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Semantic Analysis. Chapter 6. Two Flavors. Static (done during compile time) C Ada Dynamic (done during run time) LISP Smalltalk Optimization. Static Semantic Analysis. Build symbol table Keep track of declarations Perform type checking. Static Analysis. Description
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Semantic Analysis Chapter 6
Two Flavors • Static (done during compile time) • C • Ada • Dynamic (done during run time) • LISP • Smalltalk • Optimization
Static Semantic Analysis • Build symbol table • Keep track of declarations • Perform type checking
Static Analysis • Description • Attributes (properties) • Implementation • Attribute equations (semantic rules) • Application of rules Syntax-directed semantics
General Attribute • Property of the Language • Data type • Value of expressions • Location of variables in memory • Object code of procedure • Number of Significant digits
Specific Attributes • Parameters/Arguments type • Parameters/Arguments number • Array subscript type • Array subscript number • Continue with no place to continue to • Variable undeclared • Variable duplicately declared • Scope • Incorrect structure reference
Specific Attributes Cont. • Break inappropriate • Incorrect Return • Wrong type • Array • None when needed (void) • No main • Two main’s • Constant on left side • Expression types
Binding Time of Attributes • Static - prior to execution • Fortran • Dynamic - during execution • Combination • C • Java • Pascal
Attribute Grammars • X is grammar symbol, Xa is an attribute for this symbol XABCD (grammar) X.x= A.a B.b C.c D.d (attribute grammar)
Attribute Grammar Example • E1 E2 + T E1.type= E2.type+ T.type
Attribute Grammar Example • decl type var-list var-list.dtype =type.dtype • type int type.dtype = integer • type float type.dtype = float • var-list1 id, var-list2 id.dtype = var-list1.dtype var-list2.dtype = var-list1.dtype • var-list id id.dtype = var-list.dtype
Attribute Grammar Comments • Symbols may have more than one attribute • The grammar is not the master • More of a guide
Attribute Grammar Example • E1 E2 + T E1.tree= mkOpNode(+, E2.tree, T.tree) • E T E.tree = T.tree • F number F.tree = mkNumNode(number.lexval)
Attribute Up and DownDependency Tree • Synthesized • Point from child to parent • Inherited • Point child to child or parent to child
Symbol Tables • Lists of Lists • Hash • Collision resolving by use of buckets • Collision resolving by probing • …
Symbol Tables • Keep track of identifiers • Must deal with scope efficiently
Code Fragment int f(int size) { char i, temp; … { double j, i; } { char * j; *j = i = 5; } }
Static vs Dynamic Scopecompile time or run time int i = 1; void f(void) { printf(“%d\n”,i); } void main(void) { int i = 2; f(); return; } What is printed?
Kinds of Declarations • Sequential – each declaration is available starting with the next line • C • Collateral – each declaration is evaluated in the environment preceding the declaration group. Declared identifiers are available only after all finishes. • scheme • ML • Recursive - requires the function name to be added to the symbol table before processing the body of the function. C functions and type declarations are recursive.
Example - Sequential/Colateralorder is not important with in group int i = 1; void f(void) { int i = 2, j = i + 1; … } Is j 2 or 3?
Example - Recursive int gcd(int n, int m) { if (m == 0) return n; else return gcd(m, n%m); } gcd must be added to the symbol table before processing the body
Example - Recursive void f(void) { … g() … } void g(void) { … f() … } Resolved by using prototype. Some languages have issue with using g before g is defined. (pascal)
Data Types – Type Checking • Explicit datatype • int x • Implicit datatype • #define x 5
Implementation of Types • Hardware implementation • int • double • float • Software implementation • boolean • char • enum – can be integers to save space
More Complicated Types • Arrays • base(b)+i*esize • base(ar)+(i1*r2 +i2)*esize • Records • allocate memory sequentially • base+displacement
Type Checking Statements • S id = E S.type = if id.type = E.type then void else error • S if E then S1 S.type=if E.type=boolean then S1.type
Equivalence of type Expressions • Structural Equivalence • two expressions are either the same basic type, or are formed by applying the same constructor to structurally equivalent types. I.E. equivalent only if they are identical. • Example typedef link = *cell link next; cell * p; • Name Equivalence • two expressions use the same name
Name Equivalence typedef int t1; typedef int t2; t2 and t1 are not the same type. int typeEqual(t1, t2) { if (t1 and t2 are simple types) return t1 == t2; if (t1 and t2 are type names) return t1 == t2; else return 0;} in case you read the text
Name Equivalence typedef int t1; typedef int t2; t2 x; t2 y; t1 z; x and y are the same type. z is not the same type.