lib/Parser/expr-parsers.cpp - llvm-project/flang - Git at Google

 //===-- lib/Parser/expr-parsers.cpp ---------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 // Per-type parsers for expressions.

 #include "expr-parsers.h"
 #include "basic-parsers.h"
 #include "debug-parser.h"
 #include "misc-parsers.h"
 #include "stmt-parser.h"
 #include "token-parsers.h"
 #include "type-parser-implementation.h"
 #include "flang/Parser/characters.h"
 #include "flang/Parser/parse-tree.h"

 namespace Fortran::parser {

 // R764 boz-literal-constant -> binary-constant | octal-constant | hex-constant
 // R765 binary-constant -> B ' digit [digit]... ' | B " digit [digit]... "
 // R766 octal-constant -> O ' digit [digit]... ' | O " digit [digit]... "
 // R767 hex-constant ->
 //        Z ' hex-digit [hex-digit]... ' | Z " hex-digit [hex-digit]... "
 // extension: X accepted for Z
 // extension: BOZX suffix accepted
 TYPE_PARSER(construct<BOZLiteralConstant>(BOZLiteral{}))

 // R769 array-constructor -> (/ ac-spec /) | lbracket ac-spec rbracket
 TYPE_CONTEXT_PARSER("array constructor"_en_US,
     construct<ArrayConstructor>(
         "(/" >> Parser<AcSpec>{} / "/)" || bracketed(Parser<AcSpec>{})))

 // R770 ac-spec -> type-spec :: | [type-spec ::] ac-value-list
 TYPE_PARSER(construct<AcSpec>(maybe(typeSpec / "::"),
                 nonemptyList("expected array constructor values"_err_en_US,
                     Parser<AcValue>{})) ||
     construct<AcSpec>(typeSpec / "::"))

 // R773 ac-value -> expr | ac-implied-do
 TYPE_PARSER(
     // PGI/Intel extension: accept triplets in array constructors
     extension<LanguageFeature::TripletInArrayConstructor>(
         construct<AcValue>(construct<AcValue::Triplet>(scalarIntExpr,
             ":" >> scalarIntExpr, maybe(":" >> scalarIntExpr)))) ||
     construct<AcValue>(indirect(expr)) ||
     construct<AcValue>(indirect(Parser<AcImpliedDo>{})))

 // R774 ac-implied-do -> ( ac-value-list , ac-implied-do-control )
 TYPE_PARSER(parenthesized(
     construct<AcImpliedDo>(nonemptyList(Parser<AcValue>{} / lookAhead(","_tok)),
         "," >> Parser<AcImpliedDoControl>{})))

 // R775 ac-implied-do-control ->
 //        [integer-type-spec ::] ac-do-variable = scalar-int-expr ,
 //        scalar-int-expr [, scalar-int-expr]
 // R776 ac-do-variable -> do-variable
 TYPE_PARSER(construct<AcImpliedDoControl>(
     maybe(integerTypeSpec / "::"), loopBounds(scalarIntExpr)))

 // R1001 primary ->
 //         literal-constant | designator | array-constructor |
 //         structure-constructor | function-reference | type-param-inquiry |
 //         type-param-name | ( expr )
 // N.B. type-param-inquiry is parsed as a structure component
 constexpr auto primary{instrumented("primary"_en_US,
     first(construct<Expr>(indirect(Parser<CharLiteralConstantSubstring>{})),
         construct<Expr>(literalConstant),
         construct<Expr>(construct<Expr::Parentheses>(parenthesized(expr))),
         construct<Expr>(indirect(functionReference) / !"("_tok),
         construct<Expr>(designator / !"("_tok),
         construct<Expr>(Parser<StructureConstructor>{}),
         construct<Expr>(Parser<ArrayConstructor>{}),
         // PGI/XLF extension: COMPLEX constructor (x,y)
         extension<LanguageFeature::ComplexConstructor>(
             construct<Expr>(parenthesized(
                 construct<Expr::ComplexConstructor>(expr, "," >> expr)))),
         extension<LanguageFeature::PercentLOC>(construct<Expr>("%LOC" >>
             parenthesized(construct<Expr::PercentLoc>(indirect(variable)))))))};

 // R1002 level-1-expr -> [defined-unary-op] primary
 // TODO: Reasonable extension: permit multiple defined-unary-ops
 constexpr auto level1Expr{sourced(
     first(primary, // must come before define op to resolve .TRUE._8 ambiguity
         construct<Expr>(construct<Expr::DefinedUnary>(definedOpName, primary)),
         extension<LanguageFeature::SignedPrimary>(
             construct<Expr>(construct<Expr::UnaryPlus>("+" >> primary))),
         extension<LanguageFeature::SignedPrimary>(
             construct<Expr>(construct<Expr::Negate>("-" >> primary)))))};

 // R1004 mult-operand -> level-1-expr [power-op mult-operand]
 // R1007 power-op -> **
 // Exponentiation (**) is Fortran's only right-associative binary operation.
 struct MultOperand {
   using resultType = Expr;
   constexpr MultOperand() {}
   static inline std::optional<Expr> Parse(ParseState &);
 };

 static constexpr auto multOperand{sourced(MultOperand{})};

 inline std::optional<Expr> MultOperand::Parse(ParseState &state) {
   std::optional<Expr> result{level1Expr.Parse(state)};
   if (result) {
     static constexpr auto op{attempt("**"_tok)};
     if (op.Parse(state)) {
       std::function<Expr(Expr &&)> power{[&result](Expr &&right) {
         return Expr{Expr::Power(std::move(result).value(), std::move(right))};
       }};
       return applyLambda(power, multOperand).Parse(state); // right-recursive
     }
   }
   return result;
 }

 // R1005 add-operand -> [add-operand mult-op] mult-operand
 // R1008 mult-op -> * | /
 // The left recursion in the grammar is implemented iteratively.
 struct AddOperand {
   using resultType = Expr;
   constexpr AddOperand() {}
   static inline std::optional<Expr> Parse(ParseState &state) {
     std::optional<Expr> result{multOperand.Parse(state)};
     if (result) {
       auto source{result->source};
       std::function<Expr(Expr &&)> multiply{[&result](Expr &&right) {
         return Expr{
             Expr::Multiply(std::move(result).value(), std::move(right))};
       }};
       std::function<Expr(Expr &&)> divide{[&result](Expr &&right) {
         return Expr{Expr::Divide(std::move(result).value(), std::move(right))};
       }};
       auto more{attempt(sourced("*" >> applyLambda(multiply, multOperand) ||
           "/" >> applyLambda(divide, multOperand)))};
       while (std::optional<Expr> next{more.Parse(state)}) {
         result = std::move(next);
         result->source.ExtendToCover(source);
       }
     }
     return result;
   }
 };
 constexpr AddOperand addOperand;

 // R1006 level-2-expr -> [[level-2-expr] add-op] add-operand
 // R1009 add-op -> + | -
 // These are left-recursive productions, implemented iteratively.
 // Note that standard Fortran admits a unary + or - to appear only here,
 // by means of a missing first operand; e.g., 2*-3 is valid in C but not
 // standard Fortran.  We accept unary + and - to appear before any primary
 // as an extension.
 struct Level2Expr {
   using resultType = Expr;
   constexpr Level2Expr() {}
   static inline std::optional<Expr> Parse(ParseState &state) {
     static constexpr auto unary{
         sourced(
             construct<Expr>(construct<Expr::UnaryPlus>("+" >> addOperand)) ||
             construct<Expr>(construct<Expr::Negate>("-" >> addOperand))) ||
         addOperand};
     std::optional<Expr> result{unary.Parse(state)};
     if (result) {
       auto source{result->source};
       std::function<Expr(Expr &&)> add{[&result](Expr &&right) {
         return Expr{Expr::Add(std::move(result).value(), std::move(right))};
       }};
       std::function<Expr(Expr &&)> subtract{[&result](Expr &&right) {
         return Expr{
             Expr::Subtract(std::move(result).value(), std::move(right))};
       }};
       auto more{attempt(sourced("+" >> applyLambda(add, addOperand) ||
           "-" >> applyLambda(subtract, addOperand)))};
       while (std::optional<Expr> next{more.Parse(state)}) {
         result = std::move(next);
         result->source.ExtendToCover(source);
       }
     }
     return result;
   }
 };
 constexpr Level2Expr level2Expr;

 // R1010 level-3-expr -> [level-3-expr concat-op] level-2-expr
 // R1011 concat-op -> //
 // Concatenation (//) is left-associative for parsing performance, although
 // one would never notice if it were right-associated.
 struct Level3Expr {
   using resultType = Expr;
   constexpr Level3Expr() {}
   static inline std::optional<Expr> Parse(ParseState &state) {
     std::optional<Expr> result{level2Expr.Parse(state)};
     if (result) {
       auto source{result->source};
       std::function<Expr(Expr &&)> concat{[&result](Expr &&right) {
         return Expr{Expr::Concat(std::move(result).value(), std::move(right))};
       }};
       auto more{attempt(sourced("//" >> applyLambda(concat, level2Expr)))};
       while (std::optional<Expr> next{more.Parse(state)}) {
         result = std::move(next);
         result->source.ExtendToCover(source);
       }
     }
     return result;
   }
 };
 constexpr Level3Expr level3Expr;

 // R1012 level-4-expr -> [level-3-expr rel-op] level-3-expr
 // R1013 rel-op ->
 //         .EQ. | .NE. | .LT. | .LE. | .GT. | .GE. |
 //          == | /= | < | <= | > | >=  @ | <>
 // N.B. relations are not recursive (i.e., LOGICAL is not ordered)
 struct Level4Expr {
   using resultType = Expr;
   constexpr Level4Expr() {}
   static inline std::optional<Expr> Parse(ParseState &state) {
     std::optional<Expr> result{level3Expr.Parse(state)};
     if (result) {
       auto source{result->source};
       std::function<Expr(Expr &&)> lt{[&result](Expr &&right) {
         return Expr{Expr::LT(std::move(result).value(), std::move(right))};
       }};
       std::function<Expr(Expr &&)> le{[&result](Expr &&right) {
         return Expr{Expr::LE(std::move(result).value(), std::move(right))};
       }};
       std::function<Expr(Expr &&)> eq{[&result](Expr &&right) {
         return Expr{Expr::EQ(std::move(result).value(), std::move(right))};
       }};
       std::function<Expr(Expr &&)> ne{[&result](Expr &&right) {
         return Expr{Expr::NE(std::move(result).value(), std::move(right))};
       }};
       std::function<Expr(Expr &&)> ge{[&result](Expr &&right) {
         return Expr{Expr::GE(std::move(result).value(), std::move(right))};
       }};
       std::function<Expr(Expr &&)> gt{[&result](Expr &&right) {
         return Expr{Expr::GT(std::move(result).value(), std::move(right))};
       }};
       auto more{attempt(
           sourced((".LT."_tok || "<"_tok) >> applyLambda(lt, level3Expr) ||
               (".LE."_tok || "<="_tok) >> applyLambda(le, level3Expr) ||
               (".EQ."_tok || "=="_tok) >> applyLambda(eq, level3Expr) ||
               (".NE."_tok || "/="_tok ||
                   extension<LanguageFeature::AlternativeNE>(
                       "<>"_tok /* PGI/Cray extension; Cray also has .LG. */)) >>
                   applyLambda(ne, level3Expr) ||
               (".GE."_tok || ">="_tok) >> applyLambda(ge, level3Expr) ||
               (".GT."_tok || ">"_tok) >> applyLambda(gt, level3Expr)))};
       if (std::optional<Expr> next{more.Parse(state)}) {
         next->source.ExtendToCover(source);
         return next;
       }
     }
     return result;
   }
 };
 constexpr Level4Expr level4Expr;

 // R1014 and-operand -> [not-op] level-4-expr
 // R1018 not-op -> .NOT.
 // N.B. Fortran's .NOT. binds less tightly than its comparison operators do.
 // PGI/Intel extension: accept multiple .NOT. operators
 struct AndOperand {
   using resultType = Expr;
   constexpr AndOperand() {}
   static inline std::optional<Expr> Parse(ParseState &);
 };
 constexpr AndOperand andOperand;

 // Match a logical operator or, optionally, its abbreviation.
 inline constexpr auto logicalOp(const char *op, const char *abbrev) {
   return TokenStringMatch{op} ||
       extension<LanguageFeature::LogicalAbbreviations>(
           TokenStringMatch{abbrev});
 }

 inline std::optional<Expr> AndOperand::Parse(ParseState &state) {
   static constexpr auto notOp{attempt(logicalOp(".NOT.", ".N.") >> andOperand)};
   if (std::optional<Expr> negation{notOp.Parse(state)}) {
     return Expr{Expr::NOT{std::move(*negation)}};
   } else {
     return level4Expr.Parse(state);
   }
 }

 // R1015 or-operand -> [or-operand and-op] and-operand
 // R1019 and-op -> .AND.
 // .AND. is left-associative
 struct OrOperand {
   using resultType = Expr;
   constexpr OrOperand() {}
   static inline std::optional<Expr> Parse(ParseState &state) {
     static constexpr auto operand{sourced(andOperand)};
     std::optional<Expr> result{operand.Parse(state)};
     if (result) {
       auto source{result->source};
       std::function<Expr(Expr &&)> logicalAnd{[&result](Expr &&right) {
         return Expr{Expr::AND(std::move(result).value(), std::move(right))};
       }};
       auto more{attempt(sourced(
           logicalOp(".AND.", ".A.") >> applyLambda(logicalAnd, andOperand)))};
       while (std::optional<Expr> next{more.Parse(state)}) {
         result = std::move(next);
         result->source.ExtendToCover(source);
       }
     }
     return result;
   }
 };
 constexpr OrOperand orOperand;

 // R1016 equiv-operand -> [equiv-operand or-op] or-operand
 // R1020 or-op -> .OR.
 // .OR. is left-associative
 struct EquivOperand {
   using resultType = Expr;
   constexpr EquivOperand() {}
   static inline std::optional<Expr> Parse(ParseState &state) {
     std::optional<Expr> result{orOperand.Parse(state)};
     if (result) {
       auto source{result->source};
       std::function<Expr(Expr &&)> logicalOr{[&result](Expr &&right) {
         return Expr{Expr::OR(std::move(result).value(), std::move(right))};
       }};
       auto more{attempt(sourced(
           logicalOp(".OR.", ".O.") >> applyLambda(logicalOr, orOperand)))};
       while (std::optional<Expr> next{more.Parse(state)}) {
         result = std::move(next);
         result->source.ExtendToCover(source);
       }
     }
     return result;
   }
 };
 constexpr EquivOperand equivOperand;

 // R1017 level-5-expr -> [level-5-expr equiv-op] equiv-operand
 // R1021 equiv-op -> .EQV. | .NEQV.
 // Logical equivalence is left-associative.
 // Extension: .XOR. as synonym for .NEQV.
 struct Level5Expr {
   using resultType = Expr;
   constexpr Level5Expr() {}
   static inline std::optional<Expr> Parse(ParseState &state) {
     std::optional<Expr> result{equivOperand.Parse(state)};
     if (result) {
       auto source{result->source};
       std::function<Expr(Expr &&)> eqv{[&result](Expr &&right) {
         return Expr{Expr::EQV(std::move(result).value(), std::move(right))};
       }};
       std::function<Expr(Expr &&)> neqv{[&result](Expr &&right) {
         return Expr{Expr::NEQV(std::move(result).value(), std::move(right))};
       }};
       auto more{attempt(sourced(".EQV." >> applyLambda(eqv, equivOperand) ||
           (".NEQV."_tok ||
               extension<LanguageFeature::XOROperator>(
                   logicalOp(".XOR.", ".X."))) >>
               applyLambda(neqv, equivOperand)))};
       while (std::optional<Expr> next{more.Parse(state)}) {
         result = std::move(next);
         result->source.ExtendToCover(source);
       }
     }
     return result;
   }
 };
 constexpr Level5Expr level5Expr;

 // R1022 expr -> [expr defined-binary-op] level-5-expr
 // Defined binary operators associate leftwards.
 template <> std::optional<Expr> Parser<Expr>::Parse(ParseState &state) {
   std::optional<Expr> result{level5Expr.Parse(state)};
   if (result) {
     auto source{result->source};
     std::function<Expr(DefinedOpName &&, Expr &&)> defBinOp{
         [&result](DefinedOpName &&op, Expr &&right) {
           return Expr{Expr::DefinedBinary(
               std::move(op), std::move(result).value(), std::move(right))};
         }};
     auto more{attempt(
         sourced(applyLambda<Expr>(defBinOp, definedOpName, level5Expr)))};
     while (std::optional<Expr> next{more.Parse(state)}) {
       result = std::move(next);
       result->source.ExtendToCover(source);
     }
   }
   return result;
 }

 // R1003 defined-unary-op -> . letter [letter]... .
 // R1023 defined-binary-op -> . letter [letter]... .
 // R1414 local-defined-operator -> defined-unary-op | defined-binary-op
 // R1415 use-defined-operator -> defined-unary-op | defined-binary-op
 // C1003 A defined operator must be distinct from logical literal constants
 // and intrinsic operator names; this is handled by attempting their parses
 // first, and by name resolution on their definitions, for best errors.
 // N.B. The name of the operator is captured with the dots around it.
 constexpr auto definedOpNameChar{
     letter || extension<LanguageFeature::PunctuationInNames>("$@"_ch)};
 TYPE_PARSER(
     space >> construct<DefinedOpName>(sourced("."_ch >>
                  some(definedOpNameChar) >> construct<Name>() / "."_ch)))

 // R1028 specification-expr -> scalar-int-expr
 TYPE_PARSER(construct<SpecificationExpr>(scalarIntExpr))

 // R1032 assignment-stmt -> variable = expr
 TYPE_CONTEXT_PARSER("assignment statement"_en_US,
     construct<AssignmentStmt>(variable / "=", expr))

 // R1033 pointer-assignment-stmt ->
 //         data-pointer-object [( bounds-spec-list )] => data-target |
 //         data-pointer-object ( bounds-remapping-list ) => data-target |
 //         proc-pointer-object => proc-target
 // R1034 data-pointer-object ->
 //         variable-name | scalar-variable % data-pointer-component-name
 //   C1022 a scalar-variable shall be a data-ref
 //   C1024 a data-pointer-object shall not be a coindexed object
 // R1038 proc-pointer-object -> proc-pointer-name | proc-component-ref
 //
 // A distinction can't be made at the time of the initial parse between
 // data-pointer-object and proc-pointer-object, or between data-target
 // and proc-target.
 TYPE_CONTEXT_PARSER("pointer assignment statement"_en_US,
     construct<PointerAssignmentStmt>(dataRef,
         parenthesized(nonemptyList(Parser<BoundsRemapping>{})), "=>" >> expr) ||
         construct<PointerAssignmentStmt>(dataRef,
             defaulted(parenthesized(nonemptyList(Parser<BoundsSpec>{}))),
             "=>" >> expr))

 // R1035 bounds-spec -> lower-bound-expr :
 TYPE_PARSER(construct<BoundsSpec>(boundExpr / ":"))

 // R1036 bounds-remapping -> lower-bound-expr : upper-bound-expr
 TYPE_PARSER(construct<BoundsRemapping>(boundExpr / ":", boundExpr))

 // R1039 proc-component-ref -> scalar-variable % procedure-component-name
 //   C1027 the scalar-variable must be a data-ref without coindices.
 TYPE_PARSER(construct<ProcComponentRef>(structureComponent))

 // R1041 where-stmt -> WHERE ( mask-expr ) where-assignment-stmt
 // R1045 where-assignment-stmt -> assignment-stmt
 // R1046 mask-expr -> logical-expr
 TYPE_CONTEXT_PARSER("WHERE statement"_en_US,
     construct<WhereStmt>("WHERE" >> parenthesized(logicalExpr), assignmentStmt))

 // R1042 where-construct ->
 //         where-construct-stmt [where-body-construct]...
 //         [masked-elsewhere-stmt [where-body-construct]...]...
 //         [elsewhere-stmt [where-body-construct]...] end-where-stmt
 TYPE_CONTEXT_PARSER("WHERE construct"_en_US,
     construct<WhereConstruct>(statement(Parser<WhereConstructStmt>{}),
         many(whereBodyConstruct),
         many(construct<WhereConstruct::MaskedElsewhere>(
             statement(Parser<MaskedElsewhereStmt>{}),
             many(whereBodyConstruct))),
         maybe(construct<WhereConstruct::Elsewhere>(
             statement(Parser<ElsewhereStmt>{}), many(whereBodyConstruct))),
         statement(Parser<EndWhereStmt>{})))

 // R1043 where-construct-stmt -> [where-construct-name :] WHERE ( mask-expr )
 TYPE_CONTEXT_PARSER("WHERE construct statement"_en_US,
     construct<WhereConstructStmt>(
         maybe(name / ":"), "WHERE" >> parenthesized(logicalExpr)))

 // R1044 where-body-construct ->
 //         where-assignment-stmt | where-stmt | where-construct
 TYPE_PARSER(construct<WhereBodyConstruct>(statement(assignmentStmt)) ||
     construct<WhereBodyConstruct>(statement(whereStmt)) ||
     construct<WhereBodyConstruct>(indirect(whereConstruct)))

 // R1047 masked-elsewhere-stmt ->
 //         ELSEWHERE ( mask-expr ) [where-construct-name]
 TYPE_CONTEXT_PARSER("masked ELSEWHERE statement"_en_US,
     construct<MaskedElsewhereStmt>(
         "ELSE WHERE" >> parenthesized(logicalExpr), maybe(name)))

 // R1048 elsewhere-stmt -> ELSEWHERE [where-construct-name]
 TYPE_CONTEXT_PARSER("ELSEWHERE statement"_en_US,
     construct<ElsewhereStmt>("ELSE WHERE" >> maybe(name)))

 // R1049 end-where-stmt -> ENDWHERE [where-construct-name]
 TYPE_CONTEXT_PARSER("END WHERE statement"_en_US,
     construct<EndWhereStmt>(
         recovery("END WHERE" >> maybe(name), endStmtErrorRecovery)))

 // R1050 forall-construct ->
 //         forall-construct-stmt [forall-body-construct]... end-forall-stmt
 TYPE_CONTEXT_PARSER("FORALL construct"_en_US,
     construct<ForallConstruct>(statement(Parser<ForallConstructStmt>{}),
         many(Parser<ForallBodyConstruct>{}),
         statement(Parser<EndForallStmt>{})))

 // R1051 forall-construct-stmt ->
 //         [forall-construct-name :] FORALL concurrent-header
 TYPE_CONTEXT_PARSER("FORALL construct statement"_en_US,
     construct<ForallConstructStmt>(
         maybe(name / ":"), "FORALL" >> indirect(concurrentHeader)))

 // R1052 forall-body-construct ->
 //         forall-assignment-stmt | where-stmt | where-construct |
 //         forall-construct | forall-stmt
 TYPE_PARSER(construct<ForallBodyConstruct>(statement(forallAssignmentStmt)) ||
     construct<ForallBodyConstruct>(statement(whereStmt)) ||
     construct<ForallBodyConstruct>(whereConstruct) ||
     construct<ForallBodyConstruct>(indirect(forallConstruct)) ||
     construct<ForallBodyConstruct>(statement(forallStmt)))

 // R1053 forall-assignment-stmt -> assignment-stmt | pointer-assignment-stmt
 TYPE_PARSER(construct<ForallAssignmentStmt>(assignmentStmt) ||
     construct<ForallAssignmentStmt>(pointerAssignmentStmt))

 // R1054 end-forall-stmt -> END FORALL [forall-construct-name]
 TYPE_CONTEXT_PARSER("END FORALL statement"_en_US,
     construct<EndForallStmt>(
         recovery("END FORALL" >> maybe(name), endStmtErrorRecovery)))

 // R1055 forall-stmt -> FORALL concurrent-header forall-assignment-stmt
 TYPE_CONTEXT_PARSER("FORALL statement"_en_US,
     construct<ForallStmt>("FORALL" >> indirect(concurrentHeader),
         unlabeledStatement(forallAssignmentStmt)))
 } // namespace Fortran::parser
	//===-- lib/Parser/expr-parsers.cpp ---------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	// Per-type parsers for expressions.

	#include "expr-parsers.h"
	#include "basic-parsers.h"
	#include "debug-parser.h"
	#include "misc-parsers.h"
	#include "stmt-parser.h"
	#include "token-parsers.h"
	#include "type-parser-implementation.h"
	#include "flang/Parser/characters.h"
	#include "flang/Parser/parse-tree.h"

	namespace Fortran::parser {

	// R764 boz-literal-constant -> binary-constant \| octal-constant \| hex-constant
	// R765 binary-constant -> B ' digit [digit]... ' \| B " digit [digit]... "
	// R766 octal-constant -> O ' digit [digit]... ' \| O " digit [digit]... "
	// R767 hex-constant ->
	// Z ' hex-digit [hex-digit]... ' \| Z " hex-digit [hex-digit]... "
	// extension: X accepted for Z
	// extension: BOZX suffix accepted
	TYPE_PARSER(construct<BOZLiteralConstant>(BOZLiteral{}))

	// R769 array-constructor -> (/ ac-spec /) \| lbracket ac-spec rbracket
	TYPE_CONTEXT_PARSER("array constructor"_en_US,
	construct<ArrayConstructor>(
	"(/" >> Parser<AcSpec>{} / "/)" \|\| bracketed(Parser<AcSpec>{})))

	// R770 ac-spec -> type-spec :: \| [type-spec ::] ac-value-list
	TYPE_PARSER(construct<AcSpec>(maybe(typeSpec / "::"),
	nonemptyList("expected array constructor values"_err_en_US,
	Parser<AcValue>{})) \|\|
	construct<AcSpec>(typeSpec / "::"))

	// R773 ac-value -> expr \| ac-implied-do
	TYPE_PARSER(
	// PGI/Intel extension: accept triplets in array constructors
	extension<LanguageFeature::TripletInArrayConstructor>(
	construct<AcValue>(construct<AcValue::Triplet>(scalarIntExpr,
	":" >> scalarIntExpr, maybe(":" >> scalarIntExpr)))) \|\|
	construct<AcValue>(indirect(expr)) \|\|
	construct<AcValue>(indirect(Parser<AcImpliedDo>{})))

	// R774 ac-implied-do -> ( ac-value-list , ac-implied-do-control )
	TYPE_PARSER(parenthesized(
	construct<AcImpliedDo>(nonemptyList(Parser<AcValue>{} / lookAhead(","_tok)),
	"," >> Parser<AcImpliedDoControl>{})))

	// R775 ac-implied-do-control ->
	// [integer-type-spec ::] ac-do-variable = scalar-int-expr ,
	// scalar-int-expr [, scalar-int-expr]
	// R776 ac-do-variable -> do-variable
	TYPE_PARSER(construct<AcImpliedDoControl>(
	maybe(integerTypeSpec / "::"), loopBounds(scalarIntExpr)))

	// R1001 primary ->
	// literal-constant \| designator \| array-constructor \|
	// structure-constructor \| function-reference \| type-param-inquiry \|
	// type-param-name \| ( expr )
	// N.B. type-param-inquiry is parsed as a structure component
	constexpr auto primary{instrumented("primary"_en_US,
	first(construct<Expr>(indirect(Parser<CharLiteralConstantSubstring>{})),
	construct<Expr>(literalConstant),
	construct<Expr>(construct<Expr::Parentheses>(parenthesized(expr))),
	construct<Expr>(indirect(functionReference) / !"("_tok),
	construct<Expr>(designator / !"("_tok),
	construct<Expr>(Parser<StructureConstructor>{}),
	construct<Expr>(Parser<ArrayConstructor>{}),
	// PGI/XLF extension: COMPLEX constructor (x,y)
	extension<LanguageFeature::ComplexConstructor>(
	construct<Expr>(parenthesized(
	construct<Expr::ComplexConstructor>(expr, "," >> expr)))),
	extension<LanguageFeature::PercentLOC>(construct<Expr>("%LOC" >>
	parenthesized(construct<Expr::PercentLoc>(indirect(variable)))))))};

	// R1002 level-1-expr -> [defined-unary-op] primary
	// TODO: Reasonable extension: permit multiple defined-unary-ops
	constexpr auto level1Expr{sourced(
	first(primary, // must come before define op to resolve .TRUE._8 ambiguity
	construct<Expr>(construct<Expr::DefinedUnary>(definedOpName, primary)),
	extension<LanguageFeature::SignedPrimary>(
	construct<Expr>(construct<Expr::UnaryPlus>("+" >> primary))),
	extension<LanguageFeature::SignedPrimary>(
	construct<Expr>(construct<Expr::Negate>("-" >> primary)))))};

	// R1004 mult-operand -> level-1-expr [power-op mult-operand]
	// R1007 power-op -> **
	// Exponentiation (**) is Fortran's only right-associative binary operation.
	struct MultOperand {
	using resultType = Expr;
	constexpr MultOperand() {}
	static inline std::optional<Expr> Parse(ParseState &);
	};

	static constexpr auto multOperand{sourced(MultOperand{})};

	inline std::optional<Expr> MultOperand::Parse(ParseState &state) {
	std::optional<Expr> result{level1Expr.Parse(state)};
	if (result) {
	static constexpr auto op{attempt("**"_tok)};
	if (op.Parse(state)) {
	std::function<Expr(Expr &&)> power{[&result](Expr &&right) {
	return Expr{Expr::Power(std::move(result).value(), std::move(right))};
	}};
	return applyLambda(power, multOperand).Parse(state); // right-recursive
	}
	}
	return result;
	}

	// R1005 add-operand -> [add-operand mult-op] mult-operand
	// R1008 mult-op -> * \| /
	// The left recursion in the grammar is implemented iteratively.
	struct AddOperand {
	using resultType = Expr;
	constexpr AddOperand() {}
	static inline std::optional<Expr> Parse(ParseState &state) {
	std::optional<Expr> result{multOperand.Parse(state)};
	if (result) {
	auto source{result->source};
	std::function<Expr(Expr &&)> multiply{[&result](Expr &&right) {
	return Expr{
	Expr::Multiply(std::move(result).value(), std::move(right))};
	}};
	std::function<Expr(Expr &&)> divide{[&result](Expr &&right) {
	return Expr{Expr::Divide(std::move(result).value(), std::move(right))};
	}};
	auto more{attempt(sourced("*" >> applyLambda(multiply, multOperand) \|\|
	"/" >> applyLambda(divide, multOperand)))};
	while (std::optional<Expr> next{more.Parse(state)}) {
	result = std::move(next);
	result->source.ExtendToCover(source);
	}
	}
	return result;
	}
	};
	constexpr AddOperand addOperand;

	// R1006 level-2-expr -> [[level-2-expr] add-op] add-operand
	// R1009 add-op -> + \| -
	// These are left-recursive productions, implemented iteratively.
	// Note that standard Fortran admits a unary + or - to appear only here,
	// by means of a missing first operand; e.g., 2*-3 is valid in C but not
	// standard Fortran. We accept unary + and - to appear before any primary
	// as an extension.
	struct Level2Expr {
	using resultType = Expr;
	constexpr Level2Expr() {}
	static inline std::optional<Expr> Parse(ParseState &state) {
	static constexpr auto unary{
	sourced(
	construct<Expr>(construct<Expr::UnaryPlus>("+" >> addOperand)) \|\|
	construct<Expr>(construct<Expr::Negate>("-" >> addOperand))) \|\|
	addOperand};
	std::optional<Expr> result{unary.Parse(state)};
	if (result) {
	auto source{result->source};
	std::function<Expr(Expr &&)> add{[&result](Expr &&right) {
	return Expr{Expr::Add(std::move(result).value(), std::move(right))};
	}};
	std::function<Expr(Expr &&)> subtract{[&result](Expr &&right) {
	return Expr{
	Expr::Subtract(std::move(result).value(), std::move(right))};
	}};
	auto more{attempt(sourced("+" >> applyLambda(add, addOperand) \|\|
	"-" >> applyLambda(subtract, addOperand)))};
	while (std::optional<Expr> next{more.Parse(state)}) {
	result = std::move(next);
	result->source.ExtendToCover(source);
	}
	}
	return result;
	}
	};
	constexpr Level2Expr level2Expr;

	// R1010 level-3-expr -> [level-3-expr concat-op] level-2-expr
	// R1011 concat-op -> //
	// Concatenation (//) is left-associative for parsing performance, although
	// one would never notice if it were right-associated.
	struct Level3Expr {
	using resultType = Expr;
	constexpr Level3Expr() {}
	static inline std::optional<Expr> Parse(ParseState &state) {
	std::optional<Expr> result{level2Expr.Parse(state)};
	if (result) {
	auto source{result->source};
	std::function<Expr(Expr &&)> concat{[&result](Expr &&right) {
	return Expr{Expr::Concat(std::move(result).value(), std::move(right))};
	}};
	auto more{attempt(sourced("//" >> applyLambda(concat, level2Expr)))};
	while (std::optional<Expr> next{more.Parse(state)}) {
	result = std::move(next);
	result->source.ExtendToCover(source);
	}
	}
	return result;
	}
	};
	constexpr Level3Expr level3Expr;

	// R1012 level-4-expr -> [level-3-expr rel-op] level-3-expr
	// R1013 rel-op ->
	// .EQ. \| .NE. \| .LT. \| .LE. \| .GT. \| .GE. \|
	// == \| /= \| < \| <= \| > \| >= @ \| <>
	// N.B. relations are not recursive (i.e., LOGICAL is not ordered)
	struct Level4Expr {
	using resultType = Expr;
	constexpr Level4Expr() {}
	static inline std::optional<Expr> Parse(ParseState &state) {
	std::optional<Expr> result{level3Expr.Parse(state)};
	if (result) {
	auto source{result->source};
	std::function<Expr(Expr &&)> lt{[&result](Expr &&right) {
	return Expr{Expr::LT(std::move(result).value(), std::move(right))};
	}};
	std::function<Expr(Expr &&)> le{[&result](Expr &&right) {
	return Expr{Expr::LE(std::move(result).value(), std::move(right))};
	}};
	std::function<Expr(Expr &&)> eq{[&result](Expr &&right) {
	return Expr{Expr::EQ(std::move(result).value(), std::move(right))};
	}};
	std::function<Expr(Expr &&)> ne{[&result](Expr &&right) {
	return Expr{Expr::NE(std::move(result).value(), std::move(right))};
	}};
	std::function<Expr(Expr &&)> ge{[&result](Expr &&right) {
	return Expr{Expr::GE(std::move(result).value(), std::move(right))};
	}};
	std::function<Expr(Expr &&)> gt{[&result](Expr &&right) {
	return Expr{Expr::GT(std::move(result).value(), std::move(right))};
	}};
	auto more{attempt(
	sourced((".LT."_tok \|\| "<"_tok) >> applyLambda(lt, level3Expr) \|\|
	(".LE."_tok \|\| "<="_tok) >> applyLambda(le, level3Expr) \|\|
	(".EQ."_tok \|\| "=="_tok) >> applyLambda(eq, level3Expr) \|\|
	(".NE."_tok \|\| "/="_tok \|\|
	extension<LanguageFeature::AlternativeNE>(
	"<>"_tok /* PGI/Cray extension; Cray also has .LG. */)) >>
	applyLambda(ne, level3Expr) \|\|
	(".GE."_tok \|\| ">="_tok) >> applyLambda(ge, level3Expr) \|\|
	(".GT."_tok \|\| ">"_tok) >> applyLambda(gt, level3Expr)))};
	if (std::optional<Expr> next{more.Parse(state)}) {
	next->source.ExtendToCover(source);
	return next;
	}
	}
	return result;
	}
	};
	constexpr Level4Expr level4Expr;

	// R1014 and-operand -> [not-op] level-4-expr
	// R1018 not-op -> .NOT.
	// N.B. Fortran's .NOT. binds less tightly than its comparison operators do.
	// PGI/Intel extension: accept multiple .NOT. operators
	struct AndOperand {
	using resultType = Expr;
	constexpr AndOperand() {}
	static inline std::optional<Expr> Parse(ParseState &);
	};
	constexpr AndOperand andOperand;

	// Match a logical operator or, optionally, its abbreviation.
	inline constexpr auto logicalOp(const char op, const char abbrev) {
	return TokenStringMatch{op} \|\|
	extension<LanguageFeature::LogicalAbbreviations>(
	TokenStringMatch{abbrev});
	}

	inline std::optional<Expr> AndOperand::Parse(ParseState &state) {
	static constexpr auto notOp{attempt(logicalOp(".NOT.", ".N.") >> andOperand)};
	if (std::optional<Expr> negation{notOp.Parse(state)}) {
	return Expr{Expr::NOT{std::move(*negation)}};
	} else {
	return level4Expr.Parse(state);
	}
	}

	// R1015 or-operand -> [or-operand and-op] and-operand
	// R1019 and-op -> .AND.
	// .AND. is left-associative
	struct OrOperand {
	using resultType = Expr;
	constexpr OrOperand() {}
	static inline std::optional<Expr> Parse(ParseState &state) {
	static constexpr auto operand{sourced(andOperand)};
	std::optional<Expr> result{operand.Parse(state)};
	if (result) {
	auto source{result->source};
	std::function<Expr(Expr &&)> logicalAnd{[&result](Expr &&right) {
	return Expr{Expr::AND(std::move(result).value(), std::move(right))};
	}};
	auto more{attempt(sourced(
	logicalOp(".AND.", ".A.") >> applyLambda(logicalAnd, andOperand)))};
	while (std::optional<Expr> next{more.Parse(state)}) {
	result = std::move(next);
	result->source.ExtendToCover(source);
	}
	}
	return result;
	}
	};
	constexpr OrOperand orOperand;

	// R1016 equiv-operand -> [equiv-operand or-op] or-operand
	// R1020 or-op -> .OR.
	// .OR. is left-associative
	struct EquivOperand {
	using resultType = Expr;
	constexpr EquivOperand() {}
	static inline std::optional<Expr> Parse(ParseState &state) {
	std::optional<Expr> result{orOperand.Parse(state)};
	if (result) {
	auto source{result->source};
	std::function<Expr(Expr &&)> logicalOr{[&result](Expr &&right) {
	return Expr{Expr::OR(std::move(result).value(), std::move(right))};
	}};
	auto more{attempt(sourced(
	logicalOp(".OR.", ".O.") >> applyLambda(logicalOr, orOperand)))};
	while (std::optional<Expr> next{more.Parse(state)}) {
	result = std::move(next);
	result->source.ExtendToCover(source);
	}
	}
	return result;
	}
	};
	constexpr EquivOperand equivOperand;

	// R1017 level-5-expr -> [level-5-expr equiv-op] equiv-operand
	// R1021 equiv-op -> .EQV. \| .NEQV.
	// Logical equivalence is left-associative.
	// Extension: .XOR. as synonym for .NEQV.
	struct Level5Expr {
	using resultType = Expr;
	constexpr Level5Expr() {}
	static inline std::optional<Expr> Parse(ParseState &state) {
	std::optional<Expr> result{equivOperand.Parse(state)};
	if (result) {
	auto source{result->source};
	std::function<Expr(Expr &&)> eqv{[&result](Expr &&right) {
	return Expr{Expr::EQV(std::move(result).value(), std::move(right))};
	}};
	std::function<Expr(Expr &&)> neqv{[&result](Expr &&right) {
	return Expr{Expr::NEQV(std::move(result).value(), std::move(right))};
	}};
	auto more{attempt(sourced(".EQV." >> applyLambda(eqv, equivOperand) \|\|
	(".NEQV."_tok \|\|
	extension<LanguageFeature::XOROperator>(
	logicalOp(".XOR.", ".X."))) >>
	applyLambda(neqv, equivOperand)))};
	while (std::optional<Expr> next{more.Parse(state)}) {
	result = std::move(next);
	result->source.ExtendToCover(source);
	}
	}
	return result;
	}
	};
	constexpr Level5Expr level5Expr;

	// R1022 expr -> [expr defined-binary-op] level-5-expr
	// Defined binary operators associate leftwards.
	template <> std::optional<Expr> Parser<Expr>::Parse(ParseState &state) {
	std::optional<Expr> result{level5Expr.Parse(state)};
	if (result) {
	auto source{result->source};
	std::function<Expr(DefinedOpName &&, Expr &&)> defBinOp{
	[&result](DefinedOpName &&op, Expr &&right) {
	return Expr{Expr::DefinedBinary(
	std::move(op), std::move(result).value(), std::move(right))};
	}};
	auto more{attempt(
	sourced(applyLambda<Expr>(defBinOp, definedOpName, level5Expr)))};
	while (std::optional<Expr> next{more.Parse(state)}) {
	result = std::move(next);
	result->source.ExtendToCover(source);
	}
	}
	return result;
	}

	// R1003 defined-unary-op -> . letter [letter]... .
	// R1023 defined-binary-op -> . letter [letter]... .
	// R1414 local-defined-operator -> defined-unary-op \| defined-binary-op
	// R1415 use-defined-operator -> defined-unary-op \| defined-binary-op
	// C1003 A defined operator must be distinct from logical literal constants
	// and intrinsic operator names; this is handled by attempting their parses
	// first, and by name resolution on their definitions, for best errors.
	// N.B. The name of the operator is captured with the dots around it.
	constexpr auto definedOpNameChar{
	letter \|\| extension<LanguageFeature::PunctuationInNames>("$@"_ch)};
	TYPE_PARSER(
	space >> construct<DefinedOpName>(sourced("."_ch >>
	some(definedOpNameChar) >> construct<Name>() / "."_ch)))

	// R1028 specification-expr -> scalar-int-expr
	TYPE_PARSER(construct<SpecificationExpr>(scalarIntExpr))

	// R1032 assignment-stmt -> variable = expr
	TYPE_CONTEXT_PARSER("assignment statement"_en_US,
	construct<AssignmentStmt>(variable / "=", expr))

	// R1033 pointer-assignment-stmt ->
	// data-pointer-object [( bounds-spec-list )] => data-target \|
	// data-pointer-object ( bounds-remapping-list ) => data-target \|
	// proc-pointer-object => proc-target
	// R1034 data-pointer-object ->
	// variable-name \| scalar-variable % data-pointer-component-name
	// C1022 a scalar-variable shall be a data-ref
	// C1024 a data-pointer-object shall not be a coindexed object
	// R1038 proc-pointer-object -> proc-pointer-name \| proc-component-ref
	//
	// A distinction can't be made at the time of the initial parse between
	// data-pointer-object and proc-pointer-object, or between data-target
	// and proc-target.
	TYPE_CONTEXT_PARSER("pointer assignment statement"_en_US,
	construct<PointerAssignmentStmt>(dataRef,
	parenthesized(nonemptyList(Parser<BoundsRemapping>{})), "=>" >> expr) \|\|
	construct<PointerAssignmentStmt>(dataRef,
	defaulted(parenthesized(nonemptyList(Parser<BoundsSpec>{}))),
	"=>" >> expr))

	// R1035 bounds-spec -> lower-bound-expr :
	TYPE_PARSER(construct<BoundsSpec>(boundExpr / ":"))

	// R1036 bounds-remapping -> lower-bound-expr : upper-bound-expr
	TYPE_PARSER(construct<BoundsRemapping>(boundExpr / ":", boundExpr))

	// R1039 proc-component-ref -> scalar-variable % procedure-component-name
	// C1027 the scalar-variable must be a data-ref without coindices.
	TYPE_PARSER(construct<ProcComponentRef>(structureComponent))

	// R1041 where-stmt -> WHERE ( mask-expr ) where-assignment-stmt
	// R1045 where-assignment-stmt -> assignment-stmt
	// R1046 mask-expr -> logical-expr
	TYPE_CONTEXT_PARSER("WHERE statement"_en_US,
	construct<WhereStmt>("WHERE" >> parenthesized(logicalExpr), assignmentStmt))

	// R1042 where-construct ->
	// where-construct-stmt [where-body-construct]...
	// [masked-elsewhere-stmt [where-body-construct]...]...
	// [elsewhere-stmt [where-body-construct]...] end-where-stmt
	TYPE_CONTEXT_PARSER("WHERE construct"_en_US,
	construct<WhereConstruct>(statement(Parser<WhereConstructStmt>{}),
	many(whereBodyConstruct),
	many(construct<WhereConstruct::MaskedElsewhere>(
	statement(Parser<MaskedElsewhereStmt>{}),
	many(whereBodyConstruct))),
	maybe(construct<WhereConstruct::Elsewhere>(
	statement(Parser<ElsewhereStmt>{}), many(whereBodyConstruct))),
	statement(Parser<EndWhereStmt>{})))

	// R1043 where-construct-stmt -> [where-construct-name :] WHERE ( mask-expr )
	TYPE_CONTEXT_PARSER("WHERE construct statement"_en_US,
	construct<WhereConstructStmt>(
	maybe(name / ":"), "WHERE" >> parenthesized(logicalExpr)))

	// R1044 where-body-construct ->
	// where-assignment-stmt \| where-stmt \| where-construct
	TYPE_PARSER(construct<WhereBodyConstruct>(statement(assignmentStmt)) \|\|
	construct<WhereBodyConstruct>(statement(whereStmt)) \|\|
	construct<WhereBodyConstruct>(indirect(whereConstruct)))

	// R1047 masked-elsewhere-stmt ->
	// ELSEWHERE ( mask-expr ) [where-construct-name]
	TYPE_CONTEXT_PARSER("masked ELSEWHERE statement"_en_US,
	construct<MaskedElsewhereStmt>(
	"ELSE WHERE" >> parenthesized(logicalExpr), maybe(name)))

	// R1048 elsewhere-stmt -> ELSEWHERE [where-construct-name]
	TYPE_CONTEXT_PARSER("ELSEWHERE statement"_en_US,
	construct<ElsewhereStmt>("ELSE WHERE" >> maybe(name)))

	// R1049 end-where-stmt -> ENDWHERE [where-construct-name]
	TYPE_CONTEXT_PARSER("END WHERE statement"_en_US,
	construct<EndWhereStmt>(
	recovery("END WHERE" >> maybe(name), endStmtErrorRecovery)))

	// R1050 forall-construct ->
	// forall-construct-stmt [forall-body-construct]... end-forall-stmt
	TYPE_CONTEXT_PARSER("FORALL construct"_en_US,
	construct<ForallConstruct>(statement(Parser<ForallConstructStmt>{}),
	many(Parser<ForallBodyConstruct>{}),
	statement(Parser<EndForallStmt>{})))

	// R1051 forall-construct-stmt ->
	// [forall-construct-name :] FORALL concurrent-header
	TYPE_CONTEXT_PARSER("FORALL construct statement"_en_US,
	construct<ForallConstructStmt>(
	maybe(name / ":"), "FORALL" >> indirect(concurrentHeader)))

	// R1052 forall-body-construct ->
	// forall-assignment-stmt \| where-stmt \| where-construct \|
	// forall-construct \| forall-stmt
	TYPE_PARSER(construct<ForallBodyConstruct>(statement(forallAssignmentStmt)) \|\|
	construct<ForallBodyConstruct>(statement(whereStmt)) \|\|
	construct<ForallBodyConstruct>(whereConstruct) \|\|
	construct<ForallBodyConstruct>(indirect(forallConstruct)) \|\|
	construct<ForallBodyConstruct>(statement(forallStmt)))

	// R1053 forall-assignment-stmt -> assignment-stmt \| pointer-assignment-stmt
	TYPE_PARSER(construct<ForallAssignmentStmt>(assignmentStmt) \|\|
	construct<ForallAssignmentStmt>(pointerAssignmentStmt))

	// R1054 end-forall-stmt -> END FORALL [forall-construct-name]
	TYPE_CONTEXT_PARSER("END FORALL statement"_en_US,
	construct<EndForallStmt>(
	recovery("END FORALL" >> maybe(name), endStmtErrorRecovery)))

	// R1055 forall-stmt -> FORALL concurrent-header forall-assignment-stmt
	TYPE_CONTEXT_PARSER("FORALL statement"_en_US,
	construct<ForallStmt>("FORALL" >> indirect(concurrentHeader),
	unlabeledStatement(forallAssignmentStmt)))
	} // namespace Fortran::parser