diff options
author | Chris Dyer <cdyer@cs.cmu.edu> | 2012-08-12 23:33:21 -0400 |
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committer | Chris Dyer <cdyer@cs.cmu.edu> | 2012-08-12 23:33:21 -0400 |
commit | da176941c1f481f14e93bd7d055cc29cac0ea8c8 (patch) | |
tree | c7ec8c0f75b386e6ca6d37da830e5a2e369b1cca /extools/extract.cc | |
parent | 4760209baa483403db3bcb9bf1a32ae87a7b576d (diff) |
use new union api
Diffstat (limited to 'extools/extract.cc')
-rw-r--r-- | extools/extract.cc | 336 |
1 files changed, 0 insertions, 336 deletions
diff --git a/extools/extract.cc b/extools/extract.cc deleted file mode 100644 index 49542fed..00000000 --- a/extools/extract.cc +++ /dev/null @@ -1,336 +0,0 @@ -#include "extract.h" - -#include <queue> -#include <vector> -#include <utility> -#include <tr1/unordered_map> -#include <set> -#include <boost/tuple/tuple_comparison.hpp> - -#include <boost/functional/hash.hpp> -#include <boost/tuple/tuple.hpp> - -#include "sentence_pair.h" -#include "tdict.h" -#include "wordid.h" -#include "array2d.h" - -using namespace std; -using namespace boost; -using std::tr1::unordered_map; -using boost::tuple; - -namespace { - inline bool IsWhitespace(char c) { return c == ' ' || c == '\t'; } - - inline void SkipWhitespace(const char* buf, int* ptr) { - while (buf[*ptr] && IsWhitespace(buf[*ptr])) { ++(*ptr); } - } -} - -Extract::RuleObserver::~RuleObserver() { - cerr << "Rules extracted: " << count << endl; -} - -void Extract::ExtractBasePhrases(const int max_base_phrase_size, - const AnnotatedParallelSentence& sentence, - vector<ParallelSpan>* phrases) { - phrases->clear(); - - vector<pair<int,int> > f_spans(sentence.f_len, pair<int,int>(sentence.e_len, 0)); - vector<pair<int,int> > e_spans(sentence.e_len, pair<int,int>(sentence.f_len, 0)); - // for each alignment point in e, precompute the minimal consistent phrases in f - // for each alignment point in f, precompute the minimal consistent phrases in e - for (int i = 0; i < sentence.f_len; ++i) { - for (int j = 0; j < sentence.e_len; ++j) { - if (sentence.aligned(i,j)) { - if (j < f_spans[i].first) f_spans[i].first = j; - f_spans[i].second = j+1; - if (i < e_spans[j].first) e_spans[j].first = i; - e_spans[j].second = i+1; - } - } - } - - for (int i1 = 0; i1 < sentence.f_len; ++i1) { - if (sentence.f_aligned[i1] == 0) continue; - int j1 = sentence.e_len; - int j2 = 0; - const int i_limit = min(sentence.f_len, i1 + max_base_phrase_size); - for (int i2 = i1 + 1; i2 <= i_limit; ++i2) { - if (sentence.f_aligned[i2-1] == 0) continue; - // cerr << "F has aligned span " << i1 << " to " << i2 << endl; - j1 = min(j1, f_spans[i2-1].first); - j2 = max(j2, f_spans[i2-1].second); - if (j1 >= j2) continue; - if (j2 - j1 > max_base_phrase_size) continue; - int condition = 0; - for (int j = j1; j < j2; ++j) { - if (e_spans[j].first < i1) { condition = 1; break; } - if (e_spans[j].second > i2) { condition = 2; break; } - } - if (condition == 1) break; - if (condition == 2) continue; - // category types added later! - phrases->push_back(ParallelSpan(i1, i2, j1, j2)); - // cerr << i1 << " " << i2 << " : " << j1 << " " << j2 << endl; - } - } -} - -void Extract::LoosenPhraseBounds(const AnnotatedParallelSentence& sentence, - const int max_base_phrase_size, - vector<ParallelSpan>* phrases) { - const int num_phrases = phrases->size(); - map<int, map<int, map<int, map<int, bool> > > > marker; - for (int i = 0; i < num_phrases; ++i) { - const ParallelSpan& cur = (*phrases)[i]; - marker[cur.i1][cur.i2][cur.j1][cur.j2] = true; - } - for (int i = 0; i < num_phrases; ++i) { - const ParallelSpan& cur = (*phrases)[i]; - const int i1_max = cur.i1; - const int i2_min = cur.i2; - const int j1_max = cur.j1; - const int j2_min = cur.j2; - int i1_min = i1_max; - while (i1_min > 0 && sentence.f_aligned[i1_min-1] == 0) { --i1_min; } - int j1_min = j1_max; - while (j1_min > 0 && sentence.e_aligned[j1_min-1] == 0) { --j1_min; } - int i2_max = i2_min; - while (i2_max < sentence.f_len && sentence.f_aligned[i2_max] == 0) { ++i2_max; } - int j2_max = j2_min; - while (j2_max < sentence.e_len && sentence.e_aligned[j2_max] == 0) { ++j2_max; } - for (int i1 = i1_min; i1 <= i1_max; ++i1) { - const int ilim = min(i2_max, i1 + max_base_phrase_size); - for (int i2 = max(i1+1,i2_min); i2 <= ilim; ++i2) { - for (int j1 = j1_min; j1 <= j1_max; ++j1) { - const int jlim = std::min(j2_max, j1 + max_base_phrase_size); - for (int j2 = std::max(j1+1, j2_min); j2 <= jlim; ++j2) { - bool& seen = marker[i1][i2][j1][j2]; - if (!seen) - phrases->push_back(ParallelSpan(i1,i2,j1,j2)); - seen = true; - } - } - } - } - } -} - -template <typename K, typename V> -void -lookup_and_append(const map<K, V> &dict, const K &key, V &output) -{ - typename map<K, V>::const_iterator found = dict.find(key); - if (found != dict.end()) - copy(found->second.begin(), found->second.end(), back_inserter(output)); -} - -// this uses the TARGET span (i,j) to annotate phrases, will copy -// phrases if there is more than one annotation. -// TODO: support source annotation -void Extract::AnnotatePhrasesWithCategoryTypes(const WordID default_cat, - const map< boost::tuple<short,short,short,short>, vector<WordID> > &types, - vector<ParallelSpan>* phrases) { - const int num_unannotated_phrases = phrases->size(); - // have to use num_unannotated_phrases since we may grow the vector - for (int i = 0; i < num_unannotated_phrases; ++i) { - ParallelSpan& phrase = (*phrases)[i]; - vector<WordID> cats; - lookup_and_append(types, boost::make_tuple(phrase.i1, phrase.i2, phrase.j1, phrase.j2), cats); - lookup_and_append(types, boost::make_tuple((short)-1, (short)-1, phrase.j1, phrase.j2), cats); - lookup_and_append(types, boost::make_tuple(phrase.i1, phrase.i2, (short)-1, (short)-1), cats); - if (cats.empty() && default_cat != 0) { - cats = vector<WordID>(1, default_cat); - } - if (cats.empty()) { - cerr << "ERROR span " << phrase.i1 << "," << phrase.i2 << "-" - << phrase.j1 << "," << phrase.j2 << " has no type. " - "Did you forget --default_category?\n"; - } - phrase.cat = cats[0]; - for (int ci = 1; ci < cats.size(); ++ci) { - ParallelSpan new_phrase = phrase; - new_phrase.cat = cats[ci]; - phrases->push_back(new_phrase); - } - } -} - -// a partially complete (f-side) of a rule -struct RuleItem { - vector<ParallelSpan> f; - int i,j,syms,vars; - explicit RuleItem(int pi) : i(pi), j(pi), syms(), vars() {} - void Extend(const WordID& fword) { - f.push_back(ParallelSpan(fword)); - ++j; - ++syms; - } - void Extend(const ParallelSpan& subphrase) { - f.push_back(subphrase); - j += subphrase.i2 - subphrase.i1; - ++vars; - ++syms; - } - bool RuleFEndsInVariable() const { - if (f.size() > 0) { - return f.back().IsVariable(); - } else { return false; } - } -}; - -void Extract::ExtractConsistentRules(const AnnotatedParallelSentence& sentence, - const vector<ParallelSpan>& phrases, - const int max_vars, - const int max_syms, - const bool permit_adjacent_nonterminals, - const bool require_aligned_terminal, - RuleObserver* observer, - vector<WordID>* all_cats) { - const char bkoff_mrkr = '_'; - queue<RuleItem> q; // agenda for BFS - int max_len = -1; - unordered_map<pair<short, short>, vector<ParallelSpan>, boost::hash<pair<short, short> > > fspans; - vector<vector<ParallelSpan> > spans_by_start(sentence.f_len); - set<int> starts; - WordID bkoff; - for (int i = 0; i < phrases.size(); ++i) { - fspans[make_pair(phrases[i].i1,phrases[i].i2)].push_back(phrases[i]); - max_len = max(max_len, phrases[i].i2 - phrases[i].i1); - // have we already added a rule item starting at phrases[i].i1? - if (starts.insert(phrases[i].i1).second) - q.push(RuleItem(phrases[i].i1)); - spans_by_start[phrases[i].i1].push_back(phrases[i]); - } - starts.clear(); - vector<pair<int,int> > next_e(sentence.e_len); - vector<WordID> cur_rhs_f, cur_rhs_e; - vector<pair<short, short> > cur_terminal_align; - vector<int> cur_es, cur_fs; - while(!q.empty()) { - const RuleItem& rule = q.front(); - - // extend the partial rule - if (rule.j < sentence.f_len && (rule.j - rule.i) < max_len && rule.syms < max_syms) { - RuleItem ew = rule; - - // extend with a word - ew.Extend(sentence.f[ew.j]); - q.push(ew); - - // with variables - if (rule.vars < max_vars && - !spans_by_start[rule.j].empty() && - ((!rule.RuleFEndsInVariable()) || permit_adjacent_nonterminals)) { - const vector<ParallelSpan>& sub_phrases = spans_by_start[rule.j]; - for (int it = 0; it < sub_phrases.size(); ++it) { - if (sub_phrases[it].i2 - sub_phrases[it].i1 + rule.j - rule.i <= max_len) { - RuleItem ev = rule; - ev.Extend(sub_phrases[it]); - q.push(ev); - assert(ev.j <= sentence.f_len); - } - } - } - } - // determine if rule is consistent - if (rule.syms > 0 && - fspans.count(make_pair(rule.i,rule.j)) && - (!rule.RuleFEndsInVariable() || rule.syms > 1)) { - const vector<ParallelSpan>& orig_spans = fspans[make_pair(rule.i,rule.j)]; - for (int s = 0; s < orig_spans.size(); ++s) { - const ParallelSpan& orig_span = orig_spans[s]; - const WordID lhs = orig_span.cat; - for (int j = orig_span.j1; j < orig_span.j2; ++j) next_e[j].first = -1; - int nt_index_e = 0; - for (int i = 0; i < rule.f.size(); ++i) { - const ParallelSpan& cur = rule.f[i]; - if (cur.IsVariable()) - next_e[cur.j1] = pair<int,int>(cur.j2, ++nt_index_e); - } - cur_rhs_f.clear(); - cur_rhs_e.clear(); - cur_terminal_align.clear(); - cur_fs.clear(); - cur_es.clear(); - - const int elen = orig_span.j2 - orig_span.j1; - vector<int> isvar(elen, 0); - int fbias = rule.i; - bool bad_rule = false; - bool has_aligned_terminal = false; - for (int i = 0; i < rule.f.size(); ++i) { - const ParallelSpan& cur = rule.f[i]; - cur_rhs_f.push_back(cur.cat); - if (cur.cat > 0) { // terminal - if (sentence.f_aligned[fbias + i]) has_aligned_terminal = true; - cur_fs.push_back(fbias + i); - } else { // non-terminal - int subj1 = cur.j1 - orig_span.j1; - int subj2 = cur.j2 - orig_span.j1; - if (subj1 < 0 || subj2 > elen) { bad_rule = true; break; } - for (int j = subj1; j < subj2 && !bad_rule; ++j) { - int& isvarj = isvar[j]; - isvarj = true; - } - if (bad_rule) break; - cur_fs.push_back(-1); - fbias += cur.i2 - cur.i1 - 1; - } - } - if (require_aligned_terminal && !has_aligned_terminal) bad_rule = true; - if (!bad_rule) { - for (int j = orig_span.j1; j < orig_span.j2; ++j) { - if (next_e[j].first < 0) { - cur_rhs_e.push_back(sentence.e[j]); - cur_es.push_back(j); - } else { - cur_rhs_e.push_back(1 - next_e[j].second); // next_e[j].second is NT gap index - cur_es.push_back(-1); - j = next_e[j].first - 1; - } - } - for (short i = 0; i < cur_fs.size(); ++i) - if (cur_fs[i] >= 0) - for (short j = 0; j < cur_es.size(); ++j) - if (cur_es[j] >= 0 && sentence.aligned(cur_fs[i],cur_es[j])) - cur_terminal_align.push_back(make_pair(i,j)); - //observer->CountRule(lhs, cur_rhs_f, cur_rhs_e, cur_terminal_align); - - if(!all_cats->empty()) { - //produce the backoff grammar if the category wordIDs are available - for (int i = 0; i < cur_rhs_f.size(); ++i) { - if(cur_rhs_f[i] < 0) { - //cerr << cur_rhs_f[i] << ": (cats,f) |" << TD::Convert(-cur_rhs_f[i]) << endl; - string nonterm = TD::Convert(-cur_rhs_f[i]); - nonterm+=bkoff_mrkr; - bkoff = -TD::Convert(nonterm); - cur_rhs_f[i]=bkoff; - /*vector<WordID> rhs_f_bkoff; - vector<WordID> rhs_e_bkoff; - vector<pair<short,short> > bkoff_align; - bkoff_align.clear(); - bkoff_align.push_back(make_pair(0,0)); - - for (int cat = 0; cat < all_cats->size(); ++cat) { - rhs_f_bkoff.clear(); - rhs_e_bkoff.clear(); - rhs_f_bkoff.push_back(-(*all_cats)[cat]); - rhs_e_bkoff.push_back(0); - observer->CountRule(bkoff,rhs_f_bkoff,rhs_e_bkoff,bkoff_align); - - }*/ - } - } - - } - observer->CountRule(lhs, cur_rhs_f, cur_rhs_e, cur_terminal_align); - } - } - } - q.pop(); - } -} - |