/****************************************************************************** * Project: GDAL * Purpose: Correlator * Author: Andrew Migal, migal.drew@gmail.com * ****************************************************************************** * Copyright (c) 2012, Andrew Migal * * SPDX-License-Identifier: MIT ****************************************************************************/ #include "gdal_simplesurf.h" /************************************************************************/ /* ==================================================================== */ /* GDALIntegralImage */ /* ==================================================================== */ /************************************************************************/ GDALIntegralImage::GDALIntegralImage() = default; int GDALIntegralImage::GetHeight() { return nHeight; } int GDALIntegralImage::GetWidth() { return nWidth; } void GDALIntegralImage::Initialize(const double **padfImg, int nHeightIn, int nWidthIn) { if (pMatrix) { for (int i = 0; i < nHeight; i++) delete[] pMatrix[i]; delete[] pMatrix; } // Memory allocation. pMatrix = new double *[nHeightIn]; for (int i = 0; i < nHeightIn; i++) pMatrix[i] = new double[nWidthIn]; nHeight = nHeightIn; nWidth = nWidthIn; // Integral image calculation. for (int i = 0; i < nHeight; i++) for (int j = 0; j < nWidth; j++) { const double val = padfImg[i][j]; double a = 0.0; double b = 0.0; double c = 0.0; if (i - 1 >= 0 && j - 1 >= 0) a = pMatrix[i - 1][j - 1]; if (j - 1 >= 0) b = pMatrix[i][j - 1]; if (i - 1 >= 0) c = pMatrix[i - 1][j]; // New value based on previous calculations. pMatrix[i][j] = val - a + b + c; } } /* * Returns value of specified cell. */ double GDALIntegralImage::GetValue(int nRow, int nCol) { if (!((nRow >= 0 && nRow < nHeight) && (nCol >= 0 && nCol < nWidth))) return 0; return pMatrix[nRow][nCol]; } double GDALIntegralImage::GetRectangleSum(int nRow, int nCol, int nWidthIn, int nHeightIn) { // Left top point of rectangle is first. const int w = nWidthIn - 1; const int h = nHeightIn - 1; const int row = nRow; const int col = nCol; // Left top point. const int lt_row = (row <= nHeight) ? (row - 1) : -1; const int lt_col = (col <= nWidth) ? (col - 1) : -1; // Right bottom point of the rectangle. const int rb_row = (row + h < nHeight) ? (row + h) : (nHeight - 1); const int rb_col = (col + w < nWidth) ? (col + w) : (nWidth - 1); double a = 0.0; double b = 0.0; double c = 0.0; double d = 0.0; if (lt_row >= 0 && lt_col >= 0) a = GetValue(lt_row, lt_col); if (lt_row >= 0 && rb_col >= 0) b = GetValue(lt_row, rb_col); if (rb_row >= 0 && rb_col >= 0) c = GetValue(rb_row, rb_col); if (rb_row >= 0 && lt_col >= 0) d = GetValue(rb_row, lt_col); const double res = a + c - b - d; return res > 0 ? res : 0; } double GDALIntegralImage::HaarWavelet_X(int nRow, int nCol, int nSize) { return GetRectangleSum(nRow, nCol + nSize / 2, nSize / 2, nSize) - GetRectangleSum(nRow, nCol, nSize / 2, nSize); } double GDALIntegralImage::HaarWavelet_Y(int nRow, int nCol, int nSize) { return GetRectangleSum(nRow + nSize / 2, nCol, nSize, nSize / 2) - GetRectangleSum(nRow, nCol, nSize, nSize / 2); } GDALIntegralImage::~GDALIntegralImage() { // Clean up memory. for (int i = 0; i < nHeight; i++) delete[] pMatrix[i]; delete[] pMatrix; } /************************************************************************/ /* ==================================================================== */ /* GDALOctaveLayer */ /* ==================================================================== */ /************************************************************************/ GDALOctaveLayer::GDALOctaveLayer(int nOctave, int nInterval) : octaveNum(nOctave), filterSize(3 * static_cast(pow(2.0, nOctave)) * nInterval + 1), radius((filterSize - 1) / 2), scale(static_cast(pow(2.0, nOctave))), width(0), height(0), detHessians(nullptr), signs(nullptr) { } void GDALOctaveLayer::ComputeLayer(GDALIntegralImage *poImg) { width = poImg->GetWidth(); height = poImg->GetHeight(); // Allocate memory for arrays. detHessians = new double *[height]; signs = new int *[height]; for (int i = 0; i < height; i++) { detHessians[i] = new double[width]; signs[i] = new int[width]; } // 1/3 of filter side. const int lobe = filterSize / 3; // Length of the longer side of the lobe in dxx and dyy filters. const int longPart = 2 * lobe - 1; const int normalization = filterSize * filterSize; // Loop over image pixels. // Filter should remain into image borders. for (int r = radius; r <= height - radius; r++) for (int c = radius; c <= width - radius; c++) { // Values of Fast Hessian filters. double dxx = poImg->GetRectangleSum(r - lobe + 1, c - radius, filterSize, longPart) - 3 * poImg->GetRectangleSum(r - lobe + 1, c - (lobe - 1) / 2, lobe, longPart); double dyy = poImg->GetRectangleSum(r - radius, c - lobe - 1, longPart, filterSize) - 3 * poImg->GetRectangleSum(r - lobe + 1, c - lobe + 1, longPart, lobe); double dxy = poImg->GetRectangleSum(r - lobe, c - lobe, lobe, lobe) + poImg->GetRectangleSum(r + 1, c + 1, lobe, lobe) - poImg->GetRectangleSum(r - lobe, c + 1, lobe, lobe) - poImg->GetRectangleSum(r + 1, c - lobe, lobe, lobe); dxx /= normalization; dyy /= normalization; dxy /= normalization; // Memorize Hessian values and their signs. detHessians[r][c] = dxx * dyy - 0.9 * 0.9 * dxy * dxy; signs[r][c] = (dxx + dyy >= 0) ? 1 : -1; } } GDALOctaveLayer::~GDALOctaveLayer() { for (int i = 0; i < height; i++) { delete[] detHessians[i]; delete[] signs[i]; } delete[] detHessians; delete[] signs; } /************************************************************************/ /* ==================================================================== */ /* GDALOctaveMap */ /* ==================================================================== */ /************************************************************************/ GDALOctaveMap::GDALOctaveMap(int nOctaveStartIn, int nOctaveEndIn) : pMap(new GDALOctaveLayer **[nOctaveEndIn]), octaveStart(nOctaveStartIn), octaveEnd(nOctaveEndIn) { for (int i = 0; i < octaveEnd; i++) pMap[i] = new GDALOctaveLayer *[INTERVALS]; for (int oct = octaveStart; oct <= octaveEnd; oct++) for (int i = 1; i <= INTERVALS; i++) pMap[oct - 1][i - 1] = new GDALOctaveLayer(oct, i); } void GDALOctaveMap::ComputeMap(GDALIntegralImage *poImg) { for (int oct = octaveStart; oct <= octaveEnd; oct++) for (int i = 1; i <= INTERVALS; i++) pMap[oct - 1][i - 1]->ComputeLayer(poImg); } bool GDALOctaveMap::PointIsExtremum(int row, int col, GDALOctaveLayer *bot, GDALOctaveLayer *mid, GDALOctaveLayer *top, double threshold) { // Check that point in middle layer has all neighbors. if (row <= top->radius || col <= top->radius || row + top->radius >= top->height || col + top->radius >= top->width) return false; const double curPoint = mid->detHessians[row][col]; // Hessian should be higher than threshold. if (curPoint < threshold) return false; // Hessian should be higher than Hessians of all neighbors. for (int i = -1; i <= 1; i++) for (int j = -1; j <= 1; j++) { const double topPoint = top->detHessians[row + i][col + j]; const double midPoint = mid->detHessians[row + i][col + j]; const double botPoint = bot->detHessians[row + i][col + j]; if (topPoint >= curPoint || botPoint >= curPoint) return false; if (i != 0 || j != 0) if (midPoint >= curPoint) return false; } return true; } GDALOctaveMap::~GDALOctaveMap() { // Clean up Octave layers. for (int oct = octaveStart; oct <= octaveEnd; oct++) for (int i = 0; i < INTERVALS; i++) delete pMap[oct - 1][i]; // Clean up allocated memory. for (int oct = 0; oct < octaveEnd; oct++) delete[] pMap[oct]; delete[] pMap; }