/* Generate code for arithmetic expression, return a register number */
int genarith(TOKEN code)
{
int num, reg;
float fnum;
TOKEN lhs, rhs;
int reg1, reg2, freg;
int offs;
if (DEBUGGEN)
{
printf("genarith\n");
dbugprinttok(code);
};
//printf("tokentype: %i\n", code->tokentype);
switch ( code->tokentype )
{
case NUMBERTOK:
switch (code->datatype)
{
case INTEGER:
num = code->intval;
reg = getreg(WORD);
if ( num >= MINIMMEDIATE && num <= MAXIMMEDIATE )
asmimmed(MOVL, num, reg);
break;
case REAL:
fnum = code->realval;
reg = getreg(FLOAT);
makeflit(fnum, nextlabel);
asmldflit(MOVSD, nextlabel, reg);
nextlabel++;
break;
case POINTER:
num = 0;
reg = getreg(WORD);
asmimmed(MOVQ, num, reg);
break;
}
break;
case IDENTIFIERTOK:
offs = code->symentry->offset - stkframesize; /* net offset of the var */
switch(code->datatype)
{
case INTEGER:
reg = getreg(WORD);
//printf("kind: %i\n", code->symtype->datatype->kind);
if(code->symtype == NULL || code->symtype->kind == BASICTYPE)
asmld(MOVL, offs, reg, code->stringval);
else
asmld(MOVQ, offs, reg, code->stringval);
break;
case REAL:
reg = getreg(FLOAT);
asmld(MOVSD, offs, reg, code->stringval);
break;
}
break;
case OPERATOR:
if(code->whichval != FUNCALLOP && code->whichval != AREFOP)
{
lhs = code->operands;
rhs = lhs->link;
if(code->datatype == REAL)
{
reg1 = genarith( lhs );
if(rhs != NULL)
{
if(rhs->tokentype == OPERATOR && rhs->whichval == FUNCALLOP)
{
asmsttemp(reg1);
reg_map[reg1] = 0;
reg2 = genarith( rhs );
reg1 = getreg(FLOAT);
asmldtemp(reg1);
}
else
{
reg2 = genarith( rhs );
}
}
}
else
{
reg1 = genarith( lhs );
if(rhs != NULL)
reg2 = genarith( rhs );
}
}
switch(code->whichval)
{
case PLUSOP:
if(code->datatype == INTEGER)
asmrr(ADDL, reg2, reg1);
else
asmrr(ADDSD, reg2, reg1);
reg = reg1;
break;
case MINUSOP:
if(rhs != NULL)
{
if(code->datatype == INTEGER)
asmrr(SUBL, reg2, reg1);
else
asmrr(SUBSD, reg2, reg1);
}
else
{
reg2 = getreg(FLOAT);
asmfneg(reg1, reg2);
reg_map[reg2] = 0;
}
reg = reg1;
break;
case TIMESOP:
if(code->datatype == INTEGER)
asmrr(IMULL, reg2, reg1);
else
asmrr(MULSD, reg2, reg1);
reg = reg1;
break;
case DIVIDEOP:
if(code->datatype == INTEGER)
asmrr(DIVL, reg2, reg1);
else
asmrr(DIVSD, reg2, reg1);
reg = reg1;
break;
case EQOP:
case NEOP:
case LTOP:
case LEOP:
case GEOP:
case GTOP:
asmrr(CMPL, reg2, reg1);
reg = reg1;
break;
case FLOATOP:
freg = getreg(FLOAT);
asmfloat(reg1, freg);
reg_map[reg1] = 0;
reg = freg;
break;
case FIXOP:
reg2 = getreg(WORD);
asmfix(reg1, reg2);
reg_map[freg] = 0;
reg = reg2;
break;
case FUNCALLOP:
reg = genfun(code);
break;
case AREFOP:
reg = genaref(code, FBASE);
break;
}
break;
case STRINGTOK:
makeblit(code->stringval, nextlabel);
return nextlabel++;
break;
};
return reg;
}
/* Generate code for arithmetic expression, return a register number */
int genarith(TOKEN code)
{ int num1, num2, reg1, reg2, offs;
TOKEN tok, lhs, rhs;
SYMBOL sym, lsym, rsym;
if (DEBUGGEN)
{ printf("genarith\n");
dbugprinttok(code);
};
// This switch determines how to handle the token based on its type
switch ( code->tokentype )
{ case NUMBERTOK:
switch (code->datatype)
{ case INTEGER:
num1 = code->intval;
reg1 = getreg(WORD);
if (code->symtype != NULL)
{ if(code->symtype->kind == POINTERSYM)
asmimmed(MOVQ, num1, reg1);
}
else if ( num1 >= MINIMMEDIATE && num1 <= MAXIMMEDIATE )
asmimmed(MOVL, num1, reg1);
break;
case REAL:
reg1 = getreg(FLOAT);
makeflit(code->realval, nextlabel++);
asmldflit(MOVSD, nextlabel-1, reg1);
break;
}
break;
case IDENTIFIERTOK:
reg1 = getreg(WORD);
sym = code->symentry;
offs = sym->offset - stkframesize;
asmld(MOVQ, offs, reg1, code->stringval);
break;
case OPERATOR:
switch(code->whichval)
{ case PLUSOP:
lhs = code->operands;
rhs = lhs->link;
lsym = lhs->symentry;
rsym = rhs->symentry;
if(lsym != NULL & lhs->tokentype != NUMBERTOK)
{
switch(lsym->basicdt)
{ case INTEGER: reg1 = getreg(WORD); break;
case REAL: reg1 = getreg(FLOAT); break;
}
asmldr(MOVL, lsym->offset - stkframesize, RBP, reg1, lsym->namestring);
}
else
{ if(lhs->tokentype == OPERATOR) reg1 = genarith(lhs);
else switch(lhs->datatype)
{ case INTEGER:
reg1 = getreg(WORD);
asmimmed(MOVL, lhs->intval, reg1);
break;
case REAL:
reg1 = getreg(FLOAT);
makeflit(lhs->realval, nextlabel++);
asmldflit(MOVSD, nextlabel-1, reg1);
break;
}
}
if(rsym != NULL & rhs->tokentype != NUMBERTOK)
{
switch(rsym->basicdt)
{ case INTEGER: reg2 = getreg(WORD); break;
case REAL: reg2 = getreg(FLOAT); break;
}
asmldr(MOVL, rsym->offset - stkframesize, RBP, reg2, rsym->namestring);
}
else
{ if(rhs->tokentype == OPERATOR) reg2 = genarith(rhs);
else switch(rhs->datatype)
{ case INTEGER:
reg2 = getreg(WORD);
asmimmed(MOVL, rhs->intval, reg2);
break;
case REAL:
reg2 = getreg(FLOAT);
makeflit(rhs->realval, nextlabel++);
asmldflit(MOVSD, nextlabel-1, reg2);
break;
}
}
if(reg1 < 8 & reg2 < 8)
asmrr(ADDL, reg2, reg1);
else
asmrr(ADDSD, reg2, reg1);
unused(reg2);
break;
case MINUSOP:
lhs = code->operands;
lsym = lhs->symentry;
rhs = lhs->link;
if(rhs == NULL) //if this is just a negation
{ if(lsym != NULL & lhs->tokentype != NUMBERTOK)
{
switch(lsym->basicdt)
{ case INTEGER:
reg1 = getreg(WORD);
asmldr(MOVL, lsym->offset - stkframesize, RBP, reg1, lsym->namestring);
break;
case REAL:
reg1 = getreg(FLOAT);
reg2 = getreg(FLOAT);
asmldr(MOVSD, lsym->offset - stkframesize, RBP, reg1, lsym->namestring);
asmfneg(reg1, reg2);
unused(reg2);
break;
}
}
else
{ if(lhs->tokentype == OPERATOR) reg1 = genarith(lhs);
else switch(lhs->datatype)
{ case INTEGER:
reg1 = getreg(WORD);
asmimmed(MOVL, lhs->intval, reg1);
break;
case REAL:
reg1 = getreg(FLOAT);
reg2 = getreg(FLOAT);
asmldflit(MOVSD, nextlabel++, reg1);
asmfneg(reg1, reg2);
unused(reg2);
break;
}
}
return reg1;
}
rsym = rhs->symentry;
if(lsym != NULL & lhs->tokentype != NUMBERTOK)
{
switch(lsym->basicdt)
{ case INTEGER:
reg1 = getreg(WORD);
asmldr(MOVL, lsym->offset - stkframesize, RBP, reg1, lsym->namestring);
break;
case REAL:
reg1 = getreg(FLOAT);
asmldr(MOVSD, lsym->offset - stkframesize, RBP, reg1, lsym->namestring);
break;
}
}
else
{ if(lhs->tokentype == OPERATOR) reg1 = genarith(lhs);
else switch(lhs->datatype)
{ case INTEGER:
reg1 = getreg(WORD);
asmimmed(MOVL, lhs->intval, reg1);
break;
case REAL:
reg1 = getreg(FLOAT);
makeflit(lhs->realval, nextlabel++);
asmldflit(MOVSD, nextlabel-1, reg1);
break;
}
}
if(rsym != NULL & rhs->tokentype != NUMBERTOK)
{
switch(rsym->basicdt)
{ case INTEGER:
reg2 = getreg(WORD);
asmldr(MOVL, rsym->offset - stkframesize, RBP, reg2, rsym->namestring);
break;
case REAL:
reg2 = getreg(FLOAT);
asmldr(MOVSD, rsym->offset - stkframesize, RBP, reg2, rsym->namestring);
break;
}
}
else
{ if(rhs->tokentype == OPERATOR) reg2 = genarith(rhs);
else switch(rhs->datatype)
{ case INTEGER:
reg2 = getreg(WORD);
asmimmed(MOVL, rhs->intval, reg2);
break;
case REAL:
reg2 = getreg(FLOAT);
makeflit(rhs->realval, nextlabel++);
asmldflit(MOVSD, nextlabel-1, reg2);
break;
}
}
if(reg1 < 8 & reg2 < 8)
asmrr(SUBL, reg2, reg1);
else
asmrr(SUBSD, reg2, reg1);
unused(reg2);
break;
case TIMESOP:
lhs = code->operands;
rhs = lhs->link;
lsym = lhs->symentry;
rsym = rhs->symentry;
if(lsym != NULL & lhs->tokentype != NUMBERTOK)
{
switch(lsym->basicdt)
{ case INTEGER:
reg1 = getreg(WORD);
asmldr(MOVL, lsym->offset - stkframesize, RBP, reg1, lsym->namestring);
break;
case REAL:
reg1 = getreg(FLOAT);
asmldr(MOVSD, lsym->offset - stkframesize, RBP, reg1, lsym->namestring);
break;
}
}
else
{ if(lhs->tokentype == OPERATOR)
{ reg1 = genarith(lhs);
if(lhs->whichval == FUNCALLOP & rhs->whichval == FUNCALLOP)
{ asmsttemp(reg1);
unused(reg1);
}
}
else switch(lhs->datatype)
{ case INTEGER:
reg1 = getreg(WORD);
asmimmed(MOVL, lhs->intval, reg1);
break;
case REAL:
reg1 = getreg(FLOAT);
makeflit(lhs->realval, nextlabel++);
asmldflit(MOVSD, nextlabel-1, reg1);
break;
}
}
if(rsym != NULL & rhs->tokentype != NUMBERTOK)
{
switch(rsym->basicdt)
{ case INTEGER:
reg2 = getreg(WORD);
asmldr(MOVL, rsym->offset - stkframesize, RBP, reg2, rsym->namestring);
break;
case REAL:
reg2 = getreg(FLOAT);
asmldr(MOVSD, rsym->offset - stkframesize, RBP, reg2, rsym->namestring);
break;
}
}
else
{ if(rhs->tokentype == OPERATOR)
{ reg2 = genarith(rhs);
if(lhs->whichval == FUNCALLOP & rhs->whichval == FUNCALLOP)
{ switch(lhs->datatype)
{ case INTEGER: reg1 = getreg(WORD); break;
case REAL: reg1 = getreg(FLOAT); break;
}
asmldtemp(reg1);
}
}
else switch(rhs->datatype)
{ case INTEGER:
reg2 = getreg(WORD);
asmimmed(MOVL, rhs->intval, reg2);
break;
case REAL:
reg2 = getreg(FLOAT);
makeflit(rhs->realval, nextlabel++);
asmldflit(MOVSD, nextlabel-1, reg2);
break;
}
}
if(reg1 < 8 & reg2 < 8)
asmrr(IMULL, reg2, reg1);
else
asmrr(MULSD, reg2, reg1);
unused(reg2);
break;
case FLOATOP:
lhs = code->operands;
lsym = lhs->symentry;
reg1 = getreg(FLOAT);
reg2 = getreg(WORD);
asmldr(MOVL, lsym->offset - stkframesize, RBP, reg2, lsym->namestring);
asmfloat(reg2, reg1);
unused(reg2);
break;
case FUNCALLOP:
tok = code->operands;
if(tok->link != NULL)
{
switch(tok->link->tokentype)
{ case STRINGTOK:
asmlitarg(nextlabel++, EDI);
makeblit(tok->link->stringval, nextlabel-1);
asmcall(tok->stringval);
break;
case OPERATOR:
reg1 = genarith(tok->link);
break;
case NUMBERTOK:
switch(tok->link->datatype)
{ case INTEGER:
reg1 = getreg(WORD);
asmimmed(MOVL,tok->link->intval,reg1);
asmrr(MOVL, reg1, EDI);
break;
case REAL:
reg1 = getreg(FLOAT);
asmimmed(MOVSD,tok->link->realval,reg1);
asmrr(MOVSD, reg1, EDI);
break;
}
}
}
asmcall(tok->stringval);
break;
case FIXOP:
reg1 = getreg(WORD);
reg2 = genarith(code->operands);
asmfix(reg2,reg1);
break;
case POINTEROP:
lhs = code->operands;
if(lhs->tokentype == OPERATOR & lhs->whichval == AREFOP)
{ reg1 = genarith(lhs);
}
else
{ reg1 = getreg(WORD);
lsym = code->operands->symentry;
asmld(MOVQ, lsym->offset - stkframesize, reg1, code->operands->stringval);
}
break;
case AREFOP:
lhs = code->operands;
rhs = lhs->link;
if(lhs->tokentype == OPERATOR & lhs->whichval == POINTEROP)
{ reg2 = genarith(lhs->operands);
if(lhs->symtype != NULL)
{ if(lhs->symtype->basicdt == REAL)
{ reg1 = getreg(FLOAT);
asmldr(MOVSD, rhs->intval, reg2, reg1, "^. ");
unused(reg2);
break;
}
}
reg1 = getreg(WORD);
asmldr(MOVQ, rhs->intval, reg2, reg1, "^. ");
}
unused(reg2);
break;
}
break;
};
return reg1;
}
