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Updated VFPProperties to use the newly implemented VFPProdTable class in opm-parser (with units)

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This commit is contained in:
André R. Brodtkorb
2015-06-25 16:30:46 +02:00
committed by babrodtk
parent 1d7f601fab
commit 179a210ad5
3 changed files with 165 additions and 638 deletions
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356
opm/autodiff/VFPProperties.cpp
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@@ -19,317 +19,31 @@
#include "config.h"
#include <opm/autodiff/VFPProperties.hpp>
#include <opm/autodiff/AutoDiffHelpers.hpp>
#include <opm/core/props/BlackoilPhases.hpp>
#include <opm/core/utility/ErrorMacros.hpp>
#include <algorithm>
namespace Opm {
/**
* Helper function that checks if an item exists in a record, and has a
* non-zero size
*/
bool itemValid(DeckRecordConstPtr& record, const char* name) {
if (record->size() == 0) {
return false;
}
else {
DeckItemPtr item;
//TODO: Should we instead here allow the exception to propagate?
try {
item = record->getItem(name);
}
catch (...) {
return false;
}
if (item->size() > 0) {
return true;
}
else {
return false;
}
}
VFPProperties::VFPProperties(VFPProdTable* table) : table_(table) {
}
VFPProperties::VFPProperties(DeckKeywordConstPtr table) {
auto iter = table->begin();
auto header = (*iter++);
assert(itemValid(header, "TABLE"));
table_num_ = header->getItem("TABLE")->getInt(0);
assert(itemValid(header, "DATUM_DEPTH"));
datum_depth_ = header->getItem("DATUM_DEPTH")->getRawDouble(0);
//Rate type
assert(itemValid(header, "RATE_TYPE"));
std::string flo_string = header->getItem("RATE_TYPE")->getString(0);
if (flo_string == "OIL") {
flo_type_ = FLO_OIL;
}
else if (flo_string == "LIQ") {
flo_type_ = FLO_LIQ;
}
else if (flo_string == "GAS") {
flo_type_ = FLO_GAS;
}
else {
flo_type_ = FLO_INVALID;
OPM_THROW(std::runtime_error, "Invalid RATE_TYPE string: '" << flo_string << "'");
}
//Water fraction
assert(itemValid(header, "WFR"));
std::string wfr_string = header->getItem("WFR")->getString(0);
if (wfr_string == "WOR") {
wfr_type_ = WFR_WOR;
}
else if (wfr_string == "WCT") {
wfr_type_ = WFR_WCT;
}
else if (wfr_string == "WGR") {
wfr_type_ = WFR_WGR;
}
else {
wfr_type_ = WFR_INVALID;
OPM_THROW(std::runtime_error, "Invalid WFR string: '" << wfr_string << "'");
}
//Gas fraction
assert(itemValid(header, "GFR"));
std::string gfr_string = header->getItem("GFR")->getString(0);
if (gfr_string == "GOR") {
gfr_type_ = GFR_GOR;
}
else if (gfr_string == "GLR") {
gfr_type_ = GFR_GLR;
}
else if (gfr_string == "OGR") {
gfr_type_ = GFR_OGR;
}
else {
gfr_type_ = GFR_INVALID;
OPM_THROW(std::runtime_error, "Invalid GFR string: '" << gfr_string << "'");
}
//Definition of THP values, must be THP
if (itemValid(header, "PRESSURE_DEF")) {
std::string quantity_string = header->getItem("PRESSURE_DEF")->getString(0);
assert(quantity_string == "THP");
}
//Artificial lift
if (itemValid(header, "ALQ_DEF")) {
std::string alq_string = header->getItem("ALQ_DEF")->getString(0);
if (alq_string == "GRAT") {
alq_type_ = ALQ_GRAT;
}
else if (alq_string == "IGLR") {
alq_type_ = ALQ_IGLR;
}
else if (alq_string == "TGLR") {
alq_type_ = ALQ_TGLR;
}
else if (alq_string == "PUMP") {
alq_type_ = ALQ_PUMP;
}
else if (alq_string == "COMP") {
alq_type_ = ALQ_COMP;
}
else if (alq_string == "BEAN") {
alq_type_ = ALQ_BEAN;
}
else if (alq_string == "UNDEF") {
alq_type_ = ALQ_UNDEF;
}
else {
alq_type_ = ALQ_INVALID;
OPM_THROW(std::runtime_error, "Invalid ALQ_DEF string: '" << alq_string << "'");
}
}
else {
alq_type_ = ALQ_UNDEF;
}
//Units used for this table
if (itemValid(header, "UNITS")) {
//TODO: Should check that table unit matches rest of deck.
std::string unit_string = header->getItem("UNITS")->getString(0);
if (unit_string == "METRIC") {
}
else if (unit_string == "FIELD") {
}
else if (unit_string == "LAB") {
}
else if (unit_string == "PVT-M") {
}
else {
OPM_THROW(std::runtime_error, "Invalid UNITS string: '" << unit_string << "'");
}
}
else {
//Do nothing, table implicitly same unit as rest of deck
}
//Quantity in the body of the table
if (itemValid(header, "BODY_DEF")) {
std::string body_string = header->getItem("BODY_DEF")->getString(0);
if (body_string == "TEMP") {
OPM_THROW(std::logic_error, "Invalid BODY_DEF string: TEMP not supported");
}
else if (body_string == "BHP") {
}
else {
OPM_THROW(std::runtime_error, "Invalid BODY_DEF string: '" << body_string << "'");
}
}
else {
//Default to BHP
}
//Get actual rate / flow values
flo_data_ = (*iter++)->getItem("FLOW_VALUES")->getSIDoubleData();
//Get actual tubing head pressure values
thp_data_ = (*iter++)->getItem("THP_VALUES")->getSIDoubleData();
//Get actual water fraction values
wfr_data_ = (*iter++)->getItem("WFR_VALUES")->getRawDoubleData(); //FIXME: unit
//Get actual gas fraction values
gfr_data_ = (*iter++)->getItem("GFR_VALUES")->getRawDoubleData(); //FIXME: unit
//Get actual gas fraction values
alq_data_ = (*iter++)->getItem("ALQ_VALUES")->getRawDoubleData(); //FIXME: unit
//Finally, read the actual table itself.
size_t nt = thp_data_.size();
size_t nw = wfr_data_.size();
size_t ng = gfr_data_.size();
size_t na = alq_data_.size();
size_t nf = flo_data_.size();
extents shape;
shape[0] = nt;
shape[1] = nw;
shape[2] = ng;
shape[3] = na;
shape[4] = nf;
data_.resize(shape);
for (; iter!=table->end(); ++iter) {
//Get indices (subtract 1 to get 0-based index)
int t = (*iter)->getItem("THP_INDEX")->getInt(0) - 1;
int w = (*iter)->getItem("WFR_INDEX")->getInt(0) - 1;
int g = (*iter)->getItem("GFR_INDEX")->getInt(0) - 1;
int a = (*iter)->getItem("ALQ_INDEX")->getInt(0) - 1;
//Rest of values (bottom hole pressure or tubing head temperature) have index of flo value
const std::vector<double>& bhp_tht = (*iter)->getItem("VALUES")->getRawDoubleData(); //FIXME: unit
std::copy(bhp_tht.begin(), bhp_tht.end(), &data_[t][w][g][a][0]);
}
check();
}
VFPProperties::VFPProperties(int table_num,
double datum_depth,
FLO_TYPE flo_type,
WFR_TYPE wfr_type,
GFR_TYPE gfr_type,
ALQ_TYPE alq_type,
const std::vector<double>& flo_data,
const std::vector<double>& thp_data,
const std::vector<double>& wfr_data,
const std::vector<double>& gfr_data,
const std::vector<double>& alq_data,
array_type data
) :
table_num_(table_num),
datum_depth_(datum_depth),
flo_type_(flo_type),
wfr_type_(wfr_type),
gfr_type_(gfr_type),
alq_type_(alq_type),
flo_data_(flo_data),
thp_data_(thp_data),
wfr_data_(wfr_data),
gfr_data_(gfr_data),
alq_data_(alq_data),
data_(data) {
check();
}
void VFPProperties::check() {
//Table number
assert(table_num_ > 0);
//Misc types
assert(flo_type_ >= FLO_OIL && flo_type_ < FLO_INVALID);
assert(wfr_type_ >= WFR_WOR && wfr_type_ < WFR_INVALID);
assert(gfr_type_ >= GFR_GOR && gfr_type_ < GFR_INVALID);
assert(alq_type_ >= ALQ_GRAT && alq_type_ < ALQ_INVALID);
//Data axis size
assert(flo_data_.size() > 0);
assert(thp_data_.size() > 0);
assert(wfr_data_.size() > 0);
assert(gfr_data_.size() > 0);
assert(alq_data_.size() > 0);
//Data axis sorted?
assert(is_sorted(flo_data_.begin(), flo_data_.end()));
assert(is_sorted(thp_data_.begin(), thp_data_.end()));
assert(is_sorted(wfr_data_.begin(), wfr_data_.end()));
assert(is_sorted(gfr_data_.begin(), gfr_data_.end()));
assert(is_sorted(alq_data_.begin(), alq_data_.end()));
//Check data size matches axes
assert(data_.num_dimensions() == 5);
assert(data_.shape()[0] == thp_data_.size());
assert(data_.shape()[1] == wfr_data_.size());
assert(data_.shape()[2] == gfr_data_.size());
assert(data_.shape()[3] == alq_data_.size());
assert(data_.shape()[4] == flo_data_.size());
//Finally, check that all data is within reasonable ranges, defined to be up-to 1.0e10...
typedef array_type::size_type size_type;
for (size_type t=0; t<data_.shape()[0]; ++t) {
for (size_type w=0; w<data_.shape()[1]; ++w) {
for (size_type g=0; g<data_.shape()[2]; ++g) {
for (size_type a=0; a<data_.shape()[3]; ++a) {
for (size_type f=0; f<data_.shape()[4]; ++f) {
if (data_[t][w][g][a][f] > 1.0e10) {
//TODO: Replace with proper log message
std::cerr << "Too large value encountered in VFPPROD in ["
<< t << "," << w << "," << g << "," << a << "," << f << "]="
<< data_[t][w][g][a][f] << std::endl;
}
}
}
}
}
}
}
double VFPProperties::bhp(const double& flo, const double& thp, const double& wfr, const double& gfr, const double& alq) {
//First, find the values to interpolate between
auto flo_i = find_interp_data(flo, flo_data_);
auto thp_i = find_interp_data(thp, thp_data_);
auto wfr_i = find_interp_data(wfr, wfr_data_);
auto gfr_i = find_interp_data(gfr, gfr_data_);
auto alq_i = find_interp_data(alq, alq_data_);
auto flo_i = find_interp_data(flo, table_->getFloAxis());
auto thp_i = find_interp_data(thp, table_->getTHPAxis());
auto wfr_i = find_interp_data(wfr, table_->getWFRAxis());
auto gfr_i = find_interp_data(gfr, table_->getGFRAxis());
auto alq_i = find_interp_data(alq, table_->getALQAxis());
//Then perform the interpolation itself
return interpolate(flo_i, thp_i, wfr_i, gfr_i, alq_i);
@@ -367,9 +81,9 @@ VFPProperties::ADB VFPProperties::bhp(const Wells& wells, const ADB& qs, const A
const ADB& o = subset(qs, Span(nw, 1, BlackoilPhases::Liquid*nw));
const ADB& g = subset(qs, Span(nw, 1, BlackoilPhases::Vapour*nw));
ADB flo = getFlo(w, o, g);
ADB wfr = getWFR(w, o, g);
ADB gfr = getGFR(w, o, g);
ADB flo = getFlo(w, o, g, table_->getFloType());
ADB wfr = getWFR(w, o, g, table_->getWFRType());
ADB gfr = getGFR(w, o, g, table_->getGFRType());
//TODO: Check ALQ type here?
@@ -377,57 +91,60 @@ VFPProperties::ADB VFPProperties::bhp(const Wells& wells, const ADB& qs, const A
}
VFPProperties::ADB VFPProperties::getFlo(const ADB& aqua, const ADB& liquid, const ADB& vapour) {
switch (flo_type_) {
case FLO_OIL:
VFPProperties::ADB VFPProperties::getFlo(const ADB& aqua, const ADB& liquid, const ADB& vapour,
const VFPProdTable::FLO_TYPE& type) {
switch (type) {
case VFPProdTable::FLO_OIL:
//Oil = liquid phase
return liquid;
case FLO_LIQ:
case VFPProdTable::FLO_LIQ:
//Liquid = aqua + liquid phases
return aqua + liquid;
case FLO_GAS:
case VFPProdTable::FLO_GAS:
//Gas = vapor phase
return vapour;
case FLO_INVALID: //Intentional fall-through
case VFPProdTable::FLO_INVALID: //Intentional fall-through
default:
OPM_THROW(std::logic_error, "Invalid FLO_TYPE: '" << flo_type_ << "'");
OPM_THROW(std::logic_error, "Invalid FLO_TYPE: '" << type << "'");
return ADB::null();
}
}
VFPProperties::ADB VFPProperties::getWFR(const ADB& aqua, const ADB& liquid, const ADB& vapour) {
switch(wfr_type_) {
case WFR_WOR:
VFPProperties::ADB VFPProperties::getWFR(const ADB& aqua, const ADB& liquid, const ADB& vapour,
const VFPProdTable::WFR_TYPE& type) {
switch(type) {
case VFPProdTable::WFR_WOR:
//Water-oil ratio = water / oil
return aqua / liquid;
case WFR_WCT:
case VFPProdTable::WFR_WCT:
//Water cut = water / (water + oil + gas)
return aqua / (aqua + liquid + vapour);
case WFR_WGR:
case VFPProdTable::WFR_WGR:
//Water-gas ratio = water / gas
return aqua / vapour;
case WFR_INVALID: //Intentional fall-through
case VFPProdTable::WFR_INVALID: //Intentional fall-through
default:
OPM_THROW(std::logic_error, "Invalid WFR_TYPE: '" << wfr_type_ << "'");
OPM_THROW(std::logic_error, "Invalid WFR_TYPE: '" << type << "'");
return ADB::null();
}
}
VFPProperties::ADB VFPProperties::getGFR(const ADB& aqua, const ADB& liquid, const ADB& vapour) {
switch(gfr_type_) {
case GFR_GOR:
VFPProperties::ADB VFPProperties::getGFR(const ADB& aqua, const ADB& liquid, const ADB& vapour,
const VFPProdTable::GFR_TYPE& type) {
switch(type) {
case VFPProdTable::GFR_GOR:
// Gas-oil ratio = gas / oil
return vapour / liquid;
case GFR_GLR:
case VFPProdTable::GFR_GLR:
// Gas-liquid ratio = gas / (oil + water)
return vapour / (liquid + aqua);
case GFR_OGR:
case VFPProdTable::GFR_OGR:
// Oil-gas ratio = oil / gas
return liquid / vapour;
case GFR_INVALID: //Intentional fall-through
case VFPProdTable::GFR_INVALID: //Intentional fall-through
default:
OPM_THROW(std::logic_error, "Invalid GFR_TYPE: '" << flo_type_ << "'");
OPM_THROW(std::logic_error, "Invalid GFR_TYPE: '" << type << "'");
return ADB::null();
}
}
@@ -483,6 +200,7 @@ double VFPProperties::interpolate(const InterpData& flo_i, const InterpData& thp
//we copy to (nn) will fit better in cache than the full original table for the
//interpolation below.
//The following ladder of for loops will presumably be unrolled by a reasonable compiler.
const VFPProdTable::array_type& data = table_->getTable();
for (int t=0; t<=1; ++t) {
for (int w=0; w<=1; ++w) {
for (int g=0; g<=1; ++g) {
@@ -496,7 +214,7 @@ double VFPProperties::interpolate(const InterpData& flo_i, const InterpData& thp
const int fi = flo_i.ind_[f];
//Copy element
nn[t][w][g][a][f] = data_[ti][wi][gi][ai][fi];
nn[t][w][g][a][f] = data[ti][wi][gi][ai][fi];
}
}
}