MemoizeFunction

class MemoizeFunction(*args)

Function which keeps tracks of input and output.

When this function is evaluated, it calls the Function passed as argument, and store input and output Sample. It also has a caching behavior, enabled by default.

Parameters:
functionFunction

Delegate function

historyStrategyHistoryStrategy (optional)

Strategy used to store points, default is Full.

Methods

addCacheContent(inSample, outSample)

Add input numerical points and associated output to the cache.

clearCache()

Empty the content of the cache.

clearHistory()

Clear input and output history.

disableCache()

Disable the cache mechanism.

disableHistory()

Disable the history mechanism.

draw(*args)

Draw the output of function as a Graph.

drawCrossCuts(*args)

Draw the 2D and 1D cross cuts of a 1D output function as a GridLayout.

enableCache()

Enable the cache mechanism.

enableHistory()

Enable the history mechanism.

getCacheHits()

Accessor to the number of computations saved thanks to the cache mechanism.

getCacheInput()

Accessor to all the input numerical points stored in the cache mechanism.

getCacheOutput()

Accessor to all the output numerical points stored in the cache mechanism.

getCallsNumber()

Accessor to the number of direct calls to the function.

getClassName()

Accessor to the object's name.

getDescription()

Accessor to the description of the inputs and outputs.

getEvaluation()

Accessor to the evaluation function.

getEvaluationCallsNumber()

Accessor to the number of times the evaluation of the function has been called.

getGradient()

Accessor to the gradient function.

getGradientCallsNumber()

Accessor to the number of times the gradient of the function has been called.

getHessian()

Accessor to the hessian function.

getHessianCallsNumber()

Accessor to the number of times the hessian of the function has been called.

getInputDescription()

Accessor to the description of the input vector.

getInputDimension()

Accessor to the dimension of the input vector.

getInputHistory()

Get the input sample.

getMarginal(*args)

Accessor to marginal.

getName()

Accessor to the object's name.

getOutputDescription()

Accessor to the description of the output vector.

getOutputDimension()

Accessor to the number of the outputs.

getOutputHistory()

Get the output sample.

getParameter()

Accessor to the parameter values.

getParameterDescription()

Accessor to the parameter description.

getParameterDimension()

Accessor to the dimension of the parameter.

gradient(inP)

Return the Jacobian transposed matrix of the function at a point.

hasName()

Test if the object is named.

hessian(inP)

Return the hessian of the function at a point.

isCacheEnabled()

Test whether the cache mechanism is enabled or not.

isHistoryEnabled()

Test whether the history mechanism is enabled or not.

isLinear()

Accessor to the linearity of the function.

isLinearlyDependent(index)

Accessor to the linearity of the function with regard to a specific variable.

parameterGradient(inP)

Accessor to the gradient against the parameter.

setDescription(description)

Accessor to the description of the inputs and outputs.

setEvaluation(evaluation)

Accessor to the evaluation function.

setGradient(gradient)

Accessor to the gradient function.

setHessian(hessian)

Accessor to the hessian function.

setInputDescription(inputDescription)

Accessor to the description of the input vector.

setName(name)

Accessor to the object's name.

setOutputDescription(outputDescription)

Accessor to the description of the output vector.

setParameter(parameter)

Accessor to the parameter values.

setParameterDescription(description)

Accessor to the parameter description.

setStopCallback(callBack[, state])

Set up a stop callback.

Notes

When the function passed as argument is a MemoizeFunction, its input and output history are copied into current instance. This allows one to retrieve this history from a Function object which is in fact a MemoizeFunction. Thus, if you create a MemoizeFunction from an unknown Function, it is better to call clearHistory(). The cache size is initialized by the value of the ResourceMap Cache-MaxSize entry.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction('x', 'x^2')
>>> inputSample = ot.Sample([[1], [2], [3], [4]])
>>> f = ot.MemoizeFunction(f)
>>> outputSample = f(inputSample)

Retrieve input sample:

>>> print(f.getInputHistory())
0 : [ 1 ]
1 : [ 2 ]
2 : [ 3 ]
3 : [ 4 ]

Retrieve output sample:

>>> print(f.getOutputHistory())
0 : [  1 ]
1 : [  4 ]
2 : [  9 ]
3 : [ 16 ]
__init__(*args)
addCacheContent(inSample, outSample)

Add input numerical points and associated output to the cache.

Parameters:
input_sample2-d sequence of float

Input numerical points to be added to the cache.

output_sample2-d sequence of float

Output numerical points associated with the input_sample to be added to the cache.

clearCache()

Empty the content of the cache.

clearHistory()

Clear input and output history.

disableCache()

Disable the cache mechanism.

disableHistory()

Disable the history mechanism.

draw(*args)

Draw the output of function as a Graph.

Available usages:

draw(inputMarg, outputMarg, centralPoint, xiMin, xiMax, ptNb, scale)

draw(firstInputMarg, secondInputMarg, outputMarg, centralPoint, xiMin_xjMin, xiMax_xjMax, ptNbs, scale, isFilled)

draw(xiMin, xiMax, ptNb, scale)

draw(xiMin_xjMin, xiMax_xjMax, ptNbs, scale)

Parameters:
outputMarg, inputMargint, outputMarg, inputMarg \geq 0

outputMarg is the index of the marginal to draw as a function of the marginal with index inputMarg.

firstInputMarg, secondInputMargint, firstInputMarg, secondInputMarg \geq 0

In the 2D case, the marginal outputMarg is drawn as a function of the two marginals with indexes firstInputMarg and secondInputMarg.

centralPointsequence of float

Central point with dimension equal to the input dimension of the function.

xiMin, xiMaxfloat

Define the interval where the curve is plotted.

xiMin_xjMin, xiMax_xjMaxsequence of float of dimension 2.

In the 2D case, define the intervals where the curves are plotted.

ptNbint ptNb > 0

The number of points to draw the curves.

ptNbslist of int of dimension 2 ptNbs_k > 0, k=1,2

The number of points to draw the contour in the 2D case.

scalebool

scale indicates whether the logarithmic scale is used either for one or both axes:

  • ot.GraphImplementation.NONE or 0: no log scale is used,

  • ot.GraphImplementation.LOGX or 1: log scale is used only for horizontal data,

  • ot.GraphImplementation.LOGY or 2: log scale is used only for vertical data,

  • ot.GraphImplementation.LOGXY or 3: log scale is used for both data.

isFilledbool

isFilled indicates whether the contour graph is filled or not

Notes

We note f: \Rset^n \rightarrow \Rset^p where \vect{x} = (x_1, \dots, x_n) and f(\vect{x}) = (f_1(\vect{x}), \dots, f_p(\vect{x})), with n\geq 1 and p\geq 1.

  • In the first usage:

Draws graph of the given 1D outputMarg marginal f_k: \Rset^n \rightarrow \Rset as a function of the given 1D inputMarg marginal with respect to the variation of x_i in the interval [x_i^{min}, x_i^{max}], when all the other components of \vect{x} are fixed to the corresponding components of the centralPoint \vect{c}. Then OpenTURNS draws the graph:

y = f_k^{(i)}(s)

for any s \in [x_i^{min}, x_i^{max}] where f_k^{(i)}(s) is defined by the equation:

f_k^{(i)}(s) = f_k(c_1, \dots, c_{i-1}, s,  c_{i+1} \dots, c_n).

  • In the second usage:

Draws the iso-curves of the given outputMarg marginal f_k as a function of the given 2D firstInputMarg and secondInputMarg marginals with respect to the variation of (x_i, x_j) in the interval [x_i^{min}, x_i^{max}] \times [x_j^{min}, x_j^{max}], when all the other components of \vect{x} are fixed to the corresponding components of the centralPoint \vect{c}. Then OpenTURNS draws the graph:

y = f_k^{(i,j)}(s, t)

for any (s, t) \in [x_i^{min}, x_i^{max}] \times [x_j^{min}, x_j^{max}] where f_k^{(i,j)} is defined by the equation:

f_k^{(i,j)}(s,t) = f_k(c_1, \dots, c_{i-1}, s, c_{i+1}, \dots, c_{j-1}, t,  c_{j+1} \dots, c_n).

  • In the third usage:

The same as the first usage but only for function f: \Rset \rightarrow \Rset.

  • In the fourth usage:

The same as the second usage but only for function f: \Rset^2 \rightarrow \Rset.

Examples

>>> import openturns as ot
>>> from openturns.viewer import View
>>> f = ot.SymbolicFunction('x', 'sin(2*pi_*x)*exp(-x^2/2)')
>>> graph = f.draw(-1.2, 1.2, 100)
>>> View(graph).show()
drawCrossCuts(*args)

Draw the 2D and 1D cross cuts of a 1D output function as a GridLayout.

Parameters:
centralPointlist of float

Central point with dimension equal to the input dimension of the function.

xMin, xMaxlist of float

Define the interval where the curve is plotted.

pointNumberIndices

The number of points to draw the contours and the curves.

withMonoDimensionalCutsbool, optional

withMonoDimensionalCuts indicates whether the mono dimension cuts are drawn or not Default value is specified in the CrossCuts-DefaultWithMonoDimensionalCuts ResourceMap key.

isFilledbool, optional

isFilled indicates whether the contour graphs are filled or not Default value is specified in the Contour-DefaultIsFilled ResourceMap key

vMin, vMaxfloat, optional

Define the interval used to build the color map for the contours If not specified, these values are computed to best fit the graphs. Either specify both values or do not specify any.

Notes

We note f: \Rset^n \rightarrow \Rset^p where \vect{x} = (x_1, \dots, x_n) and f(\vect{x}) = (f_1(\vect{x}), \dots, f_p(\vect{x})), with n\geq 1 and p\geq 1.

In all usages, draw the 1D and 2D cross cuts of f_k: \Rset^n \rightarrow \Rset as a function of all input coordinates for 1D cuts and all couples of coordinates for 2D cuts. Variable coordinates x_i are sampled regularly using ptNb[i] points in the interval [x_i^{min}, x_i^{max}], when all the other components of \vect{x} are fixed to the corresponding components of the centralPoint \vect{c}. In the first usage, vMin and vMax are evaluated as the min and max of all samples of the function value calculated in all cross cuts performed.

For 1D cross cuts the graph shows:

y = f_k^{(i)}(s)

for any s \in [x_i^{min}, x_i^{max}] where f_k^{(i)}(s) is defined by the equation:

f_k^{(i)}(s) = f_k(c_1, \dots, c_{i-1}, s,  c_{i+1} \dots, c_n).

  • For 2D cross cuts:

y = f_k^{(i,j)}(s, t)

for any (s, t) \in [x_i^{min}, x_i^{max}] \times [x_j^{min}, x_j^{max}] where f_k^{(i,j)} is defined by the equation:

f_k^{(i,j)}(s,t) = f_k(c_1, \dots, c_{i-1}, s, c_{i+1}, \dots, c_{j-1}, t,  c_{j+1} \dots, c_n).

Examples

>>> import openturns as ot
>>> from openturns.viewer import View
>>> f = ot.SymbolicFunction(['x0', 'x1', 'x2'], ['sin(1*pi_*x0) + x1 - x2 ^ 2'])
>>> grid = f.drawCrossCuts([0., 0., 0.], [-3., -3, -3], [3, 3, 3], [100, 20, 20], True, True)
>>> View(grid).show()
enableCache()

Enable the cache mechanism.

enableHistory()

Enable the history mechanism.

getCacheHits()

Accessor to the number of computations saved thanks to the cache mechanism.

Returns:
cacheHitsint

Integer that counts the number of computations saved thanks to the cache mechanism.

getCacheInput()

Accessor to all the input numerical points stored in the cache mechanism.

Returns:
cacheInputSample

All the input numerical points stored in the cache mechanism.

getCacheOutput()

Accessor to all the output numerical points stored in the cache mechanism.

Returns:
cacheInputSample

All the output numerical points stored in the cache mechanism.

getCallsNumber()

Accessor to the number of direct calls to the function.

Returns:
calls_numberint

Integer that counts the number of times the function has been called directly through the () operator.

getClassName()

Accessor to the object’s name.

Returns:
class_namestr

The object class name (object.__class__.__name__).

getDescription()

Accessor to the description of the inputs and outputs.

Returns:
descriptionDescription

Description of the inputs and the outputs.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                         ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getDescription())
[x1,x2,y0]
getEvaluation()

Accessor to the evaluation function.

Returns:
functionEvaluationImplementation

The evaluation function.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                         ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getEvaluation())
[x1,x2]->[2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6]
getEvaluationCallsNumber()

Accessor to the number of times the evaluation of the function has been called.

Returns:
evaluation_calls_numberint

Integer that counts the number of times the evaluation of the function has been called since its creation. This may include indirect calls via finite-difference gradient or Hessian.

getGradient()

Accessor to the gradient function.

Returns:
gradientGradientImplementation

The gradient function.

getGradientCallsNumber()

Accessor to the number of times the gradient of the function has been called.

Returns:
gradient_calls_numberint

Integer that counts the number of times the gradient of the Function has been called since its creation. Note that if the gradient is implemented by a finite difference method, the gradient calls number is equal to 0 and the different calls are counted in the evaluation calls number.

getHessian()

Accessor to the hessian function.

Returns:
hessianHessianImplementation

The hessian function.

getHessianCallsNumber()

Accessor to the number of times the hessian of the function has been called.

Returns:
hessian_calls_numberint

Integer that counts the number of times the hessian of the Function has been called since its creation. Note that if the hessian is implemented by a finite difference method, the hessian calls number is equal to 0 and the different calls are counted in the evaluation calls number.

getInputDescription()

Accessor to the description of the input vector.

Returns:
descriptionDescription

Description of the input vector.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                          ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getInputDescription())
[x1,x2]
getInputDimension()

Accessor to the dimension of the input vector.

Returns:
inputDimint

Dimension of the input vector d.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                          ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getInputDimension())
2
getInputHistory()

Get the input sample.

Returns:
inputSampleSample

Input points which have been evaluated.

getMarginal(*args)

Accessor to marginal.

Parameters:
indicesint or list of ints

Set of indices for which the marginal is extracted.

Returns:
marginalFunction

Function corresponding to either f_i or (f_i)_{i \in indices}, with f:\Rset^n \rightarrow \Rset^p and f=(f_0 , \dots, f_{p-1}).

getName()

Accessor to the object’s name.

Returns:
namestr

The name of the object.

getOutputDescription()

Accessor to the description of the output vector.

Returns:
descriptionDescription

Description of the output vector.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                          ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getOutputDescription())
[y0]
getOutputDimension()

Accessor to the number of the outputs.

Returns:
number_outputsint

Dimension of the output vector d'.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                          ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getOutputDimension())
1
getOutputHistory()

Get the output sample.

Returns:
outputSampleSample

Output points which have been evaluated.

getParameter()

Accessor to the parameter values.

Returns:
parameterPoint

The parameter values.

getParameterDescription()

Accessor to the parameter description.

Returns:
parameterDescription

The parameter description.

getParameterDimension()

Accessor to the dimension of the parameter.

Returns:
parameterDimensionint

Dimension of the parameter.

gradient(inP)

Return the Jacobian transposed matrix of the function at a point.

Parameters:
pointsequence of float

Point where the Jacobian transposed matrix is calculated.

Returns:
gradientMatrix

The Jacobian transposed matrix of the function at point.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6','x1 + x2'])
>>> print(f.gradient([3.14, 4]))
[[ 13.5345   1       ]
 [  4.00001  1       ]]
hasName()

Test if the object is named.

Returns:
hasNamebool

True if the name is not empty.

hessian(inP)

Return the hessian of the function at a point.

Parameters:
pointsequence of float

Point where the hessian of the function is calculated.

Returns:
hessianSymmetricTensor

Hessian of the function at point.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6','x1 + x2'])
>>> print(f.hessian([3.14, 4]))
sheet #0
[[ 20          -0.00637061 ]
 [ -0.00637061  0          ]]
sheet #1
[[  0           0          ]
 [  0           0          ]]
isCacheEnabled()

Test whether the cache mechanism is enabled or not.

Returns:
isCacheEnabledbool

Flag telling whether the cache mechanism is enabled. It is enabled by default.

isHistoryEnabled()

Test whether the history mechanism is enabled or not.

Returns:
isHistoryEnabledbool

Flag telling whether the history mechanism is enabled.

isLinear()

Accessor to the linearity of the function.

Returns:
linearbool

True if the function is linear, False otherwise.

isLinearlyDependent(index)

Accessor to the linearity of the function with regard to a specific variable.

Parameters:
indexint

The index of the variable with regard to which linearity is evaluated.

Returns:
linearbool

True if the function is linearly dependent on the specified variable, False otherwise.

parameterGradient(inP)

Accessor to the gradient against the parameter.

Returns:
gradientMatrix

The gradient.

setDescription(description)

Accessor to the description of the inputs and outputs.

Parameters:
descriptionsequence of str

Description of the inputs and the outputs.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                          ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getDescription())
[x1,x2,y0]
>>> f.setDescription(['a','b','y'])
>>> print(f.getDescription())
[a,b,y]
setEvaluation(evaluation)

Accessor to the evaluation function.

Parameters:
functionEvaluationImplementation

The evaluation function.

setGradient(gradient)

Accessor to the gradient function.

Parameters:
gradient_functionGradientImplementation

The gradient function.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                          ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> f.setGradient(ot.CenteredFiniteDifferenceGradient(
...  ot.ResourceMap.GetAsScalar('CenteredFiniteDifferenceGradient-DefaultEpsilon'),
...  f.getEvaluation()))
setHessian(hessian)

Accessor to the hessian function.

Parameters:
hessian_functionHessianImplementation

The hessian function.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                         ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> f.setHessian(ot.CenteredFiniteDifferenceHessian(
...  ot.ResourceMap.GetAsScalar('CenteredFiniteDifferenceHessian-DefaultEpsilon'),
...  f.getEvaluation()))
setInputDescription(inputDescription)

Accessor to the description of the input vector.

Parameters:
descriptionDescription

Description of the input vector.

setName(name)

Accessor to the object’s name.

Parameters:
namestr

The name of the object.

setOutputDescription(outputDescription)

Accessor to the description of the output vector.

Parameters:
descriptionDescription

Description of the output vector.

setParameter(parameter)

Accessor to the parameter values.

Parameters:
parametersequence of float

The parameter values.

setParameterDescription(description)

Accessor to the parameter description.

Parameters:
parameterDescription

The parameter description.

setStopCallback(callBack, state=None)

Set up a stop callback.

Can be used to programmatically stop an evaluation.

Parameters:
callbackcallable

Returns a bool deciding whether to stop or continue.

Examples using the class

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