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#ifndef FF_FROM_FSA_H
#define FF_FROM_FSA_H
#include "ff_fsa.h"
#define FSA_FF_DEBUG 0
#if FSA_FF_DEBUG
# define FSAFFDBG(e,x) FSADBGif(debug,e,x)
# define FSAFFDBGnl(e) FSADBGif_nl(debug,e)
#else
# define FSAFFDBG(e,x)
# define FSAFFDBGnl(e)
#endif
/* regular bottom up scorer from Fsa feature
uses guarantee about markov order=N to score ASAP
encoding of state: if less than N-1 (ctxlen) words
either:
struct FF : public FsaImpl,FeatureFunctionFromFsa<FF> (more efficient)
or:
struct FF : public FsaFeatureFunctionDynamic,FeatureFunctionFromFsa<FF> (code sharing, but double dynamic dispatch)
*/
template <class Impl>
class FeatureFunctionFromFsa : public FeatureFunction {
typedef void const* SP;
typedef WordID *W;
typedef WordID const* WP;
public:
FeatureFunctionFromFsa(std::string const& param) : ff(param) {
debug=true; // because factory won't set until after we construct.
Init();
}
static std::string usage(bool args,bool verbose) {
return Impl::usage(args,verbose);
}
Features features() const { return ff.features(); }
//TODO: add source span to Fsa FF interface, pass along
//TODO: read/debug VERY CAREFULLY
void TraversalFeaturesLog(const SentenceMetadata& smeta,
Hypergraph::Edge& edge,
const std::vector<const void*>& ant_contexts,
FeatureVector* features,
FeatureVector* estimated_features,
void* out_state) const
{
ff.init_features(features); // estimated_features is fresh
if (!ssz) {
TRule const& rule=*edge.rule_;
Sentence const& e = rule.e();
for (int j = 0; j < e.size(); ++j) { // items in target side of rule
if (e[j] < 1) { // variable
} else {
WordID ew=e[j];
FSAFFDBG(edge,' '<<TD::Convert(ew));
ff.Scan(smeta,edge,ew,0,0,features);
}
}
FSAFFDBGnl(edge);
return;
}
SP h_start=ff.heuristic_start_state();
W left_begin=(W)out_state;
W left_out=left_begin; // [left,fsa_state) = left ctx words. if left words aren't full, then null wordid
WP left_full=left_end_full(out_state);
FsaScanner<Impl> fsa(ff,smeta,edge);
TRule const& rule=*edge.rule_;
Sentence const& e = rule.e();
for (int j = 0; j < e.size(); ++j) { // items in target side of rule
if (e[j] < 1) { // variable
SP a = ant_contexts[-e[j]];
FSAFFDBG(edge,' '<<describe_state(a));
WP al=(WP)a;
WP ale=left_end(a);
// scan(al,le) these - the same as below else. macro for now; pull into closure object later?
int nw=ale-al; // this many new words
if (left_out+nw<left_full) { // nothing to score after adding
wordcpy(left_out,al,nw);
left_out+=nw;
} else if (left_out<left_full) { // something to score AND newly full left context to fill
int ntofill=left_full-left_out;
assert(ntofill==M-(left_out-left_begin));
wordcpy(left_out,al,ntofill);
left_out=(W)left_full;
// heuristic known now
fsa.reset(h_start);
fsa.scan(left_begin,left_full,estimated_features); // save heuristic (happens once only)
fsa.scan(al+ntofill,ale,features);
al+=ntofill; // we used up the first ntofill words of al to end up in some known state via exactly M words total (M-ntofill were there beforehand). now we can scan the remaining al words of this child
} else { // more to score / state to update (left already full)
fsa.scan(al,ale,features);
}
if (nw==M) // child had full state already
fsa.reset(fsa_state(a));
assert(nw<=M);
} else { // single word
WordID ew=e[j];
FSAFFDBG(edge,' '<<TD::Convert(ew));
// some redundancy: non-vectorized version of above handling of left words of child item
if (left_out<left_full) {
*left_out++=ew;
if (left_out==left_full) { // handle heuristic, once only, establish state
fsa.reset(h_start);
fsa.scan(left_begin,left_full,estimated_features); // save heuristic (happens only once)
}
} else
fsa.scan(ew,features);
}
}
if (left_out<left_full) { // finally: partial heuristic foru nfilled items
fsa.reset(h_start);
fsa.scan(left_begin,left_out,estimated_features);
clear_fsa_state(out_state); // 0 bytes so we compare / hash correctly. don't know state yet
do { *left_out++=TD::none; } while(left_out<left_full); // none-terminate so left_end(out_state) will know how many words
} else // or else store final right-state. heuristic was already assigned
fstatecpy(out_state,fsa.cs);
FSAFFDBG(edge," = " << describe_state(out_state)<<" "<<name<<"="<<ff.describe_features(*features)<<" h="<<ff.describe_features(*estimated_features)<<")");
FSAFFDBGnl(edge);
}
void print_state(std::ostream &o,void const*ant) const {
WP l=(WP)ant,le=left_end(ant),lf=left_end_full(ant);
o<<'['<<Sentence(l,le);
if (le==lf) {
o<<" : ";
ff.print_state(o,lf);
}
o << ']';
}
std::string describe_state(void const*ant) const {
std::ostringstream o;
print_state(o,ant);
return o.str();
}
//FIXME: it's assumed that the final rule is just a unary no-target-terminal rewrite (same as ff_lm)
virtual void FinalTraversalFeatures(const SentenceMetadata& smeta,
Hypergraph::Edge& edge,
const void* residual_state,
FeatureVector* final_features) const
{
ff.init_features(final_features);
Sentence const& ends=ff.end_phrase();
if (!ssz) {
AccumFeatures(ff,smeta,edge,begin(ends),end(ends),final_features,0);
return;
}
SP ss=ff.start_state();
WP l=(WP)residual_state,lend=left_end(residual_state);
SP rst=fsa_state(residual_state);
FSAFFDBG(edge," (final");// "<<name);//<< " before="<<*final_features);
if (lend==rst) { // implying we have an fsa state
AccumFeatures(ff,smeta,edge,l,lend,final_features,ss); // e.g. <s> score(full left unscored phrase)
FSAFFDBG(edge," start="<<ff.describe_state(ss)<<"->{"<<Sentence(l,lend)<<"}");
AccumFeatures(ff,smeta,edge,begin(ends),end(ends),final_features,rst); // e.g. [ctx for last M words] score("</s>")
FSAFFDBG(edge," end="<<ff.describe_state(rst)<<"->{"<<ends<<"}");
} else { // all we have is a single short phrase < M words before adding ends
int nl=lend-l;
Sentence whole(ends.size()+nl);
WordID *w=begin(whole);
wordcpy(w,l,nl);
wordcpy(w+nl,begin(ends),ends.size());
FSAFFDBG(edge," whole={"<<whole<<"}");
// whole = left-words + end-phrase
AccumFeatures(ff,smeta,edge,w,end(whole),final_features,ss);
}
FSAFFDBG(edge,' '<<name<<"="<<ff.describe_features(*final_features));
FSAFFDBGnl(edge);
}
bool rule_feature() const {
return StateSize()==0; // Fsa features don't get info about span
}
static void test() {
WordID w1[1],w1b[1],w2[2];
w1[0]=w2[0]=TD::Convert("hi");
w2[1]=w1b[0]=TD::none;
assert(left_end(w1,w1+1)==w1+1);
assert(left_end(w1b,w1b+1)==w1b);
assert(left_end(w2,w2+2)==w2+1);
}
private:
Impl ff;
void Init() {
// FeatureFunction::name=Impl::usage(false,false); // already achieved by ff_factory.cc
M=ff.markov_order();
ssz=ff.state_bytes();
state_offset=sizeof(WordID)*M;
SetStateSize(ssz+state_offset);
assert(!ssz == !M); // no fsa state <=> markov order 0
}
int M; // markov order (ctx len)
FeatureFunctionFromFsa(); // not allowed.
int state_offset; // NOTE: in bytes (add to char* only). store left-words first, then fsa state
int ssz; // bytes in fsa state
/*
state layout: left WordIds, followed by fsa state
left words have never been scored. last ones remaining will be scored on FinalTraversalFeatures only.
right state is unknown until we have all M left words (less than M means TD::none will pad out right end). unk right state will be zeroed out for proper hash/equal recombination.
*/
static inline WordID const* left_end(WordID const* left, WordID const* e) {
for (;e>left;--e)
if (e[-1]!=TD::none) break;
//post: [left,e] are the seen left words
return e;
}
inline WP left_end(SP ant) const {
return left_end((WP)ant,(WP)fsa_state(ant));
}
inline WP left_end_full(SP ant) const {
return (WP)fsa_state(ant);
}
inline SP fsa_state(SP ant) const {
return ((char const*)ant+state_offset);
}
inline void *fsa_state(void * ant) const {
return ((char *)ant+state_offset);
}
void clear_fsa_state(void *ant) const { // when state is unknown
std::memset(fsa_state(ant),0,ssz);
}
inline void fstatecpy(void *ant,void const* src) const {
std::memcpy(fsa_state(ant),src,ssz);
}
};
#ifdef TEST_FSA
# include "tdict.cc"
# include "ff_sample_fsa.h"
int main() {
std::cerr<<"Testing left_end...\n";
std::cerr<<"sizeof(FeatureVector)="<<sizeof(FeatureVector)<<"\nsizeof(FeatureVectorList)="<<sizeof(FeatureVectorList)<<"\n";
WordPenaltyFromFsa::test();
return 0;
}
#endif
#endif
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