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FunctionalParsers.m
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(*
Functional parsers Mathematica package
Copyright (C) 2014 Anton Antonov
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
Written by Anton Antonov,
ʇǝu˙oǝʇsod@ǝqnɔouoʇuɐ,
Windermere, Florida, USA.
*)
(*
Mathematica is (C) Copyright 1988-2019 Wolfram Research, Inc.
Protected by copyright law and international treaties.
Unauthorized reproduction or distribution subject to severe civil
and criminal penalties.
Mathematica is a registered trademark of Wolfram Research, Inc.
*)
(* Version 1.0 *)
(*
## Introduction
This package provides an implementation of a system of functional parsers.
The implementation follows closely the article:
"Functional parsers" by Jeroen Fokker
http://www.staff.science.uu.nl/~fokke101/article/parsers/
The parsers are categorized in the groups: basic, combinators, and transformers.
The basic parsers parse specified strings and strings adhering to predicates.
The combinator parsers allow sequential and alternative combinations of parsers.
The transformer parsers change the input or the output of the parsers that are transformed.
A basic parser or a combinator parser takes a list of strings and returns a list of pairs, {{o1,r1},{o2,r2},...}.
Each pair has as elements a parsed output and the rest of the input list.
Functions for splitting the input text into tokens are provided.
The package also have functions to generate parsers from a string of the Extended Backus-Naur Form (EBNF) definition
of a grammar.
The EBNF grammar string can have the pick-left and pick-right combinators (\[LeftTriangle] or "<&",
and \[RightTriangle] or "&>" respectively) and a ParseApply specification can be given within the form
"<rhs> = parsers <@ transformer" .
The application of transformer functions can be done over the whole definition of an EBNF non-terminal symbol,
not over the individual parts.
There is a function, InterpretWithContext, for interpreting parsed results with a context.
The context is given as a list of rules. There are two forms for the context rules: {(_Symbol->_)..} and
{"data"->{(_Symbol->_)...}, "functions"->{(_Symbol->_)...}} . If during the interpretation the context functions change
the context data the result of InterpretWithContext will return the changed data.
A more extensive introduction is given in the document:
"Functional parsers for an integration requests language grammar"
in MathematicaForPrediction at GitHub. Here is the URL:
https://github.com/antononcube/MathematicaForPrediction/blob/master/Documentation/Functional%20parsers%20for%20an%20integration%20requests%20language%20grammar.pdf
Versions of this package are also implemented in R and Lua. See:
https://github.com/antononcube/MathematicaForPrediction/tree/master/R/FunctionalParsers (R), and
https://github.com/antononcube/MathematicaForPrediction/tree/master/Lua/FunctionalParsers (Lua).
## Usage example
```mathematica
p = (Who\[CircleDot](ParseSymbol["I"]\[CirclePlus]ParseSymbol["we"]))\[CircleTimes](Verb\[CircleDot](ParseSymbol["love"]\[CirclePlus]ParseSymbol["crave"]))\[CircleTimes](What\[CircleDot](ParseSymbol["chocolate"]\[CirclePlus]ParseSymbol["coffee"]\[CirclePlus]ParseSymbol["ice"]\[CircleTimes]ParseSymbol["cream"]));
Grid[{#, p[ToTokens[#]]} & /@ {"we love ice cream", "I crave coffee"}, Dividers -> All, Alignment -> Left]
```
## TODO
1. [X] Add a simple concrete example in this file.
2. [ ] Re-implement with the new syntax for operators in Mathematica.
3. [ ] Provide unit tests.
4. [ ] Make a corresponding paclet for [WPR](https://resources.wolframcloud.com/PacletRepository/).
*)
BeginPackage["FunctionalParsers`"];
ParseSymbol::usage = "ParseSymbol[s] parses a specified symbol s.";
ParseToken::usage = "ParseToken[t] parses the token t.";
ParsePredicate::usage = "ParsePredicate[p] parses strings that give True for the predicate p.";
ParseEpsilon::usage = "ParseEpsilon parses and empty string.";
ParseSucceed::usage = "ParseSucceed[v] does not consume input and always returns v.";
ParseFail::usage = "ParseFail fails to recognize any input string.";
ParseComposeWithResults::usage = "ParseComposeWithResults[p_][res : {{_, _} ..}] is building block function for ParseSequentialComposition.";
ParseSequentialComposition::usage = "ParseSequentialComposition parses a sequential composition of two or more parsers.";
ParseAlternativeComposition::usage = "ParseAlternativeComposition parses a composition of two or more alternative parsers.";
ParseSpaces::usage = "ParseSpaces[p] is a transformation of the parser p: the leading spaces of the input are dropped then the parser p is applied.";
ParseJust::usage = "ParseJust[p] is a transformation of the parser p: those parts of output of p are selected that have empty rest strings.";
ParseApply::usage = "ParseApply[f,p] applies the function f to each of the outputs of p.\
ParseApply[{fNo, fYes}, p] applies the function fNo not unsuccessful parsing and the function fYes the output of successful parsing using p.";
ParseModify::usage = "ParseModify[f,p] applies the function f to the list of all outputs of p.";
ParseSome::usage = "ParseSome[p] applies ParseJust[p] and takes the first non-empty output if it exists.";
ParseShortest::usage = "ParseShortest[p] takes the output with the shortest rest string.";
ParseSequentialCompositionPickLeft::usage = "ParseSequentialCompositionPickLeft[p1,p2] drops the output of the p2 parser.";
ParseSequentialCompositionPickRight::usage = "ParseSequentialCompositionPickRight[p1,p2] drops the output of the p1 parser.";
ParseChoice::usage = "ParseChoice[p1,p2,p3,...] a version of ParseAlternativeComposition for more than two parsers.";
CircleDot::usage = "CircleDot[f_, p_] applies the function f to the output of p. It can be entered with \"Exc c . Esc\" .";
CircleTimes::usage = "CircleTimes[p1,p2,p3] sequential composition of the parsers p1, p2, p3, ... It can be entered with \"Exc c * Esc\" .";
CirclePlus::usage = "CirclePlus[p1,p2,p3] alternatives composition of the parsers p1, p2, p3, ... It can be entered with \"Exc c + Esc\" .";
LeftTriangle::usage = "LeftTriangle[p1_, p2_] drops the output of the right parser, p2. It can be entered with \"\:22B2\".";
RightTriangle::usage = "RightTriangle[p1_, p2_] drops the output of the left parser, p1. It can be entered with \"\:22B3\".";
ParsePack::usage = "ParsePack[s1,p,s2] parses the sequential composition of s1, p, s2 and drops the output of s1 and s2.";
ParseParenthesized::usage = "ParseParenthesized[p] parses with p input enclosed in parentheses \"(\",\")\".";
ParseBracketed::usage = "ParseBracketed[p] parses with p input enclosed in brackets \"[\",\"]\".";
ParseCurlyBracketed::usage = "ParseCurlyBracketed[p] parses with p input enclosed in curly brackets \"{\",\"}\".";
ParseOption::usage = "ParseOption[p] is optional parsing of p.";
ParseOption1::usage = "ParseOption1[p] is optional parsing of p. (Different implementation of ParseOption.)";
ParseMany1::usage = "ParseMany1[p] attempts to parse one or many times with p.";
ParseMany::usage = "ParseMany[p] attempts to parse zero or many times with p.";
ParseManyByBranching::usage = "ParseManyByBranching[p] parsing many times with p and following branches.";
ParseListOf::usage = "ParseListOf[p_, sep_] parse a list of elements parsed by p and seprated by elements parsed by sep.";
ParseChainLeft::usage = "ParseChainLeft[p_, sep_] parse a nested application of the function with a name parsed by sep.";
ParseChain1Left::usage = "ParseChain1Left[p_, sep_] parse a nested application of the function with a name parsed by sep.";
ParseChainRight::usage = "ParseChainRight[p_, sep_] parse a nested application of the function with a name parsed by sep.";
ParseRecursiveDefinition::usage = "ParseRecursiveDefinition[pname, rhs] makes a parser with name pname defined by rhs that can be used in recursive definitions.";
ToTokens::usage = "ToTokens[text] breaks down text into tokens. ToTokens[text,terminals] breaks down text using specified terminals. \
ToTokens[text,\"EBNF\"] has a special implementation for parsing EBNF code. (This function is becoming obsolete, use ParseToTokens.)";
ParseToTokens::usage = "ParseToTokens[text, terminalDelimiters, whitespaces] breaks down text into tokens using specified terminal symbols and white spaces.";
ParseToEBNFTokens::usage = "ParseToEBNFTokens[text, whitespaces] breaks down text into tokens using EBNF terminal symbols and specified white spaces.";
ParsingTestTable::usage = "ParsingTestTable[p, s, opts] parses a list of strings with the parser p and tabulates the result. \
The options allow to specify the terminal symbols, tokenizer function, and table layout.";
EBNFNonTerminal::usage = "EBNFNonTerminal head for parsers for non-terminal symbols of EBNF grammars.";
EBNFTerminal::usage = "EBNFTerminal head for parsers for terminal symbols of EBNF grammars.";
EBNFOption::usage = "EBNFOption head for parsers for optional symbols of EBNF grammars.";
EBNFRepetition::usage = "EBNFRepetition head for parsers for repeating symbols of EBNF grammars.";
EBNFSequence::usage = "EBNFSequence head for parsers for sequential composition of symbols of EBNF grammars.";
EBNFAlternatives::usage = "EBNFAlternatives head for parsers for alternatives sequential composition of symbols of EBNF grammars.";
EBNFRule::usage = "EBNFRule head for parsers of EBNF grammar rules.";
EBNF::usage = "Head symbol used to for parsed EBNF grammars.";
EBNFNonTerminalInterpreter::usage = "EBNFNonTerminal generates parsers for non-terminal symbols of EBNF grammars.";
EBNFTerminalInterpreter::usage = "EBNFTerminal generates parsers for terminal symbols of EBNF grammars.";
EBNFOptionInterpreter::usage = "EBNFOption generates parsers for optional symbols of EBNF grammars.";
EBNFRepetitionInterpreter::usage = "EBNFRepetition generates parsers for repeating symbols of EBNF grammars.";
EBNFSequenceInterpreter::usage = "EBNFSequence generates parsers for sequential composition of symbols of EBNF grammars.";
EBNFAlternativesInterpreter::usage = "EBNFAlternatives generates parsers for alternatives sequential composition of symbols of EBNF grammars.";
EBNFRuleInterpreter::usage = "EBNFRule generates parsers of EBNF grammar rules.";
SetParserModifier::usage = "SetParserModifier[p_Symbol, f_] sets the function f to modify the output of the parser p. (Replaces the previous modifier.)";
AddParserModifier::usage = "AddParserModifier[p_Symbol, f_] makes the function f to modify the output of the parser p.";
InterpretWithContext::usage = "InterpretWithContext[pout_,cr_] interprets the parser output pout with the context rules cr.";
EBNFContextRules::usage = "Context rules for EBNF parser generation.";
ParseEBNF::usage = "ParseEBNF[gr:{_String..}] parses the EBNF grammar gr.";
GenerateParsersFromEBNF::usage = "GenerateParsersFromEBNF[gr:{_String..}] generate parsers the EBNF grammar gr.";
GrammarNormalize::usage = "Remove special character sequences from an EBNF grammar string.";
GrammarRandomSentences::usage = "GrammarRandomSentences[ gr: _String | _EBNF, n_Integer] generates n random sentences using the grammar gr.";
Begin["`Private`"];
Clear["Parse?*"];
(************************************************************)
(* Basic parsers *)
(************************************************************)
ParseSymbol[a_] :=
Function[If[Length[#] > 0 && a === First[#], {{Rest[#], a}}, {}]];
ParseToken[k_][xs_] :=
With[{n = Length[k]},
If[Length[xs] >= n && k == Take[xs, n], {{Drop[xs, n], k}}, {}]];
ParsePredicate[pred_][xs_] :=
If[TrueQ[Length[xs] > 0 && pred[First[xs]]], {{Rest[xs], First[xs]}}, {}];
(*
Note that
ParseSymbol[a] = ParsePredicate[# == a &]
*)
ParseEpsilon = Function[{xs}, {{xs, {}}} ];
ParseSucceed[v_] := Function[{xs}, {{xs, v}}];
ParseFail[xs_] := {};
(************************************************************)
(* Parse combinators *)
(************************************************************)
ParseComposeWithResults[p_][{}] := {};
ParseComposeWithResults[p_][res : {{_, _} ..}] :=
Block[{t},
Flatten[#, 1] &@
Map[
Function[{r},
If[r === {}, {},
t = p[r[[1]]];
If[t === {}, {},
Map[{#[[1]], {r[[2]], #[[2]]}} &, t]
]]],
res]
];
ParseSequentialComposition[p1_][xs_] := p1[xs];
ParseSequentialComposition[args__][xs_] :=
With[{parsers = {args}},
Fold[ParseComposeWithResults[#2][#1] &, First[parsers][xs],
Rest[parsers]]
] /; Length[{args}] > 1;
ParseAlternativeComposition[args__][xs_] := Join @@ Map[#[xs] &, {args}];
(************************************************************)
(* Next combinators *)
(************************************************************)
(* ParseSpaces[p_][xs_]:=p[NestWhile[Rest,xs,First[#]==""||First[#]==" "&]]; *)
ParseSpaces[pArg_] :=
With[{p = pArg},
Function[p[
NestWhile[Rest, #,
Length[#] >
0 && (First[#] == "" || First[#] == " " ||
First[#] == "\n") &]]]]
ParseJust[p_][xs_] := With[{res = p[xs]}, Select[res, First[#] === {} &]];
ParseApply[f_, p_][xs_] := Map[{#[[1]], f[#[[2]]]} &, p[xs]];
ParseApply[{fNo_, fYes_}, p_] :=
With[{res = p[#]},
Map[{#[[1]], If[#[[2]] === {}, fNo, fYes[#[[2]]]]} &, res]] &;
ParseModify[f_, p_][xs_] := With[{res = p[xs]}, f[res] ];
ParseSome[p_][xs_] :=
With[{parsed = ParseJust[p][xs]},
If[Length[parsed] > 0, Take[parsed, 1], parsed]];
ParseShortest[p_] := With[{parsed = p[#]}, If[parsed === {}, parsed, {First@SortBy[parsed, Length[#[[1]]] &]}]] &;
ParseSequentialCompositionPickLeft[p1_, p2_][xs_] := ParseApply[#[[1]] &, ParseSequentialComposition[p1, p2]][xs];
ParseSequentialCompositionPickRight[p1_, p2_][xs_] := ParseApply[#[[2]] &, ParseSequentialComposition[p1, p2]][xs];
ParseChoice[args__][xs_] :=
With[{parsers = {args}}, Fold[Join[#2[xs], #1] &, ParseFail[xs], Reverse@parsers]];
(************************************************************)
(* Binding for infix notation *)
(************************************************************)
CircleDot[f_, p_] := ParseApply[f, p];(* Exc c . Esc *)
CircleTimes[args___] := ParseSequentialComposition[args];(* Exc c * Esc *)
CirclePlus[args___] := ParseAlternativeComposition[args];(* Exc c + Esc *)
LeftTriangle[p1_, p2_] := ParseSequentialCompositionPickLeft[p1, p2]; (* \:22B2 *)
RightTriangle[p1_, p2_] := ParseSequentialCompositionPickRight[p1, p2]; (* \:22B3 *)
(* Note that the precedence pre-assigned of the operators \[CircleDot], \[CircleTimes] and \[CirclePlus] gives the expected grouping:
Block[{a, b, c, d, f, h},
Print[f\[CircleDot]a\[CircleTimes]b\[CirclePlus]c\[CircleTimes]h\[CircleDot]d]
]
ParseAlternativeComposition[ParseSequentialComposition[ParseApply[f,a],b],ParseSequentialComposition[c,ParseApply[h,d]]]
*)
(*
Note that the precedence pre-assigned of the operators \[LeftTriangle] and \[RightTriangle] gives the expected grouping:
Block[{x, y, z},
Print[x \[RightTriangle] y \[LeftTriangle] z]
]
ParseSequentialCompositionPickLeft[ParseSequentialCompositionPickRight[x,y],z]
*)
(************************************************************)
(* Second next combinators *)
(************************************************************)
ParsePack[s1_, p_, s2_] := ParseSequentialCompositionPickLeft[ ParseSequentialCompositionPickRight[s1, p], s2];
ParseParenthesized[p_] := ParsePack[ParseSymbol["("], p, ParseSymbol[")"]];
ParseBracketed[p_] := ParsePack[ParseSymbol["["], p, ParseSymbol["]"]];
ParseCurlyBracketed[p_] := ParsePack[ParseSymbol["{"], p, ParseSymbol["}"]]
ParseOption[p_] := (ParseAlternativeComposition[ParseApply[{#1} &, p], ParseApply[{} &, ParseSucceed[{}]]]);
ParseOption1[p_] := Block[{res = p[#]}, If[TrueQ[res === {}], {{#, {}}}, res]] &;
ParseMany1[p_][xs_] :=
Module[{t = {}, res},
res = ParseShortest[ParseOption1[p]][xs];
While[! (res === {} || res[[1, 2]] === {}),
AppendTo[t, res[[1, 2]]];
res = ParseShortest[ParseOption1[p]][res[[1, 1]]];
];
{{res[[1, 1]], t}}
];
ParseMany[p_] := ParseMany1[p]\[CirclePlus]ParseSucceed[{}];
Clear[ParseManyByBranching];
ParseManyByBranching[p_][xs_] := ParseManyByBranching[p, {}, 100][xs];
ParseManyByBranching[p_, epsilon_, maxSteps_Integer ][xs_] :=
Block[{res = {}, pres, pres1, k = 0, p1},
p1 = ParseAlternativeComposition[ParseSucceed[epsilon], p];
If[Length[xs] == 0, epsilon,
pres = p1[xs];
While[! (pres === {} || And @@ Map[#[[2]] === {} &, pres]) &&
k < maxSteps,
k++;
(*Print[{k, "before:"}, pres];*)
pres = DeleteCases[pres, {xs, _}];
res = Join[res, Cases[pres, {{}, ___}]];
pres = DeleteCases[pres, {{}, ___}];
pres1 = DeleteCases[pres, {_, {___, {___, epsilon}, epsilon}}];
(*Print[{k, "after delete:"}, pres1];*)
If[Length[pres1] == 0 && Length[res] == 0,
Return[DeleteDuplicates[pres]],
pres = DeleteDuplicates[ParseComposeWithResults[p1][pres1]]
];
(*Print[{k, "after:"}, pres];*)
]
];
DeleteDuplicates[Join[res, pres]]
];
ParseListOf[p_, separatorParser_] := (Prepend[#[[2]], #[[1]]] &)\[CircleDot](p\[CircleTimes]ParseMany[separatorParser \[RightTriangle] p])\[CirclePlus]ParseSucceed[{}];
ParseChainLeft[p_, separatorParser_] :=
Fold[#2[[1]][#1, #2[[2]]] &, #[[1]], #[[2]]] &\[CircleDot](p\[CircleTimes]ParseMany[separatorParser\[CircleTimes]p])\[CirclePlus]ParseSucceed[{}];
ParseChain1Left[p_, separatorParser_] :=
Fold[#2[[1]][#1, #2[[2]]] &, #[[1]], #[[2]]] &\[CircleDot](p\[CircleTimes]ParseMany1[separatorParser\[CircleTimes]p]);
ParseChainLeft[p_, {separatorParser_, func_}] :=
(Fold[func[#1, #2[[2]]] &, #[[1]], #[[2]]] &)\[CircleDot](p\[CircleTimes]ParseMany[separatorParser\[CircleTimes]p])\[CirclePlus]ParseSucceed[{}];
ParseChainRight[p_, separatorParser_] :=
Fold[#2[[2]][#2[[1]], #1] &, #[[2]],
Reverse[#[[1]]]] &\[CircleDot](ParseMany[p\[CircleTimes]separatorParser]\[CircleTimes]p)\[CirclePlus]ParseSucceed[{}];
ParseChainRight[p_, {separatorParser_, func_}] :=
Fold[func[#2[[1]], #1] &, #[[2]],
Reverse[#[[1]]]] &\[CircleDot](ParseMany[p\[CircleTimes]separatorParser]\[CircleTimes]p)\[CirclePlus]ParseSucceed[{}];
(************************************************************)
(* ParseRecursiveDefinition *)
(************************************************************)
SetAttributes[ParseRecursiveDefinition, HoldAll]
ParseRecursiveDefinition[parserName_Symbol, rhs__] :=
Block[{},
parserName[xs_] := rhs[xs]
];
(************************************************************)
(* Tokenizer *)
(************************************************************)
ToTokens[text_String] := StringSplit[text];
ToTokens[text_String, {}] := StringSplit[text];
ToTokens[text_String, terminals : {_String ...}] :=
StringSplit[StringReplace[text, Map[# -> " " <> # <> " " &, terminals]]];
ToTokens[text_, "EBNF"] :=
ToTokens[text, {"|", ",", ";", "=", "[", "]", "(", ")", "{", "}"}];
Clear[ParseToTokens];
ParseToTokens[text_String, terminalDelimiters_ : {}, whitespaces_ : {" ", "\n"}] :=
Block[{pApplyFunc, pWord, pQWord, pLongTermDelim, pTermDelim, res, procText = Characters[text]},
pWord =
ParseSpaces[
ParseMany1[
ParsePredicate[!MemberQ[Join[terminalDelimiters, whitespaces], #] &]]];
pQWord = ParseSpaces[(ParseSymbol["'"]\[CirclePlus]ParseSymbol["\""])\[CircleTimes]
ParseMany1[ParsePredicate[# != "'" && # != "\"" &]]\[CircleTimes]
(ParseSymbol["'"]\[CirclePlus]ParseSymbol["\""])];
If[Length[Select[terminalDelimiters, StringLength[#] > 1 &]] > 0,
pLongTermDelim =
ParseAlternativeComposition @@
Map[ParseApply[StringJoin,
ParseSequentialComposition @@ (ParseSymbol /@ Characters[#])] &,
Select[terminalDelimiters, StringLength[#] > 1 &]];
pTermDelim =
ParseSpaces[ParsePredicate[MemberQ[terminalDelimiters, #] &]\[CirclePlus]pLongTermDelim],
pTermDelim =
ParseSpaces[ParsePredicate[MemberQ[terminalDelimiters, #] &]]
];
res = ParseMany1[((If[Length[#] > 0, StringJoin @@ #, #]&)\[CircleDot](pQWord\[CirclePlus]pWord))\[CirclePlus]pTermDelim][procText];
res[[1, 2]]
];
ParseToEBNFTokens[text_, whitespaces_ : {" ", "\n", "\t"}] :=
ParseToTokens[text, {"|", "&>", "<&", "<@", ",", ";", "=", "[", "]", "(", ")", "{", "}"}, whitespaces ];
(************************************************************)
(* ParsingTestTable *)
(************************************************************)
Clear[ParsingTestTable];
ParsingTestTable::unval = "Unknown value `2` for the option `1`."
Options[ParsingTestTable] = {FontFamily -> "Times", FontSize -> 16, "Terminals" -> {}, "TokenizerFunction" -> ToTokens, "Layout" -> "Horizontal"};
ParsingTestTable[parser_, statements : {_String ..}, optsArg : OptionsPattern[]] :=
Block[{res, ff = OptionValue[ParsingTestTable, FontFamily],
fs = OptionValue[ParsingTestTable, FontSize],
ts = OptionValue[ParsingTestTable, "Terminals"],
tokenizerFunc = OptionValue[ParsingTestTable, "TokenizerFunction"],
layout = OptionValue[ParsingTestTable, "Layout"], opts, ptbl, vptbl},
opts = {FontFamily -> ff, FontSize -> fs};
If[ TrueQ[tokenizerFunc === ToTokens],
res = Map[parser[ToTokens[#, ts]] &, statements],
res = Map[parser[tokenizerFunc[#]] &, statements]
];
ptbl =
Grid[
Prepend[
MapThread[Prepend, {Transpose[{Map[Style[#, opts] &, statements], res}], Style[#, Darker[Red], opts] & /@ Range[Length[statements]] }],
Style[#, Darker[Red], opts] & /@ {"#", "Statement", "Parser output"}
],
Dividers -> {All, {True, True, Sequence @@ Table[False, {Length[statements] - 1}], True}},
Alignment -> {{Right, Left, Left}}
];
Which[
TrueQ[layout == "Horizontal"], ptbl,
TrueQ[layout == "Vertical"],
ptbl = Transpose[{Map[Style[#, opts] &, statements], res}];
ptbl[[All, 2]] = Map[ If[ TrueQ[# === {}], {{{}, {}}}, #]&, ptbl[[All, 2]] ];
vptbl = Flatten[
Transpose[{statements, ptbl[[All, 2, 1, 2]], ptbl[[All, 2, 1, 1]]}], 1];
vptbl =
Transpose[{Flatten[
Table[{Style[i, Darker[Red], opts], "", ""}, {i, 1, Length[statements]}]],
Style[#, Gray] & /@
Flatten[Table[{"command:", "parsed:", "residual:"}, {Length[vptbl] / 3}]], vptbl}];
Grid[vptbl, Alignment -> {{Right, Right, Left}}, Spacings -> {0.5, 0.75},
Dividers -> {{True, True, False, True},
Join[{True}, Flatten@Table[{False, False, True}, {Length[vptbl]}]]}],
True,
Message[ParsingTestTable::unval, "Layout", layout]; ptbl
]
];
(***************************************************************************)
(* EBNF Parsers with parenthesis and \[RightTriangle] and \[LeftTriangle] *)
(***************************************************************************)
(* All parsers start with the prefix "pG" followed by a capital letter. ("p" is for "parser", "G" is for "grammar".) *)
Clear[EBNFNonTerminal, EBNFTerminal, EBNFOption, EBNFRepetition, EBNFSequence, EBNFAlternatives, EBNFRule, EBNF];
Clear["pG*"];
(* Parse typeTerminal. All teminals are assumed to be between single or double quotes. *)
EBNFSymbolTest =
TrueQ[# == "|" || # == "," || # == "=" || # == ";" || # == "\[LeftTriangle]" || # == "\[RightTriangle]" || # == "<&" || # == "&>" ] &;
NonTerminalTest =
TrueQ[StringMatchQ[#, "<" ~~ (WordCharacter | WhitespaceCharacter | "-" | "_") .. ~~ ">"]] &;
InQuotesTest = TrueQ[StringMatchQ[#, ("'" | "\"") ~~ __ ~~ ("'" | "\"")]] &;
pGTerminal =
ParsePredicate[StringQ[#] && InQuotesTest[#] && ! EBNFSymbolTest[#] &];
(* Parser typeNonTerminal. I prefer the <xxx> format for non-terminals instead of allowing any string without quotes. *)
pGNonTerminal =
ParsePredicate[StringQ[#] && NonTerminalTest[#] && ! EBNFSymbolTest[#] &];
pGOption = EBNFOption\[CircleDot]ParseBracketed[pGExpr];
pGRepetition = EBNFRepetition\[CircleDot]ParseCurlyBracketed[pGExpr];
pGNode[xs_] := (EBNFTerminal\[CircleDot]pGTerminal\[CirclePlus]EBNFNonTerminal\[CircleDot]pGNonTerminal\[CirclePlus]ParseParenthesized[pGExpr]\[CirclePlus]pGRepetition\[CirclePlus]pGOption)[xs];
pGTerm = EBNFSequence\[CircleDot]ParseChainRight[pGNode, ParseSymbol[","]\[CirclePlus]ParseSymbol["\[LeftTriangle]"]\[CirclePlus]ParseSymbol["\[RightTriangle]"]\[CirclePlus]ParseSymbol["<&"]\[CirclePlus]ParseSymbol["&>"]];
pGExpr = EBNFAlternatives\[CircleDot]ParseListOf[pGTerm, ParseSymbol["|"]];
pGRule = EBNFRule\[CircleDot](pGNonTerminal\[CircleTimes](ParseSymbol["="] \[RightTriangle] pGExpr)\[CircleTimes](ParseSymbol[";"]\[CirclePlus](ParseSymbol["<@"]\[CircleTimes]ParsePredicate[StringQ[#] &] \[LeftTriangle] ParseSymbol[";"])));
pEBNF = EBNF\[CircleDot]ParseMany1[pGRule];
(********************************************************************************)
(* EBNF grammar parser generators with \[RightTriangle] and \[LeftTriangle] *)
(********************************************************************************)
Clear[EBNFMakeSymbolName, EBNFNonTerminal, EBNFTerminalInterpreter, EBNFOptionInterpreter, EBNFRepetitionInterpreter,
EBNFSequenceInterpreter, EBNFAlternativesInterpreter, EBNFRuleInterpreter];
Clear[pNumber, pInteger, pWord, pLetterWord, pIdentifierWord];
pNumber = ToExpression\[CircleDot]ParsePredicate[StringMatchQ[#, NumberString] &];
pInteger = ToExpression\[CircleDot]ParsePredicate[StringMatchQ[#, (DigitCharacter..) | (( "+" | "-" ) ~~ (DigitCharacter..))] &];
pWord = ParsePredicate[StringMatchQ[#, (WordCharacter | "_") ..] &];
pLetterWord = ParsePredicate[StringMatchQ[#, LetterCharacter ..] &];
pIdentifierWord = ParsePredicate[StringMatchQ[#, LetterCharacter ~~ (WordCharacter ... )] &];
Clear[pNumberRange];
pNumberRange[{s_?NumberQ, e_?NumberQ}] :=
ToExpression\[CircleDot]ParsePredicate[StringMatchQ[#, NumberString] && s <= ToExpression[#] <= e &];
EBNFMakeSymbolName[p_String] :=
"p" <> ToUpperCase[StringReplace[p, {"<" -> "", ">" -> "", "_" -> "", "-" -> ""}]];
EBNFTerminalInterpreter[parsed_] :=
Which[
StringMatchQ[parsed, ("'" | "\"") ~~ "_?NumberQ" ~~ ("'" | "\"")],
pNumber,
StringMatchQ[parsed, ("'" | "\"") ~~ "_?IntegerQ" ~~ ("'" | "\"")],
pInteger,
StringMatchQ[
parsed, ("'" | "\"") ~~ "Range[" ~~ NumberString ~~ "," ~~ NumberString ~~ "]" ~~ ("'" | "\"")],
pNumberRange[
Flatten@StringCases[
parsed, ("'" | "\"") ~~ "Range[" ~~ (s : NumberString) ~~ "," ~~ (e : NumberString) ~~ "]" ~~ ("'" | "\"") :> Map[ToExpression, {s, e}]]],
parsed == "\"_String\"" || parsed == "'_String'",
ParsePredicate[StringQ[#] &],
parsed == "\"_WordString\"" || parsed == "'_WordString'", pWord,
parsed == "\"_LetterString\"" || parsed == "'_LetterString'", pLetterWord,
parsed == "\"_IdentifierString\"" || parsed == "'_IdentifierString'", pIdentifierWord,
True, ParseSymbol[
If[StringMatchQ[parsed, ("'" | "\"") ~~ ___ ~~ ("'" | "\"")],
StringTake[parsed, {2, -2}], parsed]]
];
EBNFNonTerminalInterpreter[parsed_] := ToExpression[EBNFMakeSymbolName[parsed]];
EBNFRepetitionInterpreter[parsed_] := ParseMany1[parsed];
EBNFOptionInterpreter[parsed_] := ParseOption1[parsed];
EBNFSequenceInterpreter[parsedArg_] :=
Block[{parsed = parsedArg, crules},
(*Print["before:",parsed];*)
crules = {ParseSymbol[","] -> "X$$#$#$#1",
ParseSymbol["\[LeftTriangle]"] -> "X$$#$#$#2", ParseSymbol["<&"] -> "X$$#$#$#2",
ParseSymbol["\[RightTriangle]"] -> "X$$#$#$#3", ParseSymbol["&>"] -> "X$$#$#$#3"};
parsed = parsed //. crules;
(*Print["mid:",parsed];*)
parsed = parsed /. {"," -> ParseSequentialComposition,
"\[LeftTriangle]" -> ParseSequentialCompositionPickLeft, "<&" -> ParseSequentialCompositionPickLeft,
"\[RightTriangle]" -> ParseSequentialCompositionPickRight, "&>" -> ParseSequentialCompositionPickRight};
parsed = parsed //. (Reverse /@ crules);
(*Print["after:",parsed];*)
Which[
! ListQ[parsed], parsed,
Length[parsed] == 1, parsed[[1]],
True, ParseSequentialComposition @@ parsed
]
];
EBNFAlternativesInterpreter[parsed_] :=
Which[
! ListQ[parsed], parsed,
Length[parsed] == 1, parsed[[1]],
True, ParseAlternativeComposition @@ parsed
];
EBNFRuleInterpreter[parsed_] :=
Block[{lhsSymbolName, lhsSymbol, res},
lhsSymbolName = EBNFMakeSymbolName[parsed[[1, 1]]];
With[{sn = lhsSymbolName}, Clear[sn]];
lhsSymbol = ToExpression[lhsSymbolName];
(*Print[lhsSymbol];*)
If[ListQ[parsed[[2]]],
With[{lhs = lhsSymbol, rhs = parsed[[1, 2]], func = parsed[[2, 2]]},
lhs[xs_] := ParseApply[ToExpression[func], rhs][xs]];
res = Row[{lhsSymbolName, " = ", parsed[[1, 2]], parsed[[2, 1]], parsed[[2, 2]]}],
(* assumed Length[parsed] == 2*)
With[{lhs = lhsSymbol, rhs = parsed[[1, 2]]}, lhs[xs_] := rhs[xs]];
res = Row[{lhsSymbolName, " = ", parsed[[1, 2]]}]
];
res
];
(************************************************************)
(* Parser definition modification *)
(************************************************************)
(* one downvalue per parser is assumed *)
Clear[AddParserModifier];
AddParserModifier[parser_Symbol, func_] :=
Block[{dvs = Cases[DownValues[parser], _RuleDelayed]},
If[Length[dvs] == 0, {},
With[{parserBody = dvs[[1, 2, 0]], parserVar = dvs[[1, 1, 1, 1, 1]]},
DownValues[
parser] = {dvs[[1, 1]] :> ParseApply[func, parserBody][parserVar]}
]
]
];
Clear[SetParserModifier];
SetParserModifier[parser_Symbol, func_] :=
Block[{dvs = Cases[DownValues[parser], _RuleDelayed]},
Which[
Length[dvs] == 0, {},
Length[dvs] > 0 && Head[dvs[[1, 2, 0]]] === ParseApply,
DownValues[parser] = {ReplacePart[dvs, {1, 2, 0, 1} -> func]},
True,
AddParserModifier[parser, func]
]
];
(************************************************************)
(* Interpretation *)
(************************************************************)
EBNFContextRules =
{EBNFNonTerminal -> EBNFNonTerminalInterpreter,
EBNFTerminal -> EBNFTerminalInterpreter,
EBNFOption -> EBNFOptionInterpreter,
EBNFRepetition -> EBNFRepetitionInterpreter,
EBNFSequence -> EBNFSequenceInterpreter,
EBNFAlternatives -> EBNFAlternativesInterpreter,
EBNFRule -> EBNFRuleInterpreter};
Clear[InterpretWithContext];
InterpretWithContext[parsed_, contextRules : {_Rule ...}] :=
Block[{},
{parsed /. contextRules, {} }
];
InterpretWithContext[parsed_, contextRules : {"data" -> {}, "functions" -> {(_Symbol -> _) ...}}] :=
InterpretWithContext[parsed, "functions" /. contextRules];
InterpretWithContext[parsed_, contextRules : {"data" -> {(_Symbol -> _) ..}, "functions" -> {(_Symbol -> _) ...}}] :=
Block[{dataVars, res, newData},
dataVars = ("data" /. contextRules)[[All, 1]];
{res, newData} =
Block[Evaluate[dataVars],
Do[
Evaluate[r[[1]]] = r[[2]]
, {r, ("data" /. contextRules)}];
{parsed /. ("functions" /. contextRules), dataVars}
];
{res, Thread[dataVars -> newData]}
];
ParseEBNF[code_] := pEBNF[code];
GenerateParsersFromEBNF[code_] := InterpretWithContext[ pEBNF[code], EBNFContextRules ];
(************************************************************)
(* Random sentences *)
(************************************************************)
Clear[GrammarNormalize];
GrammarNormalize[ebnf_String] := StringReplace[ebnf, {"&>" -> ",", "<&" -> ",", ("<@" ~~ (Except[{">", "<"}] ..) ~~ ";") :> ";"}];
GrammarNormalize[___] := $Failure;
(* Random sentences generator from EBNF grammar (rule based) *)
Clear[RGMakeSymbolName, RGNonTerminal, RGTerminal, RGOption, RGRepetition,
RGSequence, RGAlternatives, RGRule, EBNF];
Clear[rgInteger, rgNumber, rgString, rgLetterString];
rgInteger := ToString[RandomInteger[{0, 1000}]];
rgNumber := ToString[RandomReal[{0, 1000}]];
rgNumberRange[{s_?NumberQ, e_?NumberQ}] := ToString[RandomInteger[{s, e}]];
rgString := StringJoin @@ RandomSample[Join[CharacterRange["0", "9"], CharacterRange["a", "z"]], RandomInteger[{3, 10}]];
rgLetterString := StringJoin @@ RandomSample[CharacterRange["a", "z"], RandomInteger[{3, 10}]];
RGTerminal[parsed_] :=
Which[
StringMatchQ[parsed, ("'" | "\"") ~~ "_?IntegerQ" ~~ ("'" | "\"")],
rgInteger,
StringMatchQ[parsed, ("'" | "\"") ~~ "_?NumberQ" ~~ ("'" | "\"")],
rgNumber,
StringMatchQ[parsed, ("'" | "\"") ~~ "Range[" ~~ NumberString ~~ "," ~~ NumberString ~~ "]" ~~ ("'" | "\"")],
rgNumberRange[Flatten@
StringCases[parsed, ("'" | "\"") ~~ "Range[" ~~ (s : NumberString) ~~ "," ~~ (e : NumberString) ~~ "]" ~~ ("'" | "\"") :> Map[ToExpression, {s, e}]]],
parsed == "\"_String\"" || parsed == "'_String'" || parsed == "\"_?StringQ\"" || parsed == "'_?StringQ'",
rgString,
parsed == "\"_WordString\"" || parsed == "'_WordString'",
rgString,
parsed == "\"_LetterString\"" || parsed == "'_LetterString'",
rgLetterString,
parsed == "\"_IdentifierString\"" || parsed == "'_IdentifierString'",
rgLetterString,
True,
If[StringMatchQ[parsed, ("'" | "\"") ~~ ___ ~~ ("'" | "\"")], StringTake[parsed, {2, -2}], parsed]
];
RGNonTerminal[parsed_] := parsed;
RGRepetition[parsed_] := Flatten@Table[parsed, {RandomInteger[{1, 5}]}];
RGOption[parsed_] := If[RandomInteger[{0, 1}] == 0, parsed, ""];
RGSequence[parsed_] :=
Which[
! ListQ[parsed], parsed,
Length[parsed] == 1, parsed[[1]],
True, parsed
];
$RGAlternativesRecursionLimit = 50;
$RGAlternativesRecursionLevel = 0;
RGAlternatives[parsed_] :=
Block[{},
$RGAlternativesRecursionLevel++;
Which[
$RGAlternativesRecursionLevel > $RGAlternativesRecursionLimit,
RandomChoice[Flatten[Cases[parsed, _String, Infinity]]],
! ListQ[parsed], parsed,
Length[parsed] == 1, parsed[[1]],
True, RandomChoice[parsed]
]
];
MakeNonTerminalReplacementRules[parsedEBNFRules_] :=
Cases[parsedEBNFRules, {s_String, rhs_} :> (EBNFNonTerminal[s] -> rhs), Infinity];
Clear[RGSentence];
RGSentence[parsedEBNF_EBNF, recursionLimit : (_Integer | Automatic | Infinity ) : 20] :=
Block[{parsedEBNFRules = parsedEBNF[[1]], rrules, rrulesRest, dRRulesRest, EBNFToRGRules, t},
EBNFToRGRules =
Dispatch[Thread[{EBNFTerminal, EBNFOption, EBNFRepetition, EBNFSequence} -> {RGTerminal, RGOption, RGRepetition, RGSequence}]];
rrules = Cases[parsedEBNFRules, {s_String, rhs_} :> (EBNFNonTerminal[s] -> rhs), Infinity];
rrulesRest = Rest[rrules];
dRRulesRest = Dispatch[rrulesRest];
rrulesRest[[All, 2]] = rrulesRest[[All, 2]] /. dRRulesRest;
PRINT["1.", rrulesRest[[All, 2]]];
rrulesRest[[All, 2]] = rrulesRest[[All, 2]] /. EBNFToRGRules;
PRINT["2.", rrulesRest[[All, 2]]];
If[ IntegerQ[recursionLimit],
Do[
rrulesRest[[All, 2]] = rrulesRest[[All, 2]] /. dRRulesRest,
{i, 0, recursionLimit}
],
(*ELSE*)
rrulesRest[[All, 2]] = rrulesRest[[All, 2]] //. dRRulesRest
];
PRINT["3.", rrulesRest];
$RGAlternativesRecursionLimit = If[ NumericQ[recursionLimit], recursionLimit, $RecursionLimit];
$RGAlternativesRecursionLevel = 0;
t = Flatten@List[(First[rrules][[2]] /. Dispatch[rrulesRest]) /. EBNFToRGRules //. EBNFAlternatives[s___] :> RGAlternatives[s]];
PRINT["t=", t];
(*StringTrim[StringReplace[StringJoin@@Riffle[Which[Head[t]\[Equal]",",
List@@t,!ListQ[t],{t},True,Flatten[t]]," "]," "\[Rule]" "]]*)
t = Flatten@List[t //. (","[x__] :> {x})];
StringTrim[StringReplace[StringRiffle[t, " "], (WhitespaceCharacter ~~ WhitespaceCharacter ..) -> " "]]
];
Clear[GrammarRandomSentences];
GrammarRandomSentences::nargs = "The first argument is expected to be a string (with a grammar in EBNF). \
The second argument is expected to be a positive integer.";
Options[GrammarRandomSentences] = {"RecursionLimit" -> Automatic};
GrammarRandomSentences[ebnfGrammar_String, n_Integer, opts : OptionsPattern[]] :=
Block[{recursionLimit, EBNFMakeSymbolName, EBNFNonTerminal, EBNFTerminal, EBNFOption,
EBNFRepetition, EBNFSequence, EBNFAlternatives, EBNFRule, tokens, res},
recursionLimit = OptionValue[GrammarRandomSentences, "RecursionLimit"];
If[ !NumericQ[recursionLimit] && !MemberQ[{Automatic, Infinity}, recursionLimit],
recursionLimit = 20
];
If[ NumericQ[recursionLimit],
recursionLimit = Ceiling[recursionLimit]
];
Clear[EBNFMakeSymbolName, EBNFNonTerminal, EBNFTerminal, EBNFOption,
EBNFRepetition, EBNFSequence, EBNFAlternatives, EBNFRule];
tokens = ParseToEBNFTokens[ebnfGrammar];
(*res=ParseJust[pEBNF][tokens];*)
res = ParseEBNF[tokens];
Table[RGSentence[res[[1, 2]], recursionLimit], {n}]
] /; n > 0;
GrammarRandomSentences[parsedEBNFRules_EBNF, n_Integer] :=
Block[{},
Table[RGSentence[parsedEBNFRules], {n}]
];
GrammarRandomSentences[___] :=
Block[{},
Message[GrammarRandomSentences::nargs];
$Failed
];
End[];
EndPackage[]