#ifndef ___SIMULATE_JUMPS__ #define ___SIMULATE_JUMPS__ #include "simulateJumpsAbstract.h" using namespace std; /****************************************************************** This class implements simulateJumpsAbstract for small alphabets: (tested so far up to 3) *******************************************************************/ class simulateJumps:public simulateJumpsAbstract { public: simulateJumps(const tree& inTree, const stochasticProcess& sp, const int alphabetSize); virtual ~simulateJumps(); //for a branch length specified by a nodeName: //give the expected number of jumps (changes) from fromId to toId that occured along the specified branh length, //in which the starting character is terminalStart and the terminal character is terminalEnd MDOUBLE getExpectation(const string& nodeName, int terminalStart, int terminalEnd, int fromId, int toId); //same as above, except here we return the probability of a jump from fromId to toId given //terminal states terminalStart, terminalEnd in this branch MDOUBLE getProb(const string& nodeName, int terminalStart, int terminalEnd, int fromId, int toId); private: void init(); void runOneIter(int state); void computeExpectationsAndPosterior(); private: //_node2Jumps: maps a node name (which specify a branch length) to //the expected number of jumps between any two characters along the branch leading from the father to this node //given the terminal characters of this branch. //The matrix is 2D and not 4D because we use a "combined alphabet" to make access easier. see getCombinedState() for details //The first dimension is the combined terminal state and the second dimension is the combined jump state map _nodes2JumpsExp; //_node2JumpsProb: maps a node name (which specify a branch length) to //the probability of a jump between any two characters along the branch leading from the father to this node //given the terminal characters of this branch. //The matrix is 2D and not 4D because we use a "combined alphabet" to make access easier. see getCombinedState() for details //The first dimension is the combined terminal state and the second dimension is the combined jump state map _nodes2JumpsProb; }; #endif