/////////////////////////////////////////////////////////////////////// // File: bbgrid.cpp // Description: Class to hold BLOBNBOXs in a grid for fast access // to neighbours. // Author: Ray Smith // Created: Wed Jun 06 17:22:01 PDT 2007 // // (C) Copyright 2007, Google Inc. // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // http://www.apache.org/licenses/LICENSE-2.0 // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // /////////////////////////////////////////////////////////////////////// #include "bbgrid.h" #include "helpers.h" #include "ocrblock.h" namespace tesseract { /////////////////////////////////////////////////////////////////////// // BBGrid IMPLEMENTATION. /////////////////////////////////////////////////////////////////////// GridBase::GridBase() { } GridBase::GridBase(int gridsize, const ICOORD& bleft, const ICOORD& tright) { Init(gridsize, bleft, tright); } GridBase::~GridBase() { } // (Re)Initialize the grid. The gridsize is the size in pixels of each cell, // and bleft, tright are the bounding box of everything to go in it. void GridBase::Init(int gridsize, const ICOORD& bleft, const ICOORD& tright) { gridsize_ = gridsize; bleft_ = bleft; tright_ = tright; if (gridsize_ == 0) gridsize_ = 1; gridwidth_ = (tright.x() - bleft.x() + gridsize_ - 1) / gridsize_; gridheight_ = (tright.y() - bleft.y() + gridsize_ - 1) / gridsize_; gridbuckets_ = gridwidth_ * gridheight_; } // Compute the given grid coordinates from image coords. void GridBase::GridCoords(int x, int y, int* grid_x, int* grid_y) const { *grid_x = (x - bleft_.x()) / gridsize_; *grid_y = (y - bleft_.y()) / gridsize_; ClipGridCoords(grid_x, grid_y); } // Clip the given grid coordinates to fit within the grid. void GridBase::ClipGridCoords(int* x, int* y) const { *x = ClipToRange(*x, 0, gridwidth_ - 1); *y = ClipToRange(*y, 0, gridheight_ - 1); } IntGrid::IntGrid() { grid_ = NULL; } IntGrid::IntGrid(int gridsize, const ICOORD& bleft, const ICOORD& tright) : grid_(NULL) { Init(gridsize, bleft, tright); } IntGrid::~IntGrid() { if (grid_ != NULL) delete [] grid_; } // (Re)Initialize the grid. The gridsize is the size in pixels of each cell, // and bleft, tright are the bounding box of everything to go in it. void IntGrid::Init(int gridsize, const ICOORD& bleft, const ICOORD& tright) { GridBase::Init(gridsize, bleft, tright); if (grid_ != NULL) delete [] grid_; grid_ = new int[gridbuckets_]; Clear(); } // Clear all the ints in the grid to zero. void IntGrid::Clear() { for (int i = 0; i < gridbuckets_; ++i) { grid_[i] = 0; } } // Rotate the grid by rotation, keeping cell contents. // rotation must be a multiple of 90 degrees. // NOTE: due to partial cells, cell coverage in the rotated grid will be // inexact. This is why there is no Rotate for the generic BBGrid. // TODO(rays) investigate fixing this inaccuracy by moving the origin after // rotation. void IntGrid::Rotate(const FCOORD& rotation) { ASSERT_HOST(rotation.x() == 0.0f || rotation.y() == 0.0f); ICOORD old_bleft(bleft()); ICOORD old_tright(tright()); int old_width = gridwidth(); int old_height = gridheight(); TBOX box(bleft(), tright()); box.rotate(rotation); int* old_grid = grid_; grid_ = NULL; Init(gridsize(), box.botleft(), box.topright()); // Iterate over the old grid, copying data to the rotated position in the new. int oldi = 0; FCOORD x_step(rotation); x_step *= gridsize(); for (int oldy = 0; oldy < old_height; ++oldy) { FCOORD line_pos(old_bleft.x(), old_bleft.y() + gridsize() * oldy); line_pos.rotate(rotation); for (int oldx = 0; oldx < old_width; ++oldx, line_pos += x_step, ++oldi) { int grid_x, grid_y; GridCoords(static_cast(line_pos.x() + 0.5), static_cast(line_pos.y() + 0.5), &grid_x, &grid_y); grid_[grid_y * gridwidth() + grid_x] = old_grid[oldi]; } } delete [] old_grid; } // Returns a new IntGrid containing values equal to the sum of all the // neighbouring cells. The returned grid must be deleted after use. // For ease of implementation, edge cells are double counted, to make them // have the same range as the non-edge cells. IntGrid* IntGrid::NeighbourhoodSum() const { IntGrid* sumgrid = new IntGrid(gridsize(), bleft(), tright()); for (int y = 0; y < gridheight(); ++y) { for (int x = 0; x < gridwidth(); ++x) { int cell_count = 0; for (int yoffset = -1; yoffset <= 1; ++yoffset) { for (int xoffset = -1; xoffset <= 1; ++xoffset) { int grid_x = x + xoffset; int grid_y = y + yoffset; ClipGridCoords(&grid_x, &grid_y); cell_count += GridCellValue(grid_x, grid_y); } } if (GridCellValue(x, y) > 1) sumgrid->SetGridCell(x, y, cell_count); } } return sumgrid; } // Returns true if more than half the area of the rect is covered by grid // cells that are over the threshold. bool IntGrid::RectMostlyOverThreshold(const TBOX& rect, int threshold) const { int min_x, min_y, max_x, max_y; GridCoords(rect.left(), rect.bottom(), &min_x, &min_y); GridCoords(rect.right(), rect.top(), &max_x, &max_y); int total_area = 0; for (int y = min_y; y <= max_y; ++y) { for (int x = min_x; x <= max_x; ++x) { int value = GridCellValue(x, y); if (value > threshold) { TBOX cell_box(x * gridsize_, y * gridsize_, (x + 1) * gridsize_, (y + 1) * gridsize_); cell_box &= rect; // This is in-place box intersection. total_area += cell_box.area(); } } } return total_area * 2 > rect.area(); } // Returns true if any cell value in the given rectangle is zero. bool IntGrid::AnyZeroInRect(const TBOX& rect) const { int min_x, min_y, max_x, max_y; GridCoords(rect.left(), rect.bottom(), &min_x, &min_y); GridCoords(rect.right(), rect.top(), &max_x, &max_y); for (int y = min_y; y <= max_y; ++y) { for (int x = min_x; x <= max_x; ++x) { if (GridCellValue(x, y) == 0) return true; } } return false; } // Returns a full-resolution binary pix in which each cell over the given // threshold is filled as a black square. pixDestroy after use. // Edge cells, which have a zero 4-neighbour, are not marked. Pix* IntGrid::ThresholdToPix(int threshold) const { Pix* pix = pixCreate(tright().x() - bleft().x(), tright().y() - bleft().y(), 1); int cellsize = gridsize(); for (int y = 0; y < gridheight(); ++y) { for (int x = 0; x < gridwidth(); ++x) { if (GridCellValue(x, y) > threshold && GridCellValue(x - 1, y) > 0 && GridCellValue(x + 1, y) > 0 && GridCellValue(x, y - 1) > 0 && GridCellValue(x, y + 1) > 0) { pixRasterop(pix, x * cellsize, tright().y() - ((y + 1) * cellsize), cellsize, cellsize, PIX_SET, NULL, 0, 0); } } } return pix; } // Make a Pix of the correct scaled size for the TraceOutline functions. Pix* GridReducedPix(const TBOX& box, int gridsize, ICOORD bleft, int* left, int* bottom) { // Compute grid bounds of the outline and pad all round by 1. int grid_left = (box.left() - bleft.x()) / gridsize - 1; int grid_bottom = (box.bottom() - bleft.y()) / gridsize - 1; int grid_right = (box.right() - bleft.x()) / gridsize + 1; int grid_top = (box.top() - bleft.y()) / gridsize + 1; *left = grid_left; *bottom = grid_bottom; return pixCreate(grid_right - grid_left + 1, grid_top - grid_bottom + 1, 1); } // Helper function to return a scaled Pix with one pixel per grid cell, // set (black) where the given outline enters the corresponding grid cell, // and clear where the outline does not touch the grid cell. // Also returns the grid coords of the bottom-left of the Pix, in *left // and *bottom, which corresponds to (0, 0) on the Pix. // Note that the Pix is used upside-down, with (0, 0) being the bottom-left. Pix* TraceOutlineOnReducedPix(C_OUTLINE* outline, int gridsize, ICOORD bleft, int* left, int* bottom) { const TBOX& box = outline->bounding_box(); Pix* pix = GridReducedPix(box, gridsize, bleft, left, bottom); int wpl = pixGetWpl(pix); l_uint32* data = pixGetData(pix); int length = outline->pathlength(); ICOORD pos = outline->start_pos(); for (int i = 0; i < length; ++i) { int grid_x = (pos.x() - bleft.x()) / gridsize - *left; int grid_y = (pos.y() - bleft.y()) / gridsize - *bottom; SET_DATA_BIT(data + grid_y * wpl, grid_x); pos += outline->step(i); } return pix; } #if 0 // Example code shows how to use TraceOutlineOnReducedPix. C_OUTLINE_IT ol_it(blob->cblob()->out_list()); int grid_left, grid_bottom; Pix* pix = TraceOutlineOnReducedPix(ol_it.data(), gridsize_, bleft_, &grid_left, &grid_bottom); grid->InsertPixPtBBox(grid_left, grid_bottom, pix, blob); pixDestroy(&pix); #endif // As TraceOutlineOnReducedPix above, but on a BLOCK instead of a C_OUTLINE. Pix* TraceBlockOnReducedPix(BLOCK* block, int gridsize, ICOORD bleft, int* left, int* bottom) { const TBOX& box = block->bounding_box(); Pix* pix = GridReducedPix(box, gridsize, bleft, left, bottom); int wpl = pixGetWpl(pix); l_uint32* data = pixGetData(pix); ICOORDELT_IT it(block->poly_block()->points()); for (it.mark_cycle_pt(); !it.cycled_list();) { ICOORD pos = *it.data(); it.forward(); ICOORD next_pos = *it.data(); ICOORD line_vector = next_pos - pos; int major, minor; ICOORD major_step, minor_step; line_vector.setup_render(&major_step, &minor_step, &major, &minor); int accumulator = major / 2; while (pos != next_pos) { int grid_x = (pos.x() - bleft.x()) / gridsize - *left; int grid_y = (pos.y() - bleft.y()) / gridsize - *bottom; SET_DATA_BIT(data + grid_y * wpl, grid_x); pos += major_step; accumulator += minor; if (accumulator >= major) { accumulator -= major; pos += minor_step; } } } return pix; } } // namespace tesseract.