/****************************************************************************** * * Project: GDAL Warp API * Purpose: Implemenentation of 2D Thin Plate Spline transformer. * Author: VIZRT Development Team. * * This code was provided by Gilad Ronnen (gro at visrt dot com) with * permission to reuse under the following license. * ****************************************************************************** * Copyright (c) 2004, VIZRT Inc. * Copyright (c) 2008-2014, Even Rouault * * SPDX-License-Identifier: MIT ****************************************************************************/ /*! @cond Doxygen_Suppress */ #include "cpl_port.h" #include "thinplatespline.h" #include "gdallinearsystem.h" #include #include #include #include #include #include // bad_alloc #include #include "cpl_error.h" #include "cpl_vsi.h" ////////////////////////////////////////////////////////////////////////////// //// vizGeorefSpline2D ////////////////////////////////////////////////////////////////////////////// // #define VIZ_GEOREF_SPLINE_DEBUG 0 bool VizGeorefSpline2D::grow_points() { const int new_max = _max_nof_points * 2 + 2 + 3; double *new_x = static_cast(VSI_REALLOC_VERBOSE(x, sizeof(double) * new_max)); if (!new_x) return false; x = new_x; double *new_y = static_cast(VSI_REALLOC_VERBOSE(y, sizeof(double) * new_max)); if (!new_y) return false; y = new_y; double *new_u = static_cast(VSI_REALLOC_VERBOSE(u, sizeof(double) * new_max)); if (!new_u) return false; u = new_u; int *new_unused = static_cast(VSI_REALLOC_VERBOSE(unused, sizeof(int) * new_max)); if (!new_unused) return false; unused = new_unused; int *new_index = static_cast(VSI_REALLOC_VERBOSE(index, sizeof(int) * new_max)); if (!new_index) return false; index = new_index; for (int i = 0; i < _nof_vars; i++) { double *rhs_i_new = static_cast( VSI_REALLOC_VERBOSE(rhs[i], sizeof(double) * new_max)); if (!rhs_i_new) return false; rhs[i] = rhs_i_new; double *coef_i_new = static_cast( VSI_REALLOC_VERBOSE(coef[i], sizeof(double) * new_max)); if (!coef_i_new) return false; coef[i] = coef_i_new; if (_max_nof_points == 0) { memset(rhs[i], 0, 3 * sizeof(double)); memset(coef[i], 0, 3 * sizeof(double)); } } _max_nof_points = new_max - 3; return true; } bool VizGeorefSpline2D::add_point(const double Px, const double Py, const double *Pvars) { type = VIZ_GEOREF_SPLINE_POINT_WAS_ADDED; int i; if (_nof_points == _max_nof_points) { if (!grow_points()) return false; } i = _nof_points; // A new point is added. x[i] = Px; y[i] = Py; for (int j = 0; j < _nof_vars; j++) rhs[j][i + 3] = Pvars[j]; _nof_points++; return true; } #if 0 bool VizGeorefSpline2D::change_point( int index, double Px, double Py, double* Pvars ) { if( index < _nof_points ) { int i = index; x[i] = Px; y[i] = Py; for( int j = 0; j < _nof_vars; j++ ) rhs[j][i+3] = Pvars[j]; } return true; } bool VizGeorefSpline2D::get_xy( int index, double& outX, double& outY ) { if( index < _nof_points ) { ok = true; outX = x[index]; outY = y[index]; return true; } outX = 0.0; outY = 0.0; return false; } int VizGeorefSpline2D::delete_point( const double Px, const double Py ) { for( int i = 0; i < _nof_points; i++ ) { if( ( fabs(Px - x[i]) <= _tx ) && ( fabs(Py - y[i]) <= _ty ) ) { for( int j = i; j < _nof_points - 1; j++ ) { x[j] = x[j+1]; y[j] = y[j+1]; for( int k = 0; k < _nof_vars; k++ ) rhs[k][j+3] = rhs[k][j+3+1]; } _nof_points--; type = VIZ_GEOREF_SPLINE_POINT_WAS_DELETED; return 1; } } return 0; } #endif template static inline T SQ(const T &x) { return x * x; } static inline double VizGeorefSpline2DBase_func(const double x1, const double y1, const double x2, const double y2) { const double dist = SQ(x2 - x1) + SQ(y2 - y1); return dist != 0.0 ? dist * log(dist) : 0.0; } #if defined(__GNUC__) && defined(__x86_64__) /* Some versions of ICC fail to compile VizGeorefSpline2DBase_func4 (#6350) */ #if defined(__INTEL_COMPILER) #if __INTEL_COMPILER >= 1500 #define USE_OPTIMIZED_VizGeorefSpline2DBase_func4 #else #if (__INTEL_COMPILER == 1200) || (__INTEL_COMPILER == 1210) #define USE_OPTIMIZED_VizGeorefSpline2DBase_func4 #else #undef USE_OPTIMIZED_VizGeorefSpline2DBase_func4 #endif #endif #else // defined(__INTEL_COMPILER) #define USE_OPTIMIZED_VizGeorefSpline2DBase_func4 #endif // defined(__INTEL_COMPILER) #endif #if defined(USE_OPTIMIZED_VizGeorefSpline2DBase_func4) && !defined(CPPCHECK) /* Derived and adapted from code originating from: */ /* @(#)e_log.c 1.3 95/01/18 */ /* * ==================================================== * Copyright (C) 1993 by Sun Microsystems, Inc. All rights reserved. * * Developed at SunSoft, a Sun Microsystems, Inc. business. * Permission to use, copy, modify, and distribute this * software is freely granted, provided that this notice * is preserved. * ==================================================== */ /* __ieee754_log(x) * Return the logarithm of x * * Method: * 1. Argument Reduction: find k and f such that * x = 2^k * (1+f), * where sqrt(2)/2 < 1+f < sqrt(2) . * * 2. Approximation of log(1+f). * Let s = f/(2+f) ; based on log(1+f) = log(1+s) - log(1-s) * = 2s + 2/3 s**3 + 2/5 s**5 + ....., * = 2s + s*R * We use a special Reme algorithm on [0,0.1716] to generate * a polynomial of degree 14 to approximate R The maximum error * of this polynomial approximation is bounded by 2**-58.45. In * other words, * 2 4 6 8 10 12 14 * R(z) ~ Lg1*s +Lg2*s +Lg3*s +Lg4*s +Lg5*s +Lg6*s +Lg7*s * (the values of Lg1 to Lg7 are listed in the program) * and * | 2 14 | -58.45 * | Lg1*s +...+Lg7*s - R(z) | <= 2 * | | * Note that 2s = f - s*f = f - hfsq + s*hfsq, where hfsq = f*f/2. * In order to guarantee error in log below 1ulp, we compute log * by * log(1+f) = f - s*(f - R) (if f is not too large) * log(1+f) = f - (hfsq - s*(hfsq+R)). (better accuracy) * * 3. Finally, log(x) = k*ln2 + log(1+f). * = k*ln2_hi+(f-(hfsq-(s*(hfsq+R)+k*ln2_lo))) * Here ln2 is split into two floating point number: * ln2_hi + ln2_lo, * where n*ln2_hi is always exact for |n| < 2000. * * Special cases: * log(x) is NaN with signal if x < 0 (including -INF) ; * log(+INF) is +INF; log(0) is -INF with signal; * log(NaN) is that NaN with no signal. * * Accuracy: * according to an error analysis, the error is always less than * 1 ulp (unit in the last place). * * Constants: * The hexadecimal values are the intended ones for the following * constants. The decimal values may be used, provided that the * compiler will convert from decimal to binary accurately enough * to produce the hexadecimal values shown. */ typedef double V2DF __attribute__((__vector_size__(16))); typedef union { V2DF v2; double d[2]; } v2dfunion; typedef union { int i[2]; long long li; } i64union; static const V2DF v2_ln2_div_2pow20 = {6.93147180559945286e-01 / 1048576, 6.93147180559945286e-01 / 1048576}; static const V2DF v2_Lg1 = {6.666666666666735130e-01, 6.666666666666735130e-01}; static const V2DF v2_Lg2 = {3.999999999940941908e-01, 3.999999999940941908e-01}; static const V2DF v2_Lg3 = {2.857142874366239149e-01, 2.857142874366239149e-01}; static const V2DF v2_Lg4 = {2.222219843214978396e-01, 2.222219843214978396e-01}; static const V2DF v2_Lg5 = {1.818357216161805012e-01, 1.818357216161805012e-01}; static const V2DF v2_Lg6 = {1.531383769920937332e-01, 1.531383769920937332e-01}; /*v2_Lg7 = {1.479819860511658591e-01, 1.479819860511658591e-01}, */ static const V2DF v2_one = {1.0, 1.0}; static const V2DF v2_const1023_mul_2pow20 = {1023.0 * 1048576, 1023.0 * 1048576}; #define GET_HIGH_WORD(hx, x) memcpy(&hx, reinterpret_cast(&x) + 4, 4) #define SET_HIGH_WORD(x, hx) memcpy(reinterpret_cast(&x) + 4, &hx, 4) #define MAKE_WIDE_CST(x) (((static_cast(x)) << 32) | (x)) constexpr long long cst_expmask = MAKE_WIDE_CST(0xfff00000); constexpr long long cst_0x95f64 = MAKE_WIDE_CST(0x00095f64); constexpr long long cst_0x100000 = MAKE_WIDE_CST(0x00100000); constexpr long long cst_0x3ff00000 = MAKE_WIDE_CST(0x3ff00000); // Modified version of __ieee754_log(), less precise than log() but a bit // faster, and computing 4 log() at a time. Assumes that the values are > 0. static void FastApproxLog4Val(v2dfunion *x) { i64union hx[2] = {}; i64union k[2] = {}; i64union i[2] = {}; GET_HIGH_WORD(hx[0].i[0], x[0].d[0]); GET_HIGH_WORD(hx[0].i[1], x[0].d[1]); // coverity[uninit_use] k[0].li = hx[0].li & cst_expmask; hx[0].li &= ~cst_expmask; i[0].li = (hx[0].li + cst_0x95f64) & cst_0x100000; hx[0].li |= i[0].li ^ cst_0x3ff00000; SET_HIGH_WORD(x[0].d[0], hx[0].i[0]); // Normalize x or x/2. SET_HIGH_WORD(x[0].d[1], hx[0].i[1]); // Normalize x or x/2. k[0].li += i[0].li; v2dfunion dk[2] = {}; dk[0].d[0] = static_cast(k[0].i[0]); dk[0].d[1] = static_cast(k[0].i[1]); GET_HIGH_WORD(hx[1].i[0], x[1].d[0]); GET_HIGH_WORD(hx[1].i[1], x[1].d[1]); k[1].li = hx[1].li & cst_expmask; hx[1].li &= ~cst_expmask; i[1].li = (hx[1].li + cst_0x95f64) & cst_0x100000; hx[1].li |= i[1].li ^ cst_0x3ff00000; SET_HIGH_WORD(x[1].d[0], hx[1].i[0]); // Normalize x or x/2. SET_HIGH_WORD(x[1].d[1], hx[1].i[1]); // Normalize x or x/2. k[1].li += i[1].li; dk[1].d[0] = static_cast(k[1].i[0]); dk[1].d[1] = static_cast(k[1].i[1]); V2DF f[2] = {}; f[0] = x[0].v2 - v2_one; V2DF s[2] = {}; s[0] = f[0] / (x[0].v2 + v2_one); V2DF z[2] = {}; z[0] = s[0] * s[0]; V2DF w[2] = {}; w[0] = z[0] * z[0]; V2DF t1[2] = {}; // coverity[ptr_arith] t1[0] = w[0] * (v2_Lg2 + w[0] * (v2_Lg4 + w[0] * v2_Lg6)); V2DF t2[2] = {}; // coverity[ptr_arith] t2[0] = z[0] * (v2_Lg1 + w[0] * (v2_Lg3 + w[0] * (v2_Lg5 /*+w[0]*v2_Lg7*/))); V2DF R[2] = {}; R[0] = t2[0] + t1[0]; x[0].v2 = (dk[0].v2 - v2_const1023_mul_2pow20) * v2_ln2_div_2pow20 - (s[0] * (f[0] - R[0]) - f[0]); f[1] = x[1].v2 - v2_one; s[1] = f[1] / (x[1].v2 + v2_one); z[1] = s[1] * s[1]; w[1] = z[1] * z[1]; // coverity[ptr_arith] t1[1] = w[1] * (v2_Lg2 + w[1] * (v2_Lg4 + w[1] * v2_Lg6)); // coverity[ptr_arith] t2[1] = z[1] * (v2_Lg1 + w[1] * (v2_Lg3 + w[1] * (v2_Lg5 /*+w[1]*v2_Lg7*/))); R[1] = t2[1] + t1[1]; x[1].v2 = (dk[1].v2 - v2_const1023_mul_2pow20) * v2_ln2_div_2pow20 - (s[1] * (f[1] - R[1]) - f[1]); } static CPL_INLINE void VizGeorefSpline2DBase_func4(double *res, const double *pxy, const double *xr, const double *yr) { v2dfunion xv[2] = {}; xv[0].d[0] = xr[0]; xv[0].d[1] = xr[1]; xv[1].d[0] = xr[2]; xv[1].d[1] = xr[3]; v2dfunion yv[2] = {}; yv[0].d[0] = yr[0]; yv[0].d[1] = yr[1]; yv[1].d[0] = yr[2]; yv[1].d[1] = yr[3]; v2dfunion x1v; x1v.d[0] = pxy[0]; x1v.d[1] = pxy[0]; v2dfunion y1v; y1v.d[0] = pxy[1]; y1v.d[1] = pxy[1]; v2dfunion dist[2] = {}; dist[0].v2 = SQ(xv[0].v2 - x1v.v2) + SQ(yv[0].v2 - y1v.v2); dist[1].v2 = SQ(xv[1].v2 - x1v.v2) + SQ(yv[1].v2 - y1v.v2); v2dfunion resv[2] = {dist[0], dist[1]}; FastApproxLog4Val(dist); resv[0].v2 *= dist[0].v2; resv[1].v2 *= dist[1].v2; res[0] = resv[0].d[0]; res[1] = resv[0].d[1]; res[2] = resv[1].d[0]; res[3] = resv[1].d[1]; } #else // defined(USE_OPTIMIZED_VizGeorefSpline2DBase_func4) static void VizGeorefSpline2DBase_func4(double *res, const double *pxy, const double *xr, const double *yr) { double dist0 = SQ(xr[0] - pxy[0]) + SQ(yr[0] - pxy[1]); res[0] = dist0 != 0.0 ? dist0 * log(dist0) : 0.0; double dist1 = SQ(xr[1] - pxy[0]) + SQ(yr[1] - pxy[1]); res[1] = dist1 != 0.0 ? dist1 * log(dist1) : 0.0; double dist2 = SQ(xr[2] - pxy[0]) + SQ(yr[2] - pxy[1]); res[2] = dist2 != 0.0 ? dist2 * log(dist2) : 0.0; double dist3 = SQ(xr[3] - pxy[0]) + SQ(yr[3] - pxy[1]); res[3] = dist3 != 0.0 ? dist3 * log(dist3) : 0.0; } #endif // defined(USE_OPTIMIZED_VizGeorefSpline2DBase_func4) int VizGeorefSpline2D::solve(bool bForceBuiltinMethod) { // No points at all. if (_nof_points < 1) { type = VIZ_GEOREF_SPLINE_ZERO_POINTS; return 0; } // Only one point. if (_nof_points == 1) { type = VIZ_GEOREF_SPLINE_ONE_POINT; return 1; } // Just 2 points - it is necessarily 1D case. if (_nof_points == 2) { _dx = x[1] - x[0]; _dy = y[1] - y[0]; const double denom = _dx * _dx + _dy * _dy; if (denom == 0.0) return 0; const double fact = 1.0 / denom; _dx *= fact; _dy *= fact; type = VIZ_GEOREF_SPLINE_TWO_POINTS; return 2; } // More than 2 points - first we have to check if it is 1D or 2D case double xmax = x[0]; double xmin = x[0]; double ymax = y[0]; double ymin = y[0]; double sumx = 0.0; double sumy = 0.0; double sumx2 = 0.0; double sumy2 = 0.0; double sumxy = 0.0; for (int p = 0; p < _nof_points; p++) { const double xx = x[p]; const double yy = y[p]; xmax = std::max(xmax, xx); xmin = std::min(xmin, xx); ymax = std::max(ymax, yy); ymin = std::min(ymin, yy); sumx += xx; sumx2 += xx * xx; sumy += yy; sumy2 += yy * yy; sumxy += xx * yy; } const double delx = xmax - xmin; const double dely = ymax - ymin; const double SSxx = sumx2 - sumx * sumx / _nof_points; const double SSyy = sumy2 - sumy * sumy / _nof_points; const double SSxy = sumxy - sumx * sumy / _nof_points; if (SSxx * SSyy == 0.0) { CPLError(CE_Failure, CPLE_AppDefined, "Degenerate system. Computation aborted."); return 0; } if (delx < 0.001 * dely || dely < 0.001 * delx || fabs(SSxy * SSxy / (SSxx * SSyy)) > 0.99) { type = VIZ_GEOREF_SPLINE_ONE_DIMENSIONAL; _dx = _nof_points * sumx2 - sumx * sumx; _dy = _nof_points * sumy2 - sumy * sumy; const double fact = 1.0 / sqrt(_dx * _dx + _dy * _dy); _dx *= fact; _dy *= fact; for (int p = 0; p < _nof_points; p++) { const double dxp = x[p] - x[0]; const double dyp = y[p] - y[0]; u[p] = _dx * dxp + _dy * dyp; unused[p] = 1; } for (int p = 0; p < _nof_points; p++) { int min_index = -1; double min_u = 0.0; for (int p1 = 0; p1 < _nof_points; p1++) { if (unused[p1]) { if (min_index < 0 || u[p1] < min_u) { min_index = p1; min_u = u[p1]; } } } index[p] = min_index; unused[min_index] = 0; } return 3; } type = VIZ_GEOREF_SPLINE_FULL; // Make the necessary memory allocations. _nof_eqs = _nof_points + 3; if (_nof_eqs > std::numeric_limits::max() / _nof_eqs) { CPLError(CE_Failure, CPLE_AppDefined, "Too many coefficients. Computation aborted."); return 0; } try { GDALMatrix A(_nof_eqs, _nof_eqs); x_mean = 0; y_mean = 0; for (int c = 0; c < _nof_points; c++) { x_mean += x[c]; y_mean += y[c]; } x_mean /= _nof_points; y_mean /= _nof_points; for (int c = 0; c < _nof_points; c++) { x[c] -= x_mean; y[c] -= y_mean; A(0, c + 3) = 1.0; A(1, c + 3) = x[c]; A(2, c + 3) = y[c]; A(c + 3, 0) = 1.0; A(c + 3, 1) = x[c]; A(c + 3, 2) = y[c]; } for (int r = 0; r < _nof_points; r++) for (int c = r; c < _nof_points; c++) { A(r + 3, c + 3) = VizGeorefSpline2DBase_func(x[r], y[r], x[c], y[c]); if (r != c) A(c + 3, r + 3) = A(r + 3, c + 3); } #if VIZ_GEOREF_SPLINE_DEBUG for (r = 0; r < _nof_eqs; r++) { for (c = 0; c < _nof_eqs; c++) fprintf(stderr, "%f", A(r, c)); /*ok*/ fprintf(stderr, "\n"); /*ok*/ } #endif GDALMatrix RHS(_nof_eqs, _nof_vars); for (int iRHS = 0; iRHS < _nof_vars; iRHS++) for (int iRow = 0; iRow < _nof_eqs; iRow++) RHS(iRow, iRHS) = rhs[iRHS][iRow]; GDALMatrix Coef(_nof_eqs, _nof_vars); if (!GDALLinearSystemSolve(A, RHS, Coef, bForceBuiltinMethod)) { return 0; } for (int iRHS = 0; iRHS < _nof_vars; iRHS++) for (int iRow = 0; iRow < _nof_eqs; iRow++) coef[iRHS][iRow] = Coef(iRow, iRHS); return 4; } catch (const std::bad_alloc &) { CPLError(CE_Failure, CPLE_OutOfMemory, "thinplatespline: out of memory allocating matrices"); return 0; } } int VizGeorefSpline2D::get_point(const double Px, const double Py, double *vars) { switch (type) { case VIZ_GEOREF_SPLINE_ZERO_POINTS: { for (int v = 0; v < _nof_vars; v++) vars[v] = 0.0; break; } case VIZ_GEOREF_SPLINE_ONE_POINT: { for (int v = 0; v < _nof_vars; v++) vars[v] = rhs[v][3]; break; } case VIZ_GEOREF_SPLINE_TWO_POINTS: { const double fact = _dx * (Px - x[0]) + _dy * (Py - y[0]); for (int v = 0; v < _nof_vars; v++) vars[v] = (1 - fact) * rhs[v][3] + fact * rhs[v][4]; break; } case VIZ_GEOREF_SPLINE_ONE_DIMENSIONAL: { int leftP = 0; int rightP = 0; const double Pu = _dx * (Px - x[0]) + _dy * (Py - y[0]); if (Pu <= u[index[0]]) { leftP = index[0]; rightP = index[1]; } else if (Pu >= u[index[_nof_points - 1]]) { leftP = index[_nof_points - 2]; rightP = index[_nof_points - 1]; } else { for (int r = 1; r < _nof_points; r++) { leftP = index[r - 1]; rightP = index[r]; if (Pu >= u[leftP] && Pu <= u[rightP]) break; // Found. } } const double fact = (Pu - u[leftP]) / (u[rightP] - u[leftP]); for (int v = 0; v < _nof_vars; v++) vars[v] = (1.0 - fact) * rhs[v][leftP + 3] + fact * rhs[v][rightP + 3]; break; } case VIZ_GEOREF_SPLINE_FULL: { const double Pxy[2] = {Px - x_mean, Py - y_mean}; for (int v = 0; v < _nof_vars; v++) vars[v] = coef[v][0] + coef[v][1] * Pxy[0] + coef[v][2] * Pxy[1]; int r = 0; // Used after for. for (; r < (_nof_points & (~3)); r += 4) { double dfTmp[4] = {}; VizGeorefSpline2DBase_func4(dfTmp, Pxy, &x[r], &y[r]); for (int v = 0; v < _nof_vars; v++) vars[v] += coef[v][r + 3] * dfTmp[0] + coef[v][r + 3 + 1] * dfTmp[1] + coef[v][r + 3 + 2] * dfTmp[2] + coef[v][r + 3 + 3] * dfTmp[3]; } for (; r < _nof_points; r++) { const double tmp = VizGeorefSpline2DBase_func(Pxy[0], Pxy[1], x[r], y[r]); for (int v = 0; v < _nof_vars; v++) vars[v] += coef[v][r + 3] * tmp; } break; } case VIZ_GEOREF_SPLINE_POINT_WAS_ADDED: { CPLError(CE_Failure, CPLE_AppDefined, "A point was added after the last solve." " NO interpolation - return values are zero"); for (int v = 0; v < _nof_vars; v++) vars[v] = 0.0; return 0; } case VIZ_GEOREF_SPLINE_POINT_WAS_DELETED: { CPLError(CE_Failure, CPLE_AppDefined, "A point was deleted after the last solve." " NO interpolation - return values are zero"); for (int v = 0; v < _nof_vars; v++) vars[v] = 0.0; return 0; } default: { return 0; } } return 1; } /*! @endcond */