コード例 #1
0
ファイル: ratngs.cpp プロジェクト: Annyjain29/tess-two
// Displays the segmentation state of *this (if not the same as the last
// one displayed) and waits for a click in the window.
void WERD_CHOICE::DisplaySegmentation(TWERD* word) {
#ifndef GRAPHICS_DISABLED
  // Number of different colors to draw with.
  const int kNumColors = 6;
  static ScrollView *segm_window = NULL;
  // Check the state against the static prev_drawn_state.
  static GenericVector<int> prev_drawn_state;
  bool already_done = prev_drawn_state.size() == length_;
  if (!already_done) prev_drawn_state.init_to_size(length_, 0);
  for (int i = 0; i < length_; ++i) {
    if (prev_drawn_state[i] != state_[i]) {
      already_done = false;
    }
    prev_drawn_state[i] = state_[i];
  }
  if (already_done || word->blobs.empty()) return;

  // Create the window if needed.
  if (segm_window == NULL) {
    segm_window = new ScrollView("Segmentation", 5, 10, 500, 256,
                                 2000.0, 256.0, true);
  } else {
    segm_window->Clear();
  }

  TBOX bbox;
  int blob_index = 0;
  for (int c = 0; c < length_; ++c) {
    ScrollView::Color color =
        static_cast<ScrollView::Color>(c % kNumColors + 3);
    for (int i = 0; i < state_[c]; ++i, ++blob_index) {
      TBLOB* blob = word->blobs[blob_index];
      bbox += blob->bounding_box();
      blob->plot(segm_window, color, color);
    }
  }
  segm_window->ZoomToRectangle(bbox.left(), bbox.top(),
                               bbox.right(), bbox.bottom());
  segm_window->Update();
  window_wait(segm_window);
#endif
}
コード例 #2
0
ファイル: seam.cpp プロジェクト: 11110101/tess-two
/**
 * @name test_insert_seam
 *
 * @returns true if insert_seam will succeed.
 */
bool test_insert_seam(const GenericVector<SEAM*>& seam_array,
                      TWERD *word, int index) {
  SEAM *test_seam;
  int list_length = seam_array.size();
  for (int test_index = 0; test_index < index; ++test_index) {
    test_seam = seam_array[test_index];
    if (test_index + test_seam->widthp < index &&
        test_seam->widthp + test_index == index - 1 &&
        account_splits(test_seam, word, test_index + 1, 1) < 0)
      return false;
  }
  for (int test_index = index; test_index < list_length; test_index++) {
    test_seam = seam_array[test_index];
    if (test_index - test_seam->widthn >= index &&
        test_index - test_seam->widthn == index &&
        account_splits(test_seam, word, test_index + 1, -1) < 0)
      return false;
  }
  return true;
}
コード例 #3
0
ファイル: errorcounter.cpp プロジェクト: 0xkasun/Dummy_Tes
// Accumulates counts for junk. Counts only whether the junk was correctly
// rejected or not.
void ErrorCounter::AccumulateJunk(const ShapeTable& shape_table,
                                  const GenericVector<ShapeRating>& results,
                                  TrainingSample* sample) {
  // For junk we accept no answer, or an explicit shape answer matching the
  // class id of the sample.
  int num_results = results.size();
  int font_id = sample->font_id();
  int unichar_id = sample->class_id();
  if (num_results > 0 &&
      !shape_table.GetShape(results[0].shape_id).ContainsUnichar(unichar_id)) {
    // This is a junk error.
    ++font_counts_[font_id].n[CT_ACCEPTED_JUNK];
    sample->set_is_error(true);
    // It counts as an error for boosting too so sum the weight.
    scaled_error_ += sample->weight();
  } else {
    // Correctly rejected.
    ++font_counts_[font_id].n[CT_REJECTED_JUNK];
    sample->set_is_error(false);
  }
}
コード例 #4
0
// Computes the features used by the subset of samples defined by
// the iterator and sets up the feature mapping.
// Returns the size of the compacted feature space.
int IntFeatureMap::FindNZFeatureMapping(SampleIterator* it) {
  feature_map_.Init(feature_space_.Size(), false);
  int total_samples = 0;
  for (it->Begin(); !it->AtEnd(); it->Next()) {
    const TrainingSample& sample = it->GetSample();
    GenericVector<int> features;
    feature_space_.IndexAndSortFeatures(sample.features(),
                                        sample.num_features(),
                                        &features);
    int num_features = features.size();
    for (int f = 0; f < num_features; ++f)
      feature_map_.SetMap(features[f], true);
    ++total_samples;
  }
  feature_map_.Setup();
  compact_size_ = feature_map_.CompactSize();
  mapping_changed_ = true;
  FinalizeMapping(it);
  tprintf("%d non-zero features found in %d samples\n",
          compact_size_, total_samples);
  return compact_size_;
}
コード例 #5
0
// Displays the labels and cuts at the corresponding xcoords.
// Size of labels should match xcoords.
void LSTMRecognizer::DisplayLSTMOutput(const GenericVector<int>& labels,
                                       const GenericVector<int>& xcoords,
                                       int height, ScrollView* window) {
#ifndef GRAPHICS_DISABLED  // do nothing if there's no graphics
  int x_scale = network_->XScaleFactor();
  window->TextAttributes("Arial", height / 4, false, false, false);
  int end = 1;
  for (int start = 0; start < labels.size(); start = end) {
    int xpos = xcoords[start] * x_scale;
    if (labels[start] == null_char_) {
      end = start + 1;
      window->Pen(ScrollView::RED);
    } else {
      window->Pen(ScrollView::GREEN);
      const char* str = DecodeLabel(labels, start, &end, NULL);
      if (*str == '\\') str = "\\\\";
      xpos = xcoords[(start + end) / 2] * x_scale;
      window->Text(xpos, height, str);
    }
    window->Line(xpos, 0, xpos, height * 3 / 2);
  }
  window->Update();
#endif  // GRAPHICS_DISABLED
}
コード例 #6
0
// Prints debug output detailing the activation path that is implied by the
// label_coords.
void LSTMRecognizer::DebugActivationPath(const NetworkIO& outputs,
                                         const GenericVector<int>& labels,
                                         const GenericVector<int>& xcoords) {
  if (xcoords[0] > 0)
    DebugActivationRange(outputs, "<null>", null_char_, 0, xcoords[0]);
  int end = 1;
  for (int start = 0; start < labels.size(); start = end) {
    if (labels[start] == null_char_) {
      end = start + 1;
      DebugActivationRange(outputs, "<null>", null_char_, xcoords[start],
                           xcoords[end]);
      continue;
    } else {
      int decoded;
      const char* label = DecodeLabel(labels, start, &end, &decoded);
      DebugActivationRange(outputs, label, labels[start], xcoords[start],
                           xcoords[start + 1]);
      for (int i = start + 1; i < end; ++i) {
        DebugActivationRange(outputs, DecodeSingleLabel(labels[i]), labels[i],
                             xcoords[i], xcoords[i + 1]);
      }
    }
  }
}
コード例 #7
0
ファイル: tesseractmain.cpp プロジェクト: ErwcPKerr/node-dv
int main(int argc, char **argv) {
  if ((argc == 2 && strcmp(argv[1], "-v") == 0) ||
      (argc == 2 && strcmp(argv[1], "--version") == 0)) {
    char *versionStrP;

    fprintf(stderr, "tesseract %s\n", tesseract::TessBaseAPI::Version());

    versionStrP = getLeptonicaVersion();
    fprintf(stderr, " %s\n", versionStrP);
    lept_free(versionStrP);

    versionStrP = getImagelibVersions();
    fprintf(stderr, "  %s\n", versionStrP);
    lept_free(versionStrP);

    exit(0);
  }

  // Make the order of args a bit more forgiving than it used to be.
  const char* lang = "eng";
  const char* image = NULL;
  const char* output = NULL;
  bool noocr = false;
  bool list_langs = false;
  bool print_parameters = false;

  tesseract::PageSegMode pagesegmode = tesseract::PSM_AUTO;
  int arg = 1;
  while (arg < argc && (output == NULL || argv[arg][0] == '-')) {
    if (strcmp(argv[arg], "-l") == 0 && arg + 1 < argc) {
      lang = argv[arg + 1];
      ++arg;
    } else if (strcmp(argv[arg], "-psm") == 0 && arg + 1 < argc) {
      pagesegmode = static_cast<tesseract::PageSegMode>(atoi(argv[arg + 1]));
      ++arg;
    } else if (strcmp(argv[arg], "--print-parameters") == 0) {
      noocr = true;
      print_parameters = true;
    } else if (strcmp(argv[arg], "-c") == 0 && arg + 1 < argc) {
      // handled properly after api init
      ++arg;
    } else if (image == NULL) {
      image = argv[arg];
    } else if (output == NULL) {
      output = argv[arg];
    }
    ++arg;
  }

  if (argc == 2 && strcmp(argv[1], "--list-langs") == 0) {
    list_langs = true;
    noocr = true;
  }

  if (output == NULL && noocr == false) {
    fprintf(stderr, "Usage:%s imagename outputbase|stdout [-l lang] "
                      "[-psm pagesegmode] [-c configvar=value] "
                      "[configfile...]\n\n", argv[0]);
    fprintf(stderr,
              "pagesegmode values are:\n"
              "0 = Orientation and script detection (OSD) only.\n"
              "1 = Automatic page segmentation with OSD.\n"
              "2 = Automatic page segmentation, but no OSD, or OCR\n"
              "3 = Fully automatic page segmentation, but no OSD. (Default)\n"
              "4 = Assume a single column of text of variable sizes.\n"
              "5 = Assume a single uniform block of vertically aligned text.\n"
              "6 = Assume a single uniform block of text.\n"
              "7 = Treat the image as a single text line.\n"
              "8 = Treat the image as a single word.\n"
              "9 = Treat the image as a single word in a circle.\n"
              "10 = Treat the image as a single character.\n");
    fprintf(stderr, "multiple -c arguments are allowed.\n");
    fprintf(stderr, "-l lang, -psm pagesegmode and any -c options must occur"
                      "before any configfile.\n\n");
    fprintf(stderr, "Single options:\n");
    fprintf(stderr, "  -v --version: version info\n");
    fprintf(stderr, "  --list-langs: list available languages for tesseract "
                      "engine\n");
    fprintf(stderr, "  --print-parameters: print tesseract parameters to the "
                      "stdout\n");
    exit(1);
  }

  tesseract::TessBaseAPI api;

  STRING tessdata_dir;
  truncate_path(argv[0], &tessdata_dir);
  api.SetOutputName(output);
  int rc = api.Init(tessdata_dir.string(), lang, tesseract::OEM_DEFAULT,
                &(argv[arg]), argc - arg, NULL, NULL, false);

  if (rc) {
    fprintf(stderr, "Could not initialize tesseract.\n");
    exit(1);
  }

  char opt1[255], opt2[255];
  for (arg = 0; arg < argc; arg++) {
    if (strcmp(argv[arg], "-c") == 0 && arg + 1 < argc) {
      strncpy(opt1, argv[arg + 1], 255);
      *(strchr(opt1, '=')) = 0;
      strncpy(opt2, strchr(argv[arg + 1], '=') + 1, 255);
      opt2[254] = 0;
      ++arg;

      if(!api.SetVariable(opt1, opt2)) {
        fprintf(stderr, "Could not set option: %s=%s\n", opt1, opt2);
      }
    }
  }

  if (list_langs) {
     GenericVector<STRING> languages;
     api.GetAvailableLanguagesAsVector(&languages);
     fprintf(stderr, "List of available languages (%d):\n",
             languages.size());
     for (int index = 0; index < languages.size(); ++index) {
       STRING& string = languages[index];
       fprintf(stderr, "%s\n", string.string());
     }
     api.End();
     exit(0);
  }

  if (print_parameters) {
     FILE* fout = stdout;
     fprintf(stdout, "Tesseract parameters:\n");
     api.PrintVariables(fout);
     api.End();
     exit(0);
  }

  // We have 2 possible sources of pagesegmode: a config file and
  // the command line. For backwards compatability reasons, the
  // default in tesseract is tesseract::PSM_SINGLE_BLOCK, but the
  // default for this program is tesseract::PSM_AUTO. We will let
  // the config file take priority, so the command-line default
  // can take priority over the tesseract default, so we use the
  // value from the command line only if the retrieved mode
  // is still tesseract::PSM_SINGLE_BLOCK, indicating no change
  // in any config file. Therefore the only way to force
  // tesseract::PSM_SINGLE_BLOCK is from the command line.
  // It would be simpler if we could set the value before Init,
  // but that doesn't work.
  if (api.GetPageSegMode() == tesseract::PSM_SINGLE_BLOCK)
    api.SetPageSegMode(pagesegmode);
  tprintf("Tesseract Open Source OCR Engine v%s with Leptonica\n",
           tesseract::TessBaseAPI::Version());


  FILE* fin = fopen(image, "rb");
  if (fin == NULL) {
    fprintf(stderr, "Cannot open input file: %s\n", image);
    exit(2);
  }
  fclose(fin);

  bool output_hocr = false;
  api.GetBoolVariable("tessedit_create_hocr", &output_hocr);
  bool output_box = false;
  api.GetBoolVariable("tessedit_create_boxfile", &output_box);

  FILE* fout = stdout;
  if (strcmp(output, "-") && strcmp(output, "stdout")) {
    STRING outfile = output;
    outfile += output_hocr ? ".html" : output_box ? ".box" : ".txt";
    fout = fopen(outfile.string(), "wb");
    if (fout == NULL) {
      fprintf(stderr, "Cannot create output file %s\n", outfile.string());
      exit(1);
    }
  }

  STRING text_out;
  if (!api.ProcessPages(image, NULL, 0, &text_out)) {
    fprintf(stderr, "Error during processing.\n");
    if (fout != stdout)
      fclose(fout);
  exit(1);
  }

  fwrite(text_out.string(), 1, text_out.length(), fout);
  if (fout != stdout)
    fclose(fout);
  else
    clearerr(fout);

  return 0;                      // Normal exit
}
コード例 #8
0
ファイル: errorcounter.cpp プロジェクト: 0xkasun/Dummy_Tes
// Accumulates the errors from the classifier results on a single sample.
// Returns true if debug is true and a CT_UNICHAR_TOPN_ERR error occurred.
// boosting_mode selects the type of error to be used for boosting and the
// is_error_ member of sample is set according to whether the required type
// of error occurred. The font_table provides access to font properties
// for error counting and shape_table is used to understand the relationship
// between unichar_ids and shape_ids in the results
bool ErrorCounter::AccumulateErrors(bool debug, CountTypes boosting_mode,
                                    const UnicityTable<FontInfo>& font_table,
                                    const ShapeTable& shape_table,
                                    const GenericVector<ShapeRating>& results,
                                    TrainingSample* sample) {
  int num_results = results.size();
  int res_index = 0;
  bool debug_it = false;
  int font_id = sample->font_id();
  int unichar_id = sample->class_id();
  sample->set_is_error(false);
  if (num_results == 0) {
    // Reject. We count rejects as a separate category, but still mark the
    // sample as an error in case any training module wants to use that to
    // improve the classifier.
    sample->set_is_error(true);
    ++font_counts_[font_id].n[CT_REJECT];
  } else if (shape_table.GetShape(results[0].shape_id).
          ContainsUnicharAndFont(unichar_id, font_id)) {
    ++font_counts_[font_id].n[CT_SHAPE_TOP_CORRECT];
    // Unichar and font OK, but count if multiple unichars.
    if (shape_table.GetShape(results[0].shape_id).size() > 1)
      ++font_counts_[font_id].n[CT_OK_MULTI_UNICHAR];
  } else {
    // This is a top shape error.
    ++font_counts_[font_id].n[CT_SHAPE_TOP_ERR];
    // Check to see if any font in the top choice has attributes that match.
    bool attributes_match = false;
    uinT32 font_props = font_table.get(font_id).properties;
    const Shape& shape = shape_table.GetShape(results[0].shape_id);
    for (int c = 0; c < shape.size() && !attributes_match; ++c) {
      for (int f = 0; f < shape[c].font_ids.size(); ++f) {
        if (font_table.get(shape[c].font_ids[f]).properties == font_props) {
          attributes_match = true;
          break;
        }
      }
    }
    // TODO(rays) It is easy to add counters for individual font attributes
    // here if we want them.
    if (!attributes_match)
      ++font_counts_[font_id].n[CT_FONT_ATTR_ERR];
    if (boosting_mode == CT_SHAPE_TOP_ERR) sample->set_is_error(true);
    // Find rank of correct unichar answer. (Ignoring the font.)
    while (res_index < num_results &&
           !shape_table.GetShape(results[res_index].shape_id).
                ContainsUnichar(unichar_id)) {
      ++res_index;
    }
    if (res_index == 0) {
      // Unichar OK, but count if multiple unichars.
      if (shape_table.GetShape(results[res_index].shape_id).size() > 1) {
        ++font_counts_[font_id].n[CT_OK_MULTI_UNICHAR];
      }
    } else {
      // Count maps from unichar id to shape id.
      if (num_results > 0)
        ++unichar_counts_(unichar_id, results[0].shape_id);
      // This is a unichar error.
      ++font_counts_[font_id].n[CT_UNICHAR_TOP1_ERR];
      if (boosting_mode == CT_UNICHAR_TOP1_ERR) sample->set_is_error(true);
      if (res_index >= MIN(2, num_results)) {
        // It is also a 2nd choice unichar error.
        ++font_counts_[font_id].n[CT_UNICHAR_TOP2_ERR];
        if (boosting_mode == CT_UNICHAR_TOP2_ERR) sample->set_is_error(true);
      }
      if (res_index >= num_results) {
        // It is also a top-n choice unichar error.
        ++font_counts_[font_id].n[CT_UNICHAR_TOPN_ERR];
        if (boosting_mode == CT_UNICHAR_TOPN_ERR) sample->set_is_error(true);
        debug_it = debug;
      }
    }
  }
  // Compute mean number of return values and mean rank of correct answer.
  font_counts_[font_id].n[CT_NUM_RESULTS] += num_results;
  font_counts_[font_id].n[CT_RANK] += res_index;
  // If it was an error for boosting then sum the weight.
  if (sample->is_error()) {
    scaled_error_ += sample->weight();
  }
  if (debug_it) {
    tprintf("%d results for char %s font %d :",
            num_results, shape_table.unicharset().id_to_unichar(unichar_id),
            font_id);
    for (int i = 0; i < num_results; ++i) {
      tprintf(" %.3f/%.3f:%s",
              results[i].rating, results[i].font,
              shape_table.DebugStr(results[i].shape_id).string());
    }
    tprintf("\n");
    return true;
  }
  return false;
}
コード例 #9
0
ファイル: ambigs.cpp プロジェクト: Kailigithub/tesseract
void UnicharAmbigs::LoadUnicharAmbigs(const UNICHARSET& encoder_set,
                                      TFile *ambig_file,
                                      int debug_level,
                                      bool use_ambigs_for_adaption,
                                      UNICHARSET *unicharset) {
  int i, j;
  UnicharIdVector *adaption_ambigs_entry;
  if (debug_level) tprintf("Reading ambiguities\n");

  int test_ambig_part_size;
  int replacement_ambig_part_size;
  // The space for buffer is allocated on the heap to avoid
  // GCC frame size warning.
  const int kBufferSize = 10 + 2 * kMaxAmbigStringSize;
  char *buffer = new char[kBufferSize];
  char replacement_string[kMaxAmbigStringSize];
  UNICHAR_ID test_unichar_ids[MAX_AMBIG_SIZE + 1];
  int line_num = 0;
  int type = NOT_AMBIG;

  // Determine the version of the ambigs file.
  int version = 0;
  ASSERT_HOST(ambig_file->FGets(buffer, kBufferSize) != NULL &&
              strlen(buffer) > 0);
  if (*buffer == 'v') {
    version = static_cast<int>(strtol(buffer+1, NULL, 10));
    ++line_num;
  } else {
    ambig_file->Rewind();
  }
  while (ambig_file->FGets(buffer, kBufferSize) != NULL) {
    chomp_string(buffer);
    if (debug_level > 2) tprintf("read line %s\n", buffer);
    ++line_num;
    if (!ParseAmbiguityLine(line_num, version, debug_level, encoder_set,
                            buffer, &test_ambig_part_size, test_unichar_ids,
                            &replacement_ambig_part_size,
                            replacement_string, &type)) continue;
    // Construct AmbigSpec and add it to the appropriate AmbigSpec_LIST.
    AmbigSpec *ambig_spec = new AmbigSpec();
    if (!InsertIntoTable((type == REPLACE_AMBIG) ? replace_ambigs_
                                                 : dang_ambigs_,
                         test_ambig_part_size, test_unichar_ids,
                         replacement_ambig_part_size, replacement_string, type,
                         ambig_spec, unicharset))
      continue;

    // Update one_to_one_definite_ambigs_.
    if (test_ambig_part_size == 1 &&
        replacement_ambig_part_size == 1 && type == DEFINITE_AMBIG) {
      if (one_to_one_definite_ambigs_[test_unichar_ids[0]] == NULL) {
        one_to_one_definite_ambigs_[test_unichar_ids[0]] = new UnicharIdVector();
      }
      one_to_one_definite_ambigs_[test_unichar_ids[0]]->push_back(
          ambig_spec->correct_ngram_id);
    }
    // Update ambigs_for_adaption_.
    if (use_ambigs_for_adaption) {
      GenericVector<UNICHAR_ID> encoding;
      // Silently ignore invalid strings, as before, so it is safe to use a
      // universal ambigs file.
      if (unicharset->encode_string(replacement_string, true, &encoding,
                                    NULL, NULL)) {
        for (i = 0; i < test_ambig_part_size; ++i) {
          if (ambigs_for_adaption_[test_unichar_ids[i]] == NULL) {
            ambigs_for_adaption_[test_unichar_ids[i]] = new UnicharIdVector();
          }
          adaption_ambigs_entry = ambigs_for_adaption_[test_unichar_ids[i]];
          for (int r = 0; r < encoding.size(); ++r) {
            UNICHAR_ID id_to_insert = encoding[r];
            ASSERT_HOST(id_to_insert != INVALID_UNICHAR_ID);
            // Add the new unichar id to adaption_ambigs_entry (only if the
            // vector does not already contain it) keeping it in sorted order.
            for (j = 0; j < adaption_ambigs_entry->size() &&
                 (*adaption_ambigs_entry)[j] > id_to_insert; ++j);
            if (j < adaption_ambigs_entry->size()) {
              if ((*adaption_ambigs_entry)[j] != id_to_insert) {
                adaption_ambigs_entry->insert(id_to_insert, j);
              }
            } else {
              adaption_ambigs_entry->push_back(id_to_insert);
            }
          }
        }
      }
    }
  }
  delete[] buffer;

  // Fill in reverse_ambigs_for_adaption from ambigs_for_adaption vector.
  if (use_ambigs_for_adaption) {
    for (i = 0; i < ambigs_for_adaption_.size(); ++i) {
      adaption_ambigs_entry = ambigs_for_adaption_[i];
      if (adaption_ambigs_entry == NULL) continue;
      for (j = 0; j < adaption_ambigs_entry->size(); ++j) {
        UNICHAR_ID ambig_id = (*adaption_ambigs_entry)[j];
        if (reverse_ambigs_for_adaption_[ambig_id] == NULL) {
          reverse_ambigs_for_adaption_[ambig_id] = new UnicharIdVector();
        }
        reverse_ambigs_for_adaption_[ambig_id]->push_back(i);
      }
    }
  }

  // Print what was read from the input file.
  if (debug_level > 1) {
    for (int tbl = 0; tbl < 2; ++tbl) {
      const UnicharAmbigsVector &print_table =
        (tbl == 0) ? replace_ambigs_ : dang_ambigs_;
      for (i = 0; i < print_table.size(); ++i) {
        AmbigSpec_LIST *lst = print_table[i];
        if (lst == NULL) continue;
        if (!lst->empty()) {
          tprintf("%s Ambiguities for %s:\n",
                  (tbl == 0) ? "Replaceable" : "Dangerous",
                  unicharset->debug_str(i).string());
        }
        AmbigSpec_IT lst_it(lst);
        for (lst_it.mark_cycle_pt(); !lst_it.cycled_list(); lst_it.forward()) {
          AmbigSpec *ambig_spec = lst_it.data();
          tprintf("wrong_ngram:");
          UnicharIdArrayUtils::print(ambig_spec->wrong_ngram, *unicharset);
          tprintf("correct_fragments:");
          UnicharIdArrayUtils::print(ambig_spec->correct_fragments, *unicharset);
        }
      }
    }
    if (use_ambigs_for_adaption) {
      for (int vec_id = 0; vec_id < 2; ++vec_id) {
        const GenericVector<UnicharIdVector *> &vec = (vec_id == 0) ?
          ambigs_for_adaption_ : reverse_ambigs_for_adaption_;
        for (i = 0; i < vec.size(); ++i) {
          adaption_ambigs_entry = vec[i];
          if (adaption_ambigs_entry != NULL) {
            tprintf("%sAmbigs for adaption for %s:\n",
                    (vec_id == 0) ? "" : "Reverse ",
                    unicharset->debug_str(i).string());
            for (j = 0; j < adaption_ambigs_entry->size(); ++j) {
              tprintf("%s ", unicharset->debug_str(
                  (*adaption_ambigs_entry)[j]).string());
            }
            tprintf("\n");
          }
        }
      }
    }
  }
}
コード例 #10
0
ファイル: ambigs.cpp プロジェクト: Kailigithub/tesseract
bool UnicharAmbigs::ParseAmbiguityLine(
    int line_num, int version, int debug_level, const UNICHARSET &unicharset,
    char *buffer, int *test_ambig_part_size, UNICHAR_ID *test_unichar_ids,
    int *replacement_ambig_part_size, char *replacement_string, int *type) {
  if (version > 1) {
    // Simpler format is just wrong-string correct-string type\n.
    STRING input(buffer);
    GenericVector<STRING> fields;
    input.split(' ', &fields);
    if (fields.size() != 3) {
      if (debug_level) tprintf(kIllegalMsg, line_num);
      return false;
    }
    // Encode wrong-string.
    GenericVector<UNICHAR_ID> unichars;
    if (!unicharset.encode_string(fields[0].string(), true, &unichars, NULL,
                                  NULL)) {
      return false;
    }
    *test_ambig_part_size = unichars.size();
    if (*test_ambig_part_size > MAX_AMBIG_SIZE) {
      if (debug_level)
        tprintf("Too many unichars in ambiguity on line %d\n", line_num);
      return false;
    }
    // Copy encoded string to output.
    for (int i = 0; i < unichars.size(); ++i)
      test_unichar_ids[i] = unichars[i];
    test_unichar_ids[unichars.size()] = INVALID_UNICHAR_ID;
    // Encode replacement-string to check validity.
    if (!unicharset.encode_string(fields[1].string(), true, &unichars, NULL,
                                  NULL)) {
      return false;
    }
    *replacement_ambig_part_size = unichars.size();
    if (*replacement_ambig_part_size > MAX_AMBIG_SIZE) {
      if (debug_level)
        tprintf("Too many unichars in ambiguity on line %d\n", line_num);
      return false;
    }
    if (sscanf(fields[2].string(), "%d", type) != 1) {
      if (debug_level) tprintf(kIllegalMsg, line_num);
      return false;
    }
    snprintf(replacement_string, kMaxAmbigStringSize, "%s", fields[1].string());
    return true;
  }
  int i;
  char *token;
  char *next_token;
  if (!(token = strtok_r(buffer, kAmbigDelimiters, &next_token)) ||
      !sscanf(token, "%d", test_ambig_part_size) ||
      *test_ambig_part_size <= 0) {
    if (debug_level) tprintf(kIllegalMsg, line_num);
    return false;
  }
  if (*test_ambig_part_size > MAX_AMBIG_SIZE) {
    if (debug_level)
      tprintf("Too many unichars in ambiguity on line %d\n", line_num);
    return false;
  }
  for (i = 0; i < *test_ambig_part_size; ++i) {
    if (!(token = strtok_r(NULL, kAmbigDelimiters, &next_token))) break;
    if (!unicharset.contains_unichar(token)) {
      if (debug_level) tprintf(kIllegalUnicharMsg, token);
      break;
    }
    test_unichar_ids[i] = unicharset.unichar_to_id(token);
  }
  test_unichar_ids[i] = INVALID_UNICHAR_ID;

  if (i != *test_ambig_part_size ||
      !(token = strtok_r(NULL, kAmbigDelimiters, &next_token)) ||
      !sscanf(token, "%d", replacement_ambig_part_size) ||
        *replacement_ambig_part_size <= 0) {
    if (debug_level) tprintf(kIllegalMsg, line_num);
    return false;
  }
  if (*replacement_ambig_part_size > MAX_AMBIG_SIZE) {
    if (debug_level)
      tprintf("Too many unichars in ambiguity on line %d\n", line_num);
    return false;
  }
  replacement_string[0] = '\0';
  for (i = 0; i < *replacement_ambig_part_size; ++i) {
    if (!(token = strtok_r(NULL, kAmbigDelimiters, &next_token))) break;
    strcat(replacement_string, token);
    if (!unicharset.contains_unichar(token)) {
      if (debug_level) tprintf(kIllegalUnicharMsg, token);
      break;
    }
  }
  if (i != *replacement_ambig_part_size) {
    if (debug_level) tprintf(kIllegalMsg, line_num);
    return false;
  }
  if (version > 0) {
    // The next field being true indicates that the abiguity should
    // always be substituted (e.g. '' should always be changed to ").
    // For such "certain" n -> m ambigs tesseract will insert character
    // fragments for the n pieces in the unicharset. AmbigsFound()
    // will then replace the incorrect ngram with the character
    // fragments of the correct character (or ngram if m > 1).
    // Note that if m > 1, an ngram will be inserted into the
    // modified word, not the individual unigrams. Tesseract
    // has limited support for ngram unichar (e.g. dawg permuter).
    if (!(token = strtok_r(NULL, kAmbigDelimiters, &next_token)) ||
        !sscanf(token, "%d", type)) {
      if (debug_level) tprintf(kIllegalMsg, line_num);
      return false;
    }
  }
  return true;
}
コード例 #11
0
// Gets the properties for a grapheme string, combining properties for
// multiple characters in a meaningful way where possible.
// Returns false if no valid match was found in the unicharset.
// NOTE that script_id, mirror, and other_case refer to this unicharset on
// return and will need translation if the target unicharset is different.
bool UNICHARSET::GetStrProperties(const char* utf8_str,
                                  UNICHAR_PROPERTIES* props) const {
  props->Init();
  props->SetRangesEmpty();
  props->min_advance = 0;
  props->max_advance = 0;
  int total_unicodes = 0;
  GenericVector<UNICHAR_ID> encoding;
  if (!encode_string(utf8_str, true, &encoding, NULL, NULL))
    return false;  // Some part was invalid.
  for (int i = 0; i < encoding.size(); ++i) {
    int id = encoding[i];
    const UNICHAR_PROPERTIES& src_props = unichars[id].properties;
    // Logical OR all the bools.
    if (src_props.isalpha) props->isalpha = true;
    if (src_props.islower) props->islower = true;
    if (src_props.isupper) props->isupper = true;
    if (src_props.isdigit) props->isdigit = true;
    if (src_props.ispunctuation) props->ispunctuation = true;
    if (src_props.isngram) props->isngram = true;
    if (src_props.enabled) props->enabled = true;
    // Min/max the tops/bottoms.
    UpdateRange(src_props.min_bottom, &props->min_bottom, &props->max_bottom);
    UpdateRange(src_props.max_bottom, &props->min_bottom, &props->max_bottom);
    UpdateRange(src_props.min_top, &props->min_top, &props->max_top);
    UpdateRange(src_props.max_top, &props->min_top, &props->max_top);
    int bearing = ClipToRange(props->min_advance + src_props.min_bearing,
                              -MAX_INT16, MAX_INT16);
    if (total_unicodes == 0 || bearing < props->min_bearing)
      props->min_bearing = bearing;
    bearing = ClipToRange(props->max_advance + src_props.max_bearing,
                          -MAX_INT16, MAX_INT16);
    if (total_unicodes == 0 || bearing < props->max_bearing)
      props->max_bearing = bearing;
    props->min_advance = ClipToRange(props->min_advance + src_props.min_advance,
                                     -MAX_INT16, MAX_INT16);
    props->max_advance = ClipToRange(props->max_advance + src_props.max_advance,
                                     -MAX_INT16, MAX_INT16);
    // With a single width, just use the widths stored in the unicharset.
    props->min_width = src_props.min_width;
    props->max_width = src_props.max_width;
    // Use the first script id, other_case, mirror, direction.
    // Note that these will need translation, except direction.
    if (total_unicodes == 0) {
      props->script_id = src_props.script_id;
      props->other_case = src_props.other_case;
      props->mirror = src_props.mirror;
      props->direction = src_props.direction;
    }
    // The normed string for the compound character is the concatenation of
    // the normed versions of the individual characters.
    props->normed += src_props.normed;
    ++total_unicodes;
  }
  if (total_unicodes > 1) {
    // Estimate the total widths from the advance - bearing.
    props->min_width = ClipToRange(props->min_advance - props->max_bearing,
                                   -MAX_INT16, MAX_INT16);
    props->max_width = ClipToRange(props->max_advance - props->min_bearing,
                                   -MAX_INT16, MAX_INT16);
  }
  return total_unicodes > 0;
}
コード例 #12
0
// Accumulates the errors from the classifier results on a single sample.
// Returns true if debug is true and a CT_UNICHAR_TOPN_ERR error occurred.
// boosting_mode selects the type of error to be used for boosting and the
// is_error_ member of sample is set according to whether the required type
// of error occurred. The font_table provides access to font properties
// for error counting and shape_table is used to understand the relationship
// between unichar_ids and shape_ids in the results
bool ErrorCounter::AccumulateErrors(bool debug, CountTypes boosting_mode,
                                    const FontInfoTable& font_table,
                                    const GenericVector<UnicharRating>& results,
                                    TrainingSample* sample) {
  int num_results = results.size();
  int answer_actual_rank = -1;
  int font_id = sample->font_id();
  int unichar_id = sample->class_id();
  sample->set_is_error(false);
  if (num_results == 0) {
    // Reject. We count rejects as a separate category, but still mark the
    // sample as an error in case any training module wants to use that to
    // improve the classifier.
    sample->set_is_error(true);
    ++font_counts_[font_id].n[CT_REJECT];
  } else {
    // Find rank of correct unichar answer, using rating_epsilon_ to allow
    // different answers to score as equal. (Ignoring the font.)
    int epsilon_rank = 0;
    int answer_epsilon_rank = -1;
    int num_top_answers = 0;
    double prev_rating = results[0].rating;
    bool joined = false;
    bool broken = false;
    int res_index = 0;
    while (res_index < num_results) {
      if (results[res_index].rating < prev_rating - rating_epsilon_) {
        ++epsilon_rank;
        prev_rating = results[res_index].rating;
      }
      if (results[res_index].unichar_id == unichar_id &&
          answer_epsilon_rank < 0) {
        answer_epsilon_rank = epsilon_rank;
        answer_actual_rank = res_index;
      }
      if (results[res_index].unichar_id == UNICHAR_JOINED &&
          unicharset_.has_special_codes())
        joined = true;
      else if (results[res_index].unichar_id == UNICHAR_BROKEN &&
               unicharset_.has_special_codes())
        broken = true;
      else if (epsilon_rank == 0)
        ++num_top_answers;
      ++res_index;
    }
    if (answer_actual_rank != 0) {
      // Correct result is not absolute top.
      ++font_counts_[font_id].n[CT_UNICHAR_TOPTOP_ERR];
      if (boosting_mode == CT_UNICHAR_TOPTOP_ERR) sample->set_is_error(true);
    }
    if (answer_epsilon_rank == 0) {
      ++font_counts_[font_id].n[CT_UNICHAR_TOP_OK];
      // Unichar OK, but count if multiple unichars.
      if (num_top_answers > 1) {
        ++font_counts_[font_id].n[CT_OK_MULTI_UNICHAR];
        ++multi_unichar_counts_[unichar_id];
      }
      // Check to see if any font in the top choice has attributes that match.
      // TODO(rays) It is easy to add counters for individual font attributes
      // here if we want them.
      if (font_table.SetContainsFontProperties(
          font_id, results[answer_actual_rank].fonts)) {
        // Font attributes were matched.
        // Check for multiple properties.
        if (font_table.SetContainsMultipleFontProperties(
            results[answer_actual_rank].fonts))
          ++font_counts_[font_id].n[CT_OK_MULTI_FONT];
      } else {
        // Font attributes weren't matched.
        ++font_counts_[font_id].n[CT_FONT_ATTR_ERR];
      }
    } else {
      // This is a top unichar error.
      ++font_counts_[font_id].n[CT_UNICHAR_TOP1_ERR];
      if (boosting_mode == CT_UNICHAR_TOP1_ERR) sample->set_is_error(true);
      // Count maps from unichar id to wrong unichar id.
      ++unichar_counts_(unichar_id, results[0].unichar_id);
      if (answer_epsilon_rank < 0 || answer_epsilon_rank >= 2) {
        // It is also a 2nd choice unichar error.
        ++font_counts_[font_id].n[CT_UNICHAR_TOP2_ERR];
        if (boosting_mode == CT_UNICHAR_TOP2_ERR) sample->set_is_error(true);
      }
      if (answer_epsilon_rank < 0) {
        // It is also a top-n choice unichar error.
        ++font_counts_[font_id].n[CT_UNICHAR_TOPN_ERR];
        if (boosting_mode == CT_UNICHAR_TOPN_ERR) sample->set_is_error(true);
        answer_epsilon_rank = epsilon_rank;
      }
    }
    // Compute mean number of return values and mean rank of correct answer.
    font_counts_[font_id].n[CT_NUM_RESULTS] += num_results;
    font_counts_[font_id].n[CT_RANK] += answer_epsilon_rank;
    if (joined)
      ++font_counts_[font_id].n[CT_OK_JOINED];
    if (broken)
      ++font_counts_[font_id].n[CT_OK_BROKEN];
  }
  // If it was an error for boosting then sum the weight.
  if (sample->is_error()) {
    scaled_error_ += sample->weight();
    if (debug) {
      tprintf("%d results for char %s font %d :",
              num_results, unicharset_.id_to_unichar(unichar_id),
              font_id);
      for (int i = 0; i < num_results; ++i) {
        tprintf(" %.3f : %s\n",
                results[i].rating,
                unicharset_.id_to_unichar(results[i].unichar_id));
      }
      return true;
    }
    int percent = 0;
    if (num_results > 0)
      percent = IntCastRounded(results[0].rating * 100);
    bad_score_hist_.add(percent, 1);
  } else {
    int percent = 0;
    if (answer_actual_rank >= 0)
      percent = IntCastRounded(results[answer_actual_rank].rating * 100);
    ok_score_hist_.add(percent, 1);
  }
  return false;
}
コード例 #13
0
ファイル: chopper.cpp プロジェクト: ManishKSharma/tess-two
/**********************************************************************
 * select_blob_to_split
 *
 * These are the results of the last classification.  Find a likely
 * place to apply splits.  If none, return -1.
 **********************************************************************/
int Wordrec::select_blob_to_split(
    const GenericVector<BLOB_CHOICE*>& blob_choices,
    float rating_ceiling, bool split_next_to_fragment) {
  BLOB_CHOICE *blob_choice;
  int x;
  float worst = -MAX_FLOAT32;
  int worst_index = -1;
  float worst_near_fragment = -MAX_FLOAT32;
  int worst_index_near_fragment = -1;
  const CHAR_FRAGMENT **fragments = NULL;

  if (chop_debug) {
    if (rating_ceiling < MAX_FLOAT32)
      tprintf("rating_ceiling = %8.4f\n", rating_ceiling);
    else
      tprintf("rating_ceiling = No Limit\n");
  }

  if (split_next_to_fragment && blob_choices.size() > 0) {
    fragments = new const CHAR_FRAGMENT *[blob_choices.length()];
    if (blob_choices[0] != NULL) {
      fragments[0] = getDict().getUnicharset().get_fragment(
          blob_choices[0]->unichar_id());
    } else {
      fragments[0] = NULL;
    }
  }

  for (x = 0; x < blob_choices.size(); ++x) {
    if (blob_choices[x] == NULL) {
      if (fragments != NULL) {
        delete[] fragments;
      }
      return x;
    } else {
      blob_choice = blob_choices[x];
      // Populate fragments for the following position.
      if (split_next_to_fragment && x+1 < blob_choices.size()) {
        if (blob_choices[x + 1] != NULL) {
          fragments[x + 1] = getDict().getUnicharset().get_fragment(
              blob_choices[x + 1]->unichar_id());
        } else {
          fragments[x + 1] = NULL;
        }
      }
      if (blob_choice->rating() < rating_ceiling &&
          blob_choice->certainty() < tessedit_certainty_threshold) {
        // Update worst and worst_index.
        if (blob_choice->rating() > worst) {
          worst_index = x;
          worst = blob_choice->rating();
        }
        if (split_next_to_fragment) {
          // Update worst_near_fragment and worst_index_near_fragment.
          bool expand_following_fragment =
            (x + 1 < blob_choices.size() &&
             fragments[x+1] != NULL && !fragments[x+1]->is_beginning());
          bool expand_preceding_fragment =
            (x > 0 && fragments[x-1] != NULL && !fragments[x-1]->is_ending());
          if ((expand_following_fragment || expand_preceding_fragment) &&
              blob_choice->rating() > worst_near_fragment) {
            worst_index_near_fragment = x;
            worst_near_fragment = blob_choice->rating();
            if (chop_debug) {
              tprintf("worst_index_near_fragment=%d"
                      " expand_following_fragment=%d"
                      " expand_preceding_fragment=%d\n",
                      worst_index_near_fragment,
                      expand_following_fragment,
                      expand_preceding_fragment);
            }
          }
        }
      }
    }
  }
  if (fragments != NULL) {
    delete[] fragments;
  }
  // TODO(daria): maybe a threshold of badness for
  // worst_near_fragment would be useful.
  return worst_index_near_fragment != -1 ?
    worst_index_near_fragment : worst_index;
}
コード例 #14
0
ファイル: FunctionSpace.cpp プロジェクト: ellipsis14/dolfin
//-----------------------------------------------------------------------------
void FunctionSpace::interpolate(GenericVector& expansion_coefficients,
                                const GenericFunction& v) const
{
  dolfin_assert(_mesh);
  dolfin_assert(_element);
  dolfin_assert(_dofmap);

  // Check that function ranks match
  if (_element->value_rank() != v.value_rank())
  {
    dolfin_error("FunctionSpace.cpp",
                 "interpolate function into function space",
                 "Rank of function (%d) does not match rank of function space (%d)",
                 v.value_rank(), element()->value_rank());
  }

  // Check that function dims match
  for (std::size_t i = 0; i < _element->value_rank(); ++i)
  {
    if (_element->value_dimension(i) != v.value_dimension(i))
    {
      dolfin_error("FunctionSpace.cpp",
                   "interpolate function into function space",
                   "Dimension %d of function (%d) does not match dimension %d of function space (%d)",
                   i, v.value_dimension(i), i, element()->value_dimension(i));
    }
  }

  // Initialize vector of expansion coefficients
  if (expansion_coefficients.size() != _dofmap->global_dimension())
  {
    dolfin_error("FunctionSpace.cpp",
                 "interpolate function into function space",
                 "Wrong size of vector");
  }
  expansion_coefficients.zero();

  // Initialize local arrays
  std::vector<double> cell_coefficients(_dofmap->max_element_dofs());

  // Iterate over mesh and interpolate on each cell
  ufc::cell ufc_cell;
  std::vector<double> vertex_coordinates;
  for (CellIterator cell(*_mesh); !cell.end(); ++cell)
  {
    // Update to current cell
    cell->get_vertex_coordinates(vertex_coordinates);
    cell->get_cell_data(ufc_cell);

    // Restrict function to cell
    v.restrict(cell_coefficients.data(), *_element, *cell,
               vertex_coordinates.data(), ufc_cell);

    // Tabulate dofs
    const ArrayView<const dolfin::la_index> cell_dofs
      = _dofmap->cell_dofs(cell->index());

    // Copy dofs to vector
    expansion_coefficients.set_local(cell_coefficients.data(),
                                     _dofmap->num_element_dofs(cell->index()),
                                     cell_dofs.data());
  }

  // Finalise changes
  expansion_coefficients.apply("insert");
}
コード例 #15
0
ファイル: applybox.cpp プロジェクト: 0xkasun/tesseract
/// Recursive helper to find a match to the target_text (from text_index
/// position) in the choices (from choices_pos position).
/// @param choices is an array of GenericVectors, of length choices_length,
/// with each element representing a starting position in the word, and the
/// #GenericVector holding classification results for a sequence of consecutive
/// blobs, with index 0 being a single blob, index 1 being 2 blobs etc.
/// @param choices_pos
/// @param choices_length
/// @param target_text
/// @param text_index
/// @param rating
/// @param segmentation
/// @param best_rating
/// @param best_segmentation
void Tesseract::SearchForText(const GenericVector<BLOB_CHOICE_LIST*>* choices,
                              int choices_pos, int choices_length,
                              const GenericVector<UNICHAR_ID>& target_text,
                              int text_index,
                              float rating, GenericVector<int>* segmentation,
                              float* best_rating,
                              GenericVector<int>* best_segmentation) {
  const UnicharAmbigsVector& table = getDict().getUnicharAmbigs().dang_ambigs();
  for (int length = 1; length <= choices[choices_pos].size(); ++length) {
    // Rating of matching choice or worst choice if no match.
    float choice_rating = 0.0f;
    // Find the corresponding best BLOB_CHOICE.
    BLOB_CHOICE_IT choice_it(choices[choices_pos][length - 1]);
    for (choice_it.mark_cycle_pt(); !choice_it.cycled_list();
         choice_it.forward()) {
      BLOB_CHOICE* choice = choice_it.data();
      choice_rating = choice->rating();
      UNICHAR_ID class_id = choice->unichar_id();
      if (class_id == target_text[text_index]) {
        break;
      }
      // Search ambigs table.
      if (class_id < table.size() && table[class_id] != NULL) {
        AmbigSpec_IT spec_it(table[class_id]);
        for (spec_it.mark_cycle_pt(); !spec_it.cycled_list();
             spec_it.forward()) {
          const AmbigSpec *ambig_spec = spec_it.data();
          // We'll only do 1-1.
          if (ambig_spec->wrong_ngram[1] == INVALID_UNICHAR_ID &&
              ambig_spec->correct_ngram_id == target_text[text_index])
            break;
        }
        if (!spec_it.cycled_list())
          break;  // Found an ambig.
      }
    }
    if (choice_it.cycled_list())
      continue;  // No match.
    segmentation->push_back(length);
    if (choices_pos + length == choices_length &&
        text_index + 1 == target_text.size()) {
      // This is a complete match. If the rating is good record a new best.
      if (applybox_debug > 2) {
        tprintf("Complete match, rating = %g, best=%g, seglength=%d, best=%d\n",
                rating + choice_rating, *best_rating, segmentation->size(),
                best_segmentation->size());
      }
      if (best_segmentation->empty() || rating + choice_rating < *best_rating) {
        *best_segmentation = *segmentation;
        *best_rating = rating + choice_rating;
      }
    } else if (choices_pos + length < choices_length &&
               text_index + 1 < target_text.size()) {
      if (applybox_debug > 3) {
        tprintf("Match found for %d=%s:%s, at %d+%d, recursing...\n",
                target_text[text_index],
                unicharset.id_to_unichar(target_text[text_index]),
                choice_it.data()->unichar_id() == target_text[text_index]
                     ? "Match" : "Ambig",
                choices_pos, length);
      }
      SearchForText(choices, choices_pos + length, choices_length, target_text,
                    text_index + 1, rating + choice_rating, segmentation,
                    best_rating, best_segmentation);
      if (applybox_debug > 3) {
        tprintf("End recursion for %d=%s\n", target_text[text_index],
                unicharset.id_to_unichar(target_text[text_index]));
      }
    }
    segmentation->truncate(segmentation->size() - 1);
  }
}
コード例 #16
0
ファイル: resultiterator.cpp プロジェクト: 11110101/tess-two
void ResultIterator::CalculateTextlineOrder(
    bool paragraph_is_ltr,
    const GenericVector<StrongScriptDirection> &word_dirs,
    GenericVectorEqEq<int> *reading_order) {
  reading_order->truncate(0);
  if (word_dirs.size() == 0) return;

  // Take all of the runs of minor direction words and insert them
  // in reverse order.
  int minor_direction, major_direction, major_step, start, end;
  if (paragraph_is_ltr) {
    start = 0;
    end = word_dirs.size();
    major_step = 1;
    major_direction = DIR_LEFT_TO_RIGHT;
    minor_direction = DIR_RIGHT_TO_LEFT;
  } else {
    start = word_dirs.size() - 1;
    end = -1;
    major_step = -1;
    major_direction = DIR_RIGHT_TO_LEFT;
    minor_direction = DIR_LEFT_TO_RIGHT;
    // Special rule: if there are neutral words at the right most side
    //   of a line adjacent to a left-to-right word in the middle of the
    //   line, we interpret the end of the line as a single LTR sequence.
    if (word_dirs[start] == DIR_NEUTRAL) {
      int neutral_end = start;
      while (neutral_end > 0 && word_dirs[neutral_end] == DIR_NEUTRAL) {
        neutral_end--;
      }
      if (neutral_end >= 0 && word_dirs[neutral_end] == DIR_LEFT_TO_RIGHT) {
        // LTR followed by neutrals.
        // Scan for the beginning of the minor left-to-right run.
        int left = neutral_end;
        for (int i = left; i >= 0 && word_dirs[i] != DIR_RIGHT_TO_LEFT; i--) {
          if (word_dirs[i] == DIR_LEFT_TO_RIGHT) left = i;
        }
        reading_order->push_back(kMinorRunStart);
        for (int i = left; i < word_dirs.size(); i++) {
          reading_order->push_back(i);
          if (word_dirs[i] == DIR_MIX) reading_order->push_back(kComplexWord);
        }
        reading_order->push_back(kMinorRunEnd);
        start = left - 1;
      }
    }
  }
  for (int i = start; i != end;) {
    if (word_dirs[i] == minor_direction) {
      int j = i;
      while (j != end && word_dirs[j] != major_direction)
        j += major_step;
      if (j == end) j -= major_step;
      while (j != i && word_dirs[j] != minor_direction)
        j -= major_step;
      //  [j..i] is a minor direction run.
      reading_order->push_back(kMinorRunStart);
      for (int k = j; k != i; k -= major_step) {
        reading_order->push_back(k);
      }
      reading_order->push_back(i);
      reading_order->push_back(kMinorRunEnd);
      i = j + major_step;
    } else {
      reading_order->push_back(i);
      if (word_dirs[i] == DIR_MIX) reading_order->push_back(kComplexWord);
      i += major_step;
    }
  }
}
コード例 #17
0
ファイル: PETScLUSolver.cpp プロジェクト: WeilinDeng/dolfin
//-----------------------------------------------------------------------------
std::size_t PETScLUSolver::solve(GenericVector& x, const GenericVector& b,
                                 bool transpose)
{
  Timer timer("PETSc LU solver");

  dolfin_assert(_ksp);
  dolfin_assert(_matA);
  PetscErrorCode ierr;

  // Downcast matrix and vectors
  const PETScVector& _b = as_type<const PETScVector>(b);
  PETScVector& _x = as_type<PETScVector>(x);

  // Check dimensions
  if (_matA->size(0) != b.size())
  {
    dolfin_error("PETScLUSolver.cpp",
                 "solve linear system using PETSc LU solver",
                 "Cannot factorize non-square PETSc matrix");
  }

  // Initialize solution vector if required (make compatible with A in
  // parallel)
  if (x.empty())
    _matA->init_vector(x, 1);

  // Set PETSc operators (depends on factorization re-use options);
  //set_petsc_operators();

  // Write a pre-solve message
  pre_report(*_matA);

  // Get package used to solve system
  PC pc;
  ierr = KSPGetPC(_ksp, &pc);
  if (ierr != 0)
    petsc_error(ierr, __FILE__, "KSPGetPC");

  configure_ksp(_solver_package);

  // Set number of threads if using PaStiX
  if (strcmp(_solver_package, MATSOLVERPASTIX) == 0)
  {
    const std::size_t num_threads = parameters["num_threads"].is_set() ?
      parameters["num_threads"] : dolfin::parameters["num_threads"];
    PETScOptions::set("-mat_pastix_threadnbr", num_threads);
  }

  // Solve linear system
  const Vec b_petsc = _b.vec();
  Vec x_petsc = _x.vec();
  if (!transpose)
  {
    ierr = KSPSolve(_ksp, b_petsc, x_petsc);
    if (ierr != 0) petsc_error(ierr, __FILE__, "KSPSolve");
  }
  else
  {
    ierr = KSPSolveTranspose(_ksp, b_petsc, x_petsc);
    if (ierr != 0) petsc_error(ierr, __FILE__, "KSPSolveTranspose");
  }

  // Update ghost values following solve
  _x.update_ghost_values();

  return 1;
}
コード例 #18
0
ファイル: permdawg.cpp プロジェクト: ming-hai/tesseract
/**
 * @name go_deeper_dawg_fxn
 *
 * If the choice being composed so far could be a dictionary word
 * keep exploring choices.
 */
void Dict::go_deeper_dawg_fxn(
    const char *debug, const BLOB_CHOICE_LIST_VECTOR &char_choices,
    int char_choice_index, const CHAR_FRAGMENT_INFO *prev_char_frag_info,
    bool word_ending, WERD_CHOICE *word, float certainties[], float *limit,
    WERD_CHOICE *best_choice, int *attempts_left, void *void_more_args) {
  DawgArgs *more_args = static_cast<DawgArgs *>(void_more_args);
  word_ending = (char_choice_index == char_choices.size()-1);
  int word_index = word->length() - 1;
  if (best_choice->rating() < *limit) return;
  // Look up char in DAWG

  // If the current unichar is an ngram first try calling
  // letter_is_okay() for each unigram it contains separately.
  UNICHAR_ID orig_uch_id = word->unichar_id(word_index);
  bool checked_unigrams = false;
  if (getUnicharset().get_isngram(orig_uch_id)) {
    if (dawg_debug_level) {
      tprintf("checking unigrams in an ngram %s\n",
              getUnicharset().debug_str(orig_uch_id).string());
    }
    int num_unigrams = 0;
    word->remove_last_unichar_id();
    GenericVector<UNICHAR_ID> encoding;
    const char *ngram_str = getUnicharset().id_to_unichar(orig_uch_id);
    // Since the string came out of the unicharset, failure is impossible.
    ASSERT_HOST(getUnicharset().encode_string(ngram_str, true, &encoding, nullptr,
                                              nullptr));
    bool unigrams_ok = true;
    // Construct DawgArgs that reflect the current state.
    DawgPositionVector unigram_active_dawgs = *(more_args->active_dawgs);
    DawgPositionVector unigram_updated_dawgs;
    DawgArgs unigram_dawg_args(&unigram_active_dawgs,
                               &unigram_updated_dawgs,
                               more_args->permuter);
    // Check unigrams in the ngram with letter_is_okay().
    for (int i = 0; unigrams_ok && i < encoding.size(); ++i) {
      UNICHAR_ID uch_id = encoding[i];
      ASSERT_HOST(uch_id != INVALID_UNICHAR_ID);
      ++num_unigrams;
      word->append_unichar_id(uch_id, 1, 0.0, 0.0);
      unigrams_ok = (this->*letter_is_okay_)(
          &unigram_dawg_args,
          word->unichar_id(word_index+num_unigrams-1),
          word_ending && i == encoding.size() - 1);
      (*unigram_dawg_args.active_dawgs) = *(unigram_dawg_args.updated_dawgs);
      if (dawg_debug_level) {
        tprintf("unigram %s is %s\n",
                getUnicharset().debug_str(uch_id).string(),
                unigrams_ok ? "OK" : "not OK");
      }
    }
    // Restore the word and copy the updated dawg state if needed.
    while (num_unigrams-- > 0) word->remove_last_unichar_id();
    word->append_unichar_id_space_allocated(orig_uch_id, 1, 0.0, 0.0);
    if (unigrams_ok) {
      checked_unigrams = true;
      more_args->permuter = unigram_dawg_args.permuter;
      *(more_args->updated_dawgs) = *(unigram_dawg_args.updated_dawgs);
    }
  }

  // Check which dawgs from the dawgs_ vector contain the word
  // up to and including the current unichar.
  if (checked_unigrams || (this->*letter_is_okay_)(
      more_args, word->unichar_id(word_index), word_ending)) {
    // Add a new word choice
    if (word_ending) {
      if (dawg_debug_level) {
        tprintf("found word = %s\n", word->debug_string().string());
      }
      if (strcmp(output_ambig_words_file.string(), "") != 0) {
        if (output_ambig_words_file_ == nullptr) {
          output_ambig_words_file_ =
              fopen(output_ambig_words_file.string(), "wb+");
          if (output_ambig_words_file_ == nullptr) {
            tprintf("Failed to open output_ambig_words_file %s\n",
                    output_ambig_words_file.string());
            exit(1);
          }
          STRING word_str;
          word->string_and_lengths(&word_str, nullptr);
          word_str += " ";
          fprintf(output_ambig_words_file_, "%s", word_str.string());
        }
        STRING word_str;
        word->string_and_lengths(&word_str, nullptr);
        word_str += " ";
        fprintf(output_ambig_words_file_, "%s", word_str.string());
      }
      WERD_CHOICE *adjusted_word = word;
      adjusted_word->set_permuter(more_args->permuter);
      update_best_choice(*adjusted_word, best_choice);
    } else {  // search the next letter
      // Make updated_* point to the next entries in the DawgPositionVector
      // arrays (that were originally created in dawg_permute_and_select)
      ++(more_args->updated_dawgs);
      // Make active_dawgs and constraints point to the updated ones.
      ++(more_args->active_dawgs);
      permute_choices(debug, char_choices, char_choice_index + 1,
                      prev_char_frag_info, word, certainties, limit,
                      best_choice, attempts_left, more_args);
      // Restore previous state to explore another letter in this position.
      --(more_args->updated_dawgs);
      --(more_args->active_dawgs);
    }
  } else {
      if (dawg_debug_level) {
        tprintf("last unichar not OK at index %d in %s\n",
                word_index, word->debug_string().string());
    }
  }
}
コード例 #19
0
int main(int argc, char **argv) {
  if ((argc == 2 && strcmp(argv[1], "-v") == 0) ||
      (argc == 2 && strcmp(argv[1], "--version") == 0)) {
    char *versionStrP;

    fprintf(stderr, "tesseract %s\n", tesseract::TessBaseAPI::Version());

    versionStrP = getLeptonicaVersion();
    fprintf(stderr, " %s\n", versionStrP);
    lept_free(versionStrP);

    versionStrP = getImagelibVersions();
    fprintf(stderr, "  %s\n", versionStrP);
    lept_free(versionStrP);

#ifdef USE_OPENCL
    cl_platform_id platform;
    cl_uint num_platforms;
    cl_device_id devices[2];
    cl_uint num_devices;
    char info[256];
    int i;

    fprintf(stderr, " OpenCL info:\n");
    clGetPlatformIDs(1, &platform, &num_platforms);
    fprintf(stderr, "  Found %d platforms.\n", num_platforms);
    clGetPlatformInfo(platform, CL_PLATFORM_NAME, 256, info, 0);
    fprintf(stderr, "  Platform name: %s.\n", info);
    clGetPlatformInfo(platform, CL_PLATFORM_VERSION, 256, info, 0);
    fprintf(stderr, "  Version: %s.\n", info);
    clGetDeviceIDs(platform, CL_DEVICE_TYPE_ALL, 2, devices, &num_devices);
    fprintf(stderr, "  Found %d devices.\n", num_devices);
    for (i = 0; i < num_devices; ++i) {
      clGetDeviceInfo(devices[i], CL_DEVICE_NAME, 256, info, 0);
      fprintf(stderr, "    Device %d name: %s.\n", i+1, info);
    }
#endif
    exit(0);
  }

  // Make the order of args a bit more forgiving than it used to be.
  const char* lang = "eng";
  const char* image = NULL;
  const char* outputbase = NULL;
  const char* datapath = NULL;
  bool noocr = false;
  bool list_langs = false;
  bool print_parameters = false;
  GenericVector<STRING> vars_vec, vars_values;

  tesseract::PageSegMode pagesegmode = tesseract::PSM_AUTO;
  int arg = 1;
  while (arg < argc && (outputbase == NULL || argv[arg][0] == '-')) {
    if (strcmp(argv[arg], "-l") == 0 && arg + 1 < argc) {
      lang = argv[arg + 1];
      ++arg;
    } else if (strcmp(argv[arg], "--tessdata-dir") == 0 && arg + 1 < argc) {
      datapath = argv[arg + 1];
      ++arg;
    } else if (strcmp(argv[arg], "--user-words") == 0 && arg + 1 < argc) {
      vars_vec.push_back("user_words_file");
      vars_values.push_back(argv[arg + 1]);
      ++arg;
    } else if (strcmp(argv[arg], "--user-patterns") == 0 && arg + 1 < argc) {
      vars_vec.push_back("user_patterns_file");
      vars_values.push_back(argv[arg + 1]);
      ++arg;
    } else if (strcmp(argv[arg], "--list-langs") == 0) {
      noocr = true;
      list_langs = true;
    } else if (strcmp(argv[arg], "-psm") == 0 && arg + 1 < argc) {
      pagesegmode = static_cast<tesseract::PageSegMode>(atoi(argv[arg + 1]));
      ++arg;
    } else if (strcmp(argv[arg], "--print-parameters") == 0) {
      noocr = true;
      print_parameters = true;
    } else if (strcmp(argv[arg], "-c") == 0 && arg + 1 < argc) {
      // handled properly after api init
      ++arg;
    } else if (image == NULL) {
      image = argv[arg];
    } else if (outputbase == NULL) {
      outputbase = argv[arg];
    }
    ++arg;
  }

  if (argc == 2 && strcmp(argv[1], "--list-langs") == 0) {
    list_langs = true;
    noocr = true;
  }

  if (outputbase == NULL && noocr == false) {
    fprintf(stderr, "Usage:\n  %s imagename|stdin outputbase|stdout "
            "[options...] [configfile...]\n\n", argv[0]);

    fprintf(stderr, "OCR options:\n");
    fprintf(stderr, "  --tessdata-dir /path\tspecify the location of tessdata"
                      " path\n");
    fprintf(stderr, "  --user-words /path/to/file\tspecify the location of user"
            " words file\n");
    fprintf(stderr, "  --user-patterns /path/to/file\tspecify the location of"
            " user patterns file\n");
    fprintf(stderr, "  -l lang[+lang]\tspecify language(s) used for OCR\n");
    fprintf(stderr, "  -c configvar=value\tset value for control parameter.\n"
                      "\t\t\tMultiple -c arguments are allowed.\n");
    fprintf(stderr, "  -psm pagesegmode\tspecify page segmentation mode.\n");
    fprintf(stderr, "These options must occur before any configfile.\n\n");
    fprintf(stderr,
            "pagesegmode values are:\n"
            "  0 = Orientation and script detection (OSD) only.\n"
            "  1 = Automatic page segmentation with OSD.\n"
            "  2 = Automatic page segmentation, but no OSD, or OCR\n"
            "  3 = Fully automatic page segmentation, but no OSD. (Default)\n"
            "  4 = Assume a single column of text of variable sizes.\n"
            "  5 = Assume a single uniform block of vertically aligned text.\n"
            "  6 = Assume a single uniform block of text.\n"
            "  7 = Treat the image as a single text line.\n"
            "  8 = Treat the image as a single word.\n"
            "  9 = Treat the image as a single word in a circle.\n"
            "  10 = Treat the image as a single character.\n\n");
    fprintf(stderr, "Single options:\n");
    fprintf(stderr, "  -v --version: version info\n");
    fprintf(stderr, "  --list-langs: list available languages for tesseract "
                      "engine. Can be used with --tessdata-dir.\n");
    fprintf(stderr, "  --print-parameters: print tesseract parameters to the "
                      "stdout.\n");
    exit(1);
  }

  if (outputbase != NULL && strcmp(outputbase, "-") &&
      strcmp(outputbase, "stdout")) {
    tprintf("Tesseract Open Source OCR Engine v%s with Leptonica\n",
           tesseract::TessBaseAPI::Version());
  }
  PERF_COUNT_START("Tesseract:main")
  tesseract::TessBaseAPI api;

  api.SetOutputName(outputbase);
  int rc = api.Init(datapath, lang, tesseract::OEM_DEFAULT,
                &(argv[arg]), argc - arg, &vars_vec, &vars_values, false);

  if (rc) {
    fprintf(stderr, "Could not initialize tesseract.\n");
    exit(1);
  }

  char opt1[255], opt2[255];
  for (arg = 0; arg < argc; arg++) {
    if (strcmp(argv[arg], "-c") == 0 && arg + 1 < argc) {
      strncpy(opt1, argv[arg + 1], 255);
      char *p = strchr(opt1, '=');
      if (!p) {
        fprintf(stderr, "Missing = in configvar assignment\n");
        exit(1);
      }
      *p = 0;
      strncpy(opt2, strchr(argv[arg + 1], '=') + 1, 255);
      opt2[254] = 0;
      ++arg;

      if (!api.SetVariable(opt1, opt2)) {
        fprintf(stderr, "Could not set option: %s=%s\n", opt1, opt2);
      }
    }
  }

  if (list_langs) {
     GenericVector<STRING> languages;
     api.GetAvailableLanguagesAsVector(&languages);
     fprintf(stderr, "List of available languages (%d):\n",
             languages.size());
     for (int index = 0; index < languages.size(); ++index) {
       STRING& string = languages[index];
       fprintf(stderr, "%s\n", string.string());
     }
     api.End();
     exit(0);
  }

  if (print_parameters) {
     FILE* fout = stdout;
     fprintf(stdout, "Tesseract parameters:\n");
     api.PrintVariables(fout);
     api.End();
     exit(0);
  }

  // We have 2 possible sources of pagesegmode: a config file and
  // the command line. For backwards compatibility reasons, the
  // default in tesseract is tesseract::PSM_SINGLE_BLOCK, but the
  // default for this program is tesseract::PSM_AUTO. We will let
  // the config file take priority, so the command-line default
  // can take priority over the tesseract default, so we use the
  // value from the command line only if the retrieved mode
  // is still tesseract::PSM_SINGLE_BLOCK, indicating no change
  // in any config file. Therefore the only way to force
  // tesseract::PSM_SINGLE_BLOCK is from the command line.
  // It would be simpler if we could set the value before Init,
  // but that doesn't work.
  if (api.GetPageSegMode() == tesseract::PSM_SINGLE_BLOCK)
     api.SetPageSegMode(pagesegmode);

  if (pagesegmode == tesseract::PSM_AUTO_ONLY ||
      pagesegmode == tesseract::PSM_OSD_ONLY) {
    int ret_val = 0;

    Pix* pixs = pixRead(image);
    if (!pixs) {
      fprintf(stderr, "Cannot open input file: %s\n", image);
      exit(2);
    }
    api.SetImage(pixs);

    if (pagesegmode == tesseract::PSM_OSD_ONLY) {
       OSResults osr;
       if (api.DetectOS(&osr)) {
         int orient = osr.best_result.orientation_id;
         int script_id = osr.get_best_script(orient);
         float orient_oco = osr.best_result.oconfidence;
         float orient_sco = osr.best_result.sconfidence;
         tprintf("Orientation: %d\nOrientation in degrees: %d\n" \
                 "Orientation confidence: %.2f\n" \
                 "Script: %d\nScript confidence: %.2f\n",
                 orient, OrientationIdToValue(orient), orient_oco,
                 script_id, orient_sco);
       } else {
         ret_val = 1;
       }
    } else {
       tesseract::Orientation orientation;
       tesseract::WritingDirection direction;
       tesseract::TextlineOrder order;
       float deskew_angle;
       tesseract::PageIterator* it =  api.AnalyseLayout();
       if (it) {
         it->Orientation(&orientation, &direction, &order, &deskew_angle);
         tprintf("Orientation: %d\nWritingDirection: %d\nTextlineOrder: %d\n" \
                 "Deskew angle: %.4f\n",
                 orientation, direction, order, deskew_angle);
       } else {
         ret_val = 1;
       }
       delete it;
    }
    pixDestroy(&pixs);
    exit(ret_val);
  }

  bool b;
  tesseract::PointerVector<tesseract::TessResultRenderer> renderers;
  api.GetBoolVariable("tessedit_create_hocr", &b);
  if (b) {
    bool font_info;
    api.GetBoolVariable("hocr_font_info", &font_info);
    renderers.push_back(new tesseract::TessHOcrRenderer(outputbase, font_info));
  }
  api.GetBoolVariable("tessedit_create_pdf", &b);
  if (b) {
    renderers.push_back(new tesseract::TessPDFRenderer(outputbase,
                                                       api.GetDatapath()));
  }
  api.GetBoolVariable("tessedit_write_unlv", &b);
  if (b) renderers.push_back(new tesseract::TessUnlvRenderer(outputbase));
  api.GetBoolVariable("tessedit_create_boxfile", &b);
  if (b) renderers.push_back(new tesseract::TessBoxTextRenderer(outputbase));
  api.GetBoolVariable("tessedit_create_txt", &b);
  if (b) renderers.push_back(new tesseract::TessTextRenderer(outputbase));
  if (!renderers.empty()) {
    // Since the PointerVector auto-deletes, null-out the renderers that are
    // added to the root, and leave the root in the vector.
    for (int r = 1; r < renderers.size(); ++r) {
      renderers[0]->insert(renderers[r]);
      renderers[r] = NULL;
    }
    if (!api.ProcessPages(image, NULL, 0, renderers[0])) {
      fprintf(stderr, "Error during processing.\n");
      exit(1);
    }
  }

  PERF_COUNT_END
  return 0;                      // Normal exit
}
コード例 #20
0
ファイル: tesseractmain.cpp プロジェクト: 2php/tesseract-ocr
int main(int argc, char **argv) {
#ifdef USING_GETTEXT
  setlocale (LC_ALL, "");
  bindtextdomain (PACKAGE, LOCALEDIR);
  textdomain (PACKAGE);
#endif
  if ((argc == 2 && strcmp(argv[1], "-v") == 0) ||
      (argc == 2 && strcmp(argv[1], "--version") == 0)) {
    char *versionStrP;

    fprintf(stderr, "tesseract %s\n", tesseract::TessBaseAPI::Version());

    versionStrP = getLeptonicaVersion();
    fprintf(stderr, " %s\n", versionStrP);
    lept_free(versionStrP);

    versionStrP = getImagelibVersions();
    fprintf(stderr, "  %s\n", versionStrP);
    lept_free(versionStrP);

    exit(0);
  }

  tesseract::TessBaseAPI  api;
  int rc = api.Init(argv[0], NULL);
  if (rc) {
    fprintf(stderr, "Could not initialize tesseract.\n");
    exit(1);
  }

  if (argc == 2 && strcmp(argv[1], "--list-langs") == 0) {
     GenericVector<STRING> languages;
     api.GetAvailableLanguagesAsVector(&languages);
     fprintf(stderr, "List of available languages (%d):\n", languages.size());
     for (int index = 0; index < languages.size(); ++index) {
       STRING& string = languages[index];
       fprintf(stderr, "%s\n", string.string());
     }
     api.Clear();
     exit(0);
  }
  api.End();

  // Make the order of args a bit more forgiving than it used to be.
  const char* lang = "eng";
  const char* image = NULL;
  const char* output = NULL;
  tesseract::PageSegMode pagesegmode = tesseract::PSM_AUTO;
  int arg = 1;
  while (arg < argc && (output == NULL || argv[arg][0] == '-')) {
    if (strcmp(argv[arg], "-l") == 0 && arg + 1 < argc) {
      lang = argv[arg + 1];
      ++arg;
    } else if (strcmp(argv[arg], "-psm") == 0 && arg + 1 < argc) {
      pagesegmode = static_cast<tesseract::PageSegMode>(atoi(argv[arg + 1]));
      ++arg;
    } else if (image == NULL) {
      image = argv[arg];
    } else if (output == NULL) {
      output = argv[arg];
    }
    ++arg;
  }
  if (output == NULL) {
    fprintf(stderr, _("Usage:%s imagename outputbase [-l lang] "
                      "[-psm pagesegmode] [configfile...]\n\n"), argv[0]);
    fprintf(stderr,
            _("pagesegmode values are:\n"
              "0 = Orientation and script detection (OSD) only.\n"
              "1 = Automatic page segmentation with OSD.\n"
              "2 = Automatic page segmentation, but no OSD, or OCR\n"
              "3 = Fully automatic page segmentation, but no OSD. (Default)\n"
              "4 = Assume a single column of text of variable sizes.\n"
              "5 = Assume a single uniform block of vertically aligned text.\n"
              "6 = Assume a single uniform block of text.\n"
              "7 = Treat the image as a single text line.\n"
              "8 = Treat the image as a single word.\n"
              "9 = Treat the image as a single word in a circle.\n"
              "10 = Treat the image as a single character.\n"));
    fprintf(stderr, _("-l lang and/or -psm pagesegmode must occur before any"
                      "configfile.\n\n"));
    fprintf(stderr, _("Single options:\n"));
    fprintf(stderr, _("  -v --version: version info\n"));
    fprintf(stderr, _("  --list-langs: list available languages for tesseract engine\n"));
    exit(1);
  }


  api.SetOutputName(output);

  STRING tessdata_dir;
  truncate_path(argv[0], &tessdata_dir);
  rc = api.Init(tessdata_dir.string(), lang, tesseract::OEM_DEFAULT,
                &(argv[arg]), argc - arg, NULL, NULL, false);
  if (rc) {
    fprintf(stderr, "Could not initialize tesseract.\n");
    exit(1);
  }

  // We have 2 possible sources of pagesegmode: a config file and
  // the command line. For backwards compatability reasons, the
  // default in tesseract is tesseract::PSM_SINGLE_BLOCK, but the
  // default for this program is tesseract::PSM_AUTO. We will let
  // the config file take priority, so the command-line default
  // can take priority over the tesseract default, so we use the
  // value from the command line only if the retrieved mode
  // is still tesseract::PSM_SINGLE_BLOCK, indicating no change
  // in any config file. Therefore the only way to force
  // tesseract::PSM_SINGLE_BLOCK is from the command line.
  // It would be simpler if we could set the value before Init,
  // but that doesn't work.
  if (api.GetPageSegMode() == tesseract::PSM_SINGLE_BLOCK)
    api.SetPageSegMode(pagesegmode);
  tprintf("Tesseract Open Source OCR Engine v%s with Leptonica\n",
           tesseract::TessBaseAPI::Version());


  FILE* fin = fopen(image, "rb");
  if (fin == NULL) {
    printf("Cannot open input file: %s\n", image);
    exit(2);
  }
  fclose(fin);

  PIX   *pixs;
  if ((pixs = pixRead(image)) == NULL) {
    printf("Unsupported image type.\n");
    exit(3);
  }
  pixDestroy(&pixs);

  STRING text_out;
  if (!api.ProcessPages(image, NULL, 0, &text_out)) {
    printf("Error during processing.\n");
  }
  bool output_hocr = false;
  api.GetBoolVariable("tessedit_create_hocr", &output_hocr);
  bool output_box = false;
  api.GetBoolVariable("tessedit_create_boxfile", &output_box);
  STRING outfile = output;
  outfile += output_hocr ? ".html" : output_box ? ".box" : ".txt";
  FILE* fout = fopen(outfile.string(), "wb");
  if (fout == NULL) {
    printf("Cannot create output file %s\n", outfile.string());
    exit(1);
  }
  fwrite(text_out.string(), 1, text_out.length(), fout);
  fclose(fout);

  return 0;                      // Normal exit
}