/* McCaskill's Algorithm -- The algorithm calculates a base paring probability matrix from the input of one sequence. $Id: nrutil.h,v 1.0 2005/10/20 14:22 $; Copyright (C) 2005 Yasuo Tabei This is free software with ABSOLUTELY NO WARRANTY. This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #ifndef _NR_UTIL_H_ #define _NR_UTIL_H_ #include #include #include #include #include // by katoh using namespace std; typedef double DP; template inline const T SQR(const T a) {return a*a;} template inline const T MAX(const T &a, const T &b) {return b > a ? (b) : (a);} inline float MAX(const double &a, const float &b) {return b > a ? (b) : float(a);} inline float MAX(const float &a, const double &b) {return b > a ? float(b) : (a);} template inline const T MIN(const T &a, const T &b) {return b < a ? (b) : (a);} inline float MIN(const double &a, const float &b) {return b < a ? (b) : float(a);} inline float MIN(const float &a, const double &b) {return b < a ? float(b) : (a);} template inline const T SIGN(const T &a, const T &b) {return b >= 0 ? (a >= 0 ? a : -a) : (a >= 0 ? -a : a);} inline float SIGN(const float &a, const double &b) {return b >= 0 ? (a >= 0 ? a : -a) : (a >= 0 ? -a : a);} inline float SIGN(const double &a, const float &b) {return b >= 0 ? (a >= 0 ? a : -a) : (a >= 0 ? -a : a);} template inline void SWAP(T &a, T &b) {T dum=a; a=b; b=dum;} namespace NR { inline void nrerror(const string error_text) // Numerical Recipes standard error handler { cerr << "Numerical Recipes run-time error..." << endl; cerr << error_text << endl; cerr << "...now exiting to system..." << endl; exit(1); } } template class NRVec { private: int nn; // size of array. upper index is nn-1 T *v; public: NRVec(); explicit NRVec(int n); // Zero-based array NRVec(const T &a, int n); //initialize to constant value NRVec(const T *a, int n); // Initialize to array NRVec(const NRVec &rhs); // Copy constructor NRVec & operator=(const NRVec &rhs); //assignment NRVec & operator=(const T &a); //assign a to every element inline T & operator[](const int i); //i∏th element inline const T & operator[](const int i) const; void Allocator(int i = 0); // by Steffen, mpg inline int size() const; ~NRVec(); }; template NRVec::NRVec() : nn(0), v(0) {} template NRVec::NRVec(int n) : nn(n), v(new T[n]) {} template NRVec::NRVec(const T& a, int n) : nn(n), v(new T[n]) { for(int i=0; i NRVec::NRVec(const T *a, int n) : nn(n), v(new T[n]) { for(int i=0; i void NRVec::Allocator(int n) // by Steffen { v = new T[n]; } template NRVec::NRVec(const NRVec &rhs) : nn(rhs.nn), v(new T[nn]) { for(int i=0; i NRVec & NRVec::operator=(const NRVec &rhs) // postcondition: normal assignment via copying has been performed; // if vector and rhs were different sizes, vector // has been resized to match the size of rhs { if (this != &rhs) { if (nn != rhs.nn) { if (v != 0) delete [] (v); nn=rhs.nn; v= new T[nn]; } for (int i=0; i NRVec & NRVec::operator=(const T &a) //assign a to every element { for (int i=0; i inline T & NRVec::operator[](const int i) //subscripting { return v[i]; } template inline const T & NRVec::operator[](const int i) const //subscripting { return v[i]; } template inline int NRVec::size() const { return nn; } template NRVec::~NRVec() { if (v != 0) delete[] (v); } template class NRMat { private: int nn; int mm; T **v; public: NRMat(); NRMat(int n, int m); // Zero-based array NRMat(const T &a, int n, int m); //Initialize to constant NRMat(const T *a, int n, int m); // Initialize to array NRMat(const NRMat &rhs); // Copy constructor void Allocator(int n, int m); void Allocator(const T &a, int n, int m); void Allocator(const T *a, int n, int m); NRMat & operator=(const NRMat &rhs); //assignment NRMat & operator=(const T &a); //assign a to every element inline T* operator[](const int i); //subscripting: pointer to row i inline const T* operator[](const int i) const; inline T & ref(const int i, const int j); inline const T ref(const int i, const int j) const; inline int nrows() const; inline int ncols() const; ~NRMat(); }; template NRMat::NRMat() : nn(0), mm(0), v(0) {} template NRMat::NRMat(int n, int m) : nn(n), mm(m), v(new T*[n]) { v[0] = new T[m*n]; for (int i=1; i< n; i++) v[i] = v[i-1] + m; } template NRMat::NRMat(const T &a, int n, int m) : nn(n), mm(m), v(new T*[n]) { int i,j; v[0] = new T[m*n]; for (i=1; i< n; i++) v[i] = v[i-1] + m; for (i=0; i< n; i++) for (j=0; j NRMat::NRMat(const T *a, int n, int m) : nn(n), mm(m), v(new T*[n]) { int i,j; v[0] = new T[m*n]; for (i=1; i< n; i++) v[i] = v[i-1] + m; for (i=0; i< n; i++) for (j=0; j void NRMat::Allocator(int n, int m) { if( v != 0 ) { delete[] (v[0]); delete (v); } nn = n; mm = m; v = new T*[n]; v[0] = new T[m*n]; for (int i=1; i< n; i++) v[i] = v[i-1] + m; } template void NRMat::Allocator(const T &a, int n, int m) { if( v != 0 ) { delete[] (v[0]); delete (v); } int i,j; nn = n; mm = m; v = new T*[n]; v[0] = new T[m*n]; for (i=1; i< n; i++) v[i] = v[i-1] + m; for (i=0; i< n; i++) for (j=0; j void NRMat::Allocator(const T *a, int n, int m) { if( v != 0 ) { delete[] (v[0]); delete (v); } int i,j; nn = n; mm = m; v = new T*[n]; v[0] = new T[m*n]; for (i=1; i< n; i++) v[i] = v[i-1] + m; for (i=0; i< n; i++) for (j=0; j NRMat::NRMat(const NRMat &rhs) : nn(rhs.nn), mm(rhs.mm), v(new T*[nn]) { int i,j; v[0] = new T[mm*nn]; for (i=1; i< nn; i++) v[i] = v[i-1] + mm; for (i=0; i< nn; i++) for (j=0; j NRMat & NRMat::operator=(const NRMat &rhs) // postcondition: normal assignment via copying has been performed; // if matrix and rhs were different sizes, matrix // has been resized to match the size of rhs { if (this != &rhs) { int i,j; if (nn != rhs.nn || mm != rhs.mm) { if (v != 0) { delete[] (v[0]); delete[] (v); } nn=rhs.nn; mm=rhs.mm; v = new T*[nn]; v[0] = new T[mm*nn]; } for (i=1; i< nn; i++) v[i] = v[i-1] + mm; for (i=0; i< nn; i++) for (j=0; j NRMat & NRMat::operator=(const T &a) //assign a to every element { for (int i=0; i< nn; i++) for (int j=0; j inline T* NRMat::operator[](const int i) //subscripting: pointer to row i { return v[i]; } template inline const T* NRMat::operator[](const int i) const { return v[i]; } template inline T & NRMat::ref(const int i, const int j) { return v[i][j]; } template inline const T NRMat::ref(const int i, const int j) const { return v[i][j]; } template inline int NRMat::nrows() const { return nn; } template inline int NRMat::ncols() const { return mm; } template NRMat::~NRMat() { if (v != 0) { delete[] (v[0]); delete[] (v); } } template class NRMat3d { private: int nn; int mm; int kk; T ***v; public: NRMat3d(); NRMat3d(int n, int m, int k); inline void Allocator(int n, int m, int k); inline T** operator[](const int i); //subscripting: pointer to row i inline const T* const * operator[](const int i) const; inline int dim1() const; inline int dim2() const; inline int dim3() const; ~NRMat3d(); }; template NRMat3d::NRMat3d(): nn(0), mm(0), kk(0), v(0) {} template NRMat3d::NRMat3d(int n, int m, int k) : nn(n), mm(m), kk(k), v(new T**[n]) { int i,j; v[0] = new T*[n*m]; v[0][0] = new T[n*m*k]; for(j=1; j inline void NRMat3d::Allocator(int n, int m, int k) { int i,j; v[0] = new T*[n*m]; v[0][0] = new T[n*m*k]; for(j=1; j inline T** NRMat3d::operator[](const int i) //subscripting: pointer to row i { return v[i]; } template inline const T* const * NRMat3d::operator[](const int i) const { return v[i]; } template inline int NRMat3d::dim1() const { return nn; } template inline int NRMat3d::dim2() const { return mm; } template inline int NRMat3d::dim3() const { return kk; } template NRMat3d::~NRMat3d() { if (v != 0) { delete[] (v[0][0]); delete[] (v[0]); delete[] (v); } } //The next 3 classes are used in artihmetic coding, Huffman coding, and //wavelet transforms respectively. This is as good a place as any to put them! class arithcode { private: NRVec *ilob_p,*iupb_p,*ncumfq_p; public: NRVec &ilob,&iupb,&ncumfq; unsigned long jdif,nc,minint,nch,ncum,nrad; arithcode(unsigned long n1, unsigned long n2, unsigned long n3) : ilob_p(new NRVec(n1)), iupb_p(new NRVec(n2)), ncumfq_p(new NRVec(n3)), ilob(*ilob_p),iupb(*iupb_p),ncumfq(*ncumfq_p) {} ~arithcode() { if (ilob_p != 0) delete ilob_p; if (iupb_p != 0) delete iupb_p; if (ncumfq_p != 0) delete ncumfq_p; } }; class huffcode { private: NRVec *icod_p,*ncod_p,*left_p,*right_p; public: NRVec &icod,&ncod,&left,&right; int nch,nodemax; huffcode(unsigned long n1, unsigned long n2, unsigned long n3, unsigned long n4) : icod_p(new NRVec(n1)), ncod_p(new NRVec(n2)), left_p(new NRVec(n3)), right_p(new NRVec(n4)), icod(*icod_p),ncod(*ncod_p),left(*left_p),right(*right_p) {} ~huffcode() { if (icod_p != 0) delete icod_p; if (ncod_p != 0) delete ncod_p; if (left_p != 0) delete left_p; if (right_p != 0) delete right_p; } }; class wavefilt { private: NRVec *cc_p,*cr_p; public: int ncof,ioff,joff; NRVec &cc,&cr; wavefilt() : cc(*cc_p),cr(*cr_p) {} wavefilt(const DP *a, const int n) : //initialize to array cc_p(new NRVec(n)),cr_p(new NRVec(n)), ncof(n),ioff(-(n >> 1)),joff(-(n >> 1)),cc(*cc_p),cr(*cr_p) { int i; for (i=0; i class Trimat { private: int nn; T **v; inline T* operator[](const int i); //subscripting: pointer to row i inline const T* operator[](const int i) const; public: Trimat(); Trimat(int n); // Zero-based array Trimat(const T &a, int n); //Initialize to constant Trimat(const T *a, int n); // Initialize to array Trimat(const Trimat &rhs); // Copy constructor void Allocator(int n); void Allocator(const T &a, int n); void Allocator(const T *a, int n); Trimat & operator=(const Trimat &rhs); //assignment Trimat & operator=(const T &a); //assign a to every element inline T & ref(const int i, const int j); inline T * getPointer(const int i, const int j); inline T * begin() const; inline T * end() const; inline const T ref(const int i, const int j) const; inline int nrows() const; ~Trimat(); }; template Trimat::Trimat() : nn(0), v(0) {} template Trimat::Trimat(int n) : nn(n), v(new T*[n]) { v[0] = new T[n*(n+1)/2]; for (int i=1; i< n; i++) v[i] = v[i-1] + (n-i+1); for (int i=0; i< n; i++) for (int j=0; j<(n-i); j++) v[i][j] = 0; } template Trimat::Trimat(const T &a, int n) : nn(n), v(new T*[n]) { int i,j; v[0] = new T[n*(n+1)/2]; for (i=1; i< n; i++) v[i] = v[i-1] + (n-i+1); for (i=0; i< n; i++) for (j=0; j<(n-i); j++) v[i][j] = a; } template Trimat::Trimat(const T *a, int n) : nn(n), v(new T*[n]) { int i,j; v[0] = new T[n*(n+1)/2]; for (i=1; i< n; i++) v[i] = v[i-1] + (n-i+1); for (i=0; i< n; i++) for (j=0; j<(n-i); j++) v[i][j] = *a++; } template void Trimat::Allocator(int n) { nn = n; v = new T*[n]; v[0] = new T[n*(n+1)/2]; for (int i=1; i< n; i++) v[i] = v[i-1] + (n-i+1); } template void Trimat::Allocator(const T &a, int n) { nn = n; v = new T*[n]; int i,j; v[0] = new T[n*(n+1)/2]; for (i=1; i < n; i++) v[i] = v[i-1] + (n-i+1); for (i=0; i < n; i++) for (j=0; j < (n-i); j++) v[i][j] = a; } template void Trimat::Allocator(const T *a, int n) { nn = n; v = new T*[n]; int i,j; v[0] = new T[n*(n+1)/2]; for (i=1; i< n; i++) v[i] = v[i-1] + (n-i+1); for (i=0; i< n; i++) for (j=0; j<(n-i); j++) v[i][j] = *a++; } template Trimat::Trimat(const Trimat &rhs) : nn(rhs.nn), v(new T*[nn]) { int i,j; v[0] = new T[nn*(nn+1)/2]; for (i=1; i< nn; i++) v[i] = v[i-1] + (nn-i+1); for (i=0; i< nn; i++) for (j=0; j<(nn-i); j++) v[i][j] = rhs[i][j]; } template Trimat & Trimat::operator=(const Trimat &rhs) // postcondition: normal assignment via copying has been performed; // if matrix and rhs were different sizes, matrix // has been resized to match the size of rhs { if (this != &rhs) { int i,j; if (nn != rhs.nn) { if (v != 0) { delete[] (v[0]); delete[] (v); } nn=rhs.nn; v = new T*[nn]; v[0] = new T[nn*(nn+1)/2]; } for (i=1; i< nn; i++) v[i] = v[i-1] + (nn-i+1); for (i=0; i< nn; i++) for (j=0; j<(nn-i); j++) v[i][j] = rhs[i][j]; } return *this; } template Trimat & Trimat::operator=(const T &a) //assign a to every element { for (int i=0; i< nn; i++) for (int j=0; j inline T & Trimat::ref(const int i, const int j) { return v[i][j-i]; } template inline const T Trimat::ref(const int i, const int j) const { return v[i][j-i]; } template inline T * Trimat::getPointer(const int i, const int j) { return &v[i][j-i]; } template inline T * Trimat::begin() const { return &v[0][0]; } template inline T * Trimat::end() const { return (&v[nn-1][0] + 1); } template inline int Trimat::nrows() const { return nn; } template Trimat::~Trimat() { if (v != 0) { delete[] (v[0]); delete[] (v); } } /* Triangle Vertical Matrix Class --------------------------------------------------------- |v[0][0]|v[1][0]| | | |v[n-1][0]| |-------|-------|------|------------|---------|---------| |v[0][1]|v[1][1]| | |v[n-2][1]| | |-------|-------|------|------------|---------|---------| | | | | | | | |-------|-------|------|------------|---------|---------| | | | | | | | | | |-------|-----------------------------------------------| | | | |-------|-----------------------------------------------| |v[0][n-2]|v[n-2][n-2]| | |-------|-----------------------------------------------| |v[0][n-1]| | |-------------------------------------------------------| */ template class TriVertMat { private: int nn; T **v; inline T* operator[](const int i); //subscripting: pointer to row i inline const T* operator[](const int i) const; public: TriVertMat(); TriVertMat(int n); // Zero-based array TriVertMat(const T &a, int n); //Initialize to constant TriVertMat(const T *a, int n); // Initialize to array TriVertMat(const TriVertMat &rhs); // Copy constructor void Allocator(int n); void Allocator(const T &a, int n); void Allocator(const T *a, int n); TriVertMat & operator=(const TriVertMat &rhs); //assignment TriVertMat & operator=(const T &a); //assign a to every element inline T & ref(const int i, const int j); inline T * getPointer(const int i, const int j); inline const T ref(const int i, const int j) const; inline int nrows() const; ~TriVertMat(); }; template TriVertMat::TriVertMat() : nn(0), v(0) {} template TriVertMat::TriVertMat(int n) : nn(n), v(new T*[n]) { v[0] = new T[n*(n+1)/2]; for (int i=1; i< n; i++) v[i] = v[i-1] + i; } template TriVertMat::TriVertMat(const T &a, int n) : nn(n), v(new T*[n]) { int i,j; v[0] = new T[n*(n+1)/2]; for (i=1; i< n; i++) v[i] = v[i-1] + i; for (i=0; i< n; i++) for (j=0; j<(n-i); j++) v[i][j] = a; } template TriVertMat::TriVertMat(const T *a, int n) : nn(n), v(new T*[n]) { int i,j; v[0] = new T[n*(n+1)/2]; for (i=1; i< n; i++) v[i] = v[i-1] + i; for (i=0; i< n; i++) for (j=0; j<(n-i); j++) v[i][j] = *a++; } template void TriVertMat::Allocator(int n) { nn = n; v = new T*[n]; v[0] = new T[n*(n+1)/2]; for (int i=1; i< n; i++) v[i] = v[i-1] + i; } template void TriVertMat::Allocator(const T &a, int n) { nn = n; v = new T*[n]; int i,j; v[0] = new T[n*(n+1)/2]; for (i=1; i< n; i++) v[i] = v[i-1] + i; for (i=0; i< n; i++) for (j=0; j<(n-i); j++) v[i][j] = a; } template void TriVertMat::Allocator(const T *a, int n) { nn = n; v = new T*[n]; int i,j; v[0] = new T[n*(n+1)/2]; for (i=1; i< n; i++) v[i] = v[i-1] + i; for (i=0; i< n; i++) for (j=0; j<(n-i); j++) v[i][j] = *a++; } template TriVertMat::TriVertMat(const TriVertMat &rhs) : nn(rhs.nn), v(new T*[nn]) { int i,j; v[0] = new T[nn*(nn+1)/2]; for (i=1; i< nn; i++) v[i] = v[i-1] + i; for (i=0; i< nn; i++) for (j=0; j<(nn-i); j++) v[i][j] = rhs[i][j]; } template TriVertMat & TriVertMat::operator=(const TriVertMat &rhs) // postcondition: normal assignment via copying has been performed; // if matrix and rhs were different sizes, matrix // has been resized to match the size of rhs { if (this != &rhs) { int i,j; if (nn != rhs.nn) { if (v != 0) { delete[] (v[0]); delete[] (v); } nn=rhs.nn; v = new T*[nn]; v[0] = new T[nn*(nn+1)/2]; } for (i=1; i< nn; i++) v[i] = v[i-1] + i; for (i=0; i< nn; i++) for (j=0; j<(nn-i); j++) v[i][j] = rhs[i][j]; } return *this; } template TriVertMat & TriVertMat::operator=(const T &a) //assign a to every element { for (int i=0; i< nn; i++) for (int j=0; j inline T & TriVertMat::ref(const int i, const int j) { return v[j][i]; } template inline const T TriVertMat::ref(const int i, const int j) const { return v[j][i]; } template inline T * TriVertMat::getPointer(const int i, const int j) { return &v[j][i]; } template inline int TriVertMat::nrows() const { return nn; } template TriVertMat::~TriVertMat() { if (v != 0) { delete[] (v[0]); delete[] (v); } } //Overloaded complex operations to handle mixed float and double //This takes care of e.g. 1.0/z, z complex inline const complex operator+(const double &a, const complex &b) { return float(a)+b; } inline const complex operator+(const complex &a, const double &b) { return a+float(b); } inline const complex operator-(const double &a, const complex &b) { return float(a)-b; } inline const complex operator-(const complex &a, const double &b) { return a-float(b); } inline const complex operator*(const double &a, const complex &b) { return float(a)*b; } inline const complex operator*(const complex &a, const double &b) { return a*float(b); } inline const complex operator/(const double &a, const complex &b) { return float(a)/b; } inline const complex operator/(const complex &a, const double &b) { return a/float(b); } //some compilers choke on pow(float,double) in single precision. also atan2 inline float pow (float x, double y) {return pow(double(x),y);} inline float pow (double x, float y) {return pow(x,double(y));} inline float atan2 (float x, double y) {return atan2(double(x),y);} inline float atan2 (double x, float y) {return atan2(x,double(y));} #endif /* _NR_UTIL_H_ */