeIdx].typeId) == 0)
+ {
+ if (matchNodePorts(needle, needleNodeIdx, haystack, haystackNodeIdx, currentCandidate))
+ return true;
+
+ if (swapPermutations.count(needle.nodes[needleNodeIdx].typeId) > 0)
+ for (const auto &permutation : swapPermutations.at(needle.nodes[needleNodeIdx].typeId)) {
+ std::map<std::string, std::string> currentSubCandidate = currentCandidate;
+ applyPermutation(currentSubCandidate, permutation);
+ if (matchNodePorts(needle, needleNodeIdx, haystack, haystackNodeIdx, currentCandidate))
+ return true;
+ }
+ }
+ else
+ {
+ std::vector<std::vector<std::string>> thisSwapPorts;
+ for (const auto &ports : swapPorts.at(needle.nodes[needleNodeIdx].typeId)) {
+ std::vector<std::string> portsVector;
+ for (const auto &port : ports)
+ portsVector.push_back(port);
+ thisSwapPorts.push_back(portsVector);
+ }
+
+ int thisPermutations = numberOfPermutationsArray(thisSwapPorts);
+ for (int i = 0; i < thisPermutations; i++)
+ {
+ permutateVectorToMapArray(currentCandidate, thisSwapPorts, i);
+
+ if (matchNodePorts(needle, needleNodeIdx, haystack, haystackNodeIdx, currentCandidate))
+ return true;
+
+ if (swapPermutations.count(needle.nodes[needleNodeIdx].typeId) > 0)
+ for (const auto &permutation : swapPermutations.at(needle.nodes[needleNodeIdx].typeId)) {
+ std::map<std::string, std::string> currentSubCandidate = currentCandidate;
+ applyPermutation(currentSubCandidate, permutation);
+ if (matchNodePorts(needle, needleNodeIdx, haystack, haystackNodeIdx, currentCandidate))
+ return true;
+ }
+ }
+ }
+
+ return false;
+ }
+
void generateEnumerationMatrix(std::vector<std::set<int>> &enumerationMatrix, const GraphData &needle, const GraphData &haystack, const std::map<std::string, std::set<std::string>> &initialMappings) const
{
std::map<std::string, std::set<int>> haystackNodesByTypeId;
assert(enumerationMatrix[idx].size() == 1);
int idxHaystack = *enumerationMatrix[idx].begin();
+ if (!matchNodePorts(needle.graph, idx, haystack.graph, idxHaystack, currentCandidate))
+ return false;
+
for (const auto &it_needle : needle.adjMatrix.at(idx))
{
int needleNeighbour = it_needle.first;
if (!diCache.compare(needleEdgeType, haystackEdgeType, currentCandidate, swapPorts, swapPermutations))
return false;
}
+
return true;
}
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