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////TODO: keep model state in forest?
//TODO: (for many nonterminals, or multi-rescoring pass) either global
//best-first, or group by (NT,span) - use prev forest outside as a (admissable,
//if models are a subset and weights are same) heuristic
#include "apply_models.h"
#include <vector>
#include <algorithm>
#include <tr1/unordered_map>
#include <tr1/unordered_set>
#include <boost/functional/hash.hpp>
#include "hg.h"
#include "ff.h"
using namespace std;
using namespace std::tr1;
struct Candidate;
typedef SmallVectorInt JVector;
typedef vector<Candidate*> CandidateHeap;
typedef vector<Candidate*> CandidateList;
// default vector size (* sizeof string is memory used)
static const size_t kRESERVE_NUM_NODES = 500000ul;
// life cycle: candidates are created, placed on the heap
// and retrieved by their estimated cost, when they're
// retrieved, they're incorporated into the +LM hypergraph
// where they also know the head node index they are
// attached to. After they are added to the +LM hypergraph
// vit_prob_ and est_prob_ fields may be updated as better
// derivations are found (this happens since the successor's
// of derivation d may have a better score- they are
// explored lazily). However, the updates don't happen
// when a candidate is in the heap so maintaining the heap
// property is not an issue.
struct Candidate {
int node_index_; // -1 until incorporated
// into the +LM forest
const Hypergraph::Edge* in_edge_; // in -LM forest
Hypergraph::Edge out_edge_;
string state_;
const JVector j_;
prob_t vit_prob_; // these are fixed until the cand
// is popped, then they may be updated
prob_t est_prob_;
Candidate(const Hypergraph::Edge& e,
const JVector& j,
const Hypergraph& out_hg,
const vector<CandidateList>& D,
const vector<string>& node_states,
const SentenceMetadata& smeta,
const ModelSet& models,
bool is_goal) :
node_index_(-1),
in_edge_(&e),
j_(j) {
InitializeCandidate(out_hg, smeta, D, node_states, models, is_goal);
}
// used to query uniqueness
Candidate(const Hypergraph::Edge& e,
const JVector& j) : in_edge_(&e), j_(j) {}
bool IsIncorporatedIntoHypergraph() const {
return node_index_ >= 0;
}
void InitializeCandidate(const Hypergraph& out_hg,
const SentenceMetadata& smeta,
const vector<vector<Candidate*> >& D,
const vector<string>& node_states,
const ModelSet& models,
const bool is_goal) {
const Hypergraph::Edge& in_edge = *in_edge_;
out_edge_.rule_ = in_edge.rule_;
out_edge_.feature_values_ = in_edge.feature_values_;
out_edge_.i_ = in_edge.i_;
out_edge_.j_ = in_edge.j_;
out_edge_.prev_i_ = in_edge.prev_i_;
out_edge_.prev_j_ = in_edge.prev_j_;
Hypergraph::TailNodeVector& tail = out_edge_.tail_nodes_;
tail.resize(j_.size());
prob_t p = prob_t::One();
// cerr << "\nEstimating application of " << in_edge.rule_->AsString() << endl;
for (int i = 0; i < tail.size(); ++i) {
const Candidate& ant = *D[in_edge.tail_nodes_[i]][j_[i]];
assert(ant.IsIncorporatedIntoHypergraph());
tail[i] = ant.node_index_;
p *= ant.vit_prob_;
}
prob_t edge_estimate = prob_t::One();
if (is_goal) {
assert(tail.size() == 1);
const string& ant_state = node_states[tail.front()];
models.AddFinalFeatures(ant_state, &out_edge_, smeta);
} else {
models.AddFeaturesToEdge(smeta, out_hg, node_states, &out_edge_, &state_, &edge_estimate);
}
vit_prob_ = out_edge_.edge_prob_ * p;
est_prob_ = vit_prob_ * edge_estimate;
}
};
ostream& operator<<(ostream& os, const Candidate& cand) {
os << "CAND[";
if (!cand.IsIncorporatedIntoHypergraph()) { os << "PENDING "; }
else { os << "+LM_node=" << cand.node_index_; }
os << " edge=" << cand.in_edge_->id_;
os << " j=<";
for (int i = 0; i < cand.j_.size(); ++i)
os << (i==0 ? "" : " ") << cand.j_[i];
os << "> vit=" << log(cand.vit_prob_);
os << " est=" << log(cand.est_prob_);
return os << ']';
}
struct HeapCandCompare {
bool operator()(const Candidate* l, const Candidate* r) const {
return l->est_prob_ < r->est_prob_;
}
};
struct EstProbSorter {
bool operator()(const Candidate* l, const Candidate* r) const {
return l->est_prob_ > r->est_prob_;
}
};
// the same candidate <edge, j> can be added multiple times if
// j is multidimensional (if you're going NW in Manhattan, you
// can first go north, then west, or you can go west then north)
// this is a hash function on the relevant variables from
// Candidate to enforce this.
struct CandidateUniquenessHash {
size_t operator()(const Candidate* c) const {
size_t x = 5381;
x = ((x << 5) + x) ^ c->in_edge_->id_;
for (int i = 0; i < c->j_.size(); ++i)
x = ((x << 5) + x) ^ c->j_[i];
return x;
}
};
struct CandidateUniquenessEquals {
bool operator()(const Candidate* a, const Candidate* b) const {
return (a->in_edge_ == b->in_edge_) && (a->j_ == b->j_);
}
};
typedef unordered_set<const Candidate*, CandidateUniquenessHash, CandidateUniquenessEquals> UniqueCandidateSet;
typedef unordered_map<string, Candidate*, boost::hash<string> > State2Node;
class CubePruningRescorer {
public:
CubePruningRescorer(const ModelSet& m,
const SentenceMetadata& sm,
const Hypergraph& i,
int pop_limit,
Hypergraph* o) :
models(m),
smeta(sm),
in(i),
out(*o),
D(in.nodes_.size()),
pop_limit_(pop_limit) {
cerr << " Applying feature functions (cube pruning, pop_limit = " << pop_limit_ << ')' << endl;
node_states_.reserve(kRESERVE_NUM_NODES);
}
void Apply() {
int num_nodes = in.nodes_.size();
int goal_id = num_nodes - 1;
int pregoal = goal_id - 1;
int every = 1;
if (num_nodes > 100) every = 10;
assert(in.nodes_[pregoal].out_edges_.size() == 1);
cerr << " ";
for (int i = 0; i < in.nodes_.size(); ++i) {
if (i % every == 0) cerr << '.';
KBest(i, i == goal_id);
}
cerr << endl;
cerr << " Best path: " << log(D[goal_id].front()->vit_prob_)
<< "\t" << log(D[goal_id].front()->est_prob_) << endl;
out.PruneUnreachable(D[goal_id].front()->node_index_);
FreeAll();
}
private:
void FreeAll() {
for (int i = 0; i < D.size(); ++i) {
CandidateList& D_i = D[i];
for (int j = 0; j < D_i.size(); ++j)
delete D_i[j];
}
D.clear();
}
void IncorporateIntoPlusLMForest(Candidate* item, State2Node* s2n, CandidateList* freelist) {
Hypergraph::Edge* new_edge = out.AddEdge(item->out_edge_.rule_, item->out_edge_.tail_nodes_);
new_edge->feature_values_ = item->out_edge_.feature_values_;
new_edge->edge_prob_ = item->out_edge_.edge_prob_;
new_edge->i_ = item->out_edge_.i_;
new_edge->j_ = item->out_edge_.j_;
new_edge->prev_i_ = item->out_edge_.prev_i_;
new_edge->prev_j_ = item->out_edge_.prev_j_;
Candidate*& o_item = (*s2n)[item->state_];
if (!o_item) o_item = item;
int& node_id = o_item->node_index_;
if (node_id < 0) {
Hypergraph::Node* new_node = out.AddNode(in.nodes_[item->in_edge_->head_node_].cat_);
node_states_.push_back(item->state_);
node_id = new_node->id_;
}
Hypergraph::Node* node = &out.nodes_[node_id];
out.ConnectEdgeToHeadNode(new_edge, node);
// update candidate if we have a better derivation
// note: the difference between the vit score and the estimated
// score is the same for all items with a common residual DP
// state
if (item->vit_prob_ > o_item->vit_prob_) {
assert(o_item->state_ == item->state_); // sanity check!
o_item->est_prob_ = item->est_prob_;
o_item->vit_prob_ = item->vit_prob_;
}
if (item != o_item) freelist->push_back(item);
}
void KBest(const int vert_index, const bool is_goal) {
// cerr << "KBest(" << vert_index << ")\n";
CandidateList& D_v = D[vert_index];
assert(D_v.empty());
const Hypergraph::Node& v = in.nodes_[vert_index];
// cerr << " has " << v.in_edges_.size() << " in-coming edges\n";
const vector<int>& in_edges = v.in_edges_;
CandidateHeap cand;
CandidateList freelist;
cand.reserve(in_edges.size());
UniqueCandidateSet unique_cands;
for (int i = 0; i < in_edges.size(); ++i) {
const Hypergraph::Edge& edge = in.edges_[in_edges[i]];
const JVector j(edge.tail_nodes_.size(), 0);
cand.push_back(new Candidate(edge, j, out, D, node_states_, smeta, models, is_goal));
assert(unique_cands.insert(cand.back()).second); // these should all be unique!
}
// cerr << " making heap of " << cand.size() << " candidates\n";
make_heap(cand.begin(), cand.end(), HeapCandCompare());
State2Node state2node; // "buf" in Figure 2
int pops = 0;
int pop_limit_eff=max(1,int(v.promise*pop_limit_));
while(!cand.empty() && pops < pop_limit_eff) {
pop_heap(cand.begin(), cand.end(), HeapCandCompare());
Candidate* item = cand.back();
cand.pop_back();
// cerr << "POPPED: " << *item << endl;
PushSucc(*item, is_goal, &cand, &unique_cands);
IncorporateIntoPlusLMForest(item, &state2node, &freelist);
++pops;
}
D_v.resize(state2node.size());
int c = 0;
for (State2Node::iterator i = state2node.begin(); i != state2node.end(); ++i)
D_v[c++] = i->second;
sort(D_v.begin(), D_v.end(), EstProbSorter());
// cerr << " expanded to " << D_v.size() << " nodes\n";
for (int i = 0; i < cand.size(); ++i)
delete cand[i];
// freelist is necessary since even after an item merged, it still stays in
// the unique set so it can't be deleted til now
for (int i = 0; i < freelist.size(); ++i)
delete freelist[i];
}
void PushSucc(const Candidate& item, const bool is_goal, CandidateHeap* pcand, UniqueCandidateSet* cs) {
CandidateHeap& cand = *pcand;
for (int i = 0; i < item.j_.size(); ++i) {
JVector j = item.j_;
++j[i];
if (j[i] < D[item.in_edge_->tail_nodes_[i]].size()) {
Candidate query_unique(*item.in_edge_, j);
if (cs->count(&query_unique) == 0) {
Candidate* new_cand = new Candidate(*item.in_edge_, j, out, D, node_states_, smeta, models, is_goal);
cand.push_back(new_cand);
push_heap(cand.begin(), cand.end(), HeapCandCompare());
assert(cs->insert(new_cand).second); // insert into uniqueness set, sanity check
}
}
}
}
const ModelSet& models;
const SentenceMetadata& smeta;
const Hypergraph& in;
Hypergraph& out;
vector<CandidateList> D; // maps nodes in in-HG to the
// equivalent nodes (many due to state
// splits) in the out-HG.
vector<string> node_states_; // for each node in the out-HG what is
// its q function value?
const int pop_limit_;
};
struct NoPruningRescorer {
NoPruningRescorer(const ModelSet& m, const SentenceMetadata &sm, const Hypergraph& i, Hypergraph* o) :
models(m),
smeta(sm),
in(i),
out(*o),
nodemap(i.nodes_.size()) {
cerr << " Rescoring forest (full intersection)\n";
node_states_.reserve(kRESERVE_NUM_NODES);
}
typedef unordered_map<string, int, boost::hash<string> > State2NodeIndex;
void ExpandEdge(const Hypergraph::Edge& in_edge, bool is_goal, State2NodeIndex* state2node) {
const int arity = in_edge.Arity();
Hypergraph::TailNodeVector ends(arity);
for (int i = 0; i < arity; ++i)
ends[i] = nodemap[in_edge.tail_nodes_[i]].size();
Hypergraph::TailNodeVector tail_iter(arity, 0);
bool done = false;
while (!done) {
Hypergraph::TailNodeVector tail(arity);
for (int i = 0; i < arity; ++i)
tail[i] = nodemap[in_edge.tail_nodes_[i]][tail_iter[i]];
Hypergraph::Edge* new_edge = out.AddEdge(in_edge.rule_, tail);
new_edge->feature_values_ = in_edge.feature_values_;
new_edge->i_ = in_edge.i_;
new_edge->j_ = in_edge.j_;
new_edge->prev_i_ = in_edge.prev_i_;
new_edge->prev_j_ = in_edge.prev_j_;
string head_state;
if (is_goal) {
assert(tail.size() == 1);
const string& ant_state = node_states_[tail.front()];
models.AddFinalFeatures(ant_state, new_edge,smeta);
} else {
prob_t edge_estimate; // this is a full intersection, so we disregard this
models.AddFeaturesToEdge(smeta, out, node_states_, new_edge, &head_state, &edge_estimate);
}
int& head_plus1 = (*state2node)[head_state];
if (!head_plus1) {
head_plus1 = out.AddNode(in_edge.rule_->GetLHS())->id_ + 1;
node_states_.push_back(head_state);
nodemap[in_edge.head_node_].push_back(head_plus1 - 1);
}
const int head_index = head_plus1 - 1;
out.ConnectEdgeToHeadNode(new_edge->id_, head_index);
int ii = 0;
for (; ii < arity; ++ii) {
++tail_iter[ii];
if (tail_iter[ii] < ends[ii]) break;
tail_iter[ii] = 0;
}
done = (ii == arity);
}
}
void ProcessOneNode(const int node_num, const bool is_goal) {
State2NodeIndex state2node;
const Hypergraph::Node& node = in.nodes_[node_num];
for (int i = 0; i < node.in_edges_.size(); ++i) {
const Hypergraph::Edge& edge = in.edges_[node.in_edges_[i]];
ExpandEdge(edge, is_goal, &state2node);
}
}
void Apply() {
int num_nodes = in.nodes_.size();
int goal_id = num_nodes - 1;
int pregoal = goal_id - 1;
int every = 1;
if (num_nodes > 100) every = 10;
assert(in.nodes_[pregoal].out_edges_.size() == 1);
cerr << " ";
for (int i = 0; i < in.nodes_.size(); ++i) {
if (i % every == 0) cerr << '.';
ProcessOneNode(i, i == goal_id);
}
cerr << endl;
}
private:
const ModelSet& models;
const SentenceMetadata& smeta;
const Hypergraph& in;
Hypergraph& out;
vector<vector<int> > nodemap;
vector<string> node_states_; // for each node in the out-HG what is
// its q function value?
};
// each node in the graph has one of these, it keeps track of
void ApplyModelSet(const Hypergraph& in,
const SentenceMetadata& smeta,
const ModelSet& models,
const IntersectionConfiguration& config,
Hypergraph* out) {
//force exhaustive if there's no state req. for model
if (models.stateless() || config.algorithm == 0) {
NoPruningRescorer ma(models, smeta, in, out); // avoid overhead of best-first when no state
ma.Apply();
} else if (config.algorithm == 1) {
int pl = config.pop_limit;
const int max_pl_for_large=50;
if (pl > max_pl_for_large && in.nodes_.size() > 80000) {
pl = max_pl_for_large;
cerr << " Note: reducing pop_limit to " << pl << " for very large forest\n";
}
CubePruningRescorer ma(models, smeta, in, pl, out);
ma.Apply();
} else {
cerr << "Don't understand intersection algorithm " << config.algorithm << endl;
exit(1);
}
out->is_linear_chain_ = in.is_linear_chain_; // TODO remove when this is computed
// automatically
}
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