C++ ROW::base_line方法代碼示例

/**
 * Returns the baseline of the current object at the given level.
 * The baseline is the line that passes through (x1, y1) and (x2, y2).
 * WARNING: with vertical text, baselines may be vertical!
 */
bool PageIterator::Baseline(PageIteratorLevel level,
                            int* x1, int* y1, int* x2, int* y2) const {
  if (it_->word() == NULL) return false;  // Already at the end!
  ROW* row = it_->row()->row;
  WERD* word = it_->word()->word;
  TBOX box = (level == RIL_WORD || level == RIL_SYMBOL)
           ? word->bounding_box()
           : row->bounding_box();
  int left = box.left();
  ICOORD startpt(left, static_cast<inT16>(row->base_line(left) + 0.5));
  int right = box.right();
  ICOORD endpt(right, static_cast<inT16>(row->base_line(right) + 0.5));
  // Rotate to image coordinates and convert to global image coords.
  startpt.rotate(it_->block()->block->re_rotation());
  endpt.rotate(it_->block()->block->re_rotation());
  *x1 = startpt.x() / scale_ + rect_left_;
  *y1 = (rect_height_ - startpt.y()) / scale_ + rect_top_;
  *x2 = endpt.x() / scale_ + rect_left_;
  *y2 = (rect_height_ - endpt.y()) / scale_ + rect_top_;
  return true;
}

// This method resolves the cc bbox to a particular row and returns the row's
// xheight.
int ShiroRekhaSplitter::GetXheightForCC(Box* cc_bbox) {
  if (!segmentation_block_list_) {
    return global_xheight_;
  }
  // Compute the box coordinates in Tesseract's coordinate system.
  TBOX bbox(cc_bbox->x,
            pixGetHeight(orig_pix_) - cc_bbox->y - cc_bbox->h - 1,
            cc_bbox->x + cc_bbox->w,
            pixGetHeight(orig_pix_) - cc_bbox->y - 1);
  // Iterate over all blocks.
  BLOCK_IT block_it(segmentation_block_list_);
  for (block_it.mark_cycle_pt(); !block_it.cycled_list(); block_it.forward()) {
    BLOCK* block = block_it.data();
    // Iterate over all rows in the block.
    ROW_IT row_it(block->row_list());
    for (row_it.mark_cycle_pt(); !row_it.cycled_list(); row_it.forward()) {
      ROW* row = row_it.data();
      if (!row->bounding_box().major_overlap(bbox)) {
        continue;
      }
      // Row could be skewed, warped, etc. Use the position of the box to
      // determine the baseline position of the row for that x-coordinate.
      // Create a square TBOX whose baseline's mid-point lies at this point
      // and side is row's xheight. Take the overlap of this box with the input
      // box and check if it is a 'major overlap'. If so, this box lies in this
      // row. In that case, return the xheight for this row.
      float box_middle = 0.5 * (bbox.left() + bbox.right());
      int baseline = static_cast<int>(row->base_line(box_middle) + 0.5);
      TBOX test_box(box_middle - row->x_height() / 2,
                    baseline,
                    box_middle + row->x_height() / 2,
                    static_cast<int>(baseline + row->x_height()));
      // Compute overlap. If it is is a major overlap, this is the right row.
      if (bbox.major_overlap(test_box)) {
        return row->x_height();
      }
    }
  }
  // No row found for this bbox.
  return kUnspecifiedXheight;
}

// Compute the distance from the left and right ends of each row to the
// left and right edges of the block's polyblock.  Illustration:
//  ____________________________   _______________________
//  |  Howdy neighbor!         |  |rectangular blocks look|
//  |  This text is  written to|  |more like stacked pizza|
//  |illustrate how useful poly-  |boxes.                 |
//  |blobs  are   in -----------  ------   The    polyblob|
//  |dealing    with|     _________     |for a BLOCK  rec-|
//  |harder   layout|   /===========\   |ords the possibly|
//  |issues.        |    |  _    _  |   |skewed    pseudo-|
//  |  You  see this|    | |_| \|_| |   |rectangular      |
//  |text is  flowed|    |      }   |   |boundary     that|
//  |around  a  mid-|     \   ____  |   |forms the  ideal-|
//  |cloumn portrait._____ \       /  __|ized  text margin|
//  |  Polyblobs     exist| \    /   |from which we should|
//  |to account for insets|  |   |   |measure    paragraph|
//  |which make  otherwise|  -----   |indentation.        |
//  -----------------------          ----------------------
//
// If we identify a drop-cap, we measure the left margin for the lines
// below the first line relative to one space past the drop cap.  The
// first line's margin and those past the drop cap area are measured
// relative to the enclosing polyblock.
//
// TODO(rays): Before this will work well, we'll need to adjust the
//             polyblob tighter around the text near images, as in:
//             UNLV_AUTO:mag.3G0  page 2
//             UNLV_AUTO:mag.3G4  page 16
void BLOCK::compute_row_margins() {
  if (row_list()->empty() || row_list()->singleton()) {
    return;
  }

  // If Layout analysis was not called, default to this.
  POLY_BLOCK rect_block(bounding_box(), PT_FLOWING_TEXT);
  POLY_BLOCK *pblock = &rect_block;
  if (poly_block() != NULL) {
    pblock = poly_block();
  }

  // Step One: Determine if there is a drop-cap.
  //           TODO(eger): Fix up drop cap code for RTL languages.
  ROW_IT r_it(row_list());
  ROW *first_row = r_it.data();
  ROW *second_row = r_it.data_relative(1);

  // initialize the bottom of a fictitious drop cap far above the first line.
  int drop_cap_bottom = first_row->bounding_box().top() +
                        first_row->bounding_box().height();
  int drop_cap_right = first_row->bounding_box().left();
  int mid_second_line = second_row->bounding_box().top() -
                        second_row->bounding_box().height() / 2;
  WERD_IT werd_it(r_it.data()->word_list());  // words of line one
  if (!werd_it.empty()) {
    C_BLOB_IT cblob_it(werd_it.data()->cblob_list());
    for (cblob_it.mark_cycle_pt(); !cblob_it.cycled_list();
         cblob_it.forward()) {
      TBOX bbox = cblob_it.data()->bounding_box();
      if (bbox.bottom() <= mid_second_line) {
        // we found a real drop cap
        first_row->set_has_drop_cap(true);
        if (drop_cap_bottom >  bbox.bottom())
          drop_cap_bottom = bbox.bottom();
        if (drop_cap_right < bbox.right())
          drop_cap_right = bbox.right();
      }
    }
  }

  // Step Two: Calculate the margin from the text of each row to the block
  //           (or drop-cap) boundaries.
  PB_LINE_IT lines(pblock);
  r_it.set_to_list(row_list());
  for (r_it.mark_cycle_pt(); !r_it.cycled_list(); r_it.forward()) {
    ROW *row = r_it.data();
    TBOX row_box = row->bounding_box();
    int left_y = row->base_line(row_box.left()) + row->x_height();
    int left_margin;
    ICOORDELT_LIST *segments = lines.get_line(left_y);
    LeftMargin(segments, row_box.left(), &left_margin);
    delete segments;

    if (row_box.top() >= drop_cap_bottom) {
      int drop_cap_distance = row_box.left() - row->space() - drop_cap_right;
      if (drop_cap_distance < 0)
        drop_cap_distance = 0;
      if (drop_cap_distance < left_margin)
        left_margin = drop_cap_distance;
    }

    int right_y = row->base_line(row_box.right()) + row->x_height();
    int right_margin;
    segments = lines.get_line(right_y);
    RightMargin(segments, row_box.right(), &right_margin);
    delete segments;
    row->set_lmargin(left_margin);
    row->set_rmargin(right_margin);
  }
}