/////////////////////////////////////////////////////////////////////// // File: stridemap.cpp // Description: Indexing into a 4-d tensor held in a 2-d Array. // Author: Ray Smith // Created: Fri Sep 20 15:30:31 PST 2016 // // (C) Copyright 2016, Google Inc. // 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 "stridemap.h" namespace tesseract { // Returns true if *this is a valid index. bool StrideMap::Index::IsValid() const { // Cheap check first. for (int d = 0; d < FD_DIMSIZE; ++d) { if (indices_[d] < 0) return false; } for (int d = 0; d < FD_DIMSIZE; ++d) { if (indices_[d] > MaxIndexOfDim(static_cast(d))) return false; } return true; } // Returns true if the index of the given dimension is the last. bool StrideMap::Index::IsLast(FlexDimensions dimension) const { return MaxIndexOfDim(dimension) == indices_[dimension]; } // Given that the dimensions up to and including dim-1 are valid, returns the // maximum index for dimension dim. int StrideMap::Index::MaxIndexOfDim(FlexDimensions dim) const { int max_index = stride_map_->shape_[dim] - 1; if (dim == FD_BATCH) return max_index; assert(0 <= indices_[FD_BATCH]); const size_t batch = indices_[FD_BATCH]; if (dim == FD_HEIGHT) { if (batch >= stride_map_->heights_.size() || stride_map_->heights_[batch] > max_index) return max_index; return stride_map_->heights_[batch] - 1; } if (batch >= stride_map_->widths_.size() || stride_map_->widths_[batch] > max_index) return max_index; return stride_map_->widths_[batch] - 1; } // Adds the given offset to the given dimension. Returns true if the result // makes a valid index. bool StrideMap::Index::AddOffset(int offset, FlexDimensions dimension) { indices_[dimension] += offset; SetTFromIndices(); return IsValid(); } // Increments the index in some encapsulated way that guarantees to remain // valid until it returns false, meaning that the iteration is complete. bool StrideMap::Index::Increment() { for (int d = FD_DIMSIZE - 1; d >= 0; --d) { if (!IsLast(static_cast(d))) { t_ += stride_map_->t_increments_[d]; ++indices_[d]; return true; } t_ -= stride_map_->t_increments_[d] * indices_[d]; indices_[d] = 0; // Now carry to the next dimension. } return false; } // Decrements the index in some encapsulated way that guarantees to remain // valid until it returns false, meaning that the iteration (that started // with InitToLast()) is complete. bool StrideMap::Index::Decrement() { for (int d = FD_DIMSIZE - 1; d >= 0; --d) { if (indices_[d] > 0) { --indices_[d]; if (d == FD_BATCH) { // The upper limits of the other dimensions may have changed as a result // of a different batch index, so they have to be reset. InitToLastOfBatch(indices_[FD_BATCH]); } else { t_ -= stride_map_->t_increments_[d]; } return true; } indices_[d] = MaxIndexOfDim(static_cast(d)); t_ += stride_map_->t_increments_[d] * indices_[d]; // Now borrow from the next dimension. } return false; } // Initializes the indices to the last valid location in the given batch // index. void StrideMap::Index::InitToLastOfBatch(int batch) { indices_[FD_BATCH] = batch; for (int d = FD_BATCH + 1; d < FD_DIMSIZE; ++d) { indices_[d] = MaxIndexOfDim(static_cast(d)); } SetTFromIndices(); } // Computes and sets t_ from the current indices_. void StrideMap::Index::SetTFromIndices() { t_ = 0; for (int d = 0; d < FD_DIMSIZE; ++d) { t_ += stride_map_->t_increments_[d] * indices_[d]; } } // Sets up the stride for the given array of height, width pairs. void StrideMap::SetStride(const std::vector>& h_w_pairs) { int max_height = 0; int max_width = 0; for (const std::pair& hw : h_w_pairs) { int height = hw.first; int width = hw.second; heights_.push_back(height); widths_.push_back(width); if (height > max_height) max_height = height; if (width > max_width) max_width = width; } shape_[FD_BATCH] = heights_.size(); shape_[FD_HEIGHT] = max_height; shape_[FD_WIDTH] = max_width; ComputeTIncrements(); } // Scales width and height dimensions by the given factors. void StrideMap::ScaleXY(int x_factor, int y_factor) { for (int& height : heights_) height /= y_factor; for (int& width : widths_) width /= x_factor; shape_[FD_HEIGHT] /= y_factor; shape_[FD_WIDTH] /= x_factor; ComputeTIncrements(); } // Reduces width to 1, across the batch, whatever the input size. void StrideMap::ReduceWidthTo1() { widths_.assign(widths_.size(), 1); shape_[FD_WIDTH] = 1; ComputeTIncrements(); } // Transposes the width and height dimensions. void StrideMap::TransposeXY() { std::swap(shape_[FD_HEIGHT], shape_[FD_WIDTH]); std::swap(heights_, widths_); ComputeTIncrements(); } // Computes t_increments_ from shape_. void StrideMap::ComputeTIncrements() { t_increments_[FD_DIMSIZE - 1] = 1; for (int d = FD_DIMSIZE - 2; d >= 0; --d) { t_increments_[d] = t_increments_[d + 1] * shape_[d + 1]; } } } // namespace tesseract