Add a New Element Fortran: Difference between revisions
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In the following section we will provide all necessary code to add a new 2d planar truss element into an OpenSees interpreter. The stress-strain relationship will be provided by a UniaxialMaterial object. Please refer to the comments inserted in the code for further explanations. | In the following section we will provide all necessary code to add a new 2d planar truss element into an OpenSees interpreter. The stress-strain relationship will be provided by a UniaxialMaterial object. Please refer to the comments inserted in the code for further explanations. | ||
Please note that the following example has been corrected and expanded by the author of this page. The following code may not match the actual version in the OpenSees repository. | |||
<source lang="fortran"> | <source lang="fortran"> | ||
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type(modelState)::modl | type(modelState)::modl | ||
double precision tang(4, *) | double precision tang(4, *) | ||
double precision resid( | double precision resid(4) | ||
integer::isw; | integer::isw; | ||
integer::error; | integer::error; | ||
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IF (isw == ISW_COMMIT) THEN | IF (isw == ISW_COMMIT) THEN | ||
</source> | |||
In ISW_COMMIT, the state of the model is saved. If your element uses state variables, save them here. | |||
<source lang="fortran"> | |||
call c_f_pointer(eleObj%mats, theCMatPtrPtr, [1]); | call c_f_pointer(eleObj%mats, theCMatPtrPtr, [1]); | ||
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j=OPS_InvokeMaterialDirectly(theCMatPtr, modl, strn, strs, | j=OPS_InvokeMaterialDirectly(theCMatPtr, modl, strn, strs, | ||
+ tng, isw) | + tng, isw) | ||
ELSE IF (isw == ISW_FORM_MASS) THEN | |||
</source> | |||
In ISW_FORM_MASS, the mass matrix (if given by the element) must be returned in tang(). | |||
<source lang="fortran"> | |||
ELSE IF (isw == ISW_FORM_TANG_AND_RESID) THEN | ELSE IF (isw == ISW_FORM_TANG_AND_RESID) THEN | ||
</source> | |||
In ISW_FORM_TANG_AND_RESID, all the trials during a non-linear analysis are performed. DO NOT save state variables here. | |||
<source lang="fortran"> | |||
call c_f_pointer(eleObj%param, theParam, [4]); | call c_f_pointer(eleObj%param, theParam, [4]); | ||
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dLength = 0.0; | dLength = 0.0; | ||
do | do i = 1,2 | ||
dLength = dLength - (d2(i)-d1(i)) * tran(i); | dLength = dLength - (d2(i)-d1(i)) * tran(i); | ||
continue | |||
strn(1) = dLength/L; | strn(1) = dLength/L; | ||
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k = A*tng(1)/L; | k = A*tng(1)/L; | ||
do | do i =1,4 | ||
resid(i) = force * tran(i); | resid(i) = force * tran(i); | ||
do | do j = 1,4 | ||
tang(i,j) = k * tran(i)*tran(j); | tang(i,j) = k * tran(i)*tran(j); | ||
continue | |||
continue | |||
END IF | END IF | ||
Revision as of 09:19, 2 March 2017
to be completed
To add a new Element module using the Fortran language, the developer must provide a new Fortran routine for the Element.
Some information about the state of the model is passed as arguments to the element methods. The input arguments are:
- the element object, eleObj
- the model state, modl
- the isw switch, isw, which indicates what action is needed for each invocation of the procedure.
The output arguments are:
- the tangent stiffness matrix, tang
- the residual vector, resid
- the error code, error
The name of the routine is important for the OpenSees interpreter: when it encounters a new element type it will look for a library with the same name of the element.
NOTE: This document assumes the reader is familiar with the Fortran programming language.
Element Routine
It should be noted the command contains all underscores. This is a consequence of the Fortran compiler, which for the compiler used output the procedure is in all lower case. Please note that before calling memory allocated for the pointers the Fortran code must make a call to the Fortran routine c f pointer().
Example - Truss2D
In the following section we will provide all necessary code to add a new 2d planar truss element into an OpenSees interpreter. The stress-strain relationship will be provided by a UniaxialMaterial object. Please refer to the comments inserted in the code for further explanations.
Please note that the following example has been corrected and expanded by the author of this page. The following code may not match the actual version in the OpenSees repository.
SUBROUTINE trussf(eleObj,modl,tang,resid,isw,error)
!DEC$ IF DEFINED (_DLL)
!DEC$ ATTRIBUTES DLLEXPORT :: TRUSSF
!DEC$ END IF
use elementTypes
use elementAPI
implicit none
type(eleObject)::eleObj
type(modelState)::modl
double precision tang(4, *)
double precision resid(4)
integer::isw;
integer::error;
integer :: tag, nd1, nd2, matTag, numCrd, i, j, numDOF
real *8, pointer::theParam(:)
integer, pointer::theNodes(:)
double precision A, dx, dy, L, cs, sn
double precision dLength, force, k
integer :: iData(3);
integer :: matTags(2);
type(c_ptr) :: theCMatPtr
type(c_ptr), pointer :: theCMatPtrPtr(:)
type(matObject), pointer :: theMat
double precision dData(1), nd1Crd(2), nd2Crd(2)
double precision d1(2), d2(2), tran(4)
double precision strs(1), strn(1), tng(1)
integer numData, err, matTypeThe main IF/THEN structure of the routine begins here; it is needed to select the proper code depending on what the flag isw is requesting.
IF (isw.eq.ISW_INIT) THEN
c get the input data - tag? nd1? nd2? A? matTag?
numData = 3
err = OPS_GetIntInput(numData, iData)
tag = iData(1);
nd1 = iData(2);
nd2 = iData(3);
numData = 1
err = OPS_GetDoubleInput(numData, dData)
A = dData(1);
numData = 1
err = OPS_GetIntInput(numData, iData)
matTag = iData(1);
c Allocate the element state
eleObj%tag = tag
eleObj%nnode = 2
eleObj%ndof = 4
eleObj%nparam = 4
eleObj%nstate = 0
eleObj%nmat = 1
matTags(1) = matTag;
matType = OPS_UNIAXIAL_MATERIAL_TYPE;
err = OPS_AllocateElement(eleObj, matTags, matType)
c Initialize the element properties
call c_f_pointer(eleObj%param, theParam, [4]);
call c_f_pointer(eleObj%node, theNodes, [2]);
numCrd = 2;
err = OPS_GetNodeCrd(nd1, numCrd, nd1Crd);
err = OPS_GetNodeCrd(nd2, numCrd, nd2Crd);
dx = nd2Crd(1)-nd1Crd(1);
dy = nd2Crd(2)-nd1Crd(2);
L = sqrt(dx*dx + dy*dy);
if (L == 0.0) then
c OPS_Error("Warning - truss element has zero length\n", 1);
return;
end if
cs = dx/L;
sn = dy/L;
theParam(1) = A;
theParam(2) = L;
theParam(3) = cs;
theParam(4) = sn;
theNodes(1) = nd1;
theNodes(2) = nd2;
ELSE
IF (isw == ISW_COMMIT) THENIn ISW_COMMIT, the state of the model is saved. If your element uses state variables, save them here.
call c_f_pointer(eleObj%mats, theCMatPtrPtr, [1]);
theCMatPtr = theCMatPtrPtr(1);
j=OPS_InvokeMaterialDirectly(theCMatPtr, modl, strn, strs,
+ tng, isw)
ELSE IF (isw == ISW_REVERT_TO_START) THEN
call c_f_pointer(eleObj%mats, theCMatPtrPtr, [1]);
theCMatPtr = theCMatPtrPtr(1);
j=OPS_InvokeMaterialDirectly(theCMatPtr, modl, strn, strs,
+ tng, isw)
ELSE IF (isw == ISW_FORM_MASS) THENIn ISW_FORM_MASS, the mass matrix (if given by the element) must be returned in tang().
ELSE IF (isw == ISW_FORM_TANG_AND_RESID) THENIn ISW_FORM_TANG_AND_RESID, all the trials during a non-linear analysis are performed. DO NOT save state variables here.
call c_f_pointer(eleObj%param, theParam, [4]);
call c_f_pointer(eleObj%node, theNodes, [2]);
call c_f_pointer(eleObj%mats, theCMatPtrPtr, [1]);
theCMatPtr = theCMatPtrPtr(1);
A = theParam(1);
L = theParam(2);
cs = theParam(3);
sn = theParam(4);
nd1 = theNodes(1);
nd2 = theNodes(2);
numDOF = 2;
err = OPS_GetNodeDisp(nd1, numDOF, d1);
err = OPS_GetNodeDisp(nd2, numDOF, d2);
tran(1) = -cs;
tran(2) = -sn;
tran(3) = cs;
tran(4) = sn;
dLength = 0.0;
do i = 1,2
dLength = dLength - (d2(i)-d1(i)) * tran(i);
continue
strn(1) = dLength/L;
c i = 0
c i=OPS_InvokeMaterial(eleObj, i, modl, strn, strs, tng, isw)
j=OPS_InvokeMaterialDirectly(theCMatPtr, modl, strn, strs,
+ tng, isw)
force = A*strs(1);
k = A*tng(1)/L;
do i =1,4
resid(i) = force * tran(i);
do j = 1,4
tang(i,j) = k * tran(i)*tran(j);
continue
continue
END IF
END IF
c return error code
error = 0
END SUBROUTINE trussfCompilation Instructions for Visual Studio on Windows
The compilation can be carried out with Visual Studio, if Windows machines are used. Intel Intel Visual Fortran can be used, it integrates itself with Visual Studio IDE during installation.