// This file is part of the Herezh++ application.
//
// The finite element software Herezh++ is dedicated to the field
// of mechanics for large transformations of solid structures.
// It is developed by Gérard Rio (APP: IDDN.FR.010.0106078.000.R.P.2006.035.20600)
// INSTITUT DE RECHERCHE DUPUY DE LÔME (IRDL) .
//
// Herezh++ is distributed under GPL 3 license ou ultérieure.
//
// Copyright (C) 1997-2022 Université Bretagne Sud (France)
// AUTHOR : Gérard Rio
// E-MAIL : gerardrio56@free.fr
//
// This program 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.
//
// This program 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 for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see .
//
// For more information, please consult: .
/************************************************************************
* UNIVERSITE DE BRETAGNE SUD (UBS) --- ENSIBS DE LORIENT *
************************************************************************
* IRDL - Equipe DE GENIE MECANIQUE ET MATERIAUX (EG2M) *
* Centre de Recherche Rue de Saint Maudé - 56325 Lorient cedex *
* tel. 02.97.87.45.70 fax. 02.97.87.45.72 http://www-lg2m.univ-ubs.fr *
************************************************************************
* DATE: 08/03/2005 *
* $ *
* AUTEUR: G RIO/H LAURENT (mailto:gerard.rio@univ-ubs.fr) *
* Tel 0297874571 fax : 02.97.87.45.72 *
* $ *
************************************************************************
* BUT: échange de structures de données: fortran Umat -> C++ *
* fonction C a implanter du coté d'abaqus (ou autre prog) *
* accés directe aux informations. *
* *
* $ *
* '''''''''''''''''''''''''''''''''''''''''''''''''''''''''''' *
* *
* VERIFICATION: *
* *
* ! date ! auteur ! but ! *
* ------------------------------------------------------------ *
* ! ! ! ! *
* $ *
* '''''''''''''''''''''''''''''''''''''''''''''''''''''''''''' *
* MODIFICATIONS: *
* ! date ! auteur ! but ! *
* 5 avril 2016 : G Rio : prise en compte des éléments axi *
* 17 janvier 2018 : G Rio : prise en compte des contraintes *
* planes et déformation planes. *
* ------------------------------------------------------------ *
* $ *
************************************************************************/
#include
#include
#include
#include /* Pour O_WRONLY, etc */
#include /* pour les ordres read write close*/
/* définition d'une union qui lie les réels, les entiers et les caractères */
union Tab_car_double_int
{ char tampon[928];
double x[116];
int n[232];
} ;
Tab_car_double_int t_car_x_n;
/* --- def des variables globales (a commenter certaines si elles sont declarees autre part) */
/* nom du tube nommé pour l'envoi des donnees */
char* envoi="../Umat_envoi_Hz";
/* nom du tube nomme pour la reception des donnees */
char* reception="../Umat_reception_Hz";
/* -- declarations des variables de passages avec un nom assez long pour qu'il n'y ait pas */
/* -- de confusion avec les noms du programme appelant */
/* --- en sortie uniquement */
double* u_herezh_DDSDDT = &t_car_x_n.x[0]; /* 6 */
double* u_herezh_DRPLDE = &t_car_x_n.x[6]; /* 6 */
double* u_herezh_DDSDDE = &t_car_x_n.x[12]; /* 36 */
/* --- en entrée - sortie */
double* u_herezh_RPL = &t_car_x_n.x[48]; /* 1 */
double* u_herezh_STRESS = &t_car_x_n.x[49]; /* 6 */
double* u_herezh_SSE = &t_car_x_n.x[55]; /* 1 */
double* u_herezh_SPD = &t_car_x_n.x[56]; /* 1 */
double* u_herezh_SCD = &t_car_x_n.x[57]; /* 1 */
double* u_herezh_DRPLDT = &t_car_x_n.x[58]; /* 1 */
double* u_herezh_PNEWDT = &t_car_x_n.x[59]; /* 1 */
/* --- en entrée seulement */
double* u_herezh_STRAN = &t_car_x_n.x[60]; /* 6 */
double* u_herezh_DSTRAN = &t_car_x_n.x[66]; /* 6 */
double* u_herezh_TIME = &t_car_x_n.x[72]; /* 2 */
double* u_herezh_DTIME = &t_car_x_n.x[74]; /* 1 */
double* u_herezh_TemP = &t_car_x_n.x[75]; /* 1 */
double* u_herezh_DTEMP = &t_car_x_n.x[76]; /* 1 */
double* u_herezh_COORDS = &t_car_x_n.x[77]; /* 3 */
double* u_herezh_DROT = &t_car_x_n.x[80]; /* 9 */
double* u_herezh_CELENT = &t_car_x_n.x[89]; /* 1 */
double* u_herezh_DFGRD0 = &t_car_x_n.x[90]; /* 9 */
double* u_herezh_DFGRD1 = &t_car_x_n.x[99]; /* 9 */
int* u_herezh_NDI = &t_car_x_n.n[216]; /* 1 */
int* u_herezh_NSHR = &t_car_x_n.n[217]; /* 1 */
int* u_herezh_NTENS = &t_car_x_n.n[218]; /* 1 */
int* u_herezh_NSTATV = &t_car_x_n.n[219]; /* 1 */
int* u_herezh_NOEL = &t_car_x_n.n[220]; /* 1 */
int* u_herezh_NPT = &t_car_x_n.n[221]; /* 1 */
int* u_herezh_LAYER = &t_car_x_n.n[222]; /* 1 */
int* u_herezh_KSPT = &t_car_x_n.n[223]; /* 1 */
int* u_herezh_KSTEP = &t_car_x_n.n[224]; /* 1 */
int* u_herezh_KINC = &t_car_x_n.n[225]; /* 1 */
char* u_herezh_CMNAME = &t_car_x_n.tampon[904]; /* 24 */
/* --------------------- rappel des parametres de passage de la routine fortran ------------- */
/* SUBROUTINE UMAT(STRESS,STATEV,DDSDDE,SSE,SPD,SCD,
1 RPL,DDSDDT,DRPLDE,DRPLDT,STRAN,DSTRAN,
2 TIME,DTIME,TEMP,DTEMP,PREDEF,DPRED,MATERL,NDI,NSHR,NTENS,
3 NSTATV,PROPS,NPROPS,COORDS,DROT,PNEWDT,CELENT,
4 DFGRD0,DFGRD1,NOEL,NPT,KSLAY,KSPT,KSTEP,KINC)
C
INCLUDE 'ABA_PARAM.INC'
C
CHARACTER*80 MATERL
DIMENSION STRESS(NTENS),STATEV(NSTATV),
1 DDSDDE(NTENS,NTENS),DDSDDT(NTENS),DRPLDE(NTENS),
2 STRAN(NTENS),DSTRAN(NTENS),TIME(2),PREDEF(1),DPRED(1),
3 PROPS(NPROPS),COORDS(3),DROT(3,3),
4 DFGRD0(3,3),DFGRD1(3,3)
C
DIMENSION EELAS(6),EPLAS(6),FLOW(6)
PARAMETER (ONE=1.0D0,TWO=2.0D0,THREE=3.0D0,SIX=6.0D0)
DATA NEWTON,TOLER/10,1.D-6/
*/
/* --------------------- fin rappel des parametres de passage de la routine fortran ------------- */
/* procedure de lecture de recuperation sur le pipe des infos calculees */
void LectureDonneesUmat(double* STRESS,double* DDSDDE
,double* SSE,double* SPD,double* SCD
,const int* NDI,const int* NSHR,const int* NTENS
,double* PNEWDT
,double* RPL,double* DDSDDT,double* DRPLDE,double* DRPLDT)
{
/* Creation d'un processus de reception des donnees */
int tub;
/* ouverture du tube nomme en lecture */
tub = open(envoi,O_RDONLY);
/* lecture dans le tampon */
read (tub,t_car_x_n.tampon,480);
close (tub); /* fermeture du tampon */
/* transformation de l'information
a priori *NDI + *NSHR = *NTENS, mais abaqus garde les 3 valeurs donc on se refere uniquement sur les 2
premieres donnees -> d'ou un test */
if ((*NDI == 3) && (*NSHR == 3))
{/* cas classique 3D */
int ij;
for (ij=0;ij<6;ij++)
{STRESS[ij] = u_herezh_STRESS[ij];
DDSDDT[ij] = u_herezh_DDSDDT[ij];
DRPLDE[ij] = u_herezh_DRPLDE[ij];
int kl;
for (kl=0;kl<6;kl++)
{int r=ij*6+kl;
DDSDDE[r] = u_herezh_DDSDDE[r];
};
};
}
else if ((*NDI == 2) && (*NSHR == 1))
{ /* cas des contraintes planes */
int ij;
for (ij=0;ij<3;ij++)
{ STRESS[ij] = u_herezh_STRESS[ij];
DDSDDT[ij] = u_herezh_DDSDDT[ij];
DRPLDE[ij] = u_herezh_DRPLDE[ij];
int kl;
for (kl=0;kl<3;kl++)
{int r=ij*3+kl;
DDSDDE[r] = u_herezh_DDSDDE[r];
};
};
}
else if ((*NDI == 3) && (*NSHR == 1))
{/* cas d'elements axisymetrique 3D */
int ij;
for (ij=0;ij<4;ij++)
{STRESS[ij] = u_herezh_STRESS[ij];
DDSDDT[ij] = u_herezh_DDSDDT[ij];
DRPLDE[ij] = u_herezh_DRPLDE[ij];
int kl;
for (kl=0;kl<4;kl++)
{int r=ij*4+kl;
DDSDDE[r] = u_herezh_DDSDDE[r];
};
};
};
*SSE = *u_herezh_SSE; *SPD = *u_herezh_SPD; *SCD = *u_herezh_SCD;
*PNEWDT = *u_herezh_PNEWDT;
*RPL = *u_herezh_RPL;
*DRPLDT = *u_herezh_DRPLDT;
};
union Tab_car_et_double
{ char tampon[21];
double truc[2];
} ;
/* procedure d'ecriture sur le pipe des infos passees par le programme principal */
void EcritureDonneesUmat(double* STRESS
,double* SSE,double* SPD,double* SCD
,const double* STRAN,const double* DSTRAN
,const double* TIME,const double* DTIME,const double* TemP,const double* DTEMP
,const char* CMNAME
,const int* NDI,const int* NSHR,const int* NTENS
,const int* NSTATV
,const double* COORDS,const double* DROT
,double* PNEWDT,const double* CELENT
,const double* DFGRD0,const double* DFGRD1
,const int* NOEL,const int* NPT,const int* LAYER
,const int* KSPT,const int* KSTEP,const int* KINC)
{
/* a priori *NDI + *NSHR = *NTENS, mais abaqus garde les 3 valeurs donc on se refere uniquement sur les 2
premieres donnees -> d'ou un test (que l'on pourrait sans doute eviter ) */
if ((*NDI == 3) && (*NSHR == 3))
{ /* cas classique 3D */
int ij;
for (ij=0;ij<6;ij++)
{u_herezh_STRESS[ij] = STRESS[ij];
u_herezh_STRAN[ij] = STRAN[ij];
u_herezh_DSTRAN[ij] = DSTRAN[ij];
};
}
else if ((*NDI == 2) && (*NSHR == 1))
{ /* cas des contraintes planes */
int ij;
for (ij=0;ij<3;ij++)
{u_herezh_STRESS[ij] = STRESS[ij];
u_herezh_STRAN[ij] = STRAN[ij];
u_herezh_DSTRAN[ij] = DSTRAN[ij];
};
}
else if ((*NDI == 3) && (*NSHR == 1))
{ /* cas d'éléments axisymétrique 3D */
int ij;
for (ij=0;ij<4;ij++)
{u_herezh_STRESS[ij] = STRESS[ij];
u_herezh_STRAN[ij] = STRAN[ij];
u_herezh_DSTRAN[ij] = DSTRAN[ij];
};
};
*u_herezh_SSE = *SSE; *u_herezh_SPD = *SPD; *u_herezh_SCD = *SCD;
*u_herezh_PNEWDT= *PNEWDT;
u_herezh_TIME[0]= TIME[0]; u_herezh_TIME[1]= TIME[1]; *u_herezh_DTIME = *DTIME;
*u_herezh_TemP = *TemP; *u_herezh_DTEMP = *DTEMP;
*u_herezh_NDI = *NDI; *u_herezh_NSHR = *NSHR; *u_herezh_NTENS = *NTENS; *u_herezh_NSTATV = *NSTATV;
int i;
for (i=0;i<3;i++)
{u_herezh_COORDS[i]= COORDS[i];
int j;
for (j=0;j<3;j++)
{int r=i*3+j;
u_herezh_DROT[r]= DROT[r]; u_herezh_DFGRD0[r]=DFGRD0[r]; u_herezh_DFGRD1[r]=DFGRD1[r];
}
};
*u_herezh_CELENT = *CELENT;
*u_herezh_NOEL = *NOEL; *u_herezh_NPT = *NPT; *u_herezh_LAYER = *LAYER; *u_herezh_KSPT = *KSPT;
*u_herezh_KSTEP = *KSTEP; *u_herezh_KINC = *KINC;
for (i=0;i<20;i++) u_herezh_CMNAME[i] = CMNAME[i];
/*cout << "\n *********** grandeurs expedier du sous prog c abaqus ************ ";
cout << "\n sigma_t "; for (int i=0;i<6;i++) cout << " ("<