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659 lines
21 KiB
C++
659 lines
21 KiB
C++
/*
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Copyright 2015 SINTEF ICT, Applied Mathematics.
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This file is part of the Open Porous Media project (OPM).
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OPM is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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OPM is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with OPM. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <config.h>
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#include <opm/simulators/wells/VFPHelpers.hpp>
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#include <opm/common/ErrorMacros.hpp>
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#include <opm/material/densead/Evaluation.hpp>
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#include <opm/input/eclipse/Schedule/VFPInjTable.hpp>
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#include <opm/input/eclipse/Schedule/VFPProdTable.hpp>
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#include <cassert>
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#include <cmath>
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#include <stdexcept>
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namespace {
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/**
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* Helper function that finds x for a given value of y for a line
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* *NOTE ORDER OF ARGUMENTS*
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*/
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double findX(const double x0,
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const double x1,
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const double y0,
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const double y1,
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const double y)
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{
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const double dx = x1 - x0;
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const double dy = y1 - y0;
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/**
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* y = y0 + (dy / dx) * (x - x0)
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* => x = x0 + (y - y0) * (dx / dy)
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*
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* If dy is zero, use x1 as the value.
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*/
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double x = 0.0;
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if (dy != 0.0) {
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x = x0 + (y-y0) * (dx/dy);
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}
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else {
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x = x1;
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}
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return x;
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}
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/**
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* Returns zero if input value is negative
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*/
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template <typename T>
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static T chopNegativeValues(const T& value) {
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return Opm::max(0.0, value);
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}
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}
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namespace Opm {
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namespace detail {
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InterpData findInterpData(const double value_in, const std::vector<double>& values)
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{
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InterpData retval;
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const int nvalues = values.size();
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// chopping the value to be zero, which means we do not
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// extrapolate the table towards nagative ranges
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const double value = value_in < 0.? 0. : value_in;
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//If we only have one value in our vector, return that
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if (values.size() == 1) {
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retval.ind_[0] = 0;
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retval.ind_[1] = 0;
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retval.inv_dist_ = 0.0;
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retval.factor_ = 0.0;
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}
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// Else search in the vector
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else {
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//If value is less than all values, use first interval
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if (value < values.front()) {
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retval.ind_[0] = 0;
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retval.ind_[1] = 1;
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}
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//If value is greater than all values, use last interval
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else if (value >= values.back()) {
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retval.ind_[0] = nvalues-2;
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retval.ind_[1] = nvalues-1;
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}
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else {
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//Search internal intervals
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for (int i=1; i<nvalues; ++i) {
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if (values[i] >= value) {
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retval.ind_[0] = i-1;
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retval.ind_[1] = i;
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break;
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}
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}
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}
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const double start = values[retval.ind_[0]];
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const double end = values[retval.ind_[1]];
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//Find interpolation ratio
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if (end > start) {
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//FIXME: Possible source for floating point error here if value and floor are large,
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//but very close to each other
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retval.inv_dist_ = 1.0 / (end-start);
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retval.factor_ = (value-start) * retval.inv_dist_;
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}
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else {
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retval.inv_dist_ = 0.0;
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retval.factor_ = 0.0;
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}
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}
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// Disallow extrapolation with higher factor than 3.0.
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// The factor 3.0 has been chosen because it works well
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// with certain testcases, and may not be optimal.
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if (retval.factor_ > 3.0) {
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retval.factor_ = 3.0;
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}
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return retval;
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}
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VFPEvaluation operator+(VFPEvaluation lhs, const VFPEvaluation& rhs)
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{
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lhs.value += rhs.value;
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lhs.dthp += rhs.dthp;
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lhs.dwfr += rhs.dwfr;
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lhs.dgfr += rhs.dgfr;
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lhs.dalq += rhs.dalq;
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lhs.dflo += rhs.dflo;
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return lhs;
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}
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VFPEvaluation operator-(VFPEvaluation lhs, const VFPEvaluation& rhs)
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{
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lhs.value -= rhs.value;
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lhs.dthp -= rhs.dthp;
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lhs.dwfr -= rhs.dwfr;
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lhs.dgfr -= rhs.dgfr;
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lhs.dalq -= rhs.dalq;
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lhs.dflo -= rhs.dflo;
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return lhs;
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}
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VFPEvaluation operator*(double lhs, const VFPEvaluation& rhs)
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{
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VFPEvaluation retval;
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retval.value = rhs.value * lhs;
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retval.dthp = rhs.dthp * lhs;
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retval.dwfr = rhs.dwfr * lhs;
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retval.dgfr = rhs.dgfr * lhs;
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retval.dalq = rhs.dalq * lhs;
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retval.dflo = rhs.dflo * lhs;
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return retval;
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}
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VFPEvaluation interpolate(const VFPProdTable& table,
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const InterpData& flo_i,
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const InterpData& thp_i,
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const InterpData& wfr_i,
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const InterpData& gfr_i,
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const InterpData& alq_i)
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{
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//Values and derivatives in a 5D hypercube
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VFPEvaluation nn[2][2][2][2][2];
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//Pick out nearest neighbors (nn) to our evaluation point
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//This is not really required, but performance-wise it may pay off, since the 32-elements
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//we copy to (nn) will fit better in cache than the full original table for the
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//interpolation below.
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//The following ladder of for loops will presumably be unrolled by a reasonable compiler.
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for (int t=0; t<=1; ++t) {
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for (int w=0; w<=1; ++w) {
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for (int g=0; g<=1; ++g) {
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for (int a=0; a<=1; ++a) {
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for (int f=0; f<=1; ++f) {
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//Shorthands for indexing
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const int ti = thp_i.ind_[t];
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const int wi = wfr_i.ind_[w];
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const int gi = gfr_i.ind_[g];
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const int ai = alq_i.ind_[a];
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const int fi = flo_i.ind_[f];
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//Copy element
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nn[t][w][g][a][f].value = table(ti,wi,gi,ai,fi);
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}
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}
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}
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}
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}
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//Calculate derivatives
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//Note that the derivative of the two end points of a line aligned with the
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//"axis of the derivative" are equal
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for (int i=0; i<=1; ++i) {
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for (int j=0; j<=1; ++j) {
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for (int k=0; k<=1; ++k) {
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for (int l=0; l<=1; ++l) {
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nn[0][i][j][k][l].dthp = (nn[1][i][j][k][l].value - nn[0][i][j][k][l].value) * thp_i.inv_dist_;
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nn[i][0][j][k][l].dwfr = (nn[i][1][j][k][l].value - nn[i][0][j][k][l].value) * wfr_i.inv_dist_;
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nn[i][j][0][k][l].dgfr = (nn[i][j][1][k][l].value - nn[i][j][0][k][l].value) * gfr_i.inv_dist_;
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nn[i][j][k][0][l].dalq = (nn[i][j][k][1][l].value - nn[i][j][k][0][l].value) * alq_i.inv_dist_;
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nn[i][j][k][l][0].dflo = (nn[i][j][k][l][1].value - nn[i][j][k][l][0].value) * flo_i.inv_dist_;
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nn[1][i][j][k][l].dthp = nn[0][i][j][k][l].dthp;
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nn[i][1][j][k][l].dwfr = nn[i][0][j][k][l].dwfr;
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nn[i][j][1][k][l].dgfr = nn[i][j][0][k][l].dgfr;
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nn[i][j][k][1][l].dalq = nn[i][j][k][0][l].dalq;
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nn[i][j][k][l][1].dflo = nn[i][j][k][l][0].dflo;
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}
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}
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}
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}
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double t1, t2; //interpolation variables, so that t1 = (1-t) and t2 = t.
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// Remove dimensions one by one
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// Example: going from 3D to 2D to 1D, we start by interpolating along
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// the z axis first, leaving a 2D problem. Then interpolating along the y
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// axis, leaving a 1D, problem, etc.
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t2 = flo_i.factor_;
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t1 = (1.0-t2);
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for (int t=0; t<=1; ++t) {
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for (int w=0; w<=1; ++w) {
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for (int g=0; g<=1; ++g) {
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for (int a=0; a<=1; ++a) {
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nn[t][w][g][a][0] = t1*nn[t][w][g][a][0] + t2*nn[t][w][g][a][1];
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}
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}
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}
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}
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t2 = alq_i.factor_;
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t1 = (1.0-t2);
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for (int t=0; t<=1; ++t) {
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for (int w=0; w<=1; ++w) {
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for (int g=0; g<=1; ++g) {
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nn[t][w][g][0][0] = t1*nn[t][w][g][0][0] + t2*nn[t][w][g][1][0];
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}
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}
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}
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t2 = gfr_i.factor_;
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t1 = (1.0-t2);
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for (int t=0; t<=1; ++t) {
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for (int w=0; w<=1; ++w) {
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nn[t][w][0][0][0] = t1*nn[t][w][0][0][0] + t2*nn[t][w][1][0][0];
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}
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}
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t2 = wfr_i.factor_;
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t1 = (1.0-t2);
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for (int t=0; t<=1; ++t) {
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nn[t][0][0][0][0] = t1*nn[t][0][0][0][0] + t2*nn[t][1][0][0][0];
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}
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t2 = thp_i.factor_;
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t1 = (1.0-t2);
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nn[0][0][0][0][0] = t1*nn[0][0][0][0][0] + t2*nn[1][0][0][0][0];
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return nn[0][0][0][0][0];
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}
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VFPEvaluation interpolate(const VFPInjTable& table,
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const InterpData& flo_i,
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const InterpData& thp_i)
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{
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//Values and derivatives in a 2D plane
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VFPEvaluation nn[2][2];
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//Pick out nearest neighbors (nn) to our evaluation point
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//The following ladder of for loops will presumably be unrolled by a reasonable compiler.
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for (int t=0; t<=1; ++t) {
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for (int f=0; f<=1; ++f) {
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//Shorthands for indexing
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const int ti = thp_i.ind_[t];
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const int fi = flo_i.ind_[f];
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//Copy element
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nn[t][f].value = table(ti,fi);
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}
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}
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//Calculate derivatives
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//Note that the derivative of the two end points of a line aligned with the
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//"axis of the derivative" are equal
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for (int i=0; i<=1; ++i) {
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nn[0][i].dthp = (nn[1][i].value - nn[0][i].value) * thp_i.inv_dist_;
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nn[i][0].dwfr = -1e100;
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nn[i][0].dgfr = -1e100;
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nn[i][0].dalq = -1e100;
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nn[i][0].dflo = (nn[i][1].value - nn[i][0].value) * flo_i.inv_dist_;
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nn[1][i].dthp = nn[0][i].dthp;
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nn[i][1].dwfr = nn[i][0].dwfr;
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nn[i][1].dgfr = nn[i][0].dgfr;
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nn[i][1].dalq = nn[i][0].dalq;
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nn[i][1].dflo = nn[i][0].dflo;
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}
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double t1, t2; //interpolation variables, so that t1 = (1-t) and t2 = t.
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// Go from 2D to 1D
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t2 = flo_i.factor_;
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t1 = (1.0-t2);
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nn[0][0] = t1*nn[0][0] + t2*nn[0][1];
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nn[1][0] = t1*nn[1][0] + t2*nn[1][1];
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// Go from line to point on line
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t2 = thp_i.factor_;
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t1 = (1.0-t2);
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nn[0][0] = t1*nn[0][0] + t2*nn[1][0];
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return nn[0][0];
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}
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VFPEvaluation bhp(const VFPProdTable& table,
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const double aqua,
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const double liquid,
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const double vapour,
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const double thp,
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const double alq)
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{
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//Find interpolation variables
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double flo = detail::getFlo(table, aqua, liquid, vapour);
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double wfr = detail::getWFR(table, aqua, liquid, vapour);
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double gfr = detail::getGFR(table, aqua, liquid, vapour);
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//First, find the values to interpolate between
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//Recall that flo is negative in Opm, so switch sign.
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auto flo_i = detail::findInterpData(-flo, table.getFloAxis());
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auto thp_i = detail::findInterpData( thp, table.getTHPAxis());
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auto wfr_i = detail::findInterpData( wfr, table.getWFRAxis());
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auto gfr_i = detail::findInterpData( gfr, table.getGFRAxis());
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auto alq_i = detail::findInterpData( alq, table.getALQAxis());
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detail::VFPEvaluation retval = detail::interpolate(table, flo_i, thp_i, wfr_i, gfr_i, alq_i);
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return retval;
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}
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VFPEvaluation bhp(const VFPInjTable& table,
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const double aqua,
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const double liquid,
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const double vapour,
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const double thp)
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{
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//Find interpolation variables
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double flo = detail::getFlo(table, aqua, liquid, vapour);
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//First, find the values to interpolate between
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auto flo_i = detail::findInterpData(flo, table.getFloAxis());
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auto thp_i = detail::findInterpData(thp, table.getTHPAxis());
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//Then perform the interpolation itself
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detail::VFPEvaluation retval = detail::interpolate(table, flo_i, thp_i);
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return retval;
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}
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double findTHP(const std::vector<double>& bhp_array,
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const std::vector<double>& thp_array,
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double bhp)
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{
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int nthp = thp_array.size();
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double thp = -1e100;
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//Check that our thp axis is sorted
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assert(std::is_sorted(thp_array.begin(), thp_array.end()));
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/**
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* Our *interpolated* bhp_array will be montonic increasing for increasing
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* THP if our input BHP values are monotonic increasing for increasing
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* THP values. However, if we have to *extrapolate* along any of the other
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* axes, this guarantee holds no more, and bhp_array may be "random"
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*/
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if (std::is_sorted(bhp_array.begin(), bhp_array.end())) {
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//Target bhp less than all values in array, extrapolate
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if (bhp <= bhp_array[0]) {
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//TODO: LOG extrapolation
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const double& x0 = thp_array[0];
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const double& x1 = thp_array[1];
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const double& y0 = bhp_array[0];
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const double& y1 = bhp_array[1];
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thp = findX(x0, x1, y0, y1, bhp);
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}
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//Target bhp greater than all values in array, extrapolate
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else if (bhp > bhp_array[nthp-1]) {
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//TODO: LOG extrapolation
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const double& x0 = thp_array[nthp-2];
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const double& x1 = thp_array[nthp-1];
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const double& y0 = bhp_array[nthp-2];
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const double& y1 = bhp_array[nthp-1];
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thp = findX(x0, x1, y0, y1, bhp);
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}
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//Target bhp within table ranges, interpolate
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else {
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//Loop over the values and find min(bhp_array(thp)) == bhp
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//so that we maximize the rate.
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//Find i so that bhp_array[i-1] <= bhp <= bhp_array[i];
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//Assuming a small number of values in bhp_array, this should be quite
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//efficient. Other strategies might be bisection, etc.
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int i=0;
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bool found = false;
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for (; i<nthp-1; ++i) {
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const double& y0 = bhp_array[i ];
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const double& y1 = bhp_array[i+1];
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if (y0 < bhp && bhp <= y1) {
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found = true;
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break;
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}
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}
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//Canary in a coal mine: shouldn't really be required
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assert(found == true);
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static_cast<void>(found); //Silence compiler warning
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const double& x0 = thp_array[i ];
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const double& x1 = thp_array[i+1];
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const double& y0 = bhp_array[i ];
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const double& y1 = bhp_array[i+1];
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thp = findX(x0, x1, y0, y1, bhp);
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}
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}
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//bhp_array not sorted, raw search.
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else {
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//Find i so that bhp_array[i-1] <= bhp <= bhp_array[i];
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//Since the BHP values might not be sorted, first search within
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//our interpolation values, and then try to extrapolate.
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int i=0;
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bool found = false;
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for (; i<nthp-1; ++i) {
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const double& y0 = bhp_array[i ];
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const double& y1 = bhp_array[i+1];
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|
|
if (y0 < bhp && bhp <= y1) {
|
|
found = true;
|
|
break;
|
|
}
|
|
}
|
|
if (found) {
|
|
const double& x0 = thp_array[i ];
|
|
const double& x1 = thp_array[i+1];
|
|
const double& y0 = bhp_array[i ];
|
|
const double& y1 = bhp_array[i+1];
|
|
thp = findX(x0, x1, y0, y1, bhp);
|
|
}
|
|
else if (bhp <= bhp_array[0]) {
|
|
//TODO: LOG extrapolation
|
|
const double& x0 = thp_array[0];
|
|
const double& x1 = thp_array[1];
|
|
const double& y0 = bhp_array[0];
|
|
const double& y1 = bhp_array[1];
|
|
thp = findX(x0, x1, y0, y1, bhp);
|
|
}
|
|
//Target bhp greater than all values in array, extrapolate
|
|
else if (bhp > bhp_array[nthp-1]) {
|
|
//TODO: LOG extrapolation
|
|
const double& x0 = thp_array[nthp-2];
|
|
const double& x1 = thp_array[nthp-1];
|
|
const double& y0 = bhp_array[nthp-2];
|
|
const double& y1 = bhp_array[nthp-1];
|
|
thp = findX(x0, x1, y0, y1, bhp);
|
|
}
|
|
else {
|
|
OPM_THROW(std::logic_error, "Programmer error: Unable to find THP in THP array");
|
|
}
|
|
}
|
|
|
|
return thp;
|
|
}
|
|
|
|
template <typename T>
|
|
T getFlo(const VFPProdTable& table,
|
|
const T& aqua,
|
|
const T& liquid,
|
|
const T& vapour)
|
|
{
|
|
auto type = table.getFloType();
|
|
switch (type) {
|
|
case VFPProdTable::FLO_TYPE::FLO_OIL:
|
|
//Oil = liquid phase
|
|
return liquid;
|
|
case VFPProdTable::FLO_TYPE::FLO_LIQ:
|
|
//Liquid = aqua + liquid phases
|
|
return aqua + liquid;
|
|
case VFPProdTable::FLO_TYPE::FLO_GAS:
|
|
//Gas = vapor phase
|
|
return vapour;
|
|
default:
|
|
throw std::logic_error("Invalid FLO_TYPE");
|
|
}
|
|
}
|
|
|
|
template <typename T>
|
|
T getFlo(const VFPInjTable& table,
|
|
const T& aqua,
|
|
const T& liquid,
|
|
const T& vapour)
|
|
{
|
|
auto type = table.getFloType();
|
|
switch (type) {
|
|
case VFPInjTable::FLO_TYPE::FLO_OIL:
|
|
//Oil = liquid phase
|
|
return liquid;
|
|
case VFPInjTable::FLO_TYPE::FLO_WAT:
|
|
//Liquid = aqua phase
|
|
return aqua;
|
|
case VFPInjTable::FLO_TYPE::FLO_GAS:
|
|
//Gas = vapor phase
|
|
return vapour;
|
|
default:
|
|
throw std::logic_error("Invalid FLO_TYPE");
|
|
}
|
|
}
|
|
|
|
static constexpr double threshold = 1e-12;
|
|
|
|
template <typename T>
|
|
T getWFR(const VFPProdTable& table,
|
|
const T& aqua,
|
|
const T& liquid,
|
|
const T& vapour)
|
|
{
|
|
auto type = table.getWFRType();
|
|
switch(type) {
|
|
case VFPProdTable::WFR_TYPE::WFR_WOR: {
|
|
//Water-oil ratio = water / oil
|
|
return chopNegativeValues(-aqua) / max(threshold, chopNegativeValues(-liquid));
|
|
}
|
|
case VFPProdTable::WFR_TYPE::WFR_WCT:
|
|
//Water cut = water / (water + oil)
|
|
return chopNegativeValues(-aqua) / max(threshold, chopNegativeValues(-aqua - liquid));
|
|
case VFPProdTable::WFR_TYPE::WFR_WGR:
|
|
//Water-gas ratio = water / gas
|
|
return chopNegativeValues(-aqua) / max(threshold, chopNegativeValues(-vapour));
|
|
default:
|
|
throw std::logic_error("Invalid WFR_TYPE");
|
|
}
|
|
}
|
|
|
|
template <typename T>
|
|
T getGFR(const VFPProdTable& table,
|
|
const T& aqua,
|
|
const T& liquid,
|
|
const T& vapour)
|
|
{
|
|
auto type = table.getGFRType();
|
|
switch(type) {
|
|
case VFPProdTable::GFR_TYPE::GFR_GOR:
|
|
// Gas-oil ratio = gas / oil
|
|
return chopNegativeValues(-vapour) / max(threshold, chopNegativeValues(-liquid));
|
|
case VFPProdTable::GFR_TYPE::GFR_GLR:
|
|
// Gas-liquid ratio = gas / (oil + water)
|
|
return chopNegativeValues(-vapour) / max(threshold, chopNegativeValues(-liquid - aqua));
|
|
case VFPProdTable::GFR_TYPE::GFR_OGR:
|
|
// Oil-gas ratio = oil / gas
|
|
return chopNegativeValues(-liquid) / max(threshold, chopNegativeValues(-vapour));
|
|
default:
|
|
throw std::logic_error("Invalid GFR_TYPE");
|
|
}
|
|
}
|
|
|
|
template <typename T>
|
|
const T& getTable(const std::map<int, std::reference_wrapper<const T>>& tables, int table_id)
|
|
{
|
|
auto entry = tables.find(table_id);
|
|
if (entry == tables.end()) {
|
|
OPM_THROW(std::invalid_argument, "Nonexistent VFP table " << table_id << " referenced.");
|
|
}
|
|
else {
|
|
return entry->second.get();
|
|
}
|
|
}
|
|
|
|
template <>
|
|
VFPProdTable::FLO_TYPE getType(const VFPProdTable& table)
|
|
{
|
|
return table.getFloType();
|
|
}
|
|
|
|
template <>
|
|
VFPProdTable::WFR_TYPE getType(const VFPProdTable& table)
|
|
{
|
|
return table.getWFRType();
|
|
}
|
|
|
|
template <>
|
|
VFPProdTable::GFR_TYPE getType(const VFPProdTable& table)
|
|
{
|
|
return table.getGFRType();
|
|
}
|
|
|
|
/**
|
|
* Returns the type variable for FLO for injection tables
|
|
*/
|
|
template <>
|
|
VFPInjTable::FLO_TYPE getType(const VFPInjTable& table)
|
|
{
|
|
return table.getFloType();
|
|
}
|
|
|
|
template const VFPInjTable& getTable<VFPInjTable>(const std::map<int, std::reference_wrapper<const VFPInjTable>>&, int);
|
|
template const VFPProdTable& getTable<VFPProdTable>(const std::map<int, std::reference_wrapper<const VFPProdTable>>&, int);
|
|
|
|
#define INSTANCE(...) \
|
|
template __VA_ARGS__ getFlo(const VFPInjTable&, const __VA_ARGS__&, const __VA_ARGS__&, const __VA_ARGS__&); \
|
|
template __VA_ARGS__ getFlo(const VFPProdTable&, const __VA_ARGS__&, const __VA_ARGS__&, const __VA_ARGS__&); \
|
|
template __VA_ARGS__ getGFR(const VFPProdTable&, const __VA_ARGS__&, const __VA_ARGS__&, const __VA_ARGS__&); \
|
|
template __VA_ARGS__ getWFR(const VFPProdTable&, const __VA_ARGS__&, const __VA_ARGS__&, const __VA_ARGS__&);
|
|
|
|
INSTANCE(double)
|
|
INSTANCE(DenseAd::Evaluation<double, -1, 4u>)
|
|
INSTANCE(DenseAd::Evaluation<double, -1, 5u>)
|
|
INSTANCE(DenseAd::Evaluation<double, -1, 6u>)
|
|
INSTANCE(DenseAd::Evaluation<double, -1, 7u>)
|
|
INSTANCE(DenseAd::Evaluation<double, -1, 8u>)
|
|
INSTANCE(DenseAd::Evaluation<double, -1, 9u>)
|
|
INSTANCE(DenseAd::Evaluation<double, -1, 10u>)
|
|
INSTANCE(DenseAd::Evaluation<double, 3, 0u>)
|
|
INSTANCE(DenseAd::Evaluation<double, 4, 0u>)
|
|
INSTANCE(DenseAd::Evaluation<double, 5, 0u>)
|
|
INSTANCE(DenseAd::Evaluation<double, 6, 0u>)
|
|
INSTANCE(DenseAd::Evaluation<double, 7, 0u>)
|
|
INSTANCE(DenseAd::Evaluation<double, 8, 0u>)
|
|
INSTANCE(DenseAd::Evaluation<double, 9, 0u>)
|
|
|
|
|
|
} // namespace detail
|
|
} // namespace Opm
|