172 lines
4.0 KiB
C++
172 lines
4.0 KiB
C++
// This code is in the public domain -- castanyo@yahoo.es
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#ifndef NV_MESH_WELD_H
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#define NV_MESH_WELD_H
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#include "nvcore/Array.h"
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#include "nvcore/Hash.h"
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#include "nvcore/Utils.h" // nextPowerOfTwo
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#include <string.h> // for memset, memcmp, memcpy
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// Weld function to remove array duplicates in linear time using hashing.
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namespace nv
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{
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/// Generic welding routine. This function welds the elements of the array p
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/// and returns the cross references in the xrefs array. To compare the elements
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/// it uses the given hash and equal functors.
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///
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/// This code is based on the ideas of Ville Miettinen and Pierre Terdiman.
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template <class T, class H=Hash<T>, class E=Equal<T> >
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struct Weld
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{
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// xrefs maps old elements to new elements
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uint operator()(Array<T> & p, Array<uint> & xrefs)
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{
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const uint N = p.size(); // # of input vertices.
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uint outputCount = 0; // # of output vertices
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uint hashSize = nextPowerOfTwo(N); // size of the hash table
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uint * hashTable = new uint[hashSize + N]; // hash table + linked list
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uint * next = hashTable + hashSize; // use bottom part as linked list
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xrefs.resize(N);
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memset( hashTable, NIL, hashSize*sizeof(uint) ); // init hash table (NIL = 0xFFFFFFFF so memset works)
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H hash;
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E equal;
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for (uint i = 0; i < N; i++)
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{
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const T & e = p[i];
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uint32 hashValue = hash(e) & (hashSize-1);
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uint offset = hashTable[hashValue];
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// traverse linked list
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while( offset != NIL && !equal(p[offset], e) )
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{
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offset = next[offset];
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}
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xrefs[i] = offset;
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// no match found - copy vertex & add to hash
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if( offset == NIL )
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{
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// save xref
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xrefs[i] = outputCount;
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// copy element
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p[outputCount] = e;
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// link to hash table
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next[outputCount] = hashTable[hashValue];
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// update hash heads and increase output counter
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hashTable[hashValue] = outputCount++;
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}
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}
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// cleanup
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delete [] hashTable;
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p.resize(outputCount);
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// number of output vertices
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return outputCount;
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}
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};
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/// Reorder the given array accoding to the indices given in xrefs.
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template <class T>
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void reorderArray(Array<T> & array, const Array<uint> & xrefs)
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{
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const uint count = xrefs.count();
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Array<T> new_array;
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new_array.resize(count);
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for(uint i = 0; i < count; i++) {
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new_array[i] = array[xrefs[i]];
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}
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swap(array, new_array);
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}
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/// Reverse the given array so that new indices point to old indices.
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inline void reverseXRefs(Array<uint> & xrefs, uint count)
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{
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Array<uint> new_xrefs;
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new_xrefs.resize(count);
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for(uint i = 0; i < xrefs.count(); i++) {
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new_xrefs[xrefs[i]] = i;
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}
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swap(xrefs, new_xrefs);
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}
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//
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struct WeldN
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{
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uint vertexSize;
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WeldN(uint n) : vertexSize(n) {}
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// xrefs maps old elements to new elements
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uint operator()(uint8 * ptr, uint N, Array<uint> & xrefs)
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{
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uint outputCount = 0; // # of output vertices
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uint hashSize = nextPowerOfTwo(N); // size of the hash table
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uint * hashTable = new uint[hashSize + N]; // hash table + linked list
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uint * next = hashTable + hashSize; // use bottom part as linked list
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xrefs.resize(N);
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memset( hashTable, NIL, hashSize*sizeof(uint) ); // init hash table (NIL = 0xFFFFFFFF so memset works)
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for (uint i = 0; i < N; i++)
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{
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const uint8 * vertex = ptr + i * vertexSize;
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uint32 hashValue = sdbmHash(vertex, vertexSize) & (hashSize-1);
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uint offset = hashTable[hashValue];
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// traverse linked list
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while (offset != NIL && memcmp(ptr + offset * vertexSize, vertex, vertexSize) != 0)
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{
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offset = next[offset];
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}
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xrefs[i] = offset;
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// no match found - copy vertex & add to hash
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if (offset == NIL)
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{
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// save xref
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xrefs[i] = outputCount;
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// copy element
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memcpy(ptr + outputCount * vertexSize, vertex, vertexSize);
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// link to hash table
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next[outputCount] = hashTable[hashValue];
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// update hash heads and increase output counter
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hashTable[hashValue] = outputCount++;
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}
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}
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// cleanup
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delete [] hashTable;
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// number of output vertices
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return outputCount;
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}
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};
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} // nv namespace
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#endif // NV_MESH_WELD_H
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