* register verwendet werden */
#define KIDREG2PARM(A) if(bnode->kids[A]->param_index > -1) { bnode->kids[A]->reg = param_reg(bnode->kids[A]->param_index); }
+#define KIDREG2ID(A) if(bnode->kids[A]->op == O_ID && bnode->kids[A]->param_index > -1) move(param_reg(bnode->kids[A]->param_index), bnode->kids[A]->reg);
+
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
void gen_e_eno(struct treenode *bnode, char *instr)
{
+ printf("\t//gen_e_eno(%s)\n", instr);
+ KIDREG2ID(0);
KIDREG2PARM(1);
printf("\t%s %%%s, %%%s\n", instr, KID_REG(1), KID_REG(0));
}
void gen_e_imm(struct treenode *bnode, char *instr)
{
+ printf("\t//gen_e_imm(%s)\n", instr);
+ KIDREG2ID(0);
+ KIDREG2ID(1);
/* man kann sich ein move der konstante bei der multiplikation ersparen */
if(strcmp(instr, "imulq") == 0) {
- printf("\timulq $%li, %%%s, %%%s\n", KID_VAL(1), KID_REG(0), BN_REG);
+ printf("\timulq $%d, %%%s, %%%s\n", KID_VAL(1), KID_REG(0), BN_REG);
} else {
- printf("\t%s $%li, %%%s\n", instr, KID_VAL(1), KID_REG(0));
+ printf("\t%s $%d, %%%s\n", instr, KID_VAL(1), KID_REG(0));
move(KID_REG(0), BN_REG);
}
}
void gen_imm_eno(struct treenode *bnode, char *instr)
{
+ printf("\t//gen_imm_eno(%s)\n", instr);
+ KIDREG2ID(0);
KIDREG2PARM(1);
/* man kann sich ein move der konstante bei der multiplikation ersparen */
if(strcmp(instr, "imulq") == 0) {
- printf("\timulq $%li, %%%s, %%%s\n", KID_VAL(0), KID_REG(1), BN_REG);
- } else {
+ printf("\timulq $%d, %%%s, %%%s\n", KID_VAL(0), KID_REG(1), BN_REG);
+ } else if(strcmp(instr, "addq") == 0) {
+ printf("\taddq $%d, %%%s\n", KID_VAL(0), BN_REG);
+ } else { /* subq */
moveimm(KID_VAL(0), BN_REG);
printf("\t%s %%%s, %%%s\n", instr, KID_REG(1), BN_REG);
}
void gen_eqless(struct treenode *bnode, char *op, short e0, short e1)
{
printf("\t//gen_eqless_%i%i\n", e0, e1);
- if(e0) KIDREG2PARM(0);
- if(e1) KIDREG2PARM(1);
+ if(e0) { KIDREG2PARM(0); } else { KIDREG2ID(0); }
+ if(e1) { KIDREG2PARM(1); } else { KIDREG2ID(1); }
if(e0 && e1) {
printf("\tcmp %%%s, %%%s\n", KID_REG(1), KID_REG(0));
} else if(e0 && !e1) {
- printf("\tcmp $%li, %%%s\n", KID_VAL(1), KID_REG(0));
+ printf("\tcmp $%d, %%%s\n", KID_VAL(1), KID_REG(0));
} else if(!e0 && e1) {
if(strcmp("e", op) == 0) {
- printf("\tcmp $%li, %%%s\n", KID_VAL(0), KID_REG(1));
+ printf("\tcmp $%d, %%%s\n", KID_VAL(0), KID_REG(1));
} else {
moveimm(KID_VAL(0), BN_REG);
printf("\tcmp %%%s, %%%s\n", KID_REG(1), BN_REG);
%%
begin: ret # 0 # printf("\n");
-ret: O_RET(expr) # 2 # move(BN_REG, "rax"); func_footer();
+ret: O_RET(retexpr) # 2 # printf("\t//o_ret(expr)\n"); move(BN_REG, "rax"); func_footer();
-expr: O_ID # 1 # if(bnode->param_index > -1) move(param_reg(bnode->param_index), BN_REG);
+retexpr: O_ID # 1 # printf("\t//retexpr\n"); if(bnode->param_index > -1) move(param_reg(bnode->param_index), BN_REG);
+retexpr: expr
+
+expr: O_ID # 0 #
expr: imm # 1 # moveimm(BN_VAL, BN_REG);
-expr: O_SUB(expr,exprno) # 1 # gen_e_eno(bnode, "subq");
+expr: O_SUB(expr,expr) # 1 # gen_e_eno(bnode, "subq");
expr: O_SUB(expr,imm) # 2 # gen_e_imm(bnode, "subq");
-expr: O_SUB(imm,exprno) # 2 # gen_imm_eno(bnode, "subq");
+expr: O_SUB(imm,expr) # 2 # gen_imm_eno(bnode, "subq");
-expr: O_ADD(expr,exprno) # 1 # gen_e_eno(bnode, "addq");
-expr: O_ADD(imm,expr) # 2 # gen_e_imm(bnode, "addq");
+expr: O_ADD(expr,expr) # 1 # gen_e_eno(bnode, "addq");
+expr: O_ADD(expr,imm) # 2 # gen_e_imm(bnode, "addq");
+expr: O_ADD(imm,expr) # 2 # gen_imm_eno(bnode, "addq");
-expr: O_MUL(expr,exprno) # 1 # gen_e_eno(bnode, "imulq");
+expr: O_MUL(expr,expr) # 1 # gen_e_eno(bnode, "imulq");
expr: O_MUL(expr,imm) # 1 # gen_e_imm(bnode, "imulq");
-expr: O_MUL(imm,exprno) # 1 # gen_imm_eno(bnode, "imulq");
+expr: O_MUL(imm,expr) # 1 # gen_imm_eno(bnode, "imulq");
-expr: O_OR(expr,exprno) # 1 # gen_e_eno(bnode, "orq");
+expr: O_OR(expr,expr) # 1 # gen_e_eno(bnode, "orq");
expr: O_OR(expr,imm) # 2 # gen_e_imm(bnode, "orq");
expr: O_LESS(expr,expr) # 3 # gen_eqless(bnode, "l", 1, 1);
expr: O_LESS(expr,imm) # 3 # gen_eqless(bnode, "l", 1, 0);
expr: O_LESS(imm,expr) # 3 # gen_eqless(bnode, "l", 0, 1);
-expr: O_EQ(exprno,exprno) # 3 # gen_eqless(bnode, "e", 1, 1);
-expr: O_EQ(exprno,imm) # 3 # gen_eqless(bnode, "e", 1, 0);
-expr: O_EQ(imm,exprno) # 3 # gen_eqless(bnode, "e", 0, 1);
+expr: O_EQ(expr,expr) # 3 # gen_eqless(bnode, "e", 1, 1);
+expr: O_EQ(expr,imm) # 3 # gen_eqless(bnode, "e", 1, 0);
+expr: O_EQ(imm,expr) # 3 # gen_eqless(bnode, "e", 0, 1);
expr: O_EQ(nexpr,O_NULL) # 0 #
-expr: O_EQ(exprno,O_NULL) # 3 # gen_eqless(bnode, "e", 1, 0);
-
-expr: O_FIELD(exprno) # 1 # KIDREG2PARM(0); printf("\tmovq %li(%%%s), %%%s\n", bnode->soffset * 8, KID_REG(0), BN_REG);
+expr: O_EQ(expr,O_NULL) # 3 # gen_eqless(bnode, "e", 1, 0);
+expr: O_FIELD(expr) # 1 # printf("\t//field(expr)\n"); KIDREG2PARM(0); printf("\tmovq %d(%%%s), %%%s\n", bnode->soffset * 8, KID_REG(0), BN_REG);
+expr: O_FIELD(imm) # 1 # printf("\t//field(imm)\n"); printf("\tmovq %d, %%%s\n", KID_VAL(0) + (bnode->soffset * 8), BN_REG);
-exprno: O_ID # 0 # /* brauchen wir nicht 'zwischenlagern', weil nur gelesen wird */
-exprno: expr
-nexpr: O_EQ(expr,O_NULL) # 0 #
+nexpr: O_EQ(expr,O_NULL) # 0 # gen_eqless(bnode, "ne", 1, 0);
imm: O_ADD(imm,imm) # 0 # BN_VAL = KID_VAL(0) + KID_VAL(1);