source: liacs/coco/assignment4/DOCUMENTATION.txt@ 44

= INTRODUCTION =

Welcome reader,

You will find our solution on assignment 4 of Compiler Constructions 2008
given at LIACS University. First we will give you a grand overview of the files
altered, next we will bullet point the most important design decisions. After that
an example is shown.

And the grand finale will show the usage of the program.

Enjoy!
Johan and Rick <hvdzwet@liacs.nl>

= FILES EDITED/ADDED =
A globals.h            = Some global definitions
A MOperand.cc          = Represents a operand for a MIPS statement
A MOperator.cc         = Represents a MIPS operator/opcode
A MStatement.cc        = Represents MIPS statements
E StackFrameManager.cc = Manages the stack frame
A RegisterManager.cc
E CodeGenerator.cc
E main.cc              = Main program function, argument parsing

= DESIGN DECISIONS =
*  Added a register manager to keep track of what symbols are associated with what
   registers. The register manager also loads the register if it's new and writes
   it back to memory.

* The current implementation for spilling a register is to select a random one. Also
  all registers are written back before a function call, before the end of a
  function and before jumps and branches. This can be optimized in the next assignment.

* We prefix all the symbol names with "__" to prevent name clashes with MIPS
  assembly instructions.

* Register $V0 is used for integer function return values and $f0 for real
  return values.

* Register $V1 is used for expressions

* Registers $A0, $A1, $A2 and $A3 do not have to be gotten through the RegisterManager
  and can thus be used as temporaries inside a known code block while generating code.

* The stack pointer $sp points to the last used word on the stack. We generate code
  that assumes it's pointing to the first free word. Therefore the stack is increased
  by one word in main before calling the program body.

* The stack frame layout is as follows:
        ^                ^
        |                |
  $fp + 8         second parameter
  $fp + 4         first parameter
  $fp + 0         return address
  $fp - 4         previous frame pointer
  $fp - 8         return value
  $fp - 12        first local variable
  $fp - 16        second local variable
        |                |
        v                v

* We created a framework for Assembly code, model-ed after the intermediate code
  framework. This was done to separate the generation of the output file from
  generation of the code. It can also later be used to implement further
  optimizations on the MIPS assembly code.

= SAMPLE GENERATED CODE =
C01) program example;
C02)
C03) var x, y, z: integer;
C04) function foo(a,b: integer): integer;
C05) begin
C06)   foo := 1
C07) end;
C08)
C09) begin
C10)     x := readinteger;
C11)     y := 20;
C12)     z := x + 20;
C13)     z := z + foo(0,0)
C14) end.

     1  ## Output generated by ./comp @ kubuntu-desktop
     2  ## Thu Nov 20 14:30:48 2008
     3
     4  ## Compiler Construction Course - Leiden University - LIACS
     5  ## Johan IJsveld - Rick van der Zwet
     6  ## BSD Licenced
     7
     8          .data           # Global data section
     9          .align  4
    10  __x:
    11          .word   0
    12  __y:
    13          .word   0
    14  __z:
    15          .word   0
    16
    17          .text           # Code section
    18          .align  4
    19          .globl  main
    20
    21          .ent    main
    22  main:
    23          addi    $sp, $sp, -4
    24          jal     __example               # Jump to program body
    25          addi    $sp, $sp, 4
    26          addi    $v0, $0, 10             # Exit system call
    27          syscall
    28          .end    main
    29
    30          .ent    __example
    31  __example:
    32          sw      $ra, 0($sp)             # Set up stack frame
    33          sw      $fp, -4($sp)
    34          move    $fp, $sp
    35          addi    $sp, $sp, -28
    36          jal     __readinteger
    37          lw      $t0, -12($fp)           # Load integer Register
    38          move    $t0, $v0                # Store integer function result
    39          lw      $t1, __x                # Load integer Register
    40          move    $t1, $t0                # Assign integer
    41          lw      $t2, __y                # Load integer Register
    42          addi    $t2, $0, 20             # Assign constant integer
    43          lw      $t3, -16($fp)           # Load integer Register
    44          addi    $a0, $0, 20
    45          add     $t3, $t1, $a0           # Add integers
    46          lw      $t4, __z                # Load integer Register
    47          move    $t4, $t3                # Assign integer
    48          addi    $v1, $0, 0              # Push constant integer parameter
    49          sw      $v1, 0($sp)
    50          addi    $sp, $sp, -4
    51          addi    $v1, $0, 0              # Push constant integer parameter
    52          sw      $v1, 0($sp)
    53          addi    $sp, $sp, -4
    54          sw      $t0, -12($fp)           # Write back integer register
    55          sw      $t1, __x                # Write back integer register
    56          sw      $t2, __y                # Write back integer register
    57          sw      $t3, -16($fp)           # Write back integer register
    58          sw      $t4, __z                # Write back integer register
    59          jal     __foo
    60          lw      $t0, -20($fp)           # Load integer Register
    61          move    $t0, $v0                # Store integer function result
    62          lw      $t1, -24($fp)           # Load integer Register
    63          lw      $t2, __z                # Load integer Register
    64          add     $t1, $t2, $t0           # Add integers
    65          move    $t2, $t1                # Assign integer
    66          sw      $t0, -20($fp)           # Write back integer register
    67          sw      $t1, -24($fp)           # Write back integer register
    68          sw      $t2, __z                # Write back integer register
    69          lw      $ra, 0($fp)             # Return from call
    70          lw      $fp, -4($fp)
    71          addi    $sp, $sp, 28
    72          jr      $ra
    73          .end    __example
    74
    75          .ent    __foo
    76  __foo:
    77          sw      $ra, 0($sp)             # Set up stack frame
    78          sw      $fp, -4($sp)
    79          move    $fp, $sp
    80          addi    $sp, $sp, -12
    81          lw      $t0, -8($fp)            # Load integer Register
    82          addi    $t0, $0, 1              # Assign constant integer
    83          sw      $t0, -8($fp)            # Write back integer register
    84          lw      $t0, -8($fp)            # Load integer Register
    85          move    $v0, $t0                # Store integer return value
    86          lw      $ra, 0($fp)             # Return from call
    87          lw      $fp, -4($fp)
    88          addi    $sp, $sp, 20
    89          jr      $ra
    90          .end    __foo
    91
    92          .ent    __readinteger           # Start of builtin functions and procedures
    93  __readinteger:
    94          addi    $v0, $0, 5
    95          syscall
    96          jr      $ra
    97          .end    __readinteger
    98
    99          .ent    __writeinteger
   100  __writeinteger:
   101          lw      $a0, 4($sp)
   102          addi    $v0, $0, 1
   103          syscall
   104          addi    $sp, $sp, 4
   105          jr      $ra
   106          .end    __writeinteger
   107
   108          .ent    __readreal
   109  __readreal:
   110          addi    $v0, $0, 6
   111          syscall
   112          jr      $ra
   113          .end    __readreal
   114
   115          .ent    __writereal
   116  __writereal:
   117          l.s     $f12, 4($sp)
   118          addi    $v0, $0, 2
   119          syscall
   120          addi    $sp, $sp, 4
   121          jr      $ra
   122          .end    __writereal
   123

Lines 8 through 16 shows the space for globals being reserved.
Lines 21 through 28 is the main function calling the program body and doing a syscall to exit.
Lines 30 through 73 is the program body code.
Lines 75 through 90 is the function foo, where on lines 77 through 80 the stack
frame is set up. In lines 81 through 85 the return value 1 is stored on the stack
and then put in the return register $v0.
On line 86 and line 87, $ra and the old $fp are restored. The stack is shrunk back again,
including parameters, on line 88 and on line 89 is the jump back from where the call was made.
After line 92 are the builtin functions.

= USAGE =
# Compile
$ make first
$ make
# Call without optimalisation
$ ./comp -w -00 <testfile
# Call with optimalisation
$ ./comp -w -01 <testfile
The resultant MIPS assembly is stored in the file "out.s".