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Subroutines (Part 1)

Subroutines (Part 1). CSE 262, Spring 2003. Subroutines. Method of process abstraction Supports modular design Improves readability Allows code reuse Conserves memory Saves coding time Characteristics: Single Entry Calling program blocks during subroutine call

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Subroutines (Part 1)

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  1. Subroutines (Part 1) CSE 262, Spring 2003 © 2003 G. Drew Kessler and William M. Pottenger

  2. Subroutines • Method of process abstraction • Supports modular design • Improves readability • Allows code reuse • Conserves memory • Saves coding time • Characteristics: • Single Entry • Calling program blocks during subroutine call • Control always returns to caller • Except: co-routines, concurrent execution © 2003 G. Drew Kessler and William M. Pottenger

  3. Design Issues & Mechanisms • Method of parameter passing • Function vs. procedure • Mathematical function vs. program statement • Local and non-local referencing environments • Overloaded subroutines • Generic subroutines • Separate compilation, independent compilation • Require info for type checking separately compiled subroutines? • Aliasing and side effect problems © 2003 G. Drew Kessler and William M. Pottenger

  4. Subroutine Parameters • Parameters • Provide access to data outside of subroutine • ‘Safer’ than using global variables • Allows for specialization of computational tasks • Actual parameters: values given at subprogram call site • Formal parameters are given in subprogram definition © 2003 G. Drew Kessler and William M. Pottenger

  5. Subprogram Definition • Subprogram header: first line of definition • Provides name, list of parameters (0 or more) • May use special word (“procedure”, “function”, “subroutine”), or context (as in C) • Parameter profile: provides #, order, and types of formal parameters • Parameter protocol: profile plus subroutine return type • Subprogram declaration or prototype: provides info needed by compiler to do type-checking, before definition (some languages need forward qualifier) © 2003 G. Drew Kessler and William M. Pottenger

  6. Parameter Designs • Association between formal and actual parameters: • Positional parameters void sort(int list[], int size, bool ascending); sort(numbers, n, true); // call to sort() • Keyword parameters sort(size=>n, list=>numbers, ascending=>true); //call • Default parameters? void sort(int list[], int size=100, bool ascending=true); sort(numbers); // call to sort() • Parameter list length fixed? (In C++, “...” is 0 or more) void sort(int list[], …); // avoid type checking of … sort(numbers, size); // call to sort() sort(…); // Will this work? What does it mean? What commonly used C function employs this ellipsis operator? How does it work? • Parameters (& subroutine parameters) type-checked? © 2003 G. Drew Kessler and William M. Pottenger

  7. Local and Non-Local Referencing Environments • Local variables defined inside subroutine • Formal parameters are usually local variables • Non-local variables are either global or are variables that are in scope but local to another subroutine • Local variable storage • Static • Allows direct access • Provides for history sensitive subroutines • Stack-dynamic • Allows recursion • Provides memory savings © 2003 G. Drew Kessler and William M. Pottenger

  8. Parameter Passing Methods • Semantic modes: • In, out, in out • Implementation methods of data transfer: • value, access path (a.k.a. reference) • Methods: • Pass-by-value (in) • Pass-by-result (out) • We’re not referring to the subroutine’s return value here! • Pass-by-value-result (in out, value) • (a.k.a. pass-by-copy) • Pass-by-reference (in out, reference) • Pass-by-name (in out, other) © 2003 G. Drew Kessler and William M. Pottenger

  9. Parameter Passing Examples Caller Subroutine Actual parameter Formal parameter Pass-by-value Pass-by-result Pass-by-value-result Pass-by-reference © 2003 G. Drew Kessler and William M. Pottenger

  10. Parameter Passing in Various Languages • Wide variety of implementations • Fortran: always by reference • Pascal: programmers choice (var) • C: by value (except for arrays/explicit pointers) • C++: by value, C++ ‘reference’ or as with C • Java: ‘built-ins’ by value; others by reference © 2003 G. Drew Kessler and William M. Pottenger

  11. Parameter Passing in Ada • In, In/Out, Out: • Ada parameter passing can be implemented by value or reference… • Morgan Kaufmann (Figure reproduced by permission of author/publisher) © 2003 G. Drew Kessler and William M. Pottenger

  12. Call-by-Name Example (ALGOL 60) real procedure sum ( k, l, u, ak) value l, u; integer k, l, u; real ak; begin real s; s := 0; for k := l step 1 until u do s := s + ak end • Use: x := sum (i, 1, n, V[i]) x := sum (i, 1, m, sum(j, 1, n, A[i, j])) (Jensen’s Device) © 2003 G. Drew Kessler and William M. Pottenger

  13. Call-by-Name Problem • Consider a swap routine: procedure swap (j, k) integer j, k; begin integer t; t := j; j := k; k := t; end; • And, consider this: i := 1, A[1]:=2, A[2]:=8 swap(i, A[i]) • Do other methods have a problem with this? © 2003 G. Drew Kessler and William M. Pottenger

  14. Overloaded subprograms • System and user-defined • Same name, different operation • Right operation identified by parameter and return types • Return type distinction not available if mixed-mode expressions allowed • For example: int f (int i) {…;} float f (int i) {…;} int i = j = 7; float result = f(i) + f(j); // Which f() is called? © 2003 G. Drew Kessler and William M. Pottenger

  15. Generic subroutines • Provide routine, where parameter and/or variable types are defined at a later time. • New instance of routine with specific type created when needed or explicitly • Ada generic units • C++ templates template <class Type> Type findMax(Type list[], int size) { Type max = list[0]; for (int i=1; i<size; i++) if (list[i]<max) max = list[i]; return max; } © 2003 G. Drew Kessler and William M. Pottenger

  16. Generic Subroutines/Modules • Morgan Kaufmann (Figure reproduced by permission of author/publisher) Is it wise to return item by value? © 2003 G. Drew Kessler and William M. Pottenger

  17. Inline Expansion • C++ and Ada support ‘inline expansion’ • C++: • inline int max (int a, int b) { • return a > b ? a : b; • } • Ada: • pragma inline (max); • Avoids potential problems with macros: e.g., • #define MAX(a,b) ((a) > (b) ? (a) : (b)) • Doesn’t work when ‘calling’ MAX(x++,y++) • Costs more – increase in code size/compile time © 2003 G. Drew Kessler and William M. Pottenger

  18. Co- Routines © 2003 G. Drew Kessler and William M. Pottenger

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