# What is the difference between LL and LR parsing?

Can anyone give me a simple example of LL parsing versus LR parsing?

At a high level, the difference between LL parsing and LR parsing is that LL parsers begin at the start symbol and try to apply productions to arrive at the target string, whereas LR parsers begin at the target string and try to arrive back at the start symbol.

An LL parse is a left-to-right, leftmost derivation. That is, we consider the input symbols from the left to the right and attempt to construct a leftmost derivation. This is done by beginning at the start symbol and repeatedly expanding out the leftmost nonterminal until we arrive at the target string. An LR parse is a left-to-right, rightmost derivation, meaning that we scan from the left to right and attempt to construct a rightmost derivation. The parser continuously picks a substring of the input and attempts to reverse it back to a nonterminal.

During an LL parse, the parser continuously chooses between two actions:

1. Predict: Based on the leftmost nonterminal and some number of lookahead tokens, choose which production ought to be applied to get closer to the input string.
2. Match: Match the leftmost guessed terminal symbol with the leftmost unconsumed symbol of input.

As an example, given this grammar:

• S → E
• E → T + E
• E → T
• T → `int`

Then given the string `int + int + int`, an LL(2) parser (which uses two tokens of lookahead) would parse the string as follows:

``````Production       Input              Action
---------------------------------------------------------
S                int + int + int    Predict S -> E
E                int + int + int    Predict E -> T + E
T + E            int + int + int    Predict T -> int
int + E          int + int + int    Match int
+ E              + int + int        Match +
E                int + int          Predict E -> T + E
T + E            int + int          Predict T -> int
int + E          int + int          Match int
+ E              + int              Match +
E                int                Predict E -> T
T                int                Predict T -> int
int              int                Match int
Accept
``````

Notice that in each step we look at the leftmost symbol in our production. If it's a terminal, we match it, and if it's a nonterminal, we predict what it's going to be by choosing one of the rules.

In an LR parser, there are two actions:

1. Shift: Add the next token of input to a buffer for consideration.
2. Reduce: Reduce a collection of terminals and nonterminals in this buffer back to some nonterminal by reversing a production.

As an example, an LR(1) parser (with one token of lookahead) might parse that same string as follows:

``````Workspace        Input              Action
---------------------------------------------------------
int + int + int    Shift
int              + int + int        Reduce T -> int
T                + int + int        Shift
T +              int + int          Shift
T + int          + int              Reduce T -> int
T + T            + int              Shift
T + T +          int                Shift
T + T + int                         Reduce T -> int
T + T + T                           Reduce E -> T
T + T + E                           Reduce E -> T + E
T + E                               Reduce E -> T + E
E                                   Reduce S -> E
S                                   Accept
``````

The two parsing algorithms you mentioned (LL and LR) are known to have different characteristics. LL parsers tend to be easier to write by hand, but they are less powerful than LR parsers and accept a much smaller set of grammars than LR parsers do. LR parsers come in many flavors (LR(0), SLR(1), LALR(1), LR(1), IELR(1), GLR(0), etc.) and are far more powerful. They also tend to have much more complex and are almost always generated by tools like `yacc` or `bison`. LL parsers also come in many flavors (including LL(*), which is used by the `ANTLR` tool), though in practice LL(1) is the most-widely used.

As a shameless plug, if you'd like to learn more about LL and LR parsing, I just finished teaching a compilers course and have some handouts and lecture slides on parsing on the course website. I'd be glad to elaborate on any of them if you think it would be useful.

• Your lecture slides are phenomenal, easily the most fun explanation that I have seen :) This is the kind of thing that actually sparks interests. – kizzx2 Aug 11 '11 at 14:57
• Thank you Great slides – Adi Dec 31 '11 at 6:23
• I have to comment on the slides as well! Going through all of them now. Helps a lot! Thanks! – kornfridge May 29 '13 at 20:16
• The one thing I can contribute to Matt's excellent summary answer is that any grammar which can be parsed by an LL(k) parser (ie, looking ahead "k" terminals to decide upon the next parse action) can be parsed by an LR(1) parser. This gives one a hint at the incredible power of LR parsing over LL parsing. Source: compiler course at UCSC taught by Dr. F. DeRemer, creator of LALR() parsers. – JoGusto Feb 2 '15 at 10:34
• Excellent resource! Thanks for providing slides, handouts, projects as well. – P. Hinker Sep 21 '18 at 12:32

Josh Haberman in his article LL and LR Parsing Demystified claims that LL parsing directly corresponds with the Polish Notation, whereas LR corresponds to Reverse Polish Notation. The difference between PN and RPN is the order of traversing the binary tree of the equation: ``````+ 1 * 2 3  // Polish (prefix) expression; pre-order traversal.
1 2 3 * +  // Reverse Polish (postfix) expression; post-order traversal.
``````

According to Haberman, this illustrates the main difference between LL and LR parsers:

The primary difference between how LL and LR parsers operate is that an LL parser outputs a pre-order traversal of the parse tree and an LR parser outputs a post-order traversal.

For the in-depth explanation, examples and conclusions check out Haberman's article.

The LL uses top-down, while the LR uses bottom-up approach.

If you parse a progamming language:

• The LL sees a source code, which contains functions, which contains expression.
• The LR sees expression, which belongs to functions, which results the full source.

LL parsing is handicapped, when compared to LR. Here is a grammar that is a nightmare for an LL parser generator:

``````Goal           -> (FunctionDef | FunctionDecl)* <eof>

FunctionDef    -> TypeSpec FuncName '(' [Arg/','+] ')' '{' '}'

FunctionDecl   -> TypeSpec FuncName '(' [Arg/','+] ')' ';'

TypeSpec       -> int
-> char '*' '*'
-> long
-> short

FuncName       -> IDENTIFIER

Arg            -> TypeSpec ArgName

ArgName        -> IDENTIFIER
``````

A FunctionDef looks exactly like a FunctionDecl until the ';' or '{' is encountered.

An LL parser cannot handle two rules at the same time, so it must chose either FunctionDef or FunctionDecl. But to know which is correct it has to lookahead for a ';' or '{'. At grammar analysis time, the lookahead (k) appears to be infinite. At parsing time it is finite, but could be large.

An LR parser does not have to lookahead, because it can handle two rules at the same time. So LALR(1) parser generators can handle this grammar with ease.

Given the input code:

``````int main (int na, char** arg);

int main (int na, char** arg)
{

}
``````

An LR parser can parse the

``````int main (int na, char** arg)
``````

without caring what rule is being recognized until it encounters a ';' or a '{'.

An LL parser gets hung up at the 'int' because it needs to know which rule is being recognized. Therefore it must lookahead for a ';' or '{'.

The other nightmare for LL parsers is left recursion in a grammar. Left recursion is a normal thing in grammars, no problem for an LR parser generator, but LL can't handle it.

So you have to write your grammars in an unnatural way with LL.

Left Most derivation Example: A grammar G which is context-free has the productions

z → xXY (Rule: 1) X → Ybx (Rule: 2) Y → bY (Rule: 3) Y → c (Rule: 4)

Compute the String w = ‘xcbxbc’ with left most derivation.

z ⇒ xXY (Rule: 1) ⇒ xYbxY (Rule: 2) ⇒ xcbxY (Rule: 4) ⇒ xcbxbY (Rule: 3) ⇒ xcbxbc (Rule: 4)

Right Most derivation Example: K → aKK (Rule: 1) A → b (Rule: 2)

Compute the String w = ‘aababbb’ with right most derivation.

K ⇒ aKK (Rule: 1) ⇒ aKb (Rule: 2) ⇒ aaKKb (Rule: 1) ⇒ aaKaKKb (Rule: 1) ⇒ aaKaKbb (Rule: 2) ⇒ aaKabbb (Rule: 2) ⇒ aababbb (Rule: 2)