4 /* macros zum registerzugriff bei kinder */
5 #define KID_REG(A) bnode->kids[A]->reg
6 #define KIDKID_REG(A,B) bnode->kids[A]->kids[B]->reg
7 #define KIDKIDKID_REG(A,B,C) bnode->kids[A]->kids[B]->kids[C]->reg
9 /* macros zum wertezugriff bei kindern */
10 #define KID_VAL(A) bnode->kids[A]->val
11 #define KIDKID_VAL(A,B) bnode->kids[A]->kids[B]->val
12 #define KIDKIDKID_VAL(A,B,C) bnode->kids[A]->kids[B]->kids[C]->val
14 #define KID_PARM(A) bnode->kids[A]->param_index
15 #define KIDKID_PARM(A,B) bnode->kids[A]->kids[B]->param_index
16 #define KIDKIDKID_PARM(A,B,C) bnode->kids[A]->kids[B]->kids[C]->param_index
18 /* macros zum zugriff des aktuellen knotens */
19 #define BN_REG bnode->reg
20 #define BN_VAL bnode->val
22 /* wenn sich ein parameter auf der "leseseite" (also links bei at&t syntax)
23 * befindet, dann soll dieses register verwendet werden */
24 #define KIDREG2PARM(A) if(bnode->kids[A]->param_index > -1) { bnode->kids[A]->reg = param_reg(bnode->kids[A]->param_index); }
25 #define KIDKIDREG2PARM(A,B) if(bnode->kids[A]->kids[B]->param_index > -1) { bnode->kids[A]->kids[B]->reg = param_reg(bnode->kids[A]->kids[B]->param_index); }
26 #define KIDKIDKIDREG2PARM(A,B,C) if(bnode->kids[A]->kids[B]->kids[C]->param_index > -1) { bnode->kids[A]->kids[B]->kids[C]->reg = param_reg(bnode->kids[A]->kids[B]->kids[C]->param_index); }
28 /* wenn sich ein parameter auf der "schreibeseite" befindet (also rechts bei
29 * at&t syntax), dann muss es vorher in ein temporaeres register gemovt werden */
30 #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);
38 void gen_e_eno(struct treenode *bnode, char *instr)
40 printf("\t#gen_e_eno(%s)\n", instr);
43 printf("\t%s %s,%s,%s\n", instr, BN_REG, KID_REG(0), KID_REG(1));
46 void gen_id_eno(struct treenode *bnode)
48 printf("\t#gen_id_eno\n");
53 printf("\tsub %s,%s,%s\n", BN_REG, KID_REG(0), KIDKID_REG(1,1));
54 printf("\tsub %s,%s,%s\n", BN_REG, BN_REG, KIDKID_REG(1,0));
57 void gen_e_imm(struct treenode *bnode, char *instr)
59 printf("\t#gen_e_imm(%s)\n", instr);
62 /* man kann sich ein move der konstante bei der multiplikation ersparen */
63 if(strcmp(instr, "mullw") == 0) {
64 if(KID_VAL(1) == 1 && strcmp(KID_REG(0), BN_REG) == 0) {
65 printf("\t#multiplikation mit 1 wegoptimiert\n");
67 if(KID_VAL(1) > (65536)-1 || KID_VAL(1) < -65536) {
68 moveimm(KID_VAL(1), next_reg(BN_REG,0));
69 printf("\tmullw %s,%s,%s\n", BN_REG, KID_REG(0), next_reg(BN_REG,0));
71 printf("\tmulli %s,%s,%d\n", BN_REG, KID_REG(0), KID_VAL(1));
75 if(strcmp(instr, "sub") == 0 && KID_VAL(1) == 0) {
76 printf("\t#subtraktion mit 0 wegoptimiert\n");
77 move(KID_REG(0), BN_REG);
79 if(KID_VAL(1) > (65536)-1 || KID_VAL(1) < -65536) {
80 moveimm(KID_VAL(1), next_reg(BN_REG,0));
81 printf("\t%s %s,%s,%s\n", instr, BN_REG, KID_REG(0), next_reg(BN_REG,0));
83 printf("\t%si %s,%s,%d\n", instr, BN_REG, KID_REG(0), KID_VAL(1));
89 void gen_imm_eno(struct treenode *bnode, char *instr)
91 printf("\t#gen_imm_eno(%s)\n", instr);
94 /* man kann sich ein move der konstante bei der multiplikation ersparen */
95 if(strcmp(instr, "mullw") == 0) {
96 if(KID_VAL(0) == 1 && strcmp(KID_REG(1), BN_REG) == 0) {
97 printf("\t#multiplikation mit 1 wegoptimiert\n");
99 if(KID_VAL(0) > (65536)-1 || KID_VAL(0) < -65536) {
100 moveimm(KID_VAL(0), next_reg(BN_REG,0));
101 printf("\tmullw %s,%s,%s\n", BN_REG, KID_REG(1), next_reg(BN_REG,0));
103 printf("\tmulli %s,%s,%d\n", BN_REG, KID_REG(1), KID_VAL(0));
107 /* TODO: imm check einbauen */
108 printf("\taddi %s,%s,%d\n", BN_REG, KID_REG(1), KID_VAL(0));
112 void gen_eqless(struct treenode *bnode, char *op, short e0, short e1, short deep)
114 printf("\t#gen_eqless_%i%i @ %i (op: %s)\n", e0, e1, deep, op);
116 if(e0) { KIDREG2PARM(0); } else { KIDREG2ID(0); }
117 if(e1) { KIDREG2PARM(1); } else { KIDREG2ID(1); }
122 printf("\tcmp %d(%%%s), %%%s\n", bnode->kids[1]->soffset *8, KIDKID_REG(1,0), KID_REG(0));
124 printf("\tcmp %%%s, %%%s\n", KID_REG(1), KID_REG(0));
126 } else if(e0 && !e1) {
128 printf("\tcmp $%d, %%%s\n", KID_VAL(1), KID_REG(0));
129 } else if (deep == 1) {
131 printf("\tcmp $%d, %%%s\n", KID_VAL(1), KIDKID_REG(0,0));
132 } else if (deep == 2) {
133 KIDKIDKIDREG2PARM(0,0,0);
134 printf("\tcmp $%d, %%%s\n", KID_VAL(1), KIDKIDKID_REG(0,0,0));
136 } else if(!e0 && e1) {
137 printf("\tcmp $%d, %%%s\n", KID_VAL(0), KID_REG(1));
139 printf("\tset%s %%%s\n", op, reg_64to8l(BN_REG));
140 printf("\tand $1, %%%s\n", BN_REG);
142 if(e0) { KIDREG2PARM(0); } else { moveimm(KID_VAL(0), BN_REG); }
143 if(e1) { KIDREG2PARM(1); }
144 if(strcmp(op,"e")==0 && bnode->kids[1]->op == O_NULL) {
146 printf("\tcntlzw %s,%s\n", KID_REG(0), KID_REG(0));
147 printf("\tsrwi %s,%s,5\n", BN_REG, KID_REG(0));
150 moveimm(KID_VAL(1), KID_REG(1));
152 if(strcmp(op, "e")==0) {
154 printf("\txor %s,%s,%s\n", BN_REG, KID_REG(0), KID_REG(1));
155 printf("\tcntlzw %s,%s\n", BN_REG, BN_REG);
156 printf("\tsrwi %s,%s,5\n", BN_REG, BN_REG);
157 } else if(strcmp(op, "l")==0 || strcmp(op, "g")==0) {
159 printf("\tcmpw 7,%s,%s\n", KID_REG(1), KID_REG(0));
160 printf("\tmfcr %s\n", BN_REG);
162 /* um (32-29)=3 nach rechts shiften und das LSB anschauen */
163 printf("\trlwinm %s,%s,%i,31,31\n", BN_REG, BN_REG, strcmp(op,"l")==0 ? 30 : 30);
166 /* vergleich mit null und in CR0 speichern */
167 printf("\tcmpwi %s,0\n", BN_REG);
171 void gen_subspecial(struct treenode *bnode, short e)
173 /* tritt z.b. bei snafu_05.0 auf */
174 printf("\t#gen_subspecial(%i)\n", e);
178 /* TODO: Loong@ codea_snafu_03.0 */
181 if(KIDKID_VAL(1,0) != 0) {
182 printf("\tsubi %s,%s,%d\n", BN_REG, BN_REG, KIDKID_VAL(1,0));
185 printf("\tsub %s,%s,%s\n", BN_REG, BN_REG, KIDKID_REG(1,0));
187 if(e) KIDKIDREG2PARM(1,1);
188 printf("\tadd %s,%s,%s\n", BN_REG, BN_REG, KIDKID_REG(1,1));
191 void assign_var(struct treenode *bnode)
193 printf("\t#assign_var\n");
195 if (strcmp(bnode->kids[0]->kids[0]->name, bnode->kids[1]->name) != 0) {
197 printf("\tmr %s,%s\n", KID_REG(1), KIDKID_REG(0,0));
198 } /*else: x := x - 1 geht in einem befehl */
199 printf("\tsubi %s,%s,%d\n", KID_REG(1), KID_REG(1), KIDKID_VAL(0,1));
203 static short sc[8] = {0};
204 void make_call(struct treenode *bnode)
207 printf("\t#params pushen\n");
208 for(j = 0; j < bnode->soffset; j++) {
210 printf("\tlwz 20,%d(1)\n", j*4);
211 printf("\tstw %s,%d(1)\n", param_reg(j), j*4);
212 printf("\tmr %s,20\n", param_reg(j));
213 } else if (sc[j] == 0) {
214 printf("\tstw %s,%d(1)\n", param_reg(j), j*4);
217 printf("\t#vars pushen\n");
218 for(j = bnode->soffset; j < bnode->soffset + bnode->vars; j++) {
219 printf("\tstw %s,%d(1)\n", param_reg(j), j*4);
222 /* TODO: schoener machen... */
223 if(strcmp(BN_REG, "14")!=0) {
224 printf("\t#tmp register pushen\n");
225 printf("\tstw 14,52(1)\n");
226 if(strcmp(BN_REG, "15")!=0) {
227 printf("\tstw 15,56(1)\n");
228 if(strcmp(BN_REG, "16")!=0) {
229 printf("\tstw 16,60(1)\n");
234 printf("\tbl %s\n", bnode->name);
237 if(strcmp(BN_REG, "14")!=0) {
238 printf("\t#tmp register poppen\n");
239 if(strcmp(BN_REG, "15")!=0) {
240 if(strcmp(BN_REG, "16")!=0) {
241 printf("\tlwz 16,60(1)\n");
243 printf("\tlwz 15,56(1)\n");
245 printf("\tlwz 14,52(1)\n");
248 printf("\t#vars poppen\n");
249 for(j = bnode->soffset + bnode->vars - 1; j > bnode->soffset - 1; j--) {
250 printf("\tlwz %s,%d(1)\n", param_reg(j), j*4);
253 printf("\t#params poppen\n");
254 for(j = bnode->soffset - 1; j >= 0; j--) {
256 printf("\tlwz %s,%d(1)\n", param_reg(j), j*4);
258 for(j = 0; j < bnode->soffset; j++) {
260 printf("\tlwz %s,%d(1)\n", param_reg(j), j*4);
263 /* clear stack control array */
264 for(j = 0; j < sizeof sc / sizeof sc[0]; j++)
268 void prep_arg(struct treenode *bnode, int moveit)
270 printf("\t#args-nr-> %i (%%%s) [moveit= %i]\n", bnode->soffset, param_reg(bnode->soffset), moveit);
271 sc[bnode->soffset] = 1;
272 if(moveit) { /* expr */
273 if((BN_REG == (char *) NULL) || (bnode->kids[1] != TREENULL && bnode->kids[1]->op == O_ID && bnode->kids[1]->kids[0] == TREENULL && bnode->kids[1]->kids[1] == TREENULL)) {
274 if(bnode->kids[1]->name != (char *) NULL && strcmp(bnode->kids[1]->name,"this")!=0) {
276 printf("\tstw %s,%d(1)\n", KID_REG(1),bnode->soffset*4);
278 printf("\tstw %s,%d(1)\n", param_reg(bnode->soffset), bnode->soffset*4);
279 sc[bnode->soffset] = 2;
282 printf("\tstw %s,%d(1)\n", BN_REG, bnode->soffset*4);
284 } else { /* just O_ID */
286 printf("\tstw %s,%d(1)\n", KID_REG(0), bnode->soffset*4);
293 %term O_RET=1 O_NULL=2 O_SUB=3 O_MUL=4 O_OR=5 O_LESS=6 O_EQ=7 O_ID=8 O_ADD=9 O_NUM=10 O_FIELD=11 O_MTWO=12 O_MFOUR=13 O_MEIGHT=14 O_MONE=15 O_ASSIGN=16 O_IF=17 O_BOOL=18 O_CALL=19 O_ARG=20 O_NOTHING=21 O_EXPR=22
303 assign: O_ASSIGN(expr, O_ID) # 1 # KIDREG2PARM(1); printf("\tmr %s,%s\n", KID_REG(1), BN_REG);
304 assign: O_ASSIGN(imm, O_ID) # 1 # KIDREG2PARM(1); moveimm(KID_VAL(0), KID_REG(1));
305 assign: O_ASSIGN(O_ID, O_ID) # 1 # KIDREG2PARM(1); KIDREG2PARM(0); printf("\tmr %s,%s\n", KID_REG(1), KID_REG(0));
307 assign: O_ASSIGN(O_SUB(O_ID,O_NUM), O_ID) # 1 # assign_var(bnode);
309 assign: O_ASSIGN(expr, O_FIELD(expr)) # 1 # KIDKIDREG2PARM(1,0); printf("\tstw %s,%d(%s)\n", BN_REG, bnode->kids[1]->soffset * 4, KIDKID_REG(1,0));
310 assign: O_ASSIGN(O_ID, O_FIELD(expr)) # 1 # KIDREG2PARM(0); KIDKIDREG2PARM(1,0); printf("\tstw %s,%d(%s)\n", KID_REG(0), bnode->kids[1]->soffset * 4, KIDKID_REG(1,0));
313 ifstat: O_IF(O_ID) # 1 # /* fuer faelle wie "if bla then" noetig */ KIDREG2PARM(0); printf("\tcmpwi %s,0\n", KID_REG(0));
314 ifstat: O_IF(O_BOOL(imm)) # 1 # printf("\tcmpwi %s,0\n", BN_REG);
315 ifstat: O_IF(expr) # 2 # /* iburg beschummeln :/ */ printf("\tcmpwi %s,0\n", BN_REG);
316 ifstat: O_IF(O_BOOL(expr)) # 1 # /* dann braucht man kein test */
319 ret: O_RET(retexpr) # 2 # printf("\t/*o_ret(expr)*/\n"); move(BN_REG, "3");
320 ret: O_EXPR(expr) # 0 #
322 retexpr: O_ID # 1 # printf("\t/*retexpr*/\n"); if(bnode->param_index > -1) move(param_reg(bnode->param_index), BN_REG);
327 expr: imm # 1 # moveimm(BN_VAL, BN_REG);
328 expr: O_BOOL(expr) # 0 #
330 expr: O_CALL(expr) # 0 # make_call(bnode);
331 expr: O_ARG(expr,expr) # 1 # prep_arg(bnode, 1);
332 expr: O_ARG(O_ID,expr) # 1 # prep_arg(bnode, 0);
333 expr: O_NOTHING # 0 #
335 expr: O_SUB(expr,expr) # 2 # gen_e_eno(bnode, "sub");
336 expr: O_SUB(expr,imm) # 1 # gen_e_imm(bnode, "sub");
338 expr: O_SUB(expr,O_SUB(O_ID,expr)) # 2 # gen_subspecial(bnode, 0);
339 expr: O_SUB(expr,O_SUB(imm,expr)) # 2 # gen_subspecial(bnode, 1);
341 expr: O_SUB(expr, O_ADD(O_ID,expr)) # 1 # gen_id_eno(bnode);
344 expr: O_ADD(expr,expr) # 1 # gen_e_eno(bnode, "add");
345 expr: O_ADD(expr,imm) # 1 # gen_e_imm(bnode, "add");
346 expr: O_ADD(imm,expr) # 1 # gen_imm_eno(bnode, "add");
349 expr: O_MUL(expr,expr) # 1 # gen_e_eno(bnode, "mullw");
350 expr: O_MUL(expr,imm) # 1 # gen_e_imm(bnode, "mullw");
351 expr: O_MUL(imm,expr) # 1 # gen_imm_eno(bnode, "mullw");
354 expr: O_OR(expr,expr) # 1 # gen_e_eno(bnode, "or");
355 expr: O_OR(expr,imm) # 2 # gen_e_imm(bnode, "or");
358 expr: O_LESS(expr,expr) # 3 # gen_eqless(bnode, "l", 1, 1, 0);
359 expr: O_LESS(expr,imm) # 3 # gen_eqless(bnode, "l", 1, 0, 0);
360 expr: O_LESS(imm,expr) # 3 # gen_eqless(bnode, "g", 0, 1, 0);
363 expr: O_EQ(expr,expr) # 3 # gen_eqless(bnode, "e", 1, 1, 0);
364 expr: O_EQ(expr,imm) # 3 # gen_eqless(bnode, "e", 1, 0, 0);
365 expr: O_EQ(imm,expr) # 3 # gen_eqless(bnode, "e", 0, 1, 0);
366 expr: O_EQ(expr,O_NULL) # 3 # gen_eqless(bnode, "e", 1, 0, 0);
368 expr: O_EQ(O_EQ(expr,O_NULL),O_NULL) # 3 # gen_eqless(bnode, "ne", 1, 0, 1);
369 expr: O_EQ(O_EQ(O_EQ(expr,O_NULL),O_NULL),O_NULL) # 3 # gen_eqless(bnode, "e", 1, 0, 2);
372 expr: O_FIELD(expr) # 1 # printf("\t/* field(expr)*/\n"); KIDREG2PARM(0); printf("\tlwz %s, %d(%s)\n", BN_REG, bnode->soffset * 4, KID_REG(0));
373 expr: O_FIELD(imm) # 1 # printf("\t/* field(imm)*/\n"); moveimm(KID_VAL(0), BN_REG); printf("\tlwz %s,%d(%s)\n", BN_REG, bnode->soffset * 4, BN_REG);
376 imm: O_ADD(imm,imm) # 0 # BN_VAL = KID_VAL(0) + KID_VAL(1);
377 imm: O_SUB(imm,imm) # 0 # BN_VAL = KID_VAL(0) - KID_VAL(1);
378 imm: O_MUL(imm,imm) # 0 # BN_VAL = KID_VAL(0) * KID_VAL(1);
379 imm: O_LESS(imm,imm) # 0 # BN_VAL = KID_VAL(0) < KID_VAL(1) ? 1 : 0;
380 imm: O_EQ(imm,imm) # 0 # BN_VAL = KID_VAL(0) == KID_VAL(1) ? 1 : 0;
381 imm: O_OR(imm,imm) # 0 # BN_VAL = KID_VAL(0) | KID_VAL(1);