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view mupdf-source/thirdparty/tesseract/src/ccstruct/blobbox.cpp @ 2:b50eed0cc0ef upstream
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| author | Franz Glasner <fzglas.hg@dom66.de> |
|---|---|
| date | Mon, 15 Sep 2025 11:43:07 +0200 |
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/********************************************************************** * File: blobbox.cpp (Formerly blobnbox.c) * Description: Code for the textord blob class. * Author: Ray Smith * * (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 automatically generated configuration file if running autoconf. #ifdef HAVE_CONFIG_H # include "config_auto.h" #endif #include "blobbox.h" #include "blobs.h" // for TPOINT #include "coutln.h" // for C_OUTLINE_IT, C_OUTLINE, C_OUTLINE_LIST #include "environ.h" // for l_uint32 #include "host.h" // for NearlyEqual #include "points.h" // for operator+=, ICOORD::rotate #include "helpers.h" // for UpdateRange, IntCastRounded #include <allheaders.h> // for pixGetHeight, pixGetPixel #include <algorithm> // for max, min #include <cmath> #include <cstdint> // for INT32_MAX, INT16_MAX #define PROJECTION_MARGIN 10 // arbitrary namespace tesseract { // Up to 30 degrees is allowed for rotations of diacritic blobs. const double kCosSmallAngle = 0.866; // Min aspect ratio for a joined word to indicate an obvious flow direction. const double kDefiniteAspectRatio = 2.0; // Multiple of short length in perimeter to make a joined word. const double kComplexShapePerimeterRatio = 1.5; // Min multiple of linesize for medium-sized blobs in ReFilterBlobs. const double kMinMediumSizeRatio = 0.25; // Max multiple of linesize for medium-sized blobs in ReFilterBlobs. const double kMaxMediumSizeRatio = 4.0; // Rotates the box and the underlying blob. void BLOBNBOX::rotate(FCOORD rotation) { cblob_ptr->rotate(rotation); rotate_box(rotation); compute_bounding_box(); } // Reflect the box in the y-axis, leaving the underlying blob untouched. void BLOBNBOX::reflect_box_in_y_axis() { int left = -box.right(); box.set_right(-box.left()); box.set_left(left); } // Rotates the box by the angle given by rotation. // If the blob is a diacritic, then only small rotations for skew // correction can be applied. void BLOBNBOX::rotate_box(FCOORD rotation) { if (IsDiacritic()) { ASSERT_HOST(rotation.x() >= kCosSmallAngle); ICOORD top_pt((box.left() + box.right()) / 2, base_char_top_); ICOORD bottom_pt(top_pt.x(), base_char_bottom_); top_pt.rotate(rotation); base_char_top_ = top_pt.y(); bottom_pt.rotate(rotation); base_char_bottom_ = bottom_pt.y(); box.rotate(rotation); } else { box.rotate(rotation); set_diacritic_box(box); } } /********************************************************************** * BLOBNBOX::merge * * Merge this blob with the given blob, which should be after this. **********************************************************************/ void BLOBNBOX::merge( // merge blobs BLOBNBOX *nextblob // blob to join with ) { box += nextblob->box; // merge boxes set_diacritic_box(box); nextblob->joined = true; } // Merge this with other, taking the outlines from other. // Other is not deleted, but left for the caller to handle. void BLOBNBOX::really_merge(BLOBNBOX *other) { if (other->cblob_ptr != nullptr) { C_OUTLINE_IT ol_it(cblob_ptr->out_list()); ol_it.add_list_after(other->cblob_ptr->out_list()); } compute_bounding_box(); } /********************************************************************** * BLOBNBOX::chop * * Chop this blob into equal sized pieces using the x height as a guide. * The blob is not actually chopped. Instead, fake blobs are inserted * with the relevant bounding boxes. **********************************************************************/ void BLOBNBOX::chop( // chop blobs BLOBNBOX_IT *start_it, // location of this BLOBNBOX_IT *end_it, // iterator FCOORD rotation, // for landscape float xheight // of line ) { int16_t blobcount; // no of blobs BLOBNBOX *newblob; // fake blob BLOBNBOX *blob; // current blob int16_t blobindex; // number of chop int16_t leftx; // left edge of blob float blobwidth; // width of each float rightx; // right edge to scan float ymin, ymax; // limits of new blob float test_ymin, test_ymax; // limits of part blob ICOORD bl, tr; // corners of box BLOBNBOX_IT blob_it; // blob iterator // get no of chops blobcount = static_cast<int16_t>(std::floor(box.width() / xheight)); if (blobcount > 1 && cblob_ptr != nullptr) { // width of each blobwidth = static_cast<float>(box.width() + 1) / blobcount; for (blobindex = blobcount - 1, rightx = box.right(); blobindex >= 0; blobindex--, rightx -= blobwidth) { ymin = static_cast<float>(INT32_MAX); ymax = static_cast<float>(-INT32_MAX); blob_it = *start_it; do { blob = blob_it.data(); find_cblob_vlimits(blob->cblob_ptr, rightx - blobwidth, rightx, /*rotation, */ test_ymin, test_ymax); blob_it.forward(); UpdateRange(test_ymin, test_ymax, &ymin, &ymax); } while (blob != end_it->data()); if (ymin < ymax) { leftx = static_cast<int16_t>(std::floor(rightx - blobwidth)); if (leftx < box.left()) { leftx = box.left(); // clip to real box } bl = ICOORD(leftx, static_cast<int16_t>(std::floor(ymin))); tr = ICOORD(static_cast<int16_t>(std::ceil(rightx)), static_cast<int16_t>(std::ceil(ymax))); if (blobindex == 0) { box = TBOX(bl, tr); // change box } else { newblob = new BLOBNBOX; // box is all it has newblob->box = TBOX(bl, tr); // stay on current newblob->base_char_top_ = tr.y(); newblob->base_char_bottom_ = bl.y(); end_it->add_after_stay_put(newblob); } } } } } // Returns the box gaps between this and its neighbours_ in an array // indexed by BlobNeighbourDir. void BLOBNBOX::NeighbourGaps(int gaps[BND_COUNT]) const { for (int dir = 0; dir < BND_COUNT; ++dir) { gaps[dir] = INT16_MAX; BLOBNBOX *neighbour = neighbours_[dir]; if (neighbour != nullptr) { const TBOX &n_box = neighbour->bounding_box(); if (dir == BND_LEFT || dir == BND_RIGHT) { gaps[dir] = box.x_gap(n_box); } else { gaps[dir] = box.y_gap(n_box); } } } } // Returns the min and max horizontal and vertical gaps (from NeighbourGaps) // modified so that if the max exceeds the max dimension of the blob, and // the min is less, the max is replaced with the min. // The objective is to catch cases where there is only a single neighbour // and avoid reporting the other gap as a ridiculously large number void BLOBNBOX::MinMaxGapsClipped(int *h_min, int *h_max, int *v_min, int *v_max) const { int max_dimension = std::max(box.width(), box.height()); int gaps[BND_COUNT]; NeighbourGaps(gaps); *h_min = std::min(gaps[BND_LEFT], gaps[BND_RIGHT]); *h_max = std::max(gaps[BND_LEFT], gaps[BND_RIGHT]); if (*h_max > max_dimension && *h_min < max_dimension) { *h_max = *h_min; } *v_min = std::min(gaps[BND_ABOVE], gaps[BND_BELOW]); *v_max = std::max(gaps[BND_ABOVE], gaps[BND_BELOW]); if (*v_max > max_dimension && *v_min < max_dimension) { *v_max = *v_min; } } // Nulls out any neighbours that are DeletableNoise to remove references. void BLOBNBOX::CleanNeighbours() { for (int dir = 0; dir < BND_COUNT; ++dir) { BLOBNBOX *neighbour = neighbours_[dir]; if (neighbour != nullptr && neighbour->DeletableNoise()) { neighbours_[dir] = nullptr; good_stroke_neighbours_[dir] = false; } } } // Returns positive if there is at least one side neighbour that has a similar // stroke width and is not on the other side of a rule line. int BLOBNBOX::GoodTextBlob() const { int score = 0; for (int dir = 0; dir < BND_COUNT; ++dir) { auto bnd = static_cast<BlobNeighbourDir>(dir); if (good_stroke_neighbour(bnd)) { ++score; } } return score; } // Returns the number of side neighbours that are of type BRT_NOISE. int BLOBNBOX::NoisyNeighbours() const { int count = 0; for (int dir = 0; dir < BND_COUNT; ++dir) { auto bnd = static_cast<BlobNeighbourDir>(dir); BLOBNBOX *blob = neighbour(bnd); if (blob != nullptr && blob->region_type() == BRT_NOISE) { ++count; } } return count; } // Returns true, and sets vert_possible/horz_possible if the blob has some // feature that makes it individually appear to flow one way. // eg if it has a high aspect ratio, yet has a complex shape, such as a // joined word in Latin, Arabic, or Hindi, rather than being a -, I, l, 1 etc. bool BLOBNBOX::DefiniteIndividualFlow() { if (cblob() == nullptr) { return false; } int box_perimeter = 2 * (box.height() + box.width()); if (box.width() > box.height() * kDefiniteAspectRatio) { // Attempt to distinguish a wide joined word from a dash. // If it is a dash, then its perimeter is approximately // 2 * (box width + stroke width), but more if the outline is noisy, // so perimeter - 2*(box width + stroke width) should be close to zero. // A complex shape such as a joined word should have a much larger value. int perimeter = cblob()->perimeter(); if (vert_stroke_width() > 0 || perimeter <= 0) { perimeter -= 2 * vert_stroke_width(); } else { perimeter -= 4 * cblob()->area() / perimeter; } perimeter -= 2 * box.width(); // Use a multiple of the box perimeter as a threshold. if (perimeter > kComplexShapePerimeterRatio * box_perimeter) { set_vert_possible(false); set_horz_possible(true); return true; } } if (box.height() > box.width() * kDefiniteAspectRatio) { // As above, but for a putative vertical word vs a I/1/l. int perimeter = cblob()->perimeter(); if (horz_stroke_width() > 0 || perimeter <= 0) { perimeter -= 2 * horz_stroke_width(); } else { perimeter -= 4 * cblob()->area() / perimeter; } perimeter -= 2 * box.height(); if (perimeter > kComplexShapePerimeterRatio * box_perimeter) { set_vert_possible(true); set_horz_possible(false); return true; } } return false; } // Returns true if there is no tabstop violation in merging this and other. bool BLOBNBOX::ConfirmNoTabViolation(const BLOBNBOX &other) const { if (box.left() < other.box.left() && box.left() < other.left_rule_) { return false; } if (other.box.left() < box.left() && other.box.left() < left_rule_) { return false; } if (box.right() > other.box.right() && box.right() > other.right_rule_) { return false; } if (other.box.right() > box.right() && other.box.right() > right_rule_) { return false; } return true; } // Returns true if other has a similar stroke width to this. bool BLOBNBOX::MatchingStrokeWidth(const BLOBNBOX &other, double fractional_tolerance, double constant_tolerance) const { // The perimeter-based width is used as a backup in case there is // no information in the blob. double p_width = area_stroke_width(); double n_p_width = other.area_stroke_width(); float h_tolerance = horz_stroke_width_ * fractional_tolerance + constant_tolerance; float v_tolerance = vert_stroke_width_ * fractional_tolerance + constant_tolerance; double p_tolerance = p_width * fractional_tolerance + constant_tolerance; bool h_zero = horz_stroke_width_ == 0.0f || other.horz_stroke_width_ == 0.0f; bool v_zero = vert_stroke_width_ == 0.0f || other.vert_stroke_width_ == 0.0f; bool h_ok = !h_zero && NearlyEqual(horz_stroke_width_, other.horz_stroke_width_, h_tolerance); bool v_ok = !v_zero && NearlyEqual(vert_stroke_width_, other.vert_stroke_width_, v_tolerance); bool p_ok = h_zero && v_zero && NearlyEqual(p_width, n_p_width, p_tolerance); // For a match, at least one of the horizontal and vertical widths // must match, and the other one must either match or be zero. // Only if both are zero will we look at the perimeter metric. return p_ok || ((v_ok || h_ok) && (h_ok || h_zero) && (v_ok || v_zero)); } // Returns a bounding box of the outline contained within the // given horizontal range. TBOX BLOBNBOX::BoundsWithinLimits(int left, int right) { FCOORD no_rotation(1.0f, 0.0f); float top = box.top(); float bottom = box.bottom(); if (cblob_ptr != nullptr) { find_cblob_limits(cblob_ptr, static_cast<float>(left), static_cast<float>(right), no_rotation, bottom, top); } if (top < bottom) { top = box.top(); bottom = box.bottom(); } FCOORD bot_left(left, bottom); FCOORD top_right(right, top); TBOX shrunken_box(bot_left); TBOX shrunken_box2(top_right); shrunken_box += shrunken_box2; return shrunken_box; } // Estimates and stores the baseline position based on the shape of the // outline. void BLOBNBOX::EstimateBaselinePosition() { baseline_y_ = box.bottom(); // The default. if (cblob_ptr == nullptr) { return; } baseline_y_ = cblob_ptr->EstimateBaselinePosition(); } // Helper to call CleanNeighbours on all blobs on the list. void BLOBNBOX::CleanNeighbours(BLOBNBOX_LIST *blobs) { BLOBNBOX_IT blob_it(blobs); for (blob_it.mark_cycle_pt(); !blob_it.cycled_list(); blob_it.forward()) { blob_it.data()->CleanNeighbours(); } } // Helper to delete all the deletable blobs on the list. void BLOBNBOX::DeleteNoiseBlobs(BLOBNBOX_LIST *blobs) { BLOBNBOX_IT blob_it(blobs); for (blob_it.mark_cycle_pt(); !blob_it.cycled_list(); blob_it.forward()) { BLOBNBOX *blob = blob_it.data(); if (blob->DeletableNoise()) { delete blob->remove_cblob(); delete blob_it.extract(); } } } // Helper to compute edge offsets for all the blobs on the list. // See coutln.h for an explanation of edge offsets. void BLOBNBOX::ComputeEdgeOffsets(Image thresholds, Image grey, BLOBNBOX_LIST *blobs) { int grey_height = 0; int thr_height = 0; int scale_factor = 1; if (thresholds != nullptr && grey != nullptr) { grey_height = pixGetHeight(grey); thr_height = pixGetHeight(thresholds); scale_factor = IntCastRounded(static_cast<double>(grey_height) / thr_height); } BLOBNBOX_IT blob_it(blobs); for (blob_it.mark_cycle_pt(); !blob_it.cycled_list(); blob_it.forward()) { BLOBNBOX *blob = blob_it.data(); if (blob->cblob() != nullptr) { // Get the threshold that applies to this blob. l_uint32 threshold = 128; if (thresholds != nullptr && grey != nullptr) { const TBOX &box = blob->cblob()->bounding_box(); // Transform the coordinates if required. TPOINT pt((box.left() + box.right()) / 2, (box.top() + box.bottom()) / 2); pixGetPixel(thresholds, pt.x / scale_factor, thr_height - 1 - pt.y / scale_factor, &threshold); } blob->cblob()->ComputeEdgeOffsets(threshold, grey); } } } #ifndef GRAPHICS_DISABLED // Helper to draw all the blobs on the list in the given body_colour, // with child outlines in the child_colour. void BLOBNBOX::PlotBlobs(BLOBNBOX_LIST *list, ScrollView::Color body_colour, ScrollView::Color child_colour, ScrollView *win) { BLOBNBOX_IT it(list); for (it.mark_cycle_pt(); !it.cycled_list(); it.forward()) { it.data()->plot(win, body_colour, child_colour); } } // Helper to draw only DeletableNoise blobs (unowned, BRT_NOISE) on the // given list in the given body_colour, with child outlines in the // child_colour. void BLOBNBOX::PlotNoiseBlobs(BLOBNBOX_LIST *list, ScrollView::Color body_colour, ScrollView::Color child_colour, ScrollView *win) { BLOBNBOX_IT it(list); for (it.mark_cycle_pt(); !it.cycled_list(); it.forward()) { BLOBNBOX *blob = it.data(); if (blob->DeletableNoise()) { blob->plot(win, body_colour, child_colour); } } } ScrollView::Color BLOBNBOX::TextlineColor(BlobRegionType region_type, BlobTextFlowType flow_type) { switch (region_type) { case BRT_HLINE: return ScrollView::BROWN; case BRT_VLINE: return ScrollView::DARK_GREEN; case BRT_RECTIMAGE: return ScrollView::RED; case BRT_POLYIMAGE: return ScrollView::ORANGE; case BRT_UNKNOWN: return flow_type == BTFT_NONTEXT ? ScrollView::CYAN : ScrollView::WHITE; case BRT_VERT_TEXT: if (flow_type == BTFT_STRONG_CHAIN || flow_type == BTFT_TEXT_ON_IMAGE) { return ScrollView::GREEN; } if (flow_type == BTFT_CHAIN) { return ScrollView::LIME_GREEN; } return ScrollView::YELLOW; case BRT_TEXT: if (flow_type == BTFT_STRONG_CHAIN) { return ScrollView::BLUE; } if (flow_type == BTFT_TEXT_ON_IMAGE) { return ScrollView::LIGHT_BLUE; } if (flow_type == BTFT_CHAIN) { return ScrollView::MEDIUM_BLUE; } if (flow_type == BTFT_LEADER) { return ScrollView::WHEAT; } if (flow_type == BTFT_NONTEXT) { return ScrollView::PINK; } return ScrollView::MAGENTA; default: return ScrollView::GREY; } } // Keep in sync with BlobRegionType. ScrollView::Color BLOBNBOX::BoxColor() const { return TextlineColor(region_type_, flow_); } void BLOBNBOX::plot(ScrollView *window, // window to draw in ScrollView::Color blob_colour, // for outer bits ScrollView::Color child_colour) { // for holes if (cblob_ptr != nullptr) { cblob_ptr->plot(window, blob_colour, child_colour); } } #endif /********************************************************************** * find_cblob_limits * * Scan the outlines of the cblob to locate the y min and max * between the given x limits. **********************************************************************/ void find_cblob_limits( // get y limits C_BLOB *blob, // blob to search float leftx, // x limits float rightx, FCOORD rotation, // for landscape float &ymin, // output y limits float &ymax) { int16_t stepindex; // current point ICOORD pos; // current coords ICOORD vec; // rotated step C_OUTLINE *outline; // current outline // outlines C_OUTLINE_IT out_it = blob->out_list(); ymin = static_cast<float>(INT32_MAX); ymax = static_cast<float>(-INT32_MAX); for (out_it.mark_cycle_pt(); !out_it.cycled_list(); out_it.forward()) { outline = out_it.data(); pos = outline->start_pos(); // get coords pos.rotate(rotation); for (stepindex = 0; stepindex < outline->pathlength(); stepindex++) { // inside if (pos.x() >= leftx && pos.x() <= rightx) { UpdateRange(pos.y(), &ymin, &ymax); } vec = outline->step(stepindex); vec.rotate(rotation); pos += vec; // move to next } } } /********************************************************************** * find_cblob_vlimits * * Scan the outlines of the cblob to locate the y min and max * between the given x limits. **********************************************************************/ void find_cblob_vlimits( // get y limits C_BLOB *blob, // blob to search float leftx, // x limits float rightx, float &ymin, // output y limits float &ymax) { int16_t stepindex; // current point ICOORD pos; // current coords ICOORD vec; // rotated step C_OUTLINE *outline; // current outline // outlines C_OUTLINE_IT out_it = blob->out_list(); ymin = static_cast<float>(INT32_MAX); ymax = static_cast<float>(-INT32_MAX); for (out_it.mark_cycle_pt(); !out_it.cycled_list(); out_it.forward()) { outline = out_it.data(); pos = outline->start_pos(); // get coords for (stepindex = 0; stepindex < outline->pathlength(); stepindex++) { // inside if (pos.x() >= leftx && pos.x() <= rightx) { UpdateRange(pos.y(), &ymin, &ymax); } vec = outline->step(stepindex); pos += vec; // move to next } } } /********************************************************************** * find_cblob_hlimits * * Scan the outlines of the cblob to locate the x min and max * between the given y limits. **********************************************************************/ void find_cblob_hlimits( // get x limits C_BLOB *blob, // blob to search float bottomy, // y limits float topy, float &xmin, // output x limits float &xmax) { int16_t stepindex; // current point ICOORD pos; // current coords ICOORD vec; // rotated step C_OUTLINE *outline; // current outline // outlines C_OUTLINE_IT out_it = blob->out_list(); xmin = static_cast<float>(INT32_MAX); xmax = static_cast<float>(-INT32_MAX); for (out_it.mark_cycle_pt(); !out_it.cycled_list(); out_it.forward()) { outline = out_it.data(); pos = outline->start_pos(); // get coords for (stepindex = 0; stepindex < outline->pathlength(); stepindex++) { // inside if (pos.y() >= bottomy && pos.y() <= topy) { UpdateRange(pos.x(), &xmin, &xmax); } vec = outline->step(stepindex); pos += vec; // move to next } } } /********************************************************************** * crotate_cblob * * Rotate the copy by the given vector and return a C_BLOB. **********************************************************************/ C_BLOB *crotate_cblob( // rotate it C_BLOB *blob, // blob to search FCOORD rotation // for landscape ) { C_OUTLINE_LIST out_list; // output outlines // input outlines C_OUTLINE_IT in_it = blob->out_list(); // output outlines C_OUTLINE_IT out_it = &out_list; for (in_it.mark_cycle_pt(); !in_it.cycled_list(); in_it.forward()) { out_it.add_after_then_move(new C_OUTLINE(in_it.data(), rotation)); } return new C_BLOB(&out_list); } /********************************************************************** * box_next * * Compute the bounding box of this blob with merging of x overlaps * but no pre-chopping. * Then move the iterator on to the start of the next blob. **********************************************************************/ TBOX box_next( // get bounding box BLOBNBOX_IT *it // iterator to blobds ) { BLOBNBOX *blob; // current blob TBOX result; // total box blob = it->data(); result = blob->bounding_box(); do { it->forward(); blob = it->data(); if (blob->cblob() == nullptr) { // was pre-chopped result += blob->bounding_box(); } } // until next real blob while ((blob->cblob() == nullptr) || blob->joined_to_prev()); return result; } /********************************************************************** * box_next_pre_chopped * * Compute the bounding box of this blob with merging of x overlaps * but WITH pre-chopping. * Then move the iterator on to the start of the next pre-chopped blob. **********************************************************************/ TBOX box_next_pre_chopped( // get bounding box BLOBNBOX_IT *it // iterator to blobds ) { BLOBNBOX *blob; // current blob TBOX result; // total box blob = it->data(); result = blob->bounding_box(); do { it->forward(); blob = it->data(); } // until next real blob while (blob->joined_to_prev()); return result; } /********************************************************************** * TO_ROW::TO_ROW * * Constructor to make a row from a blob. **********************************************************************/ TO_ROW::TO_ROW( // constructor BLOBNBOX *blob, // first blob float top, // corrected top float bottom, // of row float row_size // ideal ) { clear(); y_min = bottom; y_max = top; initial_y_min = bottom; float diff; // in size BLOBNBOX_IT it = &blobs; // list of blobs it.add_to_end(blob); diff = top - bottom - row_size; if (diff > 0) { y_max -= diff / 2; y_min += diff / 2; } // very small object else if ((top - bottom) * 3 < row_size) { diff = row_size / 3 + bottom - top; y_max += diff / 2; y_min -= diff / 2; } } void TO_ROW::print() const { tprintf( "pitch=%d, fp=%g, fps=%g, fpns=%g, prs=%g, prns=%g," " spacing=%g xh=%g y_origin=%g xev=%d, asc=%g, desc=%g," " body=%g, minsp=%d maxnsp=%d, thr=%d kern=%g sp=%g\n", pitch_decision, fixed_pitch, fp_space, fp_nonsp, pr_space, pr_nonsp, spacing, xheight, y_origin, xheight_evidence, ascrise, descdrop, body_size, min_space, max_nonspace, space_threshold, kern_size, space_size); } /********************************************************************** * TO_ROW:add_blob * * Add the blob to the end of the row. **********************************************************************/ void TO_ROW::add_blob( // constructor BLOBNBOX *blob, // first blob float top, // corrected top float bottom, // of row float row_size // ideal ) { float allowed; // allowed expansion float available; // expansion BLOBNBOX_IT it = &blobs; // list of blobs it.add_to_end(blob); allowed = row_size + y_min - y_max; if (allowed > 0) { available = top > y_max ? top - y_max : 0; if (bottom < y_min) { // total available available += y_min - bottom; } if (available > 0) { available += available; // do it gradually if (available < allowed) { available = allowed; } if (bottom < y_min) { y_min -= (y_min - bottom) * allowed / available; } if (top > y_max) { y_max += (top - y_max) * allowed / available; } } } } /********************************************************************** * TO_ROW:insert_blob * * Add the blob to the row in the correct position. **********************************************************************/ void TO_ROW::insert_blob( // constructor BLOBNBOX *blob // first blob ) { BLOBNBOX_IT it = &blobs; // list of blobs if (it.empty()) { it.add_before_then_move(blob); } else { it.mark_cycle_pt(); while (!it.cycled_list() && it.data()->bounding_box().left() <= blob->bounding_box().left()) { it.forward(); } if (it.cycled_list()) { it.add_to_end(blob); } else { it.add_before_stay_put(blob); } } } /********************************************************************** * TO_ROW::compute_vertical_projection * * Compute the vertical projection of a TO_ROW from its blobs. **********************************************************************/ void TO_ROW::compute_vertical_projection() { // project whole row TBOX row_box; // bound of row BLOBNBOX *blob; // current blob TBOX blob_box; // bounding box BLOBNBOX_IT blob_it = blob_list(); if (blob_it.empty()) { return; } row_box = blob_it.data()->bounding_box(); for (blob_it.mark_cycle_pt(); !blob_it.cycled_list(); blob_it.forward()) { row_box += blob_it.data()->bounding_box(); } projection.set_range(row_box.left() - PROJECTION_MARGIN, row_box.right() + PROJECTION_MARGIN - 1); projection_left = row_box.left() - PROJECTION_MARGIN; projection_right = row_box.right() + PROJECTION_MARGIN; for (blob_it.mark_cycle_pt(); !blob_it.cycled_list(); blob_it.forward()) { blob = blob_it.data(); if (blob->cblob() != nullptr) { vertical_cblob_projection(blob->cblob(), &projection); } } } /********************************************************************** * TO_ROW::clear * * Zero out all scalar members. **********************************************************************/ void TO_ROW::clear() { all_caps = false; used_dm_model = false; projection_left = 0; projection_right = 0; pitch_decision = PITCH_DUNNO; fixed_pitch = 0.0; fp_space = 0.0; fp_nonsp = 0.0; pr_space = 0.0; pr_nonsp = 0.0; spacing = 0.0; xheight = 0.0; xheight_evidence = 0; body_size = 0.0; ascrise = 0.0; descdrop = 0.0; min_space = 0; max_nonspace = 0; space_threshold = 0; kern_size = 0.0; space_size = 0.0; y_min = 0.0; y_max = 0.0; initial_y_min = 0.0; m = 0.0; c = 0.0; error = 0.0; para_c = 0.0; para_error = 0.0; y_origin = 0.0; credibility = 0.0; num_repeated_sets_ = -1; } /********************************************************************** * vertical_cblob_projection * * Compute the vertical projection of a cblob from its outlines * and add to the given STATS. **********************************************************************/ void vertical_cblob_projection( // project outlines C_BLOB *blob, // blob to project STATS *stats // output ) { // outlines of blob C_OUTLINE_IT out_it = blob->out_list(); for (out_it.mark_cycle_pt(); !out_it.cycled_list(); out_it.forward()) { vertical_coutline_projection(out_it.data(), stats); } } /********************************************************************** * vertical_coutline_projection * * Compute the vertical projection of an outline from its outlines * and add to the given STATS. **********************************************************************/ void vertical_coutline_projection( // project outlines C_OUTLINE *outline, // outline to project STATS *stats // output ) { ICOORD pos; // current point ICOORD step; // edge step int32_t length; // of outline int16_t stepindex; // current step C_OUTLINE_IT out_it = outline->child(); pos = outline->start_pos(); length = outline->pathlength(); for (stepindex = 0; stepindex < length; stepindex++) { step = outline->step(stepindex); if (step.x() > 0) { stats->add(pos.x(), -pos.y()); } else if (step.x() < 0) { stats->add(pos.x() - 1, pos.y()); } pos += step; } for (out_it.mark_cycle_pt(); !out_it.cycled_list(); out_it.forward()) { vertical_coutline_projection(out_it.data(), stats); } } /********************************************************************** * TO_BLOCK::TO_BLOCK * * Constructor to make a TO_BLOCK from a real block. **********************************************************************/ TO_BLOCK::TO_BLOCK( // make a block BLOCK *src_block // real block ) { clear(); block = src_block; } /********************************************************************** * TO_BLOCK::clear * * Zero out all scalar members. **********************************************************************/ void TO_BLOCK::clear() { block = nullptr; pitch_decision = PITCH_DUNNO; line_spacing = 0.0; line_size = 0.0; max_blob_size = 0.0; baseline_offset = 0.0; xheight = 0.0; fixed_pitch = 0.0; kern_size = 0.0; space_size = 0.0; min_space = 0; max_nonspace = 0; fp_space = 0.0; fp_nonsp = 0.0; pr_space = 0.0; pr_nonsp = 0.0; key_row = nullptr; } TO_BLOCK::~TO_BLOCK() { // Any residual BLOBNBOXes at this stage own their blobs, so delete them. BLOBNBOX::clear_blobnboxes(&blobs); BLOBNBOX::clear_blobnboxes(&underlines); BLOBNBOX::clear_blobnboxes(&noise_blobs); BLOBNBOX::clear_blobnboxes(&small_blobs); BLOBNBOX::clear_blobnboxes(&large_blobs); } // Helper function to divide the input blobs over noise, small, medium // and large lists. Blobs small in height and (small in width or large in width) // go in the noise list. Dash (-) candidates go in the small list, and // medium and large are by height. // SIDE-EFFECT: reset all blobs to initial state by calling Init(). static void SizeFilterBlobs(int min_height, int max_height, BLOBNBOX_LIST *src_list, BLOBNBOX_LIST *noise_list, BLOBNBOX_LIST *small_list, BLOBNBOX_LIST *medium_list, BLOBNBOX_LIST *large_list) { BLOBNBOX_IT noise_it(noise_list); BLOBNBOX_IT small_it(small_list); BLOBNBOX_IT medium_it(medium_list); BLOBNBOX_IT large_it(large_list); for (BLOBNBOX_IT src_it(src_list); !src_it.empty(); src_it.forward()) { BLOBNBOX *blob = src_it.extract(); blob->ReInit(); int width = blob->bounding_box().width(); int height = blob->bounding_box().height(); if (height < min_height && (width < min_height || width > max_height)) { noise_it.add_after_then_move(blob); } else if (height > max_height) { large_it.add_after_then_move(blob); } else if (height < min_height) { small_it.add_after_then_move(blob); } else { medium_it.add_after_then_move(blob); } } } // Reorganize the blob lists with a different definition of small, medium // and large, compared to the original definition. // Height is still the primary filter key, but medium width blobs of small // height become small, and very wide blobs of small height stay noise, along // with small dot-shaped blobs. void TO_BLOCK::ReSetAndReFilterBlobs() { int min_height = IntCastRounded(kMinMediumSizeRatio * line_size); int max_height = IntCastRounded(kMaxMediumSizeRatio * line_size); BLOBNBOX_LIST noise_list; BLOBNBOX_LIST small_list; BLOBNBOX_LIST medium_list; BLOBNBOX_LIST large_list; SizeFilterBlobs(min_height, max_height, &blobs, &noise_list, &small_list, &medium_list, &large_list); SizeFilterBlobs(min_height, max_height, &large_blobs, &noise_list, &small_list, &medium_list, &large_list); SizeFilterBlobs(min_height, max_height, &small_blobs, &noise_list, &small_list, &medium_list, &large_list); SizeFilterBlobs(min_height, max_height, &noise_blobs, &noise_list, &small_list, &medium_list, &large_list); BLOBNBOX_IT blob_it(&blobs); blob_it.add_list_after(&medium_list); blob_it.set_to_list(&large_blobs); blob_it.add_list_after(&large_list); blob_it.set_to_list(&small_blobs); blob_it.add_list_after(&small_list); blob_it.set_to_list(&noise_blobs); blob_it.add_list_after(&noise_list); } // Deletes noise blobs from all lists where not owned by a ColPartition. void TO_BLOCK::DeleteUnownedNoise() { BLOBNBOX::CleanNeighbours(&blobs); BLOBNBOX::CleanNeighbours(&small_blobs); BLOBNBOX::CleanNeighbours(&noise_blobs); BLOBNBOX::CleanNeighbours(&large_blobs); BLOBNBOX::DeleteNoiseBlobs(&blobs); BLOBNBOX::DeleteNoiseBlobs(&small_blobs); BLOBNBOX::DeleteNoiseBlobs(&noise_blobs); BLOBNBOX::DeleteNoiseBlobs(&large_blobs); } // Computes and stores the edge offsets on each blob for use in feature // extraction, using greyscale if the supplied grey and thresholds pixes // are 8-bit or otherwise (if nullptr or not 8 bit) the original binary // edge step outlines. // Thresholds must either be the same size as grey or an integer down-scale // of grey. // See coutln.h for an explanation of edge offsets. void TO_BLOCK::ComputeEdgeOffsets(Image thresholds, Image grey) { BLOBNBOX::ComputeEdgeOffsets(thresholds, grey, &blobs); BLOBNBOX::ComputeEdgeOffsets(thresholds, grey, &small_blobs); BLOBNBOX::ComputeEdgeOffsets(thresholds, grey, &noise_blobs); } #ifndef GRAPHICS_DISABLED // Draw the noise blobs from all lists in red. void TO_BLOCK::plot_noise_blobs(ScrollView *win) { BLOBNBOX::PlotNoiseBlobs(&noise_blobs, ScrollView::RED, ScrollView::RED, win); BLOBNBOX::PlotNoiseBlobs(&small_blobs, ScrollView::RED, ScrollView::RED, win); BLOBNBOX::PlotNoiseBlobs(&large_blobs, ScrollView::RED, ScrollView::RED, win); BLOBNBOX::PlotNoiseBlobs(&blobs, ScrollView::RED, ScrollView::RED, win); } // Draw the blobs on the various lists in the block in different colors. void TO_BLOCK::plot_graded_blobs(ScrollView *win) { BLOBNBOX::PlotBlobs(&noise_blobs, ScrollView::CORAL, ScrollView::BLUE, win); BLOBNBOX::PlotBlobs(&small_blobs, ScrollView::GOLDENROD, ScrollView::YELLOW, win); BLOBNBOX::PlotBlobs(&large_blobs, ScrollView::DARK_GREEN, ScrollView::YELLOW, win); BLOBNBOX::PlotBlobs(&blobs, ScrollView::WHITE, ScrollView::BROWN, win); } /********************************************************************** * plot_blob_list * * Draw a list of blobs. **********************************************************************/ void plot_blob_list(ScrollView *win, // window to draw in BLOBNBOX_LIST *list, // blob list ScrollView::Color body_colour, // colour to draw ScrollView::Color child_colour) { // colour of child BLOBNBOX_IT it = list; for (it.mark_cycle_pt(); !it.cycled_list(); it.forward()) { it.data()->plot(win, body_colour, child_colour); } } #endif // !GRAPHICS_DISABLED } // namespace tesseract