tesseract/classify/trainingsampleset.cpp
Stefan Weil dabf3f3dbd classify: Remove unused local function
This fixes a compiler warning:

classify/trainingsampleset.cpp:510:13: warning:
 'Pix* tesseract::DebugSample(const UNICHARSET&, tesseract::TrainingSample*)'
 defined but not used [-Wunused-function]

Signed-off-by: Stefan Weil <sw@weilnetz.de>
2017-03-09 16:19:21 +01:00

765 lines
31 KiB
C++

// Copyright 2010 Google Inc. All Rights Reserved.
// Author: rays@google.com (Ray Smith)
//
// 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 "trainingsampleset.h"
#include "allheaders.h"
#include "boxread.h"
#include "fontinfo.h"
#include "indexmapbidi.h"
#include "intfeaturedist.h"
#include "intfeaturemap.h"
#include "intfeaturespace.h"
#include "shapetable.h"
#include "trainingsample.h"
#include "unicity_table.h"
namespace tesseract {
const int kTestChar = -1; // 37;
// Max number of distances to compute the squared way
const int kSquareLimit = 25;
// Prime numbers for subsampling distances.
const int kPrime1 = 17;
const int kPrime2 = 13;
// Min samples from which to start discarding outliers.
const int kMinOutlierSamples = 5;
TrainingSampleSet::FontClassInfo::FontClassInfo()
: num_raw_samples(0), canonical_sample(-1), canonical_dist(0.0f) {
}
// Writes to the given file. Returns false in case of error.
bool TrainingSampleSet::FontClassInfo::Serialize(FILE* fp) const {
if (fwrite(&num_raw_samples, sizeof(num_raw_samples), 1, fp) != 1)
return false;
if (fwrite(&canonical_sample, sizeof(canonical_sample), 1, fp) != 1)
return false;
if (fwrite(&canonical_dist, sizeof(canonical_dist), 1, fp) != 1) return false;
if (!samples.Serialize(fp)) return false;
return true;
}
// Reads from the given file. Returns false in case of error.
// If swap is true, assumes a big/little-endian swap is needed.
bool TrainingSampleSet::FontClassInfo::DeSerialize(bool swap, FILE* fp) {
if (fread(&num_raw_samples, sizeof(num_raw_samples), 1, fp) != 1)
return false;
if (fread(&canonical_sample, sizeof(canonical_sample), 1, fp) != 1)
return false;
if (fread(&canonical_dist, sizeof(canonical_dist), 1, fp) != 1) return false;
if (!samples.DeSerialize(swap, fp)) return false;
if (swap) {
ReverseN(&num_raw_samples, sizeof(num_raw_samples));
ReverseN(&canonical_sample, sizeof(canonical_sample));
ReverseN(&canonical_dist, sizeof(canonical_dist));
}
return true;
}
TrainingSampleSet::TrainingSampleSet(const FontInfoTable& font_table)
: num_raw_samples_(0), unicharset_size_(0),
font_class_array_(NULL), fontinfo_table_(font_table) {
}
TrainingSampleSet::~TrainingSampleSet() {
delete font_class_array_;
}
// Writes to the given file. Returns false in case of error.
bool TrainingSampleSet::Serialize(FILE* fp) const {
if (!samples_.Serialize(fp)) return false;
if (!unicharset_.save_to_file(fp)) return false;
if (!font_id_map_.Serialize(fp)) return false;
inT8 not_null = font_class_array_ != NULL;
if (fwrite(&not_null, sizeof(not_null), 1, fp) != 1) return false;
if (not_null) {
if (!font_class_array_->SerializeClasses(fp)) return false;
}
return true;
}
// Reads from the given file. Returns false in case of error.
// If swap is true, assumes a big/little-endian swap is needed.
bool TrainingSampleSet::DeSerialize(bool swap, FILE* fp) {
if (!samples_.DeSerialize(swap, fp)) return false;
num_raw_samples_ = samples_.size();
if (!unicharset_.load_from_file(fp)) return false;
if (!font_id_map_.DeSerialize(swap, fp)) return false;
delete font_class_array_;
font_class_array_ = NULL;
inT8 not_null;
if (fread(&not_null, sizeof(not_null), 1, fp) != 1) return false;
if (not_null) {
FontClassInfo empty;
font_class_array_ = new GENERIC_2D_ARRAY<FontClassInfo >(1, 1 , empty);
if (!font_class_array_->DeSerializeClasses(swap, fp)) return false;
}
unicharset_size_ = unicharset_.size();
return true;
}
// Load an initial unicharset, or set one up if the file cannot be read.
void TrainingSampleSet::LoadUnicharset(const char* filename) {
if (!unicharset_.load_from_file(filename)) {
tprintf("Failed to load unicharset from file %s\n"
"Building unicharset from scratch...\n",
filename);
unicharset_.clear();
// Add special characters as they were removed by the clear.
UNICHARSET empty;
unicharset_.AppendOtherUnicharset(empty);
}
unicharset_size_ = unicharset_.size();
}
// Adds a character sample to this sample set.
// If the unichar is not already in the local unicharset, it is added.
// Returns the unichar_id of the added sample, from the local unicharset.
int TrainingSampleSet::AddSample(const char* unichar, TrainingSample* sample) {
if (!unicharset_.contains_unichar(unichar)) {
unicharset_.unichar_insert(unichar);
if (unicharset_.size() > MAX_NUM_CLASSES) {
tprintf("Error: Size of unicharset in TrainingSampleSet::AddSample is "
"greater than MAX_NUM_CLASSES\n");
return -1;
}
}
UNICHAR_ID char_id = unicharset_.unichar_to_id(unichar);
AddSample(char_id, sample);
return char_id;
}
// Adds a character sample to this sample set with the given unichar_id,
// which must correspond to the local unicharset (in this).
void TrainingSampleSet::AddSample(int unichar_id, TrainingSample* sample) {
sample->set_class_id(unichar_id);
samples_.push_back(sample);
num_raw_samples_ = samples_.size();
unicharset_size_ = unicharset_.size();
}
// Returns the number of samples for the given font,class pair.
// If randomize is true, returns the number of samples accessible
// with randomizing on. (Increases the number of samples if small.)
// OrganizeByFontAndClass must have been already called.
int TrainingSampleSet::NumClassSamples(int font_id, int class_id,
bool randomize) const {
ASSERT_HOST(font_class_array_ != NULL);
if (font_id < 0 || class_id < 0 ||
font_id >= font_id_map_.SparseSize() || class_id >= unicharset_size_) {
// There are no samples because the font or class doesn't exist.
return 0;
}
int font_index = font_id_map_.SparseToCompact(font_id);
if (font_index < 0)
return 0; // The font has no samples.
if (randomize)
return (*font_class_array_)(font_index, class_id).samples.size();
else
return (*font_class_array_)(font_index, class_id).num_raw_samples;
}
// Gets a sample by its index.
const TrainingSample* TrainingSampleSet::GetSample(int index) const {
return samples_[index];
}
// Gets a sample by its font, class, index.
// OrganizeByFontAndClass must have been already called.
const TrainingSample* TrainingSampleSet::GetSample(int font_id, int class_id,
int index) const {
ASSERT_HOST(font_class_array_ != NULL);
int font_index = font_id_map_.SparseToCompact(font_id);
if (font_index < 0) return NULL;
int sample_index = (*font_class_array_)(font_index, class_id).samples[index];
return samples_[sample_index];
}
// Get a sample by its font, class, index. Does not randomize.
// OrganizeByFontAndClass must have been already called.
TrainingSample* TrainingSampleSet::MutableSample(int font_id, int class_id,
int index) {
ASSERT_HOST(font_class_array_ != NULL);
int font_index = font_id_map_.SparseToCompact(font_id);
if (font_index < 0) return NULL;
int sample_index = (*font_class_array_)(font_index, class_id).samples[index];
return samples_[sample_index];
}
// Returns a string debug representation of the given sample:
// font, unichar_str, bounding box, page.
STRING TrainingSampleSet::SampleToString(const TrainingSample& sample) const {
STRING boxfile_str;
MakeBoxFileStr(unicharset_.id_to_unichar(sample.class_id()),
sample.bounding_box(), sample.page_num(), &boxfile_str);
return STRING(fontinfo_table_.get(sample.font_id()).name) + " " + boxfile_str;
}
// Gets the combined set of features used by all the samples of the given
// font/class combination.
const BitVector& TrainingSampleSet::GetCloudFeatures(
int font_id, int class_id) const {
int font_index = font_id_map_.SparseToCompact(font_id);
ASSERT_HOST(font_index >= 0);
return (*font_class_array_)(font_index, class_id).cloud_features;
}
// Gets the indexed features of the canonical sample of the given
// font/class combination.
const GenericVector<int>& TrainingSampleSet::GetCanonicalFeatures(
int font_id, int class_id) const {
int font_index = font_id_map_.SparseToCompact(font_id);
ASSERT_HOST(font_index >= 0);
return (*font_class_array_)(font_index, class_id).canonical_features;
}
// Returns the distance between the given UniCharAndFonts pair.
// If matched_fonts, only matching fonts, are considered, unless that yields
// the empty set.
// OrganizeByFontAndClass must have been already called.
float TrainingSampleSet::UnicharDistance(const UnicharAndFonts& uf1,
const UnicharAndFonts& uf2,
bool matched_fonts,
const IntFeatureMap& feature_map) {
int num_fonts1 = uf1.font_ids.size();
int c1 = uf1.unichar_id;
int num_fonts2 = uf2.font_ids.size();
int c2 = uf2.unichar_id;
double dist_sum = 0.0;
int dist_count = 0;
bool debug = false;
if (matched_fonts) {
// Compute distances only where fonts match.
for (int i = 0; i < num_fonts1; ++i) {
int f1 = uf1.font_ids[i];
for (int j = 0; j < num_fonts2; ++j) {
int f2 = uf2.font_ids[j];
if (f1 == f2) {
dist_sum += ClusterDistance(f1, c1, f2, c2, feature_map);
++dist_count;
}
}
}
} else if (num_fonts1 * num_fonts2 <= kSquareLimit) {
// Small enough sets to compute all the distances.
for (int i = 0; i < num_fonts1; ++i) {
int f1 = uf1.font_ids[i];
for (int j = 0; j < num_fonts2; ++j) {
int f2 = uf2.font_ids[j];
dist_sum += ClusterDistance(f1, c1, f2, c2, feature_map);
if (debug) {
tprintf("Cluster dist %d %d %d %d = %g\n",
f1, c1, f2, c2,
ClusterDistance(f1, c1, f2, c2, feature_map));
}
++dist_count;
}
}
} else {
// Subsample distances, using the largest set once, and stepping through
// the smaller set so as to ensure that all the pairs are different.
int increment = kPrime1 != num_fonts2 ? kPrime1 : kPrime2;
int index = 0;
int num_samples = MAX(num_fonts1, num_fonts2);
for (int i = 0; i < num_samples; ++i, index += increment) {
int f1 = uf1.font_ids[i % num_fonts1];
int f2 = uf2.font_ids[index % num_fonts2];
if (debug) {
tprintf("Cluster dist %d %d %d %d = %g\n",
f1, c1, f2, c2, ClusterDistance(f1, c1, f2, c2, feature_map));
}
dist_sum += ClusterDistance(f1, c1, f2, c2, feature_map);
++dist_count;
}
}
if (dist_count == 0) {
if (matched_fonts)
return UnicharDistance(uf1, uf2, false, feature_map);
return 0.0f;
}
return dist_sum / dist_count;
}
// Returns the distance between the given pair of font/class pairs.
// Finds in cache or computes and caches.
// OrganizeByFontAndClass must have been already called.
float TrainingSampleSet::ClusterDistance(int font_id1, int class_id1,
int font_id2, int class_id2,
const IntFeatureMap& feature_map) {
ASSERT_HOST(font_class_array_ != NULL);
int font_index1 = font_id_map_.SparseToCompact(font_id1);
int font_index2 = font_id_map_.SparseToCompact(font_id2);
if (font_index1 < 0 || font_index2 < 0)
return 0.0f;
FontClassInfo& fc_info = (*font_class_array_)(font_index1, class_id1);
if (font_id1 == font_id2) {
// Special case cache for speed.
if (fc_info.unichar_distance_cache.size() == 0)
fc_info.unichar_distance_cache.init_to_size(unicharset_size_, -1.0f);
if (fc_info.unichar_distance_cache[class_id2] < 0) {
// Distance has to be calculated.
float result = ComputeClusterDistance(font_id1, class_id1,
font_id2, class_id2,
feature_map);
fc_info.unichar_distance_cache[class_id2] = result;
// Copy to the symmetric cache entry.
FontClassInfo& fc_info2 = (*font_class_array_)(font_index2, class_id2);
if (fc_info2.unichar_distance_cache.size() == 0)
fc_info2.unichar_distance_cache.init_to_size(unicharset_size_, -1.0f);
fc_info2.unichar_distance_cache[class_id1] = result;
}
return fc_info.unichar_distance_cache[class_id2];
} else if (class_id1 == class_id2) {
// Another special-case cache for equal class-id.
if (fc_info.font_distance_cache.size() == 0)
fc_info.font_distance_cache.init_to_size(font_id_map_.CompactSize(),
-1.0f);
if (fc_info.font_distance_cache[font_index2] < 0) {
// Distance has to be calculated.
float result = ComputeClusterDistance(font_id1, class_id1,
font_id2, class_id2,
feature_map);
fc_info.font_distance_cache[font_index2] = result;
// Copy to the symmetric cache entry.
FontClassInfo& fc_info2 = (*font_class_array_)(font_index2, class_id2);
if (fc_info2.font_distance_cache.size() == 0)
fc_info2.font_distance_cache.init_to_size(font_id_map_.CompactSize(),
-1.0f);
fc_info2.font_distance_cache[font_index1] = result;
}
return fc_info.font_distance_cache[font_index2];
}
// Both font and class are different. Linear search for class_id2/font_id2
// in what is a hopefully short list of distances.
int cache_index = 0;
while (cache_index < fc_info.distance_cache.size() &&
(fc_info.distance_cache[cache_index].unichar_id != class_id2 ||
fc_info.distance_cache[cache_index].font_id != font_id2))
++cache_index;
if (cache_index == fc_info.distance_cache.size()) {
// Distance has to be calculated.
float result = ComputeClusterDistance(font_id1, class_id1,
font_id2, class_id2,
feature_map);
FontClassDistance fc_dist = { class_id2, font_id2, result };
fc_info.distance_cache.push_back(fc_dist);
// Copy to the symmetric cache entry. We know it isn't there already, as
// we always copy to the symmetric entry.
FontClassInfo& fc_info2 = (*font_class_array_)(font_index2, class_id2);
fc_dist.unichar_id = class_id1;
fc_dist.font_id = font_id1;
fc_info2.distance_cache.push_back(fc_dist);
}
return fc_info.distance_cache[cache_index].distance;
}
// Computes the distance between the given pair of font/class pairs.
float TrainingSampleSet::ComputeClusterDistance(
int font_id1, int class_id1, int font_id2, int class_id2,
const IntFeatureMap& feature_map) const {
int dist = ReliablySeparable(font_id1, class_id1, font_id2, class_id2,
feature_map, false);
dist += ReliablySeparable(font_id2, class_id2, font_id1, class_id1,
feature_map, false);
int denominator = GetCanonicalFeatures(font_id1, class_id1).size();
denominator += GetCanonicalFeatures(font_id2, class_id2).size();
return static_cast<float>(dist) / denominator;
}
// Helper to add a feature and its near neighbors to the good_features.
// levels indicates how many times to compute the offset features of what is
// already there. This is done by iteration rather than recursion.
static void AddNearFeatures(const IntFeatureMap& feature_map, int f, int levels,
GenericVector<int>* good_features) {
int prev_num_features = 0;
good_features->push_back(f);
int num_features = 1;
for (int level = 0; level < levels; ++level) {
for (int i = prev_num_features; i < num_features; ++i) {
int feature = (*good_features)[i];
for (int dir = -kNumOffsetMaps; dir <= kNumOffsetMaps; ++dir) {
if (dir == 0) continue;
int f1 = feature_map.OffsetFeature(feature, dir);
if (f1 >= 0) {
good_features->push_back(f1);
}
}
}
prev_num_features = num_features;
num_features = good_features->size();
}
}
// Returns the number of canonical features of font/class 2 for which
// neither the feature nor any of its near neighbors occurs in the cloud
// of font/class 1. Each such feature is a reliable separation between
// the classes, ASSUMING that the canonical sample is sufficiently
// representative that every sample has a feature near that particular
// feature. To check that this is so on the fly would be prohibitively
// expensive, but it might be possible to pre-qualify the canonical features
// to include only those for which this assumption is true.
// ComputeCanonicalFeatures and ComputeCloudFeatures must have been called
// first, or the results will be nonsense.
int TrainingSampleSet::ReliablySeparable(int font_id1, int class_id1,
int font_id2, int class_id2,
const IntFeatureMap& feature_map,
bool thorough) const {
int result = 0;
const TrainingSample* sample2 = GetCanonicalSample(font_id2, class_id2);
if (sample2 == NULL)
return 0; // There are no canonical features.
const GenericVector<int>& canonical2 = GetCanonicalFeatures(font_id2,
class_id2);
const BitVector& cloud1 = GetCloudFeatures(font_id1, class_id1);
if (cloud1.size() == 0)
return canonical2.size(); // There are no cloud features.
// Find a canonical2 feature that is not in cloud1.
for (int f = 0; f < canonical2.size(); ++f) {
int feature = canonical2[f];
if (cloud1[feature])
continue;
// Gather the near neighbours of f.
GenericVector<int> good_features;
AddNearFeatures(feature_map, feature, 1, &good_features);
// Check that none of the good_features are in the cloud.
int i;
for (i = 0; i < good_features.size(); ++i) {
int good_f = good_features[i];
if (cloud1[good_f]) {
break;
}
}
if (i < good_features.size())
continue; // Found one in the cloud.
++result;
}
return result;
}
// Returns the total index of the requested sample.
// OrganizeByFontAndClass must have been already called.
int TrainingSampleSet::GlobalSampleIndex(int font_id, int class_id,
int index) const {
ASSERT_HOST(font_class_array_ != NULL);
int font_index = font_id_map_.SparseToCompact(font_id);
if (font_index < 0) return -1;
return (*font_class_array_)(font_index, class_id).samples[index];
}
// Gets the canonical sample for the given font, class pair.
// ComputeCanonicalSamples must have been called first.
const TrainingSample* TrainingSampleSet::GetCanonicalSample(
int font_id, int class_id) const {
ASSERT_HOST(font_class_array_ != NULL);
int font_index = font_id_map_.SparseToCompact(font_id);
if (font_index < 0) return NULL;
int sample_index = (*font_class_array_)(font_index,
class_id).canonical_sample;
return sample_index >= 0 ? samples_[sample_index] : NULL;
}
// Gets the max distance for the given canonical sample.
// ComputeCanonicalSamples must have been called first.
float TrainingSampleSet::GetCanonicalDist(int font_id, int class_id) const {
ASSERT_HOST(font_class_array_ != NULL);
int font_index = font_id_map_.SparseToCompact(font_id);
if (font_index < 0) return 0.0f;
if ((*font_class_array_)(font_index, class_id).canonical_sample >= 0)
return (*font_class_array_)(font_index, class_id).canonical_dist;
else
return 0.0f;
}
// Generates indexed features for all samples with the supplied feature_space.
void TrainingSampleSet::IndexFeatures(const IntFeatureSpace& feature_space) {
for (int s = 0; s < samples_.size(); ++s)
samples_[s]->IndexFeatures(feature_space);
}
// Marks the given sample index for deletion.
// Deletion is actually completed by DeleteDeadSamples.
void TrainingSampleSet::KillSample(TrainingSample* sample) {
sample->set_sample_index(-1);
}
// Deletes all samples with zero features marked by KillSample.
void TrainingSampleSet::DeleteDeadSamples() {
samples_.compact(
NewPermanentTessCallback(this, &TrainingSampleSet::DeleteableSample));
num_raw_samples_ = samples_.size();
// Samples must be re-organized now we have deleted a few.
}
// Callback function returns true if the given sample is to be deleted, due
// to having a negative classid.
bool TrainingSampleSet::DeleteableSample(const TrainingSample* sample) {
return sample == NULL || sample->class_id() < 0;
}
// Construct an array to access the samples by font,class pair.
void TrainingSampleSet::OrganizeByFontAndClass() {
// Font indexes are sparse, so we used a map to compact them, so we can
// have an efficient 2-d array of fonts and character classes.
SetupFontIdMap();
int compact_font_size = font_id_map_.CompactSize();
// Get a 2-d array of generic vectors.
if (font_class_array_ != NULL)
delete font_class_array_;
FontClassInfo empty;
font_class_array_ = new GENERIC_2D_ARRAY<FontClassInfo>(
compact_font_size, unicharset_size_, empty);
for (int s = 0; s < samples_.size(); ++s) {
int font_id = samples_[s]->font_id();
int class_id = samples_[s]->class_id();
if (font_id < 0 || font_id >= font_id_map_.SparseSize()) {
tprintf("Font id = %d/%d, class id = %d/%d on sample %d\n",
font_id, font_id_map_.SparseSize(), class_id, unicharset_size_,
s);
}
ASSERT_HOST(font_id >= 0 && font_id < font_id_map_.SparseSize());
ASSERT_HOST(class_id >= 0 && class_id < unicharset_size_);
int font_index = font_id_map_.SparseToCompact(font_id);
(*font_class_array_)(font_index, class_id).samples.push_back(s);
}
// Set the num_raw_samples member of the FontClassInfo, to set the boundary
// between the raw samples and the replicated ones.
for (int f = 0; f < compact_font_size; ++f) {
for (int c = 0; c < unicharset_size_; ++c)
(*font_class_array_)(f, c).num_raw_samples =
(*font_class_array_)(f, c).samples.size();
}
// This is the global number of samples and also marks the boundary between
// real and replicated samples.
num_raw_samples_ = samples_.size();
}
// Constructs the font_id_map_ which maps real font_ids (sparse) to a compact
// index for the font_class_array_.
void TrainingSampleSet::SetupFontIdMap() {
// Number of samples for each font_id.
GenericVector<int> font_counts;
for (int s = 0; s < samples_.size(); ++s) {
int font_id = samples_[s]->font_id();
while (font_id >= font_counts.size())
font_counts.push_back(0);
++font_counts[font_id];
}
font_id_map_.Init(font_counts.size(), false);
for (int f = 0; f < font_counts.size(); ++f) {
font_id_map_.SetMap(f, font_counts[f] > 0);
}
font_id_map_.Setup();
}
// Finds the sample for each font, class pair that has least maximum
// distance to all the other samples of the same font, class.
// OrganizeByFontAndClass must have been already called.
void TrainingSampleSet::ComputeCanonicalSamples(const IntFeatureMap& map,
bool debug) {
ASSERT_HOST(font_class_array_ != NULL);
IntFeatureDist f_table;
if (debug) tprintf("feature table size %d\n", map.sparse_size());
f_table.Init(&map);
int worst_s1 = 0;
int worst_s2 = 0;
double global_worst_dist = 0.0;
// Compute distances independently for each font and char index.
int font_size = font_id_map_.CompactSize();
for (int font_index = 0; font_index < font_size; ++font_index) {
int font_id = font_id_map_.CompactToSparse(font_index);
for (int c = 0; c < unicharset_size_; ++c) {
int samples_found = 0;
FontClassInfo& fcinfo = (*font_class_array_)(font_index, c);
if (fcinfo.samples.size() == 0 ||
(kTestChar >= 0 && c != kTestChar)) {
fcinfo.canonical_sample = -1;
fcinfo.canonical_dist = 0.0f;
if (debug) tprintf("Skipping class %d\n", c);
continue;
}
// The canonical sample will be the one with the min_max_dist, which
// is the sample with the lowest maximum distance to all other samples.
double min_max_dist = 2.0;
// We keep track of the farthest apart pair (max_s1, max_s2) which
// are max_max_dist apart, so we can see how bad the variability is.
double max_max_dist = 0.0;
int max_s1 = 0;
int max_s2 = 0;
fcinfo.canonical_sample = fcinfo.samples[0];
fcinfo.canonical_dist = 0.0f;
for (int i = 0; i < fcinfo.samples.size(); ++i) {
int s1 = fcinfo.samples[i];
const GenericVector<int>& features1 = samples_[s1]->indexed_features();
f_table.Set(features1, features1.size(), true);
double max_dist = 0.0;
// Run the full squared-order search for similar samples. It is still
// reasonably fast because f_table.FeatureDistance is fast, but we
// may have to reconsider if we start playing with too many samples
// of a single char/font.
for (int j = 0; j < fcinfo.samples.size(); ++j) {
int s2 = fcinfo.samples[j];
if (samples_[s2]->class_id() != c ||
samples_[s2]->font_id() != font_id ||
s2 == s1)
continue;
GenericVector<int> features2 = samples_[s2]->indexed_features();
double dist = f_table.FeatureDistance(features2);
if (dist > max_dist) {
max_dist = dist;
if (dist > max_max_dist) {
max_s1 = s1;
max_s2 = s2;
}
}
}
// Using Set(..., false) is far faster than re initializing, due to
// the sparseness of the feature space.
f_table.Set(features1, features1.size(), false);
samples_[s1]->set_max_dist(max_dist);
++samples_found;
if (max_dist < min_max_dist) {
fcinfo.canonical_sample = s1;
fcinfo.canonical_dist = max_dist;
}
UpdateRange(max_dist, &min_max_dist, &max_max_dist);
}
if (max_max_dist > global_worst_dist) {
// Keep a record of the worst pair over all characters/fonts too.
global_worst_dist = max_max_dist;
worst_s1 = max_s1;
worst_s2 = max_s2;
}
if (debug) {
tprintf("Found %d samples of class %d=%s, font %d, "
"dist range [%g, %g], worst pair= %s, %s\n",
samples_found, c, unicharset_.debug_str(c).string(),
font_index, min_max_dist, max_max_dist,
SampleToString(*samples_[max_s1]).string(),
SampleToString(*samples_[max_s2]).string());
}
}
}
if (debug) {
tprintf("Global worst dist = %g, between sample %d and %d\n",
global_worst_dist, worst_s1, worst_s2);
}
}
// Replicates the samples to a minimum frequency defined by
// 2 * kSampleRandomSize, or for larger counts duplicates all samples.
// After replication, the replicated samples are perturbed slightly, but
// in a predictable and repeatable way.
// Use after OrganizeByFontAndClass().
void TrainingSampleSet::ReplicateAndRandomizeSamples() {
ASSERT_HOST(font_class_array_ != NULL);
int font_size = font_id_map_.CompactSize();
for (int font_index = 0; font_index < font_size; ++font_index) {
for (int c = 0; c < unicharset_size_; ++c) {
FontClassInfo& fcinfo = (*font_class_array_)(font_index, c);
int sample_count = fcinfo.samples.size();
int min_samples = 2 * MAX(kSampleRandomSize, sample_count);
if (sample_count > 0 && sample_count < min_samples) {
int base_count = sample_count;
for (int base_index = 0; sample_count < min_samples; ++sample_count) {
int src_index = fcinfo.samples[base_index++];
if (base_index >= base_count) base_index = 0;
TrainingSample* sample = samples_[src_index]->RandomizedCopy(
sample_count % kSampleRandomSize);
int sample_index = samples_.size();
sample->set_sample_index(sample_index);
samples_.push_back(sample);
fcinfo.samples.push_back(sample_index);
}
}
}
}
}
// Caches the indexed features of the canonical samples.
// ComputeCanonicalSamples must have been already called.
// TODO(rays) see note on ReliablySeparable and try restricting the
// canonical features to those that truly represent all samples.
void TrainingSampleSet::ComputeCanonicalFeatures() {
ASSERT_HOST(font_class_array_ != NULL);
int font_size = font_id_map_.CompactSize();
for (int font_index = 0; font_index < font_size; ++font_index) {
int font_id = font_id_map_.CompactToSparse(font_index);
for (int c = 0; c < unicharset_size_; ++c) {
int num_samples = NumClassSamples(font_id, c, false);
if (num_samples == 0)
continue;
const TrainingSample* sample = GetCanonicalSample(font_id, c);
FontClassInfo& fcinfo = (*font_class_array_)(font_index, c);
fcinfo.canonical_features = sample->indexed_features();
}
}
}
// Computes the combined set of features used by all the samples of each
// font/class combination. Use after ReplicateAndRandomizeSamples.
void TrainingSampleSet::ComputeCloudFeatures(int feature_space_size) {
ASSERT_HOST(font_class_array_ != NULL);
int font_size = font_id_map_.CompactSize();
for (int font_index = 0; font_index < font_size; ++font_index) {
int font_id = font_id_map_.CompactToSparse(font_index);
for (int c = 0; c < unicharset_size_; ++c) {
int num_samples = NumClassSamples(font_id, c, false);
if (num_samples == 0)
continue;
FontClassInfo& fcinfo = (*font_class_array_)(font_index, c);
fcinfo.cloud_features.Init(feature_space_size);
for (int s = 0; s < num_samples; ++s) {
const TrainingSample* sample = GetSample(font_id, c, s);
const GenericVector<int>& sample_features = sample->indexed_features();
for (int i = 0; i < sample_features.size(); ++i)
fcinfo.cloud_features.SetBit(sample_features[i]);
}
}
}
}
// Adds all fonts of the given class to the shape.
void TrainingSampleSet::AddAllFontsForClass(int class_id, Shape* shape) const {
for (int f = 0; f < font_id_map_.CompactSize(); ++f) {
int font_id = font_id_map_.CompactToSparse(f);
shape->AddToShape(class_id, font_id);
}
}
// Display the samples with the given indexed feature that also match
// the given shape.
void TrainingSampleSet::DisplaySamplesWithFeature(int f_index,
const Shape& shape,
const IntFeatureSpace& space,
ScrollView::Color color,
ScrollView* window) const {
for (int s = 0; s < num_raw_samples(); ++s) {
const TrainingSample* sample = GetSample(s);
if (shape.ContainsUnichar(sample->class_id())) {
GenericVector<int> indexed_features;
space.IndexAndSortFeatures(sample->features(), sample->num_features(),
&indexed_features);
for (int f = 0; f < indexed_features.size(); ++f) {
if (indexed_features[f] == f_index) {
sample->DisplayFeatures(color, window);
}
}
}
}
}
} // namespace tesseract.