/********************************************************************** * File: werd.cpp (Formerly word.c) * Description: Code for the WERD class. * Author: Ray Smith * Created: Tue Oct 08 14:32:12 BST 1991 * * (C) Copyright 1991, Hewlett-Packard Ltd. ** 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 "mfcpch.h" #include "blckerr.h" #include "linlsq.h" #include "werd.h" // Include automatically generated configuration file if running autoconf. #ifdef HAVE_CONFIG_H #include "config_auto.h" #endif #define FIRST_COLOUR ScrollView::RED //< first rainbow colour /// last rainbow colour #define LAST_COLOUR ScrollView::AQUAMARINE #define CHILD_COLOUR ScrollView::BROWN //< colour of children const ERRCODE CANT_SCALE_EDGESTEPS = "Attempted to scale an edgestep format word"; #define EXTERN EXTERN BOOL_VAR (bln_numericmode, 0, "Optimize for numbers"); EXTERN INT_VAR (bln_x_height, 128, "Baseline Normalisation X-height"); EXTERN INT_VAR (bln_baseline_offset, 64, "Baseline Norm. offset of baseline"); EXTERN double_VAR (bln_blshift_maxshift, -1.0, "Fraction of xh before shifting"); EXTERN double_VAR (bln_blshift_xfraction, 0.75, "Size fraction of xh before shifting"); ELISTIZE_S (WERD) /** * WERD::WERD * * Constructor to build a WERD from a list of C_BLOBs. * The C_BLOBs are not copied so the source list is emptied. */ WERD::WERD ( //constructor C_BLOB_LIST * blob_list, //< in word order uinT8 blank_count, //< blanks in front const char *text //< correct text ): flags (0), correct(text) { C_BLOB_IT start_it = blob_list;//iterator C_BLOB_IT end_it = blob_list; //another //rejected blobs in wd C_BLOB_IT rej_cblob_it = &rej_cblobs; C_OUTLINE_IT c_outline_it; //coutline iterator BOOL8 blob_inverted; BOOL8 reject_blob; inT16 inverted_vote = 0; inT16 non_inverted_vote = 0; while (!end_it.at_last ()) end_it.forward (); //move to last //move to our list cblobs.assign_to_sublist (&start_it, &end_it); blanks = blank_count; /* Set white on black flag for the WERD, moving any duff blobs onto the rej_cblobs list. First, walk the cblobs checking the inverse flag for each outline of each cblob. If a cblob has inconsistent flag settings for its different outlines, move the blob to the reject list. Otherwise, increment the appropriate w-on-b or b-on-w vote for the word. Now set the inversion flag for the WERD by maximum vote. Walk the blobs again, moving any blob whose inversion flag does not agree with the concencus onto the reject list. */ start_it.set_to_list (&cblobs); if (start_it.empty ()) return; for (start_it.mark_cycle_pt (); !start_it.cycled_list (); start_it.forward ()) { c_outline_it.set_to_list (start_it.data ()->out_list ()); blob_inverted = c_outline_it.data ()->flag (COUT_INVERSE); reject_blob = FALSE; for (c_outline_it.mark_cycle_pt (); !c_outline_it.cycled_list () && !reject_blob; c_outline_it.forward ()) { reject_blob = c_outline_it.data ()->flag (COUT_INVERSE) != blob_inverted; } if (reject_blob) rej_cblob_it.add_after_then_move (start_it.extract ()); else { if (blob_inverted) inverted_vote++; else non_inverted_vote++; } } flags.set_bit (W_INVERSE, (inverted_vote > non_inverted_vote)); start_it.set_to_list (&cblobs); if (start_it.empty ()) return; for (start_it.mark_cycle_pt (); !start_it.cycled_list (); start_it.forward ()) { c_outline_it.set_to_list (start_it.data ()->out_list ()); if (c_outline_it.data ()->flag (COUT_INVERSE) != flags.bit (W_INVERSE)) rej_cblob_it.add_after_then_move (start_it.extract ()); } } /** * WERD::WERD * * Constructor to build a WERD from a list of BLOBs. * The BLOBs are not copied so the source list is emptied. */ WERD::WERD ( //constructor PBLOB_LIST * blob_list, //< in word order uinT8 blank_count, //< blanks in front const char *text //< correct text ): flags (0), correct(text) { PBLOB_IT start_it = blob_list; //iterator PBLOB_IT end_it = blob_list; //another while (!end_it.at_last ()) end_it.forward (); //move to last ((PBLOB_LIST *) (&cblobs))->assign_to_sublist (&start_it, &end_it); //move to our list //it's a polygon flags.set_bit (W_POLYGON, TRUE); blanks = blank_count; // fprintf(stderr,"Wrong constructor!!!!\n"); } /** * WERD::WERD * * Constructor to build a WERD from a list of BLOBs. * The BLOBs are not copied so the source list is emptied. */ WERD::WERD ( //constructor PBLOB_LIST * blob_list, //< in word order WERD * clone //< sorce of flags ):flags (clone->flags), correct (clone->correct) { PBLOB_IT start_it = blob_list; //iterator PBLOB_IT end_it = blob_list; //another while (!end_it.at_last ()) end_it.forward (); //move to last ((PBLOB_LIST *) (&cblobs))->assign_to_sublist (&start_it, &end_it); //move to our list blanks = clone->blanks; // fprintf(stderr,"Wrong constructor!!!!\n"); } /** * WERD::WERD * * Constructor to build a WERD from a list of C_BLOBs. * The C_BLOBs are not copied so the source list is emptied. */ WERD::WERD ( //constructor C_BLOB_LIST * blob_list, //< in word order WERD * clone //< source of flags ):flags (clone->flags), correct (clone->correct) { C_BLOB_IT start_it = blob_list;//iterator C_BLOB_IT end_it = blob_list; //another while (!end_it.at_last ()) end_it.forward (); //move to last ((C_BLOB_LIST *) (&cblobs))->assign_to_sublist (&start_it, &end_it); //move to our list blanks = clone->blanks; // fprintf(stderr,"Wrong constructor!!!!\n"); } /** * WERD::poly_copy * * Make a copy of a WERD in polygon format. * The source WERD is untouched. */ WERD *WERD::poly_copy( //make a poly copy float xheight //< row height ) { PBLOB *blob; //new blob WERD *result = new WERD; //output word C_BLOB_IT src_it = &cblobs; //iterator // LARC_BLOB_IT larc_it=(LARC_BLOB_LIST*)(&cblobs); PBLOB_IT dest_it = (PBLOB_LIST *) (&result->cblobs); //another if (flags.bit (W_POLYGON)) { *result = *this; //just copy it } else { result->flags = flags; result->correct = correct; //copy info result->dummy = dummy; if (!src_it.empty ()) { // if (flags.bit(W_LINEARC)) // { // do // { // blob=new PBLOB; // poly_linearc_outlines(larc_it.data()->out_list(), // blob->out_list()); //convert outlines // dest_it.add_after_then_move(blob); //add to dest list // larc_it.forward(); // } // while (!larc_it.at_first()); // } // else // { do { blob = new PBLOB (src_it.data (), xheight); //convert blob //add to dest list dest_it.add_after_then_move (blob); src_it.forward (); } while (!src_it.at_first ()); // } } if (!rej_cblobs.empty ()) { /* Polygonal approx of reject blobs */ src_it.set_to_list (&rej_cblobs); dest_it = (PBLOB_LIST *) (&result->rej_cblobs); do { //convert blob blob = new PBLOB (src_it.data (), xheight); //add to dest list dest_it.add_after_then_move (blob); src_it.forward (); } while (!src_it.at_first ()); } //polygon now result->flags.set_bit (W_POLYGON, TRUE); result->blanks = blanks; } return result; } /** * WERD::bounding_box * * Return the bounding box of the WERD. * This is quite a mess to compute! * ORIGINALLY, REJECT CBLOBS WERE EXCLUDED, however, this led to bugs when the * words on the row were re-sorted. The original words were built with reject * blobs included. The FUZZY SPACE flags were set accordingly. If ALL the * blobs in a word are rejected the BB for the word is NULL, causing the sort * to screw up, leading to the erroneous possibility of the first word in a * row being marked as FUZZY space. */ TBOX WERD::bounding_box() { //bounding box TBOX box; //box being built //rejected blobs in wd C_BLOB_IT rej_cblob_it = &rej_cblobs; for (rej_cblob_it.mark_cycle_pt (); !rej_cblob_it.cycled_list (); rej_cblob_it.forward ()) { box += rej_cblob_it.data ()->bounding_box (); } if (flags.bit (W_POLYGON)) { //polygons PBLOB_IT it = (PBLOB_LIST *) (&cblobs); for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) { box += it.data ()->bounding_box (); } } else { C_BLOB_IT it = &cblobs; //blobs of WERD for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) { box += it.data ()->bounding_box (); } } return box; } /** * WERD::move * * Reposition WERD by vector * NOTE!! REJECT CBLOBS ARE NOT MOVED */ void WERD::move( // reposition WERD const ICOORD vec //< by vector ) { PBLOB_IT blob_it ((PBLOB_LIST *) & cblobs); // blob iterator // LARC_BLOB_IT lblob_it((LARC_BLOB_LIST*)&cblobs); C_BLOB_IT cblob_it(&cblobs); // cblob iterator if (flags.bit (W_POLYGON)) for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) blob_it.data ()->move (vec); // else if (flags.bit(W_LINEARC)) // for( lblob_it.mark_cycle_pt(); // !lblob_it.cycled_list(); // lblob_it.forward() ) // lblob_it.data()->move( vec ); else for (cblob_it.mark_cycle_pt (); !cblob_it.cycled_list (); cblob_it.forward ()) cblob_it.data ()->move (vec); } /** * WERD::scale * * Scale WERD by multiplier */ void WERD::scale( // scale WERD const float f //< by multiplier ) { PBLOB_IT blob_it ((PBLOB_LIST *) & cblobs); // blob iterator // LARC_BLOB_IT lblob_it((LARC_BLOB_LIST*)&cblobs); if (flags.bit (W_POLYGON)) for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) blob_it.data ()->scale (f); // else if (flags.bit(W_LINEARC)) // for (lblob_it.mark_cycle_pt(); // !lblob_it.cycled_list(); // lblob_it.forward() ) // lblob_it.data()->scale( f ); else CANT_SCALE_EDGESTEPS.error ("WERD::scale", ABORT, NULL); } /** * WERD::join_on * * Join other word onto this one. Delete the old word. */ void WERD::join_on( // join WERD WERD *&other //< other word ) { PBLOB_IT blob_it ((PBLOB_LIST *) & cblobs); // blob iterator PBLOB_IT src_it ((PBLOB_LIST *) & other->cblobs); C_BLOB_IT rej_cblob_it(&rej_cblobs); C_BLOB_IT src_rej_it (&other->rej_cblobs); while (!src_it.empty ()) { blob_it.add_to_end (src_it.extract ()); src_it.forward (); } while (!src_rej_it.empty ()) { rej_cblob_it.add_to_end (src_rej_it.extract ()); src_rej_it.forward (); } } /** * WERD::copy_on * * Copy blobs from other word onto this one. */ void WERD::copy_on( //copy blobs WERD *&other //< from other ) { if (flags.bit (W_POLYGON)) { PBLOB_IT blob_it ((PBLOB_LIST *) & cblobs); // blob iterator PBLOB_LIST blobs; blobs.deep_copy(reinterpret_cast(&other->cblobs), &PBLOB::deep_copy); blob_it.move_to_last(); blob_it.add_list_after(&blobs); } else { C_BLOB_IT c_blob_it(&cblobs); C_BLOB_LIST c_blobs; c_blobs.deep_copy(&other->cblobs, &C_BLOB::deep_copy); c_blob_it.move_to_last (); c_blob_it.add_list_after (&c_blobs); } if (!other->rej_cblobs.empty ()) { C_BLOB_IT rej_c_blob_it(&rej_cblobs); C_BLOB_LIST new_rej_c_blobs; new_rej_c_blobs.deep_copy(&other->rej_cblobs, &C_BLOB::deep_copy); rej_c_blob_it.move_to_last (); rej_c_blob_it.add_list_after (&new_rej_c_blobs); } } /** * WERD::baseline_normalise * * Baseline Normalise the word in Tesseract style. (I.e origin at centre of * word at bottom. x-height region scaled to region y = * (bln_baseline_offset)..(bln_baseline_offset + bln_x_height) * - usually 64..192) */ void WERD::baseline_normalise( // Tess style BL Norm ROW *row, DENORM *denorm //< antidote ) { baseline_normalise_x (row, row->x_height (), denorm); //Use standard x ht } /** * WERD::baseline_normalise_x * * Baseline Normalise the word in Tesseract style. (I.e origin at centre of * word at bottom. x-height region scaled to region y = * (bln_baseline_offset)..(bln_baseline_offset + bln_x_height) * - usually 64..192) * USE A SPECIFIED X-HEIGHT - NOT NECESSARILY THE ONE IN row */ void WERD::baseline_normalise_x( // Tess style BL Norm ROW *row, float x_height, //< non standard value DENORM *denorm //< antidote ) { BOOL8 using_row; //as baseline float blob_x_centre; //middle of blob float blob_offset; //bottom miss float top_offset; //top miss float blob_x_height; //xh for this blob inT16 segments; //no of segments inT16 segment; //current segment DENORM_SEG *segs; //array of segments float mean_x; //mean xheight inT32 x_count; //no of xs TBOX word_box = bounding_box ();//word bounding box TBOX blob_box; //blob bounding box PBLOB_IT blob_it ((PBLOB_LIST *) & cblobs); // blob iterator PBLOB *blob; LLSQ line; //fitted line double line_m, line_c; //fitted line //inverse norm DENORM antidote (word_box.left () + (word_box.right () - word_box.left ()) / 2.0, bln_x_height / x_height, row); if (!flags.bit (W_POLYGON)) { WRONG_WORD.error ("WERD::baseline_normalise", ABORT, "Need to poly approx"); } if (flags.bit (W_NORMALIZED)) { WRONG_WORD.error ("WERD::baseline_normalise", ABORT, "Baseline unnormalised"); } if (bln_numericmode) { segs = new DENORM_SEG[blob_it.length ()]; segments = 0; float factor; // For scaling to baseline normalised size. for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); blob_box = blob->bounding_box (); blob->move (FCOORD (-antidote.origin (), -blob_box.bottom ())); factor = bln_x_height * 4.0f / (3 * blob_box.height ()); // Constrain the scale factor as target numbers should be either // cap height already or xheight. if (factor < antidote.scale()) factor = antidote.scale(); else if (factor > antidote.scale() * 1.5f) factor = antidote.scale() * 1.5f; blob->scale (factor); blob->move (FCOORD (0.0, bln_baseline_offset)); segs[segments].xstart = blob->bounding_box().left(); segs[segments].ycoord = blob_box.bottom(); segs[segments++].scale_factor = factor; } antidote = DENORM (antidote.origin (), antidote.scale (), 0.0f, 0.0f, segments, segs, true, row); delete [] segs; //Repeat for rej blobs blob_it.set_to_list ((PBLOB_LIST *) & rej_cblobs); for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); blob_box = blob->bounding_box (); blob->move (FCOORD (-antidote.origin (), -blob_box.bottom ())); blob->scale (bln_x_height * 4.0f / (3 * blob_box.height ())); blob->move (FCOORD (0.0, bln_baseline_offset)); } } else if (bln_blshift_maxshift < 0) { for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); blob_box = blob->bounding_box (); blob_x_centre = blob_box.left () + (blob_box.right () - blob_box.left ()) / 2.0; blob->move (FCOORD (-antidote.origin (), -(row->base_line (blob_x_centre)))); blob->scale (antidote.scale ()); blob->move (FCOORD (0.0, bln_baseline_offset)); } //Repeat for rej blobs blob_it.set_to_list ((PBLOB_LIST *) & rej_cblobs); for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); blob_box = blob->bounding_box (); blob_x_centre = blob_box.left () + (blob_box.right () - blob_box.left ()) / 2.0; blob->move (FCOORD (-antidote.origin (), -(row->base_line (blob_x_centre)))); blob->scale (antidote.scale ()); blob->move (FCOORD (0.0, bln_baseline_offset)); } } else { mean_x = x_height; x_count = 1; segs = new DENORM_SEG[blob_it.length ()]; segments = 0; for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); blob_box = blob->bounding_box (); if (blob_box.height () > bln_blshift_xfraction * x_height) { blob_x_centre = blob_box.left () + (blob_box.right () - blob_box.left ()) / 2.0; blob_offset = blob_box.bottom () - row->base_line (blob_x_centre); top_offset = blob_offset + blob_box.height () - x_height - 1; blob_x_height = top_offset + x_height; if (top_offset < 0) top_offset = -top_offset; if (blob_offset < 0) blob_offset = -blob_offset; if (blob_offset < bln_blshift_maxshift * x_height) { segs[segments].ycoord = blob_box.bottom (); line.add (blob_x_centre, blob_box.bottom ()); if (top_offset < bln_blshift_maxshift * x_height) { segs[segments].scale_factor = blob_box.height () - 1.0f; x_count++; } else segs[segments].scale_factor = 0.0f; //fix it later } else { //not a goer segs[segments].ycoord = -MAX_INT32; if (top_offset < bln_blshift_maxshift * x_height) { segs[segments].scale_factor = blob_x_height; x_count++; } else segs[segments].scale_factor = 0.0f; //fix it later } } else { segs[segments].scale_factor = 0.0f; segs[segments].ycoord = -MAX_INT32; } segs[segments].xstart = blob_box.left (); segments++; } using_row = line.count () <= 1; if (!using_row) { line_m = line.m (); line_c = line.c (line_m); } else line_m = line_c = 0; segments = 0; for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); blob_box = blob->bounding_box (); blob_x_centre = blob_box.left () + (blob_box.right () - blob_box.left ()) / 2.0; if (segs[segments].ycoord == -MAX_INT32 && segs[segments].scale_factor != 0 && !using_row) { blob_offset = line_m * blob_x_centre + line_c; segs[segments].scale_factor = blob_box.top () - blob_offset; } if (segs[segments].scale_factor != 0) mean_x += segs[segments].scale_factor; segments++; } mean_x /= x_count; // printf("mean x=%g, count=%d, line_m=%g, line_c=%g\n", // mean_x,x_count,line_m,line_c); segments = 0; for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); blob_box = blob->bounding_box (); blob_x_centre = blob_box.left () + (blob_box.right () - blob_box.left ()) / 2.0; if (segs[segments].ycoord != -MAX_INT32) blob_offset = (float) segs[segments].ycoord; else if (using_row) blob_offset = row->base_line (blob_x_centre); else blob_offset = line_m * blob_x_centre + line_c; if (segs[segments].scale_factor == 0) segs[segments].scale_factor = mean_x; segs[segments].scale_factor = bln_x_height / segs[segments].scale_factor; // printf("Blob sf=%g, top=%d, bot=%d, base=%g\n", // segs[segments].scale_factor,blob_box.top(), // blob_box.bottom(),blob_offset); blob->move (FCOORD (-antidote.origin (), -blob_offset)); blob-> scale (FCOORD (antidote.scale (), segs[segments].scale_factor)); blob->move (FCOORD (0.0, bln_baseline_offset)); segments++; } //Repeat for rej blobs blob_it.set_to_list ((PBLOB_LIST *) & rej_cblobs); segment = 0; for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); blob_box = blob->bounding_box (); blob_x_centre = blob_box.left () + (blob_box.right () - blob_box.left ()) / 2.0; while (segment < segments - 1 && segs[segment + 1].xstart <= blob_x_centre) segment++; if (segs[segment].ycoord != -MAX_INT32) blob_offset = (float) segs[segment].ycoord; else if (using_row) blob_offset = row->base_line (blob_x_centre); else blob_offset = line_m * blob_x_centre + line_c; blob->move (FCOORD (-antidote.origin (), -blob_offset)); blob-> scale (FCOORD (antidote.scale (), segs[segment].scale_factor)); blob->move (FCOORD (0.0, bln_baseline_offset)); } if (line.count () > 0 || x_count > 1) antidote = DENORM (antidote.origin (), antidote.scale (), line_m, line_c, segments, segs, using_row, row); delete[]segs; } if (denorm != NULL) *denorm = antidote; //it's normalised flags.set_bit (W_NORMALIZED, TRUE); } /** * WERD::baseline_denormalise * * Baseline DeNormalise the word in Tesseract style. (I.e origin at centre of * word at bottom. x-height region scaled to region y = * (bln_baseline_offset)..(bln_baseline_offset + bln_x_height) * - usually 64..192) */ void WERD::baseline_denormalise( // Tess style BL Norm const DENORM *denorm //< antidote ) { PBLOB_IT blob_it ((PBLOB_LIST *) & cblobs); // blob iterator PBLOB *blob; if (!flags.bit (W_NORMALIZED)) { WRONG_WORD.error ("WERD::baseline_denormalise", ABORT, "Baseline normalised"); } for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); //denormalise it blob->baseline_denormalise (denorm); } //Repeat for rej blobs blob_it.set_to_list ((PBLOB_LIST *) & rej_cblobs); for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); //denormalise it blob->baseline_denormalise (denorm); } //it's not normalised flags.set_bit (W_NORMALIZED, FALSE); } /** * WERD::print * * Display members */ void WERD::print( //print FILE * //< file to print on ) { tprintf ("Blanks= %d\n", blanks); bounding_box ().print (); tprintf ("Flags = %d = 0%o\n", flags.val, flags.val); tprintf (" W_SEGMENTED = %s\n", flags.bit (W_SEGMENTED) ? "TRUE" : "FALSE "); tprintf (" W_ITALIC = %s\n", flags.bit (W_ITALIC) ? "TRUE" : "FALSE "); tprintf (" W_BOL = %s\n", flags.bit (W_BOL) ? "TRUE" : "FALSE "); tprintf (" W_EOL = %s\n", flags.bit (W_EOL) ? "TRUE" : "FALSE "); tprintf (" W_NORMALIZED = %s\n", flags.bit (W_NORMALIZED) ? "TRUE" : "FALSE "); tprintf (" W_POLYGON = %s\n", flags.bit (W_POLYGON) ? "TRUE" : "FALSE "); tprintf (" W_LINEARC = %s\n", flags.bit (W_LINEARC) ? "TRUE" : "FALSE "); tprintf (" W_DONT_CHOP = %s\n", flags.bit (W_DONT_CHOP) ? "TRUE" : "FALSE "); tprintf (" W_REP_CHAR = %s\n", flags.bit (W_REP_CHAR) ? "TRUE" : "FALSE "); tprintf (" W_FUZZY_SP = %s\n", flags.bit (W_FUZZY_SP) ? "TRUE" : "FALSE "); tprintf (" W_FUZZY_NON = %s\n", flags.bit (W_FUZZY_NON) ? "TRUE" : "FALSE "); tprintf ("Correct= %s\n", correct.string ()); tprintf ("Rejected cblob count = %d\n", rej_cblobs.length ()); } /** * WERD::plot * * Draw the WERD in the given colour. */ #ifndef GRAPHICS_DISABLED void WERD::plot( //draw it ScrollView* window, //window to draw in ScrollView::Color colour, //colour to draw in BOOL8 solid //draw larcs solid ) { if (flags.bit (W_POLYGON)) { //polygons PBLOB_IT it = (PBLOB_LIST *) (&cblobs); for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) { it.data ()->plot (window, colour, colour); } } // else if (flags.bit(W_LINEARC)) // { // LARC_BLOB_IT it=(LARC_BLOB_LIST*)(&cblobs); // for ( it.mark_cycle_pt(); !it.cycled_list(); it.forward() ) // { // it.data()->plot(window,solid,colour,solid ? BLACK : colour); // } // } else { C_BLOB_IT it = &cblobs; //blobs of WERD for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) { it.data ()->plot (window, colour, colour); } } plot_rej_blobs(window, solid); } #endif /** * WERD::plot * * Draw the WERD in rainbow colours. */ #ifndef GRAPHICS_DISABLED void WERD::plot( //draw it ScrollView* window, //< window to draw in BOOL8 solid //< draw larcs solid ) { ScrollView::Color colour = FIRST_COLOUR; //current colour if (flags.bit (W_POLYGON)) { //polygons PBLOB_IT it = (PBLOB_LIST *) (&cblobs); for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) { it.data ()->plot (window, colour, CHILD_COLOUR); colour = (ScrollView::Color) (colour + 1); if (colour == LAST_COLOUR) colour = FIRST_COLOUR; //cycle round } } // else if (flags.bit(W_LINEARC)) // { // LARC_BLOB_IT it=(LARC_BLOB_LIST*)(&cblobs); // for ( it.mark_cycle_pt(); !it.cycled_list(); it.forward() ) // { // it.data()->plot(window,solid,colour,solid ? BLACK : CHILD_COLOUR); // colour=(COLOUR)(colour+1); // if (colour==LAST_COLOUR) // colour=FIRST_COLOUR; // } // } else { C_BLOB_IT it = &cblobs; //blobs of WERD for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) { it.data ()->plot (window, colour, CHILD_COLOUR); colour = (ScrollView::Color) (colour + 1); if (colour == LAST_COLOUR) colour = FIRST_COLOUR; //cycle round } } plot_rej_blobs(window, solid); } #endif /** * WERD::plot_rej_blobs * * Draw the WERD rejected blobs - ALWAYS GREY */ #ifndef GRAPHICS_DISABLED void WERD::plot_rej_blobs( //draw it ScrollView* window, //< window to draw in BOOL8 solid //< draw larcs solid ) { if (flags.bit (W_POLYGON)) { PBLOB_IT it = (PBLOB_LIST *) (&rej_cblobs); //polygons for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) { it.data ()->plot (window, ScrollView::GREY, ScrollView::GREY); } } else { C_BLOB_IT it = &rej_cblobs; //blobs of WERD for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ()) { it.data ()->plot (window, ScrollView::GREY, ScrollView::GREY); } } } #endif /** * WERD::shallow_copy() * * Make a shallow copy of a word */ WERD *WERD::shallow_copy() { //shallow copy WERD *new_word = new WERD; new_word->blanks = blanks; new_word->flags = flags; new_word->dummy = dummy; new_word->correct = correct; return new_word; } /** * WERD::operator= * * Assign a word, DEEP copying the blob list */ WERD & WERD::operator= ( //assign words const WERD & source //from this ) { this->ELIST_LINK::operator= (source); blanks = source.blanks; flags = source.flags; dummy = source.dummy; correct = source.correct; if (flags.bit (W_POLYGON)) { if (!cblobs.empty()) reinterpret_cast(&cblobs)->clear(); reinterpret_cast(&cblobs)->deep_copy( reinterpret_cast(&source.cblobs), &PBLOB::deep_copy); if (!rej_cblobs.empty()) reinterpret_cast(&rej_cblobs)->clear(); reinterpret_cast(&rej_cblobs)->deep_copy( reinterpret_cast(&source.rej_cblobs), &PBLOB::deep_copy); } else { if (!cblobs.empty ()) cblobs.clear (); cblobs.deep_copy(&source.cblobs, &C_BLOB::deep_copy); if (!rej_cblobs.empty ()) rej_cblobs.clear (); rej_cblobs.deep_copy(&source.rej_cblobs, &C_BLOB::deep_copy); } return *this; } /** * word_comparator() * * word comparator used to sort a word list so that words are in increasing * order of left edge. */ int word_comparator( //sort blobs const void *word1p, //< ptr to ptr to word1 const void *word2p //< ptr to ptr to word2 ) { WERD * word1 = *(WERD **) word1p; WERD * word2 = *(WERD **) word2p; return word1->bounding_box ().left () - word2->bounding_box ().left (); }