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#include "apply_fsa_models.h"
#include "hg.h"
#include "ff_fsa_dynamic.h"
#include "ff_from_fsa.h"
#include "feature_vector.h"
#include "stringlib.h"
#include "apply_models.h"
#include <stdexcept>
#include <cassert>
#include "cfg.h"
#include "hg_cfg.h"
#include "utoa.h"
#include "hash.h"
#include "value_array.h"
#define DFSA(x) x
#define DPFSA(x) x
using namespace std;
//impl details (not exported). flat namespace for my ease.
typedef CFG::BinRhs BinRhs;
typedef CFG::NTs NTs;
typedef CFG::NT NT;
typedef CFG::NTHandle NTHandle;
typedef CFG::Rules Rules;
typedef CFG::Rule Rule;
typedef CFG::RuleHandle RuleHandle;
namespace {
/*
1) A -> x . * (trie)
this is somewhat nice. cost pushed for best first, of course. similar benefit as left-branching binarization without the explicit predict/complete steps?
vs. just
2) * -> x . y
here you have to potentially list out all A -> . x y as items * -> . x y immediately, and shared rhs seqs won't be shared except at the usual single-NT predict/complete. of course, the prediction of items -> . x y can occur lazy best-first.
vs.
3) * -> x . *
with 3, we predict all sorts of useless items - that won't give us our goal A and may not partcipate in any parse. this is not a good option at all.
*/
#define TRIE_START_LHS 1
// option 1) above. 0 would be option 3), which is dumb
// if we don't greedy-binarize, we want to encode recognized prefixes p (X -> p . rest) efficiently. if we're doing this, we may as well also push costs so we can best-first select rules in a lazy fashion. this is effectively left-branching binarization, of course.
template <class K,class V,class Hash>
struct fsa_map_type {
typedef std::map<K,V> type;
};
//template typedef
#define FSA_MAP(k,v) fsa_map_type<k,v,boost::hash<k> >::type
typedef WordID LHS; // so this will be -NTHandle.
struct PrefixTrieNode {
prob_t backward; // (viterbi) backward prob (for cost pushing)
#
#if TRIE_START_LHS
typedef FSA_MAP(LHS,RuleHandle) Completed; // can only have one rule w/ a given signature (duplicates should be collapsed when making CFG). but there may be multiple rules, with different LHS
Completed completed;
#else
bool complete; // may also have successors, of course
#endif
// instead of completed map, we have trie start w/ lhs.?
// outgoing edges will be ordered highest p to worst p
struct Edge {
DPFSA(prob_t p;) // we can probably just store deltas, but for debugging remember the full p
prob_t delta; // p[i]=delta*p[i-1], with p(-1)=1
PrefixTrieNode *dest;
WordID w;
};
typedef FSA_MAP(WordID,Edge) BuildAdj;
BuildAdj build_adj; //TODO: move builder elsewhere?
typedef ValueArray<Edge> Adj;
// typedef vector<Edge> Adj;
Adj adj;
//TODO:
};
#if TRIE_START_LHS
//Trie starts with lhs, then continues w/ rhs
#else
// just rhs. i think item names should exclude lhs if possible (most sharing). get prefix cost w/ forward = viterbi (global best-first admissable h only) and it should be ok?
#endif
// costs are pushed.
struct PrefixTrie {
CFG const* cfgp;
CFG const& cfg() const { return *cfgp; }
PrefixTrie(CFG const& cfg) : cfgp(&cfg) {
//TODO:
}
};
// these should go in a global best-first queue
struct Item {
prob_t forward;
/* The forward probability alpha_i(X[k]->x.y) is the sum of the probabilities of all
constrained paths of length that end in state X[k]->x.y*/
prob_t inner;
/* The inner probability beta_i(X[k]->x.y) is the sum of the probabilities of all
paths of length i-k that start in state X[k,k]->.xy and end in X[k,i]->x.y, and generate the input symbols x[k,...,i-1] */
};
}//anon ns
DEFINE_NAMED_ENUM(FSA_BY)
struct ApplyFsa {
ApplyFsa(HgCFG &i,
const SentenceMetadata& smeta,
const FsaFeatureFunction& fsa,
DenseWeightVector const& weights,
ApplyFsaBy const& by,
Hypergraph* oh
)
:hgcfg(i),smeta(smeta),fsa(fsa),weights(weights),by(by),oh(oh)
{
}
void Compute() {
if (by.IsBottomUp())
ApplyBottomUp();
else
ApplyEarley();
}
void ApplyBottomUp();
void ApplyEarley();
CFG const& GetCFG();
private:
CFG cfg;
HgCFG &hgcfg;
const SentenceMetadata& smeta;
const FsaFeatureFunction& fsa;
// WeightVector weight_vector;
DenseWeightVector weights;
ApplyFsaBy by;
Hypergraph* oh;
std::string cfg_out;
};
void ApplyFsa::ApplyBottomUp()
{
assert(by.IsBottomUp());
FeatureFunctionFromFsa<FsaFeatureFunctionFwd> buff(&fsa);
buff.Init(); // mandatory to call this (normally factory would do it)
vector<const FeatureFunction*> ffs(1,&buff);
ModelSet models(weights, ffs);
IntersectionConfiguration i(by.BottomUpAlgorithm(),by.pop_limit);
ApplyModelSet(hgcfg.ih,smeta,models,i,oh);
}
void ApplyFsa::ApplyEarley()
{
hgcfg.GiveCFG(cfg);
cfg.SortLocalBestFirst();
// don't need to uniq - option to do that already exists in cfg_options
//TODO:
}
void ApplyFsaModels(HgCFG &i,
const SentenceMetadata& smeta,
const FsaFeatureFunction& fsa,
DenseWeightVector const& weight_vector,
ApplyFsaBy const& by,
Hypergraph* oh)
{
ApplyFsa a(i,smeta,fsa,weight_vector,by,oh);
a.Compute();
}
/*
namespace {
char const* anames[]={
"BU_CUBE",
"BU_FULL",
"EARLEY",
0
};
}
*/
//TODO: named enum type in boost?
std::string ApplyFsaBy::name() const {
// return anames[algorithm];
return GetName(algorithm);
}
std::string ApplyFsaBy::all_names() {
return FsaByNames(" ");
/*
std::ostringstream o;
for (int i=0;i<N_ALGORITHMS;++i) {
assert(anames[i]);
if (i) o<<' ';
o<<anames[i];
}
return o.str();
*/
}
ApplyFsaBy::ApplyFsaBy(std::string const& n, int pop_limit) : pop_limit(pop_limit) {
std::string uname=toupper(n);
algorithm=GetFsaBy(uname);
/*anames=0;
while(anames[algorithm] && anames[algorithm] != uname) ++algorithm;
if (!anames[algorithm])
throw std::runtime_error("Unknown ApplyFsaBy type: "+n+" - legal types: "+all_names());
*/
}
ApplyFsaBy::ApplyFsaBy(FsaBy i, int pop_limit) : pop_limit(pop_limit) {
/* if (i<0 || i>=N_ALGORITHMS)
throw std::runtime_error("Unknown ApplyFsaBy type id: "+itos(i)+" - legal types: "+all_names());
*/
GetName(i); // checks validity
algorithm=i;
}
int ApplyFsaBy::BottomUpAlgorithm() const {
assert(IsBottomUp());
return algorithm==BU_CUBE ?
IntersectionConfiguration::CUBE
:IntersectionConfiguration::FULL;
}
void ApplyFsaModels(Hypergraph const& ih,
const SentenceMetadata& smeta,
const FsaFeatureFunction& fsa,
DenseWeightVector const& weights, // pre: in is weighted by these (except with fsa featval=0 before this)
ApplyFsaBy const& cfg,
Hypergraph* out)
{
HgCFG i(ih);
ApplyFsaModels(i,smeta,fsa,weights,cfg,out);
}
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