use std::rc::Rc; use std::iter::Peekable; use std::vec::IntoIter; use tokenizing::*; use tokenizing::Kw::*; use tokenizing::TokenType::*; use ast::*; use builtin::{BinOp, PrefixOp}; #[derive(Debug)] pub struct ParseError { pub msg: String, pub token: Option } impl ParseError { fn new(msg: &str) -> ParseResult { Err(ParseError { msg: msg.to_string(), token: None }) } } pub type ParseResult = Result; #[derive(Debug)] pub struct ParseRecord { production_name: String, next_token: String, level: u32, } pub struct Parser { token_handler: TokenHandler, parse_record: Vec, parse_level: u32, restrictions: ParserRestrictions, } struct ParserRestrictions { no_struct_literal: bool } struct TokenHandler { tokens: Peekable>, } impl TokenHandler { fn new(tokens: Vec) -> TokenHandler { let tokens = tokens.into_iter().peekable(); TokenHandler { tokens } } fn peek(&mut self) -> TokenType { self.tokens.peek().map(|ref t| { t.token_type.clone() }).unwrap_or(TokenType::EOF) } fn peek_with_token_offset(&mut self) -> Token { self.tokens.peek().map(|t: &Token| { t.clone()}).unwrap_or(Token { token_type: TokenType::EOF, offset: (0,0)}) } fn next(&mut self) -> TokenType { self.tokens.next().map(|ref t| { t.token_type.clone() }).unwrap_or(TokenType::EOF) } } impl Parser { pub fn new(initial_input: Vec) -> Parser { Parser { token_handler: TokenHandler::new(initial_input), parse_record: vec![], parse_level: 0, restrictions: ParserRestrictions { no_struct_literal: false } } } fn peek(&mut self) -> TokenType { self.token_handler.peek() } fn peek_with_token_offset(&mut self) -> Token { self.token_handler.peek_with_token_offset() } fn next(&mut self) -> TokenType { self.token_handler.next() } pub fn parse(&mut self) -> ParseResult { self.program() } /* pub fn parse_with_new_tokens(&mut self, new_tokens: Vec) -> ParseResult { } */ pub fn format_parse_trace(self) -> Vec { self.parse_record.into_iter().map(|r| { let mut indent = String::new(); for _ in 0..r.level { indent.push(' '); } format!("{}Production `{}`, token: {}", indent, r.production_name, r.next_token) }).collect() } } macro_rules! print_token_pattern { ($tokenpattern:pat) => { stringify!($tokenpattern) } } macro_rules! expect { ($self:expr, $token_type:pat) => { expect!($self, $token_type if true) }; ($self:expr, $token_type:pat if $cond:expr) => { match $self.peek() { $token_type if $cond => $self.next(), tok => { let msg = format!("Expected {}, got {:?}", print_token_pattern!($token_type), tok); return ParseError::new(&msg); } } } } macro_rules! delimited { ($self:expr, $start:pat, $parse_fn:ident, $( $delim:pat )|+, $end:pat, nonstrict) => { delimited!($self, $start, $parse_fn, $( $delim )|*, $end, false) }; ($self:expr, $start:pat, $parse_fn:ident, $( $delim:pat )|+, $end:pat) => { delimited!($self, $start, $parse_fn, $( $delim )|*, $end, true) }; ($self:expr, $start:pat, $parse_fn:ident, $( $delim:pat )|+, $end:pat, $strictness:expr) => { { expect!($self, $start); let mut acc = vec![]; loop { let peek = $self.peek(); match peek { $end | EOF => break, _ => (), } if !$strictness { match peek { $( $delim )|* => { $self.next(); continue }, _ => () } } acc.push($self.$parse_fn()?); match $self.peek() { $( $delim )|* => { $self.next(); continue }, _ if $strictness => break, _ => continue, }; } expect!($self, $end); acc } }; } /* Schala EBNF Grammar */ /* Terminal productions are in 'single quotes' or UPPERCASE if they are a class * or not representable in ASCII /* Top-level Structure */ program := (statement delimiter)* EOF delimiter := NEWLINE | ';' statement := expression | declaration block := '{' (statement delimiter)* '}' declaration := type_declaration | func_declaration | binding_declaration | impl_declaration /* Declarations - Types */ type_declaration := 'type' type_declaration_body type_declaration_body := 'alias' type_alias | 'mut'? type_singleton_name '=' type_body type_alias := IDENTIFIER '=' type_name type_body := variant_specifier ('|' variant_specifier)* variant_specifier := IDENTIFIER | IDENTIFIER '{' typed_identifier_list '}' | IDENTIFIER '(' type_name* ')' typed_identifier_list := typed_identifier* typed_identifier := IDENTIFIER type_anno /* Declaration - Functions */ func_declaration := func_signature func_body func_body := ε | nonempty_func_body nonempty_func_body := '{' (statement delimiter)* '}' func_signature := 'fn' func_name formal_param_list func_body func_name := IDENTIFIER | operator formal_param_list := '(' (formal_param ',')* ')' formal_param := IDENTIFIER type_anno+ /* Declaration - Variable bindings */ binding_declaration := 'let' 'mut'? IDENTIFIER '=' expresion /* Declaration - Interface */ interface_declaration := 'interface' interface_name signature_block impl_declaration := 'impl' IDENTIFIER decl_block | 'impl' interface_name 'for' IDENTIFIER decl_block decl_block := '{' (func_declaration)* '}' signature_block := '{' (func_signature)* '}' interface_name := IDENTIFIER /* Type annotations */ type_anno := (':' type_name)+ type_name := type_singleton_name | '(' type_names ')' type_names := ε | type_name (, type_name)* type_singleton_name = IDENTIFIER (type_params)* type_params := '<' type_name (, type_name)* '>' /* Expressions */ expression := precedence_expr type_anno+ precedence_expr := prefix_expr prefix_expr := prefix_op call_expr prefix_op := '+' | '-' | '!' | '~' call_expr := index_expr ( '(' expr_list ')' )* expr_list := expression (',' expression)* | ε index_expr := primary ( '[' (expression (',' (expression)* | ε) ']' )* primary := literal | paren_expr | if_expr | for_expr | while_expr | identifier_expr | lambda_expr | anonymous_struct | list_expr /* Primary Expressions */ list_expr := '[' (expression, ',')* ']' lambda_expr := '\' formal_param_list nonempty_func_body paren_expr := LParen paren_inner RParen paren_inner := (expression ',')* identifier_expr := named_struct | IDENTIFIER /* Expression - Literals */ literal := 'true' | 'false' | number_literal | STR_LITERAL named_struct := IDENTIFIER record_block record_block := '{' (record_entry, ',')* | '}' //TODO support anonymus structs, update syntax record_entry := IDENTIFIER ':' expression anonymous_struct := TODO // a float_literal can still be assigned to an int in type-checking number_literal := int_literal | float_literal int_literal = ('0x' | '0b') digits float_literal := digits ('.' digits) digits := (DIGIT_GROUP underscore)+ /* Pattern syntax */ pattern := '(' (pattern, ',')* ')' | simple_pattern simple_pattern := pattern_literal | record_pattern | tuple_struct_pattern pattern_literal := 'true' | 'false' | signed_number_literal | STR_LITERAL | IDENTIFIER signed_number_literal := '-'? number_literal record_pattern := IDENTIFIER '{' (record_pattern_entry, ',')* '}' record_pattern_entry := IDENTIFIER | IDENTIFIER ':' Pattern tuple_struct_pattern := IDENTIFIER '(' (pattern, ',')* ')' expr_or_block := '{' (statement delimiter)* '}' | expr /* Expression - If */ if_expr := 'if' discriminator ('then' condititional | 'is' simple_pattern_match | guard_block) discriminator := precedence_expr (operator)+ conditional := expr_or_block else_clause simple_pattern_match := pattern 'then' conditional else_clause := ε | 'else' expr_or_block guard_block := '{' (guard_arm, ',')* '}' guard_arm := guard '->' expr_or_block guard := 'is' pattern | (operator)+ precedence_expr /* Expression - While */ while_expr := 'while' while_cond '{' (statement delimiter)* '}' while_cond := ε | expression | expression 'is' pattern //TODO maybe is-expresions should be primary //TODO this implies there must be at least one enumerator, which the parser doesn't support right //this second, and maybe should fail later anyway /* Expression - For */ for_expr := 'for' (enumerator | '{' enumerators '}') for_expr_body for_expr_body := 'return' expression | '{' (statement delimiter)* '} enumerators := enumerator (',' enumerators)* enumerator := identifier '<-' expression | identifier '=' expression //TODO add guards, etc. */ impl Parser { //TODO make this a proper public interface #[recursive_descent_method] fn program(&mut self) -> ParseResult { let mut statements = Vec::new(); loop { match self.peek() { EOF => break, Newline | Semicolon => { self.next(); continue; }, _ => statements.push(self.statement()?), } } Ok(AST(statements)) } #[recursive_descent_method] fn statement(&mut self) -> ParseResult { //TODO handle error recovery here match self.peek() { Keyword(Type) => self.type_declaration().map(|decl| { Statement::Declaration(decl) }), Keyword(Func)=> self.func_declaration().map(|func| { Statement::Declaration(func) }), Keyword(Let) => self.binding_declaration().map(|decl| Statement::Declaration(decl)), Keyword(Interface) => self.interface_declaration().map(|decl| Statement::Declaration(decl)), Keyword(Impl) => self.impl_declaration().map(|decl| Statement::Declaration(decl)), _ => self.expression().map(|expr| { Statement::ExpressionStatement(expr) } ), } } #[recursive_descent_method] fn type_declaration(&mut self) -> ParseResult { expect!(self, Keyword(Type)); self.type_declaration_body() } #[recursive_descent_method] fn type_declaration_body(&mut self) -> ParseResult { if let Keyword(Alias) = self.peek() { self.type_alias() } else { let mutable = if let Keyword(Mut) = self.peek() { self.next(); true } else { false }; let name = self.type_singleton_name()?; expect!(self, Operator(ref c) if **c == "="); let body = self.type_body()?; Ok(Declaration::TypeDecl { name, body, mutable}) } } #[recursive_descent_method] fn type_alias(&mut self) -> ParseResult { expect!(self, Keyword(Alias)); let alias = self.identifier()?; expect!(self, Operator(ref c) if **c == "="); let original = self.identifier()?; Ok(Declaration::TypeAlias(alias, original)) } #[recursive_descent_method] fn type_body(&mut self) -> ParseResult { let mut variants = Vec::new(); variants.push(self.variant_specifier()?); loop { if let Pipe = self.peek() { self.next(); variants.push(self.variant_specifier()?); } else { break; } } Ok(TypeBody(variants)) } #[recursive_descent_method] fn variant_specifier(&mut self) -> ParseResult { use self::Variant::*; let name = self.identifier()?; match self.peek() { LParen => { let tuple_members = delimited!(self, LParen, type_name, Comma, RParen); Ok(TupleStruct(name, tuple_members)) }, LCurlyBrace => { let typed_identifier_list = delimited!(self, LCurlyBrace, typed_identifier, Comma, RCurlyBrace); Ok(Record(name, typed_identifier_list)) }, _ => Ok(UnitStruct(name)) } } #[recursive_descent_method] fn typed_identifier(&mut self) -> ParseResult<(Rc, TypeIdentifier)> { let identifier = self.identifier()?; expect!(self, Colon); let type_name = self.type_name()?; Ok((identifier, type_name)) } #[recursive_descent_method] fn func_declaration(&mut self) -> ParseResult { let signature = self.func_signature()?; if let LCurlyBrace = self.peek() { let statements = self.nonempty_func_body()?; Ok(Declaration::FuncDecl(signature, statements)) } else { Ok(Declaration::FuncSig(signature)) } } #[recursive_descent_method] fn func_signature(&mut self) -> ParseResult { expect!(self, Keyword(Func)); let (name, operator) = match self.peek() { Operator(s) => { let name = s.clone(); self.next(); (name, true) }, _ => (self.identifier()?, false) }; let params = self.formal_param_list()?; let type_anno = match self.peek() { Colon => Some(self.type_anno()?), _ => None, }; Ok(Signature { name, operator, params, type_anno }) } #[recursive_descent_method] fn nonempty_func_body(&mut self) -> ParseResult> { Ok(delimited!(self, LCurlyBrace, statement, Newline | Semicolon, RCurlyBrace, nonstrict)) } #[recursive_descent_method] fn formal_param_list(&mut self) -> ParseResult> { Ok(delimited!(self, LParen, formal_param, Comma, RParen)) } #[recursive_descent_method] fn formal_param(&mut self) -> ParseResult { let name = self.identifier()?; let ty = match self.peek() { Colon => Some(self.type_anno()?), _ => None }; Ok((name, ty)) } #[recursive_descent_method] fn binding_declaration(&mut self) -> ParseResult { expect!(self, Keyword(Kw::Let)); let constant = match self.peek() { Keyword(Kw::Mut) => { self.next(); false } _ => true }; let name = self.identifier()?; expect!(self, Operator(ref o) if **o == "="); let expr = self.expression()?; Ok(Declaration::Binding { name, constant, expr }) } #[recursive_descent_method] fn interface_declaration(&mut self) -> ParseResult { expect!(self, Keyword(Interface)); let name = self.identifier()?; let signatures = self.signature_block()?; Ok(Declaration::Interface { name, signatures }) } #[recursive_descent_method] fn signature_block(&mut self) -> ParseResult> { Ok(delimited!(self, LCurlyBrace, func_signature, Newline | Semicolon, RCurlyBrace, nonstrict)) } #[recursive_descent_method] fn impl_declaration(&mut self) -> ParseResult { expect!(self, Keyword(Impl)); let first = self.type_name()?; let second = if let Keyword(For) = self.peek() { self.next(); Some(self.type_name()?) } else { None }; let block = self.decl_block()?; let result = match (first, second) { (first, Some(second)) => { match first { TypeIdentifier::Singleton(TypeSingletonName { ref name, ref params }) if params.len() == 0 => Declaration::Impl { type_name: second, interface_name: Some(name.clone()), block }, _ => return ParseError::new(&format!("Invalid name for an interface")), } }, (first, None) => Declaration::Impl { type_name: first, interface_name: None, block } }; Ok(result) } #[recursive_descent_method] fn decl_block(&mut self) -> ParseResult> { Ok(delimited!(self, LCurlyBrace, func_declaration, Newline | Semicolon, RCurlyBrace, nonstrict)) } #[recursive_descent_method] fn expression(&mut self) -> ParseResult { let mut expr_body = self.precedence_expr(BinOp::min_precedence())?; let type_anno = match self.peek() { Colon => Some(self.type_anno()?), _ => None }; if let Some(_) = expr_body.1 { return ParseError::new("Bad parse state"); } expr_body.1 = type_anno; Ok(expr_body) } #[recursive_descent_method] fn type_anno(&mut self) -> ParseResult { expect!(self, Colon); self.type_name() } #[recursive_descent_method] fn type_name(&mut self) -> ParseResult { use self::TypeIdentifier::*; Ok(match self.peek() { LParen => Tuple(delimited!(self, LParen, type_name, Comma, RParen)), _ => Singleton(self.type_singleton_name()?), }) } #[recursive_descent_method] fn type_singleton_name(&mut self) -> ParseResult { Ok(TypeSingletonName { name: self.identifier()?, params: match self.peek() { LAngleBracket => delimited!(self, LAngleBracket, type_name, Comma, RAngleBracket), _ => vec![], } }) } // this implements Pratt parsing, see http://journal.stuffwithstuff.com/2011/03/19/pratt-parsers-expression-parsing-made-easy/ fn precedence_expr(&mut self, precedence: i32) -> ParseResult { let record = ParseRecord { production_name: "precedence_expr".to_string(), next_token: format!("{}", self.peek_with_token_offset().to_string_with_metadata()), level: self.parse_level, }; self.parse_level += 1; self.parse_record.push(record); let mut lhs = self.prefix_expr()?; loop { let new_precedence = match BinOp::get_precedence_from_token(&self.peek()) { Some(p) => p, None => break, }; if precedence >= new_precedence { break; } let operation = match BinOp::from_sigil_token(&self.next()) { Some(sigil) => sigil, None => unreachable!() }; let rhs = self.precedence_expr(new_precedence)?; lhs = Expression(ExpressionType::BinExp(operation, bx!(lhs), bx!(rhs)), None); } self.parse_level -= 1; Ok(lhs) } #[recursive_descent_method] fn prefix_expr(&mut self) -> ParseResult { match self.peek() { Operator(ref op) if PrefixOp::is_prefix(&*op) => { let sigil = match self.next() { Operator(op) => op, _ => unreachable!(), }; let expr = self.primary()?; Ok(Expression( ExpressionType::PrefixExp(PrefixOp::from_sigil(sigil.as_str()), bx!(expr)), None)) }, _ => self.call_expr() } } #[recursive_descent_method] fn call_expr(&mut self) -> ParseResult { let index = self.index_expr()?; Ok(if let LParen = self.peek() { let arguments = delimited!(self, LParen, expression, Comma, RParen); Expression(ExpressionType::Call { f: bx!(index), arguments }, None) //TODO fix this none } else { index }) } #[recursive_descent_method] fn index_expr(&mut self) -> ParseResult { let primary = self.primary()?; Ok(if let LSquareBracket = self.peek() { let indexers = delimited!(self, LSquareBracket, expression, Comma, RSquareBracket); Expression(ExpressionType::Index { indexee: bx!(Expression(primary.0, None)), indexers, }, None) } else { primary }) } #[recursive_descent_method] fn primary(&mut self) -> ParseResult { match self.peek() { LCurlyBrace => self.curly_brace_expr(), Backslash => self.lambda_expr(), LParen => self.paren_expr(), LSquareBracket => self.list_expr(), Keyword(Kw::If) => self.if_expr(), Keyword(Kw::For) => self.for_expr(), Keyword(Kw::While) => self.while_expr(), Identifier(_) => self.identifier_expr(), _ => self.literal(), } } #[recursive_descent_method] fn list_expr(&mut self) -> ParseResult { let exprs = delimited!(self, LSquareBracket, expression, Comma, RSquareBracket); Ok(Expression(ExpressionType::ListLiteral(exprs), None)) } #[recursive_descent_method] fn curly_brace_expr(&mut self) -> ParseResult { ParseError::new("Not implemented") } #[recursive_descent_method] fn lambda_expr(&mut self) -> ParseResult { expect!(self, Backslash); let params = self.formal_param_list()?; //TODO make this allow some more concise syntaxes let body = self.nonempty_func_body()?; /* let mut body = Vec::new(); loop { match self.peek() { EOF | RCurlyBrace => break, Newline | Semicolon => { self.next(); continue; }, _ => body.push(self.statement()?), } } expect!(self, RCurlyBrace); */ Ok(Expression(ExpressionType::Lambda { params, body }, None)) //TODO need to handle types somehow } #[recursive_descent_method] fn paren_expr(&mut self) -> ParseResult { use self::ExpressionType::*; let old_struct_value = self.restrictions.no_struct_literal; self.restrictions.no_struct_literal = false; let output = { let mut inner = delimited!(self, LParen, expression, Comma, RParen); match inner.len() { 0 => Ok(Expression(TupleLiteral(vec![]), None)), 1 => Ok(inner.pop().unwrap()), _ => Ok(Expression(TupleLiteral(inner), None)), } }; self.restrictions.no_struct_literal = old_struct_value; output } #[recursive_descent_method] fn identifier_expr(&mut self) -> ParseResult { use self::ExpressionType::*; let identifier = self.identifier()?; Ok(match self.peek() { LCurlyBrace if !self.restrictions.no_struct_literal => { let fields = self.record_block()?; Expression(NamedStruct { name: identifier, fields }, None) }, _ => Expression(Value(identifier), None) }) } #[recursive_descent_method] fn record_block(&mut self) -> ParseResult, Expression)>> { Ok(delimited!(self, LCurlyBrace, record_entry, Comma, RCurlyBrace)) } #[recursive_descent_method] fn record_entry(&mut self) -> ParseResult<(Rc, Expression)> { let field_name = self.identifier()?; expect!(self, Colon); let value = self.expression()?; Ok((field_name, value)) } #[recursive_descent_method] fn if_expr(&mut self) -> ParseResult { expect!(self, Keyword(Kw::If)); let discriminator = Box::new({ self.restrictions.no_struct_literal = true; let x = self.discriminator(); self.restrictions.no_struct_literal = false; x? }); let body = Box::new(match self.peek() { Keyword(Kw::Then) => self.conditional()?, Keyword(Kw::Is) => self.simple_pattern_match()? , _ => self.guard_block()? }); Ok(Expression(ExpressionType::IfExpression { discriminator, body }, None)) } #[recursive_descent_method] fn discriminator(&mut self) -> ParseResult { let lhs = self.prefix_expr()?; let ref next = self.peek(); Ok(if let Some(op) = BinOp::from_sigil_token(next) { Discriminator::BinOp(lhs, op) } else { Discriminator::Simple(lhs) }) } #[recursive_descent_method] fn conditional(&mut self) -> ParseResult { expect!(self, Keyword(Kw::Then)); let then_clause = self.expr_or_block()?; let else_clause = self.else_clause()?; Ok(IfExpressionBody::SimpleConditional(then_clause, else_clause)) } #[recursive_descent_method] fn simple_pattern_match(&mut self) -> ParseResult { expect!(self, Keyword(Kw::Is)); let pat = self.pattern()?; expect!(self, Keyword(Kw::Then)); let then_clause = self.expr_or_block()?; let else_clause = self.else_clause()?; Ok(IfExpressionBody::SimplePatternMatch(pat, then_clause, else_clause)) } #[recursive_descent_method] fn else_clause(&mut self) -> ParseResult> { Ok(if let Keyword(Kw::Else) = self.peek() { self.next(); Some(self.expr_or_block()?) } else { None }) } #[recursive_descent_method] fn guard_block(&mut self) -> ParseResult { //TODO - delimited! isn't sophisticated enough to do thisa //let guards = delimited!(self, LCurlyBrace, guard_arm, Comma, RCurlyBrace); expect!(self, LCurlyBrace); let mut guards = vec![]; loop { match self.peek() { RCurlyBrace | EOF => break, Semicolon | Newline => { self.next(); continue}, _ => { let guard_arm = self.guard_arm()?; guards.push(guard_arm); loop { match self.peek() { Semicolon | Newline => { self.next(); continue; }, _ => break, } } if let RCurlyBrace = self.peek() { break; } expect!(self, Comma); } } } expect!(self, RCurlyBrace); Ok(IfExpressionBody::GuardList(guards)) } #[recursive_descent_method] fn guard_arm(&mut self) -> ParseResult { let guard = self.guard()?; expect!(self, Operator(ref c) if **c == "->"); let body = self.expr_or_block()?; Ok(GuardArm { guard, body }) } #[recursive_descent_method] fn guard(&mut self) -> ParseResult { Ok(match self.peek() { Keyword(Kw::Is) => { self.next(); let pat = self.pattern()?; Guard::Pat(pat) }, ref tok if BinOp::from_sigil_token(tok).is_some() => { let op = BinOp::from_sigil_token(&self.next()).unwrap(); let precedence = op.get_precedence(); let Expression(expr, _) = self.precedence_expr(precedence)?; Guard::HalfExpr(HalfExpr { op: Some(op), expr }) }, _ => { //TODO - I think there's a better way to do this involving the precedence of -> let Expression(expr, _) = self.prefix_expr()?; Guard::HalfExpr(HalfExpr { op: None, expr }) } }) } #[recursive_descent_method] fn pattern(&mut self) -> ParseResult { if let LParen = self.peek() { let tuple_pattern_variants = delimited!(self, LParen, pattern, Comma, RParen); Ok(Pattern::TuplePattern(tuple_pattern_variants)) } else { self.simple_pattern() } } #[recursive_descent_method] fn simple_pattern(&mut self) -> ParseResult { Ok(match self.peek() { Identifier(_) => { let id = self.identifier()?; match self.peek() { LCurlyBrace => { let members = delimited!(self, LCurlyBrace, record_pattern_entry, Comma, RCurlyBrace); Pattern::Record(id, members) }, LParen => { let members = delimited!(self, LParen, pattern, Comma, RParen); Pattern::TupleStruct(id, members) }, _ => Pattern::Literal(PatternLiteral::VarPattern(id)) } }, Keyword(Kw::True) => { self.next(); Pattern::Literal(PatternLiteral::BoolPattern(true)) }, Keyword(Kw::False) => { self.next(); Pattern::Literal(PatternLiteral::BoolPattern(false)) }, StrLiteral(s) => { self.next(); Pattern::Literal(PatternLiteral::StringPattern(s)) }, DigitGroup(_) | HexLiteral(_) | BinNumberSigil | Period => self.signed_number_literal()?, Operator(ref op) if **op == "-" => self.signed_number_literal()?, Underscore => { self.next(); Pattern::Ignored }, other => return ParseError::new(&format!("{:?} is not a valid Pattern", other)) }) } #[recursive_descent_method] fn signed_number_literal(&mut self) -> ParseResult { let neg = match self.peek() { Operator(ref op) if **op == "-" => { self.next(); true }, _ => false }; let Expression(expr_type, _) = self.number_literal()?; Ok(Pattern::Literal(PatternLiteral::NumPattern { neg, num: expr_type })) } #[recursive_descent_method] fn record_pattern_entry(&mut self) -> ParseResult<(Rc, Pattern)> { let name = self.identifier()?; Ok(match self.peek() { Colon => { expect!(self, Colon); let pat = self.pattern()?; (name, pat) }, _ => (name.clone(), Pattern::Literal(PatternLiteral::StringPattern(name.clone()))) }) } #[recursive_descent_method] fn block(&mut self) -> ParseResult { Ok(delimited!(self, LCurlyBrace, statement, Newline | Semicolon, RCurlyBrace, nonstrict)) } #[recursive_descent_method] fn expr_or_block(&mut self) -> ParseResult { match self.peek() { LCurlyBrace => self.block(), _ => { let expr = self.expression()?; Ok(vec![Statement::ExpressionStatement(expr)]) } } } #[recursive_descent_method] fn while_expr(&mut self) -> ParseResult { use self::ExpressionType::*; expect!(self, Keyword(Kw::While)); let condition = { self.restrictions.no_struct_literal = true; let x = self.while_cond(); self.restrictions.no_struct_literal = false; x?.map(|expr| bx!(expr)) }; let body = self.block()?; Ok(Expression(WhileExpression {condition, body}, None)) } #[recursive_descent_method] fn while_cond(&mut self) -> ParseResult> { Ok(match self.peek() { LCurlyBrace => None, _ => Some(self.expression()?), }) } #[recursive_descent_method] fn for_expr(&mut self) -> ParseResult { expect!(self, Keyword(Kw::For)); let enumerators = if let LCurlyBrace = self.peek() { delimited!(self, LCurlyBrace, enumerator, Comma | Newline, RCurlyBrace) } else { let single_enum = { self.restrictions.no_struct_literal = true; let s = self.enumerator(); self.restrictions.no_struct_literal = false; s? }; vec![single_enum] }; let body = Box::new(self.for_expr_body()?); Ok(Expression(ExpressionType::ForExpression { enumerators, body }, None)) } #[recursive_descent_method] fn enumerator(&mut self) -> ParseResult { let id = self.identifier()?; expect!(self, Operator(ref c) if **c == "<-"); let generator = self.expression()?; Ok(Enumerator { id, generator }) } #[recursive_descent_method] fn for_expr_body(&mut self) -> ParseResult { use self::ForBody::*; Ok(match self.peek() { LCurlyBrace => { let statements = delimited!(self, LCurlyBrace, statement, Newline | Semicolon, RCurlyBrace, nonstrict); StatementBlock(statements) }, Keyword(Kw::Return) => { self.next(); MonadicReturn(self.expression()?) }, _ => return ParseError::new("for expressions must end in a block or 'return'"), }) } #[recursive_descent_method] fn identifier(&mut self) -> ParseResult> { match self.next() { Identifier(s) => Ok(s), p => ParseError::new(&format!("Expected an identifier, got {:?}", p)), } } #[recursive_descent_method] fn literal(&mut self) -> ParseResult { use self::ExpressionType::*; match self.peek() { DigitGroup(_) | HexLiteral(_) | BinNumberSigil | Period => self.number_literal(), Keyword(Kw::True) => { self.next(); Ok(Expression(BoolLiteral(true), None)) }, Keyword(Kw::False) => { self.next(); Ok(Expression(BoolLiteral(false), None)) }, StrLiteral(s) => { self.next(); Ok(Expression(StringLiteral(s), None)) } e => ParseError::new(&format!("Expected a literal expression, got {:?}", e)), } } #[recursive_descent_method] fn number_literal(&mut self) -> ParseResult { match self.peek() { HexLiteral(_) | BinNumberSigil => self.int_literal(), _ => self.float_literal(), } } #[recursive_descent_method] fn int_literal(&mut self) -> ParseResult { use self::ExpressionType::*; match self.next() { BinNumberSigil => { let digits = self.digits()?; let n = parse_binary(digits)?; Ok(Expression(NatLiteral(n), None)) }, HexLiteral(text) => { let digits: String = text.chars().filter(|c| c.is_digit(16)).collect(); let n = parse_hex(digits)?; Ok(Expression(NatLiteral(n), None)) }, _ => return ParseError::new("Expected '0x' or '0b'"), } } #[recursive_descent_method] fn float_literal(&mut self) -> ParseResult { use self::ExpressionType::*; let mut digits = self.digits()?; if let TokenType::Period = self.peek() { self.next(); digits.push_str("."); digits.push_str(&self.digits()?); match digits.parse::() { Ok(f) => Ok(Expression(FloatLiteral(f), None)), Err(e) => ParseError::new(&format!("Float failed to parse with error: {}", e)), } } else { match digits.parse::() { Ok(d) => Ok(Expression(NatLiteral(d), None)), Err(e) => ParseError::new(&format!("Integer failed to parse with error: {}", e)), } } } #[recursive_descent_method] fn digits(&mut self) -> ParseResult { let mut ds = String::new(); loop { match self.peek() { Underscore => { self.next(); continue; }, DigitGroup(ref s) => { self.next(); ds.push_str(s)}, _ => break, } } Ok(ds) } } fn parse_binary(digits: String) -> ParseResult { let mut result: u64 = 0; let mut multiplier = 1; for d in digits.chars().rev() { match d { '1' => result += multiplier, '0' => (), _ => return ParseError::new("Encountered a character not '1' or '0 while parsing a binary literal"), } multiplier = match multiplier.checked_mul(2) { Some(m) => m, None => return ParseError::new("This binary expression will overflow") } } Ok(result) } fn parse_hex(digits: String) -> ParseResult { let mut result: u64 = 0; let mut multiplier: u64 = 1; for d in digits.chars().rev() { match d.to_digit(16) { Some(n) => result += n as u64 * multiplier, None => return ParseError::new("Encountered a non-hex digit in a hex literal"), } multiplier = match multiplier.checked_mul(16) { Some(m) => m, None => return ParseError::new("This hex expression will overflow") } } Ok(result) } #[cfg(test)] mod parse_tests { use ::std::rc::Rc; use super::tokenize; use super::ParseResult; use builtin::{PrefixOp, BinOp}; use ast::{AST, Expression, Statement, IfExpressionBody, Discriminator, Pattern, PatternLiteral, TypeBody, Enumerator, ForBody}; use super::Statement::*; use super::Declaration::*; use super::Signature; use super::TypeIdentifier::*; use super::TypeSingletonName; use super::ExpressionType::*; use super::Variant::*; use super::ForBody::*; fn parse(tokens: Vec<::tokenizing::Token>) -> ParseResult { let mut parser = super::Parser::new(tokens); parser.parse() } macro_rules! rc { ($string:tt) => { Rc::new(stringify!($string).to_string()) } } macro_rules! parse_test { ($string:expr, $correct:expr) => { assert_eq!(parse(tokenize($string)).unwrap(), $correct) } } macro_rules! parse_error { ($string:expr) => { assert!(parse(tokenize($string)).is_err()) } } macro_rules! val { ($var:expr) => { Value(Rc::new($var.to_string())) } } macro_rules! exprstatement { ($expr_type:expr) => { Statement::ExpressionStatement(Expression($expr_type, None)) }; ($expr_type:expr, $type_anno:expr) => { Statement::ExpressionStatement(Expression($expr_type, Some($type_anno))) }; } macro_rules! ty { ($name:expr) => { Singleton(tys!($name)) } } macro_rules! tys { ($name:expr) => { TypeSingletonName { name: Rc::new($name.to_string()), params: vec![] } }; } /* new style of test macros */ macro_rules! single_expr { ($exprtype:expr) => { AST(vec![Statement::ExpressionStatement(Expression($exprtype, None))]) }; ($exprtype:expr, $type:expr) => { AST(vec![Statement::ExpressionStatement(Expression($exprtype, $type))]) } } macro_rules! ex { ($expr_type:expr) => { Expression($expr_type, None) } } macro_rules! binexp { ($op:expr, $lhs:expr, $rhs:expr) => { BinExp(BinOp::from_sigil($op), bx!(Expression($lhs, None)), bx!(Expression($rhs, None))) } } macro_rules! prefexp { ($op:expr, $lhs:expr) => { PrefixExp(PrefixOp::from_sigil($op), bx!(Expression($lhs, None))) } } macro_rules! exst { ($expr_type:expr) => { Statement::ExpressionStatement(Expression($expr_type, None)) }; ($expr_type:expr, $type_anno:expr) => { Statement::ExpressionStatement(Expression($expr_type, Some($type_anno))) }; ($op:expr, $lhs:expr, $rhs:expr) => { Statement::ExpressionStatement(ex!(binexp!($op, $lhs, $rhs))) }; } #[test] fn parsing_number_literals_and_binexps() { parse_test! { ".2", single_expr!(FloatLiteral(0.2)) }; parse_test! { "8.1", single_expr!(FloatLiteral(8.1)) }; parse_test! { "0b010", single_expr!(NatLiteral(2)) }; parse_test! { "0b0_1_0_", single_expr!(NatLiteral(2)) } parse_test! {"0xff", single_expr!(NatLiteral(255)) }; parse_test! {"0xf_f_", single_expr!(NatLiteral(255)) }; parse_test!("0xf_f_+1", AST(vec![exprstatement!(binexp!("+", NatLiteral(255), NatLiteral(1)))])); parse_test! {"3; 4; 4.3", AST( vec![exprstatement!(NatLiteral(3)), exprstatement!(NatLiteral(4)), exprstatement!(FloatLiteral(4.3))]) }; parse_test!("1 + 2 * 3", AST(vec! [ exprstatement!(binexp!("+", NatLiteral(1), binexp!("*", NatLiteral(2), NatLiteral(3)))) ])); parse_test!("1 * 2 + 3", AST(vec! [ exprstatement!(binexp!("+", binexp!("*", NatLiteral(1), NatLiteral(2)), NatLiteral(3))) ])); parse_test!("1 && 2", AST(vec![exprstatement!(binexp!("&&", NatLiteral(1), NatLiteral(2)))])); parse_test!("1 + 2 * 3 + 4", AST(vec![exprstatement!( binexp!("+", binexp!("+", NatLiteral(1), binexp!("*", NatLiteral(2), NatLiteral(3))), NatLiteral(4)))])); parse_test!("(1 + 2) * 3", AST(vec! [exprstatement!(binexp!("*", binexp!("+", NatLiteral(1), NatLiteral(2)), NatLiteral(3)))])); parse_test!(".1 + .2", AST(vec![exprstatement!(binexp!("+", FloatLiteral(0.1), FloatLiteral(0.2)))])); parse_test!("1 / 2", AST(vec![exprstatement!(binexp!("/", NatLiteral(1), NatLiteral(2)))])); } #[test] fn parsing_tuples() { parse_test!("()", AST(vec![exprstatement!(TupleLiteral(vec![]))])); parse_test!("(\"hella\", 34)", AST(vec![exprstatement!( TupleLiteral( vec![ex!(StringLiteral(rc!(hella))), ex!(NatLiteral(34))] ) )])); parse_test!("((1+2), \"slough\")", AST(vec![exprstatement!(TupleLiteral(vec![ ex!(binexp!("+", NatLiteral(1), NatLiteral(2))), ex!(StringLiteral(rc!(slough))), ]))])) } #[test] fn parsing_identifiers() { parse_test!("a", AST(vec![exprstatement!(val!("a"))])); parse_test!("a + b", AST(vec![exprstatement!(binexp!("+", val!("a"), val!("b")))])); //parse_test!("a[b]", AST(vec![Expression( //parse_test!("a[]", <- TODO THIS NEEDS TO FAIL //parse_test!(damn()[a] ,<- TODO needs to succeed parse_test!("a[b,c]", AST(vec![exprstatement!(Index { indexee: bx!(ex!(val!("a"))), indexers: vec![ex!(val!("b")), ex!(val!("c"))]} )])); parse_test!("None", AST(vec![exprstatement!(val!("None"))])); parse_test!("Pandas { a: x + y }", AST(vec![ exprstatement!(NamedStruct { name: rc!(Pandas), fields: vec![(rc!(a), ex!(binexp!("+", val!("x"), val!("y"))))]}) ])); } #[test] fn parsing_complicated_operators() { parse_test!("a <- b", AST(vec![exprstatement!(binexp!("<-", val!("a"), val!("b")))])); parse_test!("a || b", AST(vec![exprstatement!(binexp!("||", val!("a"), val!("b")))])); parse_test!("a<>b", AST(vec![exprstatement!(binexp!("<>", val!("a"), val!("b")))])); parse_test!("a.b.c.d", AST(vec![exprstatement!(binexp!(".", binexp!(".", binexp!(".", val!("a"), val!("b")), val!("c")), val!("d")))])); parse_test!("-3", AST(vec![exprstatement!(prefexp!("-", NatLiteral(3)))])); parse_test!("-0.2", AST(vec![exprstatement!(prefexp!("-", FloatLiteral(0.2)))])); parse_test!("!3", AST(vec![exprstatement!(prefexp!("!", NatLiteral(3)))])); parse_test!("a <- -b", AST(vec![exprstatement!(binexp!("<-", val!("a"), prefexp!("-", val!("b"))))])); parse_test!("a <--b", AST(vec![exprstatement!(binexp!("<--", val!("a"), val!("b")))])); } #[test] fn parsing_functions() { parse_test!("fn oi()", AST(vec![Declaration(FuncSig(Signature { name: rc!(oi), operator: false, params: vec![], type_anno: None }))])); parse_test!("oi()", AST(vec![exprstatement!(Call { f: bx!(ex!(val!("oi"))), arguments: vec![] })])); parse_test!("oi(a, 2 + 2)", AST(vec![exprstatement!(Call { f: bx!(ex!(val!("oi"))), arguments: vec![ex!(val!("a")), ex!(binexp!("+", NatLiteral(2), NatLiteral(2)))] })])); parse_error!("a(b,,c)"); parse_test!("fn a(b, c: Int): Int", AST(vec![Declaration( FuncSig(Signature { name: rc!(a), operator: false, params: vec![ (rc!(b), None), (rc!(c), Some(ty!("Int"))) ], type_anno: Some(ty!("Int")) }))])); parse_test!("fn a(x) { x() }", AST(vec![Declaration( FuncDecl(Signature { name: rc!(a), operator: false, params: vec![(rc!(x),None)], type_anno: None }, vec![exprstatement!(Call { f: bx!(ex!(val!("x"))), arguments: vec![] })]))])); parse_test!("fn a(x) {\n x() }", AST(vec![Declaration( FuncDecl(Signature { name: rc!(a), operator: false, params: vec![(rc!(x),None)], type_anno: None }, vec![exprstatement!(Call { f: bx!(ex!(val!("x"))), arguments: vec![] })]))])); let multiline = r#" fn a(x) { x() } "#; parse_test!(multiline, AST(vec![Declaration( FuncDecl(Signature { name: rc!(a), operator: false, params: vec![(rc!(x),None)], type_anno: None }, vec![exprstatement!(Call { f: bx!(ex!(val!("x"))), arguments: vec![] })]))])); let multiline2 = r#" fn a(x) { x() } "#; parse_test!(multiline2, AST(vec![Declaration( FuncDecl(Signature { name: rc!(a), operator: false, params: vec![(rc!(x),None)], type_anno: None }, vec![exprstatement!(Call { f: bx!(ex!(val!("x"))), arguments: vec![] })]))])); } #[test] fn parsing_bools() { parse_test!("false", AST(vec![exprstatement!(BoolLiteral(false))])); parse_test!("true", AST(vec![exprstatement!(BoolLiteral(true))])); } #[test] fn parsing_strings() { parse_test!(r#""hello""#, AST(vec![exprstatement!(StringLiteral(rc!(hello)))])); } #[test] fn parsing_types() { parse_test!("type Yolo = Yolo", AST(vec![Declaration(TypeDecl { name: tys!("Yolo"), body: TypeBody(vec![UnitStruct(rc!(Yolo))]), mutable: false} )])); parse_test!("type mut Yolo = Yolo", AST(vec![Declaration(TypeDecl { name: tys!("Yolo"), body: TypeBody(vec![UnitStruct(rc!(Yolo))]), mutable: true} )])); parse_test!("type alias Sex = Drugs", AST(vec![Declaration(TypeAlias(rc!(Sex), rc!(Drugs)))])); parse_test!("type Sanchez = Miguel | Alejandro(Int, Option) | Esperanza { a: Int, b: String }", AST(vec![Declaration(TypeDecl{ name: tys!("Sanchez"), body: TypeBody(vec![ UnitStruct(rc!(Miguel)), TupleStruct(rc!(Alejandro), vec![ Singleton(TypeSingletonName { name: rc!(Int), params: vec![] }), Singleton(TypeSingletonName { name: rc!(Option), params: vec![Singleton(TypeSingletonName { name: rc!(a), params: vec![] })] }), ]), Record(rc!(Esperanza), vec![ (rc!(a), Singleton(TypeSingletonName { name: rc!(Int), params: vec![] })), (rc!(b), Singleton(TypeSingletonName { name: rc!(String), params: vec![] })), ]) ]), mutable: false })])); parse_test!("type Jorge = Diego | Kike(a)", AST(vec![ Declaration(TypeDecl{ name: TypeSingletonName { name: rc!(Jorge), params: vec![Singleton(TypeSingletonName { name: rc!(a), params: vec![] })] }, body: TypeBody(vec![UnitStruct(rc!(Diego)), TupleStruct(rc!(Kike), vec![Singleton(TypeSingletonName { name: rc!(a), params: vec![] })])]), mutable: false } )])); } #[test] fn parsing_bindings() { parse_test!("let mut a = 10", AST(vec![Declaration(Binding { name: rc!(a), constant: false, expr: ex!(NatLiteral(10)) } )])); parse_test!("let a = 2 + 2", AST(vec![Declaration(Binding { name: rc!(a), constant: true, expr: ex!(binexp!("+", NatLiteral(2), NatLiteral(2))) }) ])); } #[test] fn parsing_block_expressions() { parse_test! { "if a() then { b(); c() }", AST(vec![exprstatement!( IfExpression { discriminator: bx! { Discriminator::Simple(ex!(Call { f: bx!(ex!(val!("a"))), arguments: vec![]})) }, body: bx! { IfExpressionBody::SimpleConditional( vec![exprstatement!(Call { f: bx!(ex!(val!("b"))), arguments: vec![]}), exprstatement!(Call { f: bx!(ex!(val!("c"))), arguments: vec![] })], None ) } } )]) }; parse_test! { "if a() then { b(); c() } else { q }", AST(vec![exprstatement!( IfExpression { discriminator: bx! { Discriminator::Simple(ex!(Call { f: bx!(ex!(val!("a"))), arguments: vec![]})) }, body: bx! { IfExpressionBody::SimpleConditional( vec![exprstatement!(Call { f: bx!(ex!(val!("b"))), arguments: vec![]}), exprstatement!(Call { f: bx!(ex!(val!("c"))), arguments: vec![] })], Some( vec![exprstatement!(val!("q"))], ) ) } } )]) }; /* parse_test!("if a() then { b(); c() }", AST(vec![exprstatement!( IfExpression(bx!(ex!(Call { f: bx!(ex!(val!("a"))), arguments: vec![]})), vec![exprstatement!(Call { f: bx!(ex!(val!("b"))), arguments: vec![]}), exprstatement!(Call { f: bx!(ex!(val!("c"))), arguments: vec![] })], None) )])); parse_test!(r#" if true then { const a = 10 b } else { c }"#, AST(vec![exprstatement!(IfExpression(bx!(ex!(BoolLiteral(true))), vec![Declaration(Binding { name: rc!(a), constant: true, expr: ex!(NatLiteral(10)) }), exprstatement!(val!(rc!(b)))], Some(vec![exprstatement!(val!(rc!(c)))])))]) ); parse_test!("if a { b } else { c }", AST(vec![exprstatement!( IfExpression(bx!(ex!(val!("a"))), vec![exprstatement!(val!("b"))], Some(vec![exprstatement!(val!("c"))])))])); parse_test!("if (A {a: 1}) { b } else { c }", AST(vec![exprstatement!( IfExpression(bx!(ex!(NamedStruct { name: rc!(A), fields: vec![(rc!(a), ex!(NatLiteral(1)))]})), vec![exprstatement!(val!("b"))], Some(vec![exprstatement!(val!("c"))])))])); parse_error!("if A {a: 1} { b } else { c }"); */ } #[test] fn parsing_interfaces() { parse_test!("interface Unglueable { fn unglue(a: Glue); fn mar(): Glue }", AST(vec![ Declaration(Interface { name: rc!(Unglueable), signatures: vec![ Signature { name: rc!(unglue), operator: false, params: vec![(rc!(a), Some(Singleton(TypeSingletonName { name: rc!(Glue), params: vec![] })))], type_anno: None }, Signature { name: rc!(mar), operator: false, params: vec![], type_anno: Some(Singleton(TypeSingletonName { name: rc!(Glue), params: vec![] })) }, ] }) ])); } #[test] fn parsing_impls() { parse_test!("impl Heh { fn yolo(); fn swagg(); }", AST(vec![ Declaration(Impl { type_name: ty!("Heh"), interface_name: None, block: vec![ FuncSig(Signature { name: rc!(yolo), operator: false, params: vec![], type_anno: None }), FuncSig(Signature { name: rc!(swagg), operator: false, params: vec![], type_anno: None }) ] })])); parse_test!("impl Mondai for Lollerino { fn yolo(); fn swagg(); }", AST(vec![ Declaration(Impl { type_name: ty!("Lollerino"), interface_name: Some(rc!(Mondai)), block: vec![ FuncSig(Signature { name: rc!(yolo), operator: false, params: vec![], type_anno: None}), FuncSig(Signature { name: rc!(swagg), operator: false, params: vec![], type_anno: None }) ] })])); parse_test!("impl Option { fn oi() }", AST(vec![ Declaration(Impl { type_name: Singleton(TypeSingletonName { name: rc!(Option), params: vec![ty!("WTFMate")]}), interface_name: None, block: vec![ FuncSig(Signature { name: rc!(oi), operator: false, params: vec![], type_anno: None }), ] })])); } #[test] fn parsing_type_annotations() { parse_test!("let a = b : Int", AST(vec![ Declaration(Binding { name: rc!(a), constant: true, expr: Expression(val!("b"), Some(ty!("Int"))) })])); parse_test!("a : Int", AST(vec![ exprstatement!(val!("a"), ty!("Int")) ])); parse_test!("a : Option", AST(vec![ exprstatement!(val!("a"), Singleton(TypeSingletonName { name: rc!(Option), params: vec![ty!("Int")] })) ])); parse_test!("a : KoreanBBQSpecifier >", AST(vec![ exprstatement!(val!("a"), Singleton(TypeSingletonName { name: rc!(KoreanBBQSpecifier), params: vec![ ty!("Kimchi"), Singleton(TypeSingletonName { name: rc!(Option), params: vec![ty!("Bulgogi")] }) ] })) ])); parse_test!("a : (Int, Yolo)", AST(vec![ exprstatement!(val!("a"), Tuple( vec![ty!("Int"), Singleton(TypeSingletonName { name: rc!(Yolo), params: vec![ty!("a")] })]))])); } #[test] fn parsing_lambdas() { parse_test! { r#"\(x) { x + 1}"#, single_expr!( Lambda { params: vec![(rc!(x), None)], body: vec![exst!("+", val!("x"), NatLiteral(1))] } ) } parse_test!(r#"\ (x: Int, y) { a;b;c;}"#, AST(vec![ exprstatement!(Lambda { params: vec![(rc!(x), Some(ty!("Int"))), (rc!(y), None)], body: vec![exst!(val!("a")), exst!(val!("b")), exst!(val!("c"))] }) ])); parse_test!(r#"\(x){y}(1)"#, AST(vec![ exprstatement!(Call { f: bx!(ex!( Lambda { params: vec![(rc!(x), None)], body: vec![exprstatement!(val!("y"))] })), arguments: vec![ex!(NatLiteral(1))] })])); } #[test] fn list_literals() { parse_test! { "[1,2]", AST(vec![ exprstatement!(ListLiteral(vec![ex!(NatLiteral(1)), ex!(NatLiteral(2))]))]) }; } #[test] fn while_expr() { parse_test! { "while { }", AST(vec![ exprstatement!(WhileExpression { condition: None, body: vec![] })]) } parse_test! { "while a == b { }", AST(vec![ exprstatement!(WhileExpression { condition: Some(bx![ex![binexp!("==", val!("a"), val!("b"))]]), body: vec![] })]) } } #[test] fn for_expr() { parse_test! { "for { a <- maybeValue } return 1", AST(vec![ exprstatement!(ForExpression { enumerators: vec![Enumerator { id: rc!(a), generator: ex!(val!("maybeValue")) }], body: bx!(MonadicReturn(ex!(NatLiteral(1)))) })]) } parse_test! { "for n <- someRange { f(n); }", AST(vec![ exprstatement!(ForExpression { enumerators: vec![Enumerator { id: rc!(n), generator: ex!(val!("someRange"))}], body: bx!(ForBody::StatementBlock(vec![exprstatement!(Call { f: bx![ex!(val!("f"))], arguments: vec![ex!(val!("n"))] })])) })]) } } #[test] fn patterns() { parse_test! { "if x is Some(a) then { 4 } else { 9 }", AST(vec![ exprstatement!( IfExpression { discriminator: bx!(Discriminator::Simple(ex!(Value(rc!(x))))), body: bx!(IfExpressionBody::SimplePatternMatch(Pattern::TupleStruct(rc!(Some), vec![Pattern::Literal(PatternLiteral::VarPattern(rc!(a)))]), vec![exprstatement!(NatLiteral(4))], Some(vec![exprstatement!(NatLiteral(9))]))) } ) ]) } parse_test! { "if x is Some(a) then 4 else 9", AST(vec![ exprstatement!( IfExpression { discriminator: bx!(Discriminator::Simple(ex!(Value(rc!(x))))), body: bx!(IfExpressionBody::SimplePatternMatch(Pattern::TupleStruct(rc!(Some), vec![Pattern::Literal(PatternLiteral::VarPattern(rc!(a)))]), vec![exprstatement!(NatLiteral(4))], Some(vec![exprstatement!(NatLiteral(9))]))) } ) ]) } parse_test! { "if x is Something { a, b: x } then { 4 } else { 9 }", AST(vec![ exprstatement!( IfExpression { discriminator: bx!(Discriminator::Simple(ex!(Value(rc!(x))))), body: bx!(IfExpressionBody::SimplePatternMatch( Pattern::Record(rc!(Something), vec![ (rc!(a),Pattern::Literal(PatternLiteral::StringPattern(rc!(a)))), (rc!(b),Pattern::Literal(PatternLiteral::VarPattern(rc!(x)))) ]), vec![exprstatement!(NatLiteral(4))], Some(vec![exprstatement!(NatLiteral(9))]))) } ) ]) } } #[test] fn pattern_literals() { parse_test! { "if x is -1 then 1 else 2", AST(vec![ exprstatement!( IfExpression { discriminator: bx!(Discriminator::Simple(ex!(Value(rc!(x))))), body: bx!(IfExpressionBody::SimplePatternMatch( Pattern::Literal(PatternLiteral::NumPattern { neg: true, num: NatLiteral(1) }), vec![exprstatement!(NatLiteral(1))], Some(vec![exprstatement!(NatLiteral(2))]), )) } ) ]) } parse_test! { "if x is 1 then 1 else 2", AST(vec![ exprstatement!( IfExpression { discriminator: bx!(Discriminator::Simple(ex!(Value(rc!(x))))), body: bx!(IfExpressionBody::SimplePatternMatch( Pattern::Literal(PatternLiteral::NumPattern { neg: false, num: NatLiteral(1) }), vec![exprstatement!(NatLiteral(1))], Some(vec![exprstatement!(NatLiteral(2))]), )) } ) ]) } parse_test! { "if x is true then 1 else 2", AST(vec![ exprstatement!( IfExpression { discriminator: bx!(Discriminator::Simple(ex!(Value(rc!(x))))), body: bx!(IfExpressionBody::SimplePatternMatch( Pattern::Literal(PatternLiteral::BoolPattern(true)), vec![exprstatement!(NatLiteral(1))], Some(vec![exprstatement!(NatLiteral(2))]), )) } ) ]) } parse_test! { "if x is \"gnosticism\" then 1 else 2", AST(vec![ exprstatement!( IfExpression { discriminator: bx!(Discriminator::Simple(ex!(Value(rc!(x))))), body: bx!(IfExpressionBody::SimplePatternMatch( Pattern::Literal(PatternLiteral::StringPattern(rc!(gnosticism))), vec![exprstatement!(NatLiteral(1))], Some(vec![exprstatement!(NatLiteral(2))]), )) } ) ]) } } }