1. CSCE 531 Compiler Construction Ch.7: Code Generation
Spring 2013
Marco Valtorta

2. Acknowledgment
The slides are based on the textbooks and other sources, including slides from Bent Thomsen’s course at the University of Aalborg in Denmark and several other fine textbooks
We will also use parts of Torben Mogensen’s online textbook, Basics of Compiler Design
The three main other compiler textbooks I considered are:
Aho, Alfred V., Monica S. Lam, Ravi Sethi, and Jeffrey D. Ullman. Compilers: Principles, Techniques, & Tools, 2nd ed. Addison-Welsey, (The “dragon book”)
Appel, Andrew W. Modern Compiler Implementation in Java, 2nd ed. Cambridge, (Editions in ML and C also available; the “tiger books”)
Grune, Dick, Henri E. Bal, Ceriel J.H. Jacobs, and Koen G. Langendoen. Modern Compiler Design. Wiley, 2000

3. What This Lecture is About
A compiler translates a program from a high-level language into an equivalent program in a low-level language.
Triangle Program
Compile
TAM Program
Run
Result

4. Programming Language specification
A Language specification has (at least) three parts:
Syntax of the language: usually formal: EBNF
Contextual constraints:
scope rules (often written in English, but can be formal)
type rules (formal or informal)
Semantics:
defined by the implementation
informal descriptions in English
formal using operational, axiomatic, or denotational semantics

5. The “Phases” of a Compiler
Source Program
Syntax Analysis
Error Reports
Abstract Syntax Tree
Contextual Analysis
Error Reports
Decorated Abstract Syntax Tree
Code Generation
Chapter 7
Object Code

6. Multi Pass Compiler
A multi pass compiler makes several passes over the program. The output of a preceding phase is stored in a data structure and used by subsequent phases.
Dependency diagram of a typical Multi Pass Compiler:
Compiler Driver
Chapter 7
calls
calls
calls
Syntactic Analyzer
Contextual Analyzer
Code Generator
input
Source Text
output
AST
Decorated AST
Object Code

7. Issues in Code Generation
Code Selection:
Deciding which sequence of target machine instructions will be used to implement each phrase in the source language.
Storage Allocation
Deciding the storage address for each variable in the source program. (static allocation, stack allocation etc.)
Register Allocation (for register-based machines)
How to use registers efficiently to store intermediate results.
We use a stack based machine. This is not an issue for us

8. ~ Code Generation Source Program Target program
let var n: integer; var c: char in begin c := ‘&’; n := n+1 end
PUSH 2 LOADL 38 STORE 1[SB] LOAD 0 LOADL 1 CALL add STORE 0[SB] POP 2 HALT ~
Source and target program must be
“semantically equivalent”
Semantic specification of the source language is structured in terms of phrases in the SL: expressions, commands, etc.
=> Code generation follows the same “inductive” structure.
Q: Can you see the connection with denotational semantics?

9. “Inductive” Code Generation
“Inductive” means: code generation for a “big” structure is defined in terms of putting together chunks of code that correspond to the sub-structures.
Example: Sequential Command code generation
Semantic specification
The sequential command C1 ; C2 is executed as follows: first C1 is executed then C2 is executed.
Code generation function:
execute : Command -> Instruction*
execute [C1 ; C2] =
execute [C1]
execute [C2]
instructions for C1
instructions for
C1 ; C2
instructions for C2

10. “Inductive” Code Generation
Example: Assignment command code generation
Code generation function:
execute [I := E] =
evaluate [E]
STORE address [I]
instructions for E yield value for E on top of the stack
instruction to store result into variable
These “pictures” of the code layout for a particular source language construct are called code templates.
Inductive means: A code template specifies the object code to which a phrase is translated, in terms of the object code to which its subphrases are translated.

11. “Inductive” Code Generation
Example: code generation for a larger phrase in terms of its subphrases
LOAD f
LOAD n
CALL mult
STORE f
execute [f := f*n]
execute [f := f*n;
n := n-1]
LOAD n
CALL pred
STORE n
execute [n := n-1]

12. Specifying Code Generation with Code Templates
For each “phrase class” P in the abstract syntax of the source language:
Define code function fP : P -> Instruction*
that translate each phrase in class P to object code.
We specify the function fP by code templates. Typically they look like:
fP […Q…R…] = …
fQ [Q]
fR [R]
note: A “phrase class” typically corresponds to a non-terminal of the abstract syntax.
This in turn corresponds to an abstract class in the Java classes that implement the AST nodes. (for example Expression, Command, Declaration)

13. Specifying Code Generation with Code Templates
Example: Code templates specification for Mini Triangle
RECAP: The mini triangle AST
Program ::= Command Program
Command
::= V-name := Expression AssignCmd
| let Declaration in Command LetCmd
...
Expression
::= Integer-Literal IntegerExp
| V-name VnameExp
| Operator Expression UnaryExp
| Expression Op Expression BinaryExp
Declaration
::= ...
V-name::= Identifier SimpleVName

14. Specifying Code Generation with Code Templates
The code generation functions for Mini Triangle
Phrase Class Function Effect of the generated code
Program
Command
Expres-
sion
V-name
Decla- ration
run P
execute C
evaluate E
fetch V
assign V
elaborate D
Run program P then halt. Starting and finishing with empty stack
Execute Command C. May update variables but does not shrink or grow the stack.
Evaluate E, net result is pushing the value of E on the stack.
Push value of constant or variable on the stack.
Pop value from stack and store in variable V
Elaborate declaration, make space on the stack for constants and variables in the decl.

15. Code Generation with Code Templates
The code generation functions for Mini Triangle
Programs:
run [C] =
execute [C]
HALT
Commands:
execute [V := E] =
evaluate [E]
assign [V]
execute [I ( E )] =
CALL p where p is address of the routine named I

16. Code Generation with Code Templates
Commands:
execute [C1 ; C2] =
execute [C1]
execute [C2]
execute [if E then C1 else C2] =
evaluate [E]
JUMPIF(0) g
JUMP h
g: execute [C2] h: C1 C2 E g: h:

17. Code Generation with Code Templates
Commands:
execute [while E do C] =
JUMP h
g: execute [C]
h: evaluate[E]
JUMPIF(1) g C E
execute [while E do C] =
g: evaluate [E]
JUMPIF(0) h
execute[C]
JUMP g h:
Alternative While Command code template: E C

18. Code Generation with Code Templates
Repeat Command code template:
execute [repeat C until E] =
g: execute [C]
h: evaluate[E]
JUMPIF(0) g
execute [let D in C] =
elaborate[D]
execute [C]
POP(0) s if s>0 where s = amount of storage allocated by D C E

19. Code Generation with Code Templates
Expressions:
evaluate [IL] = note: IL is an integer literal
LOADL v where v = the integer value of IL
evaluate [V] = note: V is variable name
fetch[V]
evaluate [O E] = note: O is a unary operator
evaluate[E]
CALL p where p = address of routine for O
evaluate [E1 O E2] = note: O is a binary operator
evaluate[E1]
evaluate[E2]

20. Code Generation with Code Templates
Variables:
note: Mini triangle only needs static allocation (Q: why is that? )
fetch [V] =
LOAD d[SB] where d = address of V relative to SB
assign [V] =
STORE d[SB] where d = address of V relative to SB

21. Code Generation with Code Templates
Declarations:
elaborate [const I ~ E] =
evaluate[E]
elaborate [var I : T] =
PUSH s where s = size of T
elaborate [D1 ; D2] =
elaborate [D1]
elaborate [D2]
THE END: these are all the code templates for Mini Triangle.
Now let’s put them to use in an example.

22. Example of Mini Triangle Code Generation
execute [while i>0 do i:=i+2] =
JUMP h
g: LOAD i
LOADL 2
CALL add
STORE i
h: LOAD i
LOADL 0
CALL gt
JUMPIF(1) g
evaluate [i+2]
execute [i:=i+2]
evaluate [i>0]
Note: Picture shows a few steps but not all

23. Special Case Code Templates
There are often several ways to generate code for an expression, command, etc.
The templates we defined work, but sometimes we can get more efficient code for special cases => special case code templates.
Example:
evaluate [i+1] =
LOAD i
LOADL 1
CALL add
evaluate [i+1] =
LOAD i
CALL succ
more efficient code for
the special case “+1”
what we get with
the “general” code
templates

24. Special Case Code Templates
Example: some special case code template for “+1”, “-1”, …
evaluate [E + 1] =
evaluate [E]
CALL succ
evaluate [1 + E] =
evaluate [E]
CALL succ
evaluate [E - 1] =
evaluate [E]
CALL pred
A special-case code template is one that is applicable to phrase of a special form. Such phrases are also covered by a more general form.

25. Special Case Code Templates
Example: “Inlining” known constants.
execute [let const n~7;
var i:Integer
in i:=n*n] =
LOADL 7
PUSH 1
LOAD n
CALL mult
STORE i
POP(0) 2
elaborate [const n~7]
elaborate [var i:Integer]
execute [i:=n*n]
This is how the code looks like with no special case templates

26. Special Case Code Templates
Example: “Inlining” known constants.
Special case templates for inlining literals.
elaborate [const I ~ IL] = no code
fetch [I] = special case if I is a known literal constant
LOADL v where v is the known value of I
execute [let const n~7; var i:Integer in i:=n*n] =
PUSH 1
LOADL 7
CALL mult
STORE i
POP(0) 1

27. Code Generation Algorithm
The code templates specify how code is to be generated
=> determines code generation algorithm.
Generating code: traversal of the AST emitting instructions one by one.
The code templates determine the order of the traversal and the instructions to be emitted.
We will now look at how to implement a Mini Triangle code generator in Java.

28. Representation of Object Program: Instructions
public class Instruction {
public byte op; // op-code 0..15
public byte r; // register field (0..15)
public byte n; // length field (0..255)
public short d; // operand f. ( )
public static final byte // op-codes
LOADop = 0, LOADAop = 1, ...
public static final byte // register numbers
CBr = 0, CTr = 1, …
SBr = 4, STr = 5, …
public Instruction(byte op,byte n,
byte r,short d) { ... } }

29. Representation of Object Program: Emitting Code
public class Encoder {
private Instruction[] code =
new Instruction[1024];
private short nextInstrAddr = 0;
private void emit(byte op,byte n,
byte r,short d) {
code[nextInstrAddr++]=new Instruction(
op,n,r,d); }
... lots of other stuff in here of course ...

30. Developing a Code Generator “Visitor”
generate code as specified by execute[C]
generate code as specified by evaluate[E]
Return “entity description” for the visited variable or constant name.
generate code as specified by elaborate[D]
return the size of the type
Program
visitProgram
generate code as specified by run[P]
Command
visit…Command
Expression
visit…Expression
V-name
visit…Vname
Declaration
visit…Declaration
Type-Den
visit…TypeDen
Phrase
Class
visitor method
Behavior of the visitor method

31. Developing a Code Generator “Visitor”
For variables we have two distinct code generation functions:
fetch and assign.
=> Not implemented as visitor methods but as separate methods.
public void encodeFetch(Vname name) {
... as specified by fetch template ... }
public void encodeAssign(Vname name) {
... as specified by assign template ...

32. Developing a Code Generator “Visitor”
run [C] =
execute [C]
HALT
public class Encoder implements Visitor {
...
/* Generating code for entire Program */
public Object visitProgram(Program prog,
Object arg ) {
prog.C.visit(this,arg);
emit a halt instruction
return null; }

33. Developing a Code Generator “Visitor”
RECAP:
execute [V := E] =
evaluate [E]
assign [V]
/* Generating code for commands */
public Object visitAssignCommand(
AssignCommand com,Object arg) {
com.E.visit(this,arg);
encodeAssign(com.V);
return null; }

34. Developing a Code Generator “Visitor”
execute [I ( E )] =
evaluate [E]
CALL p where p is address of the routine named I
public Object visitCallCommand(
CallCommand com,Object arg) {
com.E.visit(this,arg);
short p = address of primitive routine for
name com.I
emit(Instruction.CALLop,
Instruction.SBr,
Instruction.PBr, p);
return null; }

35. Developing a Code Generator “Visitor”
execute [C1 ; C2] =
execute[C1]
execute[C2]
public Object visitSequentialCommand(
SequentialCommand com,Object arg) {
com.C1.visit(this,arg);
com.C2.visit(this,arg);
return null; }
LetCommand, IfCommand, WhileCommand => later.
- LetCommand is more complex: memory allocation and addresses
- IfCommand and WhileCommand: complications with jumps

36. Developing a Code Generator “Visitor”
evaluate [IL] =
LOADL v where v is the integer value of IL
/* Expressions */
public Object visitIntegerExpression (
IntegerExpression expr,Object arg) {
short v = valuation(expr.IL.spelling);
emit(Instruction.LOADLop, 0, 0, v);
return null; }
public short valuation(String s) {
... convert string to integer value ...

37. Developing a Code Generator “Visitor”
evaluate [E1 O E2] =
evaluate [E1]
evaluate [E2]
CALL p where p is the address of routine for O
public Object visitBinaryExpression (
BinaryExpression expr,Object arg) {
expr.E1.visit(this,arg);
expr.E2.visit(this,arg);
short p = address for expr.O operation
emit(Instruction.CALLop,
Instruction.SBr,
Instruction.PBr, p);
return null; }
Remaining expression visitors are developed in a similar way.

38. Controls Structures
We have yet to discuss generation for IfCommand and WhileCommand
execute [while E do C] =
JUMP h
g: execute [C]
h: evaluate[E]
JUMPIF(1) g C E
A complication is the generation of the correct addresses for the jump instructions.
We can determine the address of the instructions by incrementing a counter while emitting instructions.
Backwards jumps are easy but forward jumps are harder.
Q: why?

39. Control Structures Backwards jumps are easy:
The “address” of the target has already been generated and is known
Forward jumps are harder:
When the jump is generated the target is not yet generated so its address is not (yet) known.
There is a solution which is known as backpatching
1) Emit jump with “dummy” address (e.g. simply 0).
2) Remember the address where the jump instruction occurred.
3) When the target label is reached, go back and patch the jump instruction.

40. Backpatching Example public Object WhileCommand (
WhileCommand com,Object arg) {
short j = nextInstrAddr;
emit(Instruction.JUMPop, 0,
Instruction.CBr,0);
short g = nextInstrAddr;
com.C.visit(this,arg);
short h = nextInstrAddr;
code[j].d = h;
com.E.visit(this,arg);
emit(Instruction.JUMPIFop, 1,
Instruction.CBr,g);
return null; }
dummy address
backpatch
execute [while E do C] =
JUMP h
g: execute [C]
h: evaluate[E]
JUMPIF(1) g

41. Constants and Variables
We have not yet discussed generation of LetCommand. This is the place in MiniTriangle where declarations are.
Calculated during generation for
elaborate[D]
execute [let D in C] =
elaborate[D]
execute [C]
POP(0) s if s>0 where s = amount of storage allocated by D
How to know these?
fetch [V] =
LOAD d[SB] where d = address of V relative to SB
assign [V] =
STORE d[SB] where d = address of V relative to SB

42. Constants and Variables
Example
Accessing known values and known addresses
let
const b ~ 10;
var i:Integer; in
i := i*b
PUSH 1
LOAD 4[SB]
LOADL 10
CALL mult
STORE 4[SB]
elaborate[const … ; var …]
execute [i:=i*b]

43. Constants and Variables
Example
Accessing an unknown value.
Not all constants have values known (at compile time).
let
var x:Integer; in
let const y ~ x
in putint(y)
Depends on variable x: value not known at compile time.
When visiting declarations the code generator must decide whether
to represent constants in memory or as a literal value
=> We have to remember the address or the value somehow.

44. Constants and Variables
Example
Accessing an unknown value.
let
var x:Integer; in
let const y ~ x
in putint(y)
PUSH 1
LOADL 365
LOAD 4[SB]
CALL add
STORE 5[SB]
LOAD 5[SB]
CALL putint
elaborate[var x:Integer]
elaborate[const y ~ x]
execute [putint(y)]

45. Constants and Variables
Entity descriptions:
When the code generator visits a declaration:
1) it decides whether to represent it as a known value or a known address
2) if its an address then
emit code to reserve space.
3) make an entity description: an object that describes the
variable or constant: its value or address, its size.
4) put a link in the AST that points to the entity description
Example and picture on next slide

46. Constants and Variables
let const b ~ 10; var i:Integer;
in i := i*b
RECAP: Applied occurrences of Identifiers point to their declaration
LetCommand
SequentialDeclaration
ConstDecl
VarDecl
Ident
Int.Exp
Ident
Ident
Ident
Ident b 10 i i i b
known value
size = 1
value = 10
known address
address = 4
size = 1

47. Constants and Variables
let var x:Integer;
in let const y ~ x
in putint(y)
LetCommand
Note: There are also unknown
addresses. More about these
later.
VarDecl
Ident x
ConstDecl
Ident y
Q: When do unknown addresses occur?
known address
address = 4
size = 1
unknown value
address = 5
size = 1

48. Values and Addresses
Known value: this describes a value bound in a constant declaration whose right side is a literal
Unknown value: this describes a value bound in a constant declaration whose right side must be evaluated at run-time, or an argument value bound to a constant parameter
Known address: this describes an address allocated and bound in a variable declaration
Unknown address: this describes an argument address bound to a variable parameter
Entity descriptions are used in all these cases; for unknown entities, the addresses are known at run-time, and the code generated will fetch unknown entities at run-time

49. Static Storage Allocation
Example 1: Global variables
Tam Address:
a 0[SB]
b 1[SB]
c 2[SB]
d 3[SB]
let var a: Integer;
var b: Boolean;
var c: Integer;
var d: Integer;
in ...
Note: In this example all globals have the same size: 1. This is not always the case.

50. Static Storage Allocation
Example 2: Static allocation with nested blocks: overlays
Tam Address:
a 0[SB]
b 1[SB]
c 2[SB]
d 1[SB]
let var a: Integer;
in begin
...
let var b: Boolean;
var c: Integer;
in begin ... end;
let var d: Integer;
end
Same address!
Q: Why can b and d share the same address?

51. Static Storage Allocation: In the Code Generator
Entity Descriptions:
public abstract class RuntimeEntity {
public short size;
... }
public class KnownValue extends RuntimeEntity {
public short value;
public class UnknownValue extends RuntimeEntity {
public short address;
public class KnownAddress extends RuntimeEntity {

52. Static Storage Allocation: In the Code Generator
Entity Descriptions:
public abstract class AST {
public RuntimeEntity entity; // mostly used for Decls
... }
Each nonterminal node of the AST has an entity field.
Note: This is an addition to the AST class and requires recompilation of a lot of code if added late in the compiler implementation, but there seems to be no way around it!

53. Static Storage Allocation: In the Code Generator
public Object visit...Command(
...Command com, Object arg) {
short gs = shortValueOf(arg);
generate code as specified by execute[com]
return null; }
public Object visit...Expression(
...Expression expr, Object arg) {
generate code as specified by evaluate[com]
return new Short(size of expr result);
public Object visit...Declaration(
...Declaration dec, Object arg) {
return new Short(amount of extra allocated by dec);

54. Static Storage Allocation: In the Code Generator
The visitor is started …
public void encode(Program prog) {
prog.visit(this, new Short(0)); }
Amount of global storage already allocated. Initially = 0

55. Static Storage Allocation: In the Code Generator
Some concrete examples of visit methods
elaborate [var I : T] =
PUSH s where s = size of T
public Object visitVarDeclaration(
VarDeclaration decl, Object arg) {
short gs = shortValueOf(arg);
short s = shortValueOf(decl.T.visit(this, null));
decl.entity = new KnownAddress(s, gs);
emit(Instruction.PUSHop, 0, 0, s);
return new Short(s); }
Remember the address/size of the variable

56. Static Storage Allocation: In the Code Generator
elaborate [D1 ; D2] =
elaborate [D1]
elaborate [D2]
public Object visitSequentialDeclaration(
SequentialDeclaration decl, Object arg) {
short gs = shortValueOf(arg);
short s1 = shortValueOf(decl.D1.visit(this,arg));
short s2 = shortValueOf(decl.D2.visit(this,
new Short(gs+s1)));
return new Short(s1+s2); }

57. Static Storage Allocation: In the Code Generator
execute [let D in C] =
elaborate[D]
execute [C]
POP(0) s if s>0 where s = amount of storage allocated by D
public Object visitLetCommand(
LetCommand com, Object arg) {
short gs = shortValueOf(arg);
short s = shortValueOf(com.D.visit(this,arg));
com.C.visit(this,new Short(gs+s));
if (s > 0) emit(Instruction.POPop,0,0,s)
return null; }

58. Static Storage Allocation: In the Code Generator
fetch [I] = special case if I is a known literal constant
LOADL v where v is the known value of I
fetch [V] =
LOAD d[SB] where d = address of V relative to SB
public void encodeFetch(Vname name, short s) {
RuntimeEntity ent = VName.I.decl.entity;
if (ent instanceof KnownValue) {
short v = ((KnownValue)ent).value;
emit(Instruction.LOADLop, 0, 0, v);
} else {
short d = (entity instanceof UnknownValue) ?
((UnknownValue)ent).address :
((KnownAddress)ent).address ;
emit(Instruction.LOADop, 0, Instruction.SBr, d); }

59. Stack Allocation, Procedures and Functions
Now we will consider:
1) how procedures and functions are compiled
2) how to modify code generator to compute addresses
when we use a stack allocation model (instead of static allocation)

60. RECAP: TAM Frame Layout Summary
Arguments for current procedure
they were put here by the caller.
arguments LB
dynamic link
static link
return address
Link data
local variables
and intermediate
results
Local data, grows and shrinks
during execution. ST

61. RECAP: Accessing Global & Local Variables
Example: Compute the addresses of the variables in this program
Var Size Address
let var a: array 3 of Integer;
var b: Boolean;
var c: Char;
proc Y() ~
let var d: Integer;
var e: ...
in ... ;
proc Z() ~
let var f: Integer;
in begin ...; Y(); ... end in
begin ...; Y(); ...; Z(); end
[0]SB
[3]SB
[4]SB a b c d e f 3 1 1 ?
[2]LB
[3]LB 1
[2]LB

62. RECAP: TAM addressing schemas overview
We now have a complete picture of the different kinds of addresses that are used for accessing variables and formal parameters stored on the stack.
Type of variable
Global
Local
Parameter
Non-local, 1 level up
Non-local, 2 levels up
...
Load instruction
LOAD +offset[SB]
LOAD +offset[LB]
LOAD -offset[LB]
LOAD +offset[L1]
LOAD +offset[L2]

63. How To Characterize Addresses now?
When we have a static allocation model only, an address can be characterized by a single positive integer (i.e. the offset from SB)
Now we generalize this to stack allocation (for nested procedures)
Q: How do we characterize an address for a variable/constant now?
A: We need two numbers.
- nesting level
- offset (similar to static allocation)
Q: How do we compute the addresses to use in an instruction that loads or stores a value from/to a variable?

64. How To Characterize Addresses
Example: Compute the addresses of the variables in this program
Var Size Addr Accessing
let var a: array 3 of Integer;
var b: Boolean;
proc foo() ~
let var d: Integer;
var e: ...
proc bar() ~
let var f: Integer;
in ...bar body...
in ...foo body... ;
in ... global code ... a b d e f 3 1
(0,0)
(0,3)
(1,0)
(1,1)
(3,0)
0[SB]
3[SB] ?
How to access depends on … where are you accessing from! 1 ? 1
0[LB]
accessing e from foo body =>
accessing e from bar body =>
1[LB]
1[L1]

65. New Fetch / Assign Code Templates
fetch [I] =
LOADL(s) d[r]
s = Size of the type of I
d from address of I is (d, l)
r determined by l and cl (current level)
How to determine r
l = 0 ==> r = SB
l = cl ==> r = LB
otherwise ==> r = L(cl-l)

66. How To Modify The Code Generator
An info structure to pass as argument in the visitor (instead of “gs”)
public class Frame {
public byte level;
public short size; }
Before it was sufficient to pass the current size (gs) of the global frame since without procedures all storage is allocated at level 0. With subprograms we need to know the current level and the size of the frame.

67. How To Modify The Code Generator
Different kind of “address” in entity descriptors
public class EntityAddress {
public byte level;
public short displacement; }
public class UnknownValue extends RuntimeEntity {
public EntityAddress address;
... }
public class KnownAddress extends RuntimeEntity {

68. How To Modify The Code Generator
Changes to code generator (visitor)
Example:
public Object visitVarDeclaration(
VarDeclaration decl, Object arg) {
Frame frame = (Frame)arg;
short s = shortValueOf(decl.T.visit(this,null));
decl.entity = new KnownAddress(s,frame);
emit(Instruction.PUSHop, 0, 0, s);
return new Short(s); }
etc.
Q: When will the level of a frame be changed?
Q: When will the size be changed?

69. Change of frame level and size
In the visitor/encoding method for translating a procedure body, the frame level must be incremented by one and the frame size set to 3 (space for link data)
Frame outerFrame …
Frame localFrame = new Frame(outerFrame.level +1, 3);
The encoder starts at frame level 0 and with no storage allocated:
public void encoder(Program prog) {
Frame globalFrame = new Frame(0,0);
prog.visit(this, globalFrame); }

70. Procedures and Functions
We extend Mini Triangle with procedures:
Declaration
::= ...
| proc Identifier ( ) ~ Command
Command
| Identifier ( )
First , we will only consider global procedures (with no arguments).

71. Code Template: Global Procedure
elaborate [proc I () ~ C] =
JUMP g
e: execute [C]
RETURN(0) 0 g: C
execute [I ()] =
CALL(SB) e

72. Code Template: Global Procedure
Example:
let var n: Integer;
proc double() ~ n := n*2
in begin n := 9; double() end
0: PUSH 1
1: JUMP 7
2: LOAD 0[SB]
3: LOADL 2
4: CALL mult
5: STORE 0[SB]
6: RETURN(0) 0
7: LOADL 9
8: STORE 0[SB]
9: CALL(SB) 2
10:POP(0) 1
11:HALT
var n: Integer
proc double() ~
n := n*2
n := n*2
n := 9
double()

73. Procedures and Functions
We extend Mini Triangle with functions:
Declaration
::= ...
| func Identifier ( ) : TypeDenoter ~
Expression
| Identifier ( )
First , we will only consider global functions (with no arguments).
This is all pretty much the same as procedures (except for the
RETURN)

74. Code Template: Global Function
elaborate [func I () : T ~ E] =
JUMP g
e: evaluate [E]
RETURN(s) 0 g: C
where s is the size of T
evaluate [I ()] =
CALL(SB) e

75. Nested Procedures and Functions
Again, this is all pretty much the same except for static links.
When calling a (nested) procedure we must tell the CALL where to find the static link.
Revised code template:
execute [I ()] =
CALL(r) e
e from address of I is (d, l)
r determined by l and cl (current level)
evaluate [I ()] =
CALL(r) e

76. Procedures and Functions: Parameters
We extend Mini Triangle with ...
Declaration
::= ...
| proc Identifier (Formal) : TypeDenoter ~
Expression
| Identifier (Actual)
Formal
::= Identifier : TypeDenoter
| var Identifier : TypeDenoter
Actual
::= Expression
| var VName

77. Procedures and Functions: Parameters
Parameters are pushed right before calling a proc/func.
They are addressed like locals, but with negative offsets (in TAM).
let proc double(var n:Integer)
~ n := n*2
in ...
arguments
UnknownAddress LB
dynamic link
static link
return addres
address = (1,-1)
local variables
and intermediate
results ST

78. Code Templates Parameters
elaborate [proc I(FP) ~ C] =
JUMP g
e: execute [C]
RETURN(0) d g:
where d is the size of FP
execute [I (AP)] =
passArgument [AP]
CALL(r) e
passArgument [E] =
evaluate [E]
passArgument [var V] =
fetchAddress [V]
Where (l,e) = address of routine bound to I,
Cl = current routine level
R = display-register(cl,l)

79. Code Templates Parameters
An “UnknownAddress” extra case for fetch and assign
fetch [V] = if V bound to unknown address
LOAD d[r] where (d,l) = address where the
LOADI(s) unknown address will be stored at runtime.
s is the size of the type of V
assign [V] =
LOAD d[r]
STOREI(s) where d = address where the unknown
address will be stored a runtime.

80. Runtime Entities Overview
Known
Unknown
const lucky ~ 888
const foo ~ x + 10
Value
Address
Routine
value: 888
address: (level,offset)
the address where value will
be stored
var counter : Integer
A var parameter
address: (level,offset) of the address where the pointer will be stored.
address: (level,offset) of the variable.
proc double() ~ ...
A procedure or function parameter.
address: (level,offset)
address where closure object will be stored.
address: (level,offset) of
the routine (label e in
template)

81. Code generation summary
Create code templates inductively
There may be special case templates generating equivalent, but more efficient code
Use visitors pattern to walk the AST recursively emitting code as you go along
Back patching is needed for forward jumps
It is necessary to keep track of frame level and allocated space
That’s it folks!
At least for MiniTriangle on TAM