Ejemplo n.º 1
0
        /// <summary>
        /// Carrega em memória os valores da "Matriz energética"
        /// </summary>
        public static void LoadEnergeticMatrix(Param param)
        {
            int N = GCPS.chain.r.Count;              //número de residuos

            GCPS.energeticMatrix = new double[N, N]; //Matriz M quadrada (NxN)

            for (int i = 0; i < (N - 1); i++)
            {
                for (int j = i + 1; j < N; j++)
                {
                    if (i == j)
                    {
                        GCPS.energeticMatrix[i, j] = 0;
                    }
                    else
                    {
                        double r = 0;

                        if (GCPS.modelType == 0)
                        {
                            //0-Randon

                            //Sorteio randomico
                            Randomic.Random();
                            r = (Randomic.randu * 2) - 1; //R´=(R*2)-1
                        }
                        else if (GCPS.modelType == 1)
                        {
                            //1-H (Hidrofobico)
                            r = -1;
                        }
                        else if (GCPS.modelType == 2)
                        {
                            //2-P (Polar)
                            r = 1;
                        }

                        else //if (GCPS.modelType == 2)
                        {
                            //3-HP;4-estero-quimico,5-GO

                            //O AJUSTE SOMENTE É VALIDO PARA MODELO HP
                            //Onde: H=-, P=+
                            //Sendo: Eij(H,H) = -1, Eij(H,P)=0, Eij(P,P)= +1

                            if (param.model[i].value == -1 && param.model[j].value == -1)
                            {
                                r = -1;
                            }
                            else if (param.model[i].value == 1 && param.model[j].value == 1)
                            {
                                r = 1;
                            }
                        }
                        GCPS.energeticMatrix[i, j] = r;
                        GCPS.energeticMatrix[j, i] = r;
                    }
                }
            }
        }
        /// <summary>
        /// Sorteia o Monomero o qual ocorreá a tentiva de movimento
        /// </summary>
        /// <returns>Retorna a posição do Monomero</returns>
        public static void SortMoviment()
        {
            Randomic.Random();

            int selectNode = (int)(Randomic.randu * GCPS.chain.r.Count);

            GCPS.chain.selectNode = GCPS.tempChain.selectNode = selectNode;
        }
Ejemplo n.º 3
0
 /// <summary>
 /// Prepara aplicação para gerar uma nova ISEM
 /// </summary>
 public static void ClearAppToGenNewIsem()
 {
     GCPS.chain.r.Clear();
     Randomic.Random();
     GCPS.initialIsem      = AppConfigClient.Param.dataToProcess.isem < 0 ? (AppConfigClient.Param.dataToProcess.isem * -1) : AppConfigClient.Param.dataToProcess.isem;
     GCPS.chain.isem       = GCPS.initialIsem;
     GCPS.chain.chainTypes = null;
 }
Ejemplo n.º 4
0
        /// <summary>
        /// Rotina o qual costroi a cadeia de monomeros
        /// </summary>
        /// <param name="lastValed">posição do último monomero válido</param>
        public static void CreateStruct(ref int lastValed)
        {
            while (GCPS.chain.r.Count < AppConfigClient.Param.dataToProcess.totalSitio)
            {
                BasicStructs.Point tempCoord = new BasicStructs.Point(); //Crio uma coordenada temporária

                lastValed = GCPS.chain.r.Count - 1;

                tempCoord.x = GCPS.chain.r[lastValed].x; //Copia o último ponto válido para a coordenada temporária
                tempCoord.y = GCPS.chain.r[lastValed].y;
                tempCoord.z = GCPS.chain.r[lastValed].z;

                tempCoord.deadEndPoints = string.Empty;
                tempCoord.deadEnd       = 0;

                //Sorteira X,Y ou Z
                Randomic.Random();
                if (Randomic.randu < Consts.rXYZ) //X
                {
                    Randomic.Random();
                    tempCoord.x = Randomic.randu < 0.5 ? tempCoord.x - 1 : tempCoord.x + 1; //escolhe +/- 1
                }
                else if (Randomic.randu < (Consts.rXYZ * 2))                                //Y
                {
                    Randomic.Random();
                    tempCoord.y = Randomic.randu < 0.5 ? tempCoord.y - 1 : tempCoord.y + 1; //escolhe +/- 1
                }
                else
                {                                                                           //Z
                    Randomic.Random();
                    tempCoord.z = Randomic.randu < 0.5 ? tempCoord.z - 1 : tempCoord.z + 1; //escolhe +/- 1
                }


                //aidiconar valor de enegia inicial
                tempCoord.e = new List <TypeE>();

                //adiciona o novo ponto
                GCPS.chain.r.Add(tempCoord);
            }
        }
Ejemplo n.º 5
0
        /// <summary>
        /// Cria um Monometro
        /// </summary>
        /// <param name="tempCoord"></param>
        public static void CreateMono(ref BasicStructs.Point tempCoord)
        {
            tempCoord = GCPS.chain.r[GCPS.chain.r.Count - 1]; //Copia o último ponto válido para a coordenada temporária

            //Sorteira X,Y ou Z
            Randomic.Random();
            if (Randomic.randu < Consts.rXYZ) //X
            {
                Randomic.Random();
                tempCoord.x = Randomic.randu < 0.5 ? tempCoord.x - 1 : tempCoord.x + 1; //escolhe +/- 1
            }
            else if (Randomic.randu < (Consts.rXYZ * 2))                                //Y
            {
                Randomic.Random();

                tempCoord.y = Randomic.randu < 0.5 ? tempCoord.y - 1 : tempCoord.y + 1; //escolhe +/- 1
            }
            else
            {                                                                           //Z
                Randomic.Random();
                tempCoord.z = Randomic.randu < 0.5 ? tempCoord.z - 1 : tempCoord.z + 1; //escolhe +/- 1
            }
        }
Ejemplo n.º 6
0
        /// <summary>
        /// Sortei qual a posibilidade de moviment entre 1 e lenght
        /// </summary>
        /// <returns></returns>
        internal static int SortPossibilities(int lenght)
        {
            Randomic.Random();

            int ret = (int)(Randomic.randu * lenght);

            //Caso ocorra algum erro no sorteio o algoritmo finaliza a execução
            if (ret < 0 || ret > lenght)
            {
                new GridProteinFolding.Middle.Helpers.LoggingHelpers.Log().ErroParseMoves(new Middle.Helpers.LoggingHelpers.User_Defined_Exceptions.ErroParseMovesException("SortCrankShaftMove"), Types.ErrorLevel.None);

                throw new System.Exception();
                //CustomMessage customMessage = new CustomMessage();

                //throw new CustomException(SeverityLevel.Critical,
                //    LogLevel.Event,
                //    new ErroParseMoves("SortCrankShaftMove Exception"),
                //   customMessage.GetString("SortCrankShaftMove"));
            }
            else
            {
                return(ret);
            }
        }
Ejemplo n.º 7
0
        /// <summary>
        /// Este Metodo executa o movimento de End.
        /// </summary>
        /// <returns>Return TRUE se o movimento ocorreu</returns>
        public bool Do()
        {
            Structs.BasicStructs.Point r1;
            Structs.BasicStructs.Point r2;

            if (GCPS.chain.selectNode == 0)
            {
                //r1 = Members.monomero.r[Members.monomero.selectNode];
                //r2 = Members.monomero.r[Members.monomero.selectNode + 1];

                //copia dos dados do monomero para movimento
                r1 = new Structs.BasicStructs.Point()
                {
                    x = GCPS.chain.r[GCPS.chain.selectNode].x,
                    y = GCPS.chain.r[GCPS.chain.selectNode].y,
                    z = GCPS.chain.r[GCPS.chain.selectNode].z
                };
                r1.e = new List <TypeE>();
                r1.e.AddRange(GCPS.chain.r[GCPS.chain.selectNode].e);

                //copia dos dados do monomero para movimento
                r2 = new Structs.BasicStructs.Point()
                {
                    x = GCPS.chain.r[GCPS.chain.selectNode + 1].x,
                    y = GCPS.chain.r[GCPS.chain.selectNode + 1].y,
                    z = GCPS.chain.r[GCPS.chain.selectNode + 1].z
                };
                r2.e = new List <TypeE>();
                r2.e.AddRange(GCPS.chain.r[GCPS.chain.selectNode + 1].e);
            }
            else
            {
                //r1 = Members.monomero.r[Members.monomero.selectNode];
                //r2 = Members.monomero.r[Members.monomero.selectNode - 1];

                //copia dos dados do monomero para movimento
                r1 = new Structs.BasicStructs.Point()
                {
                    x = GCPS.chain.r[GCPS.chain.selectNode].x,
                    y = GCPS.chain.r[GCPS.chain.selectNode].y,
                    z = GCPS.chain.r[GCPS.chain.selectNode].z
                };
                r1.e = new List <TypeE>();
                r1.e.AddRange(GCPS.chain.r[GCPS.chain.selectNode].e);

                //copia dos dados do monomero para movimento
                r2 = new Structs.BasicStructs.Point()
                {
                    x = GCPS.chain.r[GCPS.chain.selectNode - 1].x,
                    y = GCPS.chain.r[GCPS.chain.selectNode - 1].y,
                    z = GCPS.chain.r[GCPS.chain.selectNode - 1].z
                };
                r2.e = new List <TypeE>();
                r2.e.AddRange(GCPS.chain.r[GCPS.chain.selectNode - 1].e);
            }

            //Vetor p, como sendo a difereça entre os vetores posuicao do residuo "2" e do residuo "1", isto é: p=r1-r1
            Structs.BasicStructs.Point p = new Structs.BasicStructs.Point()
            {
                x = r2.x - r1.x,
                y = r2.y - r1.y,
                z = r2.z - r1.z
            };


            //Definicao dos dois vetores v e w
            Structs.BasicStructs.Point v;
            Structs.BasicStructs.Point w;
            //cria as 3 possibilidades para v e w
            if (p.x != 0)
            {
                v = new Structs.BasicStructs.Point()
                {
                    x = 0, y = p.x, z = 0
                };
                w = new Structs.BasicStructs.Point()
                {
                    x = 0, y = 0, z = p.x
                };
            }
            else if (p.y != 0)
            {
                v = new Structs.BasicStructs.Point()
                {
                    x = 0, y = 0, z = p.y
                };
                w = new Structs.BasicStructs.Point()
                {
                    x = p.y, y = 0, z = 0
                };
            }
            else //if (p.z != 0)
            {
                v = new Structs.BasicStructs.Point()
                {
                    x = p.z, y = 0, z = 0
                };
                w = new Structs.BasicStructs.Point()
                {
                    x = 0, y = p.z, z = 0
                };
            }


            //Sorteio do movimento para 4 possibilidades (de 0 à 3)
            Randomic.Random();
            int i = (int)(Randomic.randu * 4);

            end type = end.none;

            switch (i)
            {
            case 0:
                //Primeira possibilidade: r1=r2+vi
                r1.x = r2.x + v.x;
                r1.y = r2.y + v.y;
                r1.z = r2.z + v.z;
                type = end.one;
                break;

            case 1:
                //Segunda possibilidade: r1=r2-vi
                r1.x = r2.x - v.x;
                r1.y = r2.y - v.y;
                r1.z = r2.z - v.z;
                type = end.two;
                break;

            case 2:
                //Terceira possibilidade: r1=r2+wi
                r1.x = r2.x + w.x;
                r1.y = r2.y + w.y;
                r1.z = r2.z + w.z;
                type = end.three;
                break;

            case 3:
                //Quarta possibilidade: r1=r2-wi
                r1.x = r2.x - w.x;
                r1.y = r2.y - w.y;
                r1.z = r2.z - w.z;
                type = end.four;
                break;

            default:
                new GridProteinFolding.Middle.Helpers.LoggingHelpers.Log().Exception(new System.Exception("Error ends.."), Types.ErrorLevel.Warning);
                break;
            }

            //GICO.WriteLine("{0} {1} {2}", r1.x, r1.y, r1.z);

            //Verifica a aceitação do movimento
            if (TryMove(ref r1)) // && TryMovePeerDPP(ref pointSorted, (Structs.Point)Members.monomero.r[neighborNode]))
            {
                GCPS.tempChain.r[GCPS.chain.selectNode] = r1;
                GCPS.tempChain.contMoves.endsAccept++;

                switch (type)
                {
                case end.one:
                    GCPS.tempChain.contMoves.moveSetEnd.endAccept_1++;
                    break;

                case end.two:
                    GCPS.tempChain.contMoves.moveSetEnd.endAccept_2++;
                    break;

                case end.three:
                    GCPS.tempChain.contMoves.moveSetEnd.endAccept_3++;
                    break;

                case end.four:
                    GCPS.tempChain.contMoves.moveSetEnd.endAccept_4++;
                    break;
                }

                GCPS.tempChain.typeOfLattice = BasicEnums.Lattices.End;

                return(true);
            }
            else
            {
                GCPS.chain.contMoves.endsReject++;

                switch (type)
                {
                case end.one:
                    GCPS.chain.contMoves.moveSetEnd.endReject_1++;
                    break;

                case end.two:
                    GCPS.chain.contMoves.moveSetEnd.endReject_2++;
                    break;

                case end.three:
                    GCPS.chain.contMoves.moveSetEnd.endReject_3++;
                    break;

                case end.four:
                    GCPS.chain.contMoves.moveSetEnd.endReject_4++;
                    break;
                }
                return(false);
            }
        }
Ejemplo n.º 8
0
        /// <summary>
        /// Sorteia o randomico para R
        /// </summary>
        /// <returns>Retorna a posição do Monomero</returns>
        private static double RandomR()
        {
            Randomic.Random();

            return(Randomizer.Randomic.randu * 1);
        }
        /// <summary>
        /// Executa teste de validação de MONOMERO seleciona é um crankShaft
        /// </summary>
        /// <returns></returns>
        public bool Do()
        {
            int internalSelectNode = GCPS.chain.selectNode;

            //Movimento de crankShaft é sempre em função de R1
            //Abaixo efetuaremos o ajustes do Ri
            if (GCPS.chain.r[internalSelectNode].classificationMotion.crankShaft__R0)
            {
                internalSelectNode++;
            }
            else if (GCPS.chain.r[internalSelectNode].classificationMotion.crankShaft__R2)
            {
                internalSelectNode--;
            }
            else if (GCPS.chain.r[internalSelectNode].classificationMotion.crankShaft__R3)
            {
                internalSelectNode = internalSelectNode - 2;
            }

            // |P = |v3 - |v0
            int Px = GCPS.chain.r[internalSelectNode + 1].x - GCPS.chain.r[internalSelectNode - 1].x;
            int Py = GCPS.chain.r[internalSelectNode + 1].y - GCPS.chain.r[internalSelectNode - 1].y;
            int Pz = GCPS.chain.r[internalSelectNode + 1].z - GCPS.chain.r[internalSelectNode - 1].z;

            // |Q = |v1 - |v0
            int Qx = GCPS.chain.r[internalSelectNode].x - GCPS.chain.r[internalSelectNode - 1].x;
            int Qy = GCPS.chain.r[internalSelectNode].y - GCPS.chain.r[internalSelectNode - 1].y;
            int Qz = GCPS.chain.r[internalSelectNode].z - GCPS.chain.r[internalSelectNode - 1].z;

            //O vetor |V é perpendicular a |P e a |Q simultaneamente
            int Vx = (Py * Qz) - (Qy * Pz);  //em direção de X
            int Vy = (Pz * Qx) - (Qz * Px);  //em direção de Y
            int Vz = (Px * Qy) - (Qx * Py);  //em direção de Z

            //Tres possibilidades de movimento (3)
            int R_x   = 0;
            int R_y   = 0;
            int R_z   = 0;
            int R_x_1 = 0;
            int R_y_1 = 0;
            int R_z_1 = 0;

            //Sorteio do movimento
            Randomic.Random();
            int sort = (int)(Randomic.randu * 3);

            crankshaft type = crankshaft.none;

            switch (sort)
            {
            case 0:
                //Primeira possibilidade (1)
                //onde |r´i = |ri-1 + |V
                R_x = GCPS.chain.r[internalSelectNode - 1].x + Vx;
                R_y = GCPS.chain.r[internalSelectNode - 1].y + Vy;
                R_z = GCPS.chain.r[internalSelectNode - 1].z + Vz;
                //onde |r´i+1 = |ri+2 + |V
                R_x_1 = GCPS.chain.r[internalSelectNode + 2].x + Vx;
                R_y_1 = GCPS.chain.r[internalSelectNode + 2].y + Vy;
                R_z_1 = GCPS.chain.r[internalSelectNode + 2].z + Vz;

                type = crankshaft.one;
                break;

            case 1:
                //Segunda possibilidade (2)
                //onde |r´i = |ri-1 - |V
                R_x = GCPS.chain.r[internalSelectNode - 1].x - Vx;
                R_y = GCPS.chain.r[internalSelectNode - 1].y - Vy;
                R_z = GCPS.chain.r[internalSelectNode - 1].z - Vz;
                //onde |r´i+1 = |ri+2 - |V
                R_x_1 = GCPS.chain.r[internalSelectNode + 2].x - Vx;
                R_y_1 = GCPS.chain.r[internalSelectNode + 2].y - Vy;
                R_z_1 = GCPS.chain.r[internalSelectNode + 2].z - Vz;

                type = crankshaft.two;
                break;

            case 2:
                //Terceira possibilidade (3)
                //onde |r´i = |ri-1 - |Q
                R_x = GCPS.chain.r[internalSelectNode - 1].x - Qx;
                R_y = GCPS.chain.r[internalSelectNode - 1].y - Qy;
                R_z = GCPS.chain.r[internalSelectNode - 1].z - Qz;
                //onde |r´i+1 = |ri+2 - |Q
                R_x_1 = GCPS.chain.r[internalSelectNode + 2].x - Qx;
                R_y_1 = GCPS.chain.r[internalSelectNode + 2].y - Qy;
                R_z_1 = GCPS.chain.r[internalSelectNode + 2].z - Qz;

                type = crankshaft.three;
                break;

            default:
                new GridProteinFolding.Middle.Helpers.LoggingHelpers.Log().Exception(new System.Exception("Error Sort"), Types.ErrorLevel.Warning);
                break;
            }

            Structs.BasicStructs.Point temp01 = new Structs.BasicStructs.Point()
            {
                x = R_x, y = R_y, z = R_z
            };
            temp01.e = new List <TypeE>();
            temp01.e.AddRange(GCPS.chain.r[internalSelectNode].e);


            Structs.BasicStructs.Point temp02 = new Structs.BasicStructs.Point()
            {
                x = R_x_1, y = R_y_1, z = R_z_1
            };
            temp02.e = new List <TypeE>();
            temp02.e.AddRange(GCPS.chain.r[internalSelectNode + 1].e);


            if (TryMove(ref temp01) && TryMove(ref temp02))
            {
                GCPS.tempChain.r[internalSelectNode]     = temp01;
                GCPS.tempChain.r[internalSelectNode + 1] = temp02;
                GCPS.tempChain.contMoves.crankshaftAccept++;

                switch (type)
                {
                case crankshaft.one:
                    GCPS.tempChain.contMoves.moveSetCrankshaft.crankshaftAccept_1++;
                    break;

                case crankshaft.two:
                    GCPS.tempChain.contMoves.moveSetCrankshaft.crankshaftAccept_2++;
                    break;

                case crankshaft.three:
                    GCPS.tempChain.contMoves.moveSetCrankshaft.crankshaftAccept_3++;
                    break;
                }

                GCPS.tempChain.typeOfLattice = BasicEnums.Lattices.Crank;

                return(true);
            }
            else
            {
                GCPS.chain.contMoves.crankshaftReject++;

                switch (type)
                {
                case crankshaft.one:
                    GCPS.chain.contMoves.moveSetCrankshaft.crankshaftReject_1++;
                    break;

                case crankshaft.two:
                    GCPS.chain.contMoves.moveSetCrankshaft.crankshaftReject_2++;
                    break;

                case crankshaft.three:
                    GCPS.chain.contMoves.moveSetCrankshaft.crankshaftReject_3++;
                    break;
                }

                return(false);
            }
        }