/********************************************************************** * File: tordmain.cpp (Formerly textordp.c) * Description: C++ top level textord code. * Author: Ray Smith * Created: Tue Jul 28 17:12:33 BST 1992 * * (C) Copyright 1992, 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" #ifdef __UNIX__ #include #endif #include "stderr.h" #include "globaloc.h" #include "tessout.h" #include "blread.h" #include "blobbox.h" #include "edgblob.h" #include "drawtord.h" #include "makerow.h" #include "wordseg.h" #include "ocrclass.h" #include "genblob.h" #include "imgs.h" #include "tordmain.h" #include "secname.h" #include "tesseractclass.h" // Include automatically generated configuration file if running autoconf. #ifdef HAVE_CONFIG_H #include "config_auto.h" #endif // Some of the code in this file is dependent upon leptonica. If you don't // have it, you don't get this functionality. #ifdef HAVE_CONFIG_H #include "config_auto.h" #endif #ifdef HAVE_LIBLEPT #include "allheaders.h" #endif const ERRCODE BLOCKLESS_BLOBS = "Warning:some blobs assigned to no block"; #undef EXTERN #define EXTERN EXTERN BOOL_VAR (textord_no_rejects, FALSE, "Don't remove noise blobs"); EXTERN BOOL_VAR (textord_show_blobs, FALSE, "Display unsorted blobs"); EXTERN BOOL_VAR (textord_show_boxes, FALSE, "Display unsorted blobs"); EXTERN BOOL_VAR (textord_new_initial_xheight, TRUE, "Use test xheight mechanism"); EXTERN BOOL_VAR (textord_exit_after, FALSE, "Exit after completing textord"); EXTERN INT_VAR (textord_max_noise_size, 7, "Pixel size of noise"); EXTERN double_VAR (textord_blob_size_bigile, 95, "Percentile for large blobs"); EXTERN double_VAR (textord_noise_area_ratio, 0.7, "Fraction of bounding box for noise"); EXTERN double_VAR (textord_blob_size_smallile, 20, "Percentile for small blobs"); EXTERN double_VAR (textord_initialx_ile, 0.75, "Ile of sizes for xheight guess"); EXTERN double_VAR (textord_initialasc_ile, 0.90, "Ile of sizes for xheight guess"); EXTERN INT_VAR (textord_noise_sizefraction, 10, "Fraction of size for maxima"); EXTERN double_VAR (textord_noise_sizelimit, 0.5, "Fraction of x for big t count"); EXTERN INT_VAR (textord_noise_translimit, 16, "Transitions for normal blob"); EXTERN double_VAR (textord_noise_normratio, 2.0, "Dot to norm ratio for deletion"); EXTERN BOOL_VAR (textord_noise_rejwords, TRUE, "Reject noise-like words"); EXTERN BOOL_VAR (textord_noise_rejrows, TRUE, "Reject noise-like rows"); EXTERN double_VAR (textord_noise_syfract, 0.2, "xh fract error for norm blobs"); EXTERN double_VAR (textord_noise_sxfract, 0.4, "xh fract width error for norm blobs"); EXTERN double_VAR(textord_noise_hfract, 1.0/64, "Height fraction to discard outlines as speckle noise"); EXTERN INT_VAR (textord_noise_sncount, 1, "super norm blobs to save row"); EXTERN double_VAR (textord_noise_rowratio, 6.0, "Dot to norm ratio for deletion"); EXTERN BOOL_VAR (textord_noise_debug, FALSE, "Debug row garbage detector"); EXTERN double_VAR (textord_blshift_maxshift, 0.00, "Max baseline shift"); EXTERN double_VAR (textord_blshift_xfraction, 9.99, "Min size of baseline shift"); EXTERN STRING_EVAR (tessedit_image_ext, ".tif", "Externsion for image file"); #ifndef EMBEDDED EXTERN clock_t previous_cpu; #endif extern BOOL_VAR_H (polygon_tess_approximation, TRUE, "Do tess poly instead of grey scale"); #define MAX_NEAREST_DIST 600 //for block skew stats #define MAX_BLOB_TRANSITIONS100 //for nois stats extern IMAGE page_image; //must be defined somewhere extern BOOL_VAR_H (interactive_mode, TRUE, "Run interactively?"); extern /*"C" */ ETEXT_DESC *global_monitor; //progress monitor /********************************************************************** * find_components * * Find the C_OUTLINEs of the connected components in each block, put them * in C_BLOBs, and filter them by size, putting the different size * grades on different lists in the matching TO_BLOCK in port_blocks. **********************************************************************/ void find_components( BLOCK_LIST *blocks, TO_BLOCK_LIST *land_blocks, TO_BLOCK_LIST *port_blocks, TBOX *page_box) { BLOCK *block; //current block PDBLK_CLIST pd_blocks; //copy of list BLOCK_IT block_it = blocks; //iterator PDBLK_C_IT pd_it = &pd_blocks; //iterator IMAGE thresh_image; //thresholded int width = page_image.get_xsize(); int height = page_image.get_ysize(); if (width > MAX_INT16 || height > MAX_INT16) { tprintf("Input image too large! (%d, %d)\n", width, height); return; // Can't handle it. } ICOORD page_tr(width, height); block_it.set_to_list (blocks); if (global_monitor != NULL) global_monitor->ocr_alive = TRUE; set_global_loc_code(LOC_EDGE_PROG); if (!page_image.white_high ()) invert_image(&page_image); #ifndef EMBEDDED previous_cpu = clock (); #endif for (block_it.mark_cycle_pt(); !block_it.cycled_list(); block_it.forward()) { block = block_it.data(); if (block->poly_block() == NULL || block->poly_block()->IsText()) { #ifndef GRAPHICS_DISABLED extract_edges(NULL, &page_image, &page_image, page_tr, block); #else extract_edges(&page_image, &page_image, page_tr, block); #endif *page_box += block->bounding_box (); } } if (global_monitor != NULL) { global_monitor->ocr_alive = TRUE; global_monitor->progress = 10; } assign_blobs_to_blocks2(blocks, land_blocks, port_blocks); if (global_monitor != NULL) global_monitor->ocr_alive = TRUE; filter_blobs (page_box->topright (), land_blocks, textord_test_landscape); #ifndef EMBEDDED previous_cpu = clock (); #endif filter_blobs (page_box->topright (), port_blocks, !textord_test_landscape); if (global_monitor != NULL) global_monitor->ocr_alive = TRUE; } /********************************************************************** * SetBlobStrokeWidth * * Set the horizontal and vertical stroke widths in the blob. **********************************************************************/ void SetBlobStrokeWidth(bool debug, BLOBNBOX* blob) { #ifdef HAVE_LIBLEPT // Cut the blob rectangle into a Pix. // TODO(rays) make the page_image a Pix so this is more direct. const TBOX& box = blob->bounding_box(); IMAGE blob_im; int width = box.width(); int height = box.height(); blob_im.create(width, height, 1); copy_sub_image(&page_image, box.left(), box.bottom(), width, height, &blob_im, 0, 0, false); Pix* pix = blob_im.ToPix(); Pix* dist_pix = pixDistanceFunction(pix, 4, 8, L_BOUNDARY_BG); if (debug) { pixWrite("cutpix.png", pix, IFF_PNG); pixWrite("distpix.png", dist_pix, IFF_PNG); } pixDestroy(&pix); // Compute the stroke widths. uinT32* data = pixGetData(dist_pix); int wpl = pixGetWpl(dist_pix); // Horizontal width of stroke. STATS h_stats(0, width + 1); for (int y = 0; y < height; ++y) { uinT32* pixels = data + y*wpl; int prev_pixel = 0; int pixel = GET_DATA_BYTE(pixels, 0); for (int x = 1; x < width; ++x) { int next_pixel = GET_DATA_BYTE(pixels, x); // We are looking for a pixel that is equal to its vertical neighbours, // yet greater than its left neighbour. if (prev_pixel < pixel && (y == 0 || pixel == GET_DATA_BYTE(pixels - wpl, x - 1)) && (y == height - 1 || pixel == GET_DATA_BYTE(pixels + wpl, x - 1))) { if (pixel > next_pixel) { // Single local max, so an odd width. h_stats.add(pixel * 2 - 1, 1); } else if (pixel == next_pixel && x + 1 < width && pixel > GET_DATA_BYTE(pixels, x + 1)) { // Double local max, so an even width. h_stats.add(pixel * 2, 1); } } prev_pixel = pixel; pixel = next_pixel; } } if (debug) { h_stats.print(stderr, true); } // Vertical width of stroke. STATS v_stats(0, height + 1); for (int x = 0; x < width; ++x) { int prev_pixel = 0; int pixel = GET_DATA_BYTE(data, x); for (int y = 1; y < height; ++y) { uinT32* pixels = data + y*wpl; int next_pixel = GET_DATA_BYTE(pixels, x); // We are looking for a pixel that is equal to its horizontal neighbours, // yet greater than its upper neighbour. if (prev_pixel < pixel && (x == 0 || pixel == GET_DATA_BYTE(pixels - wpl, x - 1)) && (x == width - 1 || pixel == GET_DATA_BYTE(pixels - wpl, x + 1))) { if (pixel > next_pixel) { // Single local max, so an odd width. v_stats.add(pixel * 2 - 1, 1); } else if (pixel == next_pixel && y + 1 < height && pixel > GET_DATA_BYTE(pixels + wpl, x)) { // Double local max, so an even width. v_stats.add(pixel * 2, 1); } } prev_pixel = pixel; pixel = next_pixel; } } if (debug) { v_stats.print(stderr, true); } pixDestroy(&dist_pix); // Store the horizontal and vertical width in the blob, keeping both // widths if there is enough information, otherwse only the one with // the most samples. // If there are insufficent samples, store zero, rather than using // 2*area/perimeter, as the numbers that gives do not match the numbers // from the distance method. if (debug) { tprintf("box=%d,%d->%d,%d, hcount=%d, vcount=%d, target=%d\n", box.left(), box.bottom(), box.right(), box.top(), h_stats.get_total(), v_stats.get_total(), (width+height) /4); tprintf("hstats median=%f, lq=%f, uq=%f, sd=%f\n", h_stats.median(), h_stats.ile(0.25f), h_stats.ile(0.75f), h_stats.sd()); tprintf("vstats median=%f, lq=%f, uq=%f, sd=%f\n", v_stats.median(), v_stats.ile(0.25f), v_stats.ile(0.75f), v_stats.sd()); } if (h_stats.get_total() >= (width + height) / 4) { blob->set_horz_stroke_width(h_stats.ile(0.5f)); if (v_stats.get_total() >= (width + height) / 4) blob->set_vert_stroke_width(v_stats.ile(0.5f)); else blob->set_vert_stroke_width(0.0f); } else { if (v_stats.get_total() >= (width + height) / 4 || v_stats.get_total() > h_stats.get_total()) { blob->set_horz_stroke_width(0.0f); blob->set_vert_stroke_width(v_stats.ile(0.5f)); } else { blob->set_horz_stroke_width(h_stats.get_total() > 2 ? h_stats.ile(0.5f) : 0.0f); blob->set_vert_stroke_width(0.0f); } } #else // Without leptonica present, use the 2*area/perimeter as an approximation. float width = 2.0f * blob->cblob()->area(); width /= blob->cblob()->perimeter(); blob->set_horz_stroke_width(width); blob->set_vert_stroke_width(width); #endif } /********************************************************************** * assign_blobs_to_blocks2 * * Make a list of TO_BLOCKs for portrait and landscape orientation. **********************************************************************/ void assign_blobs_to_blocks2( // split into groups BLOCK_LIST *blocks, // blocks to process TO_BLOCK_LIST *land_blocks, // ** unused ** TO_BLOCK_LIST *port_blocks // output list ) { BLOCK *block; // current block BLOBNBOX *newblob; // created blob C_BLOB *blob; // current blob BLOCK_IT block_it = blocks; C_BLOB_IT blob_it; // iterator BLOBNBOX_IT port_box_it; // iterator // destination iterator TO_BLOCK_IT port_block_it = port_blocks; TO_BLOCK *port_block; // created block for (block_it.mark_cycle_pt(); !block_it.cycled_list(); block_it.forward()) { block = block_it.data (); port_block = new TO_BLOCK(block); // Convert the good outlines to block->blob_list port_box_it.set_to_list(&port_block->blobs); blob_it.set_to_list(block->blob_list()); for (blob_it.mark_cycle_pt(); !blob_it.cycled_list(); blob_it.forward()) { blob = blob_it.extract(); newblob = new BLOBNBOX(blob); // Convert blob to BLOBNBOX. SetBlobStrokeWidth(false, newblob); port_box_it.add_after_then_move(newblob); } // Put the rejected outlines in block->noise_blobs, which allows them to // be reconsidered and sorted back into rows and recover outlines mistakenly // rejected. port_box_it.set_to_list(&port_block->noise_blobs); blob_it.set_to_list(block->reject_blobs()); for (blob_it.mark_cycle_pt(); !blob_it.cycled_list(); blob_it.forward()) { blob = blob_it.extract(); newblob = new BLOBNBOX(blob); // Convert blob to BLOBNBOX. SetBlobStrokeWidth(false, newblob); port_box_it.add_after_then_move(newblob); } port_block_it.add_after_then_move(port_block); } } /********************************************************************** * filter_blobs * * Sort the blobs into sizes in all the blocks for later work. **********************************************************************/ void filter_blobs( //split into groups ICOORD page_tr, //top right TO_BLOCK_LIST *blocks, //output list BOOL8 testing_on //for plotting ) { TO_BLOCK_IT block_it = blocks; //destination iterator TO_BLOCK *block; //created block if (to_win != NULL) to_win->Clear(); for (block_it.mark_cycle_pt (); !block_it.cycled_list (); block_it.forward ()) { block = block_it.data (); block->line_size = filter_noise_blobs (&block->blobs, &block->noise_blobs, &block->small_blobs, &block->large_blobs); block->line_spacing = block->line_size * (textord_merge_desc + textord_merge_x + textord_merge_asc + textord_merge_asc) / textord_merge_x; block->line_size *= textord_min_linesize; block->max_blob_size = block->line_size * textord_excess_blobsize; #ifndef GRAPHICS_DISABLED if (textord_show_blobs && testing_on) { if (to_win == NULL) create_to_win(page_tr); block->plot_graded_blobs(to_win); } if (textord_show_boxes && testing_on) { if (to_win == NULL) create_to_win(page_tr); plot_box_list (to_win, &block->noise_blobs, ScrollView::WHITE); plot_box_list (to_win, &block->small_blobs, ScrollView::WHITE); plot_box_list (to_win, &block->large_blobs, ScrollView::WHITE); plot_box_list (to_win, &block->blobs, ScrollView::WHITE); } #endif } } /********************************************************************** * filter_noise_blobs * * Move small blobs to a separate list. **********************************************************************/ float filter_noise_blobs( //separate noise BLOBNBOX_LIST *src_list, //origonal list BLOBNBOX_LIST *noise_list, //noise list BLOBNBOX_LIST *small_list, //small blobs BLOBNBOX_LIST *large_list //large blobs ) { inT16 height; //height of blob inT16 width; //of blob BLOBNBOX_IT src_it = src_list; //iterators BLOBNBOX_IT noise_it = noise_list; BLOBNBOX_IT small_it = small_list; BLOBNBOX_IT large_it = large_list; STATS size_stats (0, MAX_NEAREST_DIST); //blob heights if (textord_new_initial_xheight) return filter_noise_blobs2 (src_list, noise_list, small_list, large_list); float min_y; //size limits float max_y; float max_x; for (src_it.mark_cycle_pt (); !src_it.cycled_list (); src_it.forward ()) { if (src_it.data ()->bounding_box ().height () < textord_max_noise_size) noise_it.add_after_then_move (src_it.extract ()); } for (src_it.mark_cycle_pt (); !src_it.cycled_list (); src_it.forward ()) { size_stats.add (src_it.data ()->bounding_box ().height (), 1); } min_y = floor (size_stats.ile (textord_blob_size_smallile / 100.0)); max_y = ceil (size_stats.ile (textord_blob_size_bigile / 100.0)); max_x = ceil (size_stats.ile (0.5) * textord_width_limit); for (src_it.mark_cycle_pt (); !src_it.cycled_list (); src_it.forward ()) { height = src_it.data ()->bounding_box ().height (); width = src_it.data ()->bounding_box ().width (); if (height < min_y) small_it.add_after_then_move (src_it.extract ()); else if (height > max_y || width > max_x) large_it.add_after_then_move (src_it.extract ()); } return size_stats.ile (textord_initialx_ile); } /********************************************************************** * filter_noise_blobs2 * * Move small blobs to a separate list. **********************************************************************/ float filter_noise_blobs2( //separate noise BLOBNBOX_LIST *src_list, //origonal list BLOBNBOX_LIST *noise_list, //noise list BLOBNBOX_LIST *small_list, //small blobs BLOBNBOX_LIST *large_list //large blobs ) { inT16 height; //height of blob inT16 width; //of blob BLOBNBOX *blob; //current blob float initial_x; //first guess BLOBNBOX_IT src_it = src_list; //iterators BLOBNBOX_IT noise_it = noise_list; BLOBNBOX_IT small_it = small_list; BLOBNBOX_IT large_it = large_list; STATS size_stats (0, MAX_NEAREST_DIST); //blob heights float min_y; //size limits float max_y; float max_x; float max_height; //of good blobs for (src_it.mark_cycle_pt (); !src_it.cycled_list (); src_it.forward ()) { blob = src_it.data (); if (blob->bounding_box ().height () < textord_max_noise_size) noise_it.add_after_then_move (src_it.extract ()); else if (blob->enclosed_area () >= blob->bounding_box ().height () * blob->bounding_box ().width () * textord_noise_area_ratio) small_it.add_after_then_move (src_it.extract ()); } for (src_it.mark_cycle_pt (); !src_it.cycled_list (); src_it.forward ()) { size_stats.add (src_it.data ()->bounding_box ().height (), 1); } initial_x = size_stats.ile (textord_initialx_ile); max_y = ceil (initial_x * (textord_merge_desc + textord_merge_x + 2 * textord_merge_asc) / textord_merge_x); min_y = floor (initial_x / 2); max_x = ceil (initial_x * textord_width_limit); small_it.move_to_first (); for (small_it.mark_cycle_pt (); !small_it.cycled_list (); small_it.forward ()) { height = small_it.data()->bounding_box().height(); if (height > max_y) large_it.add_after_then_move(small_it.extract ()); else if (height >= min_y) src_it.add_after_then_move(small_it.extract ()); } size_stats.clear (); for (src_it.mark_cycle_pt (); !src_it.cycled_list (); src_it.forward ()) { height = src_it.data ()->bounding_box ().height (); width = src_it.data ()->bounding_box ().width (); if (height < min_y) small_it.add_after_then_move (src_it.extract ()); else if (height > max_y || width > max_x) large_it.add_after_then_move (src_it.extract ()); else size_stats.add (height, 1); } max_height = size_stats.ile (textord_initialasc_ile); // printf("max_y=%g, min_y=%g, initial_x=%g, max_height=%g,", // max_y,min_y,initial_x,max_height); max_height *= textord_merge_x / (textord_merge_x + textord_merge_asc); if (max_height > initial_x) initial_x = max_height; // printf(" ret=%g\n",initial_x); return initial_x; } /********************************************************************** * textord_page * * Textord the list of blobs and return a list of proper blocks. **********************************************************************/ void textord_page( //make rows & words ICOORD page_tr, //top right BLOCK_LIST *blocks, //block list TO_BLOCK_LIST *land_blocks, //rotated for landscape TO_BLOCK_LIST *port_blocks, //output list tesseract::Tesseract* tess ) { float gradient; //global skew set_global_loc_code(LOC_TEXT_ORD_ROWS); gradient = make_rows (page_tr, blocks, land_blocks, port_blocks, tess); if (global_monitor != NULL) { global_monitor->ocr_alive = TRUE; global_monitor->progress = 20; } set_global_loc_code(LOC_TEXT_ORD_WORDS); make_words(page_tr, gradient, blocks, land_blocks, port_blocks, tess); if (global_monitor != NULL) { global_monitor->ocr_alive = TRUE; global_monitor->progress = 30; } cleanup_blocks(blocks); //remove empties #ifndef GRAPHICS_DISABLED close_to_win(); #endif if (textord_exit_after && !interactive_mode) exit (0); } /********************************************************************** * cleanup_blocks * * Delete empty blocks, rows from the page. **********************************************************************/ void cleanup_blocks( //remove empties BLOCK_LIST *blocks //list ) { BLOCK_IT block_it = blocks; //iterator ROW_IT row_it; //row iterator for (block_it.mark_cycle_pt (); !block_it.cycled_list (); block_it.forward ()) { row_it.set_to_list (block_it.data ()->row_list ()); for (row_it.mark_cycle_pt (); !row_it.cycled_list (); row_it.forward ()) { clean_small_noise_from_words(row_it.data()); if ((textord_noise_rejrows && !row_it.data ()->word_list ()->empty () && clean_noise_from_row (row_it.data ())) || row_it.data ()->word_list ()->empty ()) delete row_it.extract ();//lose empty row else { if (textord_noise_rejwords) clean_noise_from_words (row_it.data ()); if (textord_blshift_maxshift >= 0) tweak_row_baseline (row_it.data ()); } } if (block_it.data ()->row_list ()->empty ()) { delete block_it.extract ();//lose empty block } } } /********************************************************************** * clean_noise_from_row * * Move blobs of words from rows of garbage into the reject blobs list. **********************************************************************/ BOOL8 clean_noise_from_row( //remove empties ROW *row //row to clean ) { BOOL8 testing_on; TBOX blob_box; //bounding box C_BLOB *blob; //current blob C_OUTLINE *outline; //current outline WERD *word; //current word inT32 blob_size; //biggest size inT32 trans_count = 0; //no of transitions inT32 trans_threshold; //noise tolerance inT32 dot_count; //small objects inT32 norm_count; //normal objects inT32 super_norm_count; //real char-like //words of row WERD_IT word_it = row->word_list (); C_BLOB_IT blob_it; //blob iterator C_OUTLINE_IT out_it; //outline iterator if (textord_test_y > row->base_line (textord_test_x) && textord_show_blobs && textord_test_y < row->base_line (textord_test_x) + row->x_height ()) testing_on = TRUE; else testing_on = FALSE; dot_count = 0; norm_count = 0; super_norm_count = 0; for (word_it.mark_cycle_pt (); !word_it.cycled_list (); word_it.forward ()) { word = word_it.data (); //current word //blobs in word blob_it.set_to_list (word->cblob_list ()); for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); if (!word->flag (W_DONT_CHOP)) { //get outlines out_it.set_to_list (blob->out_list ()); for (out_it.mark_cycle_pt (); !out_it.cycled_list (); out_it.forward ()) { outline = out_it.data (); blob_box = outline->bounding_box (); blob_size = blob_box.width () > blob_box.height ()? blob_box.width () : blob_box. height(); if (blob_size < textord_noise_sizelimit * row->x_height ()) dot_count++; //count smal outlines if (!outline->child ()->empty () && blob_box.height () < (1 + textord_noise_syfract) * row->x_height () && blob_box.height () > (1 - textord_noise_syfract) * row->x_height () && blob_box.width () < (1 + textord_noise_sxfract) * row->x_height () && blob_box.width () > (1 - textord_noise_sxfract) * row->x_height ()) super_norm_count++; //count smal outlines } } else super_norm_count++; blob_box = blob->bounding_box (); blob_size = blob_box.width () > blob_box.height ()? blob_box.width () : blob_box.height (); if (blob_size >= textord_noise_sizelimit * row->x_height () && blob_size < row->x_height () * 2) { trans_threshold = blob_size / textord_noise_sizefraction; trans_count = blob->count_transitions (trans_threshold); if (trans_count < textord_noise_translimit) norm_count++; } else if (blob_box.height () > row->x_height () * 2 && (!word_it.at_first () || !blob_it.at_first ())) dot_count += 2; #ifndef SECURE_NAMES if (testing_on) { tprintf ("Blob at (%d,%d) -> (%d,%d), ols=%d, tc=%d, bldiff=%g\n", blob_box.left (), blob_box.bottom (), blob_box.right (), blob_box.top (), blob->out_list ()->length (), trans_count, blob_box.bottom () - row->base_line (blob_box.left ())); } #endif } } #ifndef SECURE_NAMES if (textord_noise_debug) { tprintf ("Row ending at (%d,%g):", blob_box.right (), row->base_line (blob_box.right ())); tprintf (" R=%g, dc=%d, nc=%d, %s\n", norm_count > 0 ? (float) dot_count / norm_count : 9999, dot_count, norm_count, dot_count > norm_count * textord_noise_normratio && dot_count > 2 ? "REJECTED" : "ACCEPTED"); } #endif return super_norm_count < textord_noise_sncount && dot_count > norm_count * textord_noise_rowratio && dot_count > 2; } /********************************************************************** * clean_noise_from_words * * Move blobs of words from rows of garbage into the reject blobs list. **********************************************************************/ void clean_noise_from_words( //remove empties ROW *row //row to clean ) { TBOX blob_box; //bounding box inT8 *word_dud; //was it chucked C_BLOB *blob; //current blob C_OUTLINE *outline; //current outline WERD *word; //current word inT32 blob_size; //biggest size inT32 trans_count; //no of transitions inT32 trans_threshold; //noise tolerance inT32 dot_count; //small objects inT32 norm_count; //normal objects inT32 dud_words; //number discarded inT32 ok_words; //number remaining inT32 word_index; //current word //words of row WERD_IT word_it = row->word_list (); C_BLOB_IT blob_it; //blob iterator C_OUTLINE_IT out_it; //outline iterator ok_words = word_it.length (); if (ok_words == 0 || textord_no_rejects) return; word_dud = (inT8 *) alloc_mem (ok_words * sizeof (inT8)); dud_words = 0; ok_words = 0; word_index = 0; for (word_it.mark_cycle_pt (); !word_it.cycled_list (); word_it.forward ()) { word = word_it.data (); //current word dot_count = 0; norm_count = 0; //blobs in word blob_it.set_to_list (word->cblob_list ()); for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); if (!word->flag (W_DONT_CHOP)) { //get outlines out_it.set_to_list (blob->out_list ()); for (out_it.mark_cycle_pt (); !out_it.cycled_list (); out_it.forward ()) { outline = out_it.data (); blob_box = outline->bounding_box (); blob_size = blob_box.width () > blob_box.height ()? blob_box.width () : blob_box. height(); if (blob_size < textord_noise_sizelimit * row->x_height ()) dot_count++; //count smal outlines if (!outline->child ()->empty () && blob_box.height () < (1 + textord_noise_syfract) * row->x_height () && blob_box.height () > (1 - textord_noise_syfract) * row->x_height () && blob_box.width () < (1 + textord_noise_sxfract) * row->x_height () && blob_box.width () > (1 - textord_noise_sxfract) * row->x_height ()) norm_count++; //count smal outlines } } else norm_count++; blob_box = blob->bounding_box (); blob_size = blob_box.width () > blob_box.height ()? blob_box.width () : blob_box.height (); if (blob_size >= textord_noise_sizelimit * row->x_height () && blob_size < row->x_height () * 2) { trans_threshold = blob_size / textord_noise_sizefraction; trans_count = blob->count_transitions (trans_threshold); if (trans_count < textord_noise_translimit) norm_count++; } else if (blob_box.height () > row->x_height () * 2 && (!word_it.at_first () || !blob_it.at_first ())) dot_count += 2; } if (dot_count > 2) { if (dot_count > norm_count * textord_noise_normratio * 2) word_dud[word_index] = 2; else if (dot_count > norm_count * textord_noise_normratio) word_dud[word_index] = 1; else word_dud[word_index] = 0; } else word_dud[word_index] = 0; if (word_dud[word_index] == 2) dud_words++; else ok_words++; word_index++; } word_index = 0; for (word_it.mark_cycle_pt (); !word_it.cycled_list (); word_it.forward ()) { if (word_dud[word_index] == 2 || (word_dud[word_index] == 1 && dud_words > ok_words)) { word = word_it.data (); //current word //rejected blobs blob_it.set_to_list (word->rej_cblob_list ()); //move from blobs blob_it.add_list_after (word->cblob_list ()); } word_index++; } free_mem(word_dud); } // Remove outlines that are a tiny fraction in either width or height // of the word height. void clean_small_noise_from_words(ROW *row) { WERD_IT word_it(row->word_list()); for (word_it.mark_cycle_pt(); !word_it.cycled_list(); word_it.forward()) { WERD* word = word_it.data(); int min_size = static_cast( textord_noise_hfract * word->bounding_box().height() + 0.5); C_BLOB_IT blob_it(word->cblob_list()); for (blob_it.mark_cycle_pt(); !blob_it.cycled_list(); blob_it.forward()) { C_BLOB* blob = blob_it.data(); C_OUTLINE_IT out_it(blob->out_list()); for (out_it.mark_cycle_pt(); !out_it.cycled_list(); out_it.forward()) { C_OUTLINE* outline = out_it.data(); outline->RemoveSmallRecursive(min_size, &out_it); } if (blob->out_list()->empty()) { delete blob_it.extract(); } } if (word->cblob_list()->empty()) { if (!word_it.at_last()) { // The next word is no longer a fuzzy non space if it was before, // since the word before is about to be deleted. WERD* next_word = word_it.data_relative(1); if (next_word->flag(W_FUZZY_NON)) { next_word->set_flag(W_FUZZY_NON, false); } } delete word_it.extract(); } } } /********************************************************************** * tweak_row_baseline * * Shift baseline to fit the blobs more accurately where they are * close enough. **********************************************************************/ void tweak_row_baseline( //remove empties ROW *row //row to clean ) { TBOX blob_box; //bounding box C_BLOB *blob; //current blob WERD *word; //current word inT32 blob_count; //no of blobs inT32 src_index; //source segment inT32 dest_index; //destination segment inT32 *xstarts; //spline segments double *coeffs; //spline coeffs float ydiff; //baseline error float x_centre; //centre of blob //words of row WERD_IT word_it = row->word_list (); C_BLOB_IT blob_it; //blob iterator blob_count = 0; for (word_it.mark_cycle_pt (); !word_it.cycled_list (); word_it.forward ()) { word = word_it.data (); //current word //get total blobs blob_count += word->cblob_list ()->length (); } if (blob_count == 0) return; xstarts = (inT32 *) alloc_mem ((blob_count + row->baseline.segments + 1) * sizeof (inT32)); coeffs = (double *) alloc_mem ((blob_count + row->baseline.segments) * 3 * sizeof (double)); src_index = 0; dest_index = 0; xstarts[0] = row->baseline.xcoords[0]; for (word_it.mark_cycle_pt (); !word_it.cycled_list (); word_it.forward ()) { word = word_it.data (); //current word //blobs in word blob_it.set_to_list (word->cblob_list ()); for (blob_it.mark_cycle_pt (); !blob_it.cycled_list (); blob_it.forward ()) { blob = blob_it.data (); blob_box = blob->bounding_box (); x_centre = (blob_box.left () + blob_box.right ()) / 2.0; ydiff = blob_box.bottom () - row->base_line (x_centre); if (ydiff < 0) ydiff = -ydiff / row->x_height (); else ydiff = ydiff / row->x_height (); if (ydiff < textord_blshift_maxshift && blob_box.height () / row->x_height () > textord_blshift_xfraction) { if (xstarts[dest_index] >= x_centre) xstarts[dest_index] = blob_box.left (); coeffs[dest_index * 3] = 0; coeffs[dest_index * 3 + 1] = 0; coeffs[dest_index * 3 + 2] = blob_box.bottom (); //shift it dest_index++; xstarts[dest_index] = blob_box.right () + 1; } else { if (xstarts[dest_index] <= x_centre) { while (row->baseline.xcoords[src_index + 1] <= x_centre && src_index < row->baseline.segments - 1) { if (row->baseline.xcoords[src_index + 1] > xstarts[dest_index]) { coeffs[dest_index * 3] = row->baseline.quadratics[src_index].a; coeffs[dest_index * 3 + 1] = row->baseline.quadratics[src_index].b; coeffs[dest_index * 3 + 2] = row->baseline.quadratics[src_index].c; dest_index++; xstarts[dest_index] = row->baseline.xcoords[src_index + 1]; } src_index++; } coeffs[dest_index * 3] = row->baseline.quadratics[src_index].a; coeffs[dest_index * 3 + 1] = row->baseline.quadratics[src_index].b; coeffs[dest_index * 3 + 2] = row->baseline.quadratics[src_index].c; dest_index++; xstarts[dest_index] = row->baseline.xcoords[src_index + 1]; } } } } while (src_index < row->baseline.segments && row->baseline.xcoords[src_index + 1] <= xstarts[dest_index]) src_index++; while (src_index < row->baseline.segments) { coeffs[dest_index * 3] = row->baseline.quadratics[src_index].a; coeffs[dest_index * 3 + 1] = row->baseline.quadratics[src_index].b; coeffs[dest_index * 3 + 2] = row->baseline.quadratics[src_index].c; dest_index++; src_index++; xstarts[dest_index] = row->baseline.xcoords[src_index]; } //turn to spline row->baseline = QSPLINE (dest_index, xstarts, coeffs); free_mem(xstarts); free_mem(coeffs); } /********************************************************************** * blob_y_order * * Sort function to sort blobs in y from page top. **********************************************************************/ inT32 blob_y_order( //sort function void *item1, //items to compare void *item2) { //converted ptr BLOBNBOX *blob1 = *(BLOBNBOX **) item1; //converted ptr BLOBNBOX *blob2 = *(BLOBNBOX **) item2; if (blob1->bounding_box ().bottom () > blob2->bounding_box ().bottom ()) return -1; else if (blob1->bounding_box ().bottom () < blob2->bounding_box ().bottom ()) return 1; else { if (blob1->bounding_box ().left () < blob2->bounding_box ().left ()) return -1; else if (blob1->bounding_box ().left () > blob2->bounding_box ().left ()) return 1; else return 0; } }