CSI3120A Fall 2023 Lecture 9 PDF

Summary

This document appears to be lecture notes on implementing subprograms in programming languages. It covers concepts like subprogram linkage, call semantics, return semantics, and activation records. It also provides examples using C and JavaScript.

Full Transcript

Chapter 10

Implementing
Subprograms

ISBN 0- 0-321-49362-1

Chapter 10 Topics
• The General Semantics of Calls and Returns
• Implementing “Simple” Subprograms
• Implementing Subprograms with Stack-Dynamic
Local Variables
• Nested Subprograms
• Blocks
• Implementing Dynamic Scoping

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1-2

The General Semantics of Calls and
Returns
• The subprogram call and return operations
of a language are together called its

subprogram linkage

• General semantics of calls to a subprogram
–
–
–
–
–

Parameter passing methods
Stack-dynamic allocation of local variables
Save the execution status of calling program
Transfer of control and arrange for the return
If subprogram nesting is supported, access to
nonlocal variables must be arranged

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1-3

The General Semantics of Calls and
Returns
• General semantics of subprogram returns:
– In mode and inout mode parameters
must have their values returned
– Deallocation of stack-dynamic locals
– Restore the execution status
– Return control to the caller

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1-4

Implementing “Simple” Subprograms
• Call Semantics:
-

Save the execution status of the caller
Pass the parameters
Pass the return address to the called
Transfer control to the called

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1-5

Implementing “Simple” Subprograms
(continued)

• Return Semantics:

– If pass-by-value-result or out mode parameters
are used, move the current values of those
parameters to their corresponding actual
parameters
– If it is a function, move the functional value to a
place the caller can get it
– Restore the execution status of the caller
– Transfer control back to the caller

• Required storage:

– Status information, parameters, return address,
return value for functions, temporaries

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1-6

Implementing “Simple” Subprograms
(continued)

• Two separate parts: the actual code and the
non-code part (local variables and data that
can change)
• The format, or layout, of the non-code part
of an executing subprogram is called an

activation record
• An activation record instance is a concrete
example of an activation record (the
collection of data for a particular
subprogram activation)

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1-7

An Activation Record for “Simple”
Subprograms

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1-8

Code and Activation Records of a
Program with “Simple” Subprograms

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1-9

Implementing Subprograms with
Stack-Dynamic Local Variables
• More complex activation record

– The compiler must generate code to cause
implicit allocation and deallocation of local
variables
– Recursion must be supported (adds the
possibility of multiple simultaneous activations
of a subprogram)

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1-10

Typical Activation Record for a Language
with Stack-Dynamic Local Variables

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1-11

Implementing Subprograms with StackDynamic Local Variables: Activation Record
• The activation record format is static, but its size
may be dynamic
• The dynamic link points to the base of an instance
of the activation record of the caller
• An activation record instance is dynamically
created when a subprogram is called
• Activation record instances reside on the run-time
stack
• The Environment Pointer (EP) must be maintained
by the run-time system. It always points at the
base of the activation record instance of the
currently executing program unit
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1-12

An Example: C Function
void sub(float total, int part)
{
int list[5];
float sum;
…
}

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1-13

Revised Semantic Call/Return Actions
• Caller Actions:
–
–
–
–
–

Create an activation record instance
Save the execution status of the current program unit
Compute and pass the parameters
Pass the return address to the called
Transfer control to the called

• Prologue actions of the called:

– Save the old EP in the stack as the dynamic link and create
the new value
– Allocate local variables

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1-14

Revised Semantic Call/Return Actions
(continued)

• Epilogue actions of the called:

– If there are pass-by-value-result or out-mode
parameters, the current values of those parameters are
moved to the corresponding actual parameters
– If the subprogram is a function, its value is moved to a
place accessible to the caller
– Restore the stack top pointer by setting it to the value of
the current EP-1 and set the EP to the old dynamic link
– Restore the execution status of the caller
– Transfer control back to the caller

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1-15

An Example Without Recursion
void fun1(float r) {
int s, t;
...
fun2(s);
...
}
void fun2(int x) {
int y;
...
fun3(y);
...
}
void fun3(int q) {
...
}
void main() {
float p;
...
fun1(p);
...
}
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main calls fun1
fun1 calls fun2
fun2 calls fun3

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An Example Without Recursion

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1-17

Dynamic Chain and Local Offset
• The collection of dynamic links in the stack at a
given time is called the dynamic chain, or call

chain

• Local variables can be accessed by their offset
from the beginning of the activation record, whose
address is in the EP. This offset is called the

local_offset

• The local_offset of a local variable can be
determined by the compiler at compile time

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1-18

An Example With Recursion
• The activation record used in the
previous example supports recursion
int factorial (int n) {
<-----------------------------1
if (n <= 1) return 1;
else return (n * factorial(n - 1));
<-----------------------------2
}
void main() {
int value;
value = factorial(3);
<-----------------------------3
}

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1-19

Activation Record for factorial

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1-20

Stacks for calls to

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factorial

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Stacks for returns from

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factorial

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Nested Subprograms
•

•
•

Some non-C-based static-scoped languages
(e.g., Fortran 95+, Ada, Python, JavaScript, Ruby,
and Swift) use stack-dynamic local variables and
allow subprograms to be nested
All variables that can be non-locally accessed
reside in some activation record instance in the
stack
The process of locating a non-local reference:

1. Find the correct activation record instance
2. Determine the correct offset within that activation record
instance

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1-23

Locating a Non-local Reference
• Finding the offset is easy
• Finding the correct activation record
instance

– Static semantic rules guarantee that all nonlocal variables that can be referenced have been
allocated in some activation record instance that
is on the stack when the reference is made

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1-24

Static Scoping
• A static chain is a chain of static links that
connects certain activation record instances
• The static link in an activation record instance for
subprogram A points to one of the activation
record instances of A's static parent
• The static chain from an activation record instance
connects it to all of its static ancestors
• Static_depth is an integer associated with a static
scope whose value is the depth of nesting of that
scope
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1-25

Static Scoping

(continued)

• The chain_offset or nesting_depth of a nonlocal
reference is the difference between the
static_depth of the reference and that of the scope
when it is declared
• A reference to a variable can be represented by the
pair:
(chain_offset, local_offset),
where local_offset is the offset in the activation
record of the variable being referenced

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1-26

Example JavaScript Program
function main(){
var x;
function bigsub() {
var a, b, c;
function sub1 {
var a, d;
function main(){
var x;
function bigsub() {
var a, b, c;
function sub1 {
var a, d;
a = b + c; -------------------------------1
...
} // end of sub1
function sub2(x) {
var b, e;
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1-27

Example JavaScript Program (continued)
function sub3() {
var c, e;
...
sub1();
...
e = b + a; ------------------------------2
} // end of sub3 ...
sub3();
...
a = d + e; --------------------------------3
} // end of sub2
...
sub2(7);
...
} // end of bigsub
...
bigsub();
...
} // end of main
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1-28

Example JavaScript Program (continued)
• Call sequence for main
main calls bigsub
bigsub calls sub2
sub2 calls sub3
sub3 calls sub1

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1-29

Stack Contents at
Position 1

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1-30

Static Chain Maintenance
• At the call,
- The activation record instance must be built
- The dynamic link is just the old stack top pointer
- The static link must point to the most recent ari
of the static parent
- Two methods:
1. Search the dynamic chain
2. Treat subprogram calls and
definitions like variable references
and definitions

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1-31

Evaluation of Static Chains
• Problems:
1. A nonlocal reference is slow if the
nesting depth is large
2. Time-critical code is difficult:
a. Costs of nonlocal references are
difficult to determine
b. Code changes can change the
nesting depth, and therefore the cost

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1-32

Blocks
• Blocks are user-specified local scopes for variables
• An example in C
{int temp;
temp = list [upper];
list [upper] = list [lower];
list [lower] = temp
}

• The lifetime of temp in the above example begins
when control enters the block
• An advantage of using a local variable like temp is
that it cannot interfere with any other variable with
the same name

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1-33

Implementing Blocks
• Two Methods:

1. Treat blocks as parameter-less subprograms
that are always called from the same location
–

Every block has an activation record; an instance is
created every time the block is executed

2. Since the maximum storage required for a
block can be statically determined, this amount
of space can be allocated after the local
variables in the activation record

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1-34

Implementing Dynamic Scoping
• Deep Access: non-local references are
found by searching the activation record
instances on the dynamic chain
- Length of the chain cannot be statically
determined
- Every activation record instance must
have variable names

• Shallow Access: put locals in a central place
– One stack for each variable name
– Central table with an entry for each variable
name

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1-35

Using Shallow Access to Implement
Dynamic Scoping
void sub3() {
int x, z;
x = u + v;
…
}
void sub2() {
int w, x;
…
}
void sub1() {
int v, w;
…
}
void main() {
int v, u;
…
}

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1-36

Summary
• Subprogram linkage semantics requires
many action by the implementation
• Simple subprograms have relatively basic
actions
• Stack-dynamic languages are more
complex
• Subprograms with stack-dynamic local
variables and nested subprograms have two
components
– actual code
– activation record

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1-37

Summary (continued)
• Activation record instances contain formal
parameters and local variables among other
things
• Static chains are the primary method of
implementing accesses to non-local
variables in static-scoped languages with
nested subprograms
• Access to non-local variables in dynamicscoped languages can be implemented by
use of the dynamic chain or thru some
central variable table method
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1-38