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Merge branch 'fishbones' into pre-proto

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Bjørnar Grip Fjær
2017-06-01 12:32:36 +02:00
parent a1738d8e3a 1aedf92efc
commit 935299b3df
97 changed files with 9865 additions and 1293 deletions
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4
ApplicationCode/Commands/WellPathCommands/CMakeLists_files.cmake
View File

@@ -6,8 +6,6 @@ endif()
set (SOURCE_GROUP_HEADER_FILES
${CEE_CURRENT_LIST_DIR}RicWellPathDeleteFeature.h
${CEE_CURRENT_LIST_DIR}RicWellPathExportCompletionDataFeature.h
${CEE_CURRENT_LIST_DIR}RicWellPathImportCompletionsFileFeature.h
${CEE_CURRENT_LIST_DIR}RicWellPathsImportFileFeature.h
${CEE_CURRENT_LIST_DIR}RicWellPathsImportSsihubFeature.h
${CEE_CURRENT_LIST_DIR}RicWellPathViewerEventHandler.h
@@ -15,8 +13,6 @@ ${CEE_CURRENT_LIST_DIR}RicWellPathViewerEventHandler.h
set (SOURCE_GROUP_SOURCE_FILES
${CEE_CURRENT_LIST_DIR}RicWellPathDeleteFeature.cpp
${CEE_CURRENT_LIST_DIR}RicWellPathExportCompletionDataFeature.cpp
${CEE_CURRENT_LIST_DIR}RicWellPathImportCompletionsFileFeature.cpp
${CEE_CURRENT_LIST_DIR}RicWellPathsImportFileFeature.cpp
${CEE_CURRENT_LIST_DIR}RicWellPathsImportSsihubFeature.cpp
${CEE_CURRENT_LIST_DIR}RicWellPathViewerEventHandler.cpp

898
ApplicationCode/Commands/WellPathCommands/RicWellPathExportCompletionDataFeature.cpp
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@@ -1,898 +0,0 @@
/////////////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2017 Statoil ASA
//
// ResInsight 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 3 of the License, or
// (at your option) any later version.
//
// ResInsight 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 at <http://www.gnu.org/licenses/gpl.html>
// for more details.
//
/////////////////////////////////////////////////////////////////////////////////
#include "RicWellPathExportCompletionDataFeature.h"
#include "RiaApplication.h"
#include "RiaLogging.h"
#include "RimProject.h"
#include "RimWellPath.h"
#include "RimFishbonesMultipleSubs.h"
#include "RimFishbonesCollection.h"
#include "RimExportCompletionDataSettings.h"
#include "RiuMainWindow.h"
#include "RigWellLogExtractionTools.h"
#include "RigEclipseCaseData.h"
#include "RigMainGrid.h"
#include "RigWellPath.h"
#include "cafSelectionManager.h"
#include "cafPdmUiPropertyViewDialog.h"
#include "cvfPlane.h"
#include <QAction>
#include <QFileDialog>
#include <QMessageBox>
CAF_CMD_SOURCE_INIT(RicWellPathExportCompletionDataFeature, "RicWellPathExportCompletionDataFeature");
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
bool RicWellPathExportCompletionDataFeature::isCommandEnabled()
{
std::vector<RimWellPath*> objects;
caf::SelectionManager::instance()->objectsByType(&objects);
if (objects.size() == 1) {
return true;
}
return false;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::onActionTriggered(bool isChecked)
{
std::vector<RimWellPath*> objects;
caf::SelectionManager::instance()->objectsByType(&objects);
CVF_ASSERT(objects.size() == 1);
RiaApplication* app = RiaApplication::instance();
QString projectFolder = app->currentProjectPath();
QString defaultDir = RiaApplication::instance()->lastUsedDialogDirectoryWithFallback("COMPLETIONS", projectFolder);
RimExportCompletionDataSettings exportSettings;
std::vector<RimCase*> cases;
app->project()->allCases(cases);
for (auto c : cases)
{
RimEclipseCase* eclipseCase = dynamic_cast<RimEclipseCase*>(c);
if (eclipseCase != nullptr)
{
exportSettings.caseToApply = eclipseCase;
break;
}
}
exportSettings.fileName = QDir(defaultDir).filePath("Completions");
caf::PdmUiPropertyViewDialog propertyDialog(RiuMainWindow::instance(), &exportSettings, "Export Completion Data", "");
if (propertyDialog.exec() == QDialog::Accepted)
{
RiaApplication::instance()->setLastUsedDialogDirectory("COMPLETIONS", QFileInfo(exportSettings.fileName).absolutePath());
exportToFolder(objects[0], exportSettings);
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::setupActionLook(QAction* actionToSetup)
{
actionToSetup->setText("Export Completion Data");
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::exportToFolder(RimWellPath* wellPath, const RimExportCompletionDataSettings& exportSettings)
{
QFile exportFile(exportSettings.fileName());
if (exportSettings.caseToApply() == nullptr)
{
RiaLogging::error("Export Completions Data: Cannot export completions data without specified eclipse case");
return;
}
if (!exportFile.open(QIODevice::WriteOnly))
{
RiaLogging::error(QString("Export Completions Data: Could not open the file: %1").arg(exportSettings.fileName()));
return;
}
RiaLogging::debug(QString("Exporting completion data for well path %1 to %2 [WPIMULT: %3, REM BORE CELLS: %4]").arg(wellPath->name).arg(exportSettings.fileName()).arg(exportSettings.includeWpimult()).arg(exportSettings.removeLateralsInMainBoreCells()));
// Generate data
const RigEclipseCaseData* caseData = exportSettings.caseToApply()->eclipseCaseData();
std::vector<WellSegmentLocation> wellSegmentLocations = findWellSegmentLocations(exportSettings.caseToApply, wellPath);
// Filter out cells where main bore is present
if (exportSettings.removeLateralsInMainBoreCells())
{
std::vector<size_t> wellPathCells = findIntersectingCells(caseData, wellPath->wellPathGeometry()->m_wellPathPoints);
markWellPathCells(wellPathCells, &wellSegmentLocations);
}
// Print data
QTextStream stream(&exportFile);
RifEclipseOutputTableFormatter formatter(stream);
generateCompdatTable(formatter, wellPath, exportSettings, wellSegmentLocations);
if (exportSettings.includeWpimult())
{
std::map<size_t, double> lateralsPerCell = computeLateralsPerCell(wellSegmentLocations, exportSettings.removeLateralsInMainBoreCells());
generateWpimultTable(formatter, wellPath, exportSettings, lateralsPerCell);
}
generateWelsegsTable(formatter, wellPath, exportSettings, wellSegmentLocations);
generateCompsegsTable(formatter, wellPath, exportSettings, wellSegmentLocations);
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::generateCompdatTable(RifEclipseOutputTableFormatter& formatter, const RimWellPath* wellPath, const RimExportCompletionDataSettings& settings, const std::vector<WellSegmentLocation>& locations)
{
RigMainGrid* grid = settings.caseToApply->eclipseCaseData()->mainGrid();
std::vector<RifEclipseOutputTableColumn> header = {
RifEclipseOutputTableColumn("Well"),
RifEclipseOutputTableColumn("I"),
RifEclipseOutputTableColumn("J"),
RifEclipseOutputTableColumn("K1"),
RifEclipseOutputTableColumn("K2"),
RifEclipseOutputTableColumn("Status"),
RifEclipseOutputTableColumn("SAT"),
RifEclipseOutputTableColumn("TR"),
RifEclipseOutputTableColumn("DIAM"),
RifEclipseOutputTableColumn("KH"),
RifEclipseOutputTableColumn("S"),
RifEclipseOutputTableColumn("Df"),
RifEclipseOutputTableColumn("DIR"),
RifEclipseOutputTableColumn("r0")
};
formatter.keyword("COMPDAT");
formatter.header(header);
for (const WellSegmentLocation& location : locations)
{
for (const WellSegmentLateral& lateral : location.laterals)
{
formatter.comment(QString("Fishbone %1 - Sub: %2 - Lateral: %3").arg(location.fishbonesSubs->name()).arg(location.subIndex).arg(lateral.lateralIndex));
for (const WellSegmentLateralIntersection& intersection : lateral.intersections)
{
if (settings.removeLateralsInMainBoreCells && intersection.mainBoreCell) continue;
size_t i, j, k;
grid->ijkFromCellIndex(intersection.cellIndex, &i, &j, &k);
formatter.add(wellPath->name());
formatter.addZeroBasedCellIndex(i).addZeroBasedCellIndex(j).addZeroBasedCellIndex(k).addZeroBasedCellIndex(k);
formatter.add("'OPEN'").add("1*").add("1*");
formatter.add(location.fishbonesSubs->holeRadius() / 1000);
formatter.add("1*").add("1*").add("1*");
switch (intersection.direction)
{
case POS_I:
case NEG_I:
formatter.add("'X'");
break;
case POS_J:
case NEG_J:
formatter.add("'Y'");
break;
case POS_K:
case NEG_K:
formatter.add("'Z'");
break;
}
formatter.add("1*");
formatter.rowCompleted();
}
}
}
formatter.tableCompleted();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::generateWpimultTable(RifEclipseOutputTableFormatter& formatter, const RimWellPath* wellPath, const RimExportCompletionDataSettings& settings, const std::map<size_t, double>& lateralsPerCell)
{
RigMainGrid* grid = settings.caseToApply->eclipseCaseData()->mainGrid();
std::vector<RifEclipseOutputTableColumn> header = {
RifEclipseOutputTableColumn("Well"),
RifEclipseOutputTableColumn("Mult"),
RifEclipseOutputTableColumn("I"),
RifEclipseOutputTableColumn("J"),
RifEclipseOutputTableColumn("K"),
};
formatter.keyword("WPIMULT");
formatter.header(header);
for (auto lateralsInCell : lateralsPerCell)
{
size_t i, j, k;
grid->ijkFromCellIndex(lateralsInCell.first, &i, &j, &k);
formatter.add(wellPath->name());
formatter.add(lateralsInCell.second);
formatter.addZeroBasedCellIndex(i).addZeroBasedCellIndex(j).addZeroBasedCellIndex(k);
formatter.rowCompleted();
}
formatter.tableCompleted();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::generateWelsegsTable(RifEclipseOutputTableFormatter& formatter, const RimWellPath* wellPath, const RimExportCompletionDataSettings& settings, const std::vector<WellSegmentLocation>& locations)
{
formatter.keyword("WELSEGS");
const WellSegmentLocation& firstLocation = locations[0];
{
std::vector<RifEclipseOutputTableColumn> header = {
RifEclipseOutputTableColumn("Name"),
RifEclipseOutputTableColumn("Dep 1"),
RifEclipseOutputTableColumn("Tlen 1"),
RifEclipseOutputTableColumn("Vol 1"),
RifEclipseOutputTableColumn("Len&Dep"),
RifEclipseOutputTableColumn("PresDrop"),
};
formatter.header(header);
formatter.add(wellPath->name());
formatter.add(firstLocation.trueVerticalDepth);
formatter.add(firstLocation.measuredDepth);
formatter.add("1*");
formatter.add("INC");
formatter.add("H--");
formatter.rowCompleted();
}
{
std::vector<RifEclipseOutputTableColumn> header = {
RifEclipseOutputTableColumn("First Seg"),
RifEclipseOutputTableColumn("Last Seg"),
RifEclipseOutputTableColumn("Branch Num"),
RifEclipseOutputTableColumn("Outlet Seg"),
RifEclipseOutputTableColumn("Length"),
RifEclipseOutputTableColumn("Depth Change"),
RifEclipseOutputTableColumn("Diam"),
RifEclipseOutputTableColumn("Rough"),
};
formatter.header(header);
}
{
WellSegmentLocation previousLocation = firstLocation;
formatter.comment("Main stem");
for (size_t i = 0; i < locations.size(); ++i)
{
const WellSegmentLocation& location = locations[i];
formatter.comment(QString("Segment for sub %1").arg(location.subIndex));
formatter.add(location.segmentNumber).add(location.segmentNumber);
formatter.add(1); // All segments on main stem are branch 1
formatter.add(location.segmentNumber - 1); // All main stem segments are connected to the segment below them
formatter.add(location.fishbonesSubs->locationOfSubs()[location.subIndex] - previousLocation.fishbonesSubs->locationOfSubs()[previousLocation.subIndex]);
formatter.add(location.trueVerticalDepth - previousLocation.trueVerticalDepth);
formatter.add(-1.0); // FIXME : Diam of main stem?
formatter.add(-1.0); // FIXME : Rough of main stem?
formatter.rowCompleted();
previousLocation = location;
}
}
{
formatter.comment("Laterals");
formatter.comment("Diam: MSW - Tubing Radius");
formatter.comment("Rough: MSW - Open Hole Roughness Factor");
for (const WellSegmentLocation& location : locations)
{
for (const WellSegmentLateral& lateral : location.laterals)
{
formatter.comment(QString("%1 : Sub index %2 - Lateral %3").arg(location.fishbonesSubs->name()).arg(location.subIndex).arg(lateral.lateralIndex));
for (const WellSegmentLateralIntersection& intersection : lateral.intersections)
{
formatter.add(intersection.segmentNumber);
formatter.add(intersection.segmentNumber);
formatter.add(lateral.branchNumber);
formatter.add(intersection.attachedSegmentNumber);
formatter.add(intersection.length);
formatter.add(intersection.depth);
formatter.add(location.fishbonesSubs->tubingRadius());
formatter.add(location.fishbonesSubs->openHoleRoughnessFactor());
formatter.rowCompleted();
}
}
}
}
formatter.tableCompleted();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::generateCompsegsTable(RifEclipseOutputTableFormatter& formatter, const RimWellPath* wellPath, const RimExportCompletionDataSettings& settings, const std::vector<WellSegmentLocation>& locations)
{
RigMainGrid* grid = settings.caseToApply->eclipseCaseData()->mainGrid();
formatter.keyword("COMPSEGS");
{
std::vector<RifEclipseOutputTableColumn> header = {
RifEclipseOutputTableColumn("Name")
};
formatter.header(header);
formatter.add(wellPath->name());
formatter.rowCompleted();
}
{
std::vector<RifEclipseOutputTableColumn> header = {
RifEclipseOutputTableColumn("I"),
RifEclipseOutputTableColumn("J"),
RifEclipseOutputTableColumn("K"),
RifEclipseOutputTableColumn("Branch no"),
RifEclipseOutputTableColumn("Start Length"),
RifEclipseOutputTableColumn("End Length"),
RifEclipseOutputTableColumn("Dir Pen"),
RifEclipseOutputTableColumn("End Range"),
RifEclipseOutputTableColumn("Connection Depth")
};
formatter.header(header);
}
for (const WellSegmentLocation& location : locations)
{
for (const WellSegmentLateral& lateral : location.laterals)
{
double length = 0;
for (const WellSegmentLateralIntersection& intersection : lateral.intersections)
{
length += intersection.length;
if (settings.removeLateralsInMainBoreCells && intersection.mainBoreCell) continue;
size_t i, j, k;
grid->ijkFromCellIndex(intersection.cellIndex, &i, &j, &k);
formatter.addZeroBasedCellIndex(i).addZeroBasedCellIndex(j).addZeroBasedCellIndex(k);
formatter.add(lateral.branchNumber);
formatter.add(length);
formatter.add("1*");
switch (intersection.direction)
{
case POS_I:
case NEG_I:
formatter.add("I");
break;
case POS_J:
case NEG_J:
formatter.add("J");
break;
case POS_K:
case NEG_K:
formatter.add("K");
break;
}
formatter.add(-1);
formatter.rowCompleted();
}
}
}
formatter.tableCompleted();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::vector<size_t> RicWellPathExportCompletionDataFeature::findCloseCells(const RigEclipseCaseData* caseData, const cvf::BoundingBox& bb)
{
std::vector<size_t> closeCells;
caseData->mainGrid()->findIntersectingCells(bb, &closeCells);
return closeCells;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::vector<EclipseCellIndexRange> RicWellPathExportCompletionDataFeature::getCellIndexRange(const RigMainGrid* grid, const std::vector<size_t>& cellIndices)
{
// Retrieve I, J, K indices
std::vector<EclipseCellIndex> eclipseCellIndices;
for (auto cellIndex : cellIndices)
{
size_t i, j, k;
if (!grid->ijkFromCellIndex(cellIndex, &i, &j, &k)) continue;
eclipseCellIndices.push_back(std::make_tuple(i, j, k));
}
// Group cell indices in K-ranges
std::sort(eclipseCellIndices.begin(), eclipseCellIndices.end(), RicWellPathExportCompletionDataFeature::cellOrdering);
std::vector<EclipseCellIndexRange> eclipseCellRanges;
size_t lastI = std::numeric_limits<size_t>::max();
size_t lastJ = std::numeric_limits<size_t>::max();
size_t lastK = std::numeric_limits<size_t>::max();
size_t startK = std::numeric_limits<size_t>::max();
for (EclipseCellIndex cell : eclipseCellIndices)
{
size_t i, j, k;
std::tie(i, j, k) = cell;
if (i != lastI || j != lastJ || k != lastK + 1)
{
if (startK != std::numeric_limits<size_t>::max())
{
EclipseCellIndexRange cellRange = {lastI, lastJ, startK, lastK};
eclipseCellRanges.push_back(cellRange);
}
lastI = i;
lastJ = j;
lastK = k;
startK = k;
}
else
{
lastK = k;
}
}
// Append last cell range
if (startK != std::numeric_limits<size_t>::max())
{
EclipseCellIndexRange cellRange = {lastI, lastJ, startK, lastK};
eclipseCellRanges.push_back(cellRange);
}
return eclipseCellRanges;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
bool RicWellPathExportCompletionDataFeature::cellOrdering(const EclipseCellIndex& cell1, const EclipseCellIndex& cell2)
{
size_t i1, i2, j1, j2, k1, k2;
std::tie(i1, j1, k1) = cell1;
std::tie(i2, j2, k2) = cell2;
if (i1 == i2)
{
if (j1 == j2)
{
return k1 < k2;
}
else
{
return j1 < j2;
}
}
else
{
return i1 < i2;
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
size_t RicWellPathExportCompletionDataFeature::findCellFromCoords(const RigEclipseCaseData* caseData, const cvf::Vec3d& coords)
{
const std::vector<cvf::Vec3d>& nodeCoords = caseData->mainGrid()->nodes();
cvf::BoundingBox bb;
bb.add(coords);
std::vector<size_t> closeCells = findCloseCells(caseData, bb);
cvf::Vec3d hexCorners[8];
for (size_t closeCell : closeCells)
{
const RigCell& cell = caseData->mainGrid()->globalCellArray()[closeCell];
if (cell.isInvalid()) continue;
setHexCorners(cell, nodeCoords, hexCorners);
if (RigHexIntersector::isPointInCell(coords, hexCorners, closeCell))
{
return closeCell;
}
}
// Coordinate is outside any cells?
CVF_ASSERT(false);
return 0;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::vector<size_t> RicWellPathExportCompletionDataFeature::findIntersectingCells(const RigEclipseCaseData* caseData, const std::vector<cvf::Vec3d>& coords)
{
const std::vector<cvf::Vec3d>& nodeCoords = caseData->mainGrid()->nodes();
std::set<size_t> cells;
// Find starting cell
if (coords.size() > 0)
{
size_t startCell = findCellFromCoords(caseData, coords[0]);
if (startCell > 0)
{
cells.insert(startCell);
}
}
std::vector<HexIntersectionInfo> intersections = findIntersections(caseData, coords);
for (auto intersection : intersections)
{
cells.insert(intersection.m_hexIndex);
}
// Ensure only unique cells are included
std::vector<size_t> cellsVector;
cellsVector.assign(cells.begin(), cells.end());
// Sort cells
std::sort(cellsVector.begin(), cellsVector.end());
return cellsVector;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::vector<HexIntersectionInfo> RicWellPathExportCompletionDataFeature::findIntersections(const RigEclipseCaseData* caseData, const std::vector<cvf::Vec3d>& coords)
{
const std::vector<cvf::Vec3d>& nodeCoords = caseData->mainGrid()->nodes();
std::vector<HexIntersectionInfo> intersections;
for (size_t i = 0; i < coords.size() - 1; ++i)
{
cvf::BoundingBox bb;
bb.add(coords[i]);
bb.add(coords[i + 1]);
std::vector<size_t> closeCells = findCloseCells(caseData, bb);
cvf::Vec3d hexCorners[8];
for (size_t closeCell : closeCells)
{
const RigCell& cell = caseData->mainGrid()->globalCellArray()[closeCell];
if (cell.isInvalid()) continue;
setHexCorners(cell, nodeCoords, hexCorners);
RigHexIntersector::lineHexCellIntersection(coords[i], coords[i + 1], hexCorners, closeCell, &intersections);
}
}
return intersections;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::setHexCorners(const RigCell& cell, const std::vector<cvf::Vec3d>& nodeCoords, cvf::Vec3d* hexCorners)
{
const caf::SizeTArray8& cornerIndices = cell.cornerIndices();
hexCorners[0] = nodeCoords[cornerIndices[0]];
hexCorners[1] = nodeCoords[cornerIndices[1]];
hexCorners[2] = nodeCoords[cornerIndices[2]];
hexCorners[3] = nodeCoords[cornerIndices[3]];
hexCorners[4] = nodeCoords[cornerIndices[4]];
hexCorners[5] = nodeCoords[cornerIndices[5]];
hexCorners[6] = nodeCoords[cornerIndices[6]];
hexCorners[7] = nodeCoords[cornerIndices[7]];
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::markWellPathCells(const std::vector<size_t>& wellPathCells, std::vector<WellSegmentLocation>* locations)
{
std::set<size_t> wellPathCellSet(wellPathCells.begin(), wellPathCells.end());
for (WellSegmentLocation& location : *locations)
{
for (WellSegmentLateral& lateral : location.laterals)
{
for (WellSegmentLateralIntersection& intersection : lateral.intersections)
{
if (wellPathCellSet.find(intersection.cellIndex) != wellPathCellSet.end())
{
intersection.mainBoreCell = true;
}
}
}
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::map<size_t, double> RicWellPathExportCompletionDataFeature::computeLateralsPerCell(const std::vector<WellSegmentLocation>& segmentLocations, bool removeMainBoreCells)
{
std::map<size_t, double> lateralsPerCell;
for (const WellSegmentLocation& location : segmentLocations)
{
for (const WellSegmentLateral& lateral : location.laterals)
{
for (const WellSegmentLateralIntersection& intersection : lateral.intersections)
{
if (removeMainBoreCells && intersection.mainBoreCell) continue;
auto match = lateralsPerCell.find(intersection.cellIndex);
if (match == lateralsPerCell.end())
{
lateralsPerCell[intersection.cellIndex] = 1;
}
else
{
lateralsPerCell[intersection.cellIndex] = match->second + 1;
}
}
}
}
return lateralsPerCell;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
bool RicWellPathExportCompletionDataFeature::wellSegmentLocationOrdering(const WellSegmentLocation& first, const WellSegmentLocation& second)
{
return first.measuredDepth < second.measuredDepth;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
bool RicWellPathExportCompletionDataFeature::isPointBetween(const cvf::Vec3d& pointA, const cvf::Vec3d& pointB, const cvf::Vec3d& needle)
{
cvf::Plane plane;
plane.setFromPointAndNormal(needle, pointB - pointA);
return plane.side(pointA) != plane.side(pointB);
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::filterIntersections(std::vector<HexIntersectionInfo>* intersections)
{
// Erase intersections that are marked as entering
for (auto it = intersections->begin(); it != intersections->end();)
{
if (it->m_isIntersectionEntering)
{
it = intersections->erase(it);
}
else
{
++it;
}
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::vector<WellSegmentLocation> RicWellPathExportCompletionDataFeature::findWellSegmentLocations(const RimEclipseCase* caseToApply, RimWellPath* wellPath)
{
std::vector<WellSegmentLocation> wellSegmentLocations;
for (RimFishbonesMultipleSubs* subs : wellPath->fishbonesCollection()->fishbonesSubs())
{
for (size_t subIndex = 0; subIndex < subs->locationOfSubs().size(); ++subIndex)
{
double measuredDepth = subs->locationOfSubs()[subIndex];
cvf::Vec3d position = wellPath->wellPathGeometry()->interpolatedPointAlongWellPath(measuredDepth);
WellSegmentLocation location = WellSegmentLocation(subs, measuredDepth, -position.z(), subIndex);
for (size_t lateralIndex = 0; lateralIndex < subs->lateralLengths().size(); ++lateralIndex)
{
location.laterals.push_back(WellSegmentLateral(lateralIndex));
}
wellSegmentLocations.push_back(location);
}
}
std::sort(wellSegmentLocations.begin(), wellSegmentLocations.end(), wellSegmentLocationOrdering);
assignBranchAndSegmentNumbers(caseToApply, &wellSegmentLocations);
return wellSegmentLocations;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::calculateLateralIntersections(const RimEclipseCase* caseToApply, WellSegmentLocation* location, int* branchNum, int* segmentNum)
{
for (WellSegmentLateral& lateral : location->laterals)
{
lateral.branchNumber = ++(*branchNum);
std::vector<cvf::Vec3d> coords = location->fishbonesSubs->coordsForLateral(location->subIndex, lateral.lateralIndex);
std::vector<HexIntersectionInfo> intersections = findIntersections(caseToApply->eclipseCaseData(), coords);
filterIntersections(&intersections);
const HexIntersectionInfo* prevIntersection = nullptr;
{
double length = 0;
double depth = 0;
cvf::Vec3d startPoint = coords[0];
auto intersection = intersections.cbegin();
int attachedSegmentNumber = location->segmentNumber;
for (size_t i = 1; i < coords.size() && intersection != intersections.cend(); i++)
{
if (isPointBetween(startPoint, coords[i], intersection->m_intersectionPoint))
{
cvf::Vec3d between = intersection->m_intersectionPoint - startPoint;
length += between.length();
depth += intersection->m_intersectionPoint.z() - startPoint.z();
// Find the direction of the previous cell
if (prevIntersection != nullptr)
{
std::pair<WellSegmentCellDirection, double> direction = calculateDirectionAndDistanceInCell(caseToApply->eclipseCaseData()->mainGrid(), prevIntersection->m_hexIndex, prevIntersection->m_intersectionPoint, intersection->m_intersectionPoint);
WellSegmentLateralIntersection& lateralIntersection = lateral.intersections[lateral.intersections.size() - 1];
lateralIntersection.direction = direction.first;
lateralIntersection.directionLength = direction.second;
}
lateral.intersections.push_back(WellSegmentLateralIntersection(++(*segmentNum), attachedSegmentNumber, intersection->m_hexIndex, length, depth));
length = 0;
depth = 0;
startPoint = intersection->m_intersectionPoint;
attachedSegmentNumber = *segmentNum;
++intersection;
prevIntersection = &*intersection;
}
else
{
const cvf::Vec3d between = coords[i] - startPoint;
length += between.length();
depth += coords[i].z() - startPoint.z();
startPoint = coords[i];
}
}
}
// Find the direction of the last cell
if (prevIntersection != nullptr && !coords.empty())
{
std::pair<WellSegmentCellDirection, double> direction = calculateDirectionAndDistanceInCell(caseToApply->eclipseCaseData()->mainGrid(), prevIntersection->m_hexIndex, prevIntersection->m_intersectionPoint, coords[coords.size()-1]);
WellSegmentLateralIntersection& lateralIntersection = lateral.intersections[lateral.intersections.size() - 1];
lateralIntersection.direction = direction.first;
lateralIntersection.directionLength = direction.second;
}
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::assignBranchAndSegmentNumbers(const RimEclipseCase* caseToApply, std::vector<WellSegmentLocation>* locations)
{
int segmentNumber = 1;
int branchNumber = 1;
// First loop over the locations so that each segment on the main stem is an incremental number
for (WellSegmentLocation& location : *locations)
{
location.segmentNumber = ++segmentNumber;
}
// Then assign branch and segment numbers to each lateral parts
for (WellSegmentLocation& location : *locations)
{
calculateLateralIntersections(caseToApply, &location, &branchNumber, &segmentNumber);
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathExportCompletionDataFeature::calculateCellMainAxisDirections(const RigMainGrid* grid, size_t cellIndex, cvf::Vec3d* iAxisDirection, cvf::Vec3d* jAxisDirection, cvf::Vec3d* kAxisDirection)
{
const std::vector<cvf::Vec3d>& nodeCoords = grid->nodes();
cvf::Vec3d hexCorners[8];
const RigCell& cell = grid->globalCellArray()[cellIndex];
setHexCorners(cell, nodeCoords, hexCorners);
*iAxisDirection = calculateCellMainAxisDirection(hexCorners, cvf::StructGridInterface::FaceType::NEG_I, cvf::StructGridInterface::POS_I);
*jAxisDirection = calculateCellMainAxisDirection(hexCorners, cvf::StructGridInterface::FaceType::NEG_J, cvf::StructGridInterface::POS_J);
*kAxisDirection = calculateCellMainAxisDirection(hexCorners, cvf::StructGridInterface::FaceType::NEG_K, cvf::StructGridInterface::POS_K);
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
cvf::Vec3d RicWellPathExportCompletionDataFeature::calculateCellMainAxisDirection(const cvf::Vec3d* hexCorners, cvf::StructGridInterface::FaceType startFace, cvf::StructGridInterface::FaceType endFace)
{
cvf::ubyte faceVertexIndices[4];
cvf::StructGridInterface::cellFaceVertexIndices(startFace, faceVertexIndices);
cvf::Vec3d startFaceCenter = cvf::GeometryTools::computeFaceCenter(hexCorners[faceVertexIndices[0]], hexCorners[faceVertexIndices[1]], hexCorners[faceVertexIndices[2]], hexCorners[faceVertexIndices[3]]);
cvf::StructGridInterface::cellFaceVertexIndices(endFace, faceVertexIndices);
cvf::Vec3d endFaceCenter = cvf::GeometryTools::computeFaceCenter(hexCorners[faceVertexIndices[0]], hexCorners[faceVertexIndices[1]], hexCorners[faceVertexIndices[2]], hexCorners[faceVertexIndices[3]]);
return endFaceCenter - startFaceCenter;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::pair<WellSegmentCellDirection, double> RicWellPathExportCompletionDataFeature::calculateDirectionAndDistanceInCell(const RigMainGrid* grid, size_t cellIndex, const cvf::Vec3d& startPoint, const cvf::Vec3d& endPoint)
{
cvf::Vec3d vec = endPoint - startPoint;
cvf::Vec3d iAxisDirection;
cvf::Vec3d jAxisDirection;
cvf::Vec3d kAxisDirection;
calculateCellMainAxisDirections(grid, cellIndex, &iAxisDirection, &jAxisDirection, &kAxisDirection);
double iLength = iAxisDirection.dot(vec);
double jLength = jAxisDirection.dot(vec);
double kLength = kAxisDirection.dot(vec);
double iNormalizedLength = abs(iLength / iAxisDirection.length());
double jNormalizedLength = abs(jLength / jAxisDirection.length());
double kNormalizedLength = abs(kLength / kAxisDirection.length());
if (iNormalizedLength > jNormalizedLength && iNormalizedLength > kNormalizedLength)
{
WellSegmentCellDirection direction = POS_I;
if (iLength < 0)
{
direction = NEG_I;
}
return std::make_pair(direction, iLength);
}
else if (jNormalizedLength > iNormalizedLength && jNormalizedLength > kNormalizedLength)
{
WellSegmentCellDirection direction = POS_J;
if (jLength < 0)
{
direction = NEG_J;
}
return std::make_pair(direction, jLength);
}
else
{
WellSegmentCellDirection direction = POS_K;
if (kLength < 0)
{
direction = NEG_K;
}
return std::make_pair(direction, kLength);
}
}

166
ApplicationCode/Commands/WellPathCommands/RicWellPathExportCompletionDataFeature.h
View File

@@ -1,166 +0,0 @@
/////////////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2017 Statoil ASA
//
// ResInsight 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 3 of the License, or
// (at your option) any later version.
//
// ResInsight 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 at <http://www.gnu.org/licenses/gpl.html>
// for more details.
//
/////////////////////////////////////////////////////////////////////////////////
#pragma once
#include "RifEclipseOutputTableFormatter.h"
#include "RigWellLogExtractionTools.h"
#include "RimExportCompletionDataSettings.h"
#include "cafCmdFeature.h"
#include "cvfBoundingBox.h"
class RimWellPath;
class RimEclipseCase;
class RigEclipseCaseData;
class RigMainGrid;
class RigCell;
class RimFishbonesMultipleSubs;
//==================================================================================================
///
//==================================================================================================
enum WellSegmentCellDirection {
POS_I,
NEG_I,
POS_J,
NEG_J,
POS_K,
NEG_K
};
//==================================================================================================
///
//==================================================================================================
struct WellSegmentLateralIntersection {
WellSegmentLateralIntersection(int segmentNumber, int attachedSegmentNumber, size_t cellIndex, double length, double depth)
: segmentNumber(segmentNumber),
attachedSegmentNumber(attachedSegmentNumber),
cellIndex(cellIndex),
length(length),
depth(depth),
direction(POS_I),
directionLength(-1.0),
mainBoreCell(false)
{}
int segmentNumber;
int attachedSegmentNumber;
size_t cellIndex;
bool mainBoreCell;
double length;
double depth;
WellSegmentCellDirection direction;
double directionLength;
};
//==================================================================================================
///
//==================================================================================================
struct WellSegmentLateral {
WellSegmentLateral(size_t lateralIndex) : lateralIndex(lateralIndex) {}
size_t lateralIndex;
int branchNumber;
std::vector<WellSegmentLateralIntersection> intersections;
};
//==================================================================================================
///
//==================================================================================================
struct WellSegmentLocation {
WellSegmentLocation(const RimFishbonesMultipleSubs* subs, double measuredDepth, double trueVerticalDepth, size_t subIndex, int segmentNumber = -1)
: fishbonesSubs(subs),
measuredDepth(measuredDepth),
trueVerticalDepth(trueVerticalDepth),
subIndex(subIndex),
segmentNumber(segmentNumber)
{
}
const RimFishbonesMultipleSubs* fishbonesSubs;
double measuredDepth;
double trueVerticalDepth;
size_t subIndex;
int segmentNumber;
std::vector<WellSegmentLateral> laterals;
};
//==================================================================================================
///
//==================================================================================================
struct EclipseCellIndexRange {
size_t i;
size_t j;
size_t k1;
size_t k2;
};
//==================================================================================================
///
//==================================================================================================
typedef std::tuple<size_t, size_t, size_t> EclipseCellIndex;
//==================================================================================================
///
//==================================================================================================
class RicWellPathExportCompletionDataFeature : public caf::CmdFeature
{
CAF_CMD_HEADER_INIT;
protected:
// Overrides
virtual bool isCommandEnabled() override;
virtual void onActionTriggered(bool isChecked) override;
virtual void setupActionLook(QAction* actionToSetup) override;
private:
static void exportToFolder(RimWellPath* wellPath, const RimExportCompletionDataSettings& exportSettings);
static void generateCompdatTable(RifEclipseOutputTableFormatter& formatter, const RimWellPath* wellPath, const RimExportCompletionDataSettings& settings, const std::vector<WellSegmentLocation>& locations);
static void generateWpimultTable(RifEclipseOutputTableFormatter& formatter, const RimWellPath* wellPath, const RimExportCompletionDataSettings& settings, const std::map<size_t, double>& lateralsPerCell);
static void generateWelsegsTable(RifEclipseOutputTableFormatter& formatter, const RimWellPath* wellPath, const RimExportCompletionDataSettings& settings, const std::vector<WellSegmentLocation>& locations);
static void generateCompsegsTable(RifEclipseOutputTableFormatter& formatter, const RimWellPath* wellPath, const RimExportCompletionDataSettings& settings, const std::vector<WellSegmentLocation>& locations);
static std::map<size_t, double> computeLateralsPerCell(const std::vector<WellSegmentLocation>& segmentLocations, bool removeMainBoreCells);
static std::vector<size_t> findCloseCells(const RigEclipseCaseData* caseData, const cvf::BoundingBox& bb);
static size_t findCellFromCoords(const RigEclipseCaseData* caseData, const cvf::Vec3d& coords);
static std::vector<EclipseCellIndexRange> getCellIndexRange(const RigMainGrid* grid, const std::vector<size_t>& cellIndices);
static bool cellOrdering(const EclipseCellIndex& cell1, const EclipseCellIndex& cell2);
static std::vector<size_t> findIntersectingCells(const RigEclipseCaseData* grid, const std::vector<cvf::Vec3d>& coords);
static void setHexCorners(const RigCell& cell, const std::vector<cvf::Vec3d>& nodeCoords, cvf::Vec3d* hexCorners);
static void markWellPathCells(const std::vector<size_t>& wellPathCells, std::vector<WellSegmentLocation>* locations);
static bool wellSegmentLocationOrdering(const WellSegmentLocation& first, const WellSegmentLocation& second);
static std::vector<HexIntersectionInfo> findIntersections(const RigEclipseCaseData* caseData, const std::vector<cvf::Vec3d>& coords);
static bool isPointBetween(const cvf::Vec3d& pointA, const cvf::Vec3d& pointB, const cvf::Vec3d& needle);
static void filterIntersections(std::vector<HexIntersectionInfo>* intersections);
static std::vector<WellSegmentLocation> findWellSegmentLocations(const RimEclipseCase* caseToApply, RimWellPath* wellPath);
static void calculateLateralIntersections(const RimEclipseCase* caseToApply, WellSegmentLocation* location, int* branchNum, int* segmentNum);
static void assignBranchAndSegmentNumbers(const RimEclipseCase* caseToApply, std::vector<WellSegmentLocation>* locations);
// Calculate direction
static void calculateCellMainAxisDirections(const RigMainGrid* grid, size_t cellIndex, cvf::Vec3d* iAxisDirection, cvf::Vec3d* jAxisDirection, cvf::Vec3d* kAxisDirection);
static cvf::Vec3d calculateCellMainAxisDirection(const cvf::Vec3d* hexCorners, cvf::StructGridInterface::FaceType startFace, cvf::StructGridInterface::FaceType endFace);
static std::pair<WellSegmentCellDirection, double> calculateDirectionAndDistanceInCell(const RigMainGrid* grid, size_t cellIndex, const cvf::Vec3d& startPoint, const cvf::Vec3d& endPoint);
};

103
ApplicationCode/Commands/WellPathCommands/RicWellPathImportCompletionsFileFeature.cpp
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@@ -1,103 +0,0 @@
/////////////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2017 Statoil ASA
//
// ResInsight 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 3 of the License, or
// (at your option) any later version.
//
// ResInsight 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 at <http://www.gnu.org/licenses/gpl.html>
// for more details.
//
/////////////////////////////////////////////////////////////////////////////////
#include "RicWellPathImportCompletionsFileFeature.h"
#include "RiaApplication.h"
#include "RimFishboneWellPathCollection.h"
#include "RimFishbonesCollection.h"
#include "RimProject.h"
#include "RimWellPath.h"
#include "RimWellPathCompletions.h"
#include "RiuMainWindow.h"
#include "cafSelectionManager.h"
#include <QAction>
#include <QFileDialog>
CAF_CMD_SOURCE_INIT(RicWellPathImportCompletionsFileFeature, "RicWellPathImportCompletionsFileFeature");
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
bool RicWellPathImportCompletionsFileFeature::isCommandEnabled()
{
if (RicWellPathImportCompletionsFileFeature::selectedWellPathCollection() != nullptr)
{
return true;
}
return false;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathImportCompletionsFileFeature::onActionTriggered(bool isChecked)
{
RimFishboneWellPathCollection* wellPathCollection = RicWellPathImportCompletionsFileFeature::selectedWellPathCollection();
CVF_ASSERT(wellPathCollection);
// Open dialog box to select well path files
RiaApplication* app = RiaApplication::instance();
QString defaultDir = app->lastUsedDialogDirectory("WELLPATH_DIR");
QStringList wellPathFilePaths = QFileDialog::getOpenFileNames(RiuMainWindow::instance(), "Import Well Path Completions", defaultDir, "Well Path Completions (*.json *.asc *.asci *.ascii *.dev);;All Files (*.*)");
if (wellPathFilePaths.size() < 1) return;
// Remember the path to next time
app->setLastUsedDialogDirectory("WELLPATH_DIR", QFileInfo(wellPathFilePaths.last()).absolutePath());
wellPathCollection->importCompletionsFromFile(wellPathFilePaths);
if (app->project())
{
app->project()->createDisplayModelAndRedrawAllViews();
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RicWellPathImportCompletionsFileFeature::setupActionLook(QAction* actionToSetup)
{
actionToSetup->setText("Import Completions from File");
actionToSetup->setIcon(QIcon(":/Well.png"));
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RimFishboneWellPathCollection* RicWellPathImportCompletionsFileFeature::selectedWellPathCollection()
{
std::vector<caf::PdmObject*> objects;
caf::SelectionManager::instance()->objectsByType(&objects);
if (objects.size() > 0)
{
RimFishboneWellPathCollection* fbWellColl = nullptr;
objects[0]->firstAncestorOrThisOfType(fbWellColl);
return fbWellColl;
}
return nullptr;
}

41
ApplicationCode/Commands/WellPathCommands/RicWellPathImportCompletionsFileFeature.h
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@@ -1,41 +0,0 @@
/////////////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2017 Statoil ASA
//
// ResInsight 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 3 of the License, or
// (at your option) any later version.
//
// ResInsight 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 at <http://www.gnu.org/licenses/gpl.html>
// for more details.
//
/////////////////////////////////////////////////////////////////////////////////
#pragma once
#include "cafCmdFeature.h"
class RimFishboneWellPathCollection;
//==================================================================================================
///
//==================================================================================================
class RicWellPathImportCompletionsFileFeature : public caf::CmdFeature
{
CAF_CMD_HEADER_INIT;
protected:
// Overrides
virtual bool isCommandEnabled() override;
virtual void onActionTriggered( bool isChecked ) override;
virtual void setupActionLook( QAction* actionToSetup ) override;
private:
static RimFishboneWellPathCollection* selectedWellPathCollection();
};