/********************************************************************** * File: search_column.cpp * Description: Implementation of the Beam Search Column Class * Author: Ahmad Abdulkader * Created: 2008 * * (C) Copyright 2008, Google Inc. ** Licensed under the Apache License, Version 2.0 (the "License"); ** you may not use this file except in compliance with the License. ** You may obtain a copy of the License at ** http://www.apache.org/licenses/LICENSE-2.0 ** Unless required by applicable law or agreed to in writing, software ** distributed under the License is distributed on an "AS IS" BASIS, ** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. ** See the License for the specific language governing permissions and ** limitations under the License. * **********************************************************************/ #include "search_column.h" #include namespace tesseract { SearchColumn::SearchColumn(int col_idx, int max_node) { col_idx_ = col_idx; node_cnt_ = 0; node_array_ = NULL; max_node_cnt_ = max_node; node_hash_table_ = NULL; init_ = false; min_cost_ = INT_MAX; max_cost_ = 0; } // Cleanup data void SearchColumn::Cleanup() { if (node_array_ != NULL) { for (int node_idx = 0; node_idx < node_cnt_; node_idx++) { if (node_array_[node_idx] != NULL) { delete node_array_[node_idx]; } } delete []node_array_; node_array_ = NULL; } FreeHashTable(); init_ = false; } SearchColumn::~SearchColumn() { Cleanup(); } // Initializations bool SearchColumn::Init() { if (init_ == true) { return true; } // create hash table if (node_hash_table_ == NULL) { node_hash_table_ = new SearchNodeHashTable(); } init_ = true; return true; } // Prune the nodes if necessary. Pruning is done such that a max // number of nodes is kept, i.e., the beam width void SearchColumn::Prune() { // no need to prune if (node_cnt_ <= max_node_cnt_) { return; } // compute the cost histogram memset(score_bins_, 0, sizeof(score_bins_)); int cost_range = max_cost_ - min_cost_ + 1; for (int node_idx = 0; node_idx < node_cnt_; node_idx++) { int cost_bin = static_cast( ((node_array_[node_idx]->BestCost() - min_cost_) * kScoreBins) / static_cast(cost_range)); if (cost_bin >= kScoreBins) { cost_bin = kScoreBins - 1; } score_bins_[cost_bin]++; } // determine the pruning cost by scanning the cost histogram from // least to greatest cost bins and finding the cost at which the // max number of nodes is exceeded int pruning_cost = 0; int new_node_cnt = 0; for (int cost_bin = 0; cost_bin < kScoreBins; cost_bin++) { if (new_node_cnt > 0 && (new_node_cnt + score_bins_[cost_bin]) > max_node_cnt_) { pruning_cost = min_cost_ + ((cost_bin * cost_range) / kScoreBins); break; } new_node_cnt += score_bins_[cost_bin]; } // prune out all the nodes above this cost for (int node_idx = new_node_cnt = 0; node_idx < node_cnt_; node_idx++) { // prune this node out if (node_array_[node_idx]->BestCost() > pruning_cost || new_node_cnt > max_node_cnt_) { delete node_array_[node_idx]; } else { // keep it node_array_[new_node_cnt++] = node_array_[node_idx]; } } node_cnt_ = new_node_cnt; } // sort all nodes void SearchColumn::Sort() { if (node_cnt_ > 0 && node_array_ != NULL) { qsort(node_array_, node_cnt_, sizeof(*node_array_), SearchNode::SearchNodeComparer); } } // add a new node SearchNode *SearchColumn::AddNode(LangModEdge *edge, int reco_cost, SearchNode *parent_node, CubeRecoContext *cntxt) { // init if necessary if (init_ == false && Init() == false) { return NULL; } // find out if we have an node with the same edge // look in the hash table SearchNode *new_node = node_hash_table_->Lookup(edge, parent_node); // node does not exist if (new_node == NULL) { new_node = new SearchNode(cntxt, parent_node, reco_cost, edge, col_idx_); // if the max node count has already been reached, check if the cost of // the new node exceeds the max cost. This indicates that it will be pruned // and so there is no point adding it if (node_cnt_ >= max_node_cnt_ && new_node->BestCost() > max_cost_) { delete new_node; return NULL; } // expand the node buffer if necc if ((node_cnt_ % kNodeAllocChunk) == 0) { // alloc a new buff SearchNode **new_node_buff = new SearchNode *[node_cnt_ + kNodeAllocChunk]; // free existing after copying contents if (node_array_ != NULL) { memcpy(new_node_buff, node_array_, node_cnt_ * sizeof(*new_node_buff)); delete []node_array_; } node_array_ = new_node_buff; } // add the node to the hash table only if it is non-OOD edge // because the langmod state is not unique if (edge->IsOOD() == false) { if (!node_hash_table_->Insert(edge, new_node)) { tprintf("Hash table full!!!"); delete new_node; return NULL; } } node_array_[node_cnt_++] = new_node; } else { // node exists before // if no update occurred, return NULL if (new_node->UpdateParent(parent_node, reco_cost, edge) == false) { new_node = NULL; } // free the edge delete edge; } // update Min and Max Costs if (new_node != NULL) { if (min_cost_ > new_node->BestCost()) { min_cost_ = new_node->BestCost(); } if (max_cost_ < new_node->BestCost()) { max_cost_ = new_node->BestCost(); } } return new_node; } SearchNode *SearchColumn::BestNode() { SearchNode *best_node = NULL; for (int node_idx = 0; node_idx < node_cnt_; node_idx++) { if (best_node == NULL || best_node->BestCost() > node_array_[node_idx]->BestCost()) { best_node = node_array_[node_idx]; } } return best_node; } } // namespace tesseract