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fpakc/src/modules/output/moduleOutput.f90
JGonzalez a2f9957f32 I am dumb 
The Poisson equation was not working because I didn't finish
implementing the new type of BCs. Dirichlet is probably untested. I
should stop doing shitty developments and no testing.
2025-07-18 16:31:52 +02:00

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6.3 KiB
Fortran
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!Contains information about output
MODULE moduleOutput
IMPLICIT NONE
!Output for each node
TYPE, PUBLIC:: outputNode
REAL(8):: den = 0.D0, mom(1:3) = 0.D0, tensorS(1:3,1:3) = 0.D0
CONTAINS
PROCEDURE, PASS(self), PRIVATE:: outputNode_equal_outputNode
PROCEDURE, PASS(self), PRIVATE:: outputNode_equal_real
PROCEDURE, PASS(self), PRIVATE:: outputNode_add_outputNode
PROCEDURE, PASS(self), PRIVATE:: outputNode_sub_outputNode
PROCEDURE, PASS(self), PRIVATE:: outputNode_mul_outputNode
PROCEDURE, PASS(self), PRIVATE:: outputNode_div_int
GENERIC, PUBLIC :: ASSIGNMENT(=) => outputNode_equal_outputNode, outputNode_equal_real
GENERIC, PUBLIC :: OPERATOR(+) => outputNode_add_outputNode
GENERIC, PUBLIC :: OPERATOR(-) => outputNode_sub_outputNode
GENERIC, PUBLIC :: OPERATOR(*) => outputNode_mul_outputNode
GENERIC, PUBLIC :: OPERATOR(/) => outputNode_div_int
END TYPE
!Type for EM data in node
TYPE emNode
REAL(8):: phi
REAL(8):: B(1:3)
END TYPE emNode
!Output in dimensional units to print
TYPE outputFormat
REAL(8):: density, velocity(1:3), pressure, temperature
END TYPE
CHARACTER(:), ALLOCATABLE:: path
CHARACTER(:), ALLOCATABLE:: folder
INTEGER:: iterationDigits
CHARACTER(:), ALLOCATABLE:: iterationFormat
INTEGER:: triggerOutput, counterOutput = 0
INTEGER:: triggerCPUTime, counterCPUTime = 0
LOGICAL:: timeOutput = .FALSE.
LOGICAL:: collOutput = .FALSE.
LOGICAL:: emOutput = .FALSE.
CONTAINS
PURE SUBROUTINE outputNode_equal_outputNode(self, from)
IMPLICIT NONE
CLASS(outputNode), INTENT(inout):: self
CLASS(outputNode), INTENT(in):: from
self%den = from%den
self%mom = from%mom
self%tensorS = from%tensorS
END SUBROUTINE outputNode_equal_outputNode
PURE ELEMENTAL SUBROUTINE outputNode_equal_real(self, from)
IMPLICIT NONE
CLASS(outputNode), INTENT(inout):: self
REAL(8), INTENT(in):: from
self%den = from
self%mom = from
self%tensorS = from
END SUBROUTINE outputNode_equal_real
PURE ELEMENTAL FUNCTION outputNode_add_outputNode(self, that) RESULT(total)
IMPLICIT NONE
CLASS(outputNode), INTENT(in):: self
CLASS(outputNode), INTENT(in):: that
TYPE(outputNode):: total
total%den = self%den + that%den
total%mom = self%mom + that%mom
total%tensorS = self%tensorS + that%tensorS
END FUNCTION outputNode_add_outputNode
PURE ELEMENTAL FUNCTION outputNode_sub_outputNode(self, that) RESULT(total)
IMPLICIT NONE
CLASS(outputNode), INTENT(in):: self
CLASS(outputNode), INTENT(in):: that
TYPE(outputNode):: total
total%den = self%den - that%den
total%mom = self%mom - that%mom
total%tensorS = self%tensorS - that%tensorS
END FUNCTION outputNode_sub_outputNode
PURE ELEMENTAL FUNCTION outputNode_mul_outputNode(self, that) RESULT(total)
IMPLICIT NONE
CLASS(outputNode), INTENT(in):: self
CLASS(outputNode), INTENT(in):: that
TYPE(outputNode):: total
total%den = self%den * that%den
total%mom = self%mom * that%mom
total%tensorS = self%tensorS * that%tensorS
END FUNCTION outputNode_mul_outputNode
PURE ELEMENTAL FUNCTION outputNode_div_int(self, that) RESULT(total)
IMPLICIT NONE
CLASS(outputNode), INTENT(in):: self
INTEGER, INTENT(in):: that
TYPE(outputNode):: total
total%den = self%den / REAL(that)
total%mom = self%mom / REAL(that)
total%tensorS = self%tensorS / REAL(that)
END FUNCTION outputNode_div_int
SUBROUTINE calculateOutput(rawValues, formatValues, nodeVol, speciesIn)
USE moduleConstParam
USE moduleRefParam
USE moduleSpecies
USE moduleMath
IMPLICIT NONE
TYPE(outputNode), INTENT(in):: rawValues
TYPE(outputFormat), INTENT(out):: formatValues
REAL(8), INTENT(in):: nodeVol
CLASS(speciesGeneric), INTENT(in):: speciesIn
REAL(8), DIMENSION(1:3,1:3):: tensorTemp
REAL(8), DIMENSION(1:3):: tempVel
REAL(8):: tempVol
!Resets the node outputs
formatValues%density = 0.D0
formatValues%velocity = 0.D0
formatValues%pressure = 0.D0
formatValues%temperature = 0.D0
tempVol = 1.D0/(nodeVol*Vol_ref)
IF (rawValues%den > 0.D0) THEN
tempVel = rawValues%mom(:)/rawValues%den
tensorTemp = (rawValues%tensorS(:,:) - rawValues%den*outerProduct(tempVel,tempVel))
formatValues%density = rawValues%den*tempVol
formatValues%velocity(:) = tempVel
IF (tensorTrace(tensorTemp) > 0.D0) THEN
formatValues%pressure = speciesIn%m*tensorTrace(tensorTemp)*tempVol/3.D0
formatValues%temperature = formatValues%pressure/(formatValues%density*kb)
END IF
END IF
formatValues%velocity = formatValues%velocity*v_ref
formatValues%pressure = formatValues%pressure*m_ref*v_ref**2
formatValues%temperature = formatValues%temperature*m_ref*v_ref**2
END SUBROUTINE calculateOutput
SUBROUTINE printTime(first)
USE moduleSpecies
USE moduleCompTime
USE moduleCaseParam, ONLY: timeStep
IMPLICIT NONE
LOGICAL, INTENT(in), OPTIONAL:: first
CHARACTER(:), ALLOCATABLE:: fileName
fileName = 'cpuTime.dat'
IF (timeOutput) THEN
IF (PRESENT(first)) THEN
IF (first) THEN
OPEN(20, file = path // folder // '/' // fileName, action = 'write')
WRITE(20, "(A1, 8X, A1, 9X, A1, 7(A20))") "#","t","n","total (s)","push (s)","reset (s)", &
"collision (s)","coulomb (s)", &
"weighting (s)","EMField (s)"
WRITE(*, "(6X,A15,A)") "Creating file: ", fileName
CLOSE(20)
END IF
END IF
OPEN(20, file = path // folder // '/' // fileName, position = 'append', action = 'write')
WRITE (20, "(I10, I10, 7(ES20.6E3))") timeStep, nPartOld, tStep, tPush, tReset, tColl, tCoul, tWeight, tEMField
CLOSE(20)
END IF
END SUBROUTINE printTime
END MODULE moduleOutput
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