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goncalvesmachadoc 2019-10-26 13:13:44 +02:00
parent 958e0e6a62
commit 18b5ad2bf8
2 changed files with 520 additions and 4 deletions
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517
ebos/ecloutputblackoilmodule.hh
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@ -2,20 +2,16 @@
// vi: set et ts=4 sw=4 sts=4:
/*
This file is part of the Open Porous Media project (OPM).
OPM is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 2 of the License, or
(at your option) any later version.
OPM is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OPM. If not, see <http://www.gnu.org/licenses/>.
Consult the COPYING file in the top-level source directory of this
module for the precise wording of the license and the list of
copyright holders.
@ -92,6 +88,7 @@ class EclOutputBlackOilModule
enum { enableEnergy = GET_PROP_VALUE(TypeTag, EnableEnergy) };
typedef std::vector<Scalar> ScalarBuffer;
typedef std::vector<std::string> StringBuffer;
struct FipDataType
{
@ -108,6 +105,70 @@ class EclOutputBlackOilModule
};
static const int numFipValues = PoreVolume + 1 ;
};
struct WellProdDataType
{
enum WPId
{
WellLocationi = 0, //WLi
WellLocationj = 1, //WLj
OilRate = 2, //OR
WaterRate = 3, //WR
GasRate = 4, //GR
FluidResVol = 5, //FRV
WaterCut = 6, //WC
GasOilRatio = 7, //GOR
WatGasRatio = 8, //WGR
BHP = 9, //BHP
THP = 10, //THP
SteadyStatePI = 11, //SteadyStatePI
WellName = 0, //WName
CTRLMode = 1, //CTRL
};
static const int numWPValues = 12;
static const int numWPNames = 2;
};
struct WellInjDataType
{
enum WIId
{
WellLocationi = 0, //WLi
WellLocationj = 1, //WLj
OilRate = 2, //OR
WaterRate = 3, //WR
GasRate = 4, //GR
FluidResVol = 5, //FRV
BHP = 6, //BHP
THP = 7, //THP
SteadyStateII = 8, //SteadyStateII
WellName = 0, //WName
CTRLModeOil = 1, //CTRLo
CTRLModeWat = 2, //CTRLw
CTRLModeGas = 3, //CTRLg
};
static const int numWIValues = 9;
static const int numWINames = 4;
};
struct WellCumDataType
{
enum WCId
{
WellLocationi = 0, //WLi
WellLocationj = 1, //WLj
OilProd = 2, //OP
WaterProd = 3, //WP
GasProd = 4, //GP
FluidResVolProd = 5, //FRVP
OilInj = 6, //OI
WaterInj = 7, //WI
GasInj = 8, //GI
FluidResVolInj = 9, //FRVI
WellName = 0, //WName
WellType = 1, //WType
WellCTRL = 2, //WCTRL
};
static const int numWCValues = 10;
static const int numWCNames = 3;
};
public:
template<class CollectDataToIORankType>
@ -1038,6 +1099,324 @@ public:
}
}
// write production report to output
void outputProdLog(size_t reportStepNum, const bool substep, bool forceDisableProdOutput)
{
if (!substep) {
ScalarBuffer tmp_values(WellProdDataType::numWPValues, 0.0);
StringBuffer tmp_names(WellProdDataType::numWPNames, "");
outputProductionReport_(tmp_values, tmp_names, forceDisableProdOutput);
const auto& st = simulator_.vanguard().summaryState();
const auto& schedule = simulator_.vanguard().schedule();
for (const auto& wname: schedule.wellNames(reportStepNum)) {
// don't bother with wells not on this process
const auto& defunctWellNames = simulator_.vanguard().defunctWellNames();
if (defunctWellNames.find(wname) != defunctWellNames.end()) {
continue;
}
const auto& well = schedule.getWell2(wname, reportStepNum);
// Ignore injector wells
if (well.isInjector()){
continue;
}
tmp_names[0] = wname;//WellProdDataType::WellName
auto wName = static_cast<std::string>(wname);
auto get = [&st, &wName](const std::string& vector)
{
const auto key = vector + ':' + wName;
return st.has(key) ? st.get(key) : 0.0;
};
const auto& controls = well.productionControls(st);
using CMode = ::Opm::Well2::ProducerCMode;
auto fctl = [](const auto wmctl) -> std::string
{
switch (wmctl) {
case CMode::ORAT: return "ORAT";
case CMode::WRAT: return "WRAT";
case CMode::GRAT: return "GRAT";
case CMode::LRAT: return "LRAT";
case CMode::RESV: return "RESV";
case CMode::THP: return "THP";
case CMode::BHP: return "BHP";
case CMode::CRAT: return "CRate";
case CMode::GRUP: return "GRUP";
default:
{
return "none";
}
}
};
tmp_names[1] = fctl(controls.cmode); //WellProdDataType::CTRLMode
tmp_values[0] = well.getHeadI() + 1;//WellProdDataType::WellLocationi
tmp_values[1] = well.getHeadJ() + 1;//WellProdDataType::WellLocationj
tmp_values[2] = get("WOPR"); //WellProdDataType::OilRate
tmp_values[3] = get("WWPR"); //WellProdDataType::WaterRate
tmp_values[4] = get("WGPR"); //WellProdDataType::GasRate
tmp_values[5] = get("WVPR"); //WellProdDataType::FluidResVol
tmp_values[6] = get("WWCT"); //WellProdDataType::WaterCut
tmp_values[7] = get("WGOR"); //WellProdDataType::GasOilRatio
tmp_values[8] = get("WWPR")/get("WGPR"); //WellProdDataType::WaterGasRatio
tmp_values[9] = get("WBHP"); //WellProdDataType::BHP
tmp_values[10] = get("WTHP"); //WellProdDataType::THP
//tmp_values[11] = 0; //WellProdDataType::SteadyStatePI //
outputProductionReport_(tmp_values, tmp_names, forceDisableProdOutput);
}
}
}
// write injection report to output
void outputInjLog(size_t reportStepNum, const bool substep, bool forceDisableInjOutput)
{
if (!substep) {
ScalarBuffer tmp_values(WellInjDataType::numWIValues, 0.0);
StringBuffer tmp_names(WellInjDataType::numWINames, "");
outputInjectionReport_(tmp_values, tmp_names, forceDisableInjOutput);
const auto& st = simulator_.vanguard().summaryState();
const auto& schedule = simulator_.vanguard().schedule();
for (const auto& group_name: schedule.groupNames()) {
std::cout << group_name; //well.groupName()
}
for (const auto& wname: schedule.wellNames(reportStepNum)) {
// don't bother with wells not on this process
const auto& defunctWellNames = simulator_.vanguard().defunctWellNames();
if (defunctWellNames.find(wname) != defunctWellNames.end()) {
continue;
}
const auto& well = schedule.getWell2(wname, reportStepNum);
// Ignore Producer wells
if (well.isProducer()){
continue;
}
tmp_names[0] = wname; //WellInjDataType::WellName
auto wName = static_cast<std::string>(wname);
auto get = [&st, &wName](const std::string& vector)
{
const auto key = vector + ':' + wName;
return st.has(key) ? st.get(key) : 0.0;
};
const auto& controls = well.injectionControls(st);
const auto ctlMode = controls.cmode;
const auto injType = controls.injector_type;
using CMode = ::Opm::Well2::InjectorCMode;
using WType = ::Opm::Well2::InjectorType;
auto ftype = [](const auto wtype) -> std::string
{
switch (wtype) {
case WType::OIL: return "Oil";
case WType::WATER: return "Wat";
case WType::GAS: return "Gas";
case WType::MULTI: return "Multi";
default:
{
return "";
}
}
};
auto fctl = [](const auto wmctl) -> std::string
{
switch (wmctl) {
case CMode::RATE: return "RATE";
case CMode::RESV: return "RESV";
case CMode::THP: return "THP";
case CMode::BHP: return "BHP";
case CMode::GRUP: return "GRUP";
default:
{
return "";
}
}
};
const auto flowtype = ftype(injType);
const auto flowctl = fctl(ctlMode);
if(flowtype == "Oil") //WellInjDataType::CTRLModeOil
{
if (flowctl == "RATE"){ tmp_names[1] = "ORAT"; }
else { tmp_names[1] = flowctl; }
}
else if (flowtype == "Wat") //WellInjDataType::CTRLModeWat
{
if (flowctl == "RATE"){ tmp_names[3] = "WRAT"; }
else { tmp_names[2] = flowctl; }
}
else if (flowtype == "Gas") //WellInjDataType::CTRLModeGas
{
if (flowctl == "RATE"){ tmp_names[3] = "GRAT"; }
else { tmp_names[3] = flowctl; }
}
tmp_values[0] = well.getHeadI() + 1; //WellInjDataType::wellLocationi
tmp_values[1] = well.getHeadJ() + 1; //WellInjDataType::wellLocationj
tmp_values[2] = get("WOIR"); //WellInjDataType::OilRate
tmp_values[3] = get("WWIR"); //WellInjDataType::WaterRate
tmp_values[4] = get("WGIR"); //WellInjDataType::GasRate
tmp_values[5] = get("WVIR");//WellInjDataType::FluidResVol
tmp_values[6] = get("WBHP"); //WellInjDataType::BHP
tmp_values[7] = get("WTHP"); //WellInjDataType::THP
//tmp_values[8] = 0; //WellInjDataType::SteadyStateII
outputInjectionReport_(tmp_values, tmp_names, forceDisableInjOutput);
}
}
}
// write cumulative production and injection reports to output
void outputCumLog(size_t reportStepNum, const bool substep, bool forceDisableCumOutput)
{
if (!substep) {
ScalarBuffer tmp_values(WellCumDataType::numWCValues, 0.0);
StringBuffer tmp_names(WellCumDataType::numWCNames, "");
outputCumulativeReport_(tmp_values, tmp_names, forceDisableCumOutput);
const auto& st = simulator_.vanguard().summaryState();
const auto& schedule = simulator_.vanguard().schedule();
for (const auto& wname : schedule.wellNames(reportStepNum)) {
// don't bother with wells not on this process
const auto& defunctWellNames = simulator_.vanguard().defunctWellNames();
if (defunctWellNames.find(wname) != defunctWellNames.end()) {
continue;
}
const auto& well = schedule.getWell2(wname, reportStepNum);
tmp_names[0] = wname; //WellCumDataType::WellName
auto wName = static_cast<std::string>(wname);
auto get = [&st, &wName](const std::string& vector)
{
const auto key = vector + ':' + wName;
return st.has(key) ? st.get(key) : 0.0;
};
if (well.isInjector()) {
const auto& controls = well.injectionControls(st);
const auto ctlMode = controls.cmode;
const auto injType = controls.injector_type;
using CMode = ::Opm::Well2::InjectorCMode;
using WType = ::Opm::Well2::InjectorType;
auto ftype = [](const auto wtype) -> std::string
{
switch (wtype) {
case WType::OIL: return "Oil";
case WType::WATER: return "Wat";
case WType::GAS: return "Gas";
case WType::MULTI: return "Multi";
default:
{
return "";
}
}
};
auto fctl = [](const auto wmctl) -> std::string
{
switch (wmctl) {
case CMode::RATE: return "RATE";
case CMode::RESV: return "RESV";
case CMode::THP: return "THP";
case CMode::BHP: return "BHP";
case CMode::GRUP: return "GRUP";
default:
{
return "";
}
}
};
tmp_names[1] = "INJ"; //WellCumDataType::WellType
const auto flowctl = fctl(ctlMode);
if (flowctl == "RATE") //WellCumDataType::WellCTRL
{
const auto flowtype = ftype(injType);
if(flowtype == "Oil"){ tmp_names[2] = "ORAT"; }
else if(flowtype == "Wat"){ tmp_names[2] = "WRAT"; }
else if(flowtype == "Gas"){ tmp_names[2] = "GRAT"; }
}
else
{
tmp_names[2] = flowctl;
}
}
else if (well.isProducer()) {
const auto& controls = well.productionControls(st);
using CMode = ::Opm::Well2::ProducerCMode;
auto fctl = [](const auto wmctl) -> std::string
{
switch (wmctl) {
case CMode::ORAT: return "ORAT";
case CMode::WRAT: return "WRAT";
case CMode::GRAT: return "GRAT";
case CMode::LRAT: return "LRAT";
case CMode::RESV: return "RESV";
case CMode::THP: return "THP";
case CMode::BHP: return "BHP";
case CMode::CRAT: return "CRAT";
case CMode::GRUP: return "GRUP";
default:
{
return "none";
}
}
};
tmp_names[1] = "PROD"; //WellProdDataType::CTRLMode
tmp_names[2] = fctl(controls.cmode); //WellProdDataType::CTRLMode
}
tmp_values[0] = well.getHeadI() + 1; //WellCumDataType::wellLocationi
tmp_values[1] = well.getHeadJ() + 1; //WellCumDataType::wellLocationj
tmp_values[2] = get("WOPT"); //WellCumDataType::OilProd
tmp_values[3] = get("WWPT"); //WellCumDataType::WaterProd
tmp_values[4] = get("WGPT"); //WellCumDataType::GasProd
tmp_values[5] = get("WVPT");//WellCumDataType::FluidResVolProd
tmp_values[2] = get("WOIT"); //WellCumDataType::OilInj
tmp_values[3] = get("WWIT"); //WellCumDataType::WaterInj
tmp_values[4] = get("WGIT"); //WellCumDataType::GasInj
tmp_values[5] = get("WVIT");//WellCumDataType::FluidResVolInj
outputCumulativeReport_(tmp_values, tmp_names, forceDisableCumOutput);
}
}
}
void setRestart(const Opm::data::Solution& sol, unsigned elemIdx, unsigned globalDofIndex)
{
@ -1450,6 +1829,94 @@ private:
<< ":========================:==========================================:================:==========================================:\n";
Opm::OpmLog::note(ss.str());
}
void outputProductionReport_(const ScalarBuffer& wellProd, const StringBuffer& wellProdNames, const bool forceDisableProdOutput)
{
if(forceDisableProdOutput)
return;
const Opm::UnitSystem& units = simulator_.vanguard().eclState().getUnits();
std::ostringstream ss;
if (wellProdNames[WellProdDataType::WellName].empty()) {
ss << "======================================================= PRODUCTION REPORT =======================================================\n"//=================== \n"
<< ": WELL : LOCATION :CTRL: OIL : WATER : GAS : FLUID : WATER : GAS/OIL : WAT/GAS : BHP OR : THP OR :\n"// STEADY-ST PI :\n"
<< ": NAME : (I,J,K) :MODE: RATE : RATE : RATE : RES.VOL. : CUT : RATIO : RATIO : CON.PR.: BLK.PR.:\n";// OR POTN OF PREF. PH:\n";
if (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_METRIC) {
ss << ": : : : SCM/DAY : SCM/DAY : SCM/DAY : RCM/DAY : SCM/SCM : SCM/SCM : SCM/SCM : BARSA : BARSA :\n";// :\n";
}
if (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_FIELD) {
ss << ": : : : STB/DAY : STB/DAY : MSCF/DAY : RB/DAY : : MSCF/STB : STB/MSCF : PSIA : PSIA :\n";// :\n";
}
if (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_LAB) {
ss << ": : : : SCC/HR : SCC/HR : SCC/HR : RCC : SCC/SCC : SCC/SCC : SCC/SCC : ATMA : ATMA :\n";// :\n";
}
ss << "=================================================================================================================================\n";//=================== \n";
}
else {
ss << std::right << std::fixed << ":" << std::setw (8) << wellProdNames[WellProdDataType::WellName] << ":" << std::setprecision(0) << std::setw(5) << wellProd[WellProdDataType::WellLocationi] << "," << std::setw(5) << wellProd[WellProdDataType::WellLocationj] << ":" << std::setw(4) << wellProdNames[WellProdDataType::CTRLMode] << ":" << std::setprecision(1) << std::setw(11) << wellProd[WellProdDataType::OilRate] << ":" << std::setw(11) << wellProd[WellProdDataType::WaterRate] << ":" << std::setw(11)<< wellProd[WellProdDataType::GasRate] << ":" << std::setw(11) << wellProd[WellProdDataType::FluidResVol] << std::setprecision(3) << ":" << std::setw(11) << wellProd[WellProdDataType::WaterCut] << std::setprecision(2) << ":" << std::setw(10) << wellProd[WellProdDataType::GasOilRatio] << std::setprecision(4) << ":" << std::setw(12) << wellProd[WellProdDataType::WatGasRatio] << std::setprecision(1) << ":" << std::setw(8) << wellProd[WellProdDataType::BHP] << ":" << std::setw(8) << wellProd[WellProdDataType::THP] << ": \n"//wellProd[WellProdDataType::SteadyStatePI] << std::setw(10) << "\n"
<< ":"<< std::setfill ('-') << std::setw (9) << ":" << std::setfill ('-') << std::setw (12) << ":" << std::setfill ('-') << std::setw (5) << ":" << std::setfill ('-') << std::setw (12) << ":" << std::setfill ('-') << std::setw (12) << ":" << std::setfill ('-') << std::setw (12) << ":" << std::setfill ('-') << std::setw (12) << ":" << std::setfill ('-') << std::setw (12) << ":" << std::setfill ('-') << std::setw (11) << ":" << std::setfill ('-') << std::setw (13) << ":" << std::setfill ('-') << std::setw (9) << ":" << std::setfill ('-') << std::setw (9) << ": \n";
}
Opm::OpmLog::note(ss.str());
}
void outputInjectionReport_(const ScalarBuffer& wellInj, const StringBuffer& wellInjNames, const bool forceDisableInjOutput)
{
if(forceDisableInjOutput)
return;
const Opm::UnitSystem& units = simulator_.vanguard().eclState().getUnits();
std::ostringstream ss;
if (wellInjNames[WellInjDataType::WellName].empty()) {
ss << "=================================================== INJECTION REPORT ========================================\n"//===================== \n"
<< ": WELL : LOCATION : CTRL : CTRL : CTRL : OIL : WATER : GAS : FLUID : BHP OR : THP OR :\n"// STEADY-ST II :\n"
<< ": NAME : (I,J,K) : MODE : MODE : MODE : RATE : RATE : RATE : RES.VOL. : CON.PR.: BLK.PR.:\n";// OR POTENTIAL :\n";
if (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_METRIC) {
ss << ": : : OIL : WAT : GAS : SCM/DAY : SCM/DAY : SCM/DAY : RCM/DAY : BARSA : BARSA :\n";// :\n";
}
if (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_FIELD) {
ss << ": : : OIL : WAT : GAS : STB/DAY : STB/DAY : MSCF/DAY : RB/DAY : PSIA : PSIA :\n";// :\n";
}
if (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_LAB) {
ss << ": : : OIL : WAT : GAS : SCC/HR : SCC/HR : SCC/HR : RCC/HR : ATMA : ATMA :\n";// :\n";
}
ss << "==============================================================================================================\n";//===================== \n";
}
else {
ss << std::right << std::fixed << std::setprecision(0) << ":" << std::setw (8) << wellInjNames[WellInjDataType::WellName] << ":" << std::setw(5) << wellInj[WellInjDataType::WellLocationi] << "," << std::setw(5) << wellInj[WellInjDataType::WellLocationj] << ":" << std::setw(6) << wellInjNames[WellInjDataType::CTRLModeOil] << ":" << std::setw(6) << wellInjNames[WellInjDataType::CTRLModeWat] << ":" << std::setw(6) << wellInjNames[WellInjDataType::CTRLModeGas] << ":" << std::setprecision(1) << std::setw(11) << wellInj[WellInjDataType::OilRate] << ":" << std::setw(11) << wellInj[WellInjDataType::WaterRate] << ":" << std::setw(11)<< wellInj[WellInjDataType::GasRate] << ":" << std::setw(11) << wellInj[WellInjDataType::FluidResVol] << ":" << std::setw(8)<< wellInj[WellInjDataType::BHP] << ":" << std::setw(8)<< wellInj[WellInjDataType::THP] << ": \n"//wellInj[WellInjDataType::SteadyStateII] << std::setw(10) << "\n"
<< ":--------:-----------:------:------:------:------------:----------:-----------:-----------:--------:--------:\n";//--------------------:\n";
}
Opm::OpmLog::note(ss.str());
}
void outputCumulativeReport_(const ScalarBuffer& wellCum, const StringBuffer& wellCumNames, const bool forceDisableCumOutput)
{
if(forceDisableCumOutput)
return;
const Opm::UnitSystem& units = simulator_.vanguard().eclState().getUnits();
std::ostringstream ss;
if (wellCumNames[WellCumDataType::WellName].empty()) {
ss << "=================================================== CUMULATIVE PRODUCTION/INJECTION REPORT =========================================\n"
<< ": WELL : LOCATION : WELL :CTRL: OIL : WATER : GAS : Prod : OIL : WATER : GAS : INJ :\n"
<< ": NAME : (I,J,K) : TYPE :MODE: PROD : PROD : PROD : RES.VOL. : INJ : INJ : INJ : RES.VOL. :\n";
if (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_METRIC) {
ss << ": : : : : MSCM : MSCM : MMSCM : MRCM : MSCM : MSCM : MMSCM : MRCM :\n";
}
if (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_FIELD) {
ss << ": : : : : MSTB : MSTB : MMSCF : MRB : MSTB : MSTB : MMSCF : MRB :\n";
}
if (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_LAB) {
ss << ": : : : : MSCC : MSCC : MMSCC : MRCC : MSCC : MSCC : MMSCC : MRCC :\n";
}
ss << "====================================================================================================================================\n";
}
else {
ss << std::right << std::fixed << std::setprecision(0) << ":" << std::setw (8) << wellCumNames[WellCumDataType::WellName] << ":" << std::setw(5) << wellCum[WellCumDataType::WellLocationi] << "," << std::setw(5) << wellCum[WellCumDataType::WellLocationj] << ":" << std::setw(8) << wellCumNames[WellCumDataType::WellType] << ":" << std::setw(4) << wellCumNames[WellCumDataType::WellCTRL] << ":" << std::setprecision(1) << std::setw(11) << wellCum[WellCumDataType::OilProd] << ":" << std::setw(11) << wellCum[WellCumDataType::WaterProd] << ":" << std::setw(11)<< wellCum[WellCumDataType::GasProd]/1000 << ":" << std::setw(11) << wellCum[WellCumDataType::FluidResVolProd] << ":" << std::setw(11) << wellCum[WellCumDataType::OilProd] << ":" << std::setw(11) << wellCum[WellCumDataType::WaterInj] << ":" << std::setw(11) << wellCum[WellCumDataType::GasInj]/1000 << ":" << std::setw(11) << wellCum[WellCumDataType::FluidResVolInj] << ": \n"
<< ":--------:-----------:--------:----:------------:----------:-----------:-----------:------------:----------:-----------:-----------:\n";
}
Opm::OpmLog::note(ss.str());
}
std::string fipEnumToString_(int i)
{
@ -1467,6 +1934,48 @@ private:
}
return "ERROR";
}
std::string WIEnumToString_(int i)
{
typedef typename WellInjDataType::WIId WIId;
switch(static_cast<WIId>(i))
{
case WellInjDataType::WellName: return "WName";
case WellInjDataType::WellLocationi: return "WLi";
case WellInjDataType::WellLocationj: return "WLj";
case WellInjDataType::CTRLModeOil: return "CTRLo";
case WellInjDataType::CTRLModeWat: return "CTRLw";
case WellInjDataType::CTRLModeGas: return "CTRLg";
case WellInjDataType::OilRate: return "OR";
case WellInjDataType::WaterRate: return "WR";
case WellInjDataType::GasRate: return "GR";
case WellInjDataType::FluidResVol: return "FRV";
case WellInjDataType::BHP: return "BHP";
case WellInjDataType::THP: return "THP";
case WellInjDataType::SteadyStateII: return "SteadyStateII";
}
return "ERROR";
}
std::string WCEnumToString_(int i)
{
typedef typename WellCumDataType::WCId WCId;
switch(static_cast<WCId>(i))
{
case WellCumDataType::WellName: return "WName";
case WellCumDataType::WellLocationi: return "WLi";
case WellCumDataType::WellLocationj: return "WLj";
case WellCumDataType::WellType: return "WType";
case WellCumDataType::WellCTRL: return "WCTRL";
case WellCumDataType::OilProd: return "OP";
case WellCumDataType::WaterProd: return "WP";
case WellCumDataType::GasProd: return "GP";
case WellCumDataType::FluidResVolProd: return "FRVP";
case WellCumDataType::OilInj: return "OI";
case WellCumDataType::WaterInj: return "WI";
case WellCumDataType::GasInj: return "GI";
case WellCumDataType::FluidResVolInj: return "FRVI";
}
return "ERROR";
}
const Simulator& simulator_;

7
ebos/eclwriter.hh
View File

@ -275,6 +275,13 @@ public:
std::map<std::string, std::vector<double>> regionData;
eclOutputModule_.outputFipLog(miscSummaryData, regionData, isSubStep);
bool forceDisableProdOutput = false;
bool forceDisableInjOutput = false;
bool forceDisableCumOutput = false;
eclOutputModule_.outputProdLog(reportStepNum, isSubStep, forceDisableProdOutput);
eclOutputModule_.outputInjLog(reportStepNum, isSubStep, forceDisableInjOutput);
eclOutputModule_.outputCumLog(reportStepNum, isSubStep, forceDisableCumOutput);
std::vector<char> buffer;
if (collectToIORank_.isIORank()) {
const auto& summary = eclIO_->summary();