Presentation is loading. Please wait.

Presentation is loading. Please wait.

Top-down parsing 1. Last Time CYK – Step 1: get a grammar in Chomsky Normal Form – Step 2: Build all possible parse trees bottom-up Start with runs of.

Published byMaude Skinner Modified over 8 years ago

Similar presentations

Presentation on theme: "Top-down parsing 1. Last Time CYK – Step 1: get a grammar in Chomsky Normal Form – Step 2: Build all possible parse trees bottom-up Start with runs of."— Presentation transcript:

1 Top-down parsing 1

2 Last Time CYK – Step 1: get a grammar in Chomsky Normal Form – Step 2: Build all possible parse trees bottom-up Start with runs of 1 terminal Connect 1-terminal runs into 2-terminal runs Connect 1- and 2- terminal runs into 3-terminal runs Connect 1- and 3- or 2- and 2- terminal runs into 4 terminal runs … If we can connect the entire tree, rooted at the start symbol, we’ve found a valid parse 2

3 Some Interesting properties of CYK Very old algorithm – Already well known in early 70s No problems with ambiguous grammars: – Gives a solution for all possible parse tree simultaneously 3

4 CYK Example 4 I,NL C R ZX N X W F FI WI W FI YI Y WL XL X XN RN R YL RL R Nid NI ZI Z ZC NC N I L( R) C,,)( 1,22,33,44,55,6 1,32,43,54,6 1,42,53,6 1,52,6 1,6

5 Thinking about Language Design Balanced considerations – Powerful enough to be useful – Simple enough to be parseable Syntax need not be complex for complex behaviors – Guy Steele’s “Growing a Language” https://www.youtube.com/watch?v=_ahvzDzKdB0 5

6 Restricting the Grammar By restricting our grammars we can – Detect ambiguity – Build linear-time, O(n) parsers LL(1) languages – Particularly amenable to parsing – Parseable by Predictive (top-down) parsers Sometimes called recursive descent 6

7 Top-Down Parsers Start at the Start symbol “predict” what productions to use – Example: if the current token to be parsed is an id, no need to try productions that start with integer literal – This might seem simple, but keep in mind multiple levels of productions that have to be used 7

8 Scanner Predictive Parser Sketch 8 Selector table “Work to do” Stack EOFabaa Token Stream Row: nonterminal Col: terminal current Parser

9 Algorithm 9 stack.push(eof) stack.push(Start non-term) t = scanner.getToken() Repeat if stack.top is a terminal y match y with t pop y from the stack t = scanner.next_token() if stack.top is a nonterminal X get table[X,t] pop X from the stack push production’s RHS (each symbol from Right to Left) Until one of the following: stack is empty stack.top is a terminal that doesn’t match t stack.top is a non-term and parse table entry is empty reject accept

10 Example 10 S → ( S ) | { S } | ε ( S )ε{ S }εε S (){} eof S) ( }S { “Work to do” Stack ({})eof S current

11 Example 2, bad input: You try 11 S → ( S ) | { S } | ε ( S )ε{ S }εε S (){} eof ((} INPUT

12 This Parser works great! Given a single token we always knew exactly what production it started 12 ( S )ε{ S }εε S (){} eof

13 Two Outstanding Issues 1.How do we know if the language is LL(1) – Easy to imagine a Grammar where a single token is not enough to select a rule 1.How do we build the selector table? – It turns out that there is one answer to both: 13 S → ( S ) | { S } | ε | ( ) If our selector table has 1 production per cell, then grammar is LL(1)

14 LL(1) Grammar Transformations Necessary (but not sufficient conditions) for LL(1) Parsing: – Free of left recursion No nonterminal loops for a production Why? Need to look past list to know when to cap it – Left factored No rules with common prefix Why? We’d need to look past the prefix to pick rule 14

15 Left-Recursion 15

16 Why Left Recursion is a Problem (Blackbox View) 16 XList XList x | x x XList How should we grow the tree top-down? x XList Current parse tree: Current token: CFG snippet: XList x (OR) Correct if there are no more xsCorrect if there are more xs We don’t know which without more lookahead

17 Why Left Recursion is a Problem (Whitebox View) 17 XList XList x | x x XList Current parse tree: Current token: CFG snippet: Parse table: XList XList x x ε eof Stack eof Current x XList x x x (Stack overflow)

18 Removing Left-Recursion 18 A → A α | βA → β A’ A’→ α A’ | ε (for a single immediately left-recursive rule) Where β does not begin with A

19 Example 19 Exp → Exp – Factor | Factor Factor → intlit | ( Exp ) A → A α | β A → β A’ A’→ α A’ | ε Exp → Factor Exp’ Exp’ → - Factor Exp’ | ε Factor → intlit | ( Exp )

20 Let’s check in on the Parse Tree… 20 E E -F E - F F 2 3 4 Exp → Exp – Factor | Factor Factor → intlit | ( Exp ) Exp → Factor Exp’ Exp’ → - Factor Exp’ | ε Factor → intlit | ( Exp ) E F E 2 - FE - FE 3 4 ε

21 … We’ll fix that later 21

22 General Rule for Removing Immediate Left-Recursion 22 A → α 1 | α 2 | … | α n | A β 1 | A β 2 | … A β m A → α 1 A’ | α 2 A’ | … | α n A’ A’ → β 1 A’ | β 2 A’ | … | β m A’ | ε

23 Left Factored Grammars If a nonterminal has two productions whose RHS has a common prefix it is not left factored and not LL(1) Exp → ( Exp ) | ( ) 23 Not left factored

24 Left Factoring Given productions of the form A → α β 1 | α β 2 24 A → α A’ A’ → β 1 | β 2

25 Combined Example 25 Exp → ( Exp ) | Exp Exp | ( ) Exp → ( Exp ) Exp' | ( ) Exp' Exp' → Exp Exp' | ε Exp -> ( Exp'' Exp'' -> Exp ) Exp' | ) Exp' Exp' -> exp exp' | ε Remove Immediate left-recursion Left-factoring

26 Where are we at? We’ve set ourselves up for success in building the selection table – Two things that prevent a grammar from being LL(1) were identified and avoided Not Left-Factored grammars Left-recursive grammars – Next time Build two data structures that combine to yield a selector table: – FIRST set – FOLLOW set 26

Download ppt "Top-down parsing 1. Last Time CYK – Step 1: get a grammar in Chomsky Normal Form – Step 2: Build all possible parse trees bottom-up Start with runs of."

Similar presentations

Parsing V: Bottom-up Parsing

Parsing V: Bottom-up Parsing
Exercise: Balanced Parentheses

Exercise: Balanced Parentheses
1 Parsing The scanner recognizes words The parser recognizes syntactic units Parser operations: Check and verify syntax based on specified syntax rules.

1 Parsing The scanner recognizes words The parser recognizes syntactic units Parser operations: Check and verify syntax based on specified syntax rules.
Chap. 5, Top-Down Parsing J. H. Wang Mar. 29, 2011.

Chap. 5, Top-Down Parsing J. H. Wang Mar. 29, 2011.
YANGYANG 1 Chap 5 LL(1) Parsing LL(1) left-to-right scanning leftmost derivation 1-token lookahead parser generator: Parsing becomes the easiest! Modifying.

YANGYANG 1 Chap 5 LL(1) Parsing LL(1) left-to-right scanning leftmost derivation 1-token lookahead parser generator: Parsing becomes the easiest! Modifying.
6/12/2015Prof. Hilfinger CS164 Lecture 111 Bottom-Up Parsing Lecture 11-12 (From slides by G. Necula & R. Bodik)

6/12/2015Prof. Hilfinger CS164 Lecture 111 Bottom-Up Parsing Lecture (From slides by G. Necula & R. Bodik)
Top-Down Parsing.

Top-Down Parsing.
Parsing III (Eliminating left recursion, recursive descent parsing)

Parsing III (Eliminating left recursion, recursive descent parsing)
COS 320 Compilers David Walker. last time context free grammars (Appel 3.1) –terminals, non-terminals, rules –derivations & parse trees –ambiguous grammars.

COS 320 Compilers David Walker. last time context free grammars (Appel 3.1) –terminals, non-terminals, rules –derivations & parse trees –ambiguous grammars.
ISBN 0-321-19362-8 Chapter 4 Lexical and Syntax Analysis The Parsing Problem Recursive-Descent Parsing.

ISBN Chapter 4 Lexical and Syntax Analysis The Parsing Problem Recursive-Descent Parsing.
1 Predictive parsing Recall the main idea of top-down parsing: Start at the root, grow towards leaves Pick a production and try to match input May need.

1 Predictive parsing Recall the main idea of top-down parsing: Start at the root, grow towards leaves Pick a production and try to match input May need.
Parsing — Part II (Ambiguity, Top-down parsing, Left-recursion Removal)

Parsing — Part II (Ambiguity, Top-down parsing, Left-recursion Removal)
Prof. Fateman CS 164 Lecture 91 Bottom-Up Parsing Lecture 9.

Prof. Fateman CS 164 Lecture 91 Bottom-Up Parsing Lecture 9.
1 The Parser Its job: –Check and verify syntax based on specified syntax rules –Report errors –Build IR Good news –the process can be automated.

1 The Parser Its job: –Check and verify syntax based on specified syntax rules –Report errors –Build IR Good news –the process can be automated.
Professor Yihjia Tsai Tamkang University

Professor Yihjia Tsai Tamkang University
COS 320 Compilers David Walker. last time context free grammars (Appel 3.1) –terminals, non-terminals, rules –derivations & parse trees –ambiguous grammars.

COS 320 Compilers David Walker. last time context free grammars (Appel 3.1) –terminals, non-terminals, rules –derivations & parse trees –ambiguous grammars.
Top-Down Parsing.

Top-Down Parsing.
1 Bottom-up parsing Goal of parser : build a derivation –top-down parser : build a derivation by working from the start symbol towards the input. builds.

1 Bottom-up parsing Goal of parser : build a derivation –top-down parser : build a derivation by working from the start symbol towards the input. builds.
CPSC 388 – Compiler Design and Construction

CPSC 388 – Compiler Design and Construction
Compiler Principles Winter 2012-2013 Compiler Principles Exercises on scanning & top-down parsing Roman Manevich Ben-Gurion University.

Compiler Principles Winter Compiler Principles Exercises on scanning & top-down parsing Roman Manevich Ben-Gurion University.

Similar presentations

Ads by Google