Title: COS 320 Compilers
1COS 320Compilers
2The Front End
- Lexical Analysis Create sequence of tokens from
characters (Chap 2) - Syntax Analysis Create abstract syntax tree from
sequence of tokens (Chap 3) - Type Checking Check program for well-formedness
constraints
stream of characters
stream of tokens
abstract syntax
Lexer
Parser
Type Checker
3Parsing with CFGs
- Context-free grammars are (often) given by BNF
expressions (Backus-Naur Form) - Appel Chap 3.1
- More powerful than regular expressions
- Matching parens
- Nested comments
- wait, we could do nested comments with ML-LEX!
- CFGs are good for describing the overall
syntactic structure of programs.
4Context-Free Grammars
- Context-free grammars consist of
- Set of symbols
- terminals that denotes token types
- non-terminals that denotes a set of strings
- Start symbol
- Rules
- left-hand side non-terminal
- right-hand side terminals and/or non-terminals
- rules explain how to rewrite non-terminals
(beginning with start symbol) into terminals
symbol symbol symbol ... symbol
5Context-Free Grammars
- A string is in the language of the CFG if only if
it is possible to derive that string using the
following non-deterministic procedure - begin with the start symbol
- while any non-terminals exist, pick a
non-terminal and rewrite it using a rule - stop when all you have left are terminals (and
check you arrived at the string your were hoping
to) - Parsing is the process of checking that a string
is in the CFG for your programming language. It
is usually coupled with creating an abstract
syntax tree.
6- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
Elist E Elist Elist , E
E ID E NUM E E E E ( S , Elist
)
S S S S ID E S PRINT ( Elist )
7- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
8. Elist E 9. Elist Elist , E
4. E ID 5. E NUM 6. E E E 7. E
( S , Elist )
1. S S S 2. S ID E 3. S PRINT
( Elist )
Derive me!
ID NUM PRINT ( NUM )
8- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
8. Elist E 9. Elist Elist , E
4. E ID 5. E NUM 6. E E E 7. E
( S , Elist )
1. S S S 2. S ID E 3. S PRINT
( Elist )
Derive me!
S ID NUM PRINT ( NUM )
9- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
8. Elist E 9. Elist Elist , E
4. E ID 5. E NUM 6. E E E 7. E
( S , Elist )
1. S S S 2. S ID E 3. S PRINT
( Elist )
Derive me!
S ID E ID NUM PRINT ( NUM )
10- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
8. Elist E 9. Elist Elist , E
4. E ID 5. E NUM 6. E E E 7. E
( S , Elist )
1. S S S 2. S ID E 3. S PRINT
( Elist )
Derive me!
S ID E ID NUM PRINT ( NUM )
oops, cant make progress
11- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
8. Elist E 9. Elist Elist , E
4. E ID 5. E NUM 6. E E E 7. E
( S , Elist )
1. S S S 2. S ID E 3. S PRINT
( Elist )
Derive me!
S ID NUM PRINT ( NUM )
12- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
8. Elist E 9. Elist Elist , E
4. E ID 5. E NUM 6. E E E 7. E
( S , Elist )
1. S S S 2. S ID E 3. S PRINT
( Elist )
Derive me!
S S S ID NUM PRINT ( NUM )
13- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
8. Elist E 9. Elist Elist , E
4. E ID 5. E NUM 6. E E E 7. E
( S , Elist )
1. S S S 2. S ID E 3. S PRINT
( Elist )
Derive me!
S S S ID E S ID NUM PRINT ( NUM )
14- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
8. Elist E 9. Elist Elist , E
4. E ID 5. E NUM 6. E E E 7. E
( S , Elist )
1. S S S 2. S ID E 3. S PRINT
( Elist )
Derive me!
S S S ID E S ID NUM S ID NUM PRINT
( Elist ) ID NUM PRINT ( E ) ID NUM PRINT
( NUM )
15- non-terminals S, E, Elist
- terminals ID, NUM, PRINT, , , (, ),
- rules
8. Elist E 9. Elist Elist , E
4. E ID 5. E NUM 6. E E E 7. E
( S , Elist )
1. S S S 2. S ID E 3. S PRINT
( Elist )
S S S ID E S ID NUM S ID NUM PRINT
( Elist ) ID NUM PRINT ( E ) ID NUM PRINT
( NUM )
S S S S PRINT ( Elist ) S PRINT ( E ) S
PRINT ( NUM ) ID E PRINT ( NUM ) ID NUM
PRINT ( NUM )
Another way to derive the same string
left-most derivation
right-most derivation
16Parse Trees
- Representing derivations as trees
- useful in compilers Parse trees correspond
quite closely (but not exactly) with abstract
syntax trees were trying to generate - difference abstract syntax vs concrete (parse)
syntax - each internal node is labeled with a non-terminal
- each leaf note is labeled with a terminal
- each use of a rule in a derivation explains how
to generate children in the parse tree from the
parents
17Parse Trees
S S S ID E S ID NUM S ID NUM PRINT
( Elist ) ID NUM PRINT ( E ) ID NUM PRINT
( NUM )
S
S
S
E
L
)
(
ID
PRINT
E
NUM
NUM
18Parse Trees
- Example 2 derivations, but 1 tree
S S S ID E S ID NUM S ID NUM PRINT
( Elist ) ID NUM PRINT ( E ) ID NUM PRINT
( NUM )
S
S
S
E
L
)
(
ID
PRINT
S S S S PRINT ( Elist ) S PRINT ( E ) S
PRINT ( NUM ) ID E PRINT ( NUM ) ID NUM
PRINT ( NUM )
E
NUM
NUM
19Parse Trees
- parse trees have meaning.
- order of children, nesting of subtrees is
significant
S
S
S
S
S
S
E
L
)
(
ID
L
)
(
PRINT
PRINT
E
ID
E
E
NUM
NUM
NUM
NUM
20Ambiguous Grammars
- a grammar is ambiguous if the same sequence of
tokens can give rise to two or more parse trees
21Ambiguous Grammars
characters 4 5 6 tokens NUM(4)
PLUS NUM(5) MULT NUM(6)
E
non-terminals E terminals ID NUM PLUS
MULT E ID NUM E E
E E
E
E
E
E
NUM(4)
NUM(6)
NUM(5)
I like using this notation where I avoid
repeating E
22Ambiguous Grammars
characters 4 5 6 tokens NUM(4)
PLUS NUM(5) MULT NUM(6)
E
non-terminals E terminals ID NUM PLUS
MULT E ID NUM E E
E E
E
E
E
E
NUM(4)
NUM(6)
NUM(5)
E
E
E
E
E
NUM(6)
NUM(5)
NUM(4)
23Ambiguous Grammars
- problem compilers use parse trees to interpret
the meaning of parsed expressions - different parse trees have different meanings
- eg (4 5) 6 is not 4 (5 6)
- languages with ambiguous grammars are DISASTROUS
The meaning of programs isnt well-defined! You
cant tell what your program might do! - solution rewrite grammar to eliminate ambiguity
- fold precedence rules into grammar to
disambiguate - fold associativity rules into grammar to
disambiguate - other tricks as well
24Building Parsers
- In theory classes, you might have learned about
general mechanisms for parsing all CFGs - algorithms for parsing all CFGs are expensive
- to compile 1/10/100 million-line applications,
compilers must be fast. - even for 10 thousand-line apps, speed is nice
- sometimes 1/3 of compilation time is spent in
parsing - compiler writers have developed specialized
algorithms for parsing the kinds of CFGs that you
need to build effective programming languages - LL(k), LR(k) grammars can be parsed.
25Recursive Descent Parsing
- Recursive Descent Parsing (Appel Chap 3.2)
- aka predictive parsing top-down parsing
- simple, efficient
- can be coded by hand in ML quickly
- parses many, but not all CFGs
- parses LL(1) grammars
- Left-to-right parse Leftmost-derivation 1
symbol lookahead - key ideas
- one recursive function for each non terminal
- each production becomes one clause in the function
26non-terminals S, E, L terminals NUM, IF,
THEN, ELSE, BEGIN, END, PRINT, , rules
1. S IF E THEN S ELSE S 2. BEGIN S
L 3. PRINT E
4. L END 5. S L 6. E NUM
NUM
27non-terminals S, E, L terminals NUM, IF,
THEN, ELSE, BEGIN, END, PRINT, , rules
1. S IF E THEN S ELSE S 2. BEGIN S
L 3. PRINT E
4. L END 5. S L 6. E NUM
NUM
Step 1 Represent the tokens
datatype token NUM IF THEN ELSE BEGIN
END PRINT SEMI EQ
Step 2 build infrastructure for reading tokens
from lexing stream
val tok ref (getToken ()) fun advance () tok
getToken () fun eat t if (! tok t) then
advance () else error ()
28non-terminals S, E, L terminals NUM, IF,
THEN, ELSE, BEGIN, END, PRINT, , rules
1. S IF E THEN S ELSE S 2. BEGIN S
L 3. PRINT E
4. L END 5. S L 6. E NUM
NUM
Step 1 Represent the tokens
datatype token NUM IF THEN ELSE BEGIN
END PRINT SEMI EQ
Step 2 build infrastructure for reading tokens
from lexing stream
val tok ref (getToken ()) fun advance () tok
getToken () fun eat t if (! tok t) then
advance () else error ()
29non-terminals S, E, L terminals NUM, IF,
THEN, ELSE, BEGIN, END, PRINT, , rules
1. S IF E THEN S ELSE S 2. BEGIN S
L 3. PRINT E
4. L END 5. S L 6. E NUM
NUM
val tok ref (getToken ()) fun advance () tok
getToken () fun eat t if (! tok t) then
advance () else error ()
datatype token NUM IF THEN ELSE BEGIN
END PRINT SEMI EQ
Step 3 write parser gt one function per
non-terminal one clause per rule
fun S () case !tok of IF gt eat
IF E () eat THEN S () eat ELSE S ()
BEGIN gt eat BEGIN S () L () PRINT gt
eat PRINT E () and L () case !tok of END
gt eat END SEMI gt eat SEMI S ()
L () and E () eat NUM eat EQ eat NUM
30non-terminals A, S, E, L rules
1. A S EOF 2. ID E 3.
PRINT ( L )
4. E ID 5. NUM 6. L E 7.
L , E
fun A () S () eat EOF and S () case !tok
of ID gt eat ID eat ASSIGN E
() PRINT gt eat PRINT eat LPAREN L ()
eat RPAREN and E () case !tok of ID
gt eat ID NUM gt eat NUM and L
() case !tok of ID gt ???
NUM gt ???
31problem
- predictive parsing only works for grammars where
the first terminal symbol of each self-expression
provides enough information to choose which
production to use - LL(1)
- if !tok ID, the parser cannot determine which
production to use
6. L E (E could be ID) 7.
L , E (L could be E could be ID)
32solution
- eliminate left-recursion
- rewrite the grammar so it parses the same
language but the rules are different
A S EOF ID E PRINT ( L
) E ID NUM
A S EOF ID E PRINT ( L
) E ID NUM
L E M M , E M
L E L , E
33eliminating left-recursion in general
- Original grammar form
- Transformed grammar
X base X X repeat
Strings base repeat repeat ...
X base Xnew Xnew repeat Xnew Xnew
Strings base repeat repeat ...
34Recursive Descent Parsing
- Unfortunately, left factoring doesnt always work
- Questions
- how do we know when we can parse grammars using
recursive descent? - Is there an algorithm for generating such parsers
automatically?
35 Constructing RD Parsers
- To construct an RD parser, we need to know what
rule to apply when - we have seen a non terminal X
- we see the next terminal a in input
- We apply rule X s when
- a is the first symbol that can be generated by
string s, OR - s reduces to the empty string (is nullable) and a
is the first symbol in any string that can follow
X
36 Constructing RD Parsers
- To construct an RD parser, we need to know what
rule to apply when - we have seen a non terminal X
- we see the next terminal a in input
- We apply rule X s when
- a is the first symbol that can be generated by
string s, OR - s reduces to the empty string (is nullable) and a
is the first symbol in any string that can follow
X
37 Constructing Predictive Parsers
1. Y 2. bb
5. Z d
3. X c 4. Y Z
next terminal
rule
non-terminal seen
X c
X b
X d
38 Constructing Predictive Parsers
1. Y 2. bb
5. Z d
3. X c 4. Y Z
next terminal
rule
non-terminal seen
X c 3
X b
X d
39 Constructing Predictive Parsers
1. Y 2. bb
5. Z d
3. X c 4. Y Z
next terminal
rule
non-terminal seen
X c 3
X b 4
X d
40 Constructing Predictive Parsers
1. Y 2. bb
5. Z d
3. X c 4. Y Z
next terminal
rule
non-terminal seen
X c 3
X b 4
X d 4
41Constricting Predictive Parsers
- in general, must compute
- for each production X s, must determine if s
can derive the empty string. - if yes, X ? Nullable
- for each production X s, must determine the
set of all first terminals Q derivable from s - Q ? First(X)
- for each non terminal X, determine all terminals
symbols Q that immediately follow X - Q ? Follow(X)
42Iterative Analysis
- Many compilers algorithms are iterative
techniques. - Iterative analysis applies when
- must compute a set of objects with some property
P - P is defined inductively. ie, there are
- base cases objects o1, o2 obviously have
property P - inductive cases if certain objects (o3, o4)
have property P, this implies other objects (f
o3 f o4) have property P - The number of objects in the set is finite
- or we can represent infinite collections using
some finite notation we can find effective
termination conditions
43Iterative Analysis
- general form
- initialize set S with base cases
- applied inductive rules over and over until you
reach a fixed point - a fixed point is a set that does not change when
you apply an inductive rule - Nullable, First and Follow sets can be determined
through iteration - many program optimizations use iteration
- worst-case complexity is bad
- average-case complexity is good iteration
usually terminates in a couple of rounds
44Computing Nullable Sets
- Non-terminal X is Nullable only if the following
constraints are satisfied (computed using
iterative analysis) - base case
- if (X ) then X is Nullable
- inductive case
- if (X ABC...) and A, B, C, ... are all
Nullable then X is Nullable
45Computing First Sets
- First(X) is computed iteratively
- base case
- if T is a terminal symbol then First (T) T
- inductive case
- if X is a non-terminal and (X ABC...) then
- First (X) First (X) U First (ABC...)
- where First(ABC...) F1 U F2 U F3 U ... and
- F1 First (A)
- F2 First (B), if A is Nullable
- F3 First (C), if A is Nullable B is Nullable
- ...
46Computing Follow Sets
- Follow(X) is computed iteratively
- base case
- initially, we assume nothing in particular
follows X - (Follow (X) is initially )
- inductive case
- if (Y s1 X s2) for any strings s1, s2 then
- Follow (X) First (s2) U Follow (X)
- if (Y s1 X s2) for any strings s1, s2 then
- Follow (X) Follow(Y) U Follow (X), if s2 is
Nullable
47building a predictive parser
Y c Y
X a X b Y e
Z X Y Z Z d
nullable first follow
Z
Y
X
48building a predictive parser
Y c Y
X a X b Y e
Z X Y Z Z d
nullable first follow
Z no
Y yes
X no
base case
49building a predictive parser
Y c Y
X a X b Y e
Z X Y Z Z d
nullable first follow
Z no
Y yes
X no
after one round of induction, we realize we have
reached a fixed point
50building a predictive parser
Y c Y
X a X b Y e
Z X Y Z Z d
nullable first follow
Z no d
Y yes c
X no a,b
base case
51building a predictive parser
Y c Y
X a X b Y e
Z X Y Z Z d
nullable first follow
Z no d,a,b
Y yes c
X no a,b
after one round of induction, no fixed point
52building a predictive parser
Y c Y
X a X b Y e
Z X Y Z Z d
nullable first follow
Z no d,a,b
Y yes c
X no a,b
after two rounds of induction, no more changes
gt fixed point
53building a predictive parser
Y c Y
X a X b Y e
Z X Y Z Z d
nullable first follow
Z no d,a,b
Y yes c
X no a,b
base case
54building a predictive parser
Y c Y
X a X b Y e
Z X Y Z Z d
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
after one round of induction, no fixed point
55building a predictive parser
Y c Y
X a X b Y e
Z X Y Z Z d
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
after two rounds of induction, fixed point (but
notice, computing Follow(X) before Follow (Y)
would have required 3rd round)
56Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d
Y c Y
X a X b Y e
- if T ? First(s) then
- enter (X s) in row X, col T
- if s is Nullable and T ? Follow(X)
- enter (X s) in row X, col T
Build parsing table where row X, col T tells
parser which clause to execute in function X with
next-token T
a b c d e
Z
Y
X
57Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d
Y c Y
X a X b Y e
- if T ? First(s) then
- enter (X s) in row X, col T
- if s is Nullable and T ? Follow(X)
- enter (X s) in row X, col T
Build parsing table where row X, col T tells
parser which clause to execute in function X with
next-token T
a b c d e
Z Z XYZ Z XYZ
Y
X
58Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d
Y c Y
X a X b Y e
- if T ? First(s) then
- enter (X s) in row X, col T
- if s is Nullable and T ? Follow(X)
- enter (X s) in row X, col T
Build parsing table where row X, col T tells
parser which clause to execute in function X with
next-token T
a b c d e
Z Z XYZ Z XYZ Z d
Y
X
59Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d
Y c Y
X a X b Y e
- if T ? First(s) then
- enter (X s) in row X, col T
- if s is Nullable and T ? Follow(X)
- enter (X s) in row X, col T
Build parsing table where row X, col T tells
parser which clause to execute in function X with
next-token T
a b c d e
Z Z XYZ Z XYZ Z d
Y Y c
X
60Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d
Y c Y
X a X b Y e
- if T ? First(s) then
- enter (X s) in row X, col T
- if s is Nullable and T ? Follow(X)
- enter (X s) in row X, col T
Build parsing table where row X, col T tells
parser which clause to execute in function X with
next-token T
a b c d e
Z Z XYZ Z XYZ Z d
Y Y Y Y c Y Y
X
61Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d
Y c Y
X a X b Y e
- if T ? First(s) then
- enter (X s) in row X, col T
- if s is Nullable and T ? Follow(X)
- enter (X s) in row X, col T
Build parsing table where row X, col T tells
parser which clause to execute in function X with
next-token T
a b c d e
Z Z XYZ Z XYZ Z d
Y Y Y Y c Y Y
X X a X b Y e
62Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d
Y c Y
X a X b Y e
What are the blanks?
a b c d e
Z Z XYZ Z XYZ Z d
Y Y Y Y c Y Y
X X a X b Y e
63Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d
Y c Y
X a X b Y e
What are the blanks? --gt syntax errors
a b c d e
Z Z XYZ Z XYZ Z d
Y Y Y Y c Y Y
X X a X b Y e
64Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d
Y c Y
X a X b Y e
Is it possible to put 2 grammar rules in the same
box?
a b c d e
Z Z XYZ Z XYZ Z d
Y Y Y Y c Y Y
X X a X b Y e
65Grammar
Computed Sets
nullable first follow
Z no d,a,b
Y yes c e,d,a,b
X no a,b c,e,d,a,b
Z X Y Z Z d Z d e
Y c Y
X a X b Y e
Is it possible to put 2 grammar rules in the same
box?
a b c d e
Z Z XYZ Z XYZ Z d Z d e
Y Y Y Y c Y Y
X X a X b Y e
66predictive parsing tables
- if a predictive parsing table constructed this
way contains no duplicate entries, the grammar is
called LL(1) - Left-to-right parse, Left-most derivation, 1
symbol lookahead - if not, of the grammar is not LL(1)
- in LL(k) parsing table, columns include every
k-length sequence of terminals
aa ab ba bb ac ca ...
67another trick
- Previously, we saw that grammars with
left-recursion were problematic, but could be
transformed into LL(1) in some cases - the example non-LL(1) grammar we just saw
- how do we fix it?
Z X Y Z Z d Z d e
Y c Y
X a X b Y e
68another trick
- Previously, we saw that grammars with
left-recursion were problematic, but could be
transformed into LL(1) in some cases - the example non-LL(1) grammar we just saw
- solution here is left-factoring
Z X Y Z Z d Z d e
Y c Y
X a X b Y e
Z X Y Z Z d W
Y c Y
X a X b Y e
W W e
69summary
- CFGs are good at specifying programming language
structure - parsing general CFGs is expensive so we define
parsers for simple classes of CFG - LL(k), LR(k)
- we can build a recursive descent parser for LL(k)
grammars by - computing nullable, first and follow sets
- constructing a parse table from the sets
- checking for duplicate entries, which indicates
failure - creating an ML program from the parse table
- if parser construction fails we can
- rewrite the grammar (left factoring, eliminating
left recursion) and try again - try to build a parser using some other method