void SetModel(PotType type) { this.type = type; models.Type1.SetActive(type == PotType.Type1); models.Type2.SetActive(type == PotType.Type2); models.Type3.SetActive(type == PotType.Type3); }
// Start is called before the first frame update void Start() { hitPoints = durability; type = defaultType; SetModel(type); owner = PotOwner.none; }
public Pot(PotType type, List<Bet> bets) { m_blBetList = bets; m_ptType = type; m_dblCap = -1; m_bCapped = false; }
public void checkScore(PotType newPot) { if ((int)newPot == trendingPot.value) { scores[player.playerIndex].value++; } }
public Pot(int id, String buff, PotType type, int health, int mana) { Id = id; Buff = buff; Type = type; Health = health; Mana = mana; }
void recalculateScores(PotType nextTrending) { GameObject[] players = GameObject.FindGameObjectsWithTag("Player"); for (int i = 0; i < players.Length; i++) { PotDetector potDetector = players[i].GetComponent <PotDetector>(); potDetector.recalculateScore(nextTrending); } }
//private void Update() //{ // if (Input.GetKeyDown(destroyTestKey)) // { // Hit(); // } // else if (Input.GetKeyDown(craftTestKey)) // { // Craft(craftDefaultType, 1); // } //} public PotSpotController Craft(PotType type, int playerOwner) { // if (this.type == PotType.None) // { aSrcPotCraft.Play(); SpawnParticles(); SetModel(type); // } owner = (PotOwner)playerOwner; return(this); }
public void recalculateScore(PotType nextTrending) { IntVariable myScore = scores[player.playerIndex]; for (int i = 0; i < pots.Length; i++) { PotSpotController pot = pots[i].GetComponent <PotSpotController>(); if (player.playerIndex == (int)pot.owner && pot.type == nextTrending) { myScore.value++; } } }
public void TrendChange(PotType type) { int index = (int)type; Debug.Log(index); if (index >= spritePool.Length) { return; } if (currentImage != null) { currentImage.sprite = spritePool[index]; } }
void SetTrend() { int rand = -1; do { rand = Random.Range(0, 3); } while (rand == (int)trend); trend = (PotType)rand; currentTrendDuration = Random.Range(10, 15); trendingIndex.value = (int)trend; onTrendChange.Invoke(trend); trendingCount++; }
public void GetPlayerScore(PotType potInTrend) { int score = 0; for (int i = 0; i < pots.Length; i++) { PotSpotController pot = pots[i].GetComponent <PotSpotController>(); if (player.playerIndex == (int)pot.owner && pot.type == potInTrend) { score++; } } totals[player.playerIndex].value = score; resetScores(); }
public Pot(int id, String buff, PotType type) { Id = id; Buff = buff; Type = type; }
public Pot(PotType type) : this(type, new List<Bet>()) { }
override public void StartCalculations() { string ostr; int iSTEMline, iSTEMpoint; DateTime start; TimeSpan period; start = DateTime.Now; Console.WriteLine("\n****************** MS with inline potentials started ********************"); if (!PrepareCurves()) { Console.WriteLine("Can't create curves, exiting"); return; } // Создание планов FFT Console.WriteLine("\nCreating FFT plans for " + N + "*" + M + " transformations"); SFT_backward.MakePlan(data, N, M, -1); SFT_direct.MakePlan(data, N, M, 1); Console.WriteLine("\nInitial wave is " + IniWaveType.ToString()); Console.WriteLine("Potential type is " + PotType.ToString()); Calc.a = a; Calc.b = b; Calc.gam = gam; Calc.N = N; Calc.M = M; Calc.E = E; Calc.data = data; Calc.PotType = PotType; Calc.atrad = atrad; Calc.dela = dela; Calc.CurveLength = CurveLength; Calc.CurveHolder = (double *)PotCurve.BaseAddress; Calc.NTypes = NTypes; Calc.NSlices = NSlices; Calc.IsSaveWaves = IsSaveWaves; Calc.IsSaveDiffractions = IsSaveDiffractions; Calc.IsSaveSTEM = (IniWaveType == MSProject.IniWaveTypes.STEMshift); Calc.SFT_direct = SFT_direct; Calc.SFT_backward = SFT_backward; // int iE, iBT, iBS, iCA, iDf, iCs, iCT ; // moved to MyProject class definition for (iE = 0; iE < Emat.Length; iE++) { Calc.E = E = Emat[iE]; for (iBT = 0; iBT < Math.Max(BeamTilt.Length, 1); iBT++) { X_beamtilt = Y_beamtilt = 0; if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { X_beamtilt = BeamTilt[iBT][0] / 1000.0; Y_beamtilt = BeamTilt[iBT][1] / 1000.0; } catch { } } if (IniWaveType == MSProject.IniWaveTypes.PlaneWave) { try { X_beamtilt = BeamTilt[iBT][0]; Y_beamtilt = BeamTilt[iBT][1]; } catch { } } for (iBS = 0; iBS < (((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift))?Math.Max(BeamShift.Length, 1):1); iBS++) { if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.Precalculated) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { X_beamshift = BeamShift[iBS][0]; Y_beamshift = BeamShift[iBS][1]; } catch { X_beamshift = Y_beamshift = 0.5; } } for (iCA = 0; iCA < (((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift))?Math.Max(ConvAngles.Length, 1):1); iCA++) { if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.Precalculated) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { ConvAngle = ConvAngles[iCA][0]; ConvAngleInner = ConvAngles[iCA][1]; } catch { ConvAngle = 0.3; ConvAngleInner = 0; } } for (iCs = 0; iCs < (((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift))?Math.Max(Csmat.Length, 1):1); iCs++) { if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.Precalculated) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { Cs = Csmat[iCs]; } catch { Cs = 0; } } for (iDf = 0; iDf < (((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift))?Math.Max(Dfmat.Length, 1):1); iDf++) { if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.Precalculated) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { Df = Dfmat[iDf]; } catch { Df = 0; } } for (iCT = 0; iCT < Math.Max(CrystalTilt.Length, 1); iCT++) { try { X_tilt_crystal = Calc.X_tilt_crystal = CrystalTilt[iCT][0] / 1000.0; Y_tilt_crystal = Calc.Y_tilt_crystal = CrystalTilt[iCT][1] / 1000.0; } catch { Calc.X_tilt_crystal = Calc.Y_tilt_crystal = 0.0; } for (TVi = 0; TVi < TVNumber; TVi++) { if ((IniWaveType == MSProject.IniWaveTypes.STEMshift)) { iSTEMline = (int)Math.Floor((double)iBS / STEM_N); iSTEMpoint = iBS % STEM_N; if ((iSTEMpoint == 0) && (iCA == 0) && (iCs == 0) && (iDf == 0) && (iCT == 0) && (TVi == 0)) { ostr = "\nLine " + iSTEMline + " (" + STEM_M + ")\n#"; } else { ostr = "#"; } if ((TVNumber > 1) && (TVi == TVNumber - 1)) { ostr += "!"; } } else { ostr = "\n*** " + (E / 1000.0).ToString("###0.0") + "kV"; ostr += ", CT(" + X_tilt_crystal.ToString("0.0###") + "," + Y_tilt_crystal.ToString("0.0###") + ")"; ostr += ", BT(" + X_beamtilt.ToString("0.0###") + "," + Y_beamtilt.ToString("0.0###") + ")"; ostr += "\n*** BS(" + X_beamshift.ToString("0.0###") + "," + Y_beamshift.ToString("0.0###") + ")"; ostr += ", CA(" + ConvAngle.ToString("0.0###") + "," + ConvAngleInner.ToString("0.0###") + ")"; ostr += ", Df" + Df.ToString("###0.0") + "A"; ostr += ", Cs" + (Cs / 1e7).ToString("###0.0") + "mm\n"; } Console.Write(ostr); // Создание начальной волны if (!CreateInitialWave()) { Console.WriteLine("Can't create initial wave, exiting"); return; } Calc.CurThickness = StartThickness; // in the case of precalculated wave - thickness of this wave if (IsCalcAll) { ThWaves = new double[] { c + StartThickness - 0.00001 } } ; Calc.ThWaves = ThWaves; // Начало мултислайса Calc.RunCalculation(); } // different phonon configurations (TVNumber) } // crystal tilt cycle } // Df cycle } // Cs cycle } // Convergence angle cycle } // beam shift cycle } // beam tilt cycle } // E cycle if (this.IsContinue) { System.IO.File.Copy(Calc.LastSavedWave, Path.Combine(WorkingDirectoryName, "last.wav"), true); } if (IniWaveType == IniWaveTypes.STEMshift) { FlushSTEMfile(); } if (SliceTmpDirectory.Length > 0) { Directory.Delete(SliceTmpDirectory, true); } period = DateTime.Now - start; Console.WriteLine("\n****** MS finished, total time " + period.ToString() + " ********************"); } bool SaveSlices() { double[] x, y, z, DW, ads, occ; double CurThickness = 0; int[] type, type_; int i, j, jj, js; string lwd; uint nas; FileRW fN; lwd = Path.Combine(WorkingDirectoryName, "Slice stack " + " (" + DateTime.Now.ToShortDateString() + " " + DateTime.Now.Hour + "_" + DateTime.Now.Minute + "_" + DateTime.Now.Second + ")"); if (!Directory.Exists(lwd)) { try { Directory.CreateDirectory(lwd); } catch (Exception e) { Console.WriteLine("Can't create working directory:\n" + e.ToString()); return(false); } } SliceTmpDirectory = lwd; Calc.SliceFilename = Path.Combine(lwd, "Slice "); bool repeat; for (i = js = 0; i < NSlices; i++) { repeat = false; memalo: try { nas = (uint)NASlices[i]; x = new double[(int)nas]; y = new double[(int)nas]; z = new double[(int)nas]; DW = new double[(int)nas]; ads = new double[(int)nas]; occ = new double[(int)nas]; type = new int[(int)nas]; type_ = new int[(int)nas]; } catch { if (repeat) { Console.WriteLine("Can't allocate memory for buffers"); return(false); } repeat = true; GC.Collect(); goto memalo; } for (j = js, jj = 0; j < js + (int)nas; jj++, j++) { x[jj] = ((AtomRec)Atoms[j]).x; y[jj] = ((AtomRec)Atoms[j]).y; z[jj] = (((AtomRec)Atoms[j]).z * c - CurThickness); DW[jj] = ((AtomRec)Atoms[j]).DW; ads[jj] = ((AtomRec)Atoms[j]).ads; occ[jj] = ((AtomRec)Atoms[j]).occ; type[jj] = ((AtomRec)Atoms[j]).type; type_[jj] = ((AtomRec)Atoms[j]).type_; } CurThickness += (double)ThSlices[i]; js += (int)nas; lwd = Calc.SliceFilename + (i + 1).ToString("00000") + ".slice_coo"; if ((fN = FileRW.Open(lwd, FileRW.Action.CreateAlways, FileRW.Access.Write)) != null) { uint nw = 0; bool sff; double cth = (double)ThSlices[i]; unsafe { nw += fN.Write((byte *)&nas, sizeof(int)); nw += fN.Write(&cth, 1); if (nas > 0) { fixed(double *xx = x, yy = y, zz = z, DDW = DW, aads = ads, oocc = occ) fixed(int *t = type, t_ = type_) { nw += fN.Write(xx, nas); nw += fN.Write(yy, nas); nw += fN.Write(zz, nas); nw += fN.Write(DDW, nas); nw += fN.Write(aads, nas); nw += fN.Write(oocc, nas); nw += fN.Write((byte *)t, sizeof(int) * nas); nw += fN.Write((byte *)t_, sizeof(int) * nas); } } sff = (nw != nas * (6 * sizeof(double) + 2 * sizeof(int)) + sizeof(double) + sizeof(int)); } fN.Close(); if (sff) { // add code to find and display the reason Console.WriteLine("Only " + nw + " bytes are written to " + lwd); fN.Close(); return(false); } } else { return(false); } x = y = z = DW = ads = occ = null; type = type_ = null; Console.Write("\rSlice " + (i + 1) + " is written "); } Console.WriteLine("\r" + i + " slices are saved "); GC.Collect(); return(true); } }
override public void StartCalculations() { DateTime start; string ostr; int iSTEMline, iSTEMpoint; TimeSpan period; start = DateTime.Now; Console.WriteLine("\n****************** MS with reused potentials started ********************"); // Создание планов FFT Console.WriteLine("\nCreating FFT plans for " + N + "*" + M + " transformations"); SFT_backward.MakePlan(data, N, M, -1); SFT_direct.MakePlan(data, N, M, 1); Calc.a = a; Calc.b = b; Calc.gam = gam; Calc.N = N; Calc.M = M; Calc.E = E; Calc.data = data; Calc.NSlices = NSlices; Calc.ThSlices = ThSlices; Calc.IsSaveWaves = IsSaveWaves; Calc.IsSaveDiffractions = IsSaveDiffractions; Calc.IsSaveSTEM = (IniWaveType == MSProject.IniWaveTypes.STEMshift); Calc.SFT_direct = SFT_direct; Calc.SFT_backward = SFT_backward; Console.WriteLine("\nInitial wave is " + IniWaveType.ToString()); // int iE, iBT, iBS, iCA, iDf, iCs, iCT ; // moved to MyProject class definition for (iE = 0; iE < Emat.Length; iE++) { Calc.E = E = Emat[iE]; // Расчет и сохранение слоев if (!GeneratePG()) { Console.WriteLine("Can't create slices, exiting"); return; } for (iCT = 0; iCT < Math.Max(CrystalTilt.Length, 1); iCT++) { try { X_tilt_crystal = CrystalTilt[iCT][0] / 1000.0; Y_tilt_crystal = CrystalTilt[iCT][1] / 1000.0; } catch { Y_tilt_crystal = 0.0; } // создание пропагаторов GenerateProps(); Calc.SliList = SliList; Calc.PropList = PropList; for (iBT = 0; iBT < Math.Max(BeamTilt.Length, 1); iBT++) { X_beamtilt = Y_beamtilt = 0; if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { X_beamtilt = BeamTilt[iBT][0] / 1000.0; Y_beamtilt = BeamTilt[iBT][1] / 1000.0; } catch { } } if (IniWaveType == MSProject.IniWaveTypes.PlaneWave) { try { X_beamtilt = BeamTilt[iBT][0]; Y_beamtilt = BeamTilt[iBT][1]; } catch { } } for (iBS = 0; iBS < (((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift))?Math.Max(BeamShift.Length, 1):1); iBS++) { if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { X_beamshift = BeamShift[iBS][0]; Y_beamshift = BeamShift[iBS][1]; } catch { X_beamshift = Y_beamshift = 0.5; } } for (iCA = 0; iCA < (((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift))?Math.Max(ConvAngles.Length, 1):1); iCA++) { if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { ConvAngle = ConvAngles[iCA][0]; ConvAngleInner = ConvAngles[iCA][1]; } catch { ConvAngle = 0.3; ConvAngleInner = 0; } } for (iCs = 0; iCs < (((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift))?Math.Max(Csmat.Length, 1):1); iCs++) { if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { Cs = Csmat[iCs]; } catch { Cs = 0; } } for (iDf = 0; iDf < (((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift))?Math.Max(Dfmat.Length, 1):1); iDf++) { if ((IniWaveType == MSProject.IniWaveTypes.Converged) || (IniWaveType == MSProject.IniWaveTypes.STEMshift)) { try { Df = Dfmat[iDf]; } catch { Df = 0; } } if ((IniWaveType == MSProject.IniWaveTypes.STEMshift)) { iSTEMline = (int)Math.Floor((double)iBS / STEM_N); iSTEMpoint = iBS % STEM_N; if ((iSTEMpoint == 0) && (iCA == 0) && (iCs == 0) && (iDf == 0) && (iCT == 0)) { ostr = "\nLine " + iSTEMline + " (" + STEM_M + ")\n#"; } else { ostr = "#"; } } else { ostr = "\n*** " + (E / 1000.0).ToString("###0.0") + "kV"; ostr += ", CT(" + X_tilt_crystal.ToString("0.0###") + "," + Y_tilt_crystal.ToString("0.0###") + ")"; ostr += ", BT(" + X_beamtilt.ToString("0.0###") + "," + Y_beamtilt.ToString("0.0###") + ")"; ostr += "\n*** BS(" + X_beamshift.ToString("0.0###") + "," + Y_beamshift.ToString("0.0###") + ")"; ostr += ", CA(" + ConvAngle.ToString("0.0###") + "," + ConvAngleInner.ToString("0.0###") + ")"; ostr += ", Df" + Df.ToString("###0.0") + "A"; ostr += ", Cs" + (Cs / 1e7).ToString("###0.0") + "mm\n"; } Console.Write(ostr); // Создание начальной волны if (!CreateInitialWave()) { Console.WriteLine("Can't create initial wave, exiting"); return; } Calc.CurThickness = StartThickness; if (IsCalcAll) { this.ThWaves = new double[] { c + StartThickness - 0.00001 } } ; Calc.ThWaves = ThWaves; // Начало мултислайса Calc.RunCalculation(); } // Df cycle } // Cs cycle } // Convergence angle cycle } // beam shift cycle } // beam tilt cycle } // crystal tilt cycle } // E cycle if (IsContinue) { System.IO.File.Copy(Calc.LastSavedWave, Path.Combine(this.WorkingDirectoryName, "last.wav"), true); } if (IniWaveType == IniWaveTypes.STEMshift) { FlushSTEMfile(); } period = DateTime.Now - start; Console.WriteLine("\n****** MS finished, total time " + period.ToString() + " ********************"); } bool GeneratePG() { int i, j, k; MemMan iM; uint NMMs; float progress; int[] PropSliTable = new int[NSlices]; Props = new ArrayList(); SliList = new double *[NSlices]; PropList = new double *[NSlices]; for (i = 0; i < NSlices; i++) { for (j = 0; j < Props.Count; j++) { if (Math.Abs((double)Props[j] - (double)ThSlices[i]) < 0.000001) { break; } } if (j == Props.Count) { j = Props.Add(ThSlices[i]); } PropSliTable[i] = j; } PropsP = new double *[Props.Count]; MMList = new ArrayList((int)(NSlices + Props.Count)); for (i = 0; i < NSlices + Props.Count; i++) { iM = new MemMan(); if (iM.Allocate(MemRequested())) { MMList.Add(iM); } else { break; } } NMMs = (uint)MMList.Count; if (NMMs < NSlices + Props.Count) { Console.WriteLine("Can't allocate all data in memory, only " + NMMs + " pages are available, " + (NSlices + Props.Count) + " requested,\nuse inline calculation"); return(false); } for (i = 0; i < NSlices; i++) { Console.WriteLine("Creating slice number " + i.ToString("0000") + " from " + (uint)NASlices[i] + " atoms using " + PotType.ToString()); //((MemMan)MMList[i]).Lock(0,MemRequested()) ; SliList[i] = (double *)((MemMan)MMList[i]).BaseAddress; if ((uint)NASlices[i] > 0) { ExtractSlice(i); fixed(double *_x = x, _y = y, _dw = DW, _ads = ads, _occ = occ) { fixed(int *_type_ = type_, _type = type) { switch (PotType) { case PotTypes.rs_DT_DW_periodic: Potential_rs_DT_DW_periodic(a, b, gam, atrad, N, M, (uint)NASlices[i], _x, _y, _dw, _ads, _occ, _type, SliList[i], &progress); break; case PotTypes.rs_DT_DW_cut: Potential_rs_DT_DW_cutpot(a, b, gam, atrad, N, M, (uint)NASlices[i], _x, _y, _dw, _ads, _occ, _type, SliList[i], &progress); break; case PotTypes.rs_curve_DW_periodic: Potential_rs_curve_DW_periodic(a, b, gam, atrad, N, M, (uint)NASlices[i], _x, _y, _ads, _occ, _type_, (double *)PotCurve.BaseAddress, CurveLength, dela, SliList[i], &progress); break; case PotTypes.rs_curve_DW_cut: Potential_rs_curve_DW_cutpot(a, b, gam, atrad, N, M, (uint)NASlices[i], _x, _y, _ads, _occ, _type_, (double *)PotCurve.BaseAddress, CurveLength, dela, SliList[i], &progress); break; case PotTypes.rec_DT_DW: Potential_rec_DT_DW(a, b, gam, Nmult, Mmult, N, M, (uint)NASlices[i], 0, M, _x, _y, _dw, _ads, _occ, _type, SliList[i], &progress); SFT_backward.MakeSFT(SliList[i]); break; case PotTypes.rec_curve_DW: Potential_rec_curve_DW(a, b, gam, Nmult, Mmult, N, M, (uint)NASlices[i], 0, M, _x, _y, _ads, _occ, _type_, (double *)PotCurve.BaseAddress, CurveLength, ds, SliList[i], &progress); SFT_backward.MakeSFT(SliList[i]); break; default: Console.WriteLine("Potential " + PotType.ToString() + " is not supported"); return(false); } } } } if (IsSaveSlices) { SaveSlice(i); } } if (IsPotRec) { a *= Nmult; b *= Mmult; } //Создание PG из слайсов double lambda = 0.387818 / Math.Sqrt(E / 1000.0 * (1.0 + 0.978459e-3 * E / 1000)); // E in V double K = lambda * Math.Sqrt(1.0 + Math.Pow((0.0242621 / lambda), 2)); if (IsPotRec) { K *= (N * M); } for (i = 0; i < NSlices; i++) { double *pbuf = SliList[i]; double aR, aI; for (j = 0; j < M; j++) { for (k = 0; k < N; k++) { aR = K * *pbuf; aI = Math.Exp(-*(pbuf + 1) * K); *pbuf = Math.Cos(aR) * aI; *(++pbuf) = -Math.Sin(aR) * aI; pbuf++; } } // y-cycle } Atoms = null; // free a memory occupied by the model GC.Collect(); for (i = 0; i < Props.Count; i++) { PropsP[i] = (double *)((MemMan)MMList[(int)(i + NSlices)]).BaseAddress; } for (i = 0; i < NSlices; i++) { PropList[i] = PropsP[PropSliTable[i]]; } return(true); } bool GenerateProps() { int i; float progress; for (i = 0; i < Props.Count; i++) { Console.WriteLine("Creating propagator for " + ((double)Props[i]).ToString("##0.000000") + " A"); CreatePropagator(a, b, gam, (double)Props[i], E, X_tilt_crystal, Y_tilt_crystal, N, M, PropsP[i], &progress); } return(true); } void ExtractSlice(int i) { uint nas = (uint)NASlices[i]; x = new double[(int)nas]; y = new double[(int)nas]; DW = new double[(int)nas]; ads = new double[(int)nas]; occ = new double[(int)nas]; type = new int[(int)nas]; type_ = new int[(int)nas]; int j = 0; foreach (AtomRec at in Atoms) { if (at.sn == i) { x[j] = at.x; y[j] = at.y; DW[j] = at.DW; ads[j] = at.ads; occ[j] = at.occ; type[j] = at.type; type_[j] = at.type_; j++; } } } /// <summary> /// Saves slices in real space /// </summary> /// <returns></returns> bool SaveSlice(int iSlice) // save slices in real space { // a*Nmult, b*Mmult FileRW fN; string lwd, SavedFilename; lwd = Path.Combine(WorkingDirectoryName, "Slice stack"); if (!Directory.Exists(lwd)) { try { Directory.CreateDirectory(lwd); } catch (Exception e) { Console.WriteLine("Can't create working directory:\n" + e.ToString()); return(false); } } SavedFilename = Path.Combine(lwd, "Slice_" + iSlice.ToString("0000") + ".slice"); if ((fN = FileRW.Open(SavedFilename, FileRW.Action.CreateAlways, FileRW.Access.Write)) != null) { byte[] sout = new byte[160]; string Sout; uint nw; nw = fN.Write(SliList[iSlice], N * M * (uint)2); if (nw != N * M * (uint)2 * sizeof(double)) { // add code to find and display the reason Console.WriteLine("Only " + nw + " bytes out of " + N * M * (uint)2 * sizeof(double) + " are written to\n" + SavedFilename); fN.Close(); SavedFilename = null; return(false); } Sout = String.Format("___ {0,12:g10} {1,12:g10} {2,12:g10} {3,10:g5} {4,10:g5} {5,10:g8} {6,10:g} {7,00000} {8,00000} {9,10:g} {10,5:n0} ", a * Nmult, b * Mmult, ThSlices[iSlice], Math.PI / 2.0, Math.PI / 2.0, gam, -1.0, N, M, iSlice, NSlices); for (int i = 0; i < 160; i++) { sout[i] = (i < Sout.Length)?System.Convert.ToByte(Sout[i]):(byte)0; } fN.Write(sout, 160); fN.Close(); return(true); } else { SavedFilename = null; return(false); } } }
public static Pot CreatePotFrom(List<Bet> bets, PotType pType) { Pot p = new Pot(pType, bets); return p; }