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413 lines
16 KiB
C++
413 lines
16 KiB
C++
///////////////////////////////////////////////////////////////////////
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// File: ctc.cpp
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// Description: Slightly improved standard CTC to compute the targets.
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// Author: Ray Smith
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// Created: Wed Jul 13 15:50:06 PDT 2016
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//
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// (C) Copyright 2016, Google Inc.
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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// http://www.apache.org/licenses/LICENSE-2.0
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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///////////////////////////////////////////////////////////////////////
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#include "ctc.h"
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#include <memory>
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#include "genericvector.h"
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#include "host.h"
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#include "matrix.h"
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#include "networkio.h"
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#include "network.h"
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#include "scrollview.h"
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namespace tesseract {
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// Magic constants that keep CTC stable.
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// Minimum probability limit for softmax input to ctc_loss.
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const float CTC::kMinProb_ = 1e-12;
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// Maximum absolute argument to exp().
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const double CTC::kMaxExpArg_ = 80.0;
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// Minimum probability for total prob in time normalization.
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const double CTC::kMinTotalTimeProb_ = 1e-8;
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// Minimum probability for total prob in final normalization.
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const double CTC::kMinTotalFinalProb_ = 1e-6;
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// Builds a target using CTC. Slightly improved as follows:
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// Includes normalizations and clipping for stability.
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// labels should be pre-padded with nulls everywhere.
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// labels can be longer than the time sequence, but the total number of
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// essential labels (non-null plus nulls between equal labels) must not exceed
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// the number of timesteps in outputs.
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// outputs is the output of the network, and should have already been
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// normalized with NormalizeProbs.
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// On return targets is filled with the computed targets.
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// Returns false if there is insufficient time for the labels.
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/* static */
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bool CTC::ComputeCTCTargets(const GenericVector<int>& labels, int null_char,
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const GENERIC_2D_ARRAY<float>& outputs,
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NetworkIO* targets) {
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std::unique_ptr<CTC> ctc(new CTC(labels, null_char, outputs));
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if (!ctc->ComputeLabelLimits()) {
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return false; // Not enough time.
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}
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// Generate simple targets purely from the truth labels by spreading them
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// evenly over time.
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GENERIC_2D_ARRAY<float> simple_targets;
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ctc->ComputeSimpleTargets(&simple_targets);
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// Add the simple targets as a starter bias to the network outputs.
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float bias_fraction = ctc->CalculateBiasFraction();
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simple_targets *= bias_fraction;
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ctc->outputs_ += simple_targets;
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NormalizeProbs(&ctc->outputs_);
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// Run regular CTC on the biased outputs.
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// Run forward and backward
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GENERIC_2D_ARRAY<double> log_alphas, log_betas;
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ctc->Forward(&log_alphas);
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ctc->Backward(&log_betas);
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// Normalize and come out of log space with a clipped softmax over time.
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log_alphas += log_betas;
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ctc->NormalizeSequence(&log_alphas);
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ctc->LabelsToClasses(log_alphas, targets);
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NormalizeProbs(targets);
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return true;
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}
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CTC::CTC(const GenericVector<int>& labels, int null_char,
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const GENERIC_2D_ARRAY<float>& outputs)
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: labels_(labels), outputs_(outputs), null_char_(null_char) {
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num_timesteps_ = outputs.dim1();
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num_classes_ = outputs.dim2();
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num_labels_ = labels_.size();
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}
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// Computes vectors of min and max label index for each timestep, based on
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// whether skippability of nulls makes it possible to complete a valid path.
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bool CTC::ComputeLabelLimits() {
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min_labels_.init_to_size(num_timesteps_, 0);
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max_labels_.init_to_size(num_timesteps_, 0);
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int min_u = num_labels_ - 1;
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if (labels_[min_u] == null_char_) --min_u;
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for (int t = num_timesteps_ - 1; t >= 0; --t) {
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min_labels_[t] = min_u;
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if (min_u > 0) {
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--min_u;
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if (labels_[min_u] == null_char_ && min_u > 0 &&
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labels_[min_u + 1] != labels_[min_u - 1]) {
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--min_u;
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}
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}
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}
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int max_u = labels_[0] == null_char_;
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for (int t = 0; t < num_timesteps_; ++t) {
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max_labels_[t] = max_u;
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if (max_labels_[t] < min_labels_[t]) return false; // Not enough room.
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if (max_u + 1 < num_labels_) {
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++max_u;
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if (labels_[max_u] == null_char_ && max_u + 1 < num_labels_ &&
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labels_[max_u + 1] != labels_[max_u - 1]) {
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++max_u;
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}
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}
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}
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return true;
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}
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// Computes targets based purely on the labels by spreading the labels evenly
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// over the available timesteps.
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void CTC::ComputeSimpleTargets(GENERIC_2D_ARRAY<float>* targets) const {
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// Initialize all targets to zero.
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targets->Resize(num_timesteps_, num_classes_, 0.0f);
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GenericVector<float> half_widths;
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GenericVector<int> means;
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ComputeWidthsAndMeans(&half_widths, &means);
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for (int l = 0; l < num_labels_; ++l) {
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int label = labels_[l];
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float left_half_width = half_widths[l];
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float right_half_width = left_half_width;
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int mean = means[l];
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if (label == null_char_) {
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if (!NeededNull(l)) {
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if ((l > 0 && mean == means[l - 1]) ||
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(l + 1 < num_labels_ && mean == means[l + 1])) {
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continue; // Drop overlapping null.
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}
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}
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// Make sure that no space is left unoccupied and that non-nulls always
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// peak at 1 by stretching nulls to meet their neighbors.
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if (l > 0) left_half_width = mean - means[l - 1];
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if (l + 1 < num_labels_) right_half_width = means[l + 1] - mean;
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}
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if (mean >= 0 && mean < num_timesteps_) targets->put(mean, label, 1.0f);
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for (int offset = 1; offset < left_half_width && mean >= offset; ++offset) {
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float prob = 1.0f - offset / left_half_width;
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if (mean - offset < num_timesteps_ &&
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prob > targets->get(mean - offset, label)) {
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targets->put(mean - offset, label, prob);
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}
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}
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for (int offset = 1;
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offset < right_half_width && mean + offset < num_timesteps_;
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++offset) {
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float prob = 1.0f - offset / right_half_width;
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if (mean + offset >= 0 && prob > targets->get(mean + offset, label)) {
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targets->put(mean + offset, label, prob);
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}
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}
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}
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}
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// Computes mean positions and half widths of the simple targets by spreading
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// the labels evenly over the available timesteps.
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void CTC::ComputeWidthsAndMeans(GenericVector<float>* half_widths,
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GenericVector<int>* means) const {
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// Count the number of labels of each type, in regexp terms, counts plus
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// (non-null or necessary null, which must occur at least once) and star
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// (optional null).
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int num_plus = 0, num_star = 0;
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for (int i = 0; i < num_labels_; ++i) {
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if (labels_[i] != null_char_ || NeededNull(i))
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++num_plus;
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else
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++num_star;
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}
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// Compute the size for each type. If there is enough space for everything
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// to have size>=1, then all are equal, otherwise plus_size=1 and star gets
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// whatever is left-over.
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float plus_size = 1.0f, star_size = 0.0f;
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float total_floating = num_plus + num_star;
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if (total_floating <= num_timesteps_) {
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plus_size = star_size = num_timesteps_ / total_floating;
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} else if (num_star > 0) {
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star_size = static_cast<float>(num_timesteps_ - num_plus) / num_star;
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}
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// Set the width and compute the mean of each.
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float mean_pos = 0.0f;
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for (int i = 0; i < num_labels_; ++i) {
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float half_width;
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if (labels_[i] != null_char_ || NeededNull(i)) {
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half_width = plus_size / 2.0f;
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} else {
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half_width = star_size / 2.0f;
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}
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mean_pos += half_width;
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means->push_back(static_cast<int>(mean_pos));
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mean_pos += half_width;
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half_widths->push_back(half_width);
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}
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}
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// Helper returns the index of the highest probability label at timestep t.
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static int BestLabel(const GENERIC_2D_ARRAY<float>& outputs, int t) {
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int result = 0;
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int num_classes = outputs.dim2();
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const float* outputs_t = outputs[t];
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for (int c = 1; c < num_classes; ++c) {
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if (outputs_t[c] > outputs_t[result]) result = c;
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}
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return result;
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}
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// Calculates and returns a suitable fraction of the simple targets to add
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// to the network outputs.
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float CTC::CalculateBiasFraction() {
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// Compute output labels via basic decoding.
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GenericVector<int> output_labels;
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for (int t = 0; t < num_timesteps_; ++t) {
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int label = BestLabel(outputs_, t);
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while (t + 1 < num_timesteps_ && BestLabel(outputs_, t + 1) == label) ++t;
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if (label != null_char_) output_labels.push_back(label);
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}
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// Simple bag of labels error calculation.
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GenericVector<int> truth_counts(num_classes_, 0);
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GenericVector<int> output_counts(num_classes_, 0);
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for (int l = 0; l < num_labels_; ++l) {
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++truth_counts[labels_[l]];
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}
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for (int l = 0; l < output_labels.size(); ++l) {
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++output_counts[output_labels[l]];
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}
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// Count the number of true and false positive non-nulls and truth labels.
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int true_pos = 0, false_pos = 0, total_labels = 0;
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for (int c = 0; c < num_classes_; ++c) {
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if (c == null_char_) continue;
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int truth_count = truth_counts[c];
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int ocr_count = output_counts[c];
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if (truth_count > 0) {
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total_labels += truth_count;
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if (ocr_count > truth_count) {
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true_pos += truth_count;
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false_pos += ocr_count - truth_count;
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} else {
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true_pos += ocr_count;
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}
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}
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// We don't need to count classes that don't exist in the truth as
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// false positives, because they don't affect CTC at all.
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}
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if (total_labels == 0) return 0.0f;
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return exp(MAX(true_pos - false_pos, 1) * log(kMinProb_) / total_labels);
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}
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// Given ln(x) and ln(y), returns ln(x + y), using:
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// ln(x + y) = ln(y) + ln(1 + exp(ln(y) - ln(x)), ensuring that ln(x) is the
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// bigger number to maximize precision.
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static double LogSumExp(double ln_x, double ln_y) {
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if (ln_x >= ln_y) {
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return ln_x + log1p(exp(ln_y - ln_x));
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} else {
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return ln_y + log1p(exp(ln_x - ln_y));
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}
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}
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// Runs the forward CTC pass, filling in log_probs.
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void CTC::Forward(GENERIC_2D_ARRAY<double>* log_probs) const {
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log_probs->Resize(num_timesteps_, num_labels_, -MAX_FLOAT32);
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log_probs->put(0, 0, log(outputs_(0, labels_[0])));
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if (labels_[0] == null_char_)
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log_probs->put(0, 1, log(outputs_(0, labels_[1])));
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for (int t = 1; t < num_timesteps_; ++t) {
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const float* outputs_t = outputs_[t];
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for (int u = min_labels_[t]; u <= max_labels_[t]; ++u) {
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// Continuing the same label.
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double log_sum = log_probs->get(t - 1, u);
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// Change from previous label.
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if (u > 0) {
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log_sum = LogSumExp(log_sum, log_probs->get(t - 1, u - 1));
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}
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// Skip the null if allowed.
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if (u >= 2 && labels_[u - 1] == null_char_ &&
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labels_[u] != labels_[u - 2]) {
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log_sum = LogSumExp(log_sum, log_probs->get(t - 1, u - 2));
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}
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// Add in the log prob of the current label.
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double label_prob = outputs_t[labels_[u]];
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log_sum += log(label_prob);
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log_probs->put(t, u, log_sum);
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}
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}
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}
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// Runs the backward CTC pass, filling in log_probs.
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void CTC::Backward(GENERIC_2D_ARRAY<double>* log_probs) const {
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log_probs->Resize(num_timesteps_, num_labels_, -MAX_FLOAT32);
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log_probs->put(num_timesteps_ - 1, num_labels_ - 1, 0.0);
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if (labels_[num_labels_ - 1] == null_char_)
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log_probs->put(num_timesteps_ - 1, num_labels_ - 2, 0.0);
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for (int t = num_timesteps_ - 2; t >= 0; --t) {
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const float* outputs_tp1 = outputs_[t + 1];
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for (int u = min_labels_[t]; u <= max_labels_[t]; ++u) {
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// Continuing the same label.
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double log_sum = log_probs->get(t + 1, u) + log(outputs_tp1[labels_[u]]);
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// Change from previous label.
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if (u + 1 < num_labels_) {
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double prev_prob = outputs_tp1[labels_[u + 1]];
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log_sum =
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LogSumExp(log_sum, log_probs->get(t + 1, u + 1) + log(prev_prob));
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}
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// Skip the null if allowed.
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if (u + 2 < num_labels_ && labels_[u + 1] == null_char_ &&
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labels_[u] != labels_[u + 2]) {
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double skip_prob = outputs_tp1[labels_[u + 2]];
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log_sum =
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LogSumExp(log_sum, log_probs->get(t + 1, u + 2) + log(skip_prob));
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}
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log_probs->put(t, u, log_sum);
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}
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}
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}
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// Normalizes and brings probs out of log space with a softmax over time.
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void CTC::NormalizeSequence(GENERIC_2D_ARRAY<double>* probs) const {
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double max_logprob = probs->Max();
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for (int u = 0; u < num_labels_; ++u) {
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double total = 0.0;
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for (int t = 0; t < num_timesteps_; ++t) {
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// Separate impossible path from unlikely probs.
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double prob = probs->get(t, u);
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if (prob > -MAX_FLOAT32)
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prob = ClippedExp(prob - max_logprob);
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else
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prob = 0.0;
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total += prob;
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probs->put(t, u, prob);
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}
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// Note that although this is a probability distribution over time and
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// therefore should sum to 1, it is important to allow some labels to be
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// all zero, (or at least tiny) as it is necessary to skip some blanks.
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if (total < kMinTotalTimeProb_) total = kMinTotalTimeProb_;
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for (int t = 0; t < num_timesteps_; ++t)
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probs->put(t, u, probs->get(t, u) / total);
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}
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}
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// For each timestep computes the max prob for each class over all
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// instances of the class in the labels_, and sets the targets to
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// the max observed prob.
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void CTC::LabelsToClasses(const GENERIC_2D_ARRAY<double>& probs,
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NetworkIO* targets) const {
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// For each timestep compute the max prob for each class over all
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// instances of the class in the labels_.
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GenericVector<double> class_probs;
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for (int t = 0; t < num_timesteps_; ++t) {
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float* targets_t = targets->f(t);
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class_probs.init_to_size(num_classes_, 0.0);
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for (int u = 0; u < num_labels_; ++u) {
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double prob = probs(t, u);
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// Note that although Graves specifies sum over all labels of the same
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// class, we need to allow skipped blanks to go to zero, so they don't
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// interfere with the non-blanks, so max is better than sum.
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if (prob > class_probs[labels_[u]]) class_probs[labels_[u]] = prob;
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// class_probs[labels_[u]] += prob;
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}
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int best_class = 0;
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for (int c = 0; c < num_classes_; ++c) {
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targets_t[c] = class_probs[c];
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if (class_probs[c] > class_probs[best_class]) best_class = c;
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}
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}
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}
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// Normalizes the probabilities such that no target has a prob below min_prob,
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// and, provided that the initial total is at least min_total_prob, then all
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// probs will sum to 1, otherwise to sum/min_total_prob. The maximum output
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// probability is thus 1 - (num_classes-1)*min_prob.
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/* static */
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void CTC::NormalizeProbs(GENERIC_2D_ARRAY<float>* probs) {
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int num_timesteps = probs->dim1();
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int num_classes = probs->dim2();
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for (int t = 0; t < num_timesteps; ++t) {
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float* probs_t = (*probs)[t];
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// Compute the total and clip that to prevent amplification of noise.
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double total = 0.0;
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for (int c = 0; c < num_classes; ++c) total += probs_t[c];
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if (total < kMinTotalFinalProb_) total = kMinTotalFinalProb_;
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// Compute the increased total as a result of clipping.
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double increment = 0.0;
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for (int c = 0; c < num_classes; ++c) {
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double prob = probs_t[c] / total;
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if (prob < kMinProb_) increment += kMinProb_ - prob;
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}
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// Now normalize with clipping. Any additional clipping is negligible.
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total += increment;
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for (int c = 0; c < num_classes; ++c) {
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float prob = probs_t[c] / total;
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probs_t[c] = MAX(prob, kMinProb_);
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}
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}
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}
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// Returns true if the label at index is a needed null.
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bool CTC::NeededNull(int index) const {
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return labels_[index] == null_char_ && index > 0 && index + 1 < num_labels_ &&
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labels_[index + 1] == labels_[index - 1];
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}
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} // namespace tesseract
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