tesseract/ccstruct/normalis.cpp
2013-09-23 15:21:37 +00:00

574 lines
21 KiB
C++

/**********************************************************************
* File: normalis.cpp (Formerly denorm.c)
* Description: Code for the DENORM class.
* Author: Ray Smith
* Created: Thu Apr 23 09:22:43 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 "normalis.h"
#include <stdlib.h>
#include "allheaders.h"
#include "blobs.h"
#include "helpers.h"
#include "matrix.h"
#include "ocrblock.h"
#include "unicharset.h"
#include "werd.h"
// Tolerance in pixels used for baseline and xheight on non-upper/lower scripts.
const int kSloppyTolerance = 4;
// Final tolerance in pixels added to the computed xheight range.
const float kFinalPixelTolerance = 0.125f;
DENORM::DENORM() {
Init();
}
DENORM::DENORM(const DENORM &src) {
rotation_ = NULL;
*this = src;
}
DENORM & DENORM::operator=(const DENORM & src) {
Clear();
inverse_ = src.inverse_;
predecessor_ = src.predecessor_;
pix_ = src.pix_;
block_ = src.block_;
if (src.rotation_ == NULL)
rotation_ = NULL;
else
rotation_ = new FCOORD(*src.rotation_);
x_origin_ = src.x_origin_;
y_origin_ = src.y_origin_;
x_scale_ = src.x_scale_;
y_scale_ = src.y_scale_;
final_xshift_ = src.final_xshift_;
final_yshift_ = src.final_yshift_;
return *this;
}
DENORM::~DENORM() {
Clear();
}
// Initializes the denorm for a transformation. For details see the large
// comment in normalis.h.
// Arguments:
// block: if not NULL, then this is the first transformation, and
// block->re_rotation() needs to be used after the Denorm
// transformation to get back to the image coords.
// rotation: if not NULL, apply this rotation after translation to the
// origin and scaling. (Usually a classify rotation.)
// predecessor: if not NULL, then predecessor has been applied to the
// input space and needs to be undone to complete the inverse.
// The above pointers are not owned by this DENORM and are assumed to live
// longer than this denorm, except rotation, which is deep copied on input.
//
// x_origin: The x origin which will be mapped to final_xshift in the result.
// y_origin: The y origin which will be mapped to final_yshift in the result.
// Added to result of row->baseline(x) if not NULL.
//
// x_scale: scale factor for the x-coordinate.
// y_scale: scale factor for the y-coordinate. Ignored if segs is given.
// Note that these scale factors apply to the same x and y system as the
// x-origin and y-origin apply, ie after any block rotation, but before
// the rotation argument is applied.
//
// final_xshift: The x component of the final translation.
// final_yshift: The y component of the final translation.
void DENORM::SetupNormalization(const BLOCK* block,
const FCOORD* rotation,
const DENORM* predecessor,
float x_origin, float y_origin,
float x_scale, float y_scale,
float final_xshift, float final_yshift) {
Clear();
block_ = block;
if (rotation == NULL)
rotation_ = NULL;
else
rotation_ = new FCOORD(*rotation);
predecessor_ = predecessor;
x_origin_ = x_origin;
y_origin_ = y_origin;
x_scale_ = x_scale;
y_scale_ = y_scale;
final_xshift_ = final_xshift;
final_yshift_ = final_yshift;
}
// Helper for SetupNonLinear computes an image of shortest run-lengths from
// the x/y edges provided.
// Based on "A nonlinear normalization method for handprinted Kanji character
// recognition -- line density equalization" by Hiromitsu Yamada et al.
// Eg below is an O in a 1-pixel margin-ed bounding box and the corresponding
// ______________ input x_coords and y_coords.
// | _________ | <empty>
// | | _ | | 1, 6
// | | | | | | 1, 3, 4, 6
// | | | | | | 1, 3, 4, 6
// | | | | | | 1, 3, 4, 6
// | | |_| | | 1, 3, 4, 6
// | |_________| | 1, 6
// |_____________| <empty>
// E 1 1 1 1 1 E
// m 7 7 2 7 7 m
// p 6 p
// t 7 t
// y y
// The output image contains the min of the x and y run-length (distance
// between edges) at each coordinate in the image thus:
// ______________
// |7 1_1_1_1_1 7|
// |1|5 5 1 5 5|1|
// |1|2 2|1|2 2|1|
// |1|2 2|1|2 2|1|
// |1|2 2|1|2 2|1|
// |1|2 2|1|2 2|1|
// |1|5_5_1_5_5|1|
// |7_1_1_1_1_1_7|
// Note that the input coords are all integer, so all partial pixels are dealt
// with elsewhere. Although it is nice for outlines to be properly connected
// and continuous, there is no requirement that they be as such, so they could
// have been derived from a flaky source, such as greyscale.
// This function works only within the provided box, and it is assumed that the
// input x_coords and y_coords have already been translated to have the bottom-
// left of box as the origin. Although an output, the minruns should have been
// pre-initialized to be the same size as box. Each element will contain the
// minimum of x and y run-length as shown above.
static void ComputeRunlengthImage(
const TBOX& box,
const GenericVector<GenericVector<int> >& x_coords,
const GenericVector<GenericVector<int> >& y_coords,
GENERIC_2D_ARRAY<int>* minruns) {
int width = box.width();
int height = box.height();
ASSERT_HOST(minruns->dim1() == width);
ASSERT_HOST(minruns->dim2() == height);
// Set a 2-d image array to the run lengths at each pixel.
for (int ix = 0; ix < width; ++ix) {
int y = 0;
for (int i = 0; i < y_coords[ix].size(); ++i) {
int y_edge = ClipToRange(y_coords[ix][i], 0, height);
int gap = y_edge - y;
// Every pixel between the last and current edge get set to the gap.
while (y < y_edge) {
(*minruns)(ix, y) = gap;
++y;
}
}
// Pretend there is a bounding box of edges all around the image.
int gap = height - y;
while (y < height) {
(*minruns)(ix, y) = gap;
++y;
}
}
// Now set the image pixels the the MIN of the x and y runlengths.
for (int iy = 0; iy < height; ++iy) {
int x = 0;
for (int i = 0; i < x_coords[iy].size(); ++i) {
int x_edge = ClipToRange(x_coords[iy][i], 0, width);
int gap = x_edge - x;
while (x < x_edge) {
if (gap < (*minruns)(x, iy))
(*minruns)(x, iy) = gap;
++x;
}
}
int gap = width - x;
while (x < width) {
if (gap < (*minruns)(x, iy))
(*minruns)(x, iy) = gap;
++x;
}
}
}
// Converts the run-length image (see above to the edge density profiles used
// for scaling, thus:
// ______________
// |7 1_1_1_1_1 7| = 5.28
// |1|5 5 1 5 5|1| = 3.8
// |1|2 2|1|2 2|1| = 5
// |1|2 2|1|2 2|1| = 5
// |1|2 2|1|2 2|1| = 5
// |1|2 2|1|2 2|1| = 5
// |1|5_5_1_5_5|1| = 3.8
// |7_1_1_1_1_1_7| = 5.28
// 6 4 4 8 4 4 6
// . . . . . . .
// 2 4 4 0 4 4 2
// 8 8
// Each profile is the sum of the reciprocals of the pixels in the image in
// the appropriate row or column, and these are then normalized to sum to 1.
// On output hx, hy contain an extra element, which will eventually be used
// to guarantee that the top/right edge of the box (and anything beyond) always
// gets mapped to the maximum target coordinate.
static void ComputeEdgeDensityProfiles(const TBOX& box,
const GENERIC_2D_ARRAY<int>& minruns,
GenericVector<float>* hx,
GenericVector<float>* hy) {
int width = box.width();
int height = box.height();
hx->init_to_size(width + 1, 0.0);
hy->init_to_size(height + 1, 0.0);
double total = 0.0;
for (int iy = 0; iy < height; ++iy) {
for (int ix = 0; ix < width; ++ix) {
int run = minruns(ix, iy);
if (run == 0) run = 1;
float density = 1.0f / run;
(*hx)[ix] += density;
(*hy)[iy] += density;
}
total += (*hy)[iy];
}
// Normalize each profile to sum to 1.
if (total > 0.0) {
for (int ix = 0; ix < width; ++ix) {
(*hx)[ix] /= total;
}
for (int iy = 0; iy < height; ++iy) {
(*hy)[iy] /= total;
}
}
// There is an extra element in each array, so initialize to 1.
(*hx)[width] = 1.0f;
(*hy)[height] = 1.0f;
}
// Sets up the DENORM to execute a non-linear transformation based on
// preserving an even distribution of stroke edges. The transformation
// operates only within the given box.
// x_coords is a collection of the x-coords of vertical edges for each
// y-coord starting at box.bottom().
// y_coords is a collection of the y-coords of horizontal edges for each
// x-coord starting at box.left().
// Eg x_coords[0] is a collection of the x-coords of edges at y=bottom.
// Eg x_coords[1] is a collection of the x-coords of edges at y=bottom + 1.
// The second-level vectors must all be sorted in ascending order.
// See comments on the helper functions above for more details.
void DENORM::SetupNonLinear(
const DENORM* predecessor, const TBOX& box, float target_width,
float target_height, float final_xshift, float final_yshift,
const GenericVector<GenericVector<int> >& x_coords,
const GenericVector<GenericVector<int> >& y_coords) {
Clear();
predecessor_ = predecessor;
// x_map_ and y_map_ store a mapping from input x and y coordinate to output
// x and y coordinate, based on scaling to the supplied target_width and
// target_height.
x_map_ = new GenericVector<float>;
y_map_ = new GenericVector<float>;
// Set a 2-d image array to the run lengths at each pixel.
int width = box.width();
int height = box.height();
GENERIC_2D_ARRAY<int> minruns(width, height, 0);
ComputeRunlengthImage(box, x_coords, y_coords, &minruns);
// Edge density is the sum of the inverses of the run lengths. Compute
// edge density projection profiles.
ComputeEdgeDensityProfiles(box, minruns, x_map_, y_map_);
// Convert the edge density profiles to the coordinates by multiplying by
// the desired size and accumulating.
(*x_map_)[width] = target_width;
for (int x = width - 1; x >= 0; --x) {
(*x_map_)[x] = (*x_map_)[x + 1] - (*x_map_)[x] * target_width;
}
(*y_map_)[height] = target_height;
for (int y = height - 1; y >= 0; --y) {
(*y_map_)[y] = (*y_map_)[y + 1] - (*y_map_)[y] * target_height;
}
x_origin_ = box.left();
y_origin_ = box.bottom();
final_xshift_ = final_xshift;
final_yshift_ = final_yshift;
}
// Transforms the given coords one step forward to normalized space, without
// using any block rotation or predecessor.
void DENORM::LocalNormTransform(const TPOINT& pt, TPOINT* transformed) const {
FCOORD src_pt(pt.x, pt.y);
FCOORD float_result;
LocalNormTransform(src_pt, &float_result);
transformed->x = IntCastRounded(float_result.x());
transformed->y = IntCastRounded(float_result.y());
}
void DENORM::LocalNormTransform(const FCOORD& pt, FCOORD* transformed) const {
FCOORD translated(pt.x() - x_origin_, pt.y() - y_origin_);
if (x_map_ != NULL && y_map_ != NULL) {
int x = ClipToRange(IntCastRounded(translated.x()), 0, x_map_->size()-1);
translated.set_x((*x_map_)[x]);
int y = ClipToRange(IntCastRounded(translated.y()), 0, y_map_->size()-1);
translated.set_y((*y_map_)[y]);
} else {
translated.set_x(translated.x() * x_scale_);
translated.set_y(translated.y() * y_scale_);
if (rotation_ != NULL)
translated.rotate(*rotation_);
}
transformed->set_x(translated.x() + final_xshift_);
transformed->set_y(translated.y() + final_yshift_);
}
// Transforms the given coords forward to normalized space using the
// full transformation sequence defined by the block rotation, the
// predecessors, deepest first, and finally this. If first_norm is not NULL,
// then the first and deepest transformation used is first_norm, ending
// with this, and the block rotation will not be applied.
void DENORM::NormTransform(const DENORM* first_norm, const TPOINT& pt,
TPOINT* transformed) const {
FCOORD src_pt(pt.x, pt.y);
FCOORD float_result;
NormTransform(first_norm, src_pt, &float_result);
transformed->x = IntCastRounded(float_result.x());
transformed->y = IntCastRounded(float_result.y());
}
void DENORM::NormTransform(const DENORM* first_norm, const FCOORD& pt,
FCOORD* transformed) const {
FCOORD src_pt(pt);
if (first_norm != this) {
if (predecessor_ != NULL) {
predecessor_->NormTransform(first_norm, pt, &src_pt);
} else if (block_ != NULL) {
FCOORD fwd_rotation(block_->re_rotation().x(),
-block_->re_rotation().y());
src_pt.rotate(fwd_rotation);
}
}
LocalNormTransform(src_pt, transformed);
}
// Transforms the given coords one step back to source space, without
// using to any block rotation or predecessor.
void DENORM::LocalDenormTransform(const TPOINT& pt, TPOINT* original) const {
FCOORD src_pt(pt.x, pt.y);
FCOORD float_result;
LocalDenormTransform(src_pt, &float_result);
original->x = IntCastRounded(float_result.x());
original->y = IntCastRounded(float_result.y());
}
void DENORM::LocalDenormTransform(const FCOORD& pt, FCOORD* original) const {
FCOORD rotated(pt.x() - final_xshift_, pt.y() - final_yshift_);
if (x_map_ != NULL && y_map_ != NULL) {
int x = x_map_->binary_search(rotated.x());
original->set_x(x + x_origin_);
int y = y_map_->binary_search(rotated.y());
original->set_y(y + y_origin_);
} else {
if (rotation_ != NULL) {
FCOORD inverse_rotation(rotation_->x(), -rotation_->y());
rotated.rotate(inverse_rotation);
}
original->set_x(rotated.x() / x_scale_ + x_origin_);
float y_scale = y_scale_;
original->set_y(rotated.y() / y_scale + y_origin_);
}
}
// Transforms the given coords all the way back to source image space using
// the full transformation sequence defined by this and its predecesors
// recursively, shallowest first, and finally any block re_rotation.
// If last_denorm is not NULL, then the last transformation used will
// be last_denorm, and the block re_rotation will never be executed.
void DENORM::DenormTransform(const DENORM* last_denorm, const TPOINT& pt,
TPOINT* original) const {
FCOORD src_pt(pt.x, pt.y);
FCOORD float_result;
DenormTransform(last_denorm, src_pt, &float_result);
original->x = IntCastRounded(float_result.x());
original->y = IntCastRounded(float_result.y());
}
void DENORM::DenormTransform(const DENORM* last_denorm, const FCOORD& pt,
FCOORD* original) const {
LocalDenormTransform(pt, original);
if (last_denorm != this) {
if (predecessor_ != NULL) {
predecessor_->DenormTransform(last_denorm, *original, original);
} else if (block_ != NULL) {
original->rotate(block_->re_rotation());
}
}
}
// Normalize a blob using blob transformations. Less accurate, but
// more accurately copies the old way.
void DENORM::LocalNormBlob(TBLOB* blob) const {
TBOX blob_box = blob->bounding_box();
ICOORD translation(-IntCastRounded(x_origin_), -IntCastRounded(y_origin_));
blob->Move(translation);
if (y_scale_ != 1.0f)
blob->Scale(y_scale_);
if (rotation_ != NULL)
blob->Rotate(*rotation_);
translation.set_x(IntCastRounded(final_xshift_));
translation.set_y(IntCastRounded(final_yshift_));
blob->Move(translation);
}
// Fills in the x-height range accepted by the given unichar_id, given its
// bounding box in the usual baseline-normalized coordinates, with some
// initial crude x-height estimate (such as word size) and this denoting the
// transformation that was used.
void DENORM::XHeightRange(int unichar_id, const UNICHARSET& unicharset,
const TBOX& bbox,
float* min_xht, float* max_xht, float* yshift) const {
// Default return -- accept anything.
*yshift = 0.0f;
*min_xht = 0.0f;
*max_xht = MAX_FLOAT32;
if (!unicharset.top_bottom_useful())
return;
// Clip the top and bottom to the limit of normalized feature space.
int top = ClipToRange<int>(bbox.top(), 0, kBlnCellHeight - 1);
int bottom = ClipToRange<int>(bbox.bottom(), 0, kBlnCellHeight - 1);
// A tolerance of yscale corresponds to 1 pixel in the image.
double tolerance = y_scale();
// If the script doesn't have upper and lower-case characters, widen the
// tolerance to allow sloppy baseline/x-height estimates.
if (!unicharset.script_has_upper_lower())
tolerance = y_scale() * kSloppyTolerance;
int min_bottom, max_bottom, min_top, max_top;
unicharset.get_top_bottom(unichar_id, &min_bottom, &max_bottom,
&min_top, &max_top);
// Calculate the scale factor we'll use to get to image y-pixels
double midx = (bbox.left() + bbox.right()) / 2;
double ydiff = (bbox.top() - bbox.bottom()) + 2;
FCOORD mid_bot(midx, bbox.bottom()), tmid_bot;
FCOORD mid_high(midx, bbox.bottom() + ydiff), tmid_high;
DenormTransform(NULL, mid_bot, &tmid_bot);
DenormTransform(NULL, mid_high, &tmid_high);
// bln_y_measure * yscale = image_y_measure
double yscale = tmid_high.pt_to_pt_dist(tmid_bot) / ydiff;
// Calculate y-shift
int bln_yshift = 0, bottom_shift = 0, top_shift = 0;
if (bottom < min_bottom - tolerance) {
bottom_shift = bottom - min_bottom;
} else if (bottom > max_bottom + tolerance) {
bottom_shift = bottom - max_bottom;
}
if (top < min_top - tolerance) {
top_shift = top - min_top;
} else if (top > max_top + tolerance) {
top_shift = top - max_top;
}
if ((top_shift >= 0 && bottom_shift > 0) ||
(top_shift < 0 && bottom_shift < 0)) {
bln_yshift = (top_shift + bottom_shift) / 2;
}
*yshift = bln_yshift * yscale;
// To help very high cap/xheight ratio fonts accept the correct x-height,
// and to allow the large caps in small caps to accept the xheight of the
// small caps, add kBlnBaselineOffset to chars with a maximum max, and have
// a top already at a significantly high position.
if (max_top == kBlnCellHeight - 1 &&
top > kBlnCellHeight - kBlnBaselineOffset / 2)
max_top += kBlnBaselineOffset;
top -= bln_yshift;
int height = top - kBlnBaselineOffset - bottom_shift;
double min_height = min_top - kBlnBaselineOffset - tolerance;
double max_height = max_top - kBlnBaselineOffset + tolerance;
// We shouldn't try calculations if the characters are very short (for example
// for punctuation).
if (min_height > kBlnXHeight / 8 && height > 0) {
float result = height * kBlnXHeight * yscale / min_height;
*max_xht = result + kFinalPixelTolerance;
result = height * kBlnXHeight * yscale / max_height;
*min_xht = result - kFinalPixelTolerance;
}
}
// Prints the content of the DENORM for debug purposes.
void DENORM::Print() const {
if (pix_ != NULL) {
tprintf("Pix dimensions %d x %d x %d\n",
pixGetWidth(pix_), pixGetHeight(pix_), pixGetDepth(pix_));
}
if (inverse_)
tprintf("Inverse\n");
if (block_ && block_->re_rotation().x() != 1.0f) {
tprintf("Block rotation %g, %g\n",
block_->re_rotation().x(), block_->re_rotation().y());
}
tprintf("Input Origin = (%g, %g)\n", x_origin_, y_origin_);
if (x_map_ != NULL && y_map_ != NULL) {
tprintf("x map:\n");
for (int x = 0; x < x_map_->size(); ++x) {
tprintf("%g ", (*x_map_)[x]);
}
tprintf("\ny map:\n");
for (int y = 0; y < y_map_->size(); ++y) {
tprintf("%g ", (*y_map_)[y]);
}
tprintf("\n");
} else {
tprintf("Scale = (%g, %g)\n", x_scale_, y_scale_);
if (rotation_ != NULL)
tprintf("Rotation = (%g, %g)\n", rotation_->x(), rotation_->y());
}
tprintf("Final Origin = (%g, %g)\n", final_xshift_, final_xshift_);
if (predecessor_ != NULL) {
tprintf("Predecessor:\n");
predecessor_->Print();
}
}
// ============== Private Code ======================
// Free allocated memory and clear pointers.
void DENORM::Clear() {
if (x_map_ != NULL) {
delete x_map_;
x_map_ = NULL;
}
if (y_map_ != NULL) {
delete y_map_;
y_map_ = NULL;
}
if (rotation_ != NULL) {
delete rotation_;
rotation_ = NULL;
}
}
// Setup default values.
void DENORM::Init() {
inverse_ = false;
pix_ = NULL;
block_ = NULL;
rotation_ = NULL;
predecessor_ = NULL;
x_map_ = NULL;
y_map_ = NULL;
x_origin_ = 0.0f;
y_origin_ = 0.0f;
x_scale_ = 1.0f;
y_scale_ = 1.0f;
final_xshift_ = 0.0f;
final_yshift_ = static_cast<float>(kBlnBaselineOffset);
}