2 * Copyright (C) 1995-2008 University of Karlsruhe. All right reserved.
4 * This file is part of libFirm.
6 * This file may be distributed and/or modified under the terms of the
7 * GNU General Public License version 2 as published by the Free Software
8 * Foundation and appearing in the file LICENSE.GPL included in the
9 * packaging of this file.
11 * Licensees holding valid libFirm Professional Edition licenses may use
12 * this file in accordance with the libFirm Commercial License.
13 * Agreement provided with the Software.
15 * This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
16 * WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR
22 * @brief Backend ABI implementation.
23 * @author Sebastian Hack, Michael Beck
33 #include "irgraph_t.h"
36 #include "iredges_t.h"
39 #include "irprintf_t.h"
45 #include "raw_bitset.h"
54 #include "besched_t.h"
56 #include "bessaconstr.h"
58 typedef struct _be_abi_call_arg_t {
59 unsigned is_res : 1; /**< 1: the call argument is a return value. 0: it's a call parameter. */
60 unsigned in_reg : 1; /**< 1: this argument is transmitted in registers. */
61 unsigned on_stack : 1; /**< 1: this argument is transmitted on the stack. */
64 const arch_register_t *reg;
67 unsigned alignment; /**< stack alignment */
68 unsigned space_before; /**< allocate space before */
69 unsigned space_after; /**< allocate space after */
72 struct _be_abi_call_t {
73 be_abi_call_flags_t flags; /**< Flags describing the ABI behavior on calls */
74 int pop; /**< number of bytes the stack frame is shrinked by the callee on return. */
75 const be_abi_callbacks_t *cb;
76 ir_type *between_type;
78 const arch_register_class_t *cls_addr; /**< register class of the call address */
82 * The ABI information for the current birg.
84 struct _be_abi_irg_t {
86 be_irg_t *birg; /**< The back end IRG. */
87 const arch_env_t *arch_env;
88 survive_dce_t *dce_survivor;
90 be_abi_call_t *call; /**< The ABI call information. */
91 ir_type *method_type; /**< The type of the method of the IRG. */
93 ir_node *init_sp; /**< The node representing the stack pointer
94 at the start of the function. */
96 ir_node *reg_params; /**< The reg params node. */
97 pmap *regs; /**< A map of all callee-save and ignore regs to
98 their Projs to the RegParams node. */
100 int start_block_bias; /**< The stack bias at the end of the start block. */
102 void *cb; /**< ABI Callback self pointer. */
104 pmap *keep_map; /**< mapping blocks to keep nodes. */
105 pset *ignore_regs; /**< Additional registers which shall be ignored. */
107 ir_node **calls; /**< flexible array containing all be_Call nodes */
109 arch_register_req_t sp_req;
110 arch_register_req_t sp_cls_req;
112 be_stack_layout_t frame; /**< The stack frame model. */
114 DEBUG_ONLY(firm_dbg_module_t *dbg;) /**< The debugging module. */
117 static heights_t *ir_heights;
119 /** Flag: if set, try to omit the frame pointer in all routines. */
120 static int be_omit_fp = 1;
122 /** Flag: if set, try to omit the frame pointer in leaf routines only. */
123 static int be_omit_leaf_fp = 1;
126 _ ____ ___ ____ _ _ _ _
127 / \ | __ )_ _| / ___|__ _| | | |__ __ _ ___| | _____
128 / _ \ | _ \| | | | / _` | | | '_ \ / _` |/ __| |/ / __|
129 / ___ \| |_) | | | |__| (_| | | | |_) | (_| | (__| <\__ \
130 /_/ \_\____/___| \____\__,_|_|_|_.__/ \__,_|\___|_|\_\___/
132 These callbacks are used by the backend to set the parameters
133 for a specific call type.
137 * Set compare function: compares two ABI call object arguments.
139 static int cmp_call_arg(const void *a, const void *b, size_t n)
141 const be_abi_call_arg_t *p = a, *q = b;
143 return !(p->is_res == q->is_res && p->pos == q->pos);
147 * Get an ABI call object argument.
149 * @param call the abi call
150 * @param is_res true for call results, false for call arguments
151 * @param pos position of the argument
153 static be_abi_call_arg_t *get_call_arg(be_abi_call_t *call, int is_res, int pos)
155 be_abi_call_arg_t arg;
158 memset(&arg, 0, sizeof(arg));
162 hash = is_res * 128 + pos;
164 return set_find(call->params, &arg, sizeof(arg), hash);
168 * Set an ABI call object argument.
170 * @param call the abi call
171 * @param is_res true for call results, false for call arguments
172 * @param pos position of the argument
174 static be_abi_call_arg_t *create_call_arg(be_abi_call_t *call, int is_res, int pos)
176 be_abi_call_arg_t arg;
179 memset(&arg, 0, sizeof(arg));
183 hash = is_res * 128 + pos;
185 return set_insert(call->params, &arg, sizeof(arg), hash);
188 /* Set the flags for a call. */
189 void be_abi_call_set_flags(be_abi_call_t *call, be_abi_call_flags_t flags, const be_abi_callbacks_t *cb)
195 /* Sets the number of bytes the stackframe is shrinked by the callee on return */
196 void be_abi_call_set_pop(be_abi_call_t *call, int pop)
202 /* Set register class for call address */
203 void be_abi_call_set_call_address_reg_class(be_abi_call_t *call, const arch_register_class_t *cls)
205 call->cls_addr = cls;
209 void be_abi_call_param_stack(be_abi_call_t *call, int arg_pos, ir_mode *load_mode, unsigned alignment, unsigned space_before, unsigned space_after)
211 be_abi_call_arg_t *arg = create_call_arg(call, 0, arg_pos);
213 arg->load_mode = load_mode;
214 arg->alignment = alignment;
215 arg->space_before = space_before;
216 arg->space_after = space_after;
217 assert(alignment > 0 && "Alignment must be greater than 0");
220 void be_abi_call_param_reg(be_abi_call_t *call, int arg_pos, const arch_register_t *reg)
222 be_abi_call_arg_t *arg = create_call_arg(call, 0, arg_pos);
227 void be_abi_call_res_reg(be_abi_call_t *call, int arg_pos, const arch_register_t *reg)
229 be_abi_call_arg_t *arg = create_call_arg(call, 1, arg_pos);
234 /* Get the flags of a ABI call object. */
235 be_abi_call_flags_t be_abi_call_get_flags(const be_abi_call_t *call)
241 * Constructor for a new ABI call object.
243 * @param cls_addr register class of the call address
245 * @return the new ABI call object
247 static be_abi_call_t *be_abi_call_new(const arch_register_class_t *cls_addr)
249 be_abi_call_t *call = XMALLOCZ(be_abi_call_t);
252 call->params = new_set(cmp_call_arg, 16);
254 call->cls_addr = cls_addr;
256 call->flags.bits.try_omit_fp = be_omit_fp | be_omit_leaf_fp;
262 * Destructor for an ABI call object.
264 static void be_abi_call_free(be_abi_call_t *call)
266 del_set(call->params);
272 | ___| __ __ _ _ __ ___ ___ | | | | __ _ _ __ __| | (_)_ __ __ _
273 | |_ | '__/ _` | '_ ` _ \ / _ \ | |_| |/ _` | '_ \ / _` | | | '_ \ / _` |
274 | _|| | | (_| | | | | | | __/ | _ | (_| | | | | (_| | | | | | | (_| |
275 |_| |_| \__,_|_| |_| |_|\___| |_| |_|\__,_|_| |_|\__,_|_|_|_| |_|\__, |
278 Handling of the stack frame. It is composed of three types:
279 1) The type of the arguments which are pushed on the stack.
280 2) The "between type" which consists of stuff the call of the
281 function pushes on the stack (like the return address and
282 the old base pointer for ia32).
283 3) The Firm frame type which consists of all local variables
287 static int get_stack_entity_offset(be_stack_layout_t *frame, ir_entity *ent,
290 ir_type *t = get_entity_owner(ent);
291 int ofs = get_entity_offset(ent);
295 /* Find the type the entity is contained in. */
296 for (index = 0; index < N_FRAME_TYPES; ++index) {
297 if (frame->order[index] == t)
299 /* Add the size of all the types below the one of the entity to the entity's offset */
300 ofs += get_type_size_bytes(frame->order[index]);
303 /* correct the offset by the initial position of the frame pointer */
304 ofs -= frame->initial_offset;
306 /* correct the offset with the current bias. */
313 * Retrieve the entity with given offset from a frame type.
315 static ir_entity *search_ent_with_offset(ir_type *t, int offset)
319 for (i = 0, n = get_compound_n_members(t); i < n; ++i) {
320 ir_entity *ent = get_compound_member(t, i);
321 if (get_entity_offset(ent) == offset)
328 static int stack_frame_compute_initial_offset(be_stack_layout_t *frame)
330 ir_type *base = frame->stack_dir < 0 ? frame->between_type : frame->frame_type;
331 ir_entity *ent = search_ent_with_offset(base, 0);
333 frame->initial_offset = ent ? get_stack_entity_offset(frame, ent, 0) : 0;
335 return frame->initial_offset;
339 * Initializes the frame layout from parts
341 * @param frame the stack layout that will be initialized
342 * @param args the stack argument layout type
343 * @param between the between layout type
344 * @param locals the method frame type
345 * @param stack_dir the stack direction: < 0 decreasing, > 0 increasing addresses
346 * @param param_map an array mapping method argument positions to the stack argument type
348 * @return the initialized stack layout
350 static be_stack_layout_t *stack_frame_init(be_stack_layout_t *frame, ir_type *args,
351 ir_type *between, ir_type *locals, int stack_dir,
352 ir_entity *param_map[])
354 frame->arg_type = args;
355 frame->between_type = between;
356 frame->frame_type = locals;
357 frame->initial_offset = 0;
358 frame->initial_bias = 0;
359 frame->stack_dir = stack_dir;
360 frame->order[1] = between;
361 frame->param_map = param_map;
364 frame->order[0] = args;
365 frame->order[2] = locals;
368 /* typical decreasing stack: locals have the
369 * lowest addresses, arguments the highest */
370 frame->order[0] = locals;
371 frame->order[2] = args;
377 /** Dumps the stack layout to file. */
378 static void stack_layout_dump(FILE *file, be_stack_layout_t *frame)
382 ir_fprintf(file, "initial offset: %d\n", frame->initial_offset);
383 for (j = 0; j < N_FRAME_TYPES; ++j) {
384 ir_type *t = frame->order[j];
386 ir_fprintf(file, "type %d: %F size: %d\n", j, t, get_type_size_bytes(t));
387 for (i = 0, n = get_compound_n_members(t); i < n; ++i) {
388 ir_entity *ent = get_compound_member(t, i);
389 ir_fprintf(file, "\t%F int ofs: %d glob ofs: %d\n", ent, get_entity_offset_bytes(ent), get_stack_entity_offset(frame, ent, 0));
396 * Returns non-zero if the call argument at given position
397 * is transfered on the stack.
399 static inline int is_on_stack(be_abi_call_t *call, int pos)
401 be_abi_call_arg_t *arg = get_call_arg(call, 0, pos);
402 return arg && !arg->in_reg;
412 Adjustment of the calls inside a graph.
417 * Transform a call node into a be_Call node.
419 * @param env The ABI environment for the current irg.
420 * @param irn The call node.
421 * @param curr_sp The stack pointer node to use.
422 * @return The stack pointer after the call.
424 static ir_node *adjust_call(be_abi_irg_t *env, ir_node *irn, ir_node *curr_sp)
426 ir_graph *irg = env->birg->irg;
427 const arch_env_t *arch_env = env->birg->main_env->arch_env;
428 ir_type *call_tp = get_Call_type(irn);
429 ir_node *call_ptr = get_Call_ptr(irn);
430 int n_params = get_method_n_params(call_tp);
431 ir_node *curr_mem = get_Call_mem(irn);
432 ir_node *bl = get_nodes_block(irn);
434 int stack_dir = arch_env->stack_dir;
435 const arch_register_t *sp = arch_env->sp;
436 be_abi_call_t *call = be_abi_call_new(sp->reg_class);
437 ir_mode *mach_mode = sp->reg_class->mode;
438 struct obstack *obst = &env->obst;
439 int no_alloc = call->flags.bits.frame_is_setup_on_call;
440 int n_res = get_method_n_ress(call_tp);
441 int do_seq = call->flags.bits.store_args_sequential && !no_alloc;
443 ir_node *res_proj = NULL;
444 int n_reg_params = 0;
445 int n_stack_params = 0;
448 pset_new_t destroyed_regs, states;
449 pset_new_iterator_t iter;
453 int n_reg_results = 0;
454 const arch_register_t *reg;
455 const ir_edge_t *edge;
457 int *stack_param_idx;
458 int i, n, destroy_all_regs;
461 pset_new_init(&destroyed_regs);
462 pset_new_init(&states);
464 /* Let the isa fill out the abi description for that call node. */
465 arch_env_get_call_abi(arch_env, call_tp, call);
467 /* Insert code to put the stack arguments on the stack. */
468 assert(get_Call_n_params(irn) == n_params);
469 for (i = 0; i < n_params; ++i) {
470 be_abi_call_arg_t *arg = get_call_arg(call, 0, i);
473 int arg_size = get_type_size_bytes(get_method_param_type(call_tp, i));
475 stack_size += round_up2(arg->space_before, arg->alignment);
476 stack_size += round_up2(arg_size, arg->alignment);
477 stack_size += round_up2(arg->space_after, arg->alignment);
478 obstack_int_grow(obst, i);
482 stack_param_idx = obstack_finish(obst);
484 /* Collect all arguments which are passed in registers. */
485 for (i = 0; i < n_params; ++i) {
486 be_abi_call_arg_t *arg = get_call_arg(call, 0, i);
487 if (arg && arg->in_reg) {
488 obstack_int_grow(obst, i);
492 reg_param_idxs = obstack_finish(obst);
495 * If the stack is decreasing and we do not want to store sequentially,
496 * or someone else allocated the call frame
497 * we allocate as much space on the stack all parameters need, by
498 * moving the stack pointer along the stack's direction.
500 * Note: we also have to do this for stack_size == 0, because we may have
501 * to adjust stack alignment for the call.
503 if (stack_dir < 0 && !do_seq && !no_alloc) {
504 curr_sp = be_new_IncSP(sp, irg, bl, curr_sp, stack_size, 1);
507 dbgi = get_irn_dbg_info(irn);
508 /* If there are some parameters which shall be passed on the stack. */
509 if (n_stack_params > 0) {
513 * Reverse list of stack parameters if call arguments are from left to right.
514 * We must them reverse again if they are pushed (not stored) and the stack
515 * direction is downwards.
517 if (call->flags.bits.left_to_right ^ (do_seq && stack_dir < 0)) {
518 for (i = 0; i < n_stack_params >> 1; ++i) {
519 int other = n_stack_params - i - 1;
520 int tmp = stack_param_idx[i];
521 stack_param_idx[i] = stack_param_idx[other];
522 stack_param_idx[other] = tmp;
526 curr_mem = get_Call_mem(irn);
528 obstack_ptr_grow(obst, curr_mem);
531 for (i = 0; i < n_stack_params; ++i) {
532 int p = stack_param_idx[i];
533 be_abi_call_arg_t *arg = get_call_arg(call, 0, p);
534 ir_node *param = get_Call_param(irn, p);
535 ir_node *addr = curr_sp;
537 ir_type *param_type = get_method_param_type(call_tp, p);
538 int param_size = get_type_size_bytes(param_type) + arg->space_after;
541 * If we wanted to build the arguments sequentially,
542 * the stack pointer for the next must be incremented,
543 * and the memory value propagated.
547 addr = curr_sp = be_new_IncSP(sp, irg, bl, curr_sp, param_size + arg->space_before, 0);
548 add_irn_dep(curr_sp, curr_mem);
551 curr_ofs += arg->space_before;
552 curr_ofs = round_up2(curr_ofs, arg->alignment);
554 /* Make the expression to compute the argument's offset. */
556 ir_mode *constmode = mach_mode;
557 if (mode_is_reference(mach_mode)) {
560 addr = new_r_Const_long(irg, constmode, curr_ofs);
561 addr = new_r_Add(irg, bl, curr_sp, addr, mach_mode);
565 /* Insert a store for primitive arguments. */
566 if (is_atomic_type(param_type)) {
568 ir_node *mem_input = do_seq ? curr_mem : new_NoMem();
569 store = new_rd_Store(dbgi, irg, bl, mem_input, addr, param, 0);
570 mem = new_r_Proj(irg, bl, store, mode_M, pn_Store_M);
573 /* Make a mem copy for compound arguments. */
577 assert(mode_is_reference(get_irn_mode(param)));
578 copy = new_rd_CopyB(dbgi, irg, bl, curr_mem, addr, param, param_type);
579 mem = new_r_Proj(irg, bl, copy, mode_M, pn_CopyB_M_regular);
582 curr_ofs += param_size;
587 obstack_ptr_grow(obst, mem);
590 in = (ir_node **) obstack_finish(obst);
592 /* We need the sync only, if we didn't build the stores sequentially. */
594 if (n_stack_params >= 1) {
595 curr_mem = new_r_Sync(irg, bl, n_stack_params + 1, in);
597 curr_mem = get_Call_mem(irn);
600 obstack_free(obst, in);
603 /* check for the return_twice property */
604 destroy_all_regs = 0;
605 if (is_SymConst_addr_ent(call_ptr)) {
606 ir_entity *ent = get_SymConst_entity(call_ptr);
608 if (get_entity_additional_properties(ent) & mtp_property_returns_twice)
609 destroy_all_regs = 1;
611 ir_type *call_tp = get_Call_type(irn);
613 if (get_method_additional_properties(call_tp) & mtp_property_returns_twice)
614 destroy_all_regs = 1;
617 /* Put caller save into the destroyed set and state registers in the states set */
618 for (i = 0, n = arch_env_get_n_reg_class(arch_env); i < n; ++i) {
620 const arch_register_class_t *cls = arch_env_get_reg_class(arch_env, i);
621 for (j = 0; j < cls->n_regs; ++j) {
622 const arch_register_t *reg = arch_register_for_index(cls, j);
624 if (destroy_all_regs || arch_register_type_is(reg, caller_save)) {
625 if (! arch_register_type_is(reg, ignore))
626 pset_new_insert(&destroyed_regs, (void *) reg);
628 if (arch_register_type_is(reg, state)) {
629 pset_new_insert(&destroyed_regs, (void*) reg);
630 pset_new_insert(&states, (void*) reg);
635 if (destroy_all_regs) {
636 /* even if destroyed all is specified, neither SP nor FP are destroyed (else bad things will happen) */
637 pset_new_remove(&destroyed_regs, arch_env->sp);
638 pset_new_remove(&destroyed_regs, arch_env->bp);
641 /* search the largest result proj number */
642 res_projs = ALLOCANZ(ir_node*, n_res);
644 foreach_out_edge(irn, edge) {
645 const ir_edge_t *res_edge;
646 ir_node *irn = get_edge_src_irn(edge);
648 if (!is_Proj(irn) || get_Proj_proj(irn) != pn_Call_T_result)
651 foreach_out_edge(irn, res_edge) {
653 ir_node *res = get_edge_src_irn(res_edge);
655 assert(is_Proj(res));
657 proj = get_Proj_proj(res);
658 assert(proj < n_res);
659 assert(res_projs[proj] == NULL);
660 res_projs[proj] = res;
666 /** TODO: this is not correct for cases where return values are passed
667 * on the stack, but no known ABI does this currently...
669 n_reg_results = n_res;
671 /* make the back end call node and set its register requirements. */
672 for (i = 0; i < n_reg_params; ++i) {
673 obstack_ptr_grow(obst, get_Call_param(irn, reg_param_idxs[i]));
676 /* add state registers ins */
677 foreach_pset_new(&states, reg, iter) {
678 const arch_register_class_t *cls = arch_register_get_class(reg);
680 ir_node *regnode = be_abi_reg_map_get(env->regs, reg);
681 ir_fprintf(stderr, "Adding %+F\n", regnode);
683 ir_node *regnode = new_r_Unknown(irg, arch_register_class_mode(cls));
684 obstack_ptr_grow(obst, regnode);
686 n_ins = n_reg_params + pset_new_size(&states);
688 in = obstack_finish(obst);
690 /* ins collected, build the call */
691 if (env->call->flags.bits.call_has_imm && is_SymConst(call_ptr)) {
693 low_call = be_new_Call(dbgi, irg, bl, curr_mem, curr_sp, curr_sp,
694 n_reg_results + pn_be_Call_first_res + pset_new_size(&destroyed_regs),
695 n_ins, in, get_Call_type(irn));
696 be_Call_set_entity(low_call, get_SymConst_entity(call_ptr));
699 low_call = be_new_Call(dbgi, irg, bl, curr_mem, curr_sp, call_ptr,
700 n_reg_results + pn_be_Call_first_res + pset_new_size(&destroyed_regs),
701 n_ins, in, get_Call_type(irn));
703 be_Call_set_pop(low_call, call->pop);
705 /* put the call into the list of all calls for later processing */
706 ARR_APP1(ir_node *, env->calls, low_call);
708 /* create new stack pointer */
709 curr_sp = new_r_Proj(irg, bl, low_call, get_irn_mode(curr_sp),
711 be_set_constr_single_reg_out(low_call, pn_be_Call_sp, sp,
712 arch_register_req_type_ignore | arch_register_req_type_produces_sp);
713 arch_set_irn_register(curr_sp, sp);
715 /* now handle results */
716 for (i = 0; i < n_res; ++i) {
718 ir_node *proj = res_projs[i];
719 be_abi_call_arg_t *arg = get_call_arg(call, 1, i);
721 /* returns values on stack not supported yet */
725 shift the proj number to the right, since we will drop the
726 unspeakable Proj_T from the Call. Therefore, all real argument
727 Proj numbers must be increased by pn_be_Call_first_res
729 pn = i + pn_be_Call_first_res;
732 ir_type *res_type = get_method_res_type(call_tp, i);
733 ir_mode *mode = get_type_mode(res_type);
734 proj = new_r_Proj(irg, bl, low_call, mode, pn);
737 set_Proj_pred(proj, low_call);
738 set_Proj_proj(proj, pn);
742 pset_new_remove(&destroyed_regs, arg->reg);
747 Set the register class of the call address to
748 the backend provided class (default: stack pointer class)
750 be_node_set_reg_class_in(low_call, be_pos_Call_ptr, call->cls_addr);
752 DBG((env->dbg, LEVEL_3, "\tcreated backend call %+F\n", low_call));
754 /* Set the register classes and constraints of the Call parameters. */
755 for (i = 0; i < n_reg_params; ++i) {
756 int index = reg_param_idxs[i];
757 be_abi_call_arg_t *arg = get_call_arg(call, 0, index);
758 assert(arg->reg != NULL);
760 be_set_constr_single_reg_in(low_call, be_pos_Call_first_arg + i,
764 /* Set the register constraints of the results. */
765 for (i = 0; i < n_res; ++i) {
766 ir_node *proj = res_projs[i];
767 const be_abi_call_arg_t *arg = get_call_arg(call, 1, i);
768 int pn = get_Proj_proj(proj);
771 be_set_constr_single_reg_out(low_call, pn, arg->reg, 0);
772 arch_set_irn_register(proj, arg->reg);
774 obstack_free(obst, in);
775 exchange(irn, low_call);
777 /* kill the ProjT node */
778 if (res_proj != NULL) {
782 /* Make additional projs for the caller save registers
783 and the Keep node which keeps them alive. */
785 const arch_register_t *reg;
789 int curr_res_proj = pn_be_Call_first_res + n_reg_results;
790 pset_new_iterator_t iter;
792 /* also keep the stack pointer */
794 set_irn_link(curr_sp, (void*) sp);
795 obstack_ptr_grow(obst, curr_sp);
797 foreach_pset_new(&destroyed_regs, reg, iter) {
798 ir_node *proj = new_r_Proj(irg, bl, low_call, reg->reg_class->mode, curr_res_proj);
800 /* memorize the register in the link field. we need afterwards to set the register class of the keep correctly. */
801 be_set_constr_single_reg_out(low_call, curr_res_proj, reg, 0);
802 arch_set_irn_register(proj, reg);
804 set_irn_link(proj, (void*) reg);
805 obstack_ptr_grow(obst, proj);
810 for (i = 0; i < n_reg_results; ++i) {
811 ir_node *proj = res_projs[i];
812 const arch_register_t *reg = arch_get_irn_register(proj);
813 set_irn_link(proj, (void*) reg);
814 obstack_ptr_grow(obst, proj);
818 /* create the Keep for the caller save registers */
819 in = (ir_node **) obstack_finish(obst);
820 keep = be_new_Keep(NULL, irg, bl, n, in);
821 for (i = 0; i < n; ++i) {
822 const arch_register_t *reg = get_irn_link(in[i]);
823 be_node_set_reg_class_in(keep, i, reg->reg_class);
825 obstack_free(obst, in);
828 /* Clean up the stack. */
829 assert(stack_size >= call->pop);
830 stack_size -= call->pop;
832 if (stack_size > 0) {
833 ir_node *mem_proj = NULL;
835 foreach_out_edge(low_call, edge) {
836 ir_node *irn = get_edge_src_irn(edge);
837 if (is_Proj(irn) && get_Proj_proj(irn) == pn_Call_M) {
844 mem_proj = new_r_Proj(irg, bl, low_call, mode_M, pn_be_Call_M_regular);
845 keep_alive(mem_proj);
848 /* Clean up the stack frame or revert alignment fixes if we allocated it */
850 curr_sp = be_new_IncSP(sp, irg, bl, curr_sp, -stack_size, 0);
853 be_abi_call_free(call);
854 obstack_free(obst, stack_param_idx);
856 pset_new_destroy(&states);
857 pset_new_destroy(&destroyed_regs);
863 * Adjust the size of a node representing a stack alloc or free for the minimum stack alignment.
865 * @param alignment the minimum stack alignment
866 * @param size the node containing the non-aligned size
867 * @param irg the irg where new nodes are allocated on
868 * @param irg the block where new nodes are allocated on
869 * @param dbg debug info for new nodes
871 * @return a node representing the aligned size
873 static ir_node *adjust_alloc_size(unsigned stack_alignment, ir_node *size,
874 ir_graph *irg, ir_node *block, dbg_info *dbg)
876 if (stack_alignment > 1) {
881 assert(is_po2(stack_alignment));
883 mode = get_irn_mode(size);
884 tv = new_tarval_from_long(stack_alignment-1, mode);
885 mask = new_r_Const(irg, tv);
886 size = new_rd_Add(dbg, irg, block, size, mask, mode);
888 tv = new_tarval_from_long(-(long)stack_alignment, mode);
889 mask = new_r_Const(irg, tv);
890 size = new_rd_And(dbg, irg, block, size, mask, mode);
896 * The alloca is transformed into a back end alloca node and connected to the stack nodes.
898 static ir_node *adjust_alloc(be_abi_irg_t *env, ir_node *alloc, ir_node *curr_sp)
907 const ir_edge_t *edge;
908 ir_node *new_alloc, *size, *addr, *ins[2];
909 unsigned stack_alignment;
911 assert(get_Alloc_where(alloc) == stack_alloc);
913 block = get_nodes_block(alloc);
914 irg = get_irn_irg(block);
917 type = get_Alloc_type(alloc);
919 foreach_out_edge(alloc, edge) {
920 ir_node *irn = get_edge_src_irn(edge);
922 assert(is_Proj(irn));
923 switch (get_Proj_proj(irn)) {
935 /* Beware: currently Alloc nodes without a result might happen,
936 only escape analysis kills them and this phase runs only for object
937 oriented source. We kill the Alloc here. */
938 if (alloc_res == NULL && alloc_mem) {
939 exchange(alloc_mem, get_Alloc_mem(alloc));
943 dbg = get_irn_dbg_info(alloc);
944 size = get_Alloc_size(alloc);
946 /* we might need to multiply the size with the element size */
947 if (type != firm_unknown_type && get_type_size_bytes(type) != 1) {
948 ir_mode *mode = get_irn_mode(size);
949 tarval *tv = new_tarval_from_long(get_type_size_bytes(type),
951 ir_node *cnst = new_rd_Const(dbg, irg, tv);
952 size = new_rd_Mul(dbg, irg, block, size, cnst, mode);
955 /* The stack pointer will be modified in an unknown manner.
956 We cannot omit it. */
957 env->call->flags.bits.try_omit_fp = 0;
959 stack_alignment = 1 << env->arch_env->stack_alignment;
960 size = adjust_alloc_size(stack_alignment, size, irg, block, dbg);
961 new_alloc = be_new_AddSP(env->arch_env->sp, irg, block, curr_sp, size);
962 set_irn_dbg_info(new_alloc, dbg);
964 if (alloc_mem != NULL) {
968 addsp_mem = new_r_Proj(irg, block, new_alloc, mode_M, pn_be_AddSP_M);
970 /* We need to sync the output mem of the AddSP with the input mem
971 edge into the alloc node. */
972 ins[0] = get_Alloc_mem(alloc);
974 sync = new_r_Sync(irg, block, 2, ins);
976 exchange(alloc_mem, sync);
979 exchange(alloc, new_alloc);
981 /* fix projnum of alloca res */
982 set_Proj_proj(alloc_res, pn_be_AddSP_res);
985 curr_sp = new_r_Proj(irg, block, new_alloc, get_irn_mode(curr_sp),
993 * The Free is transformed into a back end free node and connected to the stack nodes.
995 static ir_node *adjust_free(be_abi_irg_t *env, ir_node *free, ir_node *curr_sp)
999 ir_node *subsp, *mem, *res, *size, *sync;
1003 unsigned stack_alignment;
1006 assert(get_Free_where(free) == stack_alloc);
1008 block = get_nodes_block(free);
1009 irg = get_irn_irg(block);
1010 type = get_Free_type(free);
1011 sp_mode = env->arch_env->sp->reg_class->mode;
1012 dbg = get_irn_dbg_info(free);
1014 /* we might need to multiply the size with the element size */
1015 if (type != firm_unknown_type && get_type_size_bytes(type) != 1) {
1016 tarval *tv = new_tarval_from_long(get_type_size_bytes(type), mode_Iu);
1017 ir_node *cnst = new_rd_Const(dbg, irg, tv);
1018 ir_node *mul = new_rd_Mul(dbg, irg, block, get_Free_size(free),
1022 size = get_Free_size(free);
1025 stack_alignment = 1 << env->arch_env->stack_alignment;
1026 size = adjust_alloc_size(stack_alignment, size, irg, block, dbg);
1028 /* The stack pointer will be modified in an unknown manner.
1029 We cannot omit it. */
1030 env->call->flags.bits.try_omit_fp = 0;
1031 subsp = be_new_SubSP(env->arch_env->sp, irg, block, curr_sp, size);
1032 set_irn_dbg_info(subsp, dbg);
1034 mem = new_r_Proj(irg, block, subsp, mode_M, pn_be_SubSP_M);
1035 res = new_r_Proj(irg, block, subsp, sp_mode, pn_be_SubSP_sp);
1037 /* we need to sync the memory */
1038 in[0] = get_Free_mem(free);
1040 sync = new_r_Sync(irg, block, 2, in);
1042 /* and make the AddSP dependent on the former memory */
1043 add_irn_dep(subsp, get_Free_mem(free));
1046 exchange(free, sync);
1052 /* the following function is replaced by the usage of the heights module */
1055 * Walker for dependent_on().
1056 * This function searches a node tgt recursively from a given node
1057 * but is restricted to the given block.
1058 * @return 1 if tgt was reachable from curr, 0 if not.
1060 static int check_dependence(ir_node *curr, ir_node *tgt, ir_node *bl)
1064 if (get_nodes_block(curr) != bl)
1070 /* Phi functions stop the recursion inside a basic block */
1071 if (! is_Phi(curr)) {
1072 for (i = 0, n = get_irn_arity(curr); i < n; ++i) {
1073 if (check_dependence(get_irn_n(curr, i), tgt, bl))
1083 * Check if a node is somehow data dependent on another one.
1084 * both nodes must be in the same basic block.
1085 * @param n1 The first node.
1086 * @param n2 The second node.
1087 * @return 1, if n1 is data dependent (transitively) on n2, 0 if not.
1089 static int dependent_on(ir_node *n1, ir_node *n2)
1091 assert(get_nodes_block(n1) == get_nodes_block(n2));
1093 return heights_reachable_in_block(ir_heights, n1, n2);
1096 static int cmp_call_dependency(const void *c1, const void *c2)
1098 ir_node *n1 = *(ir_node **) c1;
1099 ir_node *n2 = *(ir_node **) c2;
1102 Classical qsort() comparison function behavior:
1103 0 if both elements are equal
1104 1 if second is "smaller" that first
1105 -1 if first is "smaller" that second
1107 if (dependent_on(n1, n2))
1110 if (dependent_on(n2, n1))
1113 /* The nodes have no depth order, but we need a total order because qsort()
1115 return get_irn_idx(n1) - get_irn_idx(n2);
1119 * Walker: links all Call/Alloc/Free nodes to the Block they are contained.
1120 * Clears the irg_is_leaf flag if a Call is detected.
1122 static void link_ops_in_block_walker(ir_node *irn, void *data)
1124 be_abi_irg_t *env = data;
1125 ir_opcode code = get_irn_opcode(irn);
1127 if (code == iro_Call ||
1128 (code == iro_Alloc && get_Alloc_where(irn) == stack_alloc) ||
1129 (code == iro_Free && get_Free_where(irn) == stack_alloc)) {
1130 ir_node *bl = get_nodes_block(irn);
1131 void *save = get_irn_link(bl);
1133 if (code == iro_Call)
1134 env->call->flags.bits.irg_is_leaf = 0;
1136 set_irn_link(irn, save);
1137 set_irn_link(bl, irn);
1140 if (code == iro_Builtin && get_Builtin_kind(irn) == ir_bk_return_address) {
1141 ir_node *param = get_Builtin_param(irn, 0);
1142 tarval *tv = get_Const_tarval(param);
1143 unsigned long value = get_tarval_long(tv);
1144 /* use ebp, so the climbframe algo works... */
1146 env->call->flags.bits.try_omit_fp = 0;
1153 * Process all Call/Alloc/Free nodes inside a basic block.
1154 * Note that the link field of the block must contain a linked list of all
1155 * Call nodes inside the Block. We first order this list according to data dependency
1156 * and that connect the calls together.
1158 static void process_ops_in_block(ir_node *bl, void *data)
1160 be_abi_irg_t *env = data;
1161 ir_node *curr_sp = env->init_sp;
1165 for (irn = get_irn_link(bl), n = 0; irn; irn = get_irn_link(irn), ++n)
1166 obstack_ptr_grow(&env->obst, irn);
1168 /* If there were call nodes in the block. */
1174 nodes = obstack_finish(&env->obst);
1176 /* order the call nodes according to data dependency */
1177 qsort(nodes, n, sizeof(nodes[0]), cmp_call_dependency);
1179 for (i = n - 1; i >= 0; --i) {
1180 ir_node *irn = nodes[i];
1182 DBG((env->dbg, LEVEL_3, "\tprocessing call %+F\n", irn));
1183 switch (get_irn_opcode(irn)) {
1186 /* The stack pointer will be modified due to a call. */
1187 env->call->flags.bits.try_omit_fp = 0;
1189 curr_sp = adjust_call(env, irn, curr_sp);
1192 if (get_Alloc_where(irn) == stack_alloc)
1193 curr_sp = adjust_alloc(env, irn, curr_sp);
1196 if (get_Free_where(irn) == stack_alloc)
1197 curr_sp = adjust_free(env, irn, curr_sp);
1200 panic("invalid call");
1205 obstack_free(&env->obst, nodes);
1207 /* Keep the last stack state in the block by tying it to Keep node,
1208 * the proj from calls is already kept */
1209 if (curr_sp != env->init_sp &&
1210 !(is_Proj(curr_sp) && be_is_Call(get_Proj_pred(curr_sp)))) {
1212 keep = be_new_Keep(env->arch_env->sp->reg_class,
1213 get_irn_irg(bl), bl, 1, nodes);
1214 pmap_insert(env->keep_map, bl, keep);
1218 set_irn_link(bl, curr_sp);
1219 } /* process_ops_in_block */
1222 * Adjust all call nodes in the graph to the ABI conventions.
1224 static void process_calls(be_abi_irg_t *env)
1226 ir_graph *irg = env->birg->irg;
1228 env->call->flags.bits.irg_is_leaf = 1;
1229 irg_walk_graph(irg, firm_clear_link, link_ops_in_block_walker, env);
1231 ir_heights = heights_new(env->birg->irg);
1232 irg_block_walk_graph(irg, NULL, process_ops_in_block, env);
1233 heights_free(ir_heights);
1237 * Computes the stack argument layout type.
1238 * Changes a possibly allocated value param type by moving
1239 * entities to the stack layout type.
1241 * @param env the ABI environment
1242 * @param call the current call ABI
1243 * @param method_type the method type
1244 * @param val_param_tp the value parameter type, will be destroyed
1245 * @param param_map an array mapping method arguments to the stack layout type
1247 * @return the stack argument layout type
1249 static ir_type *compute_arg_type(be_abi_irg_t *env, be_abi_call_t *call,
1250 ir_type *method_type, ir_type *val_param_tp,
1251 ir_entity ***param_map)
1253 int dir = env->call->flags.bits.left_to_right ? 1 : -1;
1254 int inc = env->birg->main_env->arch_env->stack_dir * dir;
1255 int n = get_method_n_params(method_type);
1256 int curr = inc > 0 ? 0 : n - 1;
1262 ident *id = get_entity_ident(get_irg_entity(env->birg->irg));
1265 *param_map = map = obstack_alloc(&env->obst, n * sizeof(ir_entity *));
1266 res = new_type_struct(id_mangle_u(id, new_id_from_chars("arg_type", 8)));
1267 for (i = 0; i < n; ++i, curr += inc) {
1268 ir_type *param_type = get_method_param_type(method_type, curr);
1269 be_abi_call_arg_t *arg = get_call_arg(call, 0, curr);
1272 if (arg->on_stack) {
1273 if (val_param_tp != NULL) {
1274 /* the entity was already created, create a copy in the param type */
1275 ir_entity *val_ent = get_method_value_param_ent(method_type, i);
1276 arg->stack_ent = copy_entity_own(val_ent, res);
1277 set_entity_link(val_ent, arg->stack_ent);
1278 set_entity_link(arg->stack_ent, NULL);
1279 /* must be automatic to set a fixed layout */
1280 set_entity_allocation(arg->stack_ent, allocation_automatic);
1282 /* create a new entity */
1283 snprintf(buf, sizeof(buf), "param_%d", i);
1284 arg->stack_ent = new_entity(res, new_id_from_str(buf), param_type);
1286 ofs += arg->space_before;
1287 ofs = round_up2(ofs, arg->alignment);
1288 set_entity_offset(arg->stack_ent, ofs);
1289 ofs += arg->space_after;
1290 ofs += get_type_size_bytes(param_type);
1291 map[i] = arg->stack_ent;
1294 set_type_size_bytes(res, ofs);
1295 set_type_state(res, layout_fixed);
1300 const arch_register_t *reg;
1304 static int cmp_regs(const void *a, const void *b)
1306 const reg_node_map_t *p = a;
1307 const reg_node_map_t *q = b;
1309 if (p->reg->reg_class == q->reg->reg_class)
1310 return p->reg->index - q->reg->index;
1312 return p->reg->reg_class - q->reg->reg_class;
1315 static reg_node_map_t *reg_map_to_arr(struct obstack *obst, pmap *reg_map)
1318 int n = pmap_count(reg_map);
1320 reg_node_map_t *res = obstack_alloc(obst, n * sizeof(res[0]));
1322 foreach_pmap(reg_map, ent) {
1323 res[i].reg = ent->key;
1324 res[i].irn = ent->value;
1328 qsort(res, n, sizeof(res[0]), cmp_regs);
1333 * Creates a barrier.
1335 static ir_node *create_barrier(be_abi_irg_t *env, ir_node *bl, ir_node **mem, pmap *regs, int in_req)
1337 ir_graph *irg = env->birg->irg;
1338 int n_regs = pmap_count(regs);
1344 rm = reg_map_to_arr(&env->obst, regs);
1346 for (n = 0; n < n_regs; ++n)
1347 obstack_ptr_grow(&env->obst, rm[n].irn);
1350 obstack_ptr_grow(&env->obst, *mem);
1354 in = (ir_node **) obstack_finish(&env->obst);
1355 irn = be_new_Barrier(irg, bl, n, in);
1356 obstack_free(&env->obst, in);
1358 for (n = 0; n < n_regs; ++n) {
1359 ir_node *pred = rm[n].irn;
1360 const arch_register_t *reg = rm[n].reg;
1361 arch_register_type_t add_type = 0;
1364 /* stupid workaround for now... as not all nodes report register
1366 if (!is_Phi(pred)) {
1367 const arch_register_req_t *ireq = arch_get_register_req_out(pred);
1368 if (ireq->type & arch_register_req_type_ignore)
1369 add_type |= arch_register_req_type_ignore;
1370 if (ireq->type & arch_register_req_type_produces_sp)
1371 add_type |= arch_register_req_type_produces_sp;
1374 proj = new_r_Proj(irg, bl, irn, get_irn_mode(pred), n);
1375 be_node_set_reg_class_in(irn, n, reg->reg_class);
1377 be_set_constr_single_reg_in(irn, n, reg, 0);
1378 be_set_constr_single_reg_out(irn, n, reg, add_type);
1379 arch_set_irn_register(proj, reg);
1381 pmap_insert(regs, (void *) reg, proj);
1385 *mem = new_r_Proj(irg, bl, irn, mode_M, n);
1388 obstack_free(&env->obst, rm);
1393 * Creates a be_Return for a Return node.
1395 * @param @env the abi environment
1396 * @param irn the Return node or NULL if there was none
1397 * @param bl the block where the be_Retun should be placed
1398 * @param mem the current memory
1399 * @param n_res number of return results
1401 static ir_node *create_be_return(be_abi_irg_t *env, ir_node *irn, ir_node *bl,
1402 ir_node *mem, int n_res)
1404 be_abi_call_t *call = env->call;
1405 const arch_env_t *arch_env = env->birg->main_env->arch_env;
1407 pmap *reg_map = pmap_create();
1408 ir_node *keep = pmap_get(env->keep_map, bl);
1415 const arch_register_t **regs;
1419 get the valid stack node in this block.
1420 If we had a call in that block there is a Keep constructed by process_calls()
1421 which points to the last stack modification in that block. we'll use
1422 it then. Else we use the stack from the start block and let
1423 the ssa construction fix the usage.
1425 stack = be_abi_reg_map_get(env->regs, arch_env->sp);
1427 stack = get_irn_n(keep, 0);
1429 remove_End_keepalive(get_irg_end(env->birg->irg), keep);
1432 /* Insert results for Return into the register map. */
1433 for (i = 0; i < n_res; ++i) {
1434 ir_node *res = get_Return_res(irn, i);
1435 be_abi_call_arg_t *arg = get_call_arg(call, 1, i);
1436 assert(arg->in_reg && "return value must be passed in register");
1437 pmap_insert(reg_map, (void *) arg->reg, res);
1440 /* Add uses of the callee save registers. */
1441 foreach_pmap(env->regs, ent) {
1442 const arch_register_t *reg = ent->key;
1443 if (arch_register_type_is(reg, callee_save) || arch_register_type_is(reg, ignore))
1444 pmap_insert(reg_map, ent->key, ent->value);
1447 be_abi_reg_map_set(reg_map, arch_env->sp, stack);
1449 /* Make the Epilogue node and call the arch's epilogue maker. */
1450 create_barrier(env, bl, &mem, reg_map, 1);
1451 call->cb->epilogue(env->cb, bl, &mem, reg_map);
1454 Maximum size of the in array for Return nodes is
1455 return args + callee save/ignore registers + memory + stack pointer
1457 in_max = pmap_count(reg_map) + n_res + 2;
1459 in = obstack_alloc(&env->obst, in_max * sizeof(in[0]));
1460 regs = obstack_alloc(&env->obst, in_max * sizeof(regs[0]));
1463 in[1] = be_abi_reg_map_get(reg_map, arch_env->sp);
1465 regs[1] = arch_env->sp;
1468 /* clear SP entry, since it has already been grown. */
1469 pmap_insert(reg_map, (void *) arch_env->sp, NULL);
1470 for (i = 0; i < n_res; ++i) {
1471 be_abi_call_arg_t *arg = get_call_arg(call, 1, i);
1473 in[n] = be_abi_reg_map_get(reg_map, arg->reg);
1474 regs[n++] = arg->reg;
1476 /* Clear the map entry to mark the register as processed. */
1477 be_abi_reg_map_set(reg_map, arg->reg, NULL);
1480 /* grow the rest of the stuff. */
1481 foreach_pmap(reg_map, ent) {
1484 regs[n++] = ent->key;
1488 /* The in array for the new back end return is now ready. */
1490 dbgi = get_irn_dbg_info(irn);
1494 /* we have to pop the shadow parameter in in case of struct returns */
1496 ret = be_new_Return(dbgi, env->birg->irg, bl, n_res, pop, n, in);
1498 /* Set the register classes of the return's parameter accordingly. */
1499 for (i = 0; i < n; ++i) {
1500 if (regs[i] == NULL)
1503 be_node_set_reg_class_in(ret, i, regs[i]->reg_class);
1506 /* Free the space of the Epilog's in array and the register <-> proj map. */
1507 obstack_free(&env->obst, in);
1508 pmap_destroy(reg_map);
1513 typedef struct ent_pos_pair ent_pos_pair;
1514 struct ent_pos_pair {
1515 ir_entity *ent; /**< a value param entity */
1516 int pos; /**< its parameter number */
1517 ent_pos_pair *next; /**< for linking */
1520 typedef struct lower_frame_sels_env_t {
1521 ent_pos_pair *value_param_list; /**< the list of all value param entities */
1522 ir_node *frame; /**< the current frame */
1523 const arch_register_class_t *sp_class; /**< register class of the stack pointer */
1524 const arch_register_class_t *link_class; /**< register class of the link pointer */
1525 ir_type *value_tp; /**< the value type if any */
1526 ir_type *frame_tp; /**< the frame type */
1527 int static_link_pos; /**< argument number of the hidden static link */
1528 } lower_frame_sels_env_t;
1531 * Return an entity from the backend for an value param entity.
1533 * @param ent an value param type entity
1534 * @param ctx context
1536 static ir_entity *get_argument_entity(ir_entity *ent, lower_frame_sels_env_t *ctx)
1538 ir_entity *argument_ent = get_entity_link(ent);
1540 if (argument_ent == NULL) {
1541 /* we have NO argument entity yet: This is bad, as we will
1542 * need one for backing store.
1545 ir_type *frame_tp = ctx->frame_tp;
1546 unsigned offset = get_type_size_bytes(frame_tp);
1547 ir_type *tp = get_entity_type(ent);
1548 unsigned align = get_type_alignment_bytes(tp);
1550 offset += align - 1;
1551 offset &= ~(align - 1);
1553 argument_ent = copy_entity_own(ent, frame_tp);
1555 /* must be automatic to set a fixed layout */
1556 set_entity_allocation(argument_ent, allocation_automatic);
1557 set_entity_offset(argument_ent, offset);
1558 offset += get_type_size_bytes(tp);
1560 set_type_size_bytes(frame_tp, offset);
1561 set_entity_link(ent, argument_ent);
1563 return argument_ent;
1566 * Walker: Replaces Sels of frame type and
1567 * value param type entities by FrameAddress.
1568 * Links all used entities.
1570 static void lower_frame_sels_walker(ir_node *irn, void *data)
1572 lower_frame_sels_env_t *ctx = data;
1575 ir_node *ptr = get_Sel_ptr(irn);
1577 if (ptr == ctx->frame) {
1578 ir_entity *ent = get_Sel_entity(irn);
1579 ir_node *bl = get_nodes_block(irn);
1582 int is_value_param = 0;
1584 if (get_entity_owner(ent) == ctx->value_tp) {
1587 /* replace by its copy from the argument type */
1588 pos = get_struct_member_index(ctx->value_tp, ent);
1589 ent = get_argument_entity(ent, ctx);
1592 nw = be_new_FrameAddr(ctx->sp_class, current_ir_graph, bl, ctx->frame, ent);
1595 /* check, if it's a param Sel and if have not seen this entity before */
1596 if (is_value_param && get_entity_link(ent) == NULL) {
1602 ARR_APP1(ent_pos_pair, ctx->value_param_list, pair);
1604 set_entity_link(ent, ctx->value_param_list);
1611 * Check if a value parameter is transmitted as a register.
1612 * This might happen if the address of an parameter is taken which is
1613 * transmitted in registers.
1615 * Note that on some architectures this case must be handled specially
1616 * because the place of the backing store is determined by their ABI.
1618 * In the default case we move the entity to the frame type and create
1619 * a backing store into the first block.
1621 static void fix_address_of_parameter_access(be_abi_irg_t *env, ent_pos_pair *value_param_list)
1623 be_abi_call_t *call = env->call;
1624 ir_graph *irg = env->birg->irg;
1625 ent_pos_pair *entry, *new_list;
1627 int i, n = ARR_LEN(value_param_list);
1628 DEBUG_ONLY(firm_dbg_module_t *dbg = env->dbg;)
1631 for (i = 0; i < n; ++i) {
1632 int pos = value_param_list[i].pos;
1633 be_abi_call_arg_t *arg = get_call_arg(call, 0, pos);
1636 DBG((dbg, LEVEL_2, "\targ #%d need backing store\n", pos));
1637 value_param_list[i].next = new_list;
1638 new_list = &value_param_list[i];
1641 if (new_list != NULL) {
1642 /* ok, change the graph */
1643 ir_node *start_bl = get_irg_start_block(irg);
1644 ir_node *first_bl = NULL;
1645 ir_node *frame, *imem, *nmem, *store, *mem, *args, *args_bl;
1646 const ir_edge_t *edge;
1647 optimization_state_t state;
1650 foreach_block_succ(start_bl, edge) {
1651 ir_node *succ = get_edge_src_irn(edge);
1652 if (start_bl != succ) {
1658 /* we had already removed critical edges, so the following
1659 assertion should be always true. */
1660 assert(get_Block_n_cfgpreds(first_bl) == 1);
1662 /* now create backing stores */
1663 frame = get_irg_frame(irg);
1664 imem = get_irg_initial_mem(irg);
1666 save_optimization_state(&state);
1668 nmem = new_r_Proj(irg, first_bl, get_irg_start(irg), mode_M, pn_Start_M);
1669 restore_optimization_state(&state);
1671 /* reroute all edges to the new memory source */
1672 edges_reroute(imem, nmem, irg);
1676 args = get_irg_args(irg);
1677 args_bl = get_nodes_block(args);
1678 for (entry = new_list; entry != NULL; entry = entry->next) {
1680 ir_type *tp = get_entity_type(entry->ent);
1681 ir_mode *mode = get_type_mode(tp);
1684 /* address for the backing store */
1685 addr = be_new_FrameAddr(env->arch_env->sp->reg_class, irg, first_bl, frame, entry->ent);
1688 mem = new_r_Proj(irg, first_bl, store, mode_M, pn_Store_M);
1690 /* the backing store itself */
1691 store = new_r_Store(irg, first_bl, mem, addr,
1692 new_r_Proj(irg, args_bl, args, mode, i), 0);
1694 /* the new memory Proj gets the last Proj from store */
1695 set_Proj_pred(nmem, store);
1696 set_Proj_proj(nmem, pn_Store_M);
1698 /* move all entities to the frame type */
1699 frame_tp = get_irg_frame_type(irg);
1700 offset = get_type_size_bytes(frame_tp);
1702 /* we will add new entities: set the layout to undefined */
1703 assert(get_type_state(frame_tp) == layout_fixed);
1704 set_type_state(frame_tp, layout_undefined);
1705 for (entry = new_list; entry != NULL; entry = entry->next) {
1706 ir_entity *ent = entry->ent;
1708 /* If the entity is still on the argument type, move it to the frame type.
1709 This happens if the value_param type was build due to compound
1711 if (get_entity_owner(ent) != frame_tp) {
1712 ir_type *tp = get_entity_type(ent);
1713 unsigned align = get_type_alignment_bytes(tp);
1715 offset += align - 1;
1716 offset &= ~(align - 1);
1717 set_entity_owner(ent, frame_tp);
1718 add_class_member(frame_tp, ent);
1719 /* must be automatic to set a fixed layout */
1720 set_entity_allocation(ent, allocation_automatic);
1721 set_entity_offset(ent, offset);
1722 offset += get_type_size_bytes(tp);
1725 set_type_size_bytes(frame_tp, offset);
1726 /* fix the layout again */
1727 set_type_state(frame_tp, layout_fixed);
1732 * The start block has no jump, instead it has an initial exec Proj.
1733 * The backend wants to handle all blocks the same way, so we replace
1734 * the out cfg edge with a real jump.
1736 static void fix_start_block(ir_graph *irg)
1738 ir_node *initial_X = get_irg_initial_exec(irg);
1739 ir_node *start_block = get_irg_start_block(irg);
1740 const ir_edge_t *edge;
1742 assert(is_Proj(initial_X));
1744 foreach_out_edge(initial_X, edge) {
1745 ir_node *block = get_edge_src_irn(edge);
1747 if (is_Anchor(block))
1749 if (block != start_block) {
1750 ir_node *jmp = new_r_Jmp(irg, start_block);
1752 set_Block_cfgpred(block, get_edge_src_pos(edge), jmp);
1756 panic("Initial exec has no follow block in %+F", irg);
1760 * Update the entity of Sels to the outer value parameters.
1762 static void update_outer_frame_sels(ir_node *irn, void *env) {
1763 lower_frame_sels_env_t *ctx = env;
1770 ptr = get_Sel_ptr(irn);
1771 if (! is_arg_Proj(ptr))
1773 if (get_Proj_proj(ptr) != ctx->static_link_pos)
1775 ent = get_Sel_entity(irn);
1777 if (get_entity_owner(ent) == ctx->value_tp) {
1778 /* replace by its copy from the argument type */
1779 pos = get_struct_member_index(ctx->value_tp, ent);
1780 ent = get_argument_entity(ent, ctx);
1781 set_Sel_entity(irn, ent);
1783 /* check, if we have not seen this entity before */
1784 if (get_entity_link(ent) == NULL) {
1790 ARR_APP1(ent_pos_pair, ctx->value_param_list, pair);
1792 set_entity_link(ent, ctx->value_param_list);
1798 * Fix access to outer local variables.
1800 static void fix_outer_variable_access(be_abi_irg_t *env,
1801 lower_frame_sels_env_t *ctx)
1807 for (i = get_class_n_members(ctx->frame_tp) - 1; i >= 0; --i) {
1808 ir_entity *ent = get_class_member(ctx->frame_tp, i);
1810 if (! is_method_entity(ent))
1812 if (get_entity_peculiarity(ent) == peculiarity_description)
1816 * FIXME: find the number of the static link parameter
1817 * for now we assume 0 here
1819 ctx->static_link_pos = 0;
1821 irg = get_entity_irg(ent);
1822 irg_walk_graph(irg, NULL, update_outer_frame_sels, ctx);
1827 * Modify the irg itself and the frame type.
1829 static void modify_irg(be_abi_irg_t *env)
1831 be_abi_call_t *call = env->call;
1832 const arch_env_t *arch_env= env->birg->main_env->arch_env;
1833 const arch_register_t *sp = arch_env->sp;
1834 ir_graph *irg = env->birg->irg;
1838 ir_node *new_mem_proj;
1840 ir_type *method_type = get_entity_type(get_irg_entity(irg));
1847 const arch_register_t *fp_reg;
1848 ir_node *frame_pointer;
1849 ir_node *reg_params_bl;
1852 const ir_edge_t *edge;
1853 ir_type *arg_type, *bet_type, *tp;
1854 lower_frame_sels_env_t ctx;
1855 ir_entity **param_map;
1857 DEBUG_ONLY(firm_dbg_module_t *dbg = env->dbg;)
1859 DBG((dbg, LEVEL_1, "introducing abi on %+F\n", irg));
1861 /* Must fetch memory here, otherwise the start Barrier gets the wrong
1862 * memory, which leads to loops in the DAG. */
1863 old_mem = get_irg_initial_mem(irg);
1865 irp_reserve_resources(irp, IR_RESOURCE_ENTITY_LINK);
1867 /* set the links of all frame entities to NULL, we use it
1868 to detect if an entity is already linked in the value_param_list */
1869 tp = get_method_value_param_type(method_type);
1872 /* clear the links of the clone type, let the
1873 original entities point to its clones */
1874 for (i = get_struct_n_members(tp) - 1; i >= 0; --i) {
1875 ir_entity *mem = get_struct_member(tp, i);
1876 set_entity_link(mem, NULL);
1880 arg_type = compute_arg_type(env, call, method_type, tp, ¶m_map);
1882 /* Convert the Sel nodes in the irg to frame addr nodes: */
1883 ctx.value_param_list = NEW_ARR_F(ent_pos_pair, 0);
1884 ctx.frame = get_irg_frame(irg);
1885 ctx.sp_class = env->arch_env->sp->reg_class;
1886 ctx.link_class = env->arch_env->link_class;
1887 ctx.frame_tp = get_irg_frame_type(irg);
1889 /* we will possible add new entities to the frame: set the layout to undefined */
1890 assert(get_type_state(ctx.frame_tp) == layout_fixed);
1891 set_type_state(ctx.frame_tp, layout_undefined);
1893 irg_walk_graph(irg, lower_frame_sels_walker, NULL, &ctx);
1895 /* fix the frame type layout again */
1896 set_type_state(ctx.frame_tp, layout_fixed);
1898 env->regs = pmap_create();
1900 n_params = get_method_n_params(method_type);
1901 args = obstack_alloc(&env->obst, n_params * sizeof(args[0]));
1902 memset(args, 0, n_params * sizeof(args[0]));
1905 * for inner function we must now fix access to outer frame entities.
1907 fix_outer_variable_access(env, &ctx);
1909 /* Check if a value parameter is transmitted as a register.
1910 * This might happen if the address of an parameter is taken which is
1911 * transmitted in registers.
1913 * Note that on some architectures this case must be handled specially
1914 * because the place of the backing store is determined by their ABI.
1916 * In the default case we move the entity to the frame type and create
1917 * a backing store into the first block.
1919 fix_address_of_parameter_access(env, ctx.value_param_list);
1921 DEL_ARR_F(ctx.value_param_list);
1922 irp_free_resources(irp, IR_RESOURCE_ENTITY_LINK);
1924 /* Fill the argument vector */
1925 arg_tuple = get_irg_args(irg);
1926 foreach_out_edge(arg_tuple, edge) {
1927 ir_node *irn = get_edge_src_irn(edge);
1928 if (! is_Anchor(irn)) {
1929 int nr = get_Proj_proj(irn);
1931 DBG((dbg, LEVEL_2, "\treading arg: %d -> %+F\n", nr, irn));
1935 bet_type = call->cb->get_between_type(env->cb);
1936 stack_frame_init(&env->frame, arg_type, bet_type, get_irg_frame_type(irg), arch_env->stack_dir, param_map);
1938 /* Count the register params and add them to the number of Projs for the RegParams node */
1939 for (i = 0; i < n_params; ++i) {
1940 be_abi_call_arg_t *arg = get_call_arg(call, 0, i);
1941 if (arg->in_reg && args[i]) {
1942 assert(arg->reg != sp && "cannot use stack pointer as parameter register");
1943 assert(i == get_Proj_proj(args[i]));
1945 /* For now, associate the register with the old Proj from Start representing that argument. */
1946 pmap_insert(env->regs, (void *) arg->reg, args[i]);
1947 DBG((dbg, LEVEL_2, "\targ #%d -> reg %s\n", i, arg->reg->name));
1951 /* Collect all callee-save registers */
1952 for (i = 0, n = arch_env_get_n_reg_class(arch_env); i < n; ++i) {
1953 const arch_register_class_t *cls = arch_env_get_reg_class(arch_env, i);
1954 for (j = 0; j < cls->n_regs; ++j) {
1955 const arch_register_t *reg = &cls->regs[j];
1956 if (arch_register_type_is(reg, callee_save) ||
1957 arch_register_type_is(reg, state)) {
1958 pmap_insert(env->regs, (void *) reg, NULL);
1963 pmap_insert(env->regs, (void *) sp, NULL);
1964 pmap_insert(env->regs, (void *) arch_env->bp, NULL);
1965 reg_params_bl = get_irg_start_block(irg);
1966 env->reg_params = be_new_RegParams(irg, reg_params_bl, pmap_count(env->regs));
1967 add_irn_dep(env->reg_params, get_irg_start(irg));
1970 * make proj nodes for the callee save registers.
1971 * memorize them, since Return nodes get those as inputs.
1973 * Note, that if a register corresponds to an argument, the regs map contains
1974 * the old Proj from start for that argument.
1977 rm = reg_map_to_arr(&env->obst, env->regs);
1978 for (i = 0, n = pmap_count(env->regs); i < n; ++i) {
1979 arch_register_t *reg = (void *) rm[i].reg;
1980 ir_mode *mode = reg->reg_class->mode;
1982 arch_register_req_type_t add_type = 0;
1986 add_type |= arch_register_req_type_produces_sp | arch_register_req_type_ignore;
1989 proj = new_r_Proj(irg, reg_params_bl, env->reg_params, mode, nr);
1990 pmap_insert(env->regs, (void *) reg, proj);
1991 be_set_constr_single_reg_out(env->reg_params, nr, reg, add_type);
1992 arch_set_irn_register(proj, reg);
1994 DBG((dbg, LEVEL_2, "\tregister save proj #%d -> reg %s\n", nr, reg->name));
1996 obstack_free(&env->obst, rm);
1998 /* create a new initial memory proj */
1999 assert(is_Proj(old_mem));
2000 new_mem_proj = new_r_Proj(irg, get_nodes_block(old_mem),
2001 new_r_Unknown(irg, mode_T), mode_M,
2002 get_Proj_proj(old_mem));
2005 /* Generate the Prologue */
2006 fp_reg = call->cb->prologue(env->cb, &mem, env->regs, &env->frame.initial_bias);
2008 /* do the stack allocation BEFORE the barrier, or spill code
2009 might be added before it */
2010 env->init_sp = be_abi_reg_map_get(env->regs, sp);
2011 start_bl = get_irg_start_block(irg);
2012 env->init_sp = be_new_IncSP(sp, irg, start_bl, env->init_sp, BE_STACK_FRAME_SIZE_EXPAND, 0);
2013 be_abi_reg_map_set(env->regs, sp, env->init_sp);
2015 create_barrier(env, start_bl, &mem, env->regs, 0);
2017 env->init_sp = be_abi_reg_map_get(env->regs, sp);
2018 arch_set_irn_register(env->init_sp, sp);
2020 frame_pointer = be_abi_reg_map_get(env->regs, fp_reg);
2021 set_irg_frame(irg, frame_pointer);
2022 pset_insert_ptr(env->ignore_regs, fp_reg);
2024 /* rewire old mem users to new mem */
2025 set_Proj_pred(new_mem_proj, get_Proj_pred(old_mem));
2026 exchange(old_mem, mem);
2028 set_irg_initial_mem(irg, mem);
2030 /* Now, introduce stack param nodes for all parameters passed on the stack */
2031 for (i = 0; i < n_params; ++i) {
2032 ir_node *arg_proj = args[i];
2033 ir_node *repl = NULL;
2035 if (arg_proj != NULL) {
2036 be_abi_call_arg_t *arg;
2037 ir_type *param_type;
2038 int nr = get_Proj_proj(arg_proj);
2041 nr = MIN(nr, n_params);
2042 arg = get_call_arg(call, 0, nr);
2043 param_type = get_method_param_type(method_type, nr);
2046 repl = pmap_get(env->regs, (void *) arg->reg);
2047 } else if (arg->on_stack) {
2048 ir_node *addr = be_new_FrameAddr(sp->reg_class, irg, reg_params_bl, frame_pointer, arg->stack_ent);
2050 /* For atomic parameters which are actually used, we create a Load node. */
2051 if (is_atomic_type(param_type) && get_irn_n_edges(args[i]) > 0) {
2052 ir_mode *mode = get_type_mode(param_type);
2053 ir_mode *load_mode = arg->load_mode;
2055 ir_node *load = new_r_Load(irg, reg_params_bl, new_NoMem(), addr, load_mode, cons_floats);
2056 repl = new_r_Proj(irg, reg_params_bl, load, load_mode, pn_Load_res);
2058 if (mode != load_mode) {
2059 repl = new_r_Conv(irg, reg_params_bl, repl, mode);
2062 /* The stack parameter is not primitive (it is a struct or array),
2063 * we thus will create a node representing the parameter's address
2069 assert(repl != NULL);
2071 /* Beware: the mode of the register parameters is always the mode of the register class
2072 which may be wrong. Add Conv's then. */
2073 mode = get_irn_mode(args[i]);
2074 if (mode != get_irn_mode(repl)) {
2075 repl = new_r_Conv(irg, get_irn_n(repl, -1), repl, mode);
2077 exchange(args[i], repl);
2081 /* the arg proj is not needed anymore now and should be only used by the anchor */
2082 assert(get_irn_n_edges(arg_tuple) == 1);
2083 kill_node(arg_tuple);
2084 set_irg_args(irg, new_r_Bad(irg));
2086 /* All Return nodes hang on the End node, so look for them there. */
2087 end = get_irg_end_block(irg);
2088 for (i = 0, n = get_Block_n_cfgpreds(end); i < n; ++i) {
2089 ir_node *irn = get_Block_cfgpred(end, i);
2091 if (is_Return(irn)) {
2092 ir_node *blk = get_nodes_block(irn);
2093 ir_node *mem = get_Return_mem(irn);
2094 ir_node *ret = create_be_return(env, irn, blk, mem, get_Return_n_ress(irn));
2098 /* if we have endless loops here, n might be <= 0. Do NOT create a be_Return then,
2099 the code is dead and will never be executed. */
2101 obstack_free(&env->obst, args);
2103 /* handle start block here (place a jump in the block) */
2104 fix_start_block(irg);
2107 /** Fix the state inputs of calls that still hang on unknowns */
2109 void fix_call_state_inputs(be_abi_irg_t *env)
2111 const arch_env_t *arch_env = env->arch_env;
2113 arch_register_t **stateregs = NEW_ARR_F(arch_register_t*, 0);
2115 /* Collect caller save registers */
2116 n = arch_env_get_n_reg_class(arch_env);
2117 for (i = 0; i < n; ++i) {
2119 const arch_register_class_t *cls = arch_env_get_reg_class(arch_env, i);
2120 for (j = 0; j < cls->n_regs; ++j) {
2121 const arch_register_t *reg = arch_register_for_index(cls, j);
2122 if (arch_register_type_is(reg, state)) {
2123 ARR_APP1(arch_register_t*, stateregs, (arch_register_t *)reg);
2128 n = ARR_LEN(env->calls);
2129 n_states = ARR_LEN(stateregs);
2130 for (i = 0; i < n; ++i) {
2132 ir_node *call = env->calls[i];
2134 arity = get_irn_arity(call);
2136 /* the state reg inputs are the last n inputs of the calls */
2137 for (s = 0; s < n_states; ++s) {
2138 int inp = arity - n_states + s;
2139 const arch_register_t *reg = stateregs[s];
2140 ir_node *regnode = be_abi_reg_map_get(env->regs, reg);
2142 set_irn_n(call, inp, regnode);
2146 DEL_ARR_F(stateregs);
2150 * Create a trampoline entity for the given method.
2152 static ir_entity *create_trampoline(be_main_env_t *be, ir_entity *method)
2154 ir_type *type = get_entity_type(method);
2155 ident *old_id = get_entity_ld_ident(method);
2156 ident *id = id_mangle3("L", old_id, "$stub");
2157 ir_type *parent = be->pic_trampolines_type;
2158 ir_entity *ent = new_entity(parent, old_id, type);
2159 set_entity_ld_ident(ent, id);
2160 set_entity_visibility(ent, visibility_local);
2161 set_entity_variability(ent, variability_uninitialized);
2167 * Returns the trampoline entity for the given method.
2169 static ir_entity *get_trampoline(be_main_env_t *env, ir_entity *method)
2171 ir_entity *result = pmap_get(env->ent_trampoline_map, method);
2172 if (result == NULL) {
2173 result = create_trampoline(env, method);
2174 pmap_insert(env->ent_trampoline_map, method, result);
2180 static ir_entity *create_pic_symbol(be_main_env_t *be, ir_entity *entity)
2182 ident *old_id = get_entity_ld_ident(entity);
2183 ident *id = id_mangle3("L", old_id, "$non_lazy_ptr");
2184 ir_type *e_type = get_entity_type(entity);
2185 ir_type *type = new_type_pointer(id, e_type, mode_P_data);
2186 ir_type *parent = be->pic_symbols_type;
2187 ir_entity *ent = new_entity(parent, old_id, type);
2188 set_entity_ld_ident(ent, id);
2189 set_entity_visibility(ent, visibility_local);
2190 set_entity_variability(ent, variability_uninitialized);
2195 static ir_entity *get_pic_symbol(be_main_env_t *env, ir_entity *entity)
2197 ir_entity *result = pmap_get(env->ent_pic_symbol_map, entity);
2198 if (result == NULL) {
2199 result = create_pic_symbol(env, entity);
2200 pmap_insert(env->ent_pic_symbol_map, entity, result);
2209 * Returns non-zero if a given entity can be accessed using a relative address.
2211 static int can_address_relative(ir_entity *entity)
2213 return get_entity_variability(entity) == variability_initialized
2214 && get_entity_visibility(entity) != visibility_external_allocated;
2217 /** patches SymConsts to work in position independent code */
2218 static void fix_pic_symconsts(ir_node *node, void *data)
2228 be_abi_irg_t *env = data;
2230 be_main_env_t *be = env->birg->main_env;
2232 arity = get_irn_arity(node);
2233 for (i = 0; i < arity; ++i) {
2235 ir_node *pred = get_irn_n(node, i);
2237 ir_entity *pic_symbol;
2238 ir_node *pic_symconst;
2240 if (!is_SymConst(pred))
2243 entity = get_SymConst_entity(pred);
2244 block = get_nodes_block(pred);
2245 irg = get_irn_irg(pred);
2247 /* calls can jump to relative addresses, so we can directly jump to
2248 the (relatively) known call address or the trampoline */
2249 if (i == 1 && is_Call(node)) {
2250 ir_entity *trampoline;
2251 ir_node *trampoline_const;
2253 if (can_address_relative(entity))
2256 dbgi = get_irn_dbg_info(pred);
2257 trampoline = get_trampoline(be, entity);
2258 trampoline_const = new_rd_SymConst_addr_ent(dbgi, irg, mode_P_code,
2260 set_irn_n(node, i, trampoline_const);
2264 /* everything else is accessed relative to EIP */
2265 mode = get_irn_mode(pred);
2266 unknown = new_r_Unknown(irg, mode);
2267 pic_base = arch_code_generator_get_pic_base(env->birg->cg);
2269 /* all ok now for locally constructed stuff */
2270 if (can_address_relative(entity)) {
2271 ir_node *add = new_r_Add(irg, block, pic_base, pred, mode);
2273 /* make sure the walker doesn't visit this add again */
2274 mark_irn_visited(add);
2275 set_irn_n(node, i, add);
2279 /* get entry from pic symbol segment */
2280 dbgi = get_irn_dbg_info(pred);
2281 pic_symbol = get_pic_symbol(be, entity);
2282 pic_symconst = new_rd_SymConst_addr_ent(dbgi, irg, mode_P_code,
2284 add = new_r_Add(irg, block, pic_base, pic_symconst, mode);
2285 mark_irn_visited(add);
2287 /* we need an extra indirection for global data outside our current
2288 module. The loads are always safe and can therefore float
2289 and need no memory input */
2290 load = new_r_Load(irg, block, new_NoMem(), add, mode, cons_floats);
2291 load_res = new_r_Proj(irg, block, load, mode, pn_Load_res);
2293 set_irn_n(node, i, load_res);
2297 be_abi_irg_t *be_abi_introduce(be_irg_t *birg)
2299 be_abi_irg_t *env = XMALLOC(be_abi_irg_t);
2300 ir_node *old_frame = get_irg_frame(birg->irg);
2301 ir_graph *irg = birg->irg;
2305 optimization_state_t state;
2306 unsigned *limited_bitset;
2308 be_omit_fp = birg->main_env->options->omit_fp;
2309 be_omit_leaf_fp = birg->main_env->options->omit_leaf_fp;
2311 obstack_init(&env->obst);
2313 env->arch_env = birg->main_env->arch_env;
2314 env->method_type = get_entity_type(get_irg_entity(irg));
2315 env->call = be_abi_call_new(env->arch_env->sp->reg_class);
2316 arch_env_get_call_abi(env->arch_env, env->method_type, env->call);
2318 env->ignore_regs = pset_new_ptr_default();
2319 env->keep_map = pmap_create();
2320 env->dce_survivor = new_survive_dce();
2323 env->sp_req.type = arch_register_req_type_limited;
2324 env->sp_req.cls = arch_register_get_class(env->arch_env->sp);
2325 limited_bitset = rbitset_obstack_alloc(&env->obst, env->sp_req.cls->n_regs);
2326 rbitset_set(limited_bitset, arch_register_get_index(env->arch_env->sp));
2327 env->sp_req.limited = limited_bitset;
2328 if (env->arch_env->sp->type & arch_register_type_ignore) {
2329 env->sp_req.type |= arch_register_req_type_ignore;
2332 env->sp_cls_req.type = arch_register_req_type_normal;
2333 env->sp_cls_req.cls = arch_register_get_class(env->arch_env->sp);
2335 /* Beware: later we replace this node by the real one, ensure it is not CSE'd
2336 to another Unknown or the stack pointer gets used */
2337 save_optimization_state(&state);
2339 env->init_sp = dummy = new_r_Unknown(irg, env->arch_env->sp->reg_class->mode);
2340 restore_optimization_state(&state);
2342 FIRM_DBG_REGISTER(env->dbg, "firm.be.abi");
2344 env->calls = NEW_ARR_F(ir_node*, 0);
2346 if (birg->main_env->options->pic) {
2347 irg_walk_graph(irg, fix_pic_symconsts, NULL, env);
2350 /* Lower all call nodes in the IRG. */
2354 Beware: init backend abi call object after processing calls,
2355 otherwise some information might be not yet available.
2357 env->cb = env->call->cb->init(env->call, birg->main_env->arch_env, irg);
2359 /* Process the IRG */
2362 /* fix call inputs for state registers */
2363 fix_call_state_inputs(env);
2365 /* We don't need the keep map anymore. */
2366 pmap_destroy(env->keep_map);
2367 env->keep_map = NULL;
2369 /* calls array is not needed anymore */
2370 DEL_ARR_F(env->calls);
2373 /* reroute the stack origin of the calls to the true stack origin. */
2374 exchange(dummy, env->init_sp);
2375 exchange(old_frame, get_irg_frame(irg));
2377 /* Make some important node pointers survive the dead node elimination. */
2378 survive_dce_register_irn(env->dce_survivor, &env->init_sp);
2379 foreach_pmap(env->regs, ent) {
2380 survive_dce_register_irn(env->dce_survivor, (ir_node **) &ent->value);
2383 env->call->cb->done(env->cb);
2388 void be_abi_free(be_abi_irg_t *env)
2390 be_abi_call_free(env->call);
2391 free_survive_dce(env->dce_survivor);
2392 del_pset(env->ignore_regs);
2393 pmap_destroy(env->regs);
2394 obstack_free(&env->obst, NULL);
2398 void be_abi_put_ignore_regs(be_abi_irg_t *abi, const arch_register_class_t *cls, bitset_t *bs)
2400 arch_register_t *reg;
2402 for (reg = pset_first(abi->ignore_regs); reg; reg = pset_next(abi->ignore_regs))
2403 if (reg->reg_class == cls)
2404 bitset_set(bs, reg->index);
2407 void be_abi_set_non_ignore_regs(be_abi_irg_t *abi, const arch_register_class_t *cls, unsigned *raw_bitset)
2410 arch_register_t *reg;
2412 for (i = 0; i < cls->n_regs; ++i) {
2413 if (arch_register_type_is(&cls->regs[i], ignore))
2416 rbitset_set(raw_bitset, i);
2419 for (reg = pset_first(abi->ignore_regs); reg != NULL;
2420 reg = pset_next(abi->ignore_regs)) {
2421 if (reg->reg_class != cls)
2424 rbitset_clear(raw_bitset, reg->index);
2428 /* Returns the stack layout from a abi environment. */
2429 const be_stack_layout_t *be_abi_get_stack_layout(const be_abi_irg_t *abi)
2437 | ___(_)_ __ / ___|| |_ __ _ ___| | __
2438 | |_ | \ \/ / \___ \| __/ _` |/ __| |/ /
2439 | _| | |> < ___) | || (_| | (__| <
2440 |_| |_/_/\_\ |____/ \__\__,_|\___|_|\_\
2444 typedef ir_node **node_array;
2446 typedef struct fix_stack_walker_env_t {
2447 node_array sp_nodes;
2448 } fix_stack_walker_env_t;
2451 * Walker. Collect all stack modifying nodes.
2453 static void collect_stack_nodes_walker(ir_node *node, void *data)
2455 fix_stack_walker_env_t *env = data;
2456 const arch_register_req_t *req;
2458 if (get_irn_mode(node) == mode_T)
2461 req = arch_get_register_req_out(node);
2462 if (! (req->type & arch_register_req_type_produces_sp))
2465 ARR_APP1(ir_node*, env->sp_nodes, node);
2468 void be_abi_fix_stack_nodes(be_abi_irg_t *env)
2470 be_ssa_construction_env_t senv;
2473 be_irg_t *birg = env->birg;
2474 be_lv_t *lv = be_get_birg_liveness(birg);
2475 fix_stack_walker_env_t walker_env;
2477 walker_env.sp_nodes = NEW_ARR_F(ir_node*, 0);
2479 irg_walk_graph(birg->irg, collect_stack_nodes_walker, NULL, &walker_env);
2481 /* nothing to be done if we didn't find any node, in fact we mustn't
2482 * continue, as for endless loops incsp might have had no users and is bad
2485 len = ARR_LEN(walker_env.sp_nodes);
2487 DEL_ARR_F(walker_env.sp_nodes);
2491 be_ssa_construction_init(&senv, birg);
2492 be_ssa_construction_add_copies(&senv, walker_env.sp_nodes,
2493 ARR_LEN(walker_env.sp_nodes));
2494 be_ssa_construction_fix_users_array(&senv, walker_env.sp_nodes,
2495 ARR_LEN(walker_env.sp_nodes));
2498 len = ARR_LEN(walker_env.sp_nodes);
2499 for (i = 0; i < len; ++i) {
2500 be_liveness_update(lv, walker_env.sp_nodes[i]);
2502 be_ssa_construction_update_liveness_phis(&senv, lv);
2505 phis = be_ssa_construction_get_new_phis(&senv);
2507 /* set register requirements for stack phis */
2508 len = ARR_LEN(phis);
2509 for (i = 0; i < len; ++i) {
2510 ir_node *phi = phis[i];
2511 be_set_phi_reg_req(phi, &env->sp_req, arch_register_req_type_produces_sp);
2512 arch_set_irn_register(phi, env->arch_env->sp);
2514 be_ssa_construction_destroy(&senv);
2516 DEL_ARR_F(walker_env.sp_nodes);
2520 * Fix all stack accessing operations in the block bl.
2522 * @param env the abi environment
2523 * @param bl the block to process
2524 * @param real_bias the bias value
2526 * @return the bias at the end of this block
2528 static int process_stack_bias(be_abi_irg_t *env, ir_node *bl, int real_bias)
2530 int omit_fp = env->call->flags.bits.try_omit_fp;
2532 int wanted_bias = real_bias;
2534 sched_foreach(bl, irn) {
2538 Check, if the node relates to an entity on the stack frame.
2539 If so, set the true offset (including the bias) for that
2542 ir_entity *ent = arch_get_frame_entity(irn);
2544 int bias = omit_fp ? real_bias : 0;
2545 int offset = get_stack_entity_offset(&env->frame, ent, bias);
2546 arch_set_frame_offset(irn, offset);
2547 DBG((env->dbg, LEVEL_2, "%F has offset %d (including bias %d)\n",
2548 ent, offset, bias));
2552 * If the node modifies the stack pointer by a constant offset,
2553 * record that in the bias.
2555 ofs = arch_get_sp_bias(irn);
2557 if (be_is_IncSP(irn)) {
2558 /* fill in real stack frame size */
2559 if (ofs == BE_STACK_FRAME_SIZE_EXPAND) {
2560 ir_type *frame_type = get_irg_frame_type(env->birg->irg);
2561 ofs = (int) get_type_size_bytes(frame_type);
2562 be_set_IncSP_offset(irn, ofs);
2563 } else if (ofs == BE_STACK_FRAME_SIZE_SHRINK) {
2564 ir_type *frame_type = get_irg_frame_type(env->birg->irg);
2565 ofs = - (int)get_type_size_bytes(frame_type);
2566 be_set_IncSP_offset(irn, ofs);
2568 if (be_get_IncSP_align(irn)) {
2569 /* patch IncSP to produce an aligned stack pointer */
2570 ir_type *between_type = env->frame.between_type;
2571 int between_size = get_type_size_bytes(between_type);
2572 int alignment = 1 << env->arch_env->stack_alignment;
2573 int delta = (real_bias + ofs + between_size) & (alignment - 1);
2576 be_set_IncSP_offset(irn, ofs + alignment - delta);
2577 real_bias += alignment - delta;
2580 /* adjust so real_bias corresponds with wanted_bias */
2581 int delta = wanted_bias - real_bias;
2584 be_set_IncSP_offset(irn, ofs + delta);
2595 assert(real_bias == wanted_bias);
2600 * A helper struct for the bias walker.
2603 be_abi_irg_t *env; /**< The ABI irg environment. */
2604 int start_block_bias; /**< The bias at the end of the start block. */
2606 ir_node *start_block; /**< The start block of the current graph. */
2610 * Block-Walker: fix all stack offsets for all blocks
2611 * except the start block
2613 static void stack_bias_walker(ir_node *bl, void *data)
2615 struct bias_walk *bw = data;
2616 if (bl != bw->start_block) {
2617 process_stack_bias(bw->env, bl, bw->start_block_bias);
2622 * Walker: finally lower all Sels of outer frame or parameter
2625 static void lower_outer_frame_sels(ir_node *sel, void *ctx) {
2626 be_abi_irg_t *env = ctx;
2634 ent = get_Sel_entity(sel);
2635 owner = get_entity_owner(ent);
2636 ptr = get_Sel_ptr(sel);
2638 if (owner == env->frame.frame_type || owner == env->frame.arg_type) {
2639 /* found access to outer frame or arguments */
2640 int offset = get_stack_entity_offset(&env->frame, ent, 0);
2643 ir_node *bl = get_nodes_block(sel);
2644 dbg_info *dbgi = get_irn_dbg_info(sel);
2645 ir_mode *mode = get_irn_mode(sel);
2646 ir_mode *mode_UInt = get_reference_mode_unsigned_eq(mode);
2647 ir_node *cnst = new_r_Const_long(current_ir_graph, mode_UInt, offset);
2649 ptr = new_rd_Add(dbgi, current_ir_graph, bl, ptr, cnst, mode);
2655 void be_abi_fix_stack_bias(be_abi_irg_t *env)
2657 ir_graph *irg = env->birg->irg;
2660 struct bias_walk bw;
2662 stack_frame_compute_initial_offset(&env->frame);
2663 // stack_layout_dump(stdout, frame);
2665 /* Determine the stack bias at the end of the start block. */
2666 bw.start_block_bias = process_stack_bias(env, get_irg_start_block(irg), env->frame.initial_bias);
2667 bw.between_size = get_type_size_bytes(env->frame.between_type);
2669 /* fix the bias is all other blocks */
2671 bw.start_block = get_irg_start_block(irg);
2672 irg_block_walk_graph(irg, stack_bias_walker, NULL, &bw);
2674 /* fix now inner functions: these still have Sel node to outer
2675 frame and parameter entities */
2676 frame_tp = get_irg_frame_type(irg);
2677 for (i = get_class_n_members(frame_tp) - 1; i >= 0; --i) {
2678 ir_entity *ent = get_class_member(frame_tp, i);
2680 if (is_method_entity(ent) && get_entity_peculiarity(ent) != peculiarity_description) {
2681 ir_graph *irg = get_entity_irg(ent);
2683 irg_walk_graph(irg, NULL, lower_outer_frame_sels, env);
2688 ir_node *be_abi_get_callee_save_irn(be_abi_irg_t *abi, const arch_register_t *reg)
2690 assert(arch_register_type_is(reg, callee_save));
2691 assert(pmap_contains(abi->regs, (void *) reg));
2692 return pmap_get(abi->regs, (void *) reg);
2695 ir_node *be_abi_get_ignore_irn(be_abi_irg_t *abi, const arch_register_t *reg)
2697 assert(arch_register_type_is(reg, ignore));
2698 assert(pmap_contains(abi->regs, (void *) reg));
2699 return pmap_get(abi->regs, (void *) reg);
2703 * Returns non-zero if the ABI has omitted the frame pointer in
2704 * the current graph.
2706 int be_abi_omit_fp(const be_abi_irg_t *abi)
2708 return abi->call->flags.bits.try_omit_fp;