[18ebc28] | 1 | \chapter{Introduction} |
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| 2 | |
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[433e2c3] | 3 | All basic types in a programming language have a set of constants (symbols), and these constants represent computable values, \eg integer types have constants @-1@, @17@, @0xff@ representing whole numbers, floating-point types have constants @5.3@, @2.3E-5@, @0xff.ffp0@ representing real numbers, character types have constants @'a'@, @"abc\n"@, \mbox{\lstinline{u8"}\texttt{\guillemotleft{na\"{i}ve}\guillemotright}\lstinline{"}} representing (human readable) text, \etc. |
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[ccfbfd9] | 4 | Constants can be overloaded among types, \eg @0@ is a null pointer for all pointer types, and the value zero for integer and floating-point types. |
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| 5 | (In \CFA, the constants @0@ and @1@ can be overloaded for any type.) |
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[433e2c3] | 6 | Higher-level types compose constants from the basic constants. |
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| 7 | \begin{cfa} |
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| 8 | struct S { int i, j, k; } s; |
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| 9 | s = (S){ 1, 2, 3 }; $\C[2in]{// structure constant}$ |
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| 10 | int x[5] = { 1, 2, 3, 4, 5 }; $\C{// array constant}\CRT$ |
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| 11 | \end{cfa} |
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[46651fb] | 12 | A constant's symbolic name is dictated by language syntax related to types, \eg @5.@ (double), @5.0f@ (float), @5l@ (long double). |
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[433e2c3] | 13 | In general, the representation of a constant's value is \newterm{opaque}, so the internal representation can be chosen arbitrarily, \eg two's complement, IEEE floating-point. |
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[ccfbfd9] | 14 | In theory, there are an infinite set of constant names per type representing an infinite set of values. |
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| 15 | |
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[4c8f29ff] | 16 | It is common in mathematics, engineering, and computer science to alias new constants to existing constants so they have the same value, \eg $\pi$, $\tau$ (2$\pi$), $\phi$ (golden ratio), K(k), M, G, T for powers of 2\footnote{Overloaded with SI powers of 10.} often prefixing bits (b) or bytes (B), \eg Gb, MB, and in general situations, \eg specific times (noon, New Years), cities (Big Apple), flowers (Lily), \etc. |
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[ccfbfd9] | 17 | An alias can bind to another alias, which transitively binds it to the specified constant. |
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| 18 | Multiple aliases can represent the same value, \eg eighth note and quaver, giving synonyms. |
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| 19 | |
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| 20 | Many programming languages capture this important software-engineering capability through a mechanism called \newterm{constant} or \newterm{literal} naming, where a new constant is aliased to an existing constant. |
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[433e2c3] | 21 | Its purpose is for readability: replacing constant values in a program with symbolic names that are more meaningful to programmers in the context of the application. |
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| 22 | Thereafter, associating a name to a different value automatically distributes this rebinding, preventing errors. |
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[ccfbfd9] | 23 | Because an aliased name is a constant, it cannot appear in a mutable context, \eg \mbox{$\pi$ \lstinline{= 42}} is meaningless, and a constant has no address, \ie it is an \newterm{rvalue}\footnote{ |
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[caf2cba] | 24 | The term rvalue defines an expression that can only appear on the right-hand side of an assignment expression.}. |
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[ccfbfd9] | 25 | In theory, there are an infinite set of possible aliasing, in practice, the number of aliasing per program is finite and small. |
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[caf2cba] | 26 | |
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[ccfbfd9] | 27 | Aliased constants can form an (ordered) set, \eg days of a week, months of a year, floors of a building (basement, ground, 1st), colours in a rainbow, \etc. |
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| 28 | In this case, the binding between a constant name and value can be implicit, where the values are chosen to support any set operations. |
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| 29 | Many programming languages capture the aliasing and ordering through a mechanism called an \newterm{enumeration}. |
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[caf2cba] | 30 | \begin{quote} |
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| 31 | enumerate (verb, transitive). |
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| 32 | To count, ascertain the number of; |
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[4da9142] | 33 | more usually, to mention (a number of things or persons) separately, as if for the purpose of counting; |
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| 34 | to specify as in a list or catalogue.~\cite{OEDenumerate} |
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[caf2cba] | 35 | \end{quote} |
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[ccfbfd9] | 36 | Within an enumeration set, the enumeration names (aliases) must be unique, and instances of an enumerated type are \emph{often} restricted to hold only these names. |
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| 37 | |
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| 38 | It is possible to enumerate among set names without having an ordering among the set values. |
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[48b76d03] | 39 | For example, the week, the weekdays, the weekend, and every second day of the week. |
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| 40 | \begin{cfa}[morekeywords={in}] |
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| 41 | for ( cursor in Mon, Tue, Wed, Thu, Fri, Sat, Sun } ... $\C[3.75in]{// week}$ |
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| 42 | for ( cursor in Mon, Tue, Wed, Thu, Fri } ... $\C{// weekday}$ |
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[4da9142] | 43 | for ( cursor in Sat, Sun } ... $\C{// weekend}$ |
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[48b76d03] | 44 | for ( cursor in Mon, Wed, Fri, Sun } ... $\C{// every second day of week}\CRT$ |
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| 45 | \end{cfa} |
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[433e2c3] | 46 | A set can have a partial or total ordering, making it possible to compare set elements, \eg Monday is before Tuesday and Tuesday is after. |
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[314c9d8] | 47 | Ordering allows iterating among the enumeration set using relational operators and advancement, \eg: |
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[caf2cba] | 48 | \begin{cfa} |
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[433e2c3] | 49 | for ( cursor = Monday; cursor @<=@ Friday; cursor = @succ@( cursor ) ) ... // weekdays |
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[caf2cba] | 50 | \end{cfa} |
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[ccfbfd9] | 51 | Here the values for the set names are logically \emph{generated} rather than listing a subset of names. |
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[4da9142] | 52 | |
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| 53 | Hence, the fundamental aspects of an enumeration are: |
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| 54 | \begin{enumerate} |
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| 55 | \item |
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[314c9d8] | 56 | \begin{sloppypar} |
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[433e2c3] | 57 | It provides a finite set of new constants, which are implicitly or explicitly assigned values that must be appropriate for any set operations, \eg increasing order. |
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[ccfbfd9] | 58 | This aspect differentiates an enumeration from general types with an infinite set of constants. |
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[314c9d8] | 59 | \end{sloppypar} |
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[4da9142] | 60 | \item |
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[ccfbfd9] | 61 | The alias names are constants, which follows transitively from their binding to other constants. |
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[4da9142] | 62 | \item |
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[314c9d8] | 63 | Defines a type for generating instants (variables). |
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[4da9142] | 64 | \item |
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[ccfbfd9] | 65 | For safety, an enumeration instance should be restricted to hold only its constant names. |
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[4da9142] | 66 | \item |
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[ccfbfd9] | 67 | There is a mechanism for \emph{enumerating} over the enumeration names, where the ordering can be implicit from the type, explicitly listed, or generated arithmetically. |
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[4da9142] | 68 | \end{enumerate} |
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[48b76d03] | 69 | |
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[956299b] | 70 | |
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[48b76d03] | 71 | \section{Terminology} |
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[4da9142] | 72 | \label{s:Terminology} |
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[48b76d03] | 73 | |
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[46651fb] | 74 | The term \newterm{enumeration} defines a type with a set of new constants, and the term \newterm{enumerator} represents an arbitrary alias name \see{\VRef{s:CEnumeration} for the name derivations}. |
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| 75 | An enumerated type can have three fundamental properties, \newterm{label} (name), \newterm{order} (position), and \newterm{value} (payload). |
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[956299b] | 76 | \begin{cquote} |
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[48b76d03] | 77 | \sf\setlength{\tabcolsep}{3pt} |
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[caf2cba] | 78 | \begin{tabular}{rcccccccr} |
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| 79 | \it\color{red}enumeration & \multicolumn{8}{c}{\it\color{red}enumerators} \\ |
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[314c9d8] | 80 | $\downarrow$\hspace*{15pt} & \multicolumn{8}{c}{$\downarrow$} \\ |
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| 81 | @enum@ Week \{ & Mon, & Tue, & Wed, & Thu, & Fri, & Sat, & Sun {\color{red}= 42} & \}; \\ |
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[48b76d03] | 82 | \it\color{red}label & Mon & Tue & Wed & Thu & Fri & Sat & Sun & \\ |
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| 83 | \it\color{red}order & 0 & 1 & 2 & 3 & 4 & 5 & 6 & \\ |
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[314c9d8] | 84 | \it\color{red}value & 0 & 1 & 2 & 3 & 4 & 5 & {\color{red}42} & |
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[956299b] | 85 | \end{tabular} |
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| 86 | \end{cquote} |
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[4c8f29ff] | 87 | Here, the enumeration @Week@ defines the enumerator constants @Mon@, @Tue@, @Wed@, @Thu@, @Fri@, @Sat@, and @Sun@. |
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[caf2cba] | 88 | The implicit ordering implies the successor of @Tue@ is @Mon@ and the predecessor of @Tue@ is @Wed@, independent of any associated enumerator values. |
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[ccfbfd9] | 89 | The value is the implicitly/explicitly assigned constant to support any enumeration operations; |
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| 90 | the value may be hidden (opaque) or visible. |
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[48b76d03] | 91 | |
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[caf2cba] | 92 | Specifying complex ordering is possible: |
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| 93 | \begin{cfa} |
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| 94 | enum E1 { $\color{red}[\(_1\)$ {A, B}, $\color{blue}[\(_2\)$ C $\color{red}]\(_1\)$, {D, E} $\color{blue}]\(_2\)$ }; $\C{// overlapping square brackets}$ |
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| 95 | enum E2 { {A, {B, C} }, { {D, E}, F }; $\C{// nesting}$ |
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| 96 | \end{cfa} |
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| 97 | For @E1@, there is the partial ordering among @A@, @B@ and @C@, and @C@, @D@ and @E@, but not among @A@, @B@ and @D@, @E@. |
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| 98 | For @E2@, there is the total ordering @A@ $<$ @{B, C}@ $<$ @{D, E}@ $<$ @F@. |
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| 99 | Only flat total-ordering among enumerators is considered in this work. |
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[7d9a805b] | 100 | |
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| 101 | |
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[48b76d03] | 102 | \section{Motivation} |
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[caf2cba] | 103 | |
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[314c9d8] | 104 | Many programming languages provide an enumeration-like mechanism, which may or may not cover the previous five fundamental enumeration aspects. |
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| 105 | Hence, the term \emph{enumeration} can be confusing and misunderstood. |
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[ccfbfd9] | 106 | Furthermore, some languages conjoin the enumeration with other type features, making it difficult to tease apart which feature is being used. |
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[314c9d8] | 107 | This section discusses some language features that are sometimes called an enumeration but do not provide all enumeration aspects. |
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| 108 | |
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| 109 | |
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| 110 | \subsection{Aliasing} |
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[f632117] | 111 | \label{s:Aliasing} |
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[314c9d8] | 112 | |
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[433e2c3] | 113 | Some languages provide simple aliasing (renaming). |
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[caf2cba] | 114 | \begin{cfa} |
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[4da9142] | 115 | const Size = 20, Pi = 3.14159, Name = "Jane"; |
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[caf2cba] | 116 | \end{cfa} |
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[ccfbfd9] | 117 | The alias name is logically replaced in the program text by its matching constant. |
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[46651fb] | 118 | It is possible to compare aliases, if the constants allow it, \eg @Size < Pi@, whereas @Pi < Name@ might be disallowed depending on the language. |
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[caf2cba] | 119 | |
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[433e2c3] | 120 | Aliasing is \emph{not} macro substitution, \eg @#define Size 20@, where a name is replaced by its value \emph{before} compilation, so the name is invisible to the programming language. |
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[ccfbfd9] | 121 | With aliasing, each new name is part of the language, and hence, participates fully, such as name overloading in the type system. |
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[433e2c3] | 122 | Aliasing is not an immutable variable. |
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[314c9d8] | 123 | \begin{cfa} |
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| 124 | extern @const@ int Size = 20; |
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| 125 | extern void foo( @const@ int @&@ size ); |
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| 126 | foo( Size ); // take the address of (reference) Size |
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| 127 | \end{cfa} |
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[caaf424] | 128 | Taking the address of an immutable variable makes it an \newterm{lvalue}, which implies it has storage. |
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[314c9d8] | 129 | With separate compilation, it is necessary to choose one translation unit to perform the initialization. |
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[433e2c3] | 130 | If aliasing requires storage, its address and initialization are opaque (compiler only), similar to \CC rvalue reference @&&@. |
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[314c9d8] | 131 | |
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| 132 | Aliasing does provide readability and automatic resubstitution. |
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[ccfbfd9] | 133 | It also provides simple enumeration properties, but with effort. |
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[caf2cba] | 134 | \begin{cfa} |
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| 135 | const Mon = 1, Tue = 2, Wed = 3, Thu = 4, Fri = 5, Sat = 6, Sun = 7; |
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| 136 | \end{cfa} |
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[4da9142] | 137 | Any reordering of the enumerators requires manual renumbering. |
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[caf2cba] | 138 | \begin{cfa} |
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[46651fb] | 139 | const @Sun = 1@, Mon = 2, Tue = 3, Wed = 4, Thu = 5, Fri = 6, Sat = 7; |
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[caf2cba] | 140 | \end{cfa} |
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[314c9d8] | 141 | For these reasons, aliasing is sometimes called an enumeration. |
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| 142 | However, there is no type to create a type-checked instance or iterator cursor, so there is no ability for enumerating. |
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| 143 | Hence, there are multiple enumeration aspects not provided by aliasing, justifying a separate enumeration type in a programming language. |
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| 144 | |
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| 145 | |
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| 146 | \subsection{Algebraic Data Type} |
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[ec20ab9] | 147 | \label{s:AlgebraicDataType} |
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[4da9142] | 148 | |
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[314c9d8] | 149 | An algebraic data type (ADT)\footnote{ADT is overloaded with abstract data type.} is another language feature often linked with enumeration, where an ADT conjoins an arbitrary type, possibly a \lstinline[language=C++]{class} or @union@, and a named constructor. |
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| 150 | For example, in Haskell: |
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| 151 | \begin{haskell} |
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| 152 | data S = S { i::Int, d::Double } $\C{// structure}$ |
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| 153 | data @Foo@ = A Int | B Double | C S $\C{// ADT, composed of three types}$ |
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| 154 | foo = A 3; $\C{// type Foo is inferred}$ |
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| 155 | bar = B 3.5 |
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| 156 | baz = C S{ i = 7, d = 7.5 } |
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| 157 | \end{haskell} |
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[433e2c3] | 158 | the ADT has three variants (constructors), @A@, @B@, @C@, with associated types @Int@, @Double@, and @S@. |
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[314c9d8] | 159 | The constructors create an initialized value of the specific type that is bound to the immutable variables @foo@, @bar@, and @baz@. |
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[ccfbfd9] | 160 | Hence, the ADT @Foo@ is like a union containing values of the associated types, and a constructor name is used to intialize and access the value using dynamic pattern-matching. |
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[4da9142] | 161 | \begin{cquote} |
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[433e2c3] | 162 | \setlength{\tabcolsep}{20pt} |
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[314c9d8] | 163 | \begin{tabular}{@{}ll@{}} |
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| 164 | \begin{haskell} |
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| 165 | prtfoo val = -- function |
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[433e2c3] | 166 | -- pattern match on constructor |
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| 167 | case val of |
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| 168 | @A@ a -> print a |
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| 169 | @B@ b -> print b |
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| 170 | @C@ (S i d) -> do |
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| 171 | print i |
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| 172 | print d |
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[314c9d8] | 173 | \end{haskell} |
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[4da9142] | 174 | & |
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[314c9d8] | 175 | \begin{haskell} |
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| 176 | main = do |
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[433e2c3] | 177 | prtfoo foo |
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| 178 | prtfoo bar |
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| 179 | prtfoo baz |
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[314c9d8] | 180 | 3 |
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| 181 | 3.5 |
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| 182 | 7 |
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| 183 | 7.5 |
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| 184 | \end{haskell} |
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[4da9142] | 185 | \end{tabular} |
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| 186 | \end{cquote} |
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[ccfbfd9] | 187 | For safety, most languages require all associated types to be listed or a default case with no field accesses. |
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[314c9d8] | 188 | |
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| 189 | A less frequent case is multiple constructors with the same type. |
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| 190 | \begin{haskell} |
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| 191 | data Bar = X Int | Y Int | Z Int; |
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| 192 | foo = X 3; |
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| 193 | bar = Y 3; |
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| 194 | baz = Z 5; |
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| 195 | \end{haskell} |
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| 196 | Here, the constructor name gives different meaning to the values in the common \lstinline[language=Haskell]{Int} type, \eg the value @3@ has different interpretations depending on the constructor name in the pattern matching. |
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| 197 | |
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[caaf424] | 198 | Note, the term \newterm{variant} is often associated with ADTs. |
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[314c9d8] | 199 | However, there are multiple languages with a @variant@ type that is not an ADT \see{Algol68~\cite{Algol68} or \CC \lstinline{variant}}. |
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[433e2c3] | 200 | Here, the type (and possibly the position for equivalent types) is used to discriminant the specific \emph{variant} within the variant instance. |
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| 201 | For example, \VRef[Figure]{f:C++variant} shows the \CC equivalent of the two Haskell ADT types using variant types. |
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| 202 | In these languages, the variant cannot be used to simulate an enumeration. |
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[314c9d8] | 203 | Hence, in this work the term variant is not a synonym for ADT. |
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| 204 | |
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[433e2c3] | 205 | \begin{figure} |
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| 206 | \begin{c++} |
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| 207 | struct S { char s[32]; }; |
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| 208 | variant< int, double, S > vd; |
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| 209 | variant< int, int, int > vs; |
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| 210 | |
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| 211 | // discrimination based on type |
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| 212 | vd = 3; |
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| 213 | if ( holds_alternative<int>(vd) ) cout << "int " << get<int>(vd ) << endl; |
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| 214 | vd = 3.5; |
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| 215 | if ( holds_alternative<double>(vd) ) cout << "double " << get<double>(vd) << endl; |
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| 216 | vd = (S){ "abc" }; |
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| 217 | if ( holds_alternative<S>(vd) ) cout << "S.s " << get<S>(vd).s << endl; |
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| 218 | |
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| 219 | // discrimination based on type and position within type |
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| 220 | vs = (variant<int,int,int>){ in_place_index<0>, 12 }; |
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| 221 | if ( vs.index() == 0 ) cout << "posn 0 " << get<0>(vs) << endl; |
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| 222 | vs = (variant<int,int,int>){ in_place_index<1>, 4 }; |
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| 223 | if ( vs.index() == 1 ) cout << "posn 1 " << get<1>(vs) << endl; |
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| 224 | vs = (variant<int,int,int>){ in_place_index<2>, 5 }; |
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| 225 | if ( vs.index() == 2 ) cout << "posn 2 " << get<2>(vs) << endl; |
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| 226 | \end{c++} |
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| 227 | \caption{\CC \lstinline[language=C++]{variant} Discrimination Using RTTI/Position} |
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| 228 | \label{f:C++variant} |
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| 229 | \end{figure} |
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| 230 | |
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[314c9d8] | 231 | % https://downloads.haskell.org/ghc/latest/docs/libraries/base-4.19.1.0-179c/GHC-Enum.html |
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| 232 | % https://hackage.haskell.org/package/base-4.19.1.0/docs/GHC-Enum.html |
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[48b76d03] | 233 | |
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[314c9d8] | 234 | The association between ADT and enumeration occurs if all the constructors have a unit (empty) type, \eg @struct unit {}@. |
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[433e2c3] | 235 | Note, the unit type is not the same as \lstinline{void}. |
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[4da9142] | 236 | \begin{cfa} |
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[314c9d8] | 237 | void foo( void ); |
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[4c8f29ff] | 238 | struct unit {} u; $\C[1.5in]{// empty type}$ |
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[314c9d8] | 239 | unit bar( unit ); |
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[433e2c3] | 240 | foo( @foo()@ ); $\C{// void argument does not match with void parameter}$ |
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[4c8f29ff] | 241 | bar( bar( u ) ); $\C{// unit argument does match with unit parameter}\CRT$ |
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[4da9142] | 242 | \end{cfa} |
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[caf2cba] | 243 | |
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[314c9d8] | 244 | For example, in the Haskell ADT: |
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| 245 | \begin{haskell} |
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| 246 | data Week = Mon | Tue | Wed | Thu | Fri | Sat | Sun deriving(Enum, Eq, Show) |
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| 247 | \end{haskell} |
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[ccfbfd9] | 248 | the default type for each constructor is the unit type, and deriving from @Enum@ enforces no other associated types, @Eq@ allows equality comparison, and @Show@ is for printing. |
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[433e2c3] | 249 | The nullary constructors for the unit types are numbered left-to-right from $0$ to @maxBound@$- 1$, and provides enumerating operations @succ@, @pred@, @enumFrom@, @enumFromTo@. |
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[314c9d8] | 250 | \VRef[Figure]{f:HaskellEnumeration} shows enumeration comparison and iterating (enumerating). |
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| 251 | |
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| 252 | \begin{figure} |
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[4da9142] | 253 | \begin{cquote} |
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[433e2c3] | 254 | \setlength{\tabcolsep}{40pt} |
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[314c9d8] | 255 | \begin{tabular}{@{}ll@{}} |
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| 256 | \begin{haskell} |
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| 257 | day = Tue |
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| 258 | main = do |
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[433e2c3] | 259 | if day == Tue then |
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| 260 | print day |
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| 261 | else |
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| 262 | putStr "not Tue" |
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| 263 | print (enumFrom Mon) $\C[2.25in]{-- week}$ |
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| 264 | print (enumFromTo Mon Fri) $\C{-- weekday}$ |
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| 265 | print (enumFromTo Sat Sun) $\C{-- weekend}\CRT$ |
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[314c9d8] | 266 | \end{haskell} |
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[4da9142] | 267 | & |
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[314c9d8] | 268 | \begin{haskell} |
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| 269 | Tue |
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| 270 | [Mon,Tue,Wed,Thu,Fri,Sat,Sun] |
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| 271 | [Mon,Tue,Wed,Thu,Fri] |
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| 272 | [Sat,Sun] |
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[caf2cba] | 273 | |
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| 274 | |
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[4da9142] | 275 | |
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[314c9d8] | 276 | |
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| 277 | |
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| 278 | \end{haskell} |
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| 279 | \end{tabular} |
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| 280 | \end{cquote} |
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| 281 | \caption{Haskell Enumeration} |
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| 282 | \label{f:HaskellEnumeration} |
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| 283 | \end{figure} |
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| 284 | |
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| 285 | The key observation is the dichotomy between an ADT and enumeration: the ADT uses the associated type resulting in a union-like data structure, and the enumeration does not use the associated type, and hence, is not a union. |
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[433e2c3] | 286 | In contrast, an enumeration may be constructed using the ADT mechanism, but it is so restricted it is not an ADT. |
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[314c9d8] | 287 | Furthermore, a general ADT cannot be an enumeration because the constructors generate different values making enumerating meaningless. |
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| 288 | While functional programming languages regularly repurpose the ADT type into an enumeration type, this process seems contrived and confusing. |
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| 289 | Hence, there is only a weak equivalence between an enumeration and ADT, justifying a separate enumeration type in a programming language. |
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[caf2cba] | 290 | |
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[f9da761] | 291 | |
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| 292 | \section{Contributions} |
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[7d9a805b] | 293 | |
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[314c9d8] | 294 | The goal of this work is to to extend the simple and unsafe enumeration type in the C programming-language into a complex and safe enumeration type in the \CFA programming-language, while maintaining backwards compatibility with C. |
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[caf2cba] | 295 | On the surface, enumerations seem like a simple type. |
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[41fb996] | 296 | However, when extended with advanced features, enumerations become complex for both the type system and the runtime implementation. |
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[48b76d03] | 297 | |
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[314c9d8] | 298 | The contribution of this work are: |
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[48b76d03] | 299 | \begin{enumerate} |
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| 300 | \item |
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[433e2c3] | 301 | overloading: |
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[48b76d03] | 302 | \item |
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| 303 | scoping |
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| 304 | \item |
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| 305 | typing |
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| 306 | \item |
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[314c9d8] | 307 | subseting |
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[48b76d03] | 308 | \item |
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| 309 | inheritance |
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| 310 | \end{enumerate} |
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[4c8f29ff] | 311 | |
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| 312 | |
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| 313 | \begin{comment} |
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| 314 | Date: Wed, 1 May 2024 13:41:58 -0400 |
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| 315 | Subject: Re: Enumeration |
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| 316 | To: "Peter A. Buhr" <pabuhr@uwaterloo.ca> |
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| 317 | From: Gregor Richards <gregor.richards@uwaterloo.ca> |
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| 318 | |
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| 319 | I think I have only one comment and one philosophical quibble to make: |
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| 320 | |
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| 321 | Comment: I really can't agree with putting MB in the same category as the |
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| 322 | others. MB is both a quantity and a unit, and the suggestion that MB *is* one |
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| 323 | million evokes the rather disgusting comparison 1MB = 1000km. Unit types are |
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| 324 | not in the scope of this work. |
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| 325 | |
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| 326 | Philosophical quibble: Pi *is* 3.14159...etc. Monday is not 0; associating |
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| 327 | Monday with 0 is just a consequence of the language. The way this is written |
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| 328 | suggests that the intentional part is subordinate to the implementation detail, |
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| 329 | which seems backwards to me. Calling the number "primary" and the name |
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| 330 | "secondary" feels like you're looking out from inside of the compiler, instead |
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| 331 | of looking at the language from the outside. And, calling secondary values |
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| 332 | without visible primary values "opaque"-which yes, I realize is my own term |
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| 333 | ;)-suggests that you insist that the primary value is a part of the design, or |
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| 334 | at least mental model, of the program. Although as a practical matter there is |
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| 335 | some system value associated with the constructor/tag of an ADT, that value is |
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| 336 | not part of the mental model, and so calling it "primary" and calling the name |
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| 337 | "secondary" and "opaque" seems either (a) very odd or (b) very C-biased. Or |
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| 338 | both. |
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| 339 | |
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| 340 | With valediction, |
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| 341 | - Gregor Richards |
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| 342 | |
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| 343 | |
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| 344 | Date: Thu, 30 May 2024 23:15:23 -0400 |
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| 345 | Subject: Re: Meaning? |
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| 346 | To: "Peter A. Buhr" <pabuhr@uwaterloo.ca> |
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| 347 | CC: <ajbeach@uwaterloo.ca>, <j82liang@uwaterloo.ca> |
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| 348 | From: Gregor Richards <gregor.richards@uwaterloo.ca> |
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| 349 | |
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| 350 | I have to disagree with this being agreeing to disagree, since we agree |
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| 351 | here. My core point was that it doesn't matter whether you enumerate over the |
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| 352 | names or the values. This is a distinction without a difference in any case |
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| 353 | that matters. If any of the various ways of looking at it are actually |
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| 354 | different from each other, then that's because the enumeration has failed to be |
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| 355 | an enumeration in some other way, not because of the actual process of |
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| 356 | enumeration. Your flag enum is a 1-to-1 map of names and values, so whether you |
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| 357 | walk through names or walk through values is not an actual distinction. It |
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| 358 | could be distinct in the *order* that it walks through, but that doesn't |
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| 359 | actually matter, it's just a choice that has to be made. Walking through entire |
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| 360 | range of machine values, including ones that aren't part of the enumeration, |
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| 361 | would be bizarre in any case. |
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| 362 | |
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| 363 | Writing these out has crystallized some thoughts, albeit perhaps not in a way |
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| 364 | that's any help to y'all. An enumeration is a set of names; ideally an ordered |
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| 365 | set of names. The state of enumerations in programming languages muddies things |
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| 366 | because they often expose the machine value underlying those names, resulting |
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| 367 | in a possibly ordered set of names and a definitely ordered set of values. And, |
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| 368 | muddying things further, because those underlying values are exposed, enums are |
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| 369 | used in ways that *depend* on the underlying values being exposed, making that |
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| 370 | a part of the definition. But, an enumeration is conceptually just *one* set, |
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| 371 | not both. So much of the difficulty is that you're trying to find a way to make |
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| 372 | a concept that should be a single set agree with an implementation that's two |
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| 373 | sets. If those sets have a 1-to-1 mapping, then who cares, they're just |
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| 374 | aliases. It's the possibility of the map being surjective (having multiple |
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| 375 | names for the same underlying values) that breaks everything. Personally, I |
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| 376 | think that an enum with aliases isn't an enumeration anyway, so who cares about |
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| 377 | the rest; if you're not wearing the gourd as a shoe, then it's not an |
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| 378 | enumeration. |
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| 379 | |
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| 380 | With valediction, |
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| 381 | - Gregor Richards |
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| 382 | \end{comment} |
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