//
// Loop across all points in FaultInterpretation polylines:
// 1. set context to Cube
// 2. set attribute value from Cube (the same as for Horizon in main exercise)
//
private void calcFI(FaultInterpretation fi, SeismicCube cube, ITransaction tr)
{
// Check for Domain
if (cube.Domain != fi.Domain)
{
return;
}
// Lock FaultInterpretation for update
tr.Lock(fi);
FaultProperty fp = findOrCreateFProperty(fi, cube.Template, "Ocean Fault Property", tr);
// Set Cube as a context for FaultInterpretation
List <FaultInterpretationPolyline> chgdPolylines = new List <FaultInterpretationPolyline>();
IEnumerable <FaultInterpretationPolyline> fiPolylines = fi.GetPolylines();
// Process each poly line and set the context for each point.
foreach (FaultInterpretationPolyline poly in fiPolylines)
{
foreach (FaultInterpretationContextPoint pt in poly)
{
// Must cast as Context is IDomainObject and can be SeismicLine2D or SeismicCube.
pt.Context = (IDomainObject)cube;
}
chgdPolylines.Add(poly);
}
fi.SetPolylines(chgdPolylines);
// set attribute's values via PointPropertyRecord, the same way as for Horizon
Index3 cubeIndex = cube.NumSamplesIJK;
foreach (PointPropertyRecord ppr in fp)
{
ppr.Value = double.NaN;
Point3 p = ppr.Geometry;
IndexDouble3 ptIndexDbl = cube.IndexAtPosition(p);
Index3 seisIndex = ptIndexDbl.ToIndex3();
if (seisIndex.I >= 0 && seisIndex.J >= 0 &&
seisIndex.I < cubeIndex.I && seisIndex.J < cubeIndex.J)
{
ITrace trace = cube.GetTrace(seisIndex.I, seisIndex.J);
if (seisIndex.K >= 0 && seisIndex.K < cubeIndex.K)
{
ppr.Value = trace[seisIndex.K];
}
}
}
return;
}
public void workingFunction()
{
maincomboIndex = 0;
SeismicRoot seismicRoot = SeismicRoot.Get(PetrelProject.PrimaryProject);
SeismicProject proj = seismicRoot.SeismicProject;
float[, ,] phi2 = new float[cubeDensity.NumSamplesIJK.I, cubeDensity.NumSamplesIJK.J, cubeDensity.NumSamplesIJK.K];
float[, ,] S2 = new float[cubeDensity.NumSamplesIJK.I, cubeDensity.NumSamplesIJK.J, cubeDensity.NumSamplesIJK.K];
float[, ,] C2 = new float[cubeDensity.NumSamplesIJK.I, cubeDensity.NumSamplesIJK.J, cubeDensity.NumSamplesIJK.K];
float minphi2 = 1.0f;
float maxphi2 = 0.0f;
float minC2 = 1.0f;
float maxC2 = 0.0f;
float minS2 = 1.0f;
float maxS2 = 0.0f;
using (ITransaction txn = DataManager.NewTransaction())
{
try
{
using (IProgress i1 = PetrelLogger.NewProgress(1, cubeDensity.NumSamplesIJK.J))
{
for (int p = 0; p < cubeDensity.NumSamplesIJK.I; p++)
{
for (int q = 0; q < cubeDensity.NumSamplesIJK.J; q++)
{
ITrace trace1 = cubeDensity.GetTrace(p, q);
ITrace trace2 = cubeSonic.GetTrace(p, q);
//ITrace tracePor = PHI_CUBE.GetTrace(p, q);
//ITrace traceSw = SW_CUBE.GetTrace(p, q);
//ITrace traceVSh = VSHALE_CUBE.GetTrace(p, q);
for (int k = 0; k < trace1.Length; k++)
{
double sample1 = trace1[k];
double sample2 = trace2[k];
float rho = (float)sample1;
float Vinv = (float)(1.0 / sample2);
float ac_imp = rho * Vinv;
float error1 = 100e30f;
for (float phi = (float)minPor; phi <= (float)(maxPor + 0.1); phi += 0.1f)
{
for (float S = (float)minWater; S <= (float)(maxWater + 0.1); S += 0.1f)
{
for (float C = (float)minClay; C <= (float)(maxClay + 0.1); C += 0.1f)
{
double error = dfunc(ac_imp, rho, Vinv, C, S, phi);
if (error1 > (float)error)
{
C2[p, q, k] = C;
S2[p, q, k] = S;
phi2[p, q, k] = phi;
error1 = (float)error;
}
}
}
}
updateVals(ac_imp, rho, Vinv, ref C2[p, q, k], ref S2[p, q, k], ref phi2[p, q, k]);
if (phi2[p, q, k] < minphi2)
{
minphi2 = phi2[p, q, k];
}
if (phi2[p, q, k] > maxphi2)
{
maxphi2 = phi2[p, q, k];
}
if (C2[p, q, k] < minC2)
{
minC2 = C2[p, q, k];
}
if (C2[p, q, k] > maxC2)
{
maxC2 = C2[p, q, k];
}
if (S2[p, q, k] < minS2)
{
minS2 = S2[p, q, k];
}
if (S2[p, q, k] > maxS2)
{
maxS2 = S2[p, q, k];
}
}
}
i1.ProgressStatus = p + 1;
}
}
txn.Lock(proj);
txn.Lock(scol);
Index3 size = new Index3(cubeDensity.NumSamplesIJK.I, cubeDensity.NumSamplesIJK.J, cubeDensity.NumSamplesIJK.K);
IndexDouble3 tempindex = new IndexDouble3(0, 0, 0);
Point3 origin = cubeDensity.PositionAtIndex(tempindex);
double d1, d2, d3;
d1 = cubeDensity.PositionAtIndex(new IndexDouble3(1, 0, 0)).X - origin.X;
d2 = cubeDensity.PositionAtIndex(new IndexDouble3(1, 0, 0)).Y - origin.Y;
d3 = cubeDensity.PositionAtIndex(new IndexDouble3(1, 0, 0)).Z - origin.Z;
Vector3 iVec = new Vector3(d1, d2, d3);
d1 = cubeDensity.PositionAtIndex(new IndexDouble3(0, 1, 0)).X - origin.X;
d2 = cubeDensity.PositionAtIndex(new IndexDouble3(0, 1, 0)).Y - origin.Y;
d3 = cubeDensity.PositionAtIndex(new IndexDouble3(0, 1, 0)).Z - origin.Z;
Vector3 jVec = new Vector3(d1, d2, d3);
d1 = cubeDensity.PositionAtIndex(new IndexDouble3(0, 0, 1)).X - origin.X;
d2 = cubeDensity.PositionAtIndex(new IndexDouble3(0, 0, 1)).Y - origin.Y;
d3 = cubeDensity.PositionAtIndex(new IndexDouble3(0, 0, 1)).Z - origin.Z;
Vector3 kVec = new Vector3(d1, d2, d3);
/*double inlineI = (cubeDensity.Lattice.Single.SpacingI) * Math.Sin(cubeDensity.Lattice.Single.RotationJ);
* double inlineJ = (cubeDensity.Lattice.Single.SpacingI) * Math.Cos(cubeDensity.Lattice.Single.RotationJ);
* double crosslineI = (cubeDensity.Lattice.Single.SpacingJ) * Math.Sin(cubeDensity.Lattice.Single.RotationJ);
* double crosslineJ = (cubeDensity.Lattice.Single.SpacingJ) * -Math.Cos(cubeDensity.Lattice.Single.RotationJ);
* Vector3 iSpacing = new Vector3(inlineJ, inlineI, 0.0);
* Vector3 jSpacing = new Vector3(crosslineI, crosslineJ, 0.0);
* Vector3 kSpacing = new Vector3(0.0, 0.0, 3.048);
*/
if (scol.CanCreateSeismicCube(size, origin, iVec, jVec, kVec))
{
Type dataType = typeof(float);
Domain vDomain = cubeDensity.Domain;
IPropertyVersionService pvs = PetrelSystem.PropertyVersionService;
ILogTemplate glob = pvs.FindTemplateByMnemonics("Seismic");
PropertyVersion pv = pvs.FindOrCreate(glob);
//PropertyVersion pv = cubeDensity.PropertyVersion;
Range1 <double> r1 = new Range1 <double>(minphi2, maxphi2);
Range1 <double> r2 = new Range1 <double>(minS2, maxS2);
Range1 <double> r3 = new Range1 <double>(minC2, maxC2);
PetrelLogger.InfoOutputWindow("OUTPUT TEMPLATE UNDER PROCESS");
try
{
PHI_CUBE = scol.CreateSeismicCube(size, origin, iVec, jVec, kVec, dataType, vDomain, pv, r1);
SW_CUBE = scol.CreateSeismicCube(size, origin, iVec, jVec, kVec, dataType, vDomain, pv, r2);
VSHALE_CUBE = scol.CreateSeismicCube(size, origin, iVec, jVec, kVec, dataType, vDomain, pv, r3);
}
catch (System.InvalidOperationException e)
{
PetrelLogger.ErrorBox(e.Message);
}
catch (System.ArgumentNullException e)
{
PetrelLogger.InfoOutputWindow(e.Message);
}
}
PHI_CUBE.Name = porCube;
SW_CUBE.Name = waterCube;
VSHALE_CUBE.Name = clayCube;
if (PHI_CUBE.IsWritable)
{
using (ITransaction txn1 = DataManager.NewTransaction())
{
PetrelLogger.InfoOutputWindow("Writing Data in the Porosity cube");
Index3 start = new Index3(0, 0, 0);
Index3 end = new Index3(cubeDensity.NumSamplesIJK.I - 1, cubeDensity.NumSamplesIJK.J - 1, cubeDensity.NumSamplesIJK.K - 1);
ISubCube to = cubeDensity.GetSubCube(start, end);
to.CopyFrom(phi2);
txn1.Commit();
}
}
if (SW_CUBE.IsWritable)
{
using (ITransaction txn1 = DataManager.NewTransaction())
{
PetrelLogger.InfoOutputWindow("Writing Data in the Water Saturation cube");
Index3 start = new Index3(0, 0, 0);
Index3 end = new Index3(cubeDensity.NumSamplesIJK.I - 1, cubeDensity.NumSamplesIJK.J - 1, cubeDensity.NumSamplesIJK.K - 1);
ISubCube to = cubeDensity.GetSubCube(start, end);
to.CopyFrom(S2);
txn1.Commit();
}
}
if (VSHALE_CUBE.IsWritable)
{
using (ITransaction txn1 = DataManager.NewTransaction())
{
PetrelLogger.InfoOutputWindow("Writing Data in the Shale Volume cube");
Index3 start = new Index3(0, 0, 0);
Index3 end = new Index3(cubeDensity.NumSamplesIJK.I - 1, cubeDensity.NumSamplesIJK.J - 1, cubeDensity.NumSamplesIJK.K - 1);
ISubCube to = cubeDensity.GetSubCube(start, end);
to.CopyFrom(C2);
txn1.Commit();
}
}
txn.Commit();
PetrelLogger.InfoOutputWindow("OUTPUT CUBES' Construction completed");
}
catch (ArgumentNullException e)
{
PetrelLogger.ErrorBox("Seismic cube name or propertyVersion can not be blank (null)" + e.Message);
}
}
}
public override void ExecuteSimple()
{
SeismicCube cube = arguments.Cube;
HorizonInterpretation hzInterp1 = arguments.HzInterpretation1;
HorizonInterpretation hzInterp2 = arguments.HzInterpretation2;
int interval = 3;
Hashtable ht2 = new Hashtable();
foreach (Point3 item in hzInterp2.GetPoints(cube.SeismicCollection))
{
IndexDouble3 ptIndexDbl = cube.IndexAtPosition(item);
Index3 seisIndex = ptIndexDbl.ToIndex3();
ht2.Add(seisIndex.I.ToString() + "-" + seisIndex.J.ToString(), ptIndexDbl.K);
//PetrelLogger.InfoOutputWindow(ptIndexDbl.I.ToString() + "-" + ptIndexDbl.J.ToString() + "-" + ptIndexDbl.K.ToString());
//PetrelLogger.InfoOutputWindow(seisIndex.I.ToString()+"-"+ seisIndex.J.ToString()+"-"+ seisIndex.K.ToString());
}
// Make sure we have input arguments
if (cube == null || hzInterp1 == null || hzInterp2 == null)
{
PetrelLogger.InfoOutputWindow("HelloSeismic: Arguments cannot be empty");
return;
}
// Make sure we have input arguments
if (cube.Domain != hzInterp1.Domain)
{
PetrelLogger.InfoOutputWindow("HelloSeismic: Cube and Horizon must be in the same domain");
return;
}
// Start a transaction
using (ITransaction t = DataManager.NewTransaction())
{
// Create an output horizon property if the user didn't supply one.
HorizonInterpretation3D hzInt3D = hzInterp1.GetHorizonInterpretation3D(cube.SeismicCollection);
t.Lock(hzInt3D);
// Create the property
// Template of the cube is the correct template
HorizonProperty3D horizonProp3D1 = hzInt3D.CreateProperty(cube.Template);
HorizonProperty3D horizonProp3D2 = hzInt3D.CreateProperty(cube.Template);
// cache cube indexes
Index3 cubeIndex = cube.NumSamplesIJK;
List <HorizonProperty3DSample> p1_1 = new List <HorizonProperty3DSample>();
List <HorizonProperty3DSample> p1_2 = new List <HorizonProperty3DSample>();
// Process the horizon property points.
foreach (PointPropertyRecord ppr in horizonProp3D1)
{
// do not need to initialize the output value, Petrel does this when the property is created initially
// ppr.Value = double.NaN;
// Get the location for the point
Point3 p = ppr.Geometry;
// Find the seismic sample at the point
IndexDouble3 ptIndexDbl = cube.IndexAtPosition(p);
Index3 seisIndex = ptIndexDbl.ToIndex3();
object obj = ht2[seisIndex.I.ToString() + "-" + seisIndex.J.ToString()];
if (obj == null)
{
continue;
}
double z2 = double.Parse(obj.ToString());
double z1_1 = double.NaN;
double z1_2 = double.NaN;
if (z2 != null)
{
z1_1 = ptIndexDbl.K - (ptIndexDbl.K - z2) / 3;
z1_2 = ptIndexDbl.K - 2 * (ptIndexDbl.K - z2) / 3;
}
// Get the trace containing the seismic sample
// SeismicCube.GetTrace(i, j) will throw an exception if the indices (i,j) is out of range.
if (seisIndex.I >= 0 && seisIndex.J >= 0 &&
seisIndex.I < cubeIndex.I && seisIndex.J < cubeIndex.J)
{
ITrace trace = cube.GetTrace(seisIndex.I, seisIndex.J);
p1_1.Add(new HorizonProperty3DSample(seisIndex.I, seisIndex.J, trace[Convert.ToInt32(z1_1)]));
p1_2.Add(new HorizonProperty3DSample(seisIndex.I, seisIndex.J, trace[Convert.ToInt32(z1_2)]));
}
}
horizonProp3D1.Samples = p1_1;
horizonProp3D2.Samples = p1_2;
// Commit the changes to the data.
t.Commit();
}
return;
}
public override void ExecuteSimple()
{
#region main exercise
SeismicCube cube = arguments.Cube;
HorizonInterpretation hzInterp = arguments.HzInterpretation;
HorizonProperty3D horizonProp3D = arguments.HorizonProp3D;
// Make sure we have input arguments
if (cube == null || hzInterp == null)
{
PetrelLogger.InfoOutputWindow("HelloSeismic: Arguments cannot be empty");
return;
}
// Make sure we have input arguments
if (cube.Domain != hzInterp.Domain)
{
PetrelLogger.InfoOutputWindow("HelloSeismic: Cube and Horizon must be in the same domain");
return;
}
// Start a transaction
using (ITransaction t = DataManager.NewTransaction())
{
// Create an output horizon property if the user didn't supply one.
if (horizonProp3D == null)
{
// get 3D part of the interpretation corresponding to cube's seismic collection
HorizonInterpretation3D hzInt3D = hzInterp.GetHorizonInterpretation3D(cube.SeismicCollection);
if (hzInt3D == null)
{
PetrelLogger.InfoOutputWindow("HelloSeismic: Unable to get Horizon Interpretation 3D from HzInt");
return;
}
t.Lock(hzInt3D);
// Create the property
// Template of the cube is the correct template
horizonProp3D = hzInt3D.CreateProperty(cube.Template);
}
else
{
// Lock the property so we can update it
t.Lock(horizonProp3D);
}
// cache cube indexes
Index3 cubeIndex = cube.NumSamplesIJK;
// Process the horizon property points.
foreach (PointPropertyRecord ppr in horizonProp3D)
{
// do not need to initialize the output value, Petrel does this when the property is created initially
// ppr.Value = double.NaN;
// Get the location for the point
Point3 p = ppr.Geometry;
// Find the seismic sample at the point
IndexDouble3 ptIndexDbl = cube.IndexAtPosition(p);
Index3 seisIndex = ptIndexDbl.ToIndex3();
// Get the trace containing the seismic sample
// SeismicCube.GetTrace(i, j) will throw an exception if the indices (i,j) is out of range.
if (seisIndex.I >= 0 && seisIndex.J >= 0 &&
seisIndex.I < cubeIndex.I && seisIndex.J < cubeIndex.J)
{
ITrace trace = cube.GetTrace(seisIndex.I, seisIndex.J);
// trace[k] will throw an exception if the index k is out of range.
// Set the property value to the corresponding trace sample value.
if (seisIndex.K >= 0 && seisIndex.K < cubeIndex.K)
{
ppr.Value = trace[seisIndex.K];
}
}
}
// Commit the changes to the data.
t.Commit();
// Set up the output argument value
arguments.HorizonProp3D = horizonProp3D;
}
#endregion
#region Challenging part, body
//
// Compute an attribute for all fault's interpretations under the SeismicProject
//
// Navigate to SeismicProject and loop through all collections
SeismicRoot sr = SeismicRoot.Get(PetrelProject.PrimaryProject);
SeismicProject sp = sr.SeismicProject;
// First part of lab checked for a cube, so project exists at this point,
// else something like: if (sp == SeismicProject.NullObject) return;
// some object can be transaction locked inside, need to commit before exit
using (ITransaction tr = DataManager.NewTransaction())
{
foreach (InterpretationCollection ic in sp.InterpretationCollections)
{
loopIC(ic, cube, tr);
}
tr.Commit();
}
#endregion
return;
}