C++ main module for emicrom Package  1.0
Public Member Functions | Static Public Member Functions | Static Public Attributes | Protected Member Functions | Private Member Functions | Private Attributes | List of all members
EMM_OptimalTimeStep Class Reference

This class describes the optimal time. More...

#include <EMM_OptimalTimeStep.h>

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Public Member Functions

virtual tBoolean isSystemCompatible (SPC::EMM_LandauLifschitzSystem system) const
 return true if the system is comatible with the computeNewDt() method More...
 
virtual tBoolean computeNewTimeStep (tReal &dt, tUInteger &nEvaluations)
 compute the new time step More...
 
virtual tString toString () const
 turn the regular time into a string More...
 
tBoolean setSystem (SP::EMM_LandauLifschitzSystem system)
 set the reverse system relation More...
 
void resetSystem ()
 reset the reverse system relation More...
 
void setCharacteristicTime (const tReal &t)
 set the characteristic time the real time will be t. mTc in seconds More...
 
void setTargetTime (const tReal &t)
 set the end time with respect of the characteristic time real time = t * getCharacteristicTime() More...
 
void setDt (const tReal &dt)
 set the time step More...
 
void setDtFactor (const tReal &f)
 set the dt factor More...
 
void setTimeStepsNumber (const tUInteger &n)
 set the time steps number More...
 
const tRealgetDtFactor () const
 get the dt factor More...
 
const tRealgetTargetTime () const
 get the end time More...
 
const tRealgetCharacteristicTime () const
 get the characteristic time More...
 
const tUIntegergetTimeStepsNumber () const
 get the time steps number More...
 
const tRealgetDt () const
 get the time step More...
 
tRealgetDt ()
 get the time step More...
 
void getSharedPointer (SP::CORE_Object &p)
 get the shared pointer of this class into p More...
 
void getSharedPointer (SPC::CORE_Object &p) const
 get the shared pointer of this class into p More...
 
tString getClassName () const
 return the class name of the object More...
 
tString getIdentityString () const
 return the identity string of the object of the form className_at_address More...
 
tString getPointerAddress () const
 return the identity string of the object More...
 
template<class T >
tBoolean isInstanceOf () const
 test if the clas T is an instance of this class More...
 
tBoolean isInstanceOf (const tString &name) const
 test if the object is an instance of className More...
 

Static Public Member Functions

static SP::EMM_OptimalTimeStep New ()
 build a shared pointer associated to the class More...
 
static void setIsMemoryChecked (const tBoolean &v)
 set if the memory checking is used More...
 
static void setOut (SP::CORE_Out out)
 set the output stream More...
 
static void resetOut ()
 reset the output stream More...
 
static void setThread (SP::CORE_Thread thread)
 set the thread More...
 
static void resetThread ()
 reset the output stream More...
 
static CORE_Outout ()
 get the output More...
 
static SP::CORE_Out getOut ()
 get the output More...
 
static CORE_ThreadgetThread ()
 get the profilier More...
 
static const tBooleanisMemoryChecked ()
 get if the memory checking is used More...
 
static tString getClassName (const tString &identityString)
 return the class name of the object More...
 
template<class T >
static tString getTypeName ()
 get type name More...
 
static tBoolean is64Architecture ()
 return true if the machine is a 64 bits machine More...
 
static tBoolean is32Architecture ()
 return true if the machine is a 32 bits machine More...
 
static tString pointer2String (const void *obj)
 return the string representation of a pointer More...
 
static void printObjectsInMemory (ostream &f)
 print object in memory More...
 
static void printObjectsInMemory ()
 print object in memory in the standart output More...
 
static tChar getMaxChar ()
 get the max value for tChar type More...
 
static tChar getMinChar ()
 get the min value for tChar type More...
 
static tUChar getMaxUChar ()
 get the max value for tUChar type More...
 
static tUChar getMinUChar ()
 get the min value for tUChar type More...
 
static tSInt getMaxSInt ()
 get the max value for tSInt type More...
 
static tSInt getMinSInt ()
 get the min value for tSInt type More...
 
static tUSInt getMaxUSInt ()
 get the max value for tUSInt type More...
 
static tUSInt getMinUSInt ()
 get the min value for tUSInt type More...
 
static tInt getMaxInt ()
 get the max value for tInt type More...
 
static tInt getMinInt ()
 get the min value for tInt type More...
 
static tUInt getMaxUInt ()
 get the max value for tUInt type More...
 
static tUInt getMinUInt ()
 get the min value for tUInt type More...
 
static tLInt getMaxLInt ()
 get the max value for tLInt type More...
 
static tLInt getMinLInt ()
 get the min value for tLInt type More...
 
static tULInt getMaxULInt ()
 get the max value for tULInt type More...
 
static tULInt getMinULInt ()
 get the min value for tULInt type More...
 
static tLLInt getMaxLLInt ()
 get the max value for tULInt type More...
 
static tLLInt getMinLLInt ()
 get the min value for tLLInt type More...
 
static tULLInt getMaxULLInt ()
 get the max value for tULLInt type More...
 
static tULLInt getMinULLInt ()
 get the min value for tULLInt type More...
 
static tFloat getMaxFloat ()
 get the max value for tFloat type More...
 
static tFloat getMinFloat ()
 get the min value for tFloat type More...
 
template<class T >
static T getEpsilon ()
 get the epsilon value for T type More...
 
template<class T >
static T getInfinity ()
 get the infinity for T type More...
 
static tFloat getFloatEpsilon ()
 get the epsilon value for tFloat type More...
 
static tFloat getFloatInfinity ()
 get the infinity value for tFloat type More...
 
static tDouble getMaxDouble ()
 get the max value for tDouble type More...
 
static tDouble getMinDouble ()
 get the min value for tDouble type More...
 
static tDouble getDoubleInfinity ()
 get the infinity value for tFloat type More...
 
static tDouble getDoubleEpsilon ()
 get the epsilon value for tDouble type More...
 
static tLDouble getMinLDouble ()
 get the min value for tLDouble type More...
 
static tLDouble getMaxLDouble ()
 get the max value for tLDouble type More...
 
static tLDouble getLDoubleEpsilon ()
 get the epsilon value for tLDouble type More...
 
static tDouble getLDoubleInfinity ()
 get the infinity value for tDouble type More...
 
static tIndex getMaxIndex ()
 get the max value for the array/vector indexing type More...
 
static tIndex getMinIndex ()
 get the min value for the array/vector indexing type More...
 
static tUIndex getMaxUIndex ()
 get the max value for difference the array/vector indexing type More...
 
static tUIndex getMinUIndex ()
 get the min value for difference the array/vector indexing type More...
 
static tFlag getMaxFlag ()
 get the max value for the tFlag type More...
 
static tFlag getMinFlag ()
 get the min value for the tFlag type More...
 
static tUInteger getMaxUInteger ()
 get the max value for the unsigned integer type More...
 
static tUInteger getMinUInteger ()
 get the min value for the unsigned integer type More...
 
static tInteger getMaxInteger ()
 get the max value for the integer type More...
 
static tInteger getMinInteger ()
 get the min value for the integer type More...
 
static tReal getMaxReal ()
 get the max value for the real type More...
 
static tReal getMinReal ()
 get the min value for the real type More...
 
static tReal getRealEpsilon ()
 get the eps which is the difference between 1 and the least value greater than 1 that is representable. More...
 
static tReal getRealInfinity ()
 get the infinity value More...
 
template<class T >
static T computeEpsilon ()
 compute epsilon More...
 

Static Public Attributes

static const tReal Mu0 =4*M_PI*1e-07
 
static const tReal Gamma =-1.7e11
 
static const tDimension X =0
 
static const tDimension Y =1
 
static const tDimension Z =2
 
static const tReal NULL_VALUE [] ={0,0,0}
 

Protected Member Functions

 EMM_OptimalTimeStep (void)
 create More...
 
virtual ~EMM_OptimalTimeStep (void)
 destroy More...
 
SPC::EMM_LandauLifschitzSystem getSystem () const
 get system for reading More...
 
SP::EMM_LandauLifschitzSystem getSystem ()
 get system for writing More...
 
virtual void toDoAfterThisSetting ()
 method called after the setting of the shared pointer this method can only be called once. More...
 
void setThis (SP::CORE_Object p)
 set this weak shared pointer called toDoAfterThis setting method More...
 

Private Member Functions

 SP_OBJECT (EMM_OptimalTimeStep)
 
tBoolean computeOptimalTimeStep (EMM_GradGaussLegendreRelaxation &GSystem, tReal &dt)
 update the time step More...
 

Private Attributes

MATH_P4 mP4
 
tReal mT [4]
 
SP::EMM_RealField mGradH_gradF
 

Detailed Description

This class describes the optimal time.

The optimal time is computed in order to maximize the energy variation.

$ \displaystyle \frac{\partial m}{\partial t} = f(m) $ where $ f(m)= \displaystyle \alpha \left ( m \wedge h(m) + \beta(x) m \wedge ( m \wedge h(m) ) \right ) $ with adimensionized variables.

Using the mean formula of integral at the mid point:

$ \displaystyle m(t^{i+1})-m(t^i)=dt . f(m(t^i+\frac{dt}{2})) $ where dt= $ \displaystyle t^{i+1} - t^i $.

By developping m(t) at order 2, we obtain:

$ \displaystyle f\left (m(t^i+\frac{dt}{2})\right)=f\left(m(t^i)\right)+\frac{dt}{2} \nabla_mf\left(m(t^i)\right)\left[\frac{\partial m}{\partial t}(t^i)\right] +dt.\epsilon(dt)$

$ \displaystyle f\left(m(t^i+\frac{dt}{2})\right)=f\left(m(t^i)\right)+\frac{dt}{2} \nabla_mf\left(m(t^i)\right)\left[f(m(t^i))\right] +dt.\epsilon(dt) $

if we denote :

we obtain:

$ \displaystyle m^{i+1}=m^i+dt.f^i +\frac{dt^2}{2} \nabla^i_mf[f^i] $

After computations,

$ \nabla_m f(m)[\delta]= \displaystyle \alpha \left ( \delta \wedge h(m) + m \wedge \nabla_mh(m)[\delta] +\beta(x) \displaystyle \left ( m \wedge \left ( m \wedge \nabla_mh(m)[\delta] \right ) + m \wedge \left( \delta \wedge h(m) \right ) + \delta \wedge \left( m \wedge h(m) \right ) \right ) \right ) $

The time step dt is chosen such that the decreasing of energy during 2 successive iterations is maximal.

The adimensionized energy $ e =\displaystyle \sum_i \int_{\omega_i} e_c(m) dx$ with $ \displaystyle \frac{de_c(m)}{dm}=- 2 \sigma h(m) $.

When h is linear and self-adjointness, we have : $ e=\displaystyle - \sum_i \int_{\omega_i} \sigma_i h(m).m dx $.

When h is constant equal to $ h_{ext} $, $ e=\displaystyle - 2 \sum_i \int_{\omega_i} \sigma_i h_{ext}.m dx$.

So, if we have h affine, we denote by

with $ \tilde h(m) $ linear and self-adjointness.

The adimensionized energy becomes $ e=\displaystyle -\sum_i \sigma_i \int_{\omega_i} g(m).m dx $

The variation of energy becomes, with (,) the ponderated scalar product in $ L^2(\omega), (f,g)= \displaystyle \sum_i \sigma_i \int_{\omega_i} f(x).g(x) dx $

$ d\tilde E=\tilde E^{i+1}-\tilde E^{i}=-\displaystyle \left( (g(m^{i+1}),m^{i+1}) - (g^i,m^i) \right ) $

We use $ \displaystyle m^{i+1}=m^i+dt.f^i +\frac{dt^2}{2} \nabla_m^if $,

$ (g(m^{i+1}),m^{i+1}) = \displaystyle \left (g(m^i+dt.f^i +\frac{dt^2}{2} \nabla^i_mf),m^{i+1}\right )$

$ (g(m^{i+1}),m^{i+1}) = \displaystyle \left ( \tilde h(m^i) +dt.\tilde h(f^i) +\frac{dt^2}{2} \tilde h\left(\nabla^i_mf\right) +2h_{ext},m^{i+1}\right )$

$ (g(m^{i+1}),m^{i+1}) = \displaystyle \left ( \tilde h(m^i), m^{i+1}\right) $ $\displaystyle + dt. \left( \tilde h(f^i), m^{i+1}\right ) $ $\displaystyle + \frac{dt^2}{2} \left( \tilde h\left(\nabla^i_m f \right), m^{i+1} \right )$ $\displaystyle + \left( 2h_{ext}, m^{i+1}\right) $

or:

So,

$ \displaystyle (g(m^{i+1}),m^{i+1})- (g(m^{i}),m^{i})=dt.\left( \left(\tilde h(m^i),f^i\right)+\left(2h_{ext},f^i\right)+\left(\tilde h(f^i),m^i\right) \right) $ $+ \displaystyle \frac{dt^2}{2} \left( \left(\tilde h(m^i),\nabla^i_mf\right)+\left(2h_{ext},\nabla^i_mf\right)+2\left(\tilde h(f^i),f^i\right)+\left(\tilde h(\nabla^i_mf),m^i\right)\right)$ $+ \displaystyle \frac{dt^3}{2} \left( \left(\tilde h(f^i),\nabla^i_mf\right)+\left(\tilde h(\nabla^i_mf),f^i\right)\right)$ $+ \displaystyle \frac{dt^4}{4} \left( \tilde h(\nabla^i_mf),\nabla^i_mf\right)$

As $ \tilde h $ is self-adjointness, we have

We obtain: $ d\tilde E=-dt \left( 2(\tilde h(m^i),f^i)+2(h_{ext},f^i) + \frac{dt}{2}\left ( 2(\tilde h(m^i),\nabla^i_mf)+2(h_{ext},\nabla^i_mf)+2(\tilde h(f^i),f^i)\right )+\frac{dt^2}{2}\left( 2(\tilde h(f^i),\nabla^i_m(f)) \right)+\frac{dt^3}{4}\left(\tilde h(\nabla^i_mf),\nabla^i_mf \right) \right ) $.

As h is affine, to eliminate $ \tilde h $, we use either $ \tilde h(x)=\nabla_mh(m^i).x = \nabla^i_m h(x) $ or $ \tilde h(m)+h_{ext}=h(m) $

So, $ d\tilde E=-2.dt\left( (h(m^i),f^i)+ \frac{dt}{2}\left ( (h(m^i),\nabla^i_mf)+(\nabla^i_mh(f^i),f^i)\right )+\frac{dt^2}{2}\left( (\nabla^i_mh(f^i),\nabla^i_m(f)) \right)+\frac{dt^3}{8}\left(\nabla^i_mh(\nabla^i_mf),\nabla^i_mf \right) \right ) $.

We have to compute the maximum of a polynom of degre 4 : $ P(x)=x \cdot (a_1+a_2 x +a_3 x^2 +a_4 x^3) $ with

For good convergence property, we multipled the optimal time step by a factor less than 1 (1.e-2 by default).

see EMM_OptimalTimeStep::computeNewDeltaT()

Author
Stephane Despreaux
Version
1.0

Constructor & Destructor Documentation

◆ EMM_OptimalTimeStep()

EMM_OptimalTimeStep::EMM_OptimalTimeStep ( void  )
protected

create

References mP4.

Referenced by New().

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◆ ~EMM_OptimalTimeStep()

EMM_OptimalTimeStep::~EMM_OptimalTimeStep ( void  )
protectedvirtual

destroy

Member Function Documentation

◆ computeEpsilon()

template<class T >
static T CORE_Object::computeEpsilon ( )
inlinestaticinherited

compute epsilon

Returns
the epsilon value eps=10^{-p/3} where p is defined by getEpsilon()=10^{-p}

◆ computeNewTimeStep()

tBoolean EMM_OptimalTimeStep::computeNewTimeStep ( tReal dt,
tUInteger nEvaluations 
)
virtual

compute the new time step

Parameters
dtthe new time step
nEvaluationsthe number of evaluations of the Landau Lifshcitz functions for computing the time step
Returns
true if the dt computation succeeded

Note the following variables:

  • M the magnetization field of the system
  • H(M) the total magnetic excitation of system
  • $ \nabla_M F(M)[D] $ is the gradient of F with respect to M at M in direction D
  • $ \nabla_M H(M)[D] $ is the gradient of H with respect to M at M in direction D
  • $ \lambda_1=F $
  • $ \lambda_2=\nabla_M F(M)[\lambda_1]= - \displaystyle \left ( \lambda_1 \wedge H(M) + M \wedge \nabla_M H(M)[\lambda_1] \right ) - \beta \sigma \displaystyle \left ( M \wedge \left ( M \wedge \nabla_M H(M)[\lambda_1] \right ) + M \wedge \left( \lambda_1 \wedge H(M) \right ) + \lambda_1 \wedge \left( M \wedge H(M) \right ) \right ) $.
  • $ a_1=\|<H,M>\|^2= <H,\lambda_1> $
  • $ a_2=(<H,\lambda_2)>+<\lambda_1,\nabla_M H(\lambda_1)>)/2 $
  • $ a_3=<\nabla_M H(\lambda_1),\lambda_2>/2 $
  • $ a_4=<\nabla_M H(\lambda_2),\lambda_2>/8 $

See EMM_OptimalTimeStep for details of the computing.

Compute the minimum of the polynomial $ P(x)=x \cdot (a_1+a_2 \cdot x+a_3 \cdot x^2+a_4 \cdot x^3) $ to obtain the best time step. see MATH_P4::maximize()

At the optimal point, the variation of energy is maximum : $ dE=-2dt \cdot \left [ \| h^i \wedge m^i \|^2 + \frac{dt}{2} \left ( (\nabla^i_mf,h^i) + (f^i,h(f^i)) \right ) +\frac{dt^2}{2} \left( (\nabla^i_mf,h(f^i))\right)+\frac{dt^3}{8} \left( (\nabla^i_mf,h(\nabla_m^if))\right) \right ]$ .

Reimplemented from EMM_RegularTimeStep.

References computeOptimalTimeStep(), EMM_Stepper::getSystem(), and null.

Referenced by isSystemCompatible().

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◆ computeOptimalTimeStep()

tBoolean EMM_OptimalTimeStep::computeOptimalTimeStep ( EMM_GradGaussLegendreRelaxation GSystem,
tReal dt 
)
private

update the time step

Parameters
GSystemthe gradient computationable system used to optimise the time step
dtthe time step to update
Returns
true if the updating succeeded.

References EMM_GradGaussLegendreRelaxation::computeMagneticExcitationFieldGradient(), EMM_RealField::dot(), MATH_Pn::firstPositiveMaximum(), EMM_GaussLegendreRelaxation::getIntermediateMagnetizationField(), EMM_LandauLifschitzSystem::getMagneticExcitationField(), EMM_GradGaussLegendreRelaxation::getMagneticExcitationFieldGradient(), EMM_LandauLifschitzSystem::getMagnetizationField(), EMM_LandauLifschitzSystem::getMagnetizationFieldTimeDerivative(), EMM_GradGaussLegendreRelaxation::getMagnetizationFieldTimeDerivativeGradient(), EMM_LandauLifschitzSystem::getSigma(), CORE_Object::getThread(), mP4, mT, CORE_Object::out(), CORE_Thread::startChrono(), and CORE_Thread::stopChrono().

Referenced by computeNewTimeStep(), and toString().

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◆ getCharacteristicTime()

const tReal& EMM_Stepper::getCharacteristicTime ( ) const
inlineinherited

get the characteristic time

Returns
the characteristic time

References EMM_Stepper::mCharacteristicTime.

◆ getClassName() [1/2]

tString CORE_Object::getClassName ( ) const
inherited

return the class name of the object

Returns
the class name of the object

References tString.

Referenced by CORE_Object::getIdentityString(), EMM_Operator::getName(), and CORE_Object::isMemoryChecked().

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◆ getClassName() [2/2]

static tString CORE_Object::getClassName ( const tString identityString)
inlinestaticinherited

return the class name of the object

Parameters
identityStringthe identity string of the object
Returns
the class name

◆ getDoubleEpsilon()

static tDouble CORE_Object::getDoubleEpsilon ( )
inlinestaticinherited

get the epsilon value for tDouble type

Returns
the epsilon value for tDouble type

Referenced by CORE_Test::testType().

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◆ getDoubleInfinity()

static tDouble CORE_Object::getDoubleInfinity ( )
inlinestaticinherited

get the infinity value for tFloat type

Returns
the intinity value for tFloat type

◆ getDt() [1/2]

const tReal& EMM_Stepper::getDt ( ) const
inlineinherited

get the time step

Returns
the time step

References EMM_Stepper::mDt.

Referenced by EMM_IterativeTimeStep::computeInitialTimeStep(), and EMM_RegularTimeStep::computeNewTimeStep().

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◆ getDt() [2/2]

tReal& EMM_Stepper::getDt ( )
inlineinherited

get the time step

Returns
the time step

References EMM_Stepper::mDt.

◆ getDtFactor()

const tReal& EMM_Stepper::getDtFactor ( ) const
inlineinherited

get the dt factor

Returns
the multiplied dt factor

References EMM_Stepper::mDtFactor.

◆ getEpsilon()

template<class T >
static T CORE_Object::getEpsilon ( )
inlinestaticinherited

get the epsilon value for T type

Returns
the epsilon value for T type

◆ getFloatEpsilon()

static tFloat CORE_Object::getFloatEpsilon ( )
inlinestaticinherited

get the epsilon value for tFloat type

Returns
the epsilon value for tFloat type

Referenced by CORE_Test::testType().

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◆ getFloatInfinity()

static tFloat CORE_Object::getFloatInfinity ( )
inlinestaticinherited

get the infinity value for tFloat type

Returns
the intinity value for tFloat type

◆ getIdentityString()

tString CORE_Object::getIdentityString ( ) const
inlineinherited

return the identity string of the object of the form className_at_address

Returns
the identity string of the object

References CORE_Object::getClassName(), CORE_Object::pointer2String(), and tString.

Referenced by MATH_GaussLegendreIntegration::copy(), EMM_MultiScaleGrid::initialize(), CORE_Object::isInstanceOf(), CORE_Object::printObjectsInMemory(), MATH_Matrix::toString(), EMMG_SLPeriodicMultiScale::toString(), EMM_Stepper::toString(), EMM_AnisotropyDirectionsField::toString(), EMM_BlockMassMatrix::toString(), CORE_Object::toString(), EMM_Tensors::toString(), EMM_MultiScaleGrid::toString(), EMM_MatterField::toString(), EMM_Grid3D::toString(), and EMM_LandauLifschitzSystem::toString().

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◆ getInfinity()

template<class T >
static T CORE_Object::getInfinity ( )
inlinestaticinherited

get the infinity for T type

Returns
the infinity value for T type

◆ getLDoubleEpsilon()

static tLDouble CORE_Object::getLDoubleEpsilon ( )
inlinestaticinherited

get the epsilon value for tLDouble type

Returns
the epsilon value for tLDouble type

Referenced by CORE_Test::testType().

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◆ getLDoubleInfinity()

static tDouble CORE_Object::getLDoubleInfinity ( )
inlinestaticinherited

get the infinity value for tDouble type

Returns
the infinity value for tDouble type

◆ getMaxChar()

static tChar CORE_Object::getMaxChar ( )
inlinestaticinherited

get the max value for tChar type

Returns
the max value for tChar type

Referenced by CORE_Test::testType().

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◆ getMaxDouble()

static tDouble CORE_Object::getMaxDouble ( )
inlinestaticinherited

get the max value for tDouble type

Returns
the max value for tDouble type

Referenced by CORE_Test::testType().

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◆ getMaxFlag()

static tFlag CORE_Object::getMaxFlag ( )
inlinestaticinherited

get the max value for the tFlag type

Returns
the max value for the tFlag type

Referenced by CORE_Test::testType().

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◆ getMaxFloat()

static tFloat CORE_Object::getMaxFloat ( )
inlinestaticinherited

get the max value for tFloat type

Returns
the max value for tFloat type

Referenced by CORE_Test::testType().

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◆ getMaxIndex()

static tIndex CORE_Object::getMaxIndex ( )
inlinestaticinherited

get the max value for the array/vector indexing type

Returns
the max value for the array/vector indexing type

Referenced by CORE_Test::testType().

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◆ getMaxInt()

static tInt CORE_Object::getMaxInt ( )
inlinestaticinherited

get the max value for tInt type

Returns
the max value for tInt type

Referenced by MATSGN_FFT::fastFourierTransform3D_FFTW(), and CORE_Test::testType().

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◆ getMaxInteger()

static tInteger CORE_Object::getMaxInteger ( )
inlinestaticinherited

get the max value for the integer type

Returns
the max value for the integer type

Referenced by CORE_Test::testType().

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◆ getMaxLDouble()

static tLDouble CORE_Object::getMaxLDouble ( )
inlinestaticinherited

get the max value for tLDouble type

Returns
the max value for tLDouble type

Referenced by CORE_Test::testType().

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◆ getMaxLInt()

static tLInt CORE_Object::getMaxLInt ( )
inlinestaticinherited

get the max value for tLInt type

Returns
the max value for tLInt type

Referenced by CORE_Test::testType().

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◆ getMaxLLInt()

static tLLInt CORE_Object::getMaxLLInt ( )
inlinestaticinherited

get the max value for tULInt type

Returns
the max value for tULInt type

Referenced by CORE_Test::testType().

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◆ getMaxReal()

static tReal CORE_Object::getMaxReal ( )
inlinestaticinherited

get the max value for the real type

Returns
he max value for the real type

Referenced by EMM_MatterField::adimensionize(), and CORE_Test::testType().

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◆ getMaxSInt()

static tSInt CORE_Object::getMaxSInt ( )
inlinestaticinherited

get the max value for tSInt type

Returns
the max value for tSInt type

Referenced by CORE_Test::testType().

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◆ getMaxUChar()

static tUChar CORE_Object::getMaxUChar ( )
inlinestaticinherited

get the max value for tUChar type

Returns
the max value for tUChar type

Referenced by CORE_Test::testType().

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◆ getMaxUIndex()

static tUIndex CORE_Object::getMaxUIndex ( )
inlinestaticinherited

get the max value for difference the array/vector indexing type

Returns
the max value for difference the array/vector indexing type

Referenced by CORE_Vector< T >::addAfterIndices(), CORE_Vector< T >::search(), CORE_Test::testType(), CORE_Integer::toHexString(), and CORE_Integer::toString().

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◆ getMaxUInt()

static tUInt CORE_Object::getMaxUInt ( )
inlinestaticinherited

get the max value for tUInt type

Returns
the max value for tUInt type

Referenced by EMM_Array< tCellFlag >::loadFromFile(), EMM_RealField::loadFromFile(), and CORE_Test::testType().

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◆ getMaxUInteger()

static tUInteger CORE_Object::getMaxUInteger ( )
inlinestaticinherited

get the max value for the unsigned integer type

Returns
the max value for the unsigned integer type

Referenced by MATH_Pn::computeExtrenums(), EMM_MultiScaleGrid::computeLevelsNumber(), EMM_Input::restoreBackup(), MATH_P0::solve(), and CORE_Test::testType().

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◆ getMaxULInt()

static tULInt CORE_Object::getMaxULInt ( )
inlinestaticinherited

get the max value for tULInt type

Returns
the max value for tULInt type

Referenced by CORE_Test::testType().

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◆ getMaxULLInt()

static tULLInt CORE_Object::getMaxULLInt ( )
inlinestaticinherited

get the max value for tULLInt type

Returns
the max value for tULLInt type

Referenced by CORE_Test::testType().

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◆ getMaxUSInt()

static tUSInt CORE_Object::getMaxUSInt ( )
inlinestaticinherited

get the max value for tUSInt type

Returns
the max value for tUSInt type

Referenced by CORE_Test::testType().

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◆ getMinChar()

static tChar CORE_Object::getMinChar ( )
inlinestaticinherited

get the min value for tChar type

Returns
the min value for tChar type

Referenced by CORE_Test::testType().

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◆ getMinDouble()

static tDouble CORE_Object::getMinDouble ( )
inlinestaticinherited

get the min value for tDouble type

Returns
the min value for tDouble type

Referenced by CORE_Test::testType().

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◆ getMinFlag()

static tFlag CORE_Object::getMinFlag ( )
inlinestaticinherited

get the min value for the tFlag type

Returns
the min value for the tFlag type

Referenced by CORE_Test::testType().

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◆ getMinFloat()

static tFloat CORE_Object::getMinFloat ( )
inlinestaticinherited

get the min value for tFloat type

Returns
the min value for tFloat type

Referenced by CORE_Test::testType().

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◆ getMinIndex()

static tIndex CORE_Object::getMinIndex ( )
inlinestaticinherited

get the min value for the array/vector indexing type

Returns
the min value for the array/vector indexing type

Referenced by CORE_Test::testType().

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◆ getMinInt()

static tInt CORE_Object::getMinInt ( )
inlinestaticinherited

get the min value for tInt type

Returns
the min value for tInt type

Referenced by CORE_Test::testType().

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◆ getMinInteger()

static tInteger CORE_Object::getMinInteger ( )
inlinestaticinherited

get the min value for the integer type

Returns
the minin value for the integer type

Referenced by CORE_Test::testType().

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◆ getMinLDouble()

static tLDouble CORE_Object::getMinLDouble ( )
inlinestaticinherited

get the min value for tLDouble type

Returns
the min value for tLDouble type

Referenced by CORE_Test::testType().

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◆ getMinLInt()

static tLInt CORE_Object::getMinLInt ( )
inlinestaticinherited

get the min value for tLInt type

Returns
the min value for tLInt type

Referenced by CORE_Test::testType().

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◆ getMinLLInt()

static tLLInt CORE_Object::getMinLLInt ( )
inlinestaticinherited

get the min value for tLLInt type

Returns
the min value for tLLInt type

Referenced by CORE_Test::testType().

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◆ getMinReal()

static tReal CORE_Object::getMinReal ( )
inlinestaticinherited

get the min value for the real type

Returns
the min value for the real type

Referenced by CORE_Test::testType().

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◆ getMinSInt()

static tSInt CORE_Object::getMinSInt ( )
inlinestaticinherited

get the min value for tSInt type

Returns
the min value for tSInt type

Referenced by CORE_Test::testType().

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◆ getMinUChar()

static tUChar CORE_Object::getMinUChar ( )
inlinestaticinherited

get the min value for tUChar type

Returns
the min value for tUChar type

Referenced by CORE_Test::testType().

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◆ getMinUIndex()

static tUIndex CORE_Object::getMinUIndex ( )
inlinestaticinherited

get the min value for difference the array/vector indexing type

Returns
the min value for difference the array/vector indexing type

Referenced by CORE_Test::testType().

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◆ getMinUInt()

static tUInt CORE_Object::getMinUInt ( )
inlinestaticinherited

get the min value for tUInt type

Returns
the min value for tUInt type

Referenced by CORE_Test::testType().

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◆ getMinUInteger()

static tUInteger CORE_Object::getMinUInteger ( )
inlinestaticinherited

get the min value for the unsigned integer type

Returns
the min value for the unsigned integer type

Referenced by CORE_Test::testType().

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◆ getMinULInt()

static tULInt CORE_Object::getMinULInt ( )
inlinestaticinherited

get the min value for tULInt type

Returns
the min value for tULInt type

Referenced by CORE_Test::testType().

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◆ getMinULLInt()

static tULLInt CORE_Object::getMinULLInt ( )
inlinestaticinherited

get the min value for tULLInt type

Returns
the min value for tULLInt type

Referenced by CORE_Test::testType().

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◆ getMinUSInt()

static tUSInt CORE_Object::getMinUSInt ( )
inlinestaticinherited

get the min value for tUSInt type

Returns
the min value for tUSInt type

Referenced by CORE_Test::testType().

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◆ getOut()

static SP::CORE_Out CORE_Object::getOut ( )
inlinestaticinherited

get the output

Returns
the shared pointer to the output stream

References CORE_Object::OUT.

◆ getPointerAddress()

tString CORE_Object::getPointerAddress ( ) const
inlineinherited

return the identity string of the object

Returns
the identity string of the object

References CORE_Object::pointer2String().

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◆ getRealEpsilon()

static tReal CORE_Object::getRealEpsilon ( )
inlinestaticinherited

get the eps which is the difference between 1 and the least value greater than 1 that is representable.

Returns
the eps which is the difference between 1 and the least value greater than 1 that is representable.

Referenced by MATH_P4::solveP4De(), and CORE_Test::testType().

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◆ getRealInfinity()

static tReal CORE_Object::getRealInfinity ( )
inlinestaticinherited

get the infinity value

Returns
the inifinity value for the real type

Referenced by BrentFunction::BrentFunction(), EMM_OperatorsTest::compareDiscretizedData(), EMM_IterativeTimeStep::EMM_IterativeTimeStep(), EMM_SLElementaryDemagnetizedMatrix::Kxy(), NRFunction::NRFunction(), EMM_PolynomialInterpolationTimeStep::optimizeTimeFunction(), and CORE_Test::testType().

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◆ getSharedPointer() [1/2]

void CORE_Object::getSharedPointer ( SP::CORE_Object &  p)
inlineinherited

get the shared pointer of this class into p

Parameters
p: shared pointer of the class This

Referenced by CORE_Map< Key, Value >::getSharedPointer(), CORE_ArrayList< tString >::getSharedPointer(), EMM_Array< tCellFlag >::getSharedPointer(), CORE_Array< tCellFlag >::getSharedPointer(), CORE_MorseArray< tUChar >::getSharedPointer(), CORE_Vector< T >::getSharedPointer(), and CORE_Object::printObjectsInMemory().

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◆ getSharedPointer() [2/2]

void CORE_Object::getSharedPointer ( SPC::CORE_Object &  p) const
inlineinherited

get the shared pointer of this class into p

Parameters
p: shared pointer of the class This

◆ getSystem() [1/2]

SPC::EMM_LandauLifschitzSystem EMM_Stepper::getSystem ( ) const
inlineprotectedinherited

get system for reading

Returns
the system

Referenced by computeNewTimeStep(), EMM_IterativeTimeStep::computeTimeFunction(), EMM_IterativeTimeStep::computeTimeFunctionDerivative(), and EMM_SecondOrderIterativeTimeStep::computeTimeFunctionDerivatives().

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◆ getSystem() [2/2]

SP::EMM_LandauLifschitzSystem EMM_Stepper::getSystem ( )
inlineprotectedinherited

get system for writing

Returns
the system

References EMM_Stepper::computeNewTimeStep(), tBoolean, EMM_Stepper::toString(), tReal, tString, and tUInteger.

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◆ getTargetTime()

const tReal& EMM_Stepper::getTargetTime ( ) const
inlineinherited

get the end time

Returns
the target time

References EMM_Stepper::mEndTime.

◆ getThread()

static CORE_Thread& CORE_Object::getThread ( )
inlinestaticinherited

get the profilier

Returns
the profiler

Referenced by MATH_MaskVector::add(), MATH_Vector::add(), EMM_DisplacementFEMOperator::addBoundaryElasticStress(), EMM_DisplacementFEMOperator::buildDataOnNeumannBoundaryFaces(), EMM_DisplacementFVMOperator::computeCineticEnergy(), EMM_DisplacementFVMOperator::computeElasticStress(), EMM_DisplacementFEMOperator::computeElasticStress(), EMM_DisplacementFVMOperator::computeElasticTensor(), EMM_DisplacementFEMOperator::computeElasticTensor(), EMM_StaticMagneticTensorOperator::computeEnergy(), EMM_CubicAnisotropyOperator::computeEnergy(), EMM_MagnetostrictionOperator::computeEnergy(), EMM_DisplacementOperator::computeEnergy(), EMM_AnisotropyOperator::computeEnergyWithMagneticExcitation(), EMM_DisplacementFVMOperator::computeEquilibriumMatrixDiagonalConditioner(), EMM_DisplacementFEMOperator::computeEquilibriumMatrixDiagonalConditioner(), EMM_FullExchangeOperator::computeMagneticExcitationField(), EMM_StaticMagnetostrictionOperator::computeMagneticExcitationField(), EMM_LinearAnisotropyOperator::computeMagneticExcitationField(), EMM_StaticMagneticTensorOperator::computeMagneticExcitationField(), EMM_CubicAnisotropyOperator::computeMagneticExcitationField(), EMM_MinimalExchangeOperator::computeMagneticExcitationField(), EMM_AnisotropyOperator::computeMagneticExcitationField(), EMM_MagnetostrictionOperator::computeMagneticExcitationField(), EMM_CubicAnisotropyOperator::computeMagneticExcitationFieldGradient(), EMM_AnisotropyOperator::computeMagneticExcitationFieldGradient(), EMM_DisplacementFVMOperator::computeMagneticStress(), EMM_DisplacementFEMOperator::computeMagneticStress(), computeOptimalTimeStep(), EMM_DisplacementFEMOperator::computeStressConstraintEnergy(), EMM_FullExchangeOperator::discretize(), EMM_MinimalExchangeOperator::discretize(), EMM_CondensedMassMatrix::discretize(), EMM_LinearAnisotropyOperator::discretize(), EMM_AnisotropyOperator::discretize(), EMM_DemagnetizedOperator::discretize(), EMMG_SLDemagnetizedOperator::discretize(), EMM_LandauLifschitzSystem::discretize(), MATH_Vector::divide(), MATH_MaskVector::dot(), MATH_Vector::dot(), EMM_4SymmetricTensors::doubleDot(), EMM_4Tensors::doubleDotCrossDoubleDotScalar(), EMM_4Tensors::doubleDotCrossProduct(), EMM_4Tensors::doubleDotCrossSquaredScalar(), EMM_4Tensors::doubleDotProduct(), MATH_Vector::init(), MATH_MaskVector::init(), EMM_LandauLifschitzODE_RK::integrateMagnetizationFieldAtTime(), EMM_DisplacementFVM_Interpolator::interpolateUAtVertices(), EMMG_SLDemagnetizedOperator::localAssembly(), EMM_DisplacementOperator::nullProjectionOnDirichletBoundary(), EMM_DisplacementOperator::periodicProjection(), EMM_2PackedSymmetricTensors::product(), EMM_CanonicalMassMatrix::product(), MATH_FullMatrix::product(), EMM_CondensedMassMatrix::product(), EMM_BlockMassMatrix::product(), MATH_MorseMatrix::product(), EMMG_SLDemagnetizedOperator::product(), EMM_DisplacementOperator::projectionOnDirichletBoundary(), EMM_LandauLifschitzSystem::resetOperatorsToInitialState(), EMM_DisplacementFVMOperator::setBoundaryFaceTypes(), FFTW_MultiDFTs::setFFT(), FFTW_MultiLevelsDFT::setFFT(), FFTW_MultiLevelsDFT::setLevels(), FFTW_MultiDFTs::setPlan(), FFTW_MultiLevelsDFT::setPlan(), EMM_CondensedMassMatrix::solve(), EMM_LandauLifschitzODE::solveODE(), EMM_4SymmetricTensors::squaredDoubleDot(), EMM_4Tensors::squaredDoubleDotCrossScalar(), EMM_4Tensors::squaredDoubleDotScalar(), EMM_CanonicalMassMatrix::symmetricDot(), EMM_CondensedMassMatrix::symmetricDot(), EMM_BlockMassMatrix::symmetricDot(), FFTW_Test::test(), MATH_SolverTest::test(), EMM_ODETest::testODE(), and EMM_Grid3D::updateLimitConditionOnPoints().

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◆ getTimeStepsNumber()

const tUInteger& EMM_Stepper::getTimeStepsNumber ( ) const
inlineinherited

get the time steps number

References EMM_Stepper::mTimeStepsNumber.

◆ getTypeName()

template<class T >
static tString CORE_Object::getTypeName ( )
inlinestaticinherited

get type name

Returns
the type name of the class

References tString.

◆ is32Architecture()

static tBoolean CORE_Object::is32Architecture ( )
inlinestaticinherited

return true if the machine is a 32 bits machine

Returns
true is the computing is done in a 32 bits machine

References CORE_Object::pointer2String(), CORE_Object::printObjectsInMemory(), and tString.

Referenced by CORE_Test::testType().

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◆ is64Architecture()

static tBoolean CORE_Object::is64Architecture ( )
inlinestaticinherited

return true if the machine is a 64 bits machine

Returns
true is the computing is done in a 64 bits machine

Referenced by EMM_VTK::getVTKType(), and CORE_Test::testType().

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◆ isInstanceOf() [1/2]

template<class T >
tBoolean CORE_Object::isInstanceOf ( ) const
inlineinherited

test if the clas T is an instance of this class

Returns
true if the object is an instance of T

References null.

Referenced by MATH_ToeplitzTest::toeplitzTest().

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◆ isInstanceOf() [2/2]

tBoolean CORE_Object::isInstanceOf ( const tString name) const
inlineinherited

test if the object is an instance of className

Parameters
namename of the class
Returns
true if the object is an instance of class Name

References CORE_Object::getIdentityString().

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◆ isMemoryChecked()

static const tBoolean& CORE_Object::isMemoryChecked ( )
inlinestaticinherited

get if the memory checking is used

Returns
true: if the memory checking is used.

References CORE_Object::getClassName(), CORE_Object::mIsMemoryTesting, and tString.

Referenced by main().

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◆ isSystemCompatible()

virtual tBoolean EMM_OptimalTimeStep::isSystemCompatible ( SPC::EMM_LandauLifschitzSystem  system) const
inlinevirtual

return true if the system is comatible with the computeNewDt() method

Returns
the true is the time can be used with the system

Reimplemented from EMM_Stepper.

References computeNewTimeStep(), EMM_Stepper::isSystemCompatible(), tBoolean, tReal, and tUInteger.

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◆ New()

static SP::EMM_OptimalTimeStep EMM_OptimalTimeStep::New ( )
inlinestatic

build a shared pointer associated to the class

References EMM_OptimalTimeStep().

Referenced by EMM_TimeClassFactory::NewInstance().

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◆ out()

static CORE_Out& CORE_Object::out ( )
inlinestaticinherited

get the output

Returns
the output stream

Referenced by EMM_Matter::adimensionize(), EMM_DisplacementFVMOperator::backup(), EMM_DisplacementOperator::backup(), MATH_ElementaryMultiLevelsToeplitzMatrix::buildSpectralVectorProjector(), EMM_Test::caseTest(), EMM_Test::caseTests(), EMM_MatterField::computeAnisotropyDirectionsField(), computeOptimalTimeStep(), MATH_MultiLevelsToeplitzMatrix::copy(), CORE_Exception::CORE_Exception(), EMM_MatterField::createAnisotropyOperator(), CORE_Run::createIO(), EMM_ElementaryTest::defaultBackupTest(), EMM_ElementaryTest::defaultTest(), MATH_MultiLevelsFFTToeplitzMatrix::diagonalize(), EMM_DisplacementFVMOperator::discretize(), EMM_MagnetostrictionOperator::discretize(), EMM_DisplacementFEMOperator::discretize(), EMM_4SymmetricTensors::doubleDot(), EMM_4Tensors::doubleDotCrossDoubleDotScalar(), EMM_TensorsTest::doubleDotCrossDoubleDotScalarTests(), EMM_4Tensors::doubleDotCrossProduct(), EMM_TensorsTest::doubleDotCrossProductTests(), EMM_4Tensors::doubleDotCrossSquaredScalar(), EMM_TensorsTest::doubleDotCrossSquaredScalarTests(), EMM_4Tensors::doubleDotProduct(), EMM_TensorsTest::doubleDotProductTests(), EMM_DisplacementWaveTest::elasticWaveTest(), EMM_Test::elementaryTests(), FFTW_Test::fftwTutorial(), MATH_IntegrationTest::gaussLegendreTest(), EMM_MagnetostrictionTest::HComputingTest(), EMM_DemagnetizedPeriodicalTest::HTest(), EMMH_HysteresisTest::hysteresisDefaultCycleTest(), EMM_TensorsTest::initializationTests(), EMM_MultiScaleGrid::initialize(), EMM_MultiScaleSDGrid::initialize(), EMM_MatterField::loadFromANIFile(), EMM_AnisotropyDirectionsField::loadFromFile(), EMM_Matter::loadFromFile(), EMM_Grid3D::loadFromGEOFile(), EMM_MatterField::loadFromLOCFile(), EMM_Array< tCellFlag >::loadFromStream(), EMM_Matter::loadFromStream(), EMM_Matter::loadMattersFromFile(), EMM_Run::loadSystemFromOptions(), EMM_ElementaryTest::magnetostrictionBackupTest(), CORE_Run::make(), EMMH_Run::makeHysteresis(), EMM_Run::makeRun(), CORE_Run::makeType(), EMM_ElementaryTest::optionsTest(), MATH_PolynomialTest::P4Tests(), EMM_Test::primaryTests(), EMM_LandauLifschitzSystem::printLog(), CORE_Run::printOptions(), EMM_2PackedSymmetricTensors::product(), EMMG_SLDemagnetizedOperator::projectionOnSpectralSpace(), CORE_Run::readOptionsFromCommandLine(), CORE_Test::readVectorTest(), EMM_DemagnetizedPeriodicalTest::relaxationTest(), EMM_DisplacementFVMOperator::restore(), EMM_DisplacementOperator::restore(), EMM_Input::restoreBackup(), EMMH_Hysteresis::run(), EMM_Output::save(), EMM_AnisotropyDirectionsField::saveToFile(), EMM_MatterField::saveToFile(), EMM_Grid3D::saveToGEOFile(), CORE_IOTest::searchTest(), EMMH_Hysteresis::setInitialMagnetizationField(), MATH_MultiLevelsToeplitzMatrix::setLevels(), EMM_4SymmetricTensors::squaredDoubleDot(), EMM_4Tensors::squaredDoubleDotCrossScalar(), EMM_TensorsTest::squaredDoubleDotCrossScalarTests(), EMM_4Tensors::squaredDoubleDotScalar(), EMM_TensorsTest::squaredDoubleDotScalarTests(), EMM_TensorsTest::squaredDoubleDotTests(), EMM_MatterTest::testAdimensionize(), EMM_MatterTest::testANIFile(), CORE_Test::testComplex(), CORE_Test::testDateWeek(), FFTW_Test::testDFT(), EMM_MatterTest::testIO(), EMM_ODETest::testODE(), CORE_Test::testOut(), CORE_Test::testReal(), EMM_FieldTest::testRealArray(), EMM_Grid3DTest::testSegment(), EMM_Grid3DTest::testThinSheet(), CORE_Test::testTime(), CORE_Test::testType(), MATH_FullMatrix::toString(), EMM_DemagnetizedPeriodicalTest::xyPeriodicalCubeSDGTest(), and EMM_DemagnetizedPeriodicalTest::xyPeriodicalSheetSDGTest().

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◆ pointer2String()

tString CORE_Object::pointer2String ( const void *  obj)
staticinherited

return the string representation of a pointer

Parameters
obj: oject to get the string pointer
Returns
the string pointer of the object

References tString.

Referenced by CORE_Object::CORE_Object(), CORE_Object::getIdentityString(), CORE_Object::getPointerAddress(), CORE_Object::is32Architecture(), and CORE_Object::~CORE_Object().

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◆ printObjectsInMemory() [1/2]

void CORE_Object::printObjectsInMemory ( ostream &  f)
staticinherited

print object in memory

Parameters
f: output to print the objects in memory

References CORE_Object::getIdentityString(), CORE_Object::getSharedPointer(), CORE_Object::mIsMemoryTesting, CORE_Object::mObjects, and tInteger.

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◆ printObjectsInMemory() [2/2]

static void CORE_Object::printObjectsInMemory ( )
inlinestaticinherited

print object in memory in the standart output

Referenced by CORE_Object::is32Architecture(), and main().

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◆ resetOut()

static void CORE_Object::resetOut ( )
inlinestaticinherited

reset the output stream

Referenced by run().

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◆ resetSystem()

void EMM_Stepper::resetSystem ( )
inherited

reset the reverse system relation

References EMM_Stepper::mSystem, and null.

Referenced by EMM_Stepper::setSystem().

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◆ resetThread()

static void CORE_Object::resetThread ( )
inlinestaticinherited

reset the output stream

Referenced by run().

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◆ setCharacteristicTime()

void EMM_Stepper::setCharacteristicTime ( const tReal t)
inlineinherited

set the characteristic time the real time will be t. mTc in seconds

Referenced by EMM_LandauLifschitzSystem::adimensionize().

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◆ setDt()

void EMM_Stepper::setDt ( const tReal dt)
inlineinherited

set the time step

Parameters
[in]dt: time step

Referenced by EMMH_Hysteresis::run().

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◆ setDtFactor()

void EMM_Stepper::setDtFactor ( const tReal f)
inlineinherited

set the dt factor

Parameters
[in]fthe multiply factor of dt

◆ setIsMemoryChecked()

static void CORE_Object::setIsMemoryChecked ( const tBoolean v)
inlinestaticinherited

set if the memory checking is used

Parameters
v: true to check memory

Referenced by main().

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◆ setOut()

static void CORE_Object::setOut ( SP::CORE_Out  out)
inlinestaticinherited

set the output stream

Parameters
out: the shared pointer to the new output stream

References null.

◆ setSystem()

tBoolean EMM_Stepper::setSystem ( SP::EMM_LandauLifschitzSystem  system)
inherited

set the reverse system relation

Parameters
system: the system to set
Returns
true if the system is compatible

References CORE_Object::getThis(), EMM_Stepper::isSystemCompatible(), EMM_Stepper::mSystem, null, and EMM_Stepper::resetSystem().

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◆ setTargetTime()

void EMM_Stepper::setTargetTime ( const tReal t)
inlineinherited

set the end time with respect of the characteristic time real time = t * getCharacteristicTime()

Parameters
ttarget time

References EMM_Stepper::mEndTime, and EMM_Stepper::mTimeStepsNumber.

◆ setThis()

void CORE_Object::setThis ( SP::CORE_Object  p)
inlineprotectedinherited

set this weak shared pointer called toDoAfterThis setting method

Parameters
p: shared pointer of the class This

References CORE_Object::toDoAfterThisSetting().

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◆ setThread()

static void CORE_Object::setThread ( SP::CORE_Thread  thread)
inlinestaticinherited

set the thread

Parameters
threadthe shared pointer to the thread

References null.

Referenced by EMM_Run::EMM_Run(), EMM_TensorsRun::EMM_TensorsRun(), and MATH_SolverRun::MATH_SolverRun().

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◆ setTimeStepsNumber()

void EMM_Stepper::setTimeStepsNumber ( const tUInteger n)
inlineinherited

set the time steps number

◆ SP_OBJECT()

EMM_OptimalTimeStep::SP_OBJECT ( EMM_OptimalTimeStep  )
private

◆ toDoAfterThisSetting()

virtual void EMM_Object::toDoAfterThisSetting ( )
inlineprotectedvirtualinherited

method called after the setting of the shared pointer this method can only be called once.

Reimplemented from CORE_Object.

Reimplemented in EMM_DisplacementOperator, EMM_DisplacementFVMOperator, EMM_GaussLegendreRelaxation, and EMM_GradGaussLegendreRelaxation.

Referenced by EMM_GaussLegendreRelaxation::toDoAfterThisSetting(), and EMM_DisplacementOperator::toDoAfterThisSetting().

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◆ toString()

virtual tString EMM_OptimalTimeStep::toString ( ) const
inlinevirtual

turn the regular time into a string

Returns
the string representation of the class

Reimplemented from EMM_Stepper.

References computeOptimalTimeStep(), tBoolean, EMM_Stepper::toString(), and tReal.

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Member Data Documentation

◆ Gamma

const tReal EMM_Object::Gamma =-1.7e11
staticinherited

Referenced by EMM_MatterField::adimensionize(), EMM_Matter::adimensionize(), EMM_Test::createMatters(), and EMM_MatterTest::testAdimensionize().

◆ mGradH_gradF

SP::EMM_RealField EMM_OptimalTimeStep::mGradH_gradF
private

◆ mP4

MATH_P4 EMM_OptimalTimeStep::mP4
mutableprivate

Referenced by computeOptimalTimeStep(), and EMM_OptimalTimeStep().

◆ mT

tReal EMM_OptimalTimeStep::mT[4]
private

Referenced by computeOptimalTimeStep().

◆ Mu0

const tReal EMM_Object::Mu0 =4*M_PI*1e-07
staticinherited

Referenced by EMM_MatterField::adimensionize(), EMM_MagnetostrictionOperator::adimensionize(), EMM_Matter::adimensionize(), EMM_CubicAnisotropyOperator::ComputeMagneticExcitation(), EMM_CubicAnisotropyOperator::computeMagneticExcitationField(), EMM_CubicAnisotropyOperator::computeMagneticExcitationFieldGradient(), EMM_CubicAnisotropyOperator::ComputeMagneticExcitationGradient(), EMM_Test::createMatters(), EMM_MatterField::getElasticTensorAdimensionizedParameter(), and EMM_MatterTest::testAdimensionize().

◆ NULL_VALUE

const tReal EMM_Object::NULL_VALUE ={0,0,0}
staticinherited

Referenced by EMM_DisplacementFVM_VOGGROperator::computeGradAlmostNullUAtCellByOstrogradskiGreenIntegration(), EMM_DisplacementFVM_VTEGROperator::computeGradAlmostNullUAtCellByTaylorExpansionWithNeumannInterpolation(), EMM_DisplacementFVM_SSGROperator::computeGradAlmostNullUAtFaceByStokesIntegration(), EMM_DisplacementFVM_VOGGROperator::computeGradAlmostNullUAtNextCellByOstrogradskiGreenIntegration(), EMM_DisplacementFVM_VTEGROperator::computeGradUAtCellByTaylorExpansionWithNeumannInterpolation(), EMM_DisplacementFVM_VGROperator::computeGradUAtFace(), EMM_DisplacementFVM_SSGROperator::computeGradUAtFaceByStokesIntegration(), EMM_DisplacementFVM_STEGROperator::computeGradUAtFaceByTaylorExpansion(), EMM_DisplacementFVM_Interpolator::interpolateUAtEdge(), and EMM_DisplacementFVM_Interpolator::interpolateUAtVertices().

◆ X

const tDimension EMM_Object::X =0
staticinherited

Referenced by EMMG_RealField::fitToSize(), EMM_MassMatrix::getElementVolume(), EMM_CanonicalMassMatrix::isSymmetric(), EMM_BlockMassMatrix::product(), EMM_CondensedMassMatrix::product(), EMM_RealField::setValue(), EMM_BlockMassMatrix::toString(), and EMMG_RealField::wedge().

◆ Y

const tDimension EMM_Object::Y =1
staticinherited

Referenced by EMMG_SLSDXPeriodicMultiScale::computeMultiGridExcitationField(), EMMG_RealField::fitToSize(), EMM_MassMatrix::getElementVolume(), EMM_CanonicalMassMatrix::isSymmetric(), EMM_BlockMassMatrix::product(), EMM_CondensedMassMatrix::product(), EMM_RealField::setValue(), EMM_CanonicalMassMatrix::solve(), EMM_BlockMassMatrix::solve(), EMM_BlockMassMatrix::toString(), and EMMG_RealField::wedge().

◆ Z

const tDimension EMM_Object::Z =2
staticinherited

Referenced by EMM_DisplacementFVM_VIGROperator::initializeEquilibriumSolver(), and EMM_DisplacementOperator::initializeEquilibriumSolver().

The documentation for this class was generated from the following files:
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