\(\newcommand{\W}[1]{ \; #1 \; }\) \(\newcommand{\R}[1]{ {\rm #1} }\) \(\newcommand{\B}[1]{ {\bf #1} }\) \(\newcommand{\D}[2]{ \frac{\partial #1}{\partial #2} }\) \(\newcommand{\DD}[3]{ \frac{\partial^2 #1}{\partial #2 \partial #3} }\) \(\newcommand{\Dpow}[2]{ \frac{\partial^{#1}}{\partial {#2}^{#1}} }\) \(\newcommand{\dpow}[2]{ \frac{ {\rm d}^{#1}}{{\rm d}\, {#2}^{#1}} }\)

ADFun

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ADFun Objects

Purpose

An AD of Base operation sequence is stored in an ADFun object by its fun_construct . The ADFun object can then be used to calculate function values, derivative values, and other values related to the corresponding function.

Contents

Name	Title
record_adfun	Create an ADFun Object by Recording an Operation Sequence
other_adfun	Other Ways to Create an ADFun Object
drivers	First and Second Order Derivatives: Easy Drivers
Forward	Forward Mode
Reverse	Reverse Mode
sparsity_pattern	Calculating Sparsity Patterns
sparse_derivative	Calculating Sparse Derivatives
optimize	Optimize an ADFun Object Tape
FunCheck	Check an ADFun Sequence of Operations
check_for_nan	Check an ADFun Object For Nan Results
to_csrc	C Source Code Corresponding to an ADFun Object