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Fhiclcpp types in detail » History » Version 42

Kyle Knoepfel, 12/16/2015 08:28 AM

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h1. @fhiclcpp@ types in detail
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{{toc}}
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----
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h1(#ctors). Parameter constructors
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h2(#ctors_rules). %{color:blue}General rules%
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For each of the @fhiclcpp@ types, the following rules apply:
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* The @Name@ argument is required.
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* Neither the @Table<T>@ parameter nor any of the @Optional*@ parameters support a default value.
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h3(#opt_comment). Note about optional parameters
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In addition to @Optional*@ parameters not supporting default values, they also cannot be used as template arguments to *any* @fhiclcpp@ types:
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<pre><code class="cpp">
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Sequence< OptionalSequence<int> >     e1 { ... };  // error
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Sequence< OptionalSequence<int,2u> >  e2 { ... };  // error
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Sequence< OptionalTuple<int,double> > e3 { ... };  // error
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OptionalSequence< Sequence<int> >     ok { ... };  // ok
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</code></pre>
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h2(#atom). %{color:blue}@Atom<T>@%
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<pre><code class="cpp">
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Atom<int> var { Name("var") };
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Atom<int> var { Name("var"), 9 };
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Atom<int> var { Name("var"), Comment("A parameter description") };
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Atom<int> var { Name("var"), Comment("A parameter description"), 9 };
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</code></pre>
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h2(#opt_atom). %{color:blue}@OptionalAtom<T>@%
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<pre><code class="cpp">
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OptionalAtom<int> var { Name("var") };
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OptionalAtom<int> var { Name("var"), Comment("A parameter description") };
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</code></pre>
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h2(#opt_vector). %{color:blue}@OptionalSequence<T>@%
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This class template is used for unbounded sequences.
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<pre><code class="cpp">
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OptionalSequence<int> seq { Name("seq") };
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OptionalSequence<int> seq { Name("seq"), Comment("A sequence") };
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</code></pre>
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h2(#opt_array). %{color:blue}@OptionalSequence<T,std::size_t>@%
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This class template is used for sequences of a specific length, known at compile time.
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<pre><code class="cpp">
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OptionalSequence<int,3u> seq { Name("seq") };
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OptionalSequence<int,3u> seq { Name("seq"), Comment("A sequence") };
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</code></pre>
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h2(#opt_table). %{color:blue}@OptionalTable<T>@%
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<pre><code class="cpp">
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OptionalTable<T> config { Name("config") };
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OptionalTable<T> config { Name("config"), Comment("This describes the table") };
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</code></pre>
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h2(#opt_tuple). %{color:blue}@OptionalTuple<T...>@%
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<pre><code class="cpp">
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OptionalTuple<string,bool> tuple { Name("tuple") };
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OptionalTuple<string,bool> tuple { Name("tuple"), Comment("A tuple") };
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</code></pre>
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h2(#vector). %{color:blue}@Sequence<T>@%
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This class template is used for unbounded sequences.  See the two caveats below.
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<pre><code class="cpp">
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Sequence<int> seq { Name("seq") };
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Sequence<int> seq { Name("seq"), Comment("A sequence") };
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Sequence<int> seq { Name("seq"), std::vector<int>{ 4, 5, 6, 7 } };
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Sequence<int> seq { Name("seq"), { 4, 5, 6, 7 } };
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Sequence<int> seq { Name("seq"), Comment("A sequence"), std::vector<int>{ 4, 5, 6, 7 } };
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Sequence<int> seq { Name("seq"), Comment("A sequence"), { 4, 5, 6, 7 } };
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</code></pre>
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h3(#narrowing). Precaution regarding narrowing conversions and @std::initializer_list@ objects
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The following configuration will trigger a compilation warning:
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<pre><code class="cpp">
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Sequence<int> seq1 { Name("seq1"), std::vector<int>{ 1, 2.4e-4 } };
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Sequence<int> seq2 { Name("seq2"), { 1, 2.4e-4 } };
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</code></pre>
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that looks similar to this:
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<pre>
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warning: narrowing conversion of ‘2.4000000000000001e-4’ from ‘double’ to ‘int’ inside { } [-Wnarrowing]
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</pre>
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For build systems that convert compile-time warnings to errors, this will result in a build failure.  The warning results from the nature of an @std::initializer_list@ object (also referred to as a brace-enclosed initializer), signified by @'{1, 2.4e-4}'@, which is used to initialize the sequence objects.  For @std::initializer_list@ objects, narrowing conversions are not allowed--that is, converting a @double@ to an @int@ is an example of narrowing that results in loss of information.  This is the most likely example of where you may find a narrowing conversion.
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h2(#array). %{color:blue}@Sequence<T,std::size_t>@%
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This class template is used for sequences of a specific length, known at compile time.
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<pre><code class="cpp">
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Sequence<int,3u> seq { Name("seq") };
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Sequence<int,3u> seq { Name("seq"), Comment("A sequence") };
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Sequence<int,3u> seq { Name("seq"), Sequence<int,3u>{ 4, 5, 6 } };
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Sequence<int,3u> seq { Name("seq"), { 4, 5, 6 } };
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Sequence<int,3u> seq { Name("seq"), Comment("A sequence"), Sequence<int,3u>{ 4, 5, 6 } };
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Sequence<int,3u> seq { Name("seq"), Comment("A sequence"), { 4, 5, 6 } };
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</code></pre>
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The warning regarding narrowing conversions [[Fhiclcpp_types_in_detail#narrowing|above]] applies for bounded sequences as well.
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h2(#table). %{color:blue}@Table<T>@%
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<pre><code class="cpp">
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Table<T> config { Name("config") };
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Table<T> config { Name("config"), Comment("This describes the table") };
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</code></pre>
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h2(#tuple). %{color:blue}@Tuple<T...>@%
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<pre><code class="cpp">
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Tuple<string,bool> tuple { Name("tuple") };
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Tuple<string,bool> tuple { Name("tuple"), Comment("A tuple") };
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Tuple<string,bool> tuple { Name("tuple"), Tuple<string,bool>{"explicit?", true} };
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Tuple<string,bool> tuple { Name("tuple"), {"compact?", true } };
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Tuple<string,bool> tuple { Name("tuple"), Comment("A tuple"), Tuple<string,bool>{ "Particle physics is neat.", true } };
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Tuple<string,bool> tuple { Name("tuple"), Comment("A tuple"), { "This is false", false } };
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</code></pre>
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----
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h1(#return). Standard parameters - return types
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_[ In what follows, @array@, @string@, @tuple@, and @vector@ should each be prefaced with the appropriate namespace resolution: '@std::@'. ]_
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|{background:#fba}. *@fhiclcpp@ parameter*|{background:#fba}. *Function call*|{background:#fba}. *Return type*|
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|\3{background:#ddd}. _Simple @fhiclcpp@ parameters_|
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|@Atom<string> label@; |@label()@| @string const&@|
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|/2.@Sequence<int> counts@; | @counts()@ | @vector<int>@|
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|@counts(1)@ | @int@ |
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|/2.@Sequence<double, 3u> point@;| @point()@ | @array<double, 3u>@|
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|@point(0)@ | @double@ |
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|/3.@Tuple<string, double> assoc;@|@assoc()@| @tuple<string, double>@|
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|@assoc.get<0>()@|@string@|
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|@assoc.get<double>()@|@double@|
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|@Table<Config> config;@|@config()@|@Config const&@|
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|\3{background:#ddd}. _Nested @fhiclcpp@ parameters_|
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|/2.@Sequence< Sequence<int> > datasets;@ | @datasets()@ | @vector< vector<int> >@ |
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| @datasets(17)@ | @vector<int>@ |
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|/2.@Sequence< Sequence<int>, 2u > twoDatasets;@ | @twoDatasets()@ | @array< vector<int>, 2u >@ |
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|@twoDatasets(1)@ | @vector<int>@ |
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|/2.@Sequence< Sequence<int, 2u> > intPairs;@ | @intPairs()@ | @vector< array<int, 2u> >@ |
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|@intPairs(42)@ | @array<int, 2u>@|
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|/2.@Sequence< Tuple<string, int, bool> > triplets;@ | @triplets()@ | @vector< tuple<string, int, bool> >@ |
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|@triplets(3)@ | @tuple<string, int, bool>@ |
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|/2.@Sequence< Table<Config> > manyConfigTables;@ | @manyConfigTables()@ | @vector< Config >@ |
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|@manyConfigTables(6)@ | @Config const&@ |
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|/3.@Tuple< string, Table<Config> > configAssoc;@ | @configAssoc()@ | @tuple< string, Config >@ |
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|@configAssoc.get<0>()@ | @string@ |
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|@configAssoc.get<1>()@ | @Config@ |
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|/3.@Tuple< Tuple<string,bool>, Sequence<int> > awkward;@ | @awkward()@ | @tuple< tuple<string, bool>, vector<int> >@ |
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|@awkward.get<0>()@|@tuple<string,bool>@|
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|@awkward.get<1>()@|@vector<int>@|
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h1(#opt_arg). @Optional@ parameters - argument types
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The usage pattern for @Optional@ @fhiclcpp@ parameters is:
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<pre><code class="cpp">
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OptionalAtom<string> message { Name("message") };
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string filled_msg; // passed argument
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if ( message(filled_msg) ) {
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   // use 'filled_msg'
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}
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</code></pre>
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The following table gives the required passed-argument types for a given @Optional@ parameter.
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_[ In what follows, @array@, @string@, @tuple@, and @vector@ should each be prefaced with the appropriate namespace resolution: '@std::@'. ]_
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|{background:#fba}. *@fhiclcpp@ parameter*|{background:#fba}. *Passed argument*|{background:#fba}. *Function call*|
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|\3{background:#ddd}. _Simple @fhiclcpp@ parameters_|
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|@OptionalAtom<string> label@; |@string l;@| @bool exists = label(l);@|
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|@OptionalSequence<int> counts@; | @vector<int> v;@|@bool exists = counts(v);@ |
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|@OptionalSequence<double, 3u> point@;| @array<double, 3u> p;@| @bool exists = point(p);@ |
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|@OptionalTuple<string, double> assoc;@|@tuple<string, double> t;@| @bool exists = assoc(t);@|
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|@OptionalTable<Config> config;@|@Config c;@|@bool exists = config(c);@|
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|\3{background:#ddd}. _Nested @fhiclcpp@ parameters_|
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|@OptionalSequence< Sequence<int> > datasets;@ |  @vector< vector<int> > sets;@ |@bool exists = datasets(sets);@ |
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|@OptionalSequence< Sequence<int>, 2u > twoDatasets;@ |  @array< vector<int>, 2u >@ sets; |@bool exists = twoDatasets(sets);@ |
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|@OptionalSequence< Sequence<int, 2u> > intPairs;@ | @vector< array<int, 2u> >@ prs; |@bool exists = intPairs(prs);@ |
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|@OptionalSequence< Tuple<string, int, bool> > triplets;@ |  @vector< tuple<string, int, bool> > trps;@ |@bool exists = triplets(trps);@ |
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|@OptionalSequence< Table<Config> > manyConfigTables;@ | @vector< Config > tbls;@ |@bool exists = manyConfigTables(tbls);@ |
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|@OptionalTuple< string, Table<Config> > configAssoc;@ | @tuple< string, Config > assoc;@ |@bool exists = configAssoc(assoc);@ |
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|@OptionalTuple< Tuple<string,bool>, Sequence<int> > awkward;@ | @tuple< tuple<string, bool>, vector<int> > wow;@ |@bool exists = awkward(wow);@ |
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----
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h1(#table_func). Additional functions for @Table<T>@
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The @Table@ template offers a few extra functions that the user can call: 
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<pre><code class="cpp">
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fhicl::ParameterSet const& get_PSet() const;
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void print_allowed_configuration(std::ostream& os,
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                                 std::string const& tab = std::string(3,' ') ) const;
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// Expert-level functions
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void validate_ParameterSet(fhicl::ParameterSet const& pset,
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                           std::set<std::string> const& keysToIgnore = {} );
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</code></pre>
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h3(#get_pset). @get_PSet@
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A call to this function returns a @const@ reference to the @ParameterSet@ object that was used to fill the values of the individual @Table@ members.  This is helpful for users who need to interact with the @ParameterSet@ object itself.
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h3(#print). @print_allowed_configuration@
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For any @Table<Config>@ object, @print_allowed_configuration@ will fill a user-supplied @std::ostream@ object with the allowed configuration as defined by the @Config@ struct.  The optional second argument specifies the number of spaces per indentation.  The default is 3 spaces but is, of course, user-configurable.
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----
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%{color:red} _[ *N.B.* The following function should not normally be invoked by users. It is meant to be called only in contexts outside of @art@.  Please consult artists@fnal.gov for guidance.]_%
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h3(#validate). @validate_ParameterSet@ (expert)
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This function is intended for experts who need to validate the @pset@ object themselves.  The @keysToIgnore@ variable represents a set of keys for which the validation step will ignore.  The validation function will ignore any nested keys as well--i.e. if a user specifies an ignorable key as @table1@, the (e.g.) @table1.someAtom@ key would be ignored in addition to just the @table1@ name.  An indexed parameter (e.g.) @seq[1]@ is considered a nested parameter of its parent @seq@.  Providing or not providing the ignorable key in a configuration will lead to no error upon validation of the @ParameterSet@.
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Should the validation step fail, an exception is thrown of type @fhicl::detail::validationException@.  This behavior is not currently configurable.
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----
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h1(#common_acc). Common parameter accessors
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Each of the @fhiclcpp@ types has the following accessors:
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<pre><code class="cpp">
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std::string key()            const;
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std::string name()           const;
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std::string comment()        const;
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bool        has_default()    const;
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bool        is_optional()    const;
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par_type    parameter_type() const;
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</code></pre>
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To call these functions, the difference in syntax is crucial:
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<pre><code class="cpp">
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Atom<int> val { Name("val") };
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auto key1 = val.key();   //   correct
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auto key2 = val().key(); // ! compile-time ERROR - 'val()' is an int, which has no accessor called 'key()' 
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</code></pre>
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h2. @key()@
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A call to @key()@ returns the _full_ key, including all enclosing tables.  For example, consider a module that is designed to allow the following configuration:
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<pre><code class="ruby">
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pset: {
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  list: [ { particle: electron },
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          { particle: muon } ]
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}
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</code></pre>For a suitably declared set of @fhiclcpp@ parameters, the returned key corresponding to "muon" would be @pset.list[1].particle@.
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h2. @name()@
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The name is the most-nested name in the key.  For the above "muon" parameter, a key of @pset.list[1].particle@ has a corresponding name of @particle@.  If the parameter in question were @pset.list[1]@, the name would be[1] @list[1]@.
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fn1. Technically, this is inaccurate -- sequence elements do not have names.  However, for the sake of parameter identification, a sequence element has a name whose value is the sequence name with the appropriate sequence element index/indices appended.
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h2. @comment()@
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Returns the comment supplied as the string literal in (e.g.) @Comment("Here is the comment")@.  If no @Comment@ argument is provided in the @fhiclcpp@ parameter constructor, a call to this function returns an empty string.
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h2. @has_default()@
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Returns @true@ or @false@ depending on whether the user supplied a default value for the parameter.
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h2. @is_optional()@
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Returns @true@ or @false@ depending on whether the parameter is of an @Optional*@ @fhiclcpp@ type.
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h2. @parameter_type()@
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Returns an enumeration value based on the parameter type:
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<pre><code class="cpp">
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enum class par_type {
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  ATOM,        // (Optional)Atom<T>
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  TABLE,       // (Optional)Table<T>
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  SEQ_VECTOR,  // (Optional)Sequence<T>
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  SEQ_ARRAY,   // (Optional)Sequence<T,std::size_t>
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  TUPLE,       // (Optional)Tuple<T...>
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  NTYPES       // Signifies invalid parameter 
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};
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</code></pre>