public SB getFileAsString(String entryName) { for (int i = 0; i < directory.size(); i++) { CompoundDocDirEntry thisEntry = directory.get(i); if (thisEntry.entryName.equals(entryName)) return getEntryAsString(thisEntry, false); } return new SB(); }
Object createAtomSeCollectionFromArrayData( List<Object> arrayData, Map<String, Object> htParams, boolean isAppend) { // NO STATE SCRIPT -- HERE WE ARE TRYING TO CONSERVE SPACE Logger.info("FileManager.getAtomSetCollectionFromArrayData(Vector)"); int nModels = arrayData.size(); String[] fullPathNames = new String[nModels]; DataReader[] readers = new DataReader[nModels]; for (int i = 0; i < nModels; i++) { fullPathNames[i] = "String[" + i + "]"; readers[i] = newDataReader(arrayData.get(i)); } JmolFilesReaderInterface filesReader = newFilesReader(fullPathNames, fullPathNames, null, readers, htParams, isAppend); filesReader.run(); return filesReader.getAtomSetCollection(); }
/** * Sets all local file references in a script file to point to files within dataPath. If a file * reference contains dataPath, then the file reference is left with that RELATIVE path. * Otherwise, it is changed to a relative file name within that dataPath. * * <p>Only file references starting with "file://" are changed. * * @param script * @param dataPath * @param isLocal * @return revised script */ private static String setScriptFileRefs(String script, String dataPath, boolean isLocal) { if (dataPath == null) return script; boolean noPath = (dataPath.length() == 0); List<String> fileNames = new List<String>(); JmolBinary.getFileReferences(script, fileNames); List<String> oldFileNames = new List<String>(); List<String> newFileNames = new List<String>(); int nFiles = fileNames.size(); for (int iFile = 0; iFile < nFiles; iFile++) { String name0 = fileNames.get(iFile); String name = name0; if (isLocal == isLocal(name)) { int pt = (noPath ? -1 : name.indexOf("/" + dataPath + "/")); if (pt >= 0) { name = name.substring(pt + 1); } else { pt = name.lastIndexOf("/"); if (pt < 0 && !noPath) name = "/" + name; if (pt < 0 || noPath) pt++; name = dataPath + name.substring(pt); } } Logger.info("FileManager substituting " + name0 + " --> " + name); oldFileNames.addLast("\"" + name0 + "\""); newFileNames.addLast("\1\"" + name + "\""); } return Txt.replaceStrings(script, oldFileNames, newFileNames); }
public String getDirectoryListing(String separator) { String str = ""; for (int i = 0; i < directory.size(); i++) { CompoundDocDirEntry thisEntry = directory.get(i); if (!thisEntry.isEmpty) str += separator + thisEntry.entryName + "\tlen=" + thisEntry.lenStream + "\tSID=" + thisEntry.SIDfirstSector + (thisEntry.isStandard ? "\tfileOffset=" + getOffset(thisEntry.SIDfirstSector) : ""); } return str; }
/** * reads a compound document directory and saves all data in a Hashtable so that the files may be * organized later in a different order. Also adds a #Directory_Listing entry. * * <p>Files are bracketed by BEGIN Directory Entry and END Directory Entry lines, similar to * ZipUtil.getAllData. * * @param prefix * @param binaryFileList |-separated list of files that should be saved as xx xx xx hex byte * strings. The directory listing is appended with ":asBinaryString" * @param fileData */ @Override public void getAllDataMapped(String prefix, String binaryFileList, Map<String, String> fileData) { fileData.put("#Directory_Listing", getDirectoryListing("|")); binaryFileList = "|" + binaryFileList + "|"; for (int i = 0; i < directory.size(); i++) { CompoundDocDirEntry thisEntry = directory.get(i); if (!thisEntry.isEmpty && thisEntry.entryType != 5) { String name = thisEntry.entryName; Logger.info("CompoundDocument file " + name); boolean isBinary = (binaryFileList.indexOf("|" + name + "|") >= 0); if (isBinary) name += ":asBinaryString"; SB data = new SB(); data.append("BEGIN Directory Entry ").append(name).append("\n"); data.appendSB(getEntryAsString(thisEntry, isBinary)); data.append("\nEND Directory Entry ").append(name).append("\n"); fileData.put(prefix + "/" + name, data.toString()); } } close(); }
/** * We build two data structures for each slater: * * <p>int[] slaterInfo[] = {iatom, a, b, c, d} float[] slaterData[] = {zeta, coef} * * <p>where * * <p>psi = (coef)(x^a)(y^b)(z^c)(r^d)exp(-zeta*r) * * <p>Mopac: a == -2 ==> z^2 ==> (coef)(2z^2-x^2-y^2)(r^d)exp(-zeta*r) and: b == -2 ==> * (coef)(x^2-y^2)(r^d)exp(-zeta*r) * * @param iAtom * @param a * @param b * @param c * @param d * @param zeta * @param coef */ protected final void addSlater(int iAtom, int a, int b, int c, int d, double zeta, float coef) { System.out.println( "SlaterReader " + slaters.size() + ": " + iAtom + " " + a + " " + b + " " + c + " " + d + " " + zeta + " " + coef); slaters.addLast(new SlaterData(iAtom, a, b, c, d, zeta, coef)); }
@Override public SB getAllDataFiles(String binaryFileList, String firstFile) { if (firstFile != null) { for (int i = 0; i < directory.size(); i++) { CompoundDocDirEntry thisEntry = directory.get(i); if (thisEntry.entryName.equals(firstFile)) { directory.remove(i); directory.add(1, thisEntry); // after ROOT_ENTRY break; } } } data = new SB(); data.append("Compound Document File Directory: "); data.append(getDirectoryListing("|")); data.append("\n"); binaryFileList = "|" + binaryFileList + "|"; for (int i = 0; i < directory.size(); i++) { CompoundDocDirEntry thisEntry = directory.get(i); Logger.info("reading " + thisEntry.entryName); if (!thisEntry.isEmpty && thisEntry.entryType != 5) { String name = thisEntry.entryName; if (name.endsWith(".gz")) name = name.substring(0, name.length() - 3); data.append("BEGIN Directory Entry ").append(name).append("\n"); data.appendSB( getEntryAsString( thisEntry, binaryFileList.indexOf("|" + thisEntry.entryName + "|") >= 0)); data.append("\n"); data.append("END Directory Entry ").append(thisEntry.entryName).append("\n"); } } close(); return data; }
/** * after the vectors intinfo and floatinfo are completed, we * * @param doScale * @param doSort TODO */ protected final void setSlaters(boolean doScale, boolean doSort) { if (slaterArray == null) { int nSlaters = slaters.size(); slaterArray = new SlaterData[nSlaters]; for (int i = 0; i < slaterArray.length; i++) slaterArray[i] = slaters.get(i); } if (doScale) for (int i = 0; i < slaterArray.length; i++) { SlaterData sd = slaterArray[i]; sd.coef *= scaleSlater(sd.x, sd.y, sd.z, sd.r, sd.zeta); if (Logger.debugging) { Logger.debug( "SlaterReader " + i + ": " + sd.iAtom + " " + sd.x + " " + sd.y + " " + sd.z + " " + sd.r + " " + sd.zeta + " " + sd.coef); } } if (doSort) { Arrays.sort(slaterArray, new SlaterSorter()); int[] pointers = new int[slaterArray.length]; for (int i = 0; i < slaterArray.length; i++) pointers[i] = slaterArray[i].index; sortOrbitalCoefficients(pointers); } moData.put("slaters", slaterArray); atomSetCollection.setAtomSetAuxiliaryInfo("moData", moData); }
private void getDirectoryTable() { int thisSID = header.SID_DIR_start; CompoundDocDirEntry thisEntry; rootEntry = null; try { while (thisSID > 0) { gotoSector(thisSID); for (int j = nDirEntriesperSector; --j >= 0; ) { thisEntry = new CompoundDocDirEntry(this); thisEntry.readData(); if (thisEntry.lenStream > 0) { directory.addLast(thisEntry); // System.out.println(thisEntry.entryName); } if (thisEntry.entryType == 5) rootEntry = thisEntry; } thisSID = SAT[thisSID]; } } catch (Exception e) { Logger.errorEx(null, e); } if (Logger.debugging) Logger.debug("CompoundDocument directory entry: \n" + getDirectoryListing("\n")); }
@Override protected void outputSurface( P3[] vertices, V3[] normals, short[] colixes, int[][] indices, short[] polygonColixes, int nVertices, int nPolygons, int nFaces, BS bsPolygons, int faceVertexMax, short colix, List<Short> colorList, Map<Short, Integer> htColixes, P3 offset) { if (polygonColixes != null) { boolean isAll = (bsPolygons == null); int i0 = (isAll ? nPolygons - 1 : bsPolygons.nextSetBit(0)); for (int i = i0; i >= 0; i = (isAll ? i - 1 : bsPolygons.nextSetBit(i + 1))) { // if ((p++) % 10 == 0) // output("\n"); output("polygon { 4\n"); for (int j = 0; j <= 3; j++) outputVertex(vertices[indices[i][j % 3]], offset); output("\n"); output("pigment{rgbt<" + color4(colix = polygonColixes[i]) + ">}\n"); output(" translucentFinish(" + translucencyFractionalFromColix(colix) + ")\n"); output(" check_shadow()\n"); output(" clip()\n"); output("}\n"); } return; } output("mesh2 {\n"); output("vertex_vectors { " + nVertices); for (int i = 0; i < nVertices; i++) outputVertex(vertices[i], offset); output("\n}\n"); boolean haveNormals = (normals != null); if (haveNormals) { output("normal_vectors { " + nVertices); for (int i = 0; i < nVertices; i++) { setTempVertex(vertices[i], offset, tempP2); output(getScreenNormal(tempP2, normals[i], 1)); output("\n"); } output("\n}\n"); } if (colixes != null) { int nColix = colorList.size(); output("texture_list { " + nColix); // just using the transparency of the first colix there... String finish = ">}" + " translucentFinish(" + translucencyFractionalFromColix(colixes[0]) + ")}"; for (int i = 0; i < nColix; i++) output("\n, texture{pigment{rgbt<" + color4(colorList.get(i).shortValue()) + finish); output("\n}\n"); } output("face_indices { " + nFaces); boolean isAll = (bsPolygons == null); int i0 = (isAll ? nPolygons - 1 : bsPolygons.nextSetBit(0)); for (int i = i0; i >= 0; i = (isAll ? i - 1 : bsPolygons.nextSetBit(i + 1))) { output(", <" + getTriad(indices[i]) + ">"); if (colixes != null) { output("," + htColixes.get(Short.valueOf(colixes[indices[i][0]]))); output("," + htColixes.get(Short.valueOf(colixes[indices[i][1]]))); output("," + htColixes.get(Short.valueOf(colixes[indices[i][2]]))); } if (faceVertexMax == 4 && indices[i].length == 4) { output(", <" + indices[i][0] + "," + indices[i][2] + "," + indices[i][3] + ">"); if (colixes != null) { output("," + htColixes.get(Short.valueOf(colixes[indices[i][0]]))); output("," + htColixes.get(Short.valueOf(colixes[indices[i][2]]))); output("," + htColixes.get(Short.valueOf(colixes[indices[i][3]]))); } } output("\n"); } output("\n}\n"); if (colixes == null) { output("pigment{rgbt<" + color4(colix) + ">}\n"); output(" translucentFinish(" + translucencyFractionalFromColix(colix) + ")\n"); } output(" check_shadow()\n"); output(" clip()\n"); output("}\n"); /* mesh2 { vertex_vectors { 9, <0,0,0>, <0.5,0,0>, <0.5,0.5,0>, <1,0,0>, <1,0.5,0>, <1,1,0> <0.5,1,0>, <0,1,0>, <0,0.5,0> } normal_vectors { 9, <-1,-1,0>, <0,-1,0>, <0,0,1>, <1,-1,0>, <1,0,0>, <1,1,0>, <0,1,0>, <-1,1,0>, <-1,0,0> } texture_list { 3, texture{pigment{rgb <0,0,1>}}, texture{pigment{rgb 1}}, texture{pigment{rgb <1,0,0>}} } face_indices { 8, <0,1,2>,0,1,2, <1,3,2>,1,0,2, <3,4,2>,0,1,2, <4,5,2>,1,0,2, <5,6,2>,0,1,2, <6,7,2>,1,0,2, <7,8,2>,0,1,2, <8,0,2>,1,0,2 } } */ }
/** * @param distance a distance from a plane or point * @param plane a slabbing plane * @param ptCenters a set of atoms to measure distance from * @param vData when not null, this is a query, not an actual slabbing * @param fData vertex values or other data to overlay * @param bsSource TODO * @param meshSurface second surface; not implemented -- still some problems there * @param andCap to cap this off, crudely only * @param doClean compact set - draw only * @param tokType type of slab * @param isGhost translucent slab, so we mark slabbed triangles */ public void getIntersection( float distance, P4 plane, P3[] ptCenters, List<P3[]> vData, float[] fData, BS bsSource, MeshSurface meshSurface, boolean andCap, boolean doClean, int tokType, boolean isGhost) { boolean isSlab = (vData == null); P3[] pts = null; if (fData == null) { if (tokType == T.decimal && bsSource != null) { fData = new float[vertexCount]; for (int i = 0; i < vertexCount; i++) if ((fData[i] = vertexSource[i]) == -1) System.out.println("meshsurface hmm"); } else { fData = vertexValues; } } Map<String, Integer> mapEdge = new Hashtable<String, Integer>(); /* Vector3f vNorm = null; Vector3f vBC = null; Vector3f vAC = null; Point3f[] pts2 = null; Vector3f vTemp3 = null; Point4f planeTemp = null; boolean isMeshIntersect = (meshSurface != null); if (isMeshIntersect) { // NOT IMPLEMENTED vBC = new Vector3f(); vAC = new Vector3f(); vNorm = new Vector3f(); plane = new Point4f(); planeTemp = new Point4f(); vTemp3 = new Vector3f(); pts2 = new Point3f[] { null, new Point3f(), new Point3f() }; } */ if (ptCenters != null || isGhost) andCap = false; // can only cap faces, and no capping of ghosts float[] values = new float[2]; float[] fracs = new float[2]; double absD = Math.abs(distance); float d1, d2, d3, valA, valB, valC; int sourceA = 0, sourceB = 0, sourceC = 0, setA = 0; List<int[]> iPts = (andCap ? new List<int[]>() : null); if (polygonCount == 0) { for (int i = mergeVertexCount0; i < vertexCount; i++) { if (Float.isNaN(fData[i]) || checkSlab(tokType, vertices[i], fData[i], distance, plane, ptCenters, bsSource) > 0) bsSlabDisplay.clear(i); } return; } int iLast = polygonCount; for (int i = mergePolygonCount0; i < iLast; i++) { if (!setABC(i)) continue; BS bsSlab = (bsSlabGhost != null && bsSlabGhost.get(i) ? bsSlabGhost : bsSlabDisplay); int check1 = polygonIndexes[i][3]; int check2 = (checkCount == 2 ? polygonIndexes[i][4] : 0); P3 vA = vertices[iA]; P3 vB = vertices[iB]; P3 vC = vertices[iC]; valA = fData[iA]; valB = fData[iB]; valC = fData[iC]; if (vertexSource != null) { sourceA = vertexSource[iA]; sourceB = vertexSource[iB]; sourceC = vertexSource[iC]; } if (vertexSets != null) setA = vertexSets[iA]; d1 = checkSlab( tokType, vA, valA, (bsSource == null ? distance : sourceA), plane, ptCenters, bsSource); d2 = checkSlab( tokType, vB, valB, (bsSource == null ? distance : sourceB), plane, ptCenters, bsSource); d3 = checkSlab( tokType, vC, valC, (bsSource == null ? distance : sourceC), plane, ptCenters, bsSource); int test1 = (d1 != 0 && d1 < 0 ? 1 : 0) + (d2 != 0 && d2 < 0 ? 2 : 0) + (d3 != 0 && d3 < 0 ? 4 : 0); /* if (iA == 955 || iB == 955 || iC == 955) { System.out.println(i + " " + iA + " " + iB + " " + iC + " "+ d1 + " " + d2 + " " + d3 + " " + test1); System.out.println("testing messhsurf "); } */ /* if (isMeshIntersect && test1 != 7 && test1 != 0) { // NOT IMPLEMENTED boolean isOK = (d1 == 0 && d2 * d3 >= 0 || d2 == 0 && (d1 * d3) >= 0 || d3 == 0 && d1 * d2 >= 0); if (isOK) continue; // We have a potential crossing. Now to find the exact point of crossing // the other isosurface. if (checkIntersection(vA, vB, vC, meshSurface, pts2, vNorm, vBC, vAC, plane, planeTemp, vTemp3)) { iD = addIntersectionVertex(pts2[0], 0, sourceA, mapEdge, -1, -1); // have to choose some source addPolygon(iA, iB, iD, check1 & 1, check2, 0, bsSlabDisplay); addPolygon(iD, iB, iC, check1 & 2, check2, 0, bsSlabDisplay); addPolygon(iA, iD, iC, check1 & 4, check2, 0, bsSlabDisplay); test1 = 0; // toss original iLast = polygonCount; } else { // process normally for now // not fully implemented -- need to check other way as well. } } */ switch (test1) { default: case 7: case 0: // all on the same side break; case 1: case 6: // BC on same side if (ptCenters == null) pts = new P3[] { interpolatePoint(vA, vB, -d1, d2, valA, valB, values, fracs, 0), interpolatePoint(vA, vC, -d1, d3, valA, valC, values, fracs, 1) }; else pts = new P3[] { interpolateSphere(vA, vB, -d1, -d2, absD, valA, valB, values, fracs, 0), interpolateSphere(vA, vC, -d1, -d3, absD, valA, valC, values, fracs, 1) }; break; case 2: case 5: // AC on same side if (ptCenters == null) pts = new P3[] { interpolatePoint(vB, vA, -d2, d1, valB, valA, values, fracs, 1), interpolatePoint(vB, vC, -d2, d3, valB, valC, values, fracs, 0) }; else pts = new P3[] { interpolateSphere(vB, vA, -d2, -d1, absD, valB, valA, values, fracs, 1), interpolateSphere(vB, vC, -d2, -d3, absD, valB, valC, values, fracs, 0) }; break; case 3: case 4: // AB on same side need A-C, B-C if (ptCenters == null) pts = new P3[] { interpolatePoint(vC, vA, -d3, d1, valC, valA, values, fracs, 0), interpolatePoint(vC, vB, -d3, d2, valC, valB, values, fracs, 1) }; else pts = new P3[] { interpolateSphere(vC, vA, -d3, -d1, absD, valC, valA, values, fracs, 0), interpolateSphere(vC, vB, -d3, -d2, absD, valC, valB, values, fracs, 1) }; break; } doClear = true; doGhost = isGhost; doCap = andCap; BS bs; // adjust for minor discrepencies // for (int j = 0; j < 2; j++) // if (fracs[j] == 0) // fracs[1 - j] = (fracs[1 - j] < 0.5 ? 0 : 1); if (isSlab) { // iD = iE = -1; switch (test1) { // A // / \ // B---C case 0: // all on the same side -- toss doCap = false; break; case 7: // all on the same side -- keep continue; case 1: case 6: // 0 A 0 // / \ // 0 -------- 1 // / \ // 1 B-------C 1 boolean tossBC = (test1 == 1); if (tossBC || isGhost) { // 1: BC on side to toss -- +tossBC+isGhost -tossBC+isGhost if (!getDE(fracs, 0, iA, iB, iC, tossBC)) break; if (iD < 0) iD = addIntersectionVertex(pts[0], values[0], sourceA, setA, mapEdge, iA, iB); if (iE < 0) iE = addIntersectionVertex(pts[1], values[1], sourceA, setA, mapEdge, iA, iC); bs = (tossBC ? bsSlab : bsSlabGhost); addPolygonV3(iA, iD, iE, check1 & 5 | 2, check2, 0, bs); if (!isGhost) break; } // BC on side to keep -- -tossBC+isGhost, +tossBC+isGhost if (!getDE(fracs, 1, iA, iC, iB, tossBC)) break; bs = (tossBC ? bsSlabGhost : bsSlab); if (iE < 0) { iE = addIntersectionVertex(pts[0], values[0], sourceB, setA, mapEdge, iA, iB); addPolygonV3(iE, iB, iC, check1 & 3, check2, 0, bs); } if (iD < 0) { iD = addIntersectionVertex(pts[1], values[1], sourceC, setA, mapEdge, iA, iC); addPolygonV3(iD, iE, iC, check1 & 4 | 1, check2, 0, bs); } break; case 5: case 2: // A // \/ \ // /\ \ // B--\--C // \ // boolean tossAC = (test1 == 2); if (tossAC || isGhost) { // AC on side to toss if (!getDE(fracs, 0, iB, iC, iA, tossAC)) break; bs = (tossAC ? bsSlab : bsSlabGhost); if (iE < 0) iE = addIntersectionVertex(pts[0], values[0], sourceB, setA, mapEdge, iB, iA); if (iD < 0) iD = addIntersectionVertex(pts[1], values[1], sourceB, setA, mapEdge, iB, iC); addPolygonV3(iE, iB, iD, check1 & 3 | 4, check2, 0, bs); if (!isGhost) break; } // AC on side to keep if (!getDE(fracs, 1, iB, iA, iC, tossAC)) break; bs = (tossAC ? bsSlabGhost : bsSlab); if (iD < 0) { iD = addIntersectionVertex(pts[0], values[0], sourceA, setA, mapEdge, iB, iA); addPolygonV3(iA, iD, iC, check1 & 5, check2, 0, bs); } if (iE < 0) { iE = addIntersectionVertex(pts[1], values[1], sourceC, setA, mapEdge, iB, iC); addPolygonV3(iD, iE, iC, check1 & 2 | 1, check2, 0, bs); } break; case 4: case 3: // A // / \/ // / /\ // B--/--C // / // boolean tossAB = (test1 == 4); if (tossAB || isGhost) { if (!getDE(fracs, 0, iC, iA, iB, tossAB)) break; if (iD < 0) iD = addIntersectionVertex(pts[0], values[0], sourceC, setA, mapEdge, iA, iC); // CA if (iE < 0) iE = addIntersectionVertex(pts[1], values[1], sourceC, setA, mapEdge, iB, iC); // CB bs = (tossAB ? bsSlab : bsSlabGhost); addPolygonV3(iD, iE, iC, check1 & 6 | 1, check2, 0, bs); if (!isGhost) break; } // AB on side to keep if (!getDE(fracs, 1, iC, iB, iA, tossAB)) break; bs = (tossAB ? bsSlabGhost : bsSlab); if (iE < 0) { iE = addIntersectionVertex(pts[0], values[0], sourceA, setA, mapEdge, iA, iC); // CA addPolygonV3(iA, iB, iE, check1 & 5, check2, 0, bs); } if (iD < 0) { iD = addIntersectionVertex(pts[1], values[1], sourceB, setA, mapEdge, iB, iC); // CB addPolygonV3(iE, iB, iD, check1 & 2 | 4, check2, 0, bs); } break; } if (doClear) { bsSlab.clear(i); if (doGhost) bsSlabGhost.set(i); } if (doCap) { iPts.addLast(new int[] {iD, iE}); } } else if (pts != null) { vData.addLast(pts); } } if (andCap && iPts.size() > 0) { P3 center = new P3(); for (int i = iPts.size(); --i >= 0; ) { int[] ipts = iPts.get(i); center.add(vertices[ipts[0]]); center.add(vertices[ipts[1]]); } center.scale(0.5f / iPts.size()); int v0 = addIntersectionVertex(center, 0, -1, setA, mapEdge, -1, -1); for (int i = iPts.size(); --i >= 0; ) { int[] ipts = iPts.get(i); // int p = addPolygonV3(ipts[0], v0, ipts[1], 0, 0, 0, bsSlabDisplay); } } if (!doClean) return; BS bsv = new BS(); BS bsp = new BS(); for (int i = 0; i < polygonCount; i++) { if (polygonIndexes[i] == null) continue; bsp.set(i); for (int j = 0; j < 3; j++) bsv.set(polygonIndexes[i][j]); } int n = 0; int nPoly = bsp.cardinality(); if (nPoly != polygonCount) { int[] map = new int[vertexCount]; for (int i = 0; i < vertexCount; i++) if (bsv.get(i)) map[i] = n++; P3[] vTemp = new P3[n]; n = 0; for (int i = 0; i < vertexCount; i++) if (bsv.get(i)) vTemp[n++] = vertices[i]; int[][] pTemp = AU.newInt2(nPoly); nPoly = 0; for (int i = 0; i < polygonCount; i++) if (polygonIndexes[i] != null) { for (int j = 0; j < 3; j++) polygonIndexes[i][j] = map[polygonIndexes[i][j]]; pTemp[nPoly++] = polygonIndexes[i]; } vertices = vTemp; vertexCount = n; polygonIndexes = pTemp; polygonCount = nPoly; } }
public void slabPolygonsList(List<Object[]> slabInfo, boolean allowCap) { for (int i = 0; i < slabInfo.size(); i++) if (!slabPolygons(slabInfo.get(i), allowCap)) break; }
protected void addSlater(SlaterData sd, int n) { sd.index = n; slaters.addLast(sd); }