%:- style_check(all). :- module(viterbi, [viterbi/4]). :- use_module(library(lists), [nth/3, member/2 ]). :- use_module(library(assoc)). :- use_module(library(dgraphs)). :- use_module(library(matrix)). :- use_module(library(clpbn), []). :- ensure_loaded(library('clpbn/hmm')). :- use_module(library('clpbn/dists'), [get_dist_params/2]). :- meta_predicate viterbi(:,:,+,-). viterbi(Start,End,String,Trace) :- init_hmm, Start, mk_graph(NOfNodes, Map, ViterbiCode), compile_trace(String, Emissions), get_id(Start, Map, SI), get_id(End, Map, EI), % add a random symbol in front (for the c/1 state). compiled_viterbi(NOfNodes, SI, ViterbiCode, Emissions, Dump, L), backtrace(Dump, EI, Map, L, Trace). state_from_goal(_:Start,S) :- state_from_goal(Start,S). state_from_goal(Start,S) :- functor(Start, N, Ar), % get rid of position and random var NAr is Ar-2, functor(S, N, NAr). mk_graph(NOfNodes, Map, ViterbiCode) :- attributes:all_attvars(Vars0), empty_assoc(KeyMap0), get_graph(Vars0, Nodes, Edges, KeyMap0, KeyMap), dgraph_new(G0), dgraph_add_vertices(G0, Nodes, G1), dgraph_add_edges(G1, Edges, G2), dgraph_top_sort(G2, SortedNodes), compile_viterbi(SortedNodes, KeyMap, NOfNodes, Map, ViterbiCode). get_graph([V|Vs], [NKey|Keys], EdgesF, KeyMap0, KeyMap) :- clpbn:get_atts(V,[key(Key), dist(Id,Parents)]), ( Key =.. [N,2|More] ; Key = s(0), N=s, More=[] ), !, NKey =.. [N|More], fetch_edges(Parents, NKey, EdgesF, Edges0, PKeys), get_emission(V, Key, EmissionProb), put_assoc(NKey,KeyMap0,nodeinfo(_,Id,EmissionProb,PKeys),KeyMapI), get_graph(Vs, Keys, Edges0, KeyMapI, KeyMap). get_graph([_|Vs], Keys, Edges, KeyMap0, KeyMap) :- get_graph(Vs, Keys, Edges, KeyMap0, KeyMap). get_graph([], [], [], KeyMap, KeyMap). get_emission(V, Key, EmissionProbs) :- hmm:get_atts(V,[emission(_)]), !, user:emission_cpt(Key, EmissionProbs). get_emission(_, _, []). fetch_edges([V|Parents], Key0, EdgesF, Edges0, [Slice-AKey|PKeys]) :- var(V), !, clpbn:get_atts(V,[key(Key)]), abstract_key(Key, AKey, Slice), ( Slice < 3 -> EdgesF = [Key0-AKey|EdgesI] ; EdgesF = EdgesI ), fetch_edges(Parents, Key0, EdgesI, Edges0, PKeys). fetch_edges([Key|Parents], Key0, EdgesF, Edges0, [Slice-AKey|PKeys]) :- abstract_key(Key, AKey, Slice), ( Slice < 3 -> EdgesF = [Key0-AKey|EdgesI] ; EdgesF = EdgesI ), fetch_edges(Parents, Key0, EdgesI, Edges0, PKeys). fetch_edges([], _, Edges, Edges, []). abstract_key(Key, NKey, Slice) :- Key =.. [N,Slice|More], NKey =.. [N|More]. compile_viterbi(Keys, KeyMap, Nodes, Map, ViterbiCode) :- enum_keys(Keys, KeyMap, 0, Nodes, Map), compile_keys(Keys, KeyMap, ViterbiCode). % just enumerate keys enum_keys([], _, I, I, []). enum_keys([Key|Keys], KeyMap, I0, Nodes, [I0-Key|Map]) :- get_assoc(Key,KeyMap,nodeinfo(I0,_,_,_)), I is I0+1, enum_keys(Keys, KeyMap, I, Nodes, Map). compile_keys([Key|Keys], KeyMap, ViterbiCodeF) :- get_assoc(Key,KeyMap,nodeinfo(IKey,Id,Emission,PKeys)), compile_emission(Emission,IKey,ViterbiCodeF,ViterbiCodeI), get_dist_params(Id,Probs), compile_propagation(PKeys,Probs,IKey,KeyMap,ViterbiCodeI,ViterbiCode0), compile_keys(Keys, KeyMap, ViterbiCode0). compile_keys([], _, []). % add a random symbol to the end. compile_emission([],_) --> !, []. compile_emission(EmissionTerm,IKey) --> [emit(IKey,EmissionTerm)]. compile_propagation([],[],_,_) --> []. compile_propagation([0-PKey|Ps], [Prob|Probs], IKey, KeyMap) --> [prop_same(IKey,Parent,Prob)], { get_assoc(PKey,KeyMap,nodeinfo(Parent,_,_,_)) }, compile_propagation(Ps, Probs, IKey, KeyMap). compile_propagation([2-PKey|Ps], [Prob|Probs], IKey, KeyMap) --> [prop_same(IKey,Parent,Prob)], { get_assoc(PKey,KeyMap,nodeinfo(Parent,_,_,_)) }, compile_propagation(Ps, Probs, IKey, KeyMap). compile_propagation([3-PKey|Ps], [Prob|Probs], IKey, KeyMap) --> [prop_next(IKey,Parent,Prob)], { get_assoc(PKey,KeyMap,nodeinfo(Parent,_,_,_)) }, compile_propagation(Ps, Probs, IKey, KeyMap). get_id(_:S, Map, SI) :- !, get_id(S, Map, SI). get_id(S, Map, SI) :- functor(S,N,A), A2 is A-2, functor(S2,N,A2), once(member(SI-S2,Map)). compile_trace(Trace, Emissions) :- user:hmm_domain(Domain), (atom(Domain) -> hmm:cvt_vals(Domain, Vals) ; Vals = Domain ), compile_trace(Trace, Vals, Emissions). compile_trace([], _, []). compile_trace([El|Trace], Vals, [N|Emissions]) :- once(nth(N, Vals, El)), compile_trace(Trace, Vals, Emissions). compiled_viterbi(Nodes, S, Commands, Input, Trace, L) :- length(Input,L), prolog_flag(min_tagged_integer, Min), matrix_new_set(ints,[Nodes], Min, Current), matrix_new_set(ints,[Nodes], Min, Next), L1 is L+1, matrix_new(ints,[L1,Nodes], Trace), matrix_set(Current, [S], 0), run_commands(Input, Commands, 0, Current, Next, Trace, Min). run_commands([], _, _, _, _, _, _). run_commands([E|Input], Commands, I, Current, Next, Trace, Min) :- run_code(Commands, E, I, Current, Next, Trace), matrix_get(Current, [32], M10), matrix_get(Current, [34], C), matrix_set_all(Current,Min), I1 is I+1, run_commands(Input, Commands, I1, Next, Current, Trace, Min). run_code([], _, _, _, _, Trace). run_code([Inst|Input], E, I, Current, Next, Trace) :- run_inst(Inst, E, I, Current, Next, Trace) , run_code(Input, E, I, Current, Next, Trace). run_inst(emit(Id,T), E, _SP, Current, _, Trace) :- arg(E,T,P), matrix_add(Current, [Id], P). run_inst(prop_same(I,P,Prob), _, SP, Current, _, Trace) :- matrix_get(Current, [I], PI), NP is PI+Prob, matrix_get(Current, [P], P0), (NP > P0 -> matrix_set(Current, [P], NP), matrix_set(Trace, [SP,P], I) ; true ). run_inst(prop_next(I,P,Prob), _, SP, Current, Next, Trace) :- matrix_get(Current, [I], PI), NP is PI+Prob, matrix_get(Next, [P], P0), (NP > P0 -> matrix_set(Next, [P], NP), SP1 is SP+1, IN is -I, matrix_set(Trace, [SP1,P], IN) ; true ). backtrace(Dump, EI, Map, L, Trace) :- L1 is L-1, Pos = [L1,EI], matrix_get(Dump,Pos,Next), trace(L1,Next,Dump,Map,[],Trace). trace(0,0,_,_,Trace,Trace) :- !. trace(L1,Next,Dump,Map,Trace0,Trace) :- (Next < 0 -> NL is L1-1, P is -Next ; NL = L1, P = Next ), once(member(P-AKey,Map)), AKey=..[N|Args], Key=..[N,NL|Args], matrix_get(Dump,[NL,P],New), trace(NL,New,Dump,Map,[Key|Trace0],Trace).