use super::*; // test expr_literals // fn foo() { // let _ = true; // let _ = false; // let _ = 1; // let _ = 2.0; // let _ = b'a'; // let _ = 'b'; // let _ = "c"; // let _ = r"d"; // let _ = b"e"; // let _ = br"f"; // } pub(super) fn literal(p: &mut Parser) -> Option { match p.current() { TRUE_KW | FALSE_KW | INT_NUMBER | FLOAT_NUMBER | BYTE | CHAR | STRING | RAW_STRING | BYTE_STRING | RAW_BYTE_STRING => { let m = p.start(); p.bump(); Some(m.complete(p, LITERAL)) } _ => None, } } pub(super) fn expr(p: &mut Parser) { let mut lhs = match prefix_expr(p) { Some(lhs) => lhs, None => return, }; loop { lhs = match p.current() { L_PAREN => call_expr(p, lhs), DOT if p.nth(1) == IDENT => if p.nth(2) == L_PAREN { method_call_expr(p, lhs) } else { field_expr(p, lhs) }, _ => break, } } } fn prefix_expr(p: &mut Parser) -> Option { match p.current() { AMPERSAND => Some(ref_expr(p)), STAR => Some(deref_expr(p)), _ => atom_expr(p), } } // test ref_expr // fn foo() { // let _ = &1; // let _ = &mut &f(); // } fn ref_expr(p: &mut Parser) -> CompletedMarker { assert!(p.at(AMPERSAND)); let m = p.start(); p.bump(); p.eat(MUT_KW); expr(p); m.complete(p, REF_EXPR) } // test deref_expr // fn foo() { // **&1; // } fn deref_expr(p: &mut Parser) -> CompletedMarker { assert!(p.at(STAR)); let m = p.start(); p.bump(); expr(p); m.complete(p, DEREF_EXPR) } fn atom_expr(p: &mut Parser) -> Option { match literal(p) { Some(m) => return Some(m), None => (), } if paths::is_path_start(p) { return Some(path_expr(p)); } match p.current() { L_PAREN => Some(tuple_expr(p)), _ => { p.err_and_bump("expected expression"); None } } } fn tuple_expr(p: &mut Parser) -> CompletedMarker { assert!(p.at(L_PAREN)); let m = p.start(); p.expect(L_PAREN); p.expect(R_PAREN); m.complete(p, TUPLE_EXPR) } // test call_expr // fn foo() { // let _ = f(); // let _ = f()(1)(1, 2,); // } fn call_expr(p: &mut Parser, lhs: CompletedMarker) -> CompletedMarker { assert!(p.at(L_PAREN)); let m = lhs.precede(p); arg_list(p); m.complete(p, CALL_EXPR) } // test method_call_expr // fn foo() { // x.foo(); // y.bar(1, 2,); // } fn method_call_expr(p: &mut Parser, lhs: CompletedMarker) -> CompletedMarker { assert!(p.at(DOT) && p.nth(1) == IDENT && p.nth(2) == L_PAREN); let m = lhs.precede(p); p.bump(); p.bump(); arg_list(p); m.complete(p, METHOD_CALL_EXPR) } // test field_expr // fn foo() { // x.foo.bar; // } fn field_expr(p: &mut Parser, lhs: CompletedMarker) -> CompletedMarker { assert!(p.at(DOT) && p.nth(1) == IDENT); let m = lhs.precede(p); p.bump(); p.bump(); m.complete(p, FIELD_EXPR) } fn arg_list(p: &mut Parser) { assert!(p.at(L_PAREN)); let m = p.start(); p.bump(); while !p.at(R_PAREN) && !p.at(EOF) { expr(p); if !p.at(R_PAREN) && !p.expect(COMMA) { break; } } p.eat(R_PAREN); m.complete(p, ARG_LIST); } // test path_expr // fn foo() { // let _ = a; // let _ = a::b; // let _ = ::a::; // } fn path_expr(p: &mut Parser) -> CompletedMarker { assert!(paths::is_path_start(p)); let m = p.start(); paths::expr_path(p); if p.at(L_CURLY) { struct_lit(p); m.complete(p, STRUCT_LIT) } else { m.complete(p, PATH_EXPR) } } // test struct_lit // fn foo() { // S {}; // S { x, y: 32, }; // S { x, y: 32, ..Default::default() }; // } fn struct_lit(p: &mut Parser) { assert!(p.at(L_CURLY)); p.bump(); while !p.at(EOF) && !p.at(R_CURLY) { match p.current() { IDENT => { let m = p.start(); name_ref(p); if p.eat(COLON) { expr(p); } m.complete(p, STRUCT_LIT_FIELD); } DOTDOT => { p.bump(); expr(p); } _ => p.err_and_bump("expected identifier"), } if !p.at(R_CURLY) { p.expect(COMMA); } } p.expect(R_CURLY); }