/////////////////////////////////////////////////////////////////////// // File: colpartitionrid.h // Description: Class collecting code that acts on a BBGrid of ColPartitions. // Author: Ray Smith // Created: Mon Oct 05 08:42:01 PDT 2009 // // (C) Copyright 2009, 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. // /////////////////////////////////////////////////////////////////////// #ifndef TESSERACT_TEXTORD_COLPARTITIONGRID_H__ #define TESSERACT_TEXTORD_COLPARTITIONGRID_H__ #include "bbgrid.h" #include "colpartition.h" #include "colpartitionset.h" namespace tesseract { class TabFind; // ColPartitionGrid is a BBGrid of ColPartition. // It collects functions that work on the grid. class ColPartitionGrid : public BBGrid { public: ColPartitionGrid(); ColPartitionGrid(int gridsize, const ICOORD& bleft, const ICOORD& tright); virtual ~ColPartitionGrid(); // Handles a click event in a display window. void HandleClick(int x, int y); // Merges ColPartitions in the grid that look like they belong in the same // textline. // For all partitions in the grid, calls the box_cb permanent callback // to compute the search box, searches the box, and if a candidate is found, // calls the confirm_cb to check any more rules. If the confirm_cb returns // true, then the partitions are merged. // Both callbacks are deleted before returning. void Merges(TessResultCallback2* box_cb, TessResultCallback2* confirm_cb); // For the given partition, calls the box_cb permanent callback // to compute the search box, searches the box, and if a candidate is found, // calls the confirm_cb to check any more rules. If the confirm_cb returns // true, then the partitions are merged. // Returns true if the partition is consumed by one or more merges. bool MergePart(TessResultCallback2* box_cb, TessResultCallback2* confirm_cb, ColPartition* part); // Computes and returns the total overlap of all partitions in the grid. // If overlap_grid is non-null, it is filled with a grid that holds empty // partitions representing the union of all overlapped partitions. int ComputeTotalOverlap(ColPartitionGrid** overlap_grid); // Finds all the ColPartitions in the grid that overlap with the given // box and returns them SortByBoxLeft(ed) and uniqued in the given list. // Any partition equal to not_this (may be NULL) is excluded. void FindOverlappingPartitions(const TBOX& box, const ColPartition* not_this, ColPartition_CLIST* parts); // Finds and returns the best candidate ColPartition to merge with part, // selected from the candidates list, based on the minimum increase in // pairwise overlap among all the partitions overlapped by the combined box. // If overlap_increase is not NULL then it returns the increase in overlap // that would result from the merge. // See colpartitiongrid.cpp for a diagram. ColPartition* BestMergeCandidate( const ColPartition* part, ColPartition_CLIST* candidates, bool debug, TessResultCallback2* confirm_cb, int* overlap_increase); // Split partitions where it reduces overlap between their bounding boxes. // ColPartitions are after all supposed to be a partitioning of the blobs // AND of the space on the page! // Blobs that cause overlaps get removed, put in individual partitions // and added to the big_parts list. They are most likely characters on // 2 textlines that touch, or something big like a dropcap. void SplitOverlappingPartitions(ColPartition_LIST* big_parts); // Filters partitions of source_type by looking at local neighbours. // Where a majority of neighbours have a text type, the partitions are // changed to text, where the neighbours have image type, they are changed // to image, and partitions that have no definite neighbourhood type are // left unchanged. // im_box and rerotation are used to map blob coordinates onto the // nontext_map, which is used to prevent the spread of text neighbourhoods // into images. // Returns true if anything was changed. bool GridSmoothNeighbours(BlobTextFlowType source_type, Pix* nontext_map, const TBOX& im_box, const FCOORD& rerotation); // Compute the mean RGB of the light and dark pixels in each ColPartition // and also the rms error in the linearity of color. void ComputePartitionColors(Pix* scaled_color, int scaled_factor, const FCOORD& rerotation); // Reflects the grid and its colpartitions in the y-axis, assuming that // all blob boxes have already been done. void ReflectInYAxis(); // Rotates the grid and its colpartitions by the given angle, assuming that // all blob boxes have already been done. void Deskew(const FCOORD& deskew); // Transforms the grid of partitions to the output blocks, putting each // partition into a separate block. We don't really care about the order, // as we just want to get as much text as possible without trying to organize // it into proper blocks or columns. void ExtractPartitionsAsBlocks(BLOCK_LIST* blocks, TO_BLOCK_LIST* to_blocks); // Sets the left and right tabs of the partitions in the grid. void SetTabStops(TabFind* tabgrid); // Makes the ColPartSets and puts them in the PartSetVector ready // for finding column bounds. Returns false if no partitions were found. // Each ColPartition in the grid is placed in a single ColPartSet based // on the bottom-left of its bounding box. bool MakeColPartSets(PartSetVector* part_sets); // Makes a single ColPartitionSet consisting of a single ColPartition that // represents the total horizontal extent of the significant content on the // page. Used for the single column setting in place of automatic detection. // Returns NULL if the page is empty of significant content. ColPartitionSet* MakeSingleColumnSet(WidthCallback* cb); // Mark the BLOBNBOXes in each partition as being owned by that partition. void ClaimBoxes(); // Retypes all the blobs referenced by the partitions in the grid. // Image blobs are sliced on the grid boundaries to give the tab finder // a better handle on the edges of the images, and the actual blobs are // returned in the im_blobs list, as they are not owned by the block. void ReTypeBlobs(BLOBNBOX_LIST* im_blobs); // The boxes within the partitions have changed (by deskew) so recompute // the bounds of all the partitions and reinsert them into the grid. void RecomputeBounds(int gridsize, const ICOORD& bleft, const ICOORD& tright, const ICOORD& vertical); // Improves the margins of the ColPartitions in the grid by calling // FindPartitionMargins on each. void GridFindMargins(ColPartitionSet** best_columns); // Improves the margins of the ColPartitions in the list by calling // FindPartitionMargins on each. void ListFindMargins(ColPartitionSet** best_columns, ColPartition_LIST* parts); // Deletes all the partitions in the grid after disowning all the blobs. void DeleteParts(); // Deletes all the partitions in the grid that are of type BRT_UNKNOWN and // all the blobs in them. void DeleteUnknownParts(TO_BLOCK* block); // Deletes all the partitions in the grid that are NOT of flow type // BTFT_LEADER. void DeleteNonLeaderParts(); // Finds and marks text partitions that represent figure captions. void FindFigureCaptions(); //////// Functions that manipulate ColPartitions in the grid /////// //////// to find chains of partner partitions of the same type. /////// // For every ColPartition in the grid, finds its upper and lower neighbours. void FindPartitionPartners(); // Finds the best partner in the given direction for the given partition. // Stores the result with AddPartner. void FindPartitionPartners(bool upper, ColPartition* part); // Finds the best partner in the given direction for the given partition. // Stores the result with AddPartner. void FindVPartitionPartners(bool to_the_left, ColPartition* part); // For every ColPartition with multiple partners in the grid, reduces the // number of partners to 0 or 1. If get_desperate is true, goes to more // desperate merge methods to merge flowing text before breaking partnerships. void RefinePartitionPartners(bool get_desperate); private: // Finds and returns a list of candidate ColPartitions to merge with part. // The candidates must overlap search_box, and when merged must not // overlap any other partitions that are not overlapped by each individually. void FindMergeCandidates(const ColPartition* part, const TBOX& search_box, bool debug, ColPartition_CLIST* candidates); // Smoothes the region type/flow type of the given part by looking at local // neighbours and the given image mask. Searches a padded rectangle with the // padding truncated on one size of the part's box in turn for each side, // using the result (if any) that has the least distance to all neighbours // that contribute to the decision. This biases in favor of rectangular // regions without completely enforcing them. // If a good decision cannot be reached, the part is left unchanged. // im_box and rerotation are used to map blob coordinates onto the // nontext_map, which is used to prevent the spread of text neighbourhoods // into images. // Returns true if the partition was changed. bool SmoothRegionType(Pix* nontext_map, const TBOX& im_box, const FCOORD& rerotation, bool debug, ColPartition* part); // Executes the search for SmoothRegionType in a single direction. // Creates a bounding box that is padded in all directions except direction, // and searches it for other partitions. Finds the nearest collection of // partitions that makes a decisive result (if any) and returns the type // and the distance of the collection. If there are any pixels in the // nontext_map, then the decision is biased towards image. BlobRegionType SmoothInOneDirection(BlobNeighbourDir direction, Pix* nontext_map, const TBOX& im_box, const FCOORD& rerotation, bool debug, const ColPartition& part, int* best_distance); // Counts the partitions in the given search_box by appending the gap // distance (scaled by dist_scaling) of the part from the base_part to the // vector of the appropriate type for the partition. Prior to return, the // vectors in the dists array are sorted in increasing order. // dists must be an array of GenericVectors of size NPT_COUNT. void AccumulatePartDistances(const ColPartition& base_part, const ICOORD& dist_scaling, const TBOX& search_box, Pix* nontext_map, const TBOX& im_box, const FCOORD& rerotation, bool debug, GenericVector* dists); // Improves the margins of the ColPartition by searching for // neighbours that vertically overlap significantly. void FindPartitionMargins(ColPartitionSet* columns, ColPartition* part); // Starting at x, and going in the specified direction, up to x_limit, finds // the margin for the given y range by searching sideways, // and ignoring not_this. int FindMargin(int x, bool right_to_left, int x_limit, int y_bottom, int y_top, const ColPartition* not_this); }; } // namespace tesseract. #endif // TESSERACT_TEXTORD_COLPARTITIONGRID_H__