The dangling else is a problem in programming of parser generators in which an optional else clause in an if–then(–else) statement results in nested conditionals being ambiguous. Formally, the reference context-free grammar of the language is ambiguous, meaning there is more than one correct parse tree.

In many programming languages one may write conditionally executed code in two forms: the if-then form, and the if-then-else form – the else clause is optional:

if a then s
if b then s1 else s2

This gives rise to an ambiguity in interpretation when there are nested statements, specifically whenever an if-then form appears as s1 in an if-then-else form:

if a then if b then s else s2

In this example, s is unambiguously executed when a is true and b is true, but one may interpret s2 as being executed when a is false (thus attaching the else to the first if) or when a is true and b is false (thus attaching the else to the second if). In other words, one may see the previous statement as either of the following expressions:

if a then (if b then s) else s2
if a then (if b then s else s2)

The dangling else problem dates to ALGOL 60,[1] and has been resolved in various ways in subsequent languages. In LR parsers, the dangling else is the archetypal example of a shift-reduce conflict.

Avoiding ambiguity while keeping the syntax

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This is a problem that often comes up in compiler construction, especially scannerless parsing. The convention when dealing with the dangling else is to attach the else to the nearby if statement,[2] allowing for unambiguous context-free grammars, in particular. Programming languages like Pascal,[3] C[4] and Java[5] follow this convention, so there is no ambiguity in the semantics of the language, though the use of a parser generator may lead to ambiguous grammars. In these cases alternative grouping is accomplished by explicit blocks, such as begin...end in Pascal[6] and {...} in C.

Depending on the compiler construction approach, one may take different corrective actions to avoid ambiguity:

  • If the parser is produced by an SLR, LR(1) or LALR LR parser generator, the programmer will often rely on the generated parser feature of preferring shift over reduce whenever there is a conflict.[2] Alternatively, the grammar can be rewritten to remove the conflict, at the expense of an increase in grammar size (see below).
  • If the parser is hand written, the programmer may use a non-ambiguous context-free grammar. Alternatively, one may rely on a non-context-free grammar or a parsing expression grammar.

Avoiding ambiguity by changing the syntax

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The problem can also be solved by making explicit the link between an else and its if, within the syntax. This usually helps avoid human errors.[7]

Possible solutions are:

  • Having an "end if" symbol delimiting the end of the if construct. Examples of such languages are ALGOL 68, Ada, Eiffel, PL/SQL, Visual Basic, Modula-2, and AppleScript.
  • Disallowing the statement following a "then" to be an "if" itself (it may however be a pair of statement brackets containing only an if-then-clause). This approach is followed by ALGOL 60.[8]
  • Requiring braces (parentheses) when an "else" follows an "if".[9]
  • Requiring every "if" to be paired with an "else". To avoid a similar problem concerning semantics rather than syntax, Racket deviates from Scheme by considering an if without a fallback clause to be an error, effectively distinguishing conditional expressions (i.e if) from conditional statements (i.e when and unless, which do not have fallback clauses).
  • Using different keywords for the one-alternative and two-alternative "if" statements. S-algol uses if e do s for the one-alternative case and if e1 then e2 else e3 for the general case.[10]
  • Requiring braces unconditionally, like Swift. This is effectively true in Python as its indentation rules delimit every block, not just those in "if" statements.

Examples

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Concrete examples follow.

In C, the grammar reads, in part:

 statement = ...
    | selection-statement

 selection-statement = ...
    | IF ( expression ) statement
    | IF ( expression ) statement ELSE statement

Thus, without further rules, the statement

if (a) if (b) s; else s2;

could ambiguously be parsed as if it were either:

if (a)
{
  if (b)
    s;
  else
    s2;
}

or:

if (a)
{
  if (b)
    s;
}
else
  s2;

The C standard clarifies that an else block is associated with the nearest if.[4] Therefore, the first tree is chosen.

Avoiding the conflict in LR parsers

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The above example could be rewritten in the following way to remove the ambiguity :

statement: open_statement
         | closed_statement
         ;

open_statement: IF '(' expression ')' statement
              | IF '(' expression ')' closed_statement ELSE open_statement
              ;

closed_statement: non_if_statement
                | IF '(' expression ')' closed_statement ELSE closed_statement
                ;

non_if_statement: ...
                ;

Any other statement-related grammar rules may also have to be duplicated in this way if they may directly or indirectly end with a statement or selection-statement non-terminal.

However, we give grammar that includes both of if and while statements.

statement: open_statement
         | closed_statement
         ;

open_statement: IF '(' expression ')' statement
              | IF '(' expression ')' closed_statement ELSE open_statement
              | WHILE '(' expression ')' open_statement
              ;

closed_statement: simple_statement
                | IF '(' expression ')' closed_statement ELSE closed_statement
                | WHILE '(' expression ')' closed_statement
                ;

simple_statement: ...
                ;

Finally, we give the grammar that forbids ambiguous IF statements.

statement: open_statement
         | closed_statement
         ;

open_statement: IF '(' expression ')' statement
              | IF '(' expression ')' closed_statement ELSE open_statement
              | WHILE '(' expression ')' open_statement
              ;

closed_statement: simple_statement
                | IF '(' expression ')' closed_statement ELSE closed_statement
                | WHILE '(' expression ')' closed_statement
                ;

simple_statement: ...
                ;

With this grammar the statement if (a) if (b) c else d can only be parsed one way, because the other interpretation (if (a) {if (b) c} else d) is produced as

statement
open_statement
IF '(' expression ')' closed_statement ELSE open_statement
'if' '(' 'a' ')' closed_statement 'else' 'd'

and then the parsing fails trying to match closed_statement to "if (b) c". An attempt with closed_statement fails in the same way. The other parse, if (a) {if (b) c else d}) succeeds:

statement
open_statement
IF '(' expression ')' statement
IF '(' expression ')' closed_statement
IF '(' a ')' (IF '(' expression ')' closed_statement ELSE closed_statement)
IF '(' a ')' (IF '(' b ')' c ELSE 'd')

See also

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References

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  1. ^ Abrahams, P. W. (1966). "A final solution to the Dangling else of ALGOL 60 and related languages". Communications of the ACM. 9 (9): 679–682. doi:10.1145/365813.365821. S2CID 6777841.
  2. ^ a b "5.2 Shift/Reduce Conflicts". Bison 3.7.6. Retrieved 2021-08-07. {{cite book}}: |website= ignored (help)
  3. ^ ISO 7185:1990 (Pascal) 6.8.3.4: An if-statement without an else-part shall not be immediately followed by the token else.
  4. ^ a b ISO 9899:1999 (C): 6.8.4.1(3): "An else is associated with the lexically nearest preceding if that is allowed by the syntax.", available at WG14 N1256, p. 134
  5. ^ "The Java Language Specification, Java SE 9 Edition, 14.5. Statements".
  6. ^ Dale, Nell B.; Weems, Chip (November 1996). "Dangling Else". Introduction to Pascal and Structured Design. Jones & Bartlett Learning. pp. 160–161. ISBN 9780763703974.
  7. ^ Ambiguity of dangling else: non-context-free grammars are semantically opaque
  8. ^ 4.5.1 Conditional Statements — Syntax in P. Nauer (ed.), Revised Report on the Algorithmic Language ALGOL 60, CACM 6,1, 1963 pp. 1-17
  9. ^ Ambiguity of dangling else: require braces when else follows if
  10. ^ Davie, Antony J. T.; Ronald Morrison (1981), Brian Meek (ed.), Recursive Descent Compiling, Ellis Horwood series in computers and their applications, Chichester, West Sussex: Ellis Horwood, p. 20, ISBN 0-470-27270-8