source: liacs/coco/assignment4/CodeGenerator.cc@ 166

/*
 * CodeGenerator.cc - Implementation of the CodeGenerator class
 *
 * Part of the assignment of the Compiler Construction course
 * LIACS, Leiden University
 */

#include "IStatement.h"
#include "AssemblerCode.h"
#include "MStatement.h"


#include "CodeGenerator.h"
#include "globals.h"
#include <time.h>
#include <unistd.h>
#include <cassert>

using namespace std;

bool IsGlobal(Symbol * sym); // Is the specified symbol a global variable?

#define SP_ALTER(offset) fprintf(out, "\taddi\t$sp, $sp, %d\n", offset)
#define OP1_NAME_C_STR(stmt) stmt->GetOperand1()->GetSymbol()->GetName().c_str()
#define OP1_NAME_STR(stmt) string(SYMBOL_PREFIX) + stmt->GetOperand1()->GetSymbol()->GetName()
#define OP2_NAME_C_STR(stmt) stmt->GetOperand2()->GetSymbol()->GetName().c_str()
#define RESULT_NAME_C_STR(stmt) stmt->GetResult()->GetSymbol()->GetName().c_str()


// Constructor

CodeGenerator::CodeGenerator()
: mCode(), currentFrame(mCode), rManager(currentFrame, mCode) {
}


// Destructor

CodeGenerator::~CodeGenerator() {
}


// Generates a header

void CodeGenerator::GenerateHeader(FILE * out) {
  time_t rawtime;
  struct tm * timeinfo;

  time(&rawtime);
  timeinfo = localtime(&rawtime);
  char hostname[20];
  gethostname(hostname, 20);

  fprintf(out, "## Output generated by ./comp @ %s\n", hostname);
  fprintf(out, "## %s\n", asctime(timeinfo));
  fprintf(out, "## Compiler Construction Course - Leiden University - LIACS\n");
  fprintf(out, "## Johan IJsveld - Rick van der Zwet\n");
  fprintf(out, "## BSD Licenced\n");

}


// Generates the declarations for the global variables

void CodeGenerator::GenerateGlobalDecls(FILE *, SymbolTable * symtab) {
  Scope * globalScope;
  Symbol * sym;

  mCode.AppendStatement(new MStatement(MOP_DATA, "Global data section"));
  mCode.AppendStatement(new MStatement(MOP_ALIGN, new MOperand(MT_INT, 4)));

  globalScope = symtab->GetRootScope();

  // Here we iterate over all global variables in the symbol table and
  // generate a declaration.
  for (unsigned int i = 0; i < globalScope->GetNumberOfSymbols(); i++) {
    sym = globalScope->GetSymbol(i);
    if (IsGlobal(sym)) {
      MStatement *stmt = new MStatement(MOP_LABEL);
      stmt->SetLabel(string(SYMBOL_PREFIX) + sym->GetName());
      mCode.AppendStatement(stmt);
      if (sym->GetReturnType() == RT_INT) {
        mCode.AppendStatement(new MStatement(MOP_WORD, new MOperand(MT_INT, 0)));
      } else {
        mCode.AppendStatement(new MStatement(MOP_FLOAT, new MOperand(MT_REAL, 0.0f)));
      }
    }
  }

}


// Takes an IntermediateCode object and emits MIPS assembly instructions

void CodeGenerator::GenerateCode(FILE *out, SymbolTable * symtab, IntermediateCode * inputCode) {
  IStatement * stmt;

  // Generate a general 'stub'.
  mCode.AppendStatement(new MStatement(MOP_TEXT, "Code section"));
  mCode.AppendStatement(new MStatement(MOP_ALIGN, new MOperand(MT_INT, 4)));
  mCode.AppendStatement(new MStatement(MOP_GLOBL, new MOperand(MT_LABEL, "main")));
  mCode.AppendStatement(new MStatement(MOP_ENT, new MOperand(MT_LABEL, "main")));
  MStatement *mstmt = new MStatement(MOP_LABEL);
  mstmt->SetLabel("main");
  mCode.AppendStatement(mstmt);
  mCode.AppendStatement(StackPointerChange(-4));
  mCode.AppendStatement(new MStatement(MOP_JAL, new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + inputCode->GetProgramName()), "Jump to program body"));
  mCode.AppendStatement(StackPointerChange(4));
  mCode.AppendStatement(new MStatement(MOP_ADDI, new MOperand(MT_REGISTER, R_V0), new MOperand(MT_REGISTER, R_ZERO), new MOperand(MT_INT, 10), "Exit system call"));
  mCode.AppendStatement(new MStatement(MOP_SYSCALL));
  mCode.AppendStatement(new MStatement(MOP_END, new MOperand(MT_LABEL, "main")));

  // Here we step through the intermediate code and output assembly instructions
  for (unsigned int i = 0; i < inputCode->GetStatementCount(); i++) {
    stmt = inputCode->GetStatement(i);

    switch (stmt->GetOperator()) {
        /* Subprogram entry
           operand1  should refer to the corresponding Symbol_Subprogram object */
      case IOP_SUBPROG: // [1--] Subprogram
      {
        // The start of a subprogram: analyze it, and generate the prologue.
        currentFrame.AnalyzeSubprogram(symtab, stmt->GetOperand1()->GetSymbol());
        currentFrame.GeneratePrologue(out);
        break;
      }
        /* Subprogram return
           operand1  should contain the value that has to be returned */
      case IOP_RETURN: // [---] Procedure return
      {
        // The end of a subprogram:
        // write back all registers
        rManager.SpillAll();

        // generate the epilogue
        currentFrame.GenerateEpilogue(out);
        break;
      }
      case IOP_RETURN_I: // [1--] Integer function return
      {
        // The end of a subprogram:
        // write back all registers
        rManager.SpillAll();

        // put result in $v0
        if (stmt->GetOperand1()->GetOperandType() == OT_INT) {
          mCode.AppendStatement(new MStatement(MOP_ADDI,
                  new MOperand(MT_REGISTER, R_V0),
                  new MOperand(MT_REGISTER, R_ZERO),
                  new MOperand(MT_INT, stmt->GetOperand1()->GetIntValue()),
                  "Store constant integer return value"));
        } else {
          MRegisterType result_reg = rManager.GetIntRegister(stmt->GetOperand1()->GetSymbol());
          mCode.AppendStatement(new MStatement(MOP_MOVE,
                  new MOperand(MT_REGISTER, R_V0),
                  new MOperand(MT_REGISTER, result_reg),
                  "Store integer return value"));
        }

        // generate the epilogue
        currentFrame.GenerateEpilogue(out);
        break;
      }
      case IOP_RETURN_R: // [1--] Real function return
      {
        // The end of a subprogram:
        // write back all registers
        rManager.SpillAll();

        // put result in $f0
        if (stmt->GetOperand1()->GetOperandType() == OT_REAL) {
          mCode.AppendStatement(new MStatement(MOP_LI_S,
                  new MOperand(MT_REGISTER, R_F0),
                  new MOperand(MT_REAL, stmt->GetOperand1()->GetRealValue()),
                  "Store constant real return value"));
        } else if (stmt->GetOperand1()->GetOperandType() == OT_REAL) {
          // XXX: is this needed?
          mCode.AppendStatement(new MStatement(MOP_LI_S,
                  new MOperand(MT_REGISTER, R_F0),
                  new MOperand(MT_INT, stmt->GetOperand1()->GetRealValue()),
                  "Store real (casted from int) return value"));
        } else {
          MRegisterType result_reg = rManager.GetFloatRegister(stmt->GetOperand1()->GetSymbol());
          mCode.AppendStatement(new MStatement(MOP_MOV_S,
                  new MOperand(MT_REGISTER, R_F0),
                  new MOperand(MT_REGISTER, result_reg),
                  "Store real return value"));
        }

        // generate the epilogue
        currentFrame.GenerateEpilogue(out);
        break;
      }
        /* Meta */
      case IOP_UNKNOWN: // [---] (yet) Unknown operation
      {
        assert(0); // can't happen
        break;
      }
        /* Parameter passing (caller side)
           operand1  actual parameter value or Symbol object */
      case IOP_PARAM_I: // [1--] Integer parameter
      {
        if (stmt->GetOperand1()->GetOperandType() == OT_INT) {
          mCode.AppendStatement(new MStatement(MOP_ADDI,
                  new MOperand(MT_REGISTER, R_V1),
                  new MOperand(MT_REGISTER, R_ZERO),
                  new MOperand(MT_INT, stmt->GetOperand1()->GetIntValue()),
                  "Push constant integer parameter"));

        } else {
          // find/associate operand symbol to a register
          MRegisterType operand_reg = rManager.GetIntRegister(stmt->GetOperand1()->GetSymbol());
          mCode.AppendStatement(new MStatement(MOP_MOVE,
                  new MOperand(MT_REGISTER, R_V1),
                  new MOperand(MT_REGISTER, operand_reg),
                  "Push integer parameter"));
        }

        mCode.AppendStatement(new MStatement(MOP_SW,
                new MOperand(MT_REGISTER, R_V1),
                new MOperand(MT_OFFSET, R_SP, 0)));

        mCode.AppendStatement(StackPointerChange(-4));
        break;
      }
      case IOP_PARAM_R: // [1--] Real parameter
      {
        if (stmt->GetOperand1()->GetOperandType() == OT_REAL) {
          mCode.AppendStatement(new MStatement(MOP_LI_S,
                  new MOperand(MT_REGISTER, R_F0),
                  new MOperand(MT_REAL, stmt->GetOperand1()->GetRealValue()),
                  "Push constant real parameter"));

        } else {
          // find/associate operand symbol to a register
          MRegisterType operand_reg = rManager.GetFloatRegister(stmt->GetOperand1()->GetSymbol());
          mCode.AppendStatement(new MStatement(MOP_MOV_S,
                  new MOperand(MT_REGISTER, R_F0),
                  new MOperand(MT_REGISTER, operand_reg),
                  "Push real parameter"));
        }

        mCode.AppendStatement(new MStatement(MOP_S_S,
                new MOperand(MT_REGISTER, R_F0),
                new MOperand(MT_OFFSET, R_SP, 0)));

        mCode.AppendStatement(StackPointerChange(-4));
        break;
      }

        /* Subprogram call
           operand1  should refer to the corresponding Symbol object
           result    receives the result of a function call */
      case IOP_PROCCALL: // [1--] Procedure call
      {
        /* making a procedure call so write back all registers */
        rManager.SpillAll();
        /* make procedure call */
        mCode.AppendStatement(new MStatement(MOP_JAL,
                new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + OP1_NAME_C_STR(stmt))));
        break;
      }
      case IOP_FUNCCALL: // [1-r] Function call
      {
        /* making a function call so write back all registers */
        rManager.SpillAll();

        /* Function call requires a call and then storage of returned data */
        mCode.AppendStatement(new MStatement(MOP_JAL,
                new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + OP1_NAME_C_STR(stmt))));

        /* find/associate a register and put the result in there */
        Symbol *result_symbol = stmt->GetResult()->GetSymbol();
        if (result_symbol->GetReturnType() == RT_INT) {
          MRegisterType result_reg = rManager.GetIntRegister(result_symbol);
          mCode.AppendStatement(new MStatement(MOP_MOVE,
                  new MOperand(MT_REGISTER, result_reg),
                  new MOperand(MT_REGISTER, R_V0),
                  "Store integer function result"));
        } else {
          MRegisterType result_reg = rManager.GetFloatRegister(result_symbol);
          mCode.AppendStatement(new MStatement(MOP_MOV_S,
                  new MOperand(MT_REGISTER, result_reg),
                  new MOperand(MT_REGISTER, R_F0),
                  "Store real function result"));
        }
        break;
      }
        /* Label
           operand1  should refer to the corresponding Symbol object */
      case IOP_LABEL: // [1--] Label
      {
        MStatement *mstmt = new MStatement(MOP_LABEL);
        mstmt->SetLabel(OP1_NAME_C_STR(stmt));
        mCode.AppendStatement(mstmt);
        break;
      }
        /* Goto
           operand1  should refer to the corresponding Symbol object; note that
                     the Symbol pointed to should be of type ST_LABEL */
      case IOP_GOTO: // [1--] Goto a label
      {
        /* changing control flow so write back all registers */
        rManager.SpillAll();

        mCode.AppendStatement(new MStatement(MOP_J, new MOperand(MT_LABEL, OP1_NAME_C_STR(stmt))));
        break;
      }
        /* Variable assignment (copy value)
           operand1  the source operand
           result    the destination operand (pointer to a Symbol object) */
      case IOP_ASSIGN_I: // [1-r] Integer assignment
      {
        // find/associate result symbol to a register
        MRegisterType result_reg = rManager.GetIntRegister(stmt->GetResult()->GetSymbol());

        if (stmt->GetOperand1()->GetOperandType() == OT_INT) {
          mCode.AppendStatement(new MStatement(MOP_ADDI,
                  new MOperand(MT_REGISTER, result_reg),
                  new MOperand(MT_REGISTER, R_ZERO),
                  new MOperand(MT_INT, stmt->GetOperand1()->GetIntValue()),
                  "Assign constant integer"));
        } else {
          // find/associate operand symbol to a register
          MRegisterType operand_reg = rManager.GetIntRegister(stmt->GetOperand1()->GetSymbol());
          mCode.AppendStatement(new MStatement(MOP_MOVE,
                  new MOperand(MT_REGISTER, result_reg),
                  new MOperand(MT_REGISTER, operand_reg),
                  "Assign integer"));
        }
        break;
      }
      case IOP_ASSIGN_R: // [1-r] Real assignment
      {
        // find/associate result symbol to a register
        MRegisterType result_reg = rManager.GetFloatRegister(stmt->GetResult()->GetSymbol());

        if (stmt->GetOperand1()->GetOperandType() == OT_REAL) {
          mCode.AppendStatement(new MStatement(MOP_LI_S,
                  new MOperand(MT_REGISTER, result_reg),
                  new MOperand(MT_REAL, stmt->GetOperand1()->GetRealValue()),
                  "Assign constant real"));
        } else {
          // find/associate operand symbol to a register
          MRegisterType operand_reg = rManager.GetFloatRegister(stmt->GetOperand1()->GetSymbol());
          mCode.AppendStatement(new MStatement(MOP_MOV_S,
                  new MOperand(MT_REGISTER, result_reg),
                  new MOperand(MT_REGISTER, operand_reg),
                  "Assign real"));
        }
        break;

      }
        /* Branching
          operand1  the first source operand
          operand2  the second source operand
          result    should refer to the target Symbol object; note that
                    the Symbol pointed to must be of type ST_LABEL */
      case IOP_BEQ_I: // [12r] = operator for integers
      {
        mCode.AppendStatement(BranchInstruction(MOP_BEQ, stmt));
        break;
      }
      case IOP_BLT_I: // [12r] < operator for integers
      {
        mCode.AppendStatement(BranchInstruction(MOP_BLT, stmt));
        break;
      }
      case IOP_BGT_I: // [12r] > operator for integers
      {
        mCode.AppendStatement(BranchInstruction(MOP_BGT, stmt));
        break;
      }
      case IOP_BLE_I: // [12r] <= operator for integers
      {
        mCode.AppendStatement(BranchInstruction(MOP_BLE, stmt));
        break;
      }
      case IOP_BGE_I: // [12r] >= operator for integers
      {
        mCode.AppendStatement(BranchInstruction(MOP_BGE, stmt));
        break;
      }
      case IOP_BNE_I: // [12r] <> operator for integers
      {
        mCode.AppendStatement(BranchInstruction(MOP_BNE, stmt));
        break;
      }
      case IOP_BEQ_R: // [12r] = operator for reals
      {
        mCode.AppendStatement(BranchInstructionReal(MOP_C_EQ_S, stmt));
        mCode.AppendStatement(new MStatement(MOP_BCZT,
                new MOperand(MT_LABEL, RESULT_NAME_C_STR(stmt))));
        break;
      }
      case IOP_BLT_R: // [12r] < operator for reals
      {
        mCode.AppendStatement(BranchInstructionReal(MOP_C_LT_S, stmt));
        mCode.AppendStatement(new MStatement(MOP_BCZT,
                new MOperand(MT_LABEL, RESULT_NAME_C_STR(stmt))));
        break;
      }
      case IOP_BGT_R: // [12r] > operator for reals
      {
        /* Use reverse style not (<=) */
        mCode.AppendStatement(BranchInstructionReal(MOP_C_LT_S, stmt, true));
        mCode.AppendStatement(new MStatement(MOP_BCZT,
                new MOperand(MT_LABEL, RESULT_NAME_C_STR(stmt))));
        break;
      }
      case IOP_BLE_R: // [12r] <= operator for reals
      {
        mCode.AppendStatement(BranchInstructionReal(MOP_C_LE_S, stmt));
        mCode.AppendStatement(new MStatement(MOP_BCZT,
                new MOperand(MT_LABEL, RESULT_NAME_C_STR(stmt))));
        break;
      }
      case IOP_BGE_R: // [12r] >= operator for reals
      {
        mCode.AppendStatement(BranchInstructionReal(MOP_C_LE_S, stmt, true));
        mCode.AppendStatement(new MStatement(MOP_BCZF,
                new MOperand(MT_LABEL, RESULT_NAME_C_STR(stmt))));
        break;
      }
      case IOP_BNE_R: // [12r] <> operator for reals
      {
        mCode.AppendStatement(BranchInstructionReal(MOP_C_EQ_S, stmt));
        mCode.AppendStatement(new MStatement(MOP_BCZF,
                new MOperand(MT_LABEL, RESULT_NAME_C_STR(stmt))));
        break;
      }

        /* Binary arithmetic operators
           operand1  the first source operand
           operand2  the second source operand
           result    the destination operand (refers to a Symbol object) */
      case IOP_ADD_I: // [12r] Integer addition
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_ADD, stmt, "Add integers"));
        break;
      }
      case IOP_ADD_R: // [12r] Real addition
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_ADD_S, stmt, "Add reals"));
        break;
      }
      case IOP_SUB_I: // [12r] Integer substraction
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_SUB, stmt, "Subtract integer"));
        break;
      }
      case IOP_SUB_R: // [12r] Real substraction
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_SUB_S, stmt, "Subtract reals"));
        break;
      }
      case IOP_MUL_I: // [12r] Integer multiplication
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_MUL, stmt, "Multiply integers"));
        break;
      }
      case IOP_MUL_R: // [12r] Real multiplication
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_MUL_S, stmt, "Multiply reals"));
        break;
      }
      case IOP_DIV_I: // [12r] Integer division
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_DIV, stmt, "Divide integers"));
        break;
      }
      case IOP_DIV_R: // [12r] Real division
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_DIV_S, stmt, "Divide reals"));
        break;
      }
      case IOP_MOD: // [12r] Modulo
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_REM, stmt, "Remainder"));
        break;
      }
      case IOP_AND: // [12r] AND operation
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_AND, stmt, "Bitwise and"));
        break;
      }
      case IOP_OR: // [12r] OR operation
      {
        mCode.AppendStatement(BinaryArithmetic(MOP_OR, stmt, "Bitwise or"));
        break;
      }

        /* Unary arithmetic operators
           operand1  the source operand
           result    the destination operand (refers to a Symbol object) */
      case IOP_NOT: // [1-r] NOT operation
      {
        mCode.AppendStatement(UnaryArithmetic(MOP_NOT, stmt, "Bitwise not"));
        break;
      }
      case IOP_UNARY_MINUS_I: // [1-r] Unary integer minus
      {
        mCode.AppendStatement(UnaryArithmetic(MOP_NEG, stmt, "Negate integer"));
        break;
      }
      case IOP_UNARY_MINUS_R: // [1-r] Unary real minus
      {
        mCode.AppendStatement(UnaryArithmetic(MOP_NEG_S, stmt, "Negate real"));
        break;
      }
        /* Coercion
           operand1  the source operand
           result    the destination operand (refers to a Symbol object) */
      case IOP_INT_TO_REAL: // [1-r] Int to Real coercion
      {
        MRegisterType dest_reg = rManager.GetFloatRegister(stmt->GetResult()->GetSymbol());
        if (stmt->GetOperand1()->GetOperandType() == OT_INT) {
          // just add constant
          float value = stmt->GetOperand1()->GetIntValue();
          mCode.AppendStatement(new MStatement(MOP_LI_S,
                  new MOperand(MT_REGISTER, dest_reg),
                  new MOperand(MT_REAL, value),
                  "Coerce constant from int to real"));
        } else {
          // load integer into register and load it into floating point register
          MRegisterType source_reg = rManager.GetIntRegister(stmt->GetOperand1()->GetSymbol());
          mCode.AppendStatement(new MStatement(MOP_MTC1,
                  new MOperand(MT_REGISTER, source_reg),
                  new MOperand(MT_REGISTER, dest_reg),
                  "Coerce from int to real"));
          // convert integer to float
          mCode.AppendStatement(new MStatement(MOP_CVT_S_W,
                  new MOperand(MT_REGISTER, dest_reg),
                  new MOperand(MT_REGISTER, dest_reg)));
        }
        break;
      }
      default:
        fprintf(stderr,
                "[CodeGenerator::GenerateCode()] Unhandled intermediate operator '%s'\n",
                IOperatorToString(stmt->GetOperator())
                );
    }
  }
}

MOperand * CodeGenerator::IOperand2MOperand(IOperand * opnd) {
  MOperand *retVal;
  MRegisterType freeRegister;
  switch (opnd->GetOperandType()) {
    case OT_SYMBOL:
    {
      MRegisterType tmpReg = rManager.GetRegister(opnd->GetSymbol());
      retVal = new MOperand(MT_REGISTER, tmpReg);
      break;
    }
    case OT_INT:
    {
      freeRegister = rManager.GetTempRegister();
      mCode.AppendStatement(new MStatement(MOP_ADDI,
              new MOperand(MT_REGISTER, freeRegister),
              new MOperand(MT_REGISTER, R_ZERO),
              new MOperand(MT_INT, opnd->GetIntValue())));

      retVal = new MOperand(MT_REGISTER, freeRegister);
      break;
    }
    case OT_REAL:
    {
      freeRegister = rManager.GetTempRegister();
      mCode.AppendStatement(new MStatement(MOP_LI_S,
              new MOperand(MT_REGISTER, freeRegister),
              new MOperand(MT_REAL, opnd->GetRealValue())));

      retVal = new MOperand(MT_REGISTER, freeRegister);
      break;
    }
    default:
      /* XXX: Should not happen */
      break;
  }
  return (retVal);
}

// Generates a trailer

/* Stack Pointer template */
MStatement * CodeGenerator::StackPointerChange(int offset,
        const char * comment) {
  MOperand *mop1 = new MOperand(MT_REGISTER, R_SP);
  MOperand *mop2 = new MOperand(MT_REGISTER, R_SP);
  MOperand *mop3 = new MOperand(MT_INT, offset);
  return (new MStatement(MOP_ADDI, mop1, mop2, mop3, comment));
}

/* Unary Artithmetic template */
MStatement * CodeGenerator::UnaryArithmetic(MOperator opcode, IStatement *stmt,
        const char * comment) {
  MOperand *mop1 = IOperand2MOperand(stmt->GetResult());
  MOperand *mop2 = IOperand2MOperand(stmt->GetOperand1());

  return (new MStatement(opcode, mop1, mop2, comment));
}

/* Binary Artithmetic template */
MStatement * CodeGenerator::BinaryArithmetic(MOperator opcode, IStatement *stmt,
        const char * comment) {
  MOperand *mop1 = IOperand2MOperand(stmt->GetResult());
  MOperand *mop2 = IOperand2MOperand(stmt->GetOperand1());
  MOperand *mop3 = IOperand2MOperand(stmt->GetOperand2());

  return (new MStatement(opcode, mop1, mop2, mop3, comment));

}

/* Branch Instruction with Int values template */
MStatement * CodeGenerator::BranchInstruction(MOperator opcode, IStatement *stmt,
        bool swap, const char * comment) {
  MOperand *mop1 = IOperand2MOperand(stmt->GetOperand1());
  MOperand *mop2 = IOperand2MOperand(stmt->GetOperand2());
  MOperand *mop3 = new MOperand(MT_LABEL, stmt->GetResult()->GetSymbol()->GetName());

  /* changing control flow so write back all registers */
  rManager.SpillAll();

  if (swap)
    return (new MStatement(opcode, mop1, mop2, mop3, comment));
  else
    return (new MStatement(opcode, mop2, mop1, mop3, comment));
}

/* Branch Instruction with Real values temlate */
MStatement * CodeGenerator::BranchInstructionReal(MOperator opcode, IStatement *stmt,
        bool swap, const char * comment) {
  MOperand *mop1 = IOperand2MOperand(stmt->GetOperand1());
  MOperand *mop2 = IOperand2MOperand(stmt->GetOperand2());
  if (swap)
    return (new MStatement(opcode, mop1, mop2, comment));
  else
    return (new MStatement(opcode, mop2, mop1, comment));
}

void CodeGenerator::Dump(FILE * out) {
  mCode.Dump(out);
  fprintf(out, "\n");
}

void CodeGenerator::GenerateTrailer(FILE *) {
  /* readinteger: syscall code 5, integer in $v0
   * General idea: init, set syscall value, call syscall, save value
   */
  {
    mCode.AppendStatement(new MStatement(MOP_ENT,
            new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + string("readinteger")),
            "Start of builtin functions and procedures"));

    MStatement *stmt = new MStatement(MOP_LABEL);
    stmt->SetLabel(string(SYMBOL_PREFIX) + string("readinteger"));
    mCode.AppendStatement(stmt);

    mCode.AppendStatement(new MStatement(MOP_ADDI,
            new MOperand(MT_REGISTER, R_V0),
            new MOperand(MT_REGISTER, R_ZERO),
            new MOperand(MT_INT, 5)));

    mCode.AppendStatement(new MStatement(MOP_SYSCALL));

    mCode.AppendStatement(new MStatement(MOP_JR,
            new MOperand(MT_REGISTER, R_RA)));

    mCode.AppendStatement(new MStatement(MOP_END,
            new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + string("readinteger"))));
  }

  /* writeinteger: syscall code 1, integer in $a0
   * General idea: init, set syscall value, ,set value, call syscall
   */
  {
    mCode.AppendStatement(new MStatement(MOP_ENT,
          new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + string("writeinteger"))));

    MStatement *stmt = new MStatement(MOP_LABEL);
    stmt->SetLabel(string(SYMBOL_PREFIX) + string("writeinteger"));
    mCode.AppendStatement(stmt);

    mCode.AppendStatement(new MStatement(MOP_LW,
            new MOperand(MT_REGISTER, R_A0),
            new MOperand(MT_OFFSET, R_SP, 4)));

    mCode.AppendStatement(new MStatement(MOP_ADDI,
            new MOperand(MT_REGISTER, R_V0),
            new MOperand(MT_REGISTER, R_ZERO),
            new MOperand(MT_INT, 1)));

    mCode.AppendStatement(new MStatement(MOP_SYSCALL));

    mCode.AppendStatement(StackPointerChange(4));

    mCode.AppendStatement(new MStatement(MOP_JR,
            new MOperand(MT_REGISTER, R_RA)));

    mCode.AppendStatement(new MStatement(MOP_END,
            new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + string("writeinteger"))));
  }

  /* readreal: syscall code 6, float in $f0
   * General idea: init, set syscall value, call syscall, save value
   */
  {
    mCode.AppendStatement(new MStatement(MOP_ENT,
            new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + string("readreal"))));

    MStatement *stmt = new MStatement(MOP_LABEL);
    stmt->SetLabel(string(SYMBOL_PREFIX) + string("readreal"));
    mCode.AppendStatement(stmt);

    mCode.AppendStatement(new MStatement(MOP_ADDI,
            new MOperand(MT_REGISTER, R_V0),
            new MOperand(MT_REGISTER, R_ZERO),
            new MOperand(MT_INT, 6)));

    mCode.AppendStatement(new MStatement(MOP_SYSCALL));

    mCode.AppendStatement(new MStatement(MOP_JR,
            new MOperand(MT_REGISTER, R_RA)));

    mCode.AppendStatement(new MStatement(MOP_END,
            new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + string("readreal"))));
  }

  /* writereal: syscall code 2, float in $f12
   * General idea: init, set syscall value, ,set value, call syscall
   */
  {
    mCode.AppendStatement(new MStatement(MOP_ENT,
          new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + string("writereal"))));

    MStatement *stmt = new MStatement(MOP_LABEL);
    stmt->SetLabel(string(SYMBOL_PREFIX) + string("writereal"));
    mCode.AppendStatement(stmt);

    mCode.AppendStatement(new MStatement(MOP_L_S,
            new MOperand(MT_REGISTER, R_F12),
            new MOperand(MT_OFFSET, R_SP, 4)));

    mCode.AppendStatement(new MStatement(MOP_ADDI,
            new MOperand(MT_REGISTER, R_V0),
            new MOperand(MT_REGISTER, R_ZERO),
            new MOperand(MT_INT, 2)));

    mCode.AppendStatement(new MStatement(MOP_SYSCALL));

    mCode.AppendStatement(StackPointerChange(4));

    mCode.AppendStatement(new MStatement(MOP_JR,
            new MOperand(MT_REGISTER, R_RA)));

    mCode.AppendStatement(new MStatement(MOP_END,
            new MOperand(MT_LABEL, string(SYMBOL_PREFIX) + string("writereal"))));
  }
}