2 * This file implements the node emitter.
22 #include "iredges_t.h"
24 #include "../besched_t.h"
25 #include "../benode_t.h"
27 #include "ia32_emitter.h"
28 #include "gen_ia32_emitter.h"
29 #include "gen_ia32_regalloc_if.h"
30 #include "ia32_nodes_attr.h"
31 #include "ia32_new_nodes.h"
32 #include "ia32_map_regs.h"
34 #ifdef obstack_chunk_alloc
35 # undef obstack_chunk_alloc
36 # define obstack_chunk_alloc xmalloc
38 # define obstack_chunk_alloc xmalloc
39 # define obstack_chunk_free free
42 #define BLOCK_PREFIX(x) ".L" x
44 extern int obstack_printf(struct obstack *obst, char *fmt, ...);
46 #define SNPRINTF_BUF_LEN 128
48 /* global arch_env for lc_printf functions */
49 static const arch_env_t *arch_env = NULL;
51 /* indicates whether blocks are scheduled or not
52 (this variable is set automatically) */
53 static int have_block_sched = 0;
55 /*************************************************************
57 * (_) | | / _| | | | |
58 * _ __ _ __ _ _ __ | |_| |_ | |__ ___| |_ __ ___ _ __
59 * | '_ \| '__| | '_ \| __| _| | '_ \ / _ \ | '_ \ / _ \ '__|
60 * | |_) | | | | | | | |_| | | | | | __/ | |_) | __/ |
61 * | .__/|_| |_|_| |_|\__|_| |_| |_|\___|_| .__/ \___|_|
64 *************************************************************/
66 /* We always pass the ir_node which is a pointer. */
67 static int ia32_get_arg_type(const lc_arg_occ_t *occ) {
68 return lc_arg_type_ptr;
73 * Returns the register at in position pos.
75 static const arch_register_t *get_in_reg(const ir_node *irn, int pos) {
77 const arch_register_t *reg = NULL;
79 assert(get_irn_arity(irn) > pos && "Invalid IN position");
81 /* The out register of the operator at position pos is the
82 in register we need. */
83 op = get_irn_n(irn, pos);
85 reg = arch_get_irn_register(arch_env, op);
87 assert(reg && "no in register found");
92 * Returns the register at out position pos.
94 static const arch_register_t *get_out_reg(const ir_node *irn, int pos) {
96 const arch_register_t *reg = NULL;
98 /* 1st case: irn is not of mode_T, so it has only */
99 /* one OUT register -> good */
100 /* 2nd case: irn is of mode_T -> collect all Projs and ask the */
101 /* Proj with the corresponding projnum for the register */
103 if (get_irn_mode(irn) != mode_T) {
104 reg = arch_get_irn_register(arch_env, irn);
106 else if (is_ia32_irn(irn)) {
107 reg = get_ia32_out_reg(irn, pos);
110 const ir_edge_t *edge;
112 foreach_out_edge(irn, edge) {
113 proj = get_edge_src_irn(edge);
114 assert(is_Proj(proj) && "non-Proj from mode_T node");
115 if (get_Proj_proj(proj) == pos) {
116 reg = arch_get_irn_register(arch_env, proj);
122 assert(reg && "no out register found");
132 * Returns the name of the in register at position pos.
134 static const char *get_ia32_reg_name(ir_node *irn, int pos, enum io_direction in_out) {
135 const arch_register_t *reg;
137 static char *buf = NULL;
140 if (in_out == IN_REG) {
141 reg = get_in_reg(irn, pos);
144 /* destination address mode nodes don't have outputs */
145 if (is_ia32_irn(irn) && get_ia32_op_type(irn) == ia32_AddrModeD) {
149 reg = get_out_reg(irn, pos);
152 name = arch_register_get_name(reg);
158 len = strlen(name) + 2;
159 buf = xcalloc(1, len);
161 snprintf(buf, len, "%%%s", name);
167 * Get the register name for a node.
169 static int ia32_get_reg_name(lc_appendable_t *app,
170 const lc_arg_occ_t *occ, const lc_arg_value_t *arg)
173 ir_node *X = arg->v_ptr;
174 int nr = occ->width - 1;
177 return lc_appendable_snadd(app, "(null)", 6);
179 buf = get_ia32_reg_name(X, nr, occ->conversion == 'S' ? IN_REG : OUT_REG);
181 return lc_appendable_snadd(app, buf, strlen(buf));
185 * Returns the tarval, offset or scale of an ia32 as a string.
187 static int ia32_const_to_str(lc_appendable_t *app,
188 const lc_arg_occ_t *occ, const lc_arg_value_t *arg)
191 ir_node *X = arg->v_ptr;
194 return lc_arg_append(app, occ, "(null)", 6);
196 if (occ->conversion == 'C') {
197 buf = get_ia32_cnst(X);
200 buf = get_ia32_am_offs(X);
203 return buf ? lc_appendable_snadd(app, buf, strlen(buf)) : 0;
207 * Determines the SSE suffix depending on the mode.
209 static int ia32_get_mode_suffix(lc_appendable_t *app,
210 const lc_arg_occ_t *occ, const lc_arg_value_t *arg)
212 ir_node *X = arg->v_ptr;
213 ir_mode *mode = get_irn_mode(X);
215 if (mode == mode_T) {
216 mode = is_ia32_AddrModeS(X) || is_ia32_AddrModeD(X) ? get_ia32_ls_mode(X) : get_ia32_res_mode(X);
220 return lc_arg_append(app, occ, "(null)", 6);
222 if (mode_is_float(mode)) {
223 return lc_appendable_chadd(app, get_mode_size_bits(mode) == 32 ? 's' : 'd');
226 return lc_appendable_chadd(app, mode_is_signed(mode) ? 's' : 'z');
231 * Return the ia32 printf arg environment.
232 * We use the firm environment with some additional handlers.
234 const lc_arg_env_t *ia32_get_arg_env(void) {
235 static lc_arg_env_t *env = NULL;
237 static const lc_arg_handler_t ia32_reg_handler = { ia32_get_arg_type, ia32_get_reg_name };
238 static const lc_arg_handler_t ia32_const_handler = { ia32_get_arg_type, ia32_const_to_str };
239 static const lc_arg_handler_t ia32_mode_handler = { ia32_get_arg_type, ia32_get_mode_suffix };
242 /* extend the firm printer */
243 env = firm_get_arg_env();
245 lc_arg_register(env, "ia32:sreg", 'S', &ia32_reg_handler);
246 lc_arg_register(env, "ia32:dreg", 'D', &ia32_reg_handler);
247 lc_arg_register(env, "ia32:cnst", 'C', &ia32_const_handler);
248 lc_arg_register(env, "ia32:offs", 'O', &ia32_const_handler);
249 lc_arg_register(env, "ia32:mode", 'M', &ia32_mode_handler);
255 static char *ia32_get_reg_name_for_mode(ia32_emit_env_t *env, ir_mode *mode, const arch_register_t *reg) {
256 switch(get_mode_size_bits(mode)) {
258 return ia32_get_mapped_reg_name(env->isa->regs_8bit, reg);
260 return ia32_get_mapped_reg_name(env->isa->regs_16bit, reg);
262 return (char *)arch_register_get_name(reg);
267 * Emits registers and/or address mode of a binary operation.
269 char *ia32_emit_binop(const ir_node *n, ia32_emit_env_t *env) {
270 static char *buf = NULL;
272 /* verify that this function is never called on non-AM supporting operations */
273 //assert(get_ia32_am_support(n) != ia32_am_None && "emit binop expects addressmode support");
275 #define PRODUCES_RESULT(n) \
276 (!(is_ia32_St(n) || \
277 is_ia32_Store8Bit(n) || \
278 is_ia32_CondJmp(n) || \
279 is_ia32_fCondJmp(n) || \
280 is_ia32_SwitchJmp(n)))
283 buf = xcalloc(1, SNPRINTF_BUF_LEN);
286 memset(buf, 0, SNPRINTF_BUF_LEN);
289 switch(get_ia32_op_type(n)) {
291 if (is_ia32_ImmConst(n) || is_ia32_ImmSymConst(n)) {
292 lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%3S, %s", n, get_ia32_cnst(n));
295 const arch_register_t *in1 = get_in_reg(n, 2);
296 const arch_register_t *in2 = get_in_reg(n, 3);
297 const arch_register_t *out = PRODUCES_RESULT(n) ? get_out_reg(n, 0) : NULL;
298 const arch_register_t *in;
300 in = out ? (REGS_ARE_EQUAL(out, in2) ? in1 : in2) : in2;
301 out = out ? out : in1;
303 snprintf(buf, SNPRINTF_BUF_LEN, "%%%s, %%%s", \
304 arch_register_get_name(out), arch_register_get_name(in));
308 if (is_ia32_ImmConst(n) || is_ia32_ImmSymConst(n)) {
309 assert(! PRODUCES_RESULT(n) && "Source AM with Const must not produce result");
310 snprintf(buf, SNPRINTF_BUF_LEN, "%s, %s", get_ia32_cnst(n), ia32_emit_am(n, env));
313 lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%4S, %s", n, ia32_emit_am(n, env));
317 if (is_ia32_ImmConst(n) || is_ia32_ImmSymConst(n)) {
318 lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%s,%s%s",
319 ia32_emit_am(n, env),
320 is_ia32_ImmSymConst(n) ? " OFFSET FLAT:" : " ", /* In case of a symconst we must add OFFSET to */
321 get_ia32_cnst(n)); /* tell the assembler to store it's address. */
324 const arch_register_t *in1 = get_in_reg(n, 2);
325 ir_mode *mode = get_ia32_res_mode(n);
327 mode = mode ? mode : get_ia32_ls_mode(n);
328 lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%s, %%%s",
329 ia32_emit_am(n, env), ia32_get_reg_name_for_mode(env, mode, in1));
333 assert(0 && "unsupported op type");
336 #undef PRODUCES_RESULT
342 * Emits registers and/or address mode of a unary operation.
344 char *ia32_emit_unop(const ir_node *n, ia32_emit_env_t *env) {
345 static char *buf = NULL;
348 buf = xcalloc(1, SNPRINTF_BUF_LEN);
351 memset(buf, 0, SNPRINTF_BUF_LEN);
354 switch(get_ia32_op_type(n)) {
356 if (is_ia32_ImmConst(n) || is_ia32_ImmSymConst(n)) {
357 lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%C", n);
360 lc_esnprintf(ia32_get_arg_env(), buf, SNPRINTF_BUF_LEN, "%1D", n);
364 snprintf(buf, SNPRINTF_BUF_LEN, ia32_emit_am(n, env));
367 assert(0 && "unsupported op type");
374 * Emits address mode.
376 char *ia32_emit_am(const ir_node *n, ia32_emit_env_t *env) {
377 ia32_am_flavour_t am_flav = get_ia32_am_flavour(n);
381 static struct obstack *obst = NULL;
382 ir_mode *mode = get_ia32_ls_mode(n);
384 if (! is_ia32_Lea(n))
385 assert(mode && "AM node must have ls_mode attribute set.");
388 obst = xcalloc(1, sizeof(*obst));
391 obstack_free(obst, NULL);
394 /* obstack_free with NULL results in an uninitialized obstack */
398 switch (get_mode_size_bits(mode)) {
400 obstack_printf(obst, "BYTE PTR ");
403 obstack_printf(obst, "WORD PTR ");
406 obstack_printf(obst, "DWORD PTR ");
413 obstack_printf(obst, "[");
415 if (am_flav & ia32_B) {
416 lc_eoprintf(ia32_get_arg_env(), obst, "%1S", n);
420 if (am_flav & ia32_I) {
422 obstack_printf(obst, "+");
425 lc_eoprintf(ia32_get_arg_env(), obst, "%2S", n);
427 if (am_flav & ia32_S) {
428 obstack_printf(obst, "*%d", 1 << get_ia32_am_scale(n));
434 if (am_flav & ia32_O) {
435 s = get_ia32_am_offs(n);
437 /* omit exlicit + if there was no base or index */
438 if (! had_output && s[0] == '+')
441 obstack_printf(obst, s);
444 obstack_printf(obst, "] ");
446 size = obstack_object_size(obst);
447 s = obstack_finish(obst);
456 * Formated print of commands and comments.
458 static void ia32_fprintf_format(FILE *F, const ir_node *irn, char *cmd_buf, char *cmnt_buf) {
460 const char *name = irn ? be_retrieve_dbg_info(get_irn_dbg_info((ir_node *)irn), &lineno) : NULL;
463 fprintf(F, "\t%-35s %-60s /* %s:%u */\n", cmd_buf, cmnt_buf, name, lineno);
465 fprintf(F, "\t%-35s %-60s\n", cmd_buf, cmnt_buf);
471 * Add a number to a prefix. This number will not be used a second time.
473 static char *get_unique_label(char *buf, size_t buflen, const char *prefix) {
474 static unsigned long id = 0;
475 snprintf(buf, buflen, "%s%lu", prefix, ++id);
481 /*************************************************
484 * ___ _ __ ___ _| |_ ___ ___ _ __ __| |
485 * / _ \ '_ ` _ \| | __| / __/ _ \| '_ \ / _` |
486 * | __/ | | | | | | |_ | (_| (_) | | | | (_| |
487 * \___|_| |_| |_|_|\__| \___\___/|_| |_|\__,_|
489 *************************************************/
492 #define IA32_DO_EMIT(irn) ia32_fprintf_format(F, irn, cmd_buf, cmnt_buf)
495 * coding of conditions
497 struct cmp2conditon_t {
503 * positive conditions for signed compares
505 static const struct cmp2conditon_t cmp2condition_s[] = {
506 { NULL, pn_Cmp_False }, /* always false */
507 { "e", pn_Cmp_Eq }, /* == */
508 { "l", pn_Cmp_Lt }, /* < */
509 { "le", pn_Cmp_Le }, /* <= */
510 { "g", pn_Cmp_Gt }, /* > */
511 { "ge", pn_Cmp_Ge }, /* >= */
512 { "ne", pn_Cmp_Lg }, /* != */
513 { "ordered", pn_Cmp_Leg }, /* Floating point: ordered */
514 { "unordered", pn_Cmp_Uo }, /* FLoting point: unordered */
515 { "unordered or ==", pn_Cmp_Ue }, /* Floating point: unordered or == */
516 { "unordered or <", pn_Cmp_Ul }, /* Floating point: unordered or < */
517 { "unordered or <=", pn_Cmp_Ule }, /* Floating point: unordered or <= */
518 { "unordered or >", pn_Cmp_Ug }, /* Floating point: unordered or > */
519 { "unordered or >=", pn_Cmp_Uge }, /* Floating point: unordered or >= */
520 { "unordered or !=", pn_Cmp_Ne }, /* Floating point: unordered or != */
521 { NULL, pn_Cmp_True }, /* always true */
525 * positive conditions for unsigned compares
527 static const struct cmp2conditon_t cmp2condition_u[] = {
528 { NULL, pn_Cmp_False }, /* always false */
529 { "e", pn_Cmp_Eq }, /* == */
530 { "b", pn_Cmp_Lt }, /* < */
531 { "be", pn_Cmp_Le }, /* <= */
532 { "a", pn_Cmp_Gt }, /* > */
533 { "ae", pn_Cmp_Ge }, /* >= */
534 { "ne", pn_Cmp_Lg }, /* != */
535 { "ordered", pn_Cmp_Leg }, /* Floating point: ordered */
536 { "unordered", pn_Cmp_Uo }, /* FLoting point: unordered */
537 { "unordered or ==", pn_Cmp_Ue }, /* Floating point: unordered or == */
538 { "unordered or <", pn_Cmp_Ul }, /* Floating point: unordered or < */
539 { "unordered or <=", pn_Cmp_Ule }, /* Floating point: unordered or <= */
540 { "unordered or >", pn_Cmp_Ug }, /* Floating point: unordered or > */
541 { "unordered or >=", pn_Cmp_Uge }, /* Floating point: unordered or >= */
542 { "unordered or !=", pn_Cmp_Ne }, /* Floating point: unordered or != */
543 { NULL, pn_Cmp_True }, /* always true */
547 * returns the condition code
549 static const char *get_cmp_suffix(int cmp_code, int unsigned_cmp)
551 assert(cmp2condition_s[cmp_code].num == cmp_code);
552 assert(cmp2condition_u[cmp_code].num == cmp_code);
554 return unsigned_cmp ? cmp2condition_u[cmp_code & 7].name : cmp2condition_s[cmp_code & 7].name;
558 * Returns the target block for a control flow node.
560 static ir_node *get_cfop_target_block(const ir_node *irn) {
561 return get_irn_link(irn);
565 * Returns the target label for a control flow node.
567 static char *get_cfop_target(const ir_node *irn, char *buf) {
568 ir_node *bl = get_cfop_target_block(irn);
570 snprintf(buf, SNPRINTF_BUF_LEN, BLOCK_PREFIX("%ld"), get_irn_node_nr(bl));
574 /** Return the next block in Block schedule */
575 static ir_node *next_blk_sched(const ir_node *block) {
576 return have_block_sched ? get_irn_link(block) : NULL;
580 * Emits the jump sequence for a conditional jump (cmp + jmp_true + jmp_false)
582 static void finish_CondJmp(FILE *F, const ir_node *irn, ir_mode *mode) {
583 const ir_node *proj1, *proj2 = NULL;
584 const ir_node *block, *next_bl = NULL;
585 const ir_edge_t *edge;
586 char buf[SNPRINTF_BUF_LEN];
587 char cmd_buf[SNPRINTF_BUF_LEN];
588 char cmnt_buf[SNPRINTF_BUF_LEN];
590 /* get both Proj's */
591 edge = get_irn_out_edge_first(irn);
592 proj1 = get_edge_src_irn(edge);
593 assert(is_Proj(proj1) && "CondJmp with a non-Proj");
595 edge = get_irn_out_edge_next(irn, edge);
597 proj2 = get_edge_src_irn(edge);
598 assert(is_Proj(proj2) && "CondJmp with a non-Proj");
601 /* for now, the code works for scheduled and non-schedules blocks */
602 block = get_nodes_block(irn);
604 /* we have a block schedule */
605 next_bl = next_blk_sched(block);
607 if (get_cfop_target_block(proj1) == next_bl) {
608 /* exchange both proj's so the second one can be omitted */
609 const ir_node *t = proj1;
615 /* the first Proj must always be created */
616 if (get_Proj_proj(proj1) == pn_Cond_true) {
617 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "j%s %s",
618 get_cmp_suffix(get_ia32_pncode(irn), !mode_is_signed(get_irn_mode(get_irn_n(irn, 0)))),
619 get_cfop_target(proj1, buf));
620 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* cmp(a, b) == TRUE */");
623 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "j%s %s",
624 get_cmp_suffix(get_negated_pnc(get_ia32_pncode(irn), mode),
625 !mode_is_signed(get_irn_mode(get_irn_n(irn, 0)))),
626 get_cfop_target(proj1, buf));
627 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* cmp(a, b) == FALSE */");
631 /* the second Proj might be a fallthrough */
633 if (get_cfop_target_block(proj2) != next_bl) {
634 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "jmp %s", get_cfop_target(proj2, buf));
635 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* otherwise */");
639 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* fallthrogh %s */", get_cfop_target(proj2, buf));
646 * Emits code for conditional jump.
648 static void CondJmp_emitter(const ir_node *irn, ia32_emit_env_t *env) {
650 char cmd_buf[SNPRINTF_BUF_LEN];
651 char cmnt_buf[SNPRINTF_BUF_LEN];
653 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "cmp %s", ia32_emit_binop(irn, env));
654 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F */", irn);
656 finish_CondJmp(F, irn, get_irn_mode(get_irn_n(irn, 2)));
660 * Emits code for conditional jump with two variables.
662 static void emit_ia32_CondJmp(const ir_node *irn, ia32_emit_env_t *env) {
663 CondJmp_emitter(irn, env);
667 * Emits code for conditional jump with immediate.
669 static void emit_ia32_CondJmp_i(const ir_node *irn, ia32_emit_env_t *env) {
670 CondJmp_emitter(irn, env);
674 * Emits code for conditional test and jump.
676 static void TestJmp_emitter(const ir_node *irn, ia32_emit_env_t *env) {
678 #define IA32_IS_IMMOP (is_ia32_ImmConst(irn) || is_ia32_ImmSymConst(irn))
681 const char *op1 = arch_register_get_name(get_in_reg(irn, 0));
682 const char *op2 = IA32_IS_IMMOP ? get_ia32_cnst(irn) : NULL;
683 char cmd_buf[SNPRINTF_BUF_LEN];
684 char cmnt_buf[SNPRINTF_BUF_LEN];
687 op2 = arch_register_get_name(get_in_reg(irn, 1));
689 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "test %%%s,%s%s ", op1, IA32_IS_IMMOP ? " " : " %", op2);
690 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F */", irn);
693 finish_CondJmp(F, irn, get_irn_mode(get_irn_n(irn, 0)));
699 * Emits code for conditional test and jump with two variables.
701 static void emit_ia32_TestJmp(const ir_node *irn, ia32_emit_env_t *env) {
702 TestJmp_emitter(irn, env);
705 static void emit_ia32_CJmp(const ir_node *irn, ia32_emit_env_t *env) {
707 char cmd_buf[SNPRINTF_BUF_LEN];
708 char cmnt_buf[SNPRINTF_BUF_LEN];
710 snprintf(cmd_buf, SNPRINTF_BUF_LEN, " ");
711 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F omitted redundant test/cmp */", irn);
713 finish_CondJmp(F, irn, get_irn_mode(get_irn_n(irn, 0)));
716 static void emit_ia32_CJmpAM(const ir_node *irn, ia32_emit_env_t *env) {
718 char cmd_buf[SNPRINTF_BUF_LEN];
719 char cmnt_buf[SNPRINTF_BUF_LEN];
721 snprintf(cmd_buf, SNPRINTF_BUF_LEN, " ");
722 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F omitted redundant test/cmp */", irn);
724 finish_CondJmp(F, irn, get_irn_mode(get_irn_n(irn, 2)));
727 /*********************************************************
730 * ___ _ __ ___ _| |_ _ _ _ _ __ ___ _ __ ___
731 * / _ \ '_ ` _ \| | __| | | | | | '_ ` _ \| '_ \/ __|
732 * | __/ | | | | | | |_ | | |_| | | | | | | |_) \__ \
733 * \___|_| |_| |_|_|\__| | |\__,_|_| |_| |_| .__/|___/
736 *********************************************************/
738 /* jump table entry (target and corresponding number) */
739 typedef struct _branch_t {
744 /* jump table for switch generation */
745 typedef struct _jmp_tbl_t {
746 ir_node *defProj; /**< default target */
747 int min_value; /**< smallest switch case */
748 int max_value; /**< largest switch case */
749 int num_branches; /**< number of jumps */
750 char *label; /**< label of the jump table */
751 branch_t *branches; /**< jump array */
755 * Compare two variables of type branch_t. Used to sort all switch cases
757 static int ia32_cmp_branch_t(const void *a, const void *b) {
758 branch_t *b1 = (branch_t *)a;
759 branch_t *b2 = (branch_t *)b;
761 if (b1->value <= b2->value)
768 * Emits code for a SwitchJmp (creates a jump table if
769 * possible otherwise a cmp-jmp cascade). Port from
772 static void emit_ia32_SwitchJmp(const ir_node *irn, ia32_emit_env_t *emit_env) {
773 unsigned long interval;
774 char buf[SNPRINTF_BUF_LEN];
775 int last_value, i, pn, do_jmp_tbl = 1;
778 const ir_edge_t *edge;
779 const lc_arg_env_t *env = ia32_get_arg_env();
780 FILE *F = emit_env->out;
781 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
783 /* fill the table structure */
784 tbl.label = xmalloc(SNPRINTF_BUF_LEN);
785 tbl.label = get_unique_label(tbl.label, SNPRINTF_BUF_LEN, "JMPTBL_");
787 tbl.num_branches = get_irn_n_edges(irn);
788 tbl.branches = xcalloc(tbl.num_branches, sizeof(tbl.branches[0]));
789 tbl.min_value = INT_MAX;
790 tbl.max_value = INT_MIN;
793 /* go over all proj's and collect them */
794 foreach_out_edge(irn, edge) {
795 proj = get_edge_src_irn(edge);
796 assert(is_Proj(proj) && "Only proj allowed at SwitchJmp");
798 pn = get_Proj_proj(proj);
800 /* create branch entry */
801 tbl.branches[i].target = proj;
802 tbl.branches[i].value = pn;
804 tbl.min_value = pn < tbl.min_value ? pn : tbl.min_value;
805 tbl.max_value = pn > tbl.max_value ? pn : tbl.max_value;
807 /* check for default proj */
808 if (pn == get_ia32_pncode(irn)) {
809 assert(tbl.defProj == NULL && "found two defProjs at SwitchJmp");
816 /* sort the branches by their number */
817 qsort(tbl.branches, tbl.num_branches, sizeof(tbl.branches[0]), ia32_cmp_branch_t);
819 /* two-complement's magic make this work without overflow */
820 interval = tbl.max_value - tbl.min_value;
822 /* check value interval */
823 if (interval > 16 * 1024) {
827 /* check ratio of value interval to number of branches */
828 if ((float)(interval + 1) / (float)tbl.num_branches > 8.0) {
834 if (tbl.min_value != 0) {
835 lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "cmpl %lu, -%d(%1S)",
836 interval, tbl.min_value, irn);
837 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* first switch value is not 0 */");
842 lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "cmpl %lu, %1S", interval, irn);
843 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* compare for switch */");
848 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "ja %s", get_cfop_target(tbl.defProj, buf));
849 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* default jump if out of range */");
852 if (tbl.num_branches > 1) {
855 lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "jmp [%1S*4+%s]", irn, tbl.label);
856 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* get jump table entry as target */");
859 fprintf(F, "\t.section\t.rodata\n");
860 fprintf(F, "\t.align 4\n");
862 fprintf(F, "%s:\n", tbl.label);
864 snprintf(cmd_buf, SNPRINTF_BUF_LEN, ".long %s", get_cfop_target(tbl.branches[0].target, buf));
865 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* case %d */\n", tbl.branches[0].value);
868 last_value = tbl.branches[0].value;
869 for (i = 1; i < tbl.num_branches; ++i) {
870 while (++last_value < tbl.branches[i].value) {
871 snprintf(cmd_buf, SNPRINTF_BUF_LEN, ".long %s", get_cfop_target(tbl.defProj, buf));
872 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* default case */");
875 snprintf(cmd_buf, SNPRINTF_BUF_LEN, ".long %s", get_cfop_target(tbl.branches[i].target, buf));
876 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* case %d */", last_value);
880 fprintf(F, "\t.text");
883 /* one jump is enough */
884 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "jmp %s", get_cfop_target(tbl.branches[0].target, buf));
885 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* only one case given */");
889 else { // no jump table
890 for (i = 0; i < tbl.num_branches; ++i) {
891 lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "cmpl %d, %1S", tbl.branches[i].value, irn);
892 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* case %d */", i);
894 fprintf(F, "\tje %s\n", get_cfop_target(tbl.branches[i].target, buf));
897 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "jmp %s", get_cfop_target(tbl.defProj, buf));
898 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* default case */");
909 * Emits code for a unconditional jump.
911 static void emit_Jmp(const ir_node *irn, ia32_emit_env_t *env) {
912 ir_node *block, *next_bl;
914 char buf[SNPRINTF_BUF_LEN], cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
916 /* for now, the code works for scheduled and non-schedules blocks */
917 block = get_nodes_block(irn);
919 /* we have a block schedule */
920 next_bl = next_blk_sched(block);
921 if (get_cfop_target_block(irn) != next_bl) {
922 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "jmp %s", get_cfop_target(irn, buf));
923 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F(%+F) */", irn, get_cfop_target_block(irn));
927 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* fallthrough %s */", get_cfop_target(irn, buf));
932 /****************************
935 * _ __ _ __ ___ _ ___
936 * | '_ \| '__/ _ \| |/ __|
937 * | |_) | | | (_) | |\__ \
938 * | .__/|_| \___/| ||___/
941 ****************************/
944 * Emits code for a proj -> node
946 static void emit_Proj(const ir_node *irn, ia32_emit_env_t *env) {
947 ir_node *pred = get_Proj_pred(irn);
949 if (get_irn_op(pred) == op_Start) {
950 switch(get_Proj_proj(irn)) {
951 case pn_Start_X_initial_exec:
960 /**********************************
963 * | | ___ _ __ _ _| |_) |
964 * | | / _ \| '_ \| | | | _ <
965 * | |___| (_) | |_) | |_| | |_) |
966 * \_____\___/| .__/ \__, |____/
969 **********************************/
972 * Emit movsb/w instructions to make mov count divideable by 4
974 static void emit_CopyB_prolog(FILE *F, int rem, int size) {
975 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
977 fprintf(F, "\t/* memcopy %d bytes*/\n", size);
979 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "cld");
980 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* copy direction forward*/");
985 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsb");
986 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy remainder 1 */");
989 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsw");
990 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy remainder 2 */");
993 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsb");
994 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy remainder 3 */");
996 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsw");
997 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy remainder 3 */");
1005 * Emit rep movsd instruction for memcopy.
1007 static void emit_ia32_CopyB(const ir_node *irn, ia32_emit_env_t *emit_env) {
1008 FILE *F = emit_env->out;
1009 tarval *tv = get_ia32_Immop_tarval(irn);
1010 int rem = get_tarval_long(tv);
1011 int size = get_tarval_long(get_ia32_Immop_tarval(get_irn_n(irn, 2)));
1012 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
1014 emit_CopyB_prolog(F, rem, size);
1016 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "rep movsd");
1017 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy */");
1022 * Emits unrolled memcopy.
1024 static void emit_ia32_CopyB_i(const ir_node *irn, ia32_emit_env_t *emit_env) {
1025 tarval *tv = get_ia32_Immop_tarval(irn);
1026 int size = get_tarval_long(tv);
1027 FILE *F = emit_env->out;
1028 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
1030 emit_CopyB_prolog(F, size & 0x3, size);
1034 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "movsd");
1035 snprintf(cmnt_buf, SNPRINTF_BUF_LEN, "/* memcopy unrolled */");
1042 /***************************
1046 * | | / _ \| '_ \ \ / /
1047 * | |___| (_) | | | \ V /
1048 * \_____\___/|_| |_|\_/
1050 ***************************/
1053 * Emit code for conversions (I, FP), (FP, I) and (FP, FP).
1055 static void emit_ia32_Conv_with_FP(const ir_node *irn, ia32_emit_env_t *emit_env) {
1056 FILE *F = emit_env->out;
1057 const lc_arg_env_t *env = ia32_get_arg_env();
1058 char *from, *to, buf[64];
1059 ir_mode *src_mode, *tgt_mode;
1060 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
1062 src_mode = is_ia32_AddrModeS(irn) ? get_ia32_ls_mode(irn) : get_irn_mode(get_irn_n(irn, 2));
1063 tgt_mode = get_ia32_res_mode(irn);
1065 from = mode_is_float(src_mode) ? (get_mode_size_bits(src_mode) == 32 ? "ss" : "sd") : "si";
1066 to = mode_is_float(tgt_mode) ? (get_mode_size_bits(tgt_mode) == 32 ? "ss" : "sd") : "si";
1068 switch(get_ia32_op_type(irn)) {
1070 lc_esnprintf(env, buf, sizeof(buf), "%1D, %3S", irn, irn);
1072 case ia32_AddrModeS:
1073 lc_esnprintf(env, buf, sizeof(buf), "%1D, %s", irn, ia32_emit_am(irn, emit_env));
1076 assert(0 && "unsupported op type for Conv");
1079 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "cvt%s2%s %s", from, to, buf);
1080 lc_esnprintf(env, cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F(%+F, %+F) */", irn, src_mode, tgt_mode);
1084 static void emit_ia32_Conv_I2FP(const ir_node *irn, ia32_emit_env_t *emit_env) {
1085 emit_ia32_Conv_with_FP(irn, emit_env);
1088 static void emit_ia32_Conv_FP2I(const ir_node *irn, ia32_emit_env_t *emit_env) {
1089 emit_ia32_Conv_with_FP(irn, emit_env);
1092 static void emit_ia32_Conv_FP2FP(const ir_node *irn, ia32_emit_env_t *emit_env) {
1093 emit_ia32_Conv_with_FP(irn, emit_env);
1097 * Emits code for an Int conversion.
1099 static void emit_ia32_Conv_I2I(const ir_node *irn, ia32_emit_env_t *emit_env) {
1100 FILE *F = emit_env->out;
1101 const lc_arg_env_t *env = ia32_get_arg_env();
1102 char *move_cmd, *conv_cmd;
1103 ir_mode *src_mode, *tgt_mode;
1105 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
1106 const arch_register_t *in_reg, *out_reg;
1108 src_mode = is_ia32_AddrModeS(irn) ? get_ia32_ls_mode(irn) : get_irn_mode(get_irn_n(irn, 2));
1109 tgt_mode = get_ia32_res_mode(irn);
1111 n = get_mode_size_bits(src_mode);
1112 m = get_mode_size_bits(tgt_mode);
1114 if (mode_is_signed(n < m ? src_mode : tgt_mode)) {
1116 if (n == 8 || m == 8)
1118 else if (n == 16 || m == 16)
1121 assert(0 && "unsupported Conv_I2I");
1128 switch(get_ia32_op_type(irn)) {
1130 in_reg = get_in_reg(irn, 2);
1131 out_reg = get_out_reg(irn, 0);
1133 if (REGS_ARE_EQUAL(in_reg, &ia32_gp_regs[REG_EAX]) &&
1134 REGS_ARE_EQUAL(out_reg, in_reg) &&
1135 mode_is_signed(n < m ? src_mode : tgt_mode))
1137 /* argument and result are both in EAX and */
1138 /* signedness is ok: -> use converts */
1139 lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "%s", conv_cmd);
1141 else if (REGS_ARE_EQUAL(out_reg, in_reg) &&
1142 ! mode_is_signed(n < m ? src_mode : tgt_mode))
1144 /* argument and result are in the same register */
1145 /* and signedness is ok: -> use and with mask */
1146 int mask = (1 << (n < m ? n : m)) - 1;
1147 lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "and %1D, 0x%x", irn, mask);
1150 /* use move w/o sign extension */
1151 lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "%s %1D, %%%s",
1152 move_cmd, irn, ia32_get_reg_name_for_mode(emit_env, n < m ? src_mode : tgt_mode, in_reg));
1156 case ia32_AddrModeS:
1157 lc_esnprintf(env, cmd_buf, SNPRINTF_BUF_LEN, "%s %1D, %s",
1158 move_cmd, irn, ia32_emit_am(irn, emit_env));
1161 assert(0 && "unsupported op type for Conv");
1164 lc_esnprintf(env, cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F(%d Bit mode_%F -> %d Bit mode_%F) */",
1165 irn, n, src_mode, m, tgt_mode);
1171 * Emits code for an 8Bit Int conversion.
1173 void emit_ia32_Conv_I2I8Bit(const ir_node *irn, ia32_emit_env_t *emit_env) {
1174 emit_ia32_Conv_I2I(irn, emit_env);
1178 /*******************************************
1181 * | |__ ___ _ __ ___ __| | ___ ___
1182 * | '_ \ / _ \ '_ \ / _ \ / _` |/ _ \/ __|
1183 * | |_) | __/ | | | (_) | (_| | __/\__ \
1184 * |_.__/ \___|_| |_|\___/ \__,_|\___||___/
1186 *******************************************/
1189 * Emits a backend call
1191 static void emit_be_Call(const ir_node *irn, ia32_emit_env_t *emit_env) {
1192 FILE *F = emit_env->out;
1193 entity *ent = be_Call_get_entity(irn);
1194 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
1197 snprintf(cmd_buf, SNPRINTF_BUF_LEN, "call %s", get_entity_name(ent));
1200 lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "%1D", get_irn_n(irn, be_pos_Call_ptr));
1203 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F (be_Call) */", irn);
1209 * Emits code to increase stack pointer.
1211 static void emit_be_IncSP(const ir_node *irn, ia32_emit_env_t *emit_env) {
1212 FILE *F = emit_env->out;
1213 unsigned offs = be_get_IncSP_offset(irn);
1214 be_stack_dir_t dir = be_get_IncSP_direction(irn);
1215 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
1218 lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "add %1S,%s%u", irn,
1219 (dir == be_stack_dir_expand) ? " -" : " ", offs);
1220 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F (IncSP) */", irn);
1223 snprintf(cmd_buf, SNPRINTF_BUF_LEN, " ");
1224 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* omitted %+F (IncSP) with 0 */", irn);
1231 * Emits code to set stack pointer.
1233 static void emit_be_SetSP(const ir_node *irn, ia32_emit_env_t *emit_env) {
1234 FILE *F = emit_env->out;
1235 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
1237 lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "mov %1D, %3S", irn, irn);
1238 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F (restore SP) */", irn);
1243 * Emits code for Copy.
1245 static void emit_be_Copy(const ir_node *irn, ia32_emit_env_t *emit_env) {
1246 FILE *F = emit_env->out;
1247 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
1249 lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "mov %1D, %1S", irn, irn);
1250 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F */", irn);
1255 * Emits code for exchange.
1257 static void emit_be_Perm(const ir_node *irn, ia32_emit_env_t *emit_env) {
1258 FILE *F = emit_env->out;
1259 char cmd_buf[SNPRINTF_BUF_LEN], cmnt_buf[SNPRINTF_BUF_LEN];
1261 lc_esnprintf(ia32_get_arg_env(), cmd_buf, SNPRINTF_BUF_LEN, "xchg %1S, %2S", irn, irn);
1262 lc_esnprintf(ia32_get_arg_env(), cmnt_buf, SNPRINTF_BUF_LEN, "/* %+F(%1A, %2A) */", irn, irn, irn);
1266 /***********************************************************************************
1269 * _ __ ___ __ _ _ _ __ | |_ _ __ __ _ _ __ ___ _____ _____ _ __| | __
1270 * | '_ ` _ \ / _` | | '_ \ | _| '__/ _` | '_ ` _ \ / _ \ \ /\ / / _ \| '__| |/ /
1271 * | | | | | | (_| | | | | | | | | | | (_| | | | | | | __/\ V V / (_) | | | <
1272 * |_| |_| |_|\__,_|_|_| |_| |_| |_| \__,_|_| |_| |_|\___| \_/\_/ \___/|_| |_|\_\
1274 ***********************************************************************************/
1277 * Enters the emitter functions for handled nodes into the generic
1278 * pointer of an opcode.
1280 static void ia32_register_emitters(void) {
1282 #define IA32_EMIT(a) op_ia32_##a->ops.generic = (op_func)emit_ia32_##a
1283 #define EMIT(a) op_##a->ops.generic = (op_func)emit_##a
1284 #define BE_EMIT(a) op_be_##a->ops.generic = (op_func)emit_be_##a
1286 /* first clear the generic function pointer for all ops */
1287 clear_irp_opcodes_generic_func();
1289 /* register all emitter functions defined in spec */
1290 ia32_register_spec_emitters();
1292 /* other ia32 emitter functions */
1297 IA32_EMIT(SwitchJmp);
1300 IA32_EMIT(Conv_I2FP);
1301 IA32_EMIT(Conv_FP2I);
1302 IA32_EMIT(Conv_FP2FP);
1303 IA32_EMIT(Conv_I2I);
1304 IA32_EMIT(Conv_I2I8Bit);
1306 /* benode emitter */
1323 * Emits code for a node.
1325 static void ia32_emit_node(const ir_node *irn, void *env) {
1326 ia32_emit_env_t *emit_env = env;
1327 firm_dbg_module_t *mod = emit_env->mod;
1328 FILE *F = emit_env->out;
1329 ir_op *op = get_irn_op(irn);
1331 DBG((mod, LEVEL_1, "emitting code for %+F\n", irn));
1333 if (op->ops.generic) {
1334 void (*emit)(const ir_node *, void *) = (void (*)(const ir_node *, void *))op->ops.generic;
1338 ir_fprintf(F, "\t%35s /* %+F */\n", " ", irn);
1343 * Walks over the nodes in a block connected by scheduling edges
1344 * and emits code for each node.
1346 static void ia32_gen_block(ir_node *block, void *env) {
1349 if (! is_Block(block))
1352 fprintf(((ia32_emit_env_t *)env)->out, BLOCK_PREFIX("%ld:\n"), get_irn_node_nr(block));
1353 sched_foreach(block, irn) {
1354 ia32_emit_node(irn, env);
1359 * Emits code for function start.
1361 static void ia32_emit_func_prolog(FILE *F, ir_graph *irg) {
1362 entity *irg_ent = get_irg_entity(irg);
1363 const char *irg_name = get_entity_name(irg_ent);
1365 fprintf(F, "\t.text\n");
1366 if (get_entity_visibility(irg_ent) == visibility_external_visible) {
1367 fprintf(F, ".globl %s\n", irg_name);
1369 fprintf(F, "\t.type\t%s, @function\n", irg_name);
1370 fprintf(F, "%s:\n", irg_name);
1374 * Emits code for function end
1376 static void ia32_emit_func_epilog(FILE *F, ir_graph *irg) {
1377 const char *irg_name = get_entity_name(get_irg_entity(irg));
1379 fprintf(F, "\tret\n");
1380 fprintf(F, "\t.size\t%s, .-%s\n\n", irg_name, irg_name);
1385 * Sets labels for control flow nodes (jump target)
1386 * TODO: Jump optimization
1388 static void ia32_gen_labels(ir_node *block, void *env) {
1390 int n = get_Block_n_cfgpreds(block);
1392 for (n--; n >= 0; n--) {
1393 pred = get_Block_cfgpred(block, n);
1394 set_irn_link(pred, block);
1404 * Ext-Block walker: create a block schedule
1406 static void create_block_list(ir_extblk *blk, void *env) {
1410 for (i = 0, n = get_extbb_n_blocks(blk); i < n; ++i) {
1411 ir_node *block = get_extbb_block(blk, i);
1413 set_irn_link(block, NULL);
1415 set_irn_link(list->end, block);
1417 list->start = block;
1424 * Main driver. Emits the code for one routine.
1426 void ia32_gen_routine(FILE *F, ir_graph *irg, const ia32_code_gen_t *cg) {
1427 ia32_emit_env_t emit_env;
1431 emit_env.mod = firm_dbg_register("firm.be.ia32.emitter");
1433 emit_env.arch_env = cg->arch_env;
1435 emit_env.isa = (ia32_isa_t *)cg->arch_env->isa;
1437 /* set the global arch_env (needed by print hooks) */
1438 arch_env = cg->arch_env;
1440 ia32_register_emitters();
1442 ia32_emit_func_prolog(F, irg);
1443 irg_block_walk_graph(irg, ia32_gen_labels, NULL, &emit_env);
1445 if (cg->opt.extbb) {
1446 /* schedule extended basic blocks */
1452 irg_extblock_walk_graph(irg, NULL, create_block_list, &list);
1454 have_block_sched = 1;
1455 for (block = list.start; block; block = get_irn_link(block))
1456 ia32_gen_block(block, &emit_env);
1459 /* "normal" block schedule */
1461 have_block_sched = 0;
1462 irg_walk_blkwise_graph(irg, NULL, ia32_gen_block, &emit_env);
1465 ia32_emit_func_epilog(F, irg);