mirror of
https://github.com/tesseract-ocr/tesseract.git
synced 2024-11-30 23:49:05 +08:00
4ec9c86226
Signed-off-by: Stefan Weil <sw@weilnetz.de>
527 lines
18 KiB
C++
527 lines
18 KiB
C++
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#include "tesseract/ccmain/equationdetect.h"
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#include <memory>
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#include <string>
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#include <utility>
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#include "leptonica/include/allheaders.h"
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#include "tesseract/ccmain/tesseractclass.h"
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#include "tesseract/textord/colpartitiongrid.h"
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#include "util/gtl/map_util.h"
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#include "util/gtl/stl_util.h"
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namespace tesseract {
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class TestableEquationDetect : public EquationDetect {
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public:
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TestableEquationDetect(const char* tessdata, Tesseract* lang_tesseract)
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: EquationDetect(tessdata, "equ") {
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SetLangTesseract(lang_tesseract);
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}
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// Insert a certain math and digit blobs into part.
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void AddMathDigitBlobs(const int math_blobs, const int digit_blobs,
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const int total_blobs, ColPartition* part) {
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CHECK(part != nullptr);
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CHECK_LE(math_blobs + digit_blobs, total_blobs);
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int count = 0;
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for (int i = 0; i < math_blobs; i++, count++) {
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BLOBNBOX* blob = new BLOBNBOX();
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blob->set_special_text_type(BSTT_MATH);
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part->AddBox(blob);
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}
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for (int i = 0; i < digit_blobs; i++, count++) {
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BLOBNBOX* blob = new BLOBNBOX();
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blob->set_special_text_type(BSTT_DIGIT);
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part->AddBox(blob);
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}
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for (int i = count; i < total_blobs; i++) {
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BLOBNBOX* blob = new BLOBNBOX();
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blob->set_special_text_type(BSTT_NONE);
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part->AddBox(blob);
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}
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}
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// Set up pix_binary for lang_tesseract_.
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void SetPixBinary(Pix* pix) {
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CHECK_EQ(1, pixGetDepth(pix));
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*(lang_tesseract_->mutable_pix_binary()) = pix;
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}
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void RunIdentifySpecialText(BLOBNBOX* blob, const int height_th) {
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IdentifySpecialText(blob, height_th);
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}
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BlobSpecialTextType RunEstimateTypeForUnichar(const char* val) {
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const UNICHARSET& unicharset = lang_tesseract_->unicharset;
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return EstimateTypeForUnichar(unicharset, unicharset.unichar_to_id(val));
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}
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EquationDetect::IndentType RunIsIndented(ColPartitionGrid* part_grid,
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ColPartition* part) {
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this->part_grid_ = part_grid;
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return IsIndented(part);
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}
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bool RunIsNearSmallNeighbor(const TBOX& seed_box, const TBOX& part_box) {
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return IsNearSmallNeighbor(seed_box, part_box);
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}
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bool RunCheckSeedBlobsCount(ColPartition* part) {
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return CheckSeedBlobsCount(part);
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}
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float RunComputeForegroundDensity(const TBOX& tbox) {
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return ComputeForegroundDensity(tbox);
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}
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int RunCountAlignment(const GenericVector<int>& sorted_vec, const int val) {
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return CountAlignment(sorted_vec, val);
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}
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void RunSplitCPHorLite(ColPartition* part,
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GenericVector<TBOX>* splitted_boxes) {
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SplitCPHorLite(part, splitted_boxes);
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}
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void RunSplitCPHor(ColPartition* part,
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GenericVector<ColPartition*>* parts_splitted) {
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SplitCPHor(part, parts_splitted);
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}
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void TestComputeCPsSuperBBox(const TBOX& box, ColPartitionGrid* part_grid) {
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CHECK(part_grid != nullptr);
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part_grid_ = part_grid;
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ComputeCPsSuperBBox();
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EXPECT_TRUE(*cps_super_bbox_ == box);
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}
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};
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class EquationFinderTest : public testing::Test {
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protected:
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std::unique_ptr<TestableEquationDetect> equation_det_;
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std::unique_ptr<Tesseract> tesseract_;
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// The directory for testdata;
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string testdata_dir_;
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void SetUp() {
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string tessdata_dir = file::JoinPath(FLAGS_test_srcdir, "tessdata");
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tesseract_.reset(new Tesseract());
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tesseract_->init_tesseract(tessdata_dir.c_str(), "eng", OEM_TESSERACT_ONLY);
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tesseract_->set_source_resolution(300);
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equation_det_.reset(
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new TestableEquationDetect(tessdata_dir.c_str(), tesseract_.get()));
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equation_det_->SetResolution(300);
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testdata_dir_ = file::JoinPath(FLAGS_test_srcdir, "testdata");
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}
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void TearDown() {
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tesseract_.reset(nullptr);
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equation_det_.reset(nullptr);
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}
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// Add a BLOCK covering the whole page.
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void AddPageBlock(Pix* pix, BLOCK_LIST* blocks) {
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CHECK(pix != nullptr);
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CHECK(blocks != nullptr);
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BLOCK_IT block_it(blocks);
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BLOCK* block =
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new BLOCK("", TRUE, 0, 0, 0, 0, pixGetWidth(pix), pixGetHeight(pix));
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block_it.add_to_end(block);
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}
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// Create col partitions, add into part_grid, and put them into all_parts.
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void CreateColParts(const int rows, const int cols,
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ColPartitionGrid* part_grid,
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std::vector<ColPartition*>* all_parts) {
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const int kWidth = 10, kHeight = 10;
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ClearParts(all_parts);
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for (int y = 0; y < rows; ++y) {
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for (int x = 0; x < cols; ++x) {
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int left = x * kWidth * 2, bottom = y * kHeight * 2;
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TBOX box(left, bottom, left + kWidth, bottom + kHeight);
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ColPartition* part = ColPartition::FakePartition(box, PT_FLOWING_TEXT,
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BRT_TEXT, BTFT_NONE);
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part_grid->InsertBBox(true, true, part);
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all_parts->push_back(part);
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}
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}
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}
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void ClearParts(std::vector<ColPartition*>* all_parts) {
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for (int i = 0; i < all_parts->size(); ++i) {
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(*all_parts)[i]->DeleteBoxes();
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delete ((*all_parts)[i]);
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}
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}
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// Create a BLOBNBOX object with bounding box tbox, and add it into part.
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void AddBlobIntoPart(const TBOX& tbox, ColPartition* part) {
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CHECK(part != nullptr);
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BLOBNBOX* blob = new BLOBNBOX();
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blob->set_bounding_box(tbox);
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part->AddBox(blob);
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}
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};
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TEST_F(EquationFinderTest, IdentifySpecialText) {
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// Load Image.
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string imagefile = file::JoinPath(testdata_dir_, "equ_gt1.tif");
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Pix* pix_binary = pixRead(imagefile.c_str());
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CHECK(pix_binary != nullptr && pixGetDepth(pix_binary) == 1);
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// Get components.
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BLOCK_LIST blocks;
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TO_BLOCK_LIST to_blocks;
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AddPageBlock(pix_binary, &blocks);
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Textord* textord = tesseract_->mutable_textord();
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textord->find_components(pix_binary, &blocks, &to_blocks);
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// Identify special texts from to_blocks.
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TO_BLOCK_IT to_block_it(&to_blocks);
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__gnu_cxx::hash_map<int, int> stt_count;
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for (to_block_it.mark_cycle_pt(); !to_block_it.cycled_list();
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to_block_it.forward()) {
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TO_BLOCK* to_block = to_block_it.data();
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BLOBNBOX_IT blob_it(&(to_block->blobs));
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for (blob_it.mark_cycle_pt(); !blob_it.cycled_list(); blob_it.forward()) {
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BLOBNBOX* blob = blob_it.data();
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// blob->set_special_text_type(BSTT_NONE);
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equation_det_->RunIdentifySpecialText(blob, 0);
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InsertIfNotPresent(&stt_count, blob->special_text_type(), 0);
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stt_count[blob->special_text_type()]++;
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}
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}
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// Verify the number, but allow a range of +/- kCountRange before squealing.
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const int kCountRange = 3;
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EXPECT_GE(39 + kCountRange, stt_count[BSTT_NONE]);
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EXPECT_LE(39 - kCountRange, stt_count[BSTT_NONE]);
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// if you count all the subscripts etc, there are ~45 italic chars.
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EXPECT_GE(45 + kCountRange, stt_count[BSTT_ITALIC]);
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EXPECT_LE(45 - kCountRange, stt_count[BSTT_ITALIC]);
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EXPECT_GE(41 + kCountRange, stt_count[BSTT_DIGIT]);
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EXPECT_LE(41 - kCountRange, stt_count[BSTT_DIGIT]);
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EXPECT_GE(50 + kCountRange, stt_count[BSTT_MATH]);
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EXPECT_LE(50 - kCountRange, stt_count[BSTT_MATH]);
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EXPECT_GE(10 + kCountRange, stt_count[BSTT_UNCLEAR]);
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EXPECT_LE(10 - kCountRange, stt_count[BSTT_UNCLEAR]);
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// Release memory.
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pixDestroy(&pix_binary);
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}
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TEST_F(EquationFinderTest, EstimateTypeForUnichar) {
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// Test abc characters.
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EXPECT_EQ(BSTT_NONE, equation_det_->RunEstimateTypeForUnichar("a"));
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EXPECT_EQ(BSTT_NONE, equation_det_->RunEstimateTypeForUnichar("c"));
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// Test punctuation characters.
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EXPECT_EQ(BSTT_NONE, equation_det_->RunEstimateTypeForUnichar("'"));
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EXPECT_EQ(BSTT_NONE, equation_det_->RunEstimateTypeForUnichar(","));
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// Test digits.
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EXPECT_EQ(BSTT_DIGIT, equation_det_->RunEstimateTypeForUnichar("1"));
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EXPECT_EQ(BSTT_DIGIT, equation_det_->RunEstimateTypeForUnichar("4"));
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EXPECT_EQ(BSTT_DIGIT, equation_det_->RunEstimateTypeForUnichar("|"));
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// Test math symbols.
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EXPECT_EQ(BSTT_MATH, equation_det_->RunEstimateTypeForUnichar("("));
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EXPECT_EQ(BSTT_MATH, equation_det_->RunEstimateTypeForUnichar("+"));
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}
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TEST_F(EquationFinderTest, IsIndented) {
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ColPartitionGrid part_grid(10, ICOORD(0, 0), ICOORD(1000, 1000));
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// Create five ColPartitions:
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// part 1: ************
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// part 2: *********
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// part 3: *******
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// part 4: *****
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//
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// part 5: ********
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TBOX box1(0, 950, 999, 999);
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ColPartition* part1 =
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ColPartition::FakePartition(box1, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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part_grid.InsertBBox(true, true, part1);
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TBOX box2(300, 920, 900, 940);
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ColPartition* part2 =
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ColPartition::FakePartition(box2, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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part_grid.InsertBBox(true, true, part2);
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TBOX box3(0, 900, 600, 910);
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ColPartition* part3 =
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ColPartition::FakePartition(box3, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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part_grid.InsertBBox(true, true, part3);
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TBOX box4(300, 890, 600, 899);
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ColPartition* part4 =
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ColPartition::FakePartition(box4, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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part_grid.InsertBBox(true, true, part4);
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TBOX box5(300, 500, 900, 510);
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ColPartition* part5 =
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ColPartition::FakePartition(box5, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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part_grid.InsertBBox(true, true, part5);
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// Test
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// part1 should be no indent.
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EXPECT_EQ(EquationDetect::NO_INDENT,
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equation_det_->RunIsIndented(&part_grid, part1));
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// part2 should be left indent in terms of part1.
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EXPECT_EQ(EquationDetect::LEFT_INDENT,
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equation_det_->RunIsIndented(&part_grid, part2));
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// part3 should be right indent.
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EXPECT_EQ(EquationDetect::RIGHT_INDENT,
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equation_det_->RunIsIndented(&part_grid, part3));
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// part4 should be both indented.
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EXPECT_EQ(EquationDetect::BOTH_INDENT,
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equation_det_->RunIsIndented(&part_grid, part4));
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// part5 should be no indent because it is too far from part1.
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EXPECT_EQ(EquationDetect::NO_INDENT,
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equation_det_->RunIsIndented(&part_grid, part5));
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// Release memory.
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part1->DeleteBoxes();
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delete (part1);
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part2->DeleteBoxes();
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delete (part2);
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part3->DeleteBoxes();
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delete (part3);
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part4->DeleteBoxes();
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delete (part4);
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part5->DeleteBoxes();
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delete (part5);
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}
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TEST_F(EquationFinderTest, IsNearSmallNeighbor) {
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// Create four tboxes:
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// part 1, part 2
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// ***** *****
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// part 3: *****
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//
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// part 4: *****************
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TBOX box1(0, 950, 499, 999);
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TBOX box2(500, 950, 999, 998);
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TBOX box3(0, 900, 499, 949);
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TBOX box4(0, 550, 499, 590);
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// Test
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// box2 should be box1's near neighbor but not vice versa.
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EXPECT_TRUE(equation_det_->RunIsNearSmallNeighbor(box1, box2));
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EXPECT_FALSE(equation_det_->RunIsNearSmallNeighbor(box2, box1));
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// box1 and box3 should be near neighbors of each other.
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EXPECT_TRUE(equation_det_->RunIsNearSmallNeighbor(box1, box3));
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EXPECT_FALSE(equation_det_->RunIsNearSmallNeighbor(box2, box3));
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// box2 and box3 should not be near neighbors of each other.
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EXPECT_FALSE(equation_det_->RunIsNearSmallNeighbor(box2, box3));
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EXPECT_FALSE(equation_det_->RunIsNearSmallNeighbor(box3, box2));
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// box4 should not be the near neighbor of any one.
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EXPECT_FALSE(equation_det_->RunIsNearSmallNeighbor(box1, box4));
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EXPECT_FALSE(equation_det_->RunIsNearSmallNeighbor(box2, box4));
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EXPECT_FALSE(equation_det_->RunIsNearSmallNeighbor(box3, box4));
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}
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TEST_F(EquationFinderTest, CheckSeedBlobsCount) {
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TBOX box(0, 950, 999, 999);
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ColPartition* part1 =
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ColPartition::FakePartition(box, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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ColPartition* part2 =
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ColPartition::FakePartition(box, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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ColPartition* part3 =
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ColPartition::FakePartition(box, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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ColPartition* part4 =
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ColPartition::FakePartition(box, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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// Part 1: 8 math, 0 digit, 20 total.
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equation_det_->AddMathDigitBlobs(8, 0, 20, part1);
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EXPECT_TRUE(equation_det_->RunCheckSeedBlobsCount(part1));
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// Part 2: 1 math, 8 digit, 20 total.
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equation_det_->AddMathDigitBlobs(1, 8, 20, part2);
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EXPECT_FALSE(equation_det_->RunCheckSeedBlobsCount(part2));
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// Part 3: 3 math, 8 digit, 8 total.
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equation_det_->AddMathDigitBlobs(3, 8, 20, part3);
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EXPECT_TRUE(equation_det_->RunCheckSeedBlobsCount(part3));
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// Part 4: 8 math, 0 digit, 8 total.
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equation_det_->AddMathDigitBlobs(0, 0, 8, part4);
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EXPECT_FALSE(equation_det_->RunCheckSeedBlobsCount(part4));
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// Release memory.
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part1->DeleteBoxes();
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delete (part1);
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part2->DeleteBoxes();
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delete (part2);
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part3->DeleteBoxes();
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delete (part3);
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part4->DeleteBoxes();
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delete (part4);
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}
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TEST_F(EquationFinderTest, ComputeForegroundDensity) {
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// Create the pix with top half foreground, bottom half background.
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int width = 1024, height = 768;
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Pix* pix = pixCreate(width, height, 1);
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pixRasterop(pix, 0, 0, width, height / 2, PIX_SET, nullptr, 0, 0);
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TBOX box1(100, 0, 140, 140), box2(100, height / 2 - 20, 140, height / 2 + 20),
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box3(100, height - 40, 140, height);
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equation_det_->SetPixBinary(pix);
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// Verify
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EXPECT_NEAR(0.0, equation_det_->RunComputeForegroundDensity(box1), 0.0001f);
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EXPECT_NEAR(0.5, equation_det_->RunComputeForegroundDensity(box2), 0.0001f);
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EXPECT_NEAR(1.0, equation_det_->RunComputeForegroundDensity(box3), 0.0001f);
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}
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TEST_F(EquationFinderTest, CountAlignment) {
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GenericVector<int> vec;
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vec.push_back(1);
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vec.push_back(1);
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vec.push_back(1);
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vec.push_back(100);
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vec.push_back(200);
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vec.push_back(200);
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// Test the right point.
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EXPECT_EQ(3, equation_det_->RunCountAlignment(vec, 1));
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EXPECT_EQ(1, equation_det_->RunCountAlignment(vec, 100));
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EXPECT_EQ(2, equation_det_->RunCountAlignment(vec, 200));
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// Test the near neighbors.
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EXPECT_EQ(3, equation_det_->RunCountAlignment(vec, 3));
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EXPECT_EQ(1, equation_det_->RunCountAlignment(vec, 99));
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EXPECT_EQ(2, equation_det_->RunCountAlignment(vec, 202));
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// Test the far neighbors.
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EXPECT_EQ(0, equation_det_->RunCountAlignment(vec, 150));
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EXPECT_EQ(0, equation_det_->RunCountAlignment(vec, 50));
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EXPECT_EQ(0, equation_det_->RunCountAlignment(vec, 250));
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}
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TEST_F(EquationFinderTest, ComputeCPsSuperBBox) {
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Pix* pix = pixCreate(1001, 1001, 1);
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equation_det_->SetPixBinary(pix);
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ColPartitionGrid part_grid(10, ICOORD(0, 0), ICOORD(1000, 1000));
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TBOX box1(0, 0, 999, 99);
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ColPartition* part1 =
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ColPartition::FakePartition(box1, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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TBOX box2(0, 100, 499, 199);
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ColPartition* part2 =
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ColPartition::FakePartition(box2, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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TBOX box3(500, 100, 999, 199);
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ColPartition* part3 =
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ColPartition::FakePartition(box3, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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TBOX box4(0, 200, 999, 299);
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ColPartition* part4 =
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ColPartition::FakePartition(box4, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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TBOX box5(0, 900, 999, 999);
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ColPartition* part5 =
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ColPartition::FakePartition(box5, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
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// Add part1->part3 into part_grid and test.
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part_grid.InsertBBox(true, true, part1);
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part_grid.InsertBBox(true, true, part2);
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part_grid.InsertBBox(true, true, part3);
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TBOX super_box(0, 0, 999, 199);
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equation_det_->TestComputeCPsSuperBBox(super_box, &part_grid);
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// Add part4 and test.
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part_grid.InsertBBox(true, true, part4);
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TBOX super_box2(0, 0, 999, 299);
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equation_det_->TestComputeCPsSuperBBox(super_box2, &part_grid);
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|
|
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// Add part5 and test.
|
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part_grid.InsertBBox(true, true, part5);
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TBOX super_box3(0, 0, 999, 999);
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equation_det_->TestComputeCPsSuperBBox(super_box3, &part_grid);
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|
|
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// Release memory.
|
|
part1->DeleteBoxes();
|
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delete (part1);
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part2->DeleteBoxes();
|
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delete (part2);
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|
part3->DeleteBoxes();
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delete (part3);
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part4->DeleteBoxes();
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delete (part4);
|
|
part5->DeleteBoxes();
|
|
delete (part5);
|
|
}
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|
|
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TEST_F(EquationFinderTest, SplitCPHorLite) {
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TBOX box(0, 0, 999, 99);
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|
ColPartition* part =
|
|
ColPartition::FakePartition(box, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
|
|
part->DeleteBoxes();
|
|
part->set_median_width(10);
|
|
GenericVector<TBOX> splitted_boxes;
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|
|
|
// Test an empty part.
|
|
equation_det_->RunSplitCPHorLite(part, &splitted_boxes);
|
|
EXPECT_TRUE(splitted_boxes.empty());
|
|
|
|
// Test with one blob.
|
|
AddBlobIntoPart(TBOX(0, 0, 10, 50), part);
|
|
equation_det_->RunSplitCPHorLite(part, &splitted_boxes);
|
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EXPECT_EQ(1, splitted_boxes.size());
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|
EXPECT_TRUE(TBOX(0, 0, 10, 50) == splitted_boxes[0]);
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|
|
|
// Add more blob and test.
|
|
AddBlobIntoPart(TBOX(11, 0, 20, 60), part);
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|
AddBlobIntoPart(TBOX(25, 0, 30, 55), part); // break point.
|
|
AddBlobIntoPart(TBOX(100, 0, 110, 15), part);
|
|
AddBlobIntoPart(TBOX(125, 0, 140, 45), part); // break point.
|
|
AddBlobIntoPart(TBOX(500, 0, 540, 35), part); // break point.
|
|
equation_det_->RunSplitCPHorLite(part, &splitted_boxes);
|
|
// Verify.
|
|
EXPECT_EQ(3, splitted_boxes.size());
|
|
EXPECT_TRUE(TBOX(0, 0, 30, 60) == splitted_boxes[0]);
|
|
EXPECT_TRUE(TBOX(100, 0, 140, 45) == splitted_boxes[1]);
|
|
EXPECT_TRUE(TBOX(500, 0, 540, 35) == splitted_boxes[2]);
|
|
|
|
part->DeleteBoxes();
|
|
delete (part);
|
|
}
|
|
|
|
TEST_F(EquationFinderTest, SplitCPHor) {
|
|
TBOX box(0, 0, 999, 99);
|
|
ColPartition* part =
|
|
ColPartition::FakePartition(box, PT_FLOWING_TEXT, BRT_TEXT, BTFT_NONE);
|
|
part->DeleteBoxes();
|
|
part->set_median_width(10);
|
|
GenericVector<ColPartition*> parts_splitted;
|
|
|
|
// Test an empty part.
|
|
equation_det_->RunSplitCPHor(part, &parts_splitted);
|
|
EXPECT_TRUE(parts_splitted.empty());
|
|
// Test with one blob.
|
|
AddBlobIntoPart(TBOX(0, 0, 10, 50), part);
|
|
|
|
equation_det_->RunSplitCPHor(part, &parts_splitted);
|
|
EXPECT_EQ(1, parts_splitted.size());
|
|
EXPECT_TRUE(TBOX(0, 0, 10, 50) == parts_splitted[0]->bounding_box());
|
|
|
|
// Add more blob and test.
|
|
AddBlobIntoPart(TBOX(11, 0, 20, 60), part);
|
|
AddBlobIntoPart(TBOX(25, 0, 30, 55), part); // break point.
|
|
AddBlobIntoPart(TBOX(100, 0, 110, 15), part);
|
|
AddBlobIntoPart(TBOX(125, 0, 140, 45), part); // break point.
|
|
AddBlobIntoPart(TBOX(500, 0, 540, 35), part); // break point.
|
|
equation_det_->RunSplitCPHor(part, &parts_splitted);
|
|
|
|
// Verify.
|
|
EXPECT_EQ(3, parts_splitted.size());
|
|
EXPECT_TRUE(TBOX(0, 0, 30, 60) == parts_splitted[0]->bounding_box());
|
|
EXPECT_TRUE(TBOX(100, 0, 140, 45) == parts_splitted[1]->bounding_box());
|
|
EXPECT_TRUE(TBOX(500, 0, 540, 35) == parts_splitted[2]->bounding_box());
|
|
|
|
parts_splitted.delete_data_pointers();
|
|
part->DeleteBoxes();
|
|
delete (part);
|
|
}
|
|
|
|
} // namespace tesseract
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