/* Copyright (c) 2016 Baidu, Inc. All Rights Reserve. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ #include "Evaluator.h" #include "paddle/gserver/gradientmachines/NeuralNetwork.h" namespace paddle { /** * calculate sequence-to-sequence edit distance */ class CTCErrorEvaluator : public Evaluator { private: MatrixPtr outActivations_; int numTimes_, numClasses_, numSequences_, blank_; real deletions_, insertions_, substitutions_; int seqClassficationError_; std::vector path2String(const std::vector& path) { std::vector str; str.clear(); int prevLabel = -1; for (std::vector::const_iterator label = path.begin(); label != path.end(); label++) { if (*label != blank_ && (str.empty() || *label != str.back() || prevLabel == blank_)) { str.push_back(*label); } prevLabel = *label; } return str; } std::vector bestLabelSeq() { std::vector path; path.clear(); real* acts = outActivations_->getData(); for (int i = 0; i < numTimes_; ++i) { path.push_back(std::max_element(acts + i * numClasses_, acts + (i + 1) * numClasses_) - (acts + i * numClasses_)); } return path2String(path); } /* "sp, dp, ip" is the weighting parameter of "substitution, deletion, * insertion" * in edit-distance error */ real stringAlignment(std::vector& gtStr, std::vector& recogStr, bool backtrace = true, real sp = 1.0, real dp = 1.0, real ip = 1.0) { std::vector> matrix; int substitutions, deletions, insertions; real distance; int n = gtStr.size(); int m = recogStr.size(); if (n == 0) { substitutions = 0; deletions = 0; insertions = m; distance = m; } else if (m == 0) { substitutions = 0; deletions = n; insertions = 0; distance = n; } else { substitutions = 0; deletions = 0; insertions = 0; distance = 0; // initialize the matrix matrix.resize(n + 1); for (int i = 0; i < n + 1; ++i) { matrix[i].resize(m + 1); for (int j = 0; j < m + 1; ++j) { matrix[i][j] = 0; } } for (int i = 0; i < n + 1; ++i) { matrix[i][0] = i; } for (int j = 0; j < m + 1; ++j) { matrix[0][j] = j; } // calculate the insertions, substitutions and deletions for (int i = 1; i < n + 1; ++i) { int s_i = gtStr[i - 1]; for (int j = 1; j < m + 1; ++j) { int t_j = recogStr[j - 1]; int cost = (s_i == t_j) ? 0 : 1; const int above = matrix[i - 1][j]; const int left = matrix[i][j - 1]; const int diag = matrix[i - 1][j - 1]; const int cell = std::min(above + 1, std::min(left + 1, diag + cost)); matrix[i][j] = cell; } } if (backtrace) { size_t i = n; size_t j = m; substitutions = 0; deletions = 0; insertions = 0; while (i != 0 && j != 0) { if (matrix[i][j] == matrix[i - 1][j - 1]) { --i; --j; } else if (matrix[i][j] == matrix[i - 1][j - 1] + 1) { ++substitutions; --i; --j; } else if (matrix[i][j] == matrix[i - 1][j] + 1) { ++deletions; --i; } else { ++insertions; --j; } } while (i != 0) { ++deletions; --i; } while (j != 0) { ++insertions; --j; } int diff = substitutions + deletions + insertions; if (diff != matrix[n][m]) { LOG(ERROR) << "Found path with distance " << diff << " but Levenshtein distance is " << matrix[n][m]; } distance = (sp * substitutions) + (dp * deletions) + (ip * insertions); } else { distance = (real)matrix[n][m]; } } real maxLen = std::max(m, n); deletions_ += deletions / maxLen; insertions_ += insertions / maxLen; substitutions_ += substitutions / maxLen; if (distance != 0) { seqClassficationError_ += 1; } return distance / maxLen; } real editDistance(real* output, int numTimes, int numClasses, int* labels, int labelsLen) { numTimes_ = numTimes; numClasses_ = numClasses; blank_ = numClasses_ - 1; outActivations_ = Matrix::create(output, numTimes, numClasses); std::vector recogStr, gtStr; recogStr = bestLabelSeq(); for (int i = 0; i < labelsLen; ++i) { gtStr.push_back(labels[i]); } return stringAlignment(gtStr, recogStr); } public: CTCErrorEvaluator() : numTimes_(0), numClasses_(0), numSequences_(0), blank_(0), deletions_(0), insertions_(0), substitutions_(0), seqClassficationError_(0) {} virtual real evalImp(std::vector& arguments) { CHECK_EQ(arguments.size(), (size_t)2); Argument output, label; output.resizeAndCopyFrom(arguments[0], false, HPPL_STREAM_DEFAULT); label.resizeAndCopyFrom(arguments[1], false, HPPL_STREAM_DEFAULT); hl_stream_synchronize(HPPL_STREAM_DEFAULT); CHECK(label.sequenceStartPositions); CHECK(label.ids); size_t numSequences = label.sequenceStartPositions->getSize() - 1; const int* labelStarts = label.sequenceStartPositions->getData(false); const int* outputStarts = output.sequenceStartPositions->getData(false); real totalErr = 0; for (size_t i = 0; i < numSequences; ++i) { real err = 0; err = editDistance( output.value->getData() + output.value->getWidth() * outputStarts[i], output.value->getHeight(), output.value->getWidth(), label.ids->getData() + labelStarts[i], labelStarts[i + 1] - labelStarts[i]); totalErr += err; } return totalErr; } virtual void eval(const NeuralNetwork& nn) { Evaluator::eval(nn); std::vector arguments; arguments.reserve(config_.input_layers_size()); for (const std::string& name : config_.input_layers()) { arguments.push_back(nn.getLayer(name)->getOutput()); } numSequences_ += arguments[1].getNumSequences(); } virtual void start() { Evaluator::start(); numSequences_ = 0; blank_ = 0; deletions_ = 0; insertions_ = 0; substitutions_ = 0; seqClassficationError_ = 0; } virtual void printStats(std::ostream& os) { os << config_.name() << "=" << (numSequences_ ? totalScore_ / numSequences_ : 0); os << " deletions error" << "=" << (numSequences_ ? deletions_ / numSequences_ : 0); os << " insertions error" << "=" << (numSequences_ ? insertions_ / numSequences_ : 0); os << " substitutions error" << "=" << (numSequences_ ? substitutions_ / numSequences_ : 0); os << " sequences error" << "=" << (real)seqClassficationError_ / numSequences_; } virtual void distributeEval(ParameterClient2* client) { double buf[6] = {totalScore_, (double)deletions_, (double)insertions_, (double)substitutions_, (double)seqClassficationError_, (double)numSequences_}; client->reduce(buf, buf, 6, FLAGS_trainer_id, 0); totalScore_ = buf[0]; deletions_ = (real)buf[1]; insertions_ = (real)buf[2]; substitutions_ = (real)buf[3]; seqClassficationError_ = (int)buf[4]; numSequences_ = (int)buf[5]; } }; REGISTER_EVALUATOR(ctc_edit_distance, CTCErrorEvaluator); } // namespace paddle