abaqus.properties

# Define SciTE settings for ABAQUS files.

file.patterns.abaqus=*.inp;*.dat;*.msg
filter.abaqus=ABAQUS input (inp)|$(file.patterns.abaqus)|

#lexer.$(file.patterns.abaqus)=abaqus
lexer.$(file.patterns.abaqus)=abaqus

# Cards input deck
cards=*amplitude *base motion *beam section *boundary *buckle *cflux *change contact type \
*change friction *change material *change plastic *change solid section *change surface behavior \
*clearence *cload *complex frequency *conductivity *contact file *contact output *contact pair \
*contact print *controls *correlation length *coupled temperature-displacement *coupling \
*crack propagation *creep *cyclic hardening *cyclic symmetry model *damping *dashpot \
*deformation plasticity *density *depvar *design response *design variables *dflux \
*distributing *distributing coupling *distribution *dload *dsload *dynamic *elastic \
*electrical conductivity *electromagnetics *element *element output *el file *el print *elset \
*end step *equation *expansion *feasible direction *filter *film *fluid constants *fluid section \
*frequency *gap *gap conductance *gap heat generation *geometric constraint *geometric tolerances \
*green *hcf *heading *heat transfer *hyperelastic *hyperfoam *include *initial conditions \
*initial mesh *initial strain increase *konematic *magnetic permeability *mass *mass flow \
*material *matrix assemble *membrane section *modal damping *modal dynamic *modal change \
*mohr coulomb *mohr coulomb hardening *mpc *network mpc *no analysis *nodal thickness \
*node *node file *node output *node print *normal print *normal *nset *objective *orientation \
*physical constants *plastic *pre-tension section *radiate *rate dependent *refine mesh \
*restart *retained nodal dofs *rigid body *robust design *section print *select cyclic symmmetry modes \
*sensitivity *shell section *solid section *specific gas constant *specific heat *spring *static \
*steady state dynamics *step *submodel *substructure generate *substructure matrix output \
*surface *surface behavior *surface interaction *temperature *tie *time points *transform \
*uncoupled temperature-displacement *user element *user material *values at infinity \
*viewfactor *visco

# Keywords
keywords=2d 3d elset material name stiffness file mass file nset output section forces section \
type generate perturbation nlgeom storage absolute zero stefan boltzmann newton gravity \
inc input incf frequencyf op amplitude film amplitude film time delay time delay time reset \
time points time reset total time at start last iterations contact elements load case \
user add fixed submodel step data step data set file bstep mass flow coriolis steady state \
compressible turbulence model shallow water node surface element compressible shock smoothing \
manning constants constraint name composite edge preservation direction weighting totals \
no heat transfer limit orientation offset offset1 offset2 nodal thickness solver submodel \
to node to surface to massless interaction type zero small sliding adjust master slave \ 
value sector omega omega0 pressure-overclosure parameters reset ref node rot node direct \
alpha deltmx magnetostatics material length law n ngraph tie elset matrix check alpha \
beta structural direct rayleigh explicit relative to absolute remove remove all method \
boundary weighting edge preservation direction weighting oil liquid storage global cycmpc \
mode mission step max cycle scaling arruda-boyce mooney-rivlin neo hoke ogden polynomial \
reduced polynomial yeoh plane straight beam dist constrained stiffness file radiation amplitude \
radiation time delay envnode cavity read write write only no change sorted random field only \
nmin nmax nonlinear harmonic thermal network file name output file position tolerance \
integration points maxdof nodes cetol system

# Elements
elements=c3d8 f3d8 c3d8r c3d8i c3d20 c3d20r c3d4 f3d4 c3d10 c3d10t c3d6 f3d6 c3d15 s3 s4 s4r \
s6 s8 s8r m3d m3d4 m3d4r m3d6 m3d8 m3d8r cps3 cps4 cps4r cps6 cps8 cps8r cpe3 cpe4 cpe4r cpe6 \
cpe8 cpe8r cax3 cax4 cax4r cax6 cax8 cax8r b21 b31 b31r b32 b32r t2d2 t3d2 t3d3 d gapuni \
dashpota spring1 spring2 springa dcoup3d mass u1 us3

# Parameters input
parameters=ortho isotropic kinematic combined iso aniso engineering constants temperature yes \
linear element pipe entrance pipe manning pipe bend pipe enlargement pipe contraction pipe gate valve \
pipe inout fluid velocity pressure grav centrif newton channel inout channel sluice gate channel straight \
channel reservoir circ rect pipe box general compression_only coordinate only total time active \
air nitrogen only node new mod tangent fraction matrixstorage spooles taucs pastix pardiso iterative scaling \
iterative cholesky node to surface surface to surface mortar linmortar pglinmortar masless time incrementation \
field line search network cfd contact cumulative orientation intersection norton gradient descent \
gradient projection linear exponential tabular quadratic cubic gauss normal displacement fluid velocity \
mass flow plastic strain pressure solution stress temperature total pressure turbulence velocity \
direct contact pair strain free with strain n p neg pos orifice orifice_pk_ms restrictor branch \
vortex tied rectangular cylindrical johnson cook drag flux sof som soarea r c mechanical thermal user         

keywords.$(file.patterns.abaqus)=
keywords2.$(file.patterns.abaqus)=$(cards)
keywords3.$(file.patterns.abaqus)=$(keywords)
keywords4.$(file.patterns.abaqus)=$(elements)
keywords5.$(file.patterns.abaqus)=$(parameters)
keywords6.$(file.patterns.abaqus)=$
comment.block.abaqus=**

# ABAQUS styles
# Default
style.abaqus.0=fore:#000000
# Comment
style.abaqus.1=fore:#999999,$(font.comment),italics
# Comment-blocks
style.abaqus.2=fore:#999999,$(font.comment),italics
# Number
style.abaqus.3=$(colour.number)
# Quoted string
style.abaqus.4=$(colour.string)
# Abaqus operator
style.abaqus.5=fore:#990000
# Abaqus word
style.abaqus.6=fore:#000000
# Abaqus processor
style.abaqus.7=fore:#008888,bold
# Abaqus command
style.abaqus.8=fore:#0000CC
# Abaqus slashcommand
style.abaqus.9=fore:#0000CC,bold
# Abaqus starcommand
style.abaqus.10=fore:#6600DD,bold
# Abaqus argument
style.abaqus.11=fore:#0077FF
# Abaqus function
style.abaqus.12=fore:#0077DD

#command.compile.*.inp=
#command.build.*.inp=abaqus job=$(FileName) cpus=4
#command.go.*.inp=

autocomplete.abaqus.ignorecase=1
calltip.abaqus.ignorecase=1

# pre1 <-- clean
# pre2 <-- build
# solve <-- compile
# post <-- go

if PLAT_WIN
	command.clean.subsystem.*.inp=0
	command.compile.subsystem.*.inp=0
	command.go.subsystem.*.inp=0
	command.compile.*.inp=C:\PROGRA~2\BCONVE~1\CalculiX\bin\ccx.bat $(FileName)
	command.clean.*.inp="C:\PROGRA~2\BCONVE~1\CalculiX\bin\cgx.bat" -c "$(FileNameExt)"
	command.go.*.inp="C:\PROGRA~2\BCONVE~1\CalculiX\bin\cgx.bat" -v "$(FileName).frd"
	command.compile.*.inp=C:\PROGRA~2\BCONVE~1\CalculiX\bin\ccx.bat $(FileName)
	command.go.*.inp="C:\PROGRA~2\BCONVE~1\CalculiX\bin\cgx.bat" -c "$(FileNameExt)"
	command.go.*.inp="C:\PROGRA~2\BCONVE~1\CalculiX\bin\cgx.bat" -v "$(FileName).frd"