2018-05-17 14:01:02 +00:00
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#pragma once
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#include "vec.h"
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#include "mat.h"
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#include "inv.h"
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namespace cgv {
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namespace math {
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/// dimension independent implementation of quadric error metrics
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template <typename T>
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class qem : public vec<T>
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{
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public:
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/// standard constructor initializes qem based on dimension
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qem(int d = -1) : vec<T>((d+1)*(d+2)/2)
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{
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if (d>=0)
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this->zeros();
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}
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/// construct from point and normal
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qem(const vec<T>& p, const vec<T>& n) : vec<T>((p.size()+1)*(p.size()+2)/2)
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{
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2018-05-17 13:50:03 +00:00
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set(n, -dot(p,n));
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2018-05-17 14:01:02 +00:00
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}
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/// construct from normal and distance to origin
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qem(const vec<T>& n, T d) : vec<T>((n.size()+1)*(n.size()+2)/2)
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{
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set(n,d);
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}
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/// set from normal and distance to origin
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void set(const vec<T>& n, T d)
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{
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2018-05-17 13:50:03 +00:00
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this->first() = d*d;
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unsigned int i,j,k=n.size()+1;
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for (i=0;i<n.size(); ++i) {
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(*this)(i+1) = d*n(i);
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for (j=i;j<n.size(); ++j, ++k)
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(*this)(k) = n(i)*n(j);
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}
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2018-05-17 14:01:02 +00:00
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}
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///number of elements
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unsigned dim() const
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{
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return (unsigned int)sqrt(2.0*this->size())-1;
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}
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///assignment of a vector v
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qem<T>& operator = (const qem<T>& v)
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{
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*static_cast<vec<T>*>(this) = v;
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return *this;
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}
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/// return the scalar part of the qem
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const T& scalar_part() const
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{
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return this->first();
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}
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/// return the vector part of the qem
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vec<T> vector_part() const
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{
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vec<T> v(dim());
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for (unsigned int i=0; i<v.size(); ++i)
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v(i) = (*this)(i+1);
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return v;
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}
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/// return matrix part
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mat<T> matrix_part() const
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{
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unsigned int d = dim();
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mat<T> m(d,d);
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unsigned int i,j,k=d+1;
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for (i=0; i<d; ++i)
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for (j=i; j<d; ++j,++k)
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m(i,j) = m(j,i) = (*this)(k);
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return m;
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}
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/// evaluate the quadric error metric at given location
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T evaluate(const vec<T>& p) const
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{
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return dot(matrix_part()*p+2.0*vector_part(),p)+scalar_part();
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}
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static bool inside(const vec<T>& p, const vec<T>& minp, const vec<T>& maxp)
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{
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for (unsigned int i=0; i<p.size(); ++i) {
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if (p(i) < minp(i))
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return false;
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if (p(i) > maxp(i))
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return false;
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}
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return true;
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}
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/** compute point that minimizes distance to qem and is inside the sphere of radius max_distance
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around p_ref. If max_distance is -1, no sphere inclusion test is performed.
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relative_epsilon gives the absolute value of the fraction betweenan eigenvalue and the
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largest eigenvalue before it is set to zero. epsilon is a global limit on the absolute
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value of a singular value before accepted as non zero. */
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vec<T> minarg(const vec<T>& p_ref, T relative_epsilon, T max_distance = -1, T epsilon = 1e-10) const
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{
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unsigned int d = p_ref.size();
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assert(d == dim());
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T max_distance2 = max_distance*max_distance;
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mat<T> U,V,A = matrix_part();
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diag_mat<T> W,iW;
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svd(A,U,W,V);
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U.transpose();
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iW = inv(W);
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vec<T> y_solve = -(inv(W)*(U*vector_part()));
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vec<T> y_ref = transpose(V)*p_ref;
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vec<T> y(3);
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for (unsigned int i = d; i > 0; ) {
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--i;
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if (fabs(W(i)) > epsilon && fabs(W(i)*iW(0)) > relative_epsilon) {
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unsigned int j;
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for (j = 0; j <= i; ++j)
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y(j) = y_solve(j);
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for (; j < d; ++j)
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y(j) = y_ref(j);
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vec<T> p = V*y;
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if (max_distance != -1 && (p-p_ref).sqr_length() <= max_distance2)
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return p;
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}
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}
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return p_ref;
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}
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/// in place qem addition
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template <typename S>
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qem<T>& operator += (const qem<S>& v)
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{
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assert(this->size() == v.size());
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for (unsigned i=0;i<this->size();++i) (*this)(i) += v(i); return *this;
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}
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///in place qem subtraction
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template <typename S>
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qem<T>& operator -= (const qem<S>& v)
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{
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assert(this->size() == v.size());
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for (unsigned i=0;i<this->size();++i) (*this)(i) -= v(i); return *this;
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}
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///qem addition
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template <typename S>
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const qem<T> operator + (const qem<S>& v) const
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{
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vec<T> r = *this; r += v; return r;
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}
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///qem subtraction
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template <typename S>
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qem<T> operator - (const qem<S>& v) const
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{
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qem<T> r = *this; r -= v; return r;
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}
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///negates the qem
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qem<T> operator-(void) const
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{
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qem<T> r=(*this);
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r=(T)(-1)*r;
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return r;
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}
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///multiplication with scalar s
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qem<T> operator * (const T& s) const
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{
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qem<T> r = *this; r *= s; return r;
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}
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///divides vector by scalar s
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qem<T> operator / (const T& s)const
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{
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qem<T> r = *this;
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r /= s;
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return r;
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}
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///resize the vector
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void resize(unsigned d)
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{
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vec<T>::resize((d+1)*(d+2)/2);
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}
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///test for equality
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template <typename S>
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bool operator == (const qem<S>& v) const
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{
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for (unsigned i=0;i<this->size();++i)
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if((*this)(i) != (T)v(i)) return false;
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return true;
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}
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///test for inequality
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template <typename S>
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bool operator != (const qem<S>& v) const
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{
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for (unsigned i=0;i<this->size();++i)
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if((*this)(i) != (T)v(i)) return true;
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return false;
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}
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};
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///returns the product of a scalar s and qem v
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template <typename T>
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const qem<T> operator * (const T& s, const qem<T>& v)
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{
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qem<T> r = v; r *= s; return r;
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}
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}
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}
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