package ini import ( "fmt" "io" ) // State enums for the parse table const ( InvalidState = iota // stmt -> value stmt' StatementState // stmt' -> MarkComplete | op stmt StatementPrimeState // value -> number | string | boolean | quoted_string ValueState // section -> [ section' OpenScopeState // section' -> value section_close SectionState // section_close -> ] CloseScopeState // SkipState will skip (NL WS)+ SkipState // SkipTokenState will skip any token and push the previous // state onto the stack. SkipTokenState // comment -> # comment' | ; comment' // comment' -> MarkComplete | value CommentState // MarkComplete state will complete statements and move that // to the completed AST list MarkCompleteState // TerminalState signifies that the tokens have been fully parsed TerminalState ) // parseTable is a state machine to dictate the grammar above. var parseTable = map[ASTKind]map[TokenType]int{ ASTKindStart: map[TokenType]int{ TokenLit: StatementState, TokenSep: OpenScopeState, TokenWS: SkipTokenState, TokenNL: SkipTokenState, TokenComment: CommentState, TokenNone: TerminalState, }, ASTKindCommentStatement: map[TokenType]int{ TokenLit: StatementState, TokenSep: OpenScopeState, TokenWS: SkipTokenState, TokenNL: SkipTokenState, TokenComment: CommentState, TokenNone: MarkCompleteState, }, ASTKindExpr: map[TokenType]int{ TokenOp: StatementPrimeState, TokenLit: ValueState, TokenSep: OpenScopeState, TokenWS: ValueState, TokenNL: SkipState, TokenComment: CommentState, TokenNone: MarkCompleteState, }, ASTKindEqualExpr: map[TokenType]int{ TokenLit: ValueState, TokenWS: SkipTokenState, TokenNL: SkipState, }, ASTKindStatement: map[TokenType]int{ TokenLit: SectionState, TokenSep: CloseScopeState, TokenWS: SkipTokenState, TokenNL: SkipTokenState, TokenComment: CommentState, TokenNone: MarkCompleteState, }, ASTKindExprStatement: map[TokenType]int{ TokenLit: ValueState, TokenSep: OpenScopeState, TokenOp: ValueState, TokenWS: ValueState, TokenNL: MarkCompleteState, TokenComment: CommentState, TokenNone: TerminalState, TokenComma: SkipState, }, ASTKindSectionStatement: map[TokenType]int{ TokenLit: SectionState, TokenOp: SectionState, TokenSep: CloseScopeState, TokenWS: SectionState, TokenNL: SkipTokenState, }, ASTKindCompletedSectionStatement: map[TokenType]int{ TokenWS: SkipTokenState, TokenNL: SkipTokenState, TokenLit: StatementState, TokenSep: OpenScopeState, TokenComment: CommentState, TokenNone: MarkCompleteState, }, ASTKindSkipStatement: map[TokenType]int{ TokenLit: StatementState, TokenSep: OpenScopeState, TokenWS: SkipTokenState, TokenNL: SkipTokenState, TokenComment: CommentState, TokenNone: TerminalState, }, } // ParseAST will parse input from an io.Reader using // an LL(1) parser. func ParseAST(r io.Reader) ([]AST, error) { lexer := iniLexer{} tokens, err := lexer.Tokenize(r) if err != nil { return []AST{}, err } return parse(tokens) } // ParseASTBytes will parse input from a byte slice using // an LL(1) parser. func ParseASTBytes(b []byte) ([]AST, error) { lexer := iniLexer{} tokens, err := lexer.tokenize(b) if err != nil { return []AST{}, err } return parse(tokens) } func parse(tokens []Token) ([]AST, error) { start := Start stack := newParseStack(3, len(tokens)) stack.Push(start) s := newSkipper() loop: for stack.Len() > 0 { k := stack.Pop() var tok Token if len(tokens) == 0 { // this occurs when all the tokens have been processed // but reduction of what's left on the stack needs to // occur. tok = emptyToken } else { tok = tokens[0] } step := parseTable[k.Kind][tok.Type()] if s.ShouldSkip(tok) { // being in a skip state with no tokens will break out of // the parse loop since there is nothing left to process. if len(tokens) == 0 { break loop } step = SkipTokenState } switch step { case TerminalState: // Finished parsing. Push what should be the last // statement to the stack. If there is anything left // on the stack, an error in parsing has occurred. if k.Kind != ASTKindStart { stack.MarkComplete(k) } break loop case SkipTokenState: // When skipping a token, the previous state was popped off the stack. // To maintain the correct state, the previous state will be pushed // onto the stack. stack.Push(k) case StatementState: if k.Kind != ASTKindStart { stack.MarkComplete(k) } expr := newExpression(tok) stack.Push(expr) case StatementPrimeState: if tok.Type() != TokenOp { stack.MarkComplete(k) continue } if k.Kind != ASTKindExpr { return nil, NewParseError( fmt.Sprintf("invalid expression: expected Expr type, but found %T type", k), ) } k = trimSpaces(k) expr := newEqualExpr(k, tok) stack.Push(expr) case ValueState: // ValueState requires the previous state to either be an equal expression // or an expression statement. // // This grammar occurs when the RHS is a number, word, or quoted string. // equal_expr -> lit op equal_expr' // equal_expr' -> number | string | quoted_string // quoted_string -> " quoted_string' // quoted_string' -> string quoted_string_end // quoted_string_end -> " // // otherwise // expr_stmt -> equal_expr (expr_stmt')* // expr_stmt' -> ws S | op S | MarkComplete // S -> equal_expr' expr_stmt' switch k.Kind { case ASTKindEqualExpr: // assiging a value to some key k.AppendChild(newExpression(tok)) stack.Push(newExprStatement(k)) case ASTKindExpr: k.Root.raw = append(k.Root.raw, tok.Raw()...) stack.Push(k) case ASTKindExprStatement: root := k.GetRoot() children := root.GetChildren() if len(children) == 0 { return nil, NewParseError( fmt.Sprintf("invalid expression: AST contains no children %s", k.Kind), ) } rhs := children[len(children)-1] if rhs.Root.ValueType != QuotedStringType { rhs.Root.ValueType = StringType rhs.Root.raw = append(rhs.Root.raw, tok.Raw()...) } children[len(children)-1] = rhs k.SetChildren(children) stack.Push(k) } case OpenScopeState: if !runeCompare(tok.Raw(), openBrace) { return nil, NewParseError("expected '['") } stmt := newStatement() stack.Push(stmt) case CloseScopeState: if !runeCompare(tok.Raw(), closeBrace) { return nil, NewParseError("expected ']'") } k = trimSpaces(k) stack.Push(newCompletedSectionStatement(k)) case SectionState: var stmt AST switch k.Kind { case ASTKindStatement: // If there are multiple literals inside of a scope declaration, // then the current token's raw value will be appended to the Name. // // This handles cases like [ profile default ] // // k will represent a SectionStatement with the children representing // the label of the section stmt = newSectionStatement(tok) case ASTKindSectionStatement: k.Root.raw = append(k.Root.raw, tok.Raw()...) stmt = k default: return nil, NewParseError( fmt.Sprintf("invalid statement: expected statement: %v", k.Kind), ) } stack.Push(stmt) case MarkCompleteState: if k.Kind != ASTKindStart { stack.MarkComplete(k) } if stack.Len() == 0 { stack.Push(start) } case SkipState: stack.Push(newSkipStatement(k)) s.Skip() case CommentState: if k.Kind == ASTKindStart { stack.Push(k) } else { stack.MarkComplete(k) } stmt := newCommentStatement(tok) stack.Push(stmt) default: return nil, NewParseError(fmt.Sprintf("invalid state with ASTKind %v and TokenType %v", k, tok)) } if len(tokens) > 0 { tokens = tokens[1:] } } // this occurs when a statement has not been completed if stack.top > 1 { return nil, NewParseError(fmt.Sprintf("incomplete expression: %v", stack.container)) } // returns a sublist which exludes the start symbol return stack.List(), nil } // trimSpaces will trim spaces on the left and right hand side of // the literal. func trimSpaces(k AST) AST { // trim left hand side of spaces for i := 0; i < len(k.Root.raw); i++ { if !isWhitespace(k.Root.raw[i]) { break } k.Root.raw = k.Root.raw[1:] i-- } // trim right hand side of spaces for i := len(k.Root.raw) - 1; i > 0; i-- { if !isWhitespace(k.Root.raw[i]) { break } k.Root.raw = k.Root.raw[:len(k.Root.raw)-1] i-- } return k }