1 / 51

LR(1) Languages An Introduction

LR(1) Languages An Introduction. CMSC 431 Shon Vick. Predictive Parsing Summary. First and Follow sets are used to construct predictive tables For non-terminal A and input t, use a production A  a where t  First( a )

sun
Download Presentation

LR(1) Languages An Introduction

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. LR(1) LanguagesAn Introduction CMSC 431 Shon Vick

  2. Predictive Parsing Summary • First and Follow sets are used to construct predictive tables • For non-terminal A and input t, use a production A  a where t  First(a) • For non-terminal A and input t, if e  First(A) and t  Follow(a), then use a production A  a where e First(a) • We’ll see First and Follow sets again . . .

  3. Bottom-Up Parsing • Bottom-up parsing is more general than top-down parsing • And just as efficient • Builds on ideas in top-down parsing • Bottom-up is the preferred method in practice • Concepts today, algorithms next time

  4. An Introductory Example • Bottom-up parsers don’t need left-factored grammars • Hence we can revert to the “natural” grammar for our example: E  T + E | T T  int * T | int | (E) • Consider the string: int * int + int

  5. The Idea Bottom-up parsing reduces a string to the start symbol by inverting productions:

  6. Terminology • Derivation Sequence starting with the start symbol S and proceeding through a sequence of derivation steps • Derivation step A non-terminal on the left side of a derivation is replaced by the right hand side of a production rule in the next step of the derivation A if A is a production, and,  are arbitrary strings of grammar symbols • Sentential Form Any derivation step • Sentence Sentential form with no non-terminals

  7.        Derivation example • Grammar EE + E | E * E | ( E ) | - E | id • Simple derivatiozn E  - E • Derivation of -(id+id) E  -E  -(E)  -(E+E)  -(id+E)  -(id+id) E-(id+id) derives it 1  2  …  n or simply   Select a nonterminal to replace and an alternative at each step of a derivation

  8. Leftmost Derivation • The derivationE  -E  -(E)  -(E+E)  -(id+E)  -(id+id)is leftmost which we designate asE lm -E lm -(E) lm -(E+E) lm -(id+E) lm -(id+id) • A sentential form is a derivation step. • A leftmost derivation step is a left sentential form, for example: • (Denoted*lm for typographical convenience)

  9. Leftmost Derivation • A derivation in which only the leftmost non-terminal in any sentential form is replaced at each step. • Unique derivation for a string most of the time

  10. Rightmost Derivation • The rightmost non-terminal is replaced in the derivation process in each step. • Also referred to as Canonical Derivation • Right sentential form: a sentential form produced via a rightmost derivation • If S *, then  is a sentential form of the CFG • If S *rm, then  is a right sentential form

  11. Right Sentential Form Grammar: S  aABe A Abc | b B  d • Reduce abbcde to S by four steps abbcde aAbcde aAdeaABe S Why not chose d here?

  12. TEST YOURSELF #1 • Question: find the rightmost derivation of the string int * int + int

  13. Observation • Read the productions found by bottom-up parse in reverse (i.e., from bottom to top) • This is a rightmost derivation!

  14. Important Fact #1 Important Fact #1 about bottom-up parsing: A bottom-up parser traces a rightmost derivation in reverse

  15. A Bottom-up Parse E T E T T + int int int *

  16. A Bottom-up Parse in Detail (1) + int int int *

  17. A Bottom-up Parse in Detail (2) T + int int int *

  18. A Bottom-up Parse in Detail (3) T T + int int int *

  19. A Bottom-up Parse in Detail (4) T T T + int int int *

  20. A Bottom-up Parse in Detail (5) T E T T + int int int *

  21. A Bottom-up Parse in Detail (6) E T E T T + int int int *

  22. A Trivial Bottom-Up Parsing Algorithm Let I = input string repeat pick a non-empty substring  of I where X  is a production if no such , backtrack replace one  by X in I until I = “S” (the start symbol) or all possibilities are exhausted

  23. Questions • Does this algorithm terminate? • How fast is the algorithm? • Does the algorithm handle all cases? • How do we choose the substring to reduce at each step?

  24. Where Do Reductions Happen Important Fact #1 has an interesting consequence: • Let  be a step of a bottom-up parse • Assume the next reduction is by X  • Then  is a string of terminals Why? Because X   is a step in a right-most derivation

  25. Notation • Idea: Split string into two substrings • Right substring is as yet unexamined by parsing (a string of terminals) • Left substring has terminals and non-terminals • The dividing point is marked by a | • The |is not part of the string • Initially, all input is unexamined |x1x2 . . . xn

  26. Shift-Reduce Parsing Bottom-up parsing uses only two kinds of actions: Shift Reduce

  27. Shift • Shift: Move | one place to the right • Shifts a terminal to the left string ABC|xyz  ABCx|yz

  28. Reduce • Apply an inverse production at the right end of the left string • If A  xy is a production, then Cbxy|ijk  CbA|ijk

  29. The Example with Reductions Only

  30. The Example with Shift-Reduce Parsing

  31. A Shift-Reduce Parse in Detail (1) + int int int * 

  32. A Shift-Reduce Parse in Detail (2) + int int int * 

  33. A Shift-Reduce Parse in Detail (3) + int int int * 

  34. A Shift-Reduce Parse in Detail (4) + int int int * 

  35. A Shift-Reduce Parse in Detail (5) T + int int int * 

  36. A Shift-Reduce Parse in Detail (6) T T + int int int * 

  37. A Shift-Reduce Parse in Detail (7) T T + int int int * 

  38. A Shift-Reduce Parse in Detail (8) T T + int int int * 

  39. A Shift-Reduce Parse in Detail (9) T T T + int int int * 

  40. A Shift-Reduce Parse in Detail (10) T E T T + int int int * 

  41. A Shift-Reduce Parse in Detail (11) E T E T T + int int int * 

  42. The Stack • Left string can be implemented by a stack • Top of the stack is the | • Shift pushes a terminal on the stack • Reduce pops 0 or more symbols off of the stack (production rhs) and pushes a non-terminal on the stack (production lhs)

  43. Key Issue (will be resolved by algorithms) • How do we decide when to shift or reduce? • Consider step int | * int + int • We could reduce by T  int giving T | * int + int • A fatal mistake: No way to reduce to the start symbol E

  44. Conflicts • Generic shift-reduce strategy: • If there is a handle on top of the stack, reduce • Otherwise, shift • But what if there is a choice? • If it is legal to shift or reduce, there is a shift-reduce conflict • If it is legal to reduce by two different productions, there is a reduce-reduce conflict

  45. Source of Conflicts • Ambiguous grammars always cause conflicts • But beware, so do many non-ambiguous grammars

  46. Conflict Example Consider everybody's favorite ambiguous grammar:

  47. One Shift-Reduce Parse

  48. Another Shift-Reduce Parse

  49. Example Notes • In the second step E * E | + int we can either shift or reduce by E  E * E • Choice determines associativity of + and * • As noted previously, grammar can be rewritten to enforce precedence • Precedence declarations are an alternative

  50. Precedence Declarations Revisited • Precedence declarations cause shift-reduce parsers to resolve conflicts in certain ways • Declaring “* has greater precedence than +” causes parser to reduce at E * E | + int • More precisely, precedence declaration is used to resolve conflict between reducing a * and shifting a +

More Related