-void
-dead_node_elimination(ir_graph *irg) {
- if (get_opt_optimize() && get_opt_dead_node_elimination()) {
- ir_graph *rem;
- int rem_ipview = get_interprocedural_view();
- struct obstack *graveyard_obst = NULL;
- struct obstack *rebirth_obst = NULL;
- assert(! edges_activated(irg) && "dead node elimination requires disabled edges");
-
- /* inform statistics that we started a dead-node elimination run */
- hook_dead_node_elim(irg, 1);
-
- /* Remember external state of current_ir_graph. */
- rem = current_ir_graph;
- current_ir_graph = irg;
- set_interprocedural_view(0);
-
- assert(get_irg_phase_state(irg) != phase_building);
-
- /* Handle graph state */
- free_callee_info(irg);
- free_irg_outs(irg);
- free_trouts();
-
- /* @@@ so far we loose loops when copying */
- free_loop_information(irg);
-
- set_irg_doms_inconsistent(irg);
-
- /* A quiet place, where the old obstack can rest in peace,
- until it will be cremated. */
- graveyard_obst = irg->obst;
-
- /* A new obstack, where the reachable nodes will be copied to. */
- rebirth_obst = xmalloc(sizeof(*rebirth_obst));
- irg->obst = rebirth_obst;
- obstack_init(irg->obst);
- irg->last_node_idx = 0;
-
- /* We also need a new value table for CSE */
- del_identities(irg->value_table);
- irg->value_table = new_identities();
-
- /* Copy the graph from the old to the new obstack */
- copy_graph_env(/*copy_node_nr=*/1);
-
- /* Free memory from old unoptimized obstack */
- obstack_free(graveyard_obst, 0); /* First empty the obstack ... */
- xfree (graveyard_obst); /* ... then free it. */
-
- /* inform statistics that the run is over */
- hook_dead_node_elim(irg, 0);
-
- current_ir_graph = rem;
- set_interprocedural_view(rem_ipview);
- }
-}
-
-/**
- * Relink bad predecessors of a block and store the old in array to the
- * link field. This function is called by relink_bad_predecessors().
- * The array of link field starts with the block operand at position 0.
- * If block has bad predecessors, create a new in array without bad preds.
- * Otherwise let in array untouched.
- */
-static void relink_bad_block_predecessors(ir_node *n, void *env) {
- ir_node **new_in, *irn;
- int i, new_irn_n, old_irn_arity, new_irn_arity = 0;
- (void) env;
-
- /* if link field of block is NULL, look for bad predecessors otherwise
- this is already done */
- if (get_irn_op(n) == op_Block &&
- get_irn_link(n) == NULL) {
-
- /* save old predecessors in link field (position 0 is the block operand)*/
- set_irn_link(n, get_irn_in(n));
-
- /* count predecessors without bad nodes */
- old_irn_arity = get_irn_arity(n);
- for (i = 0; i < old_irn_arity; i++)
- if (!is_Bad(get_irn_n(n, i))) new_irn_arity++;
-
- /* arity changing: set new predecessors without bad nodes */
- if (new_irn_arity < old_irn_arity) {
- /* Get new predecessor array. We do not resize the array, as we must
- keep the old one to update Phis. */
- new_in = NEW_ARR_D (ir_node *, current_ir_graph->obst, (new_irn_arity+1));
-
- /* set new predecessors in array */
- new_in[0] = NULL;
- new_irn_n = 1;
- for (i = 0; i < old_irn_arity; i++) {
- irn = get_irn_n(n, i);
- if (!is_Bad(irn)) {
- new_in[new_irn_n] = irn;
- is_backedge(n, i) ? set_backedge(n, new_irn_n-1) : set_not_backedge(n, new_irn_n-1);
- ++new_irn_n;
- }
- }
- /* ARR_SETLEN(int, n->attr.block.backedge, new_irn_arity); */
- ARR_SHRINKLEN(n->attr.block.backedge, new_irn_arity);
- n->in = new_in;
- } /* ir node has bad predecessors */
- } /* Block is not relinked */
-}
-
-/**
- * Relinks Bad predecessors from Blocks and Phis called by walker
- * remove_bad_predecesors(). If n is a Block, call
- * relink_bad_block_redecessors(). If n is a Phi-node, call also the relinking
- * function of Phi's Block. If this block has bad predecessors, relink preds
- * of the Phi-node.
- */
-static void relink_bad_predecessors(ir_node *n, void *env) {
- ir_node *block, **old_in;
- int i, old_irn_arity, new_irn_arity;
-
- /* relink bad predecessors of a block */
- if (get_irn_op(n) == op_Block)
- relink_bad_block_predecessors(n, env);
-
- /* If Phi node relink its block and its predecessors */
- if (get_irn_op(n) == op_Phi) {
-
- /* Relink predecessors of phi's block */
- block = get_nodes_block(n);
- if (get_irn_link(block) == NULL)
- relink_bad_block_predecessors(block, env);
-
- old_in = (ir_node **)get_irn_link(block); /* Of Phi's Block */
- old_irn_arity = ARR_LEN(old_in);
-
- /* Relink Phi predecessors if count of predecessors changed */
- if (old_irn_arity != ARR_LEN(get_irn_in(block))) {
- /* set new predecessors in array
- n->in[0] remains the same block */
- new_irn_arity = 1;
- for(i = 1; i < old_irn_arity; i++)
- if (!is_Bad((ir_node *)old_in[i])) {
- n->in[new_irn_arity] = n->in[i];
- is_backedge(n, i) ? set_backedge(n, new_irn_arity) : set_not_backedge(n, new_irn_arity);
- ++new_irn_arity;
- }
-
- ARR_SETLEN(ir_node *, n->in, new_irn_arity);
- ARR_SETLEN(int, n->attr.phi_backedge, new_irn_arity);
- }
- } /* n is a Phi node */
-}
-
-/*
- * Removes Bad Bad predecessors from Blocks and the corresponding
- * inputs to Phi nodes as in dead_node_elimination but without
- * copying the graph.
- * On walking up set the link field to NULL, on walking down call
- * relink_bad_predecessors() (This function stores the old in array
- * to the link field and sets a new in array if arity of predecessors
- * changes).
- */
-void remove_bad_predecessors(ir_graph *irg) {
- irg_walk_graph(irg, firm_clear_link, relink_bad_predecessors, NULL);
-}
-
-
-/*
- __ _ __ __
- (_ __ o _ | \/ |_
- __)|_| | \_/ | \_/(/_ |_/\__|__
-
- The following stuff implements a facility that automatically patches
- registered ir_node pointers to the new node when a dead node elimination occurs.
-*/
-
-struct _survive_dce_t {
- struct obstack obst;
- pmap *places;
- pmap *new_places;
- hook_entry_t dead_node_elim;
- hook_entry_t dead_node_elim_subst;
-};
-
-typedef struct _survive_dce_list_t {
- struct _survive_dce_list_t *next;
- ir_node **place;
-} survive_dce_list_t;
-
-static void dead_node_hook(void *context, ir_graph *irg, int start) {
- survive_dce_t *sd = context;
- (void) irg;
-
- /* Create a new map before the dead node elimination is performed. */
- if (start) {
- sd->new_places = pmap_create_ex(pmap_count(sd->places));
- } else {
- /* Patch back all nodes if dead node elimination is over and something is to be done. */
- pmap_destroy(sd->places);
- sd->places = sd->new_places;
- sd->new_places = NULL;
- }
-}
-
-/**
- * Hook called when dead node elimination replaces old by nw.
- */
-static void dead_node_subst_hook(void *context, ir_graph *irg, ir_node *old, ir_node *nw) {
- survive_dce_t *sd = context;
- survive_dce_list_t *list = pmap_get(sd->places, old);
- (void) irg;
-
- /* If the node is to be patched back, write the new address to all registered locations. */
- if (list) {
- survive_dce_list_t *p;
-
- for (p = list; p; p = p->next)
- *(p->place) = nw;
-
- pmap_insert(sd->new_places, nw, list);
- }
-}
-
-/**
- * Make a new Survive DCE environment.
- */
-survive_dce_t *new_survive_dce(void) {
- survive_dce_t *res = xmalloc(sizeof(res[0]));
- obstack_init(&res->obst);
- res->places = pmap_create();
- res->new_places = NULL;
-
- res->dead_node_elim.hook._hook_dead_node_elim = dead_node_hook;
- res->dead_node_elim.context = res;
- res->dead_node_elim.next = NULL;
-
- res->dead_node_elim_subst.hook._hook_dead_node_elim_subst = dead_node_subst_hook;
- res->dead_node_elim_subst.context = res;
- res->dead_node_elim_subst.next = NULL;
-
-#ifndef FIRM_ENABLE_HOOKS
- assert(0 && "need hooks enabled");
-#endif
-
- register_hook(hook_dead_node_elim, &res->dead_node_elim);
- register_hook(hook_dead_node_elim_subst, &res->dead_node_elim_subst);
- return res;
-}
-
-/**
- * Free a Survive DCE environment.
- */
-void free_survive_dce(survive_dce_t *sd) {
- obstack_free(&sd->obst, NULL);
- pmap_destroy(sd->places);
- unregister_hook(hook_dead_node_elim, &sd->dead_node_elim);
- unregister_hook(hook_dead_node_elim_subst, &sd->dead_node_elim_subst);
- xfree(sd);
-}
-
-/**
- * Register a node pointer to be patched upon DCE.
- * When DCE occurs, the node pointer specified by @p place will be
- * patched to the new address of the node it is pointing to.
- *
- * @param sd The Survive DCE environment.
- * @param place The address of the node pointer.
- */
-void survive_dce_register_irn(survive_dce_t *sd, ir_node **place) {
- if (*place != NULL) {
- ir_node *irn = *place;
- survive_dce_list_t *curr = pmap_get(sd->places, irn);
- survive_dce_list_t *nw = obstack_alloc(&sd->obst, sizeof(nw[0]));
-
- nw->next = curr;
- nw->place = place;
-
- pmap_insert(sd->places, irn, nw);
- }
-}
-
-/*--------------------------------------------------------------------*/
-/* Functionality for inlining */
-/*--------------------------------------------------------------------*/
-
-/**
- * Copy node for inlineing. Updates attributes that change when
- * inlineing but not for dead node elimination.
- *
- * Copies the node by calling copy_node() and then updates the entity if
- * it's a local one. env must be a pointer of the frame type of the
- * inlined procedure. The new entities must be in the link field of
- * the entities.
- */
-static INLINE void
-copy_node_inline(ir_node *n, void *env) {
- ir_node *nn;
- ir_type *frame_tp = (ir_type *)env;
-
- copy_node(n, NULL);
- if (get_irn_op(n) == op_Sel) {
- nn = get_new_node (n);
- assert(is_Sel(nn));
- if (get_entity_owner(get_Sel_entity(n)) == frame_tp) {
- set_Sel_entity(nn, get_entity_link(get_Sel_entity(n)));
- }
- } else if (get_irn_op(n) == op_Block) {
- nn = get_new_node (n);
- nn->attr.block.irg = current_ir_graph;
- }
-}
-
-/**
- * Walker: checks if P_value_arg_base is used.
- */
-static void find_addr(ir_node *node, void *env) {
- int *allow_inline = env;
- if (is_Proj(node) && get_irn_op(get_Proj_pred(node)) == op_Start) {
- if (get_Proj_proj(node) == pn_Start_P_value_arg_base)
- *allow_inline = 0;
- }
-}
-
-/**
- * Check if we can inline a given call.
- * Currently, we cannot inline two cases:
- * - call with compound arguments
- * - graphs that take the address of a parameter
- *
- * check these conditions here
- */
-static int can_inline(ir_node *call, ir_graph *called_graph) {
- ir_type *call_type = get_Call_type(call);
- int params, ress, i, res;
- assert(is_Method_type(call_type));
-
- params = get_method_n_params(call_type);
- ress = get_method_n_ress(call_type);
-
- /* check parameters for compound arguments */
- for (i = 0; i < params; ++i) {
- ir_type *p_type = get_method_param_type(call_type, i);
-
- if (is_compound_type(p_type))
- return 0;
- }
-
- /* check results for compound arguments */
- for (i = 0; i < ress; ++i) {
- ir_type *r_type = get_method_res_type(call_type, i);
-
- if (is_compound_type(r_type))
- return 0;
- }
-
- res = 1;
- irg_walk_graph(called_graph, find_addr, NULL, &res);
-
- return res;
-}
-
-enum exc_mode {
- exc_handler = 0, /**< There is a handler. */
- exc_to_end = 1, /**< Branches to End. */
- exc_no_handler = 2 /**< Exception handling not represented. */
-};
-
-/* Inlines a method at the given call site. */
-int inline_method(ir_node *call, ir_graph *called_graph) {
- ir_node *pre_call;
- ir_node *post_call, *post_bl;
- ir_node *in[pn_Start_max];
- ir_node *end, *end_bl;
- ir_node **res_pred;
- ir_node **cf_pred;
- ir_node *ret, *phi;
- int arity, n_ret, n_exc, n_res, i, j, rem_opt, irn_arity;
- enum exc_mode exc_handling;
- ir_type *called_frame;
- irg_inline_property prop = get_irg_inline_property(called_graph);
-
- if ( (prop < irg_inline_forced) &&
- (!get_opt_optimize() || !get_opt_inline() || (prop == irg_inline_forbidden))) return 0;
-
- /* Do not inline variadic functions. */
- if (get_method_variadicity(get_entity_type(get_irg_entity(called_graph))) == variadicity_variadic)
- return 0;
-
- assert(get_method_n_params(get_entity_type(get_irg_entity(called_graph))) ==
- get_method_n_params(get_Call_type(call)));
-
- /*
- * currently, we cannot inline two cases:
- * - call with compound arguments
- * - graphs that take the address of a parameter
- */
- if (! can_inline(call, called_graph))
- return 0;
-
- /* -- Turn off optimizations, this can cause problems when allocating new nodes. -- */
- rem_opt = get_opt_optimize();
- set_optimize(0);
-
- /* Handle graph state */
- assert(get_irg_phase_state(current_ir_graph) != phase_building);
- assert(get_irg_pinned(current_ir_graph) == op_pin_state_pinned);
- assert(get_irg_pinned(called_graph) == op_pin_state_pinned);
- set_irg_outs_inconsistent(current_ir_graph);
- set_irg_extblk_inconsistent(current_ir_graph);
- set_irg_doms_inconsistent(current_ir_graph);
- set_irg_loopinfo_inconsistent(current_ir_graph);
- set_irg_callee_info_state(current_ir_graph, irg_callee_info_inconsistent);
-
- /* -- Check preconditions -- */
- assert(is_Call(call));
- /* @@@ does not work for InterfaceIII.java after cgana
- assert(get_Call_type(call) == get_entity_type(get_irg_entity(called_graph)));
- assert(smaller_type(get_entity_type(get_irg_entity(called_graph)),
- get_Call_type(call)));
- */
- if (called_graph == current_ir_graph) {
- set_optimize(rem_opt);
- return 0;
- }
-
- /* here we know we WILL inline, so inform the statistics */
- hook_inline(call, called_graph);
-
- /* -- Decide how to handle exception control flow: Is there a handler
- for the Call node, or do we branch directly to End on an exception?
- exc_handling:
- 0 There is a handler.
- 1 Branches to End.
- 2 Exception handling not represented in Firm. -- */
- {
- ir_node *proj, *Mproj = NULL, *Xproj = NULL;
- for (proj = get_irn_link(call); proj; proj = get_irn_link(proj)) {
- long proj_nr = get_Proj_proj(proj);
- if (proj_nr == pn_Call_X_except) Xproj = proj;
- if (proj_nr == pn_Call_M_except) Mproj = proj;
- }
- if (Mproj) { assert(Xproj); exc_handling = exc_handler; } /* Mproj */
- else if (Xproj) { exc_handling = exc_to_end; } /* !Mproj && Xproj */
- else { exc_handling = exc_no_handler; } /* !Mproj && !Xproj */
- }
-
- /* --
- the procedure and later replaces the Start node of the called graph.
- Post_call is the old Call node and collects the results of the called
- graph. Both will end up being a tuple. -- */
- post_bl = get_nodes_block(call);
- set_irg_current_block(current_ir_graph, post_bl);
- /* XxMxPxPxPxT of Start + parameter of Call */
- in[pn_Start_X_initial_exec] = new_Jmp();
- in[pn_Start_M] = get_Call_mem(call);
- in[pn_Start_P_frame_base] = get_irg_frame(current_ir_graph);
- in[pn_Start_P_globals] = get_irg_globals(current_ir_graph);
- in[pn_Start_P_tls] = get_irg_tls(current_ir_graph);
- in[pn_Start_T_args] = new_Tuple(get_Call_n_params(call), get_Call_param_arr(call));
- /* in[pn_Start_P_value_arg_base] = ??? */
- assert(pn_Start_P_value_arg_base == pn_Start_max - 1 && "pn_Start_P_value_arg_base not supported, fix");
- pre_call = new_Tuple(pn_Start_max - 1, in);
- post_call = call;
-
- /* --
- The new block gets the ins of the old block, pre_call and all its
- predecessors and all Phi nodes. -- */
- part_block(pre_call);
-
- /* -- Prepare state for dead node elimination -- */
- /* Visited flags in calling irg must be >= flag in called irg.
- Else walker and arity computation will not work. */
- if (get_irg_visited(current_ir_graph) <= get_irg_visited(called_graph))
- set_irg_visited(current_ir_graph, get_irg_visited(called_graph)+1);
- if (get_irg_block_visited(current_ir_graph)< get_irg_block_visited(called_graph))
- set_irg_block_visited(current_ir_graph, get_irg_block_visited(called_graph));
- /* Set pre_call as new Start node in link field of the start node of
- calling graph and pre_calls block as new block for the start block
- of calling graph.
- Further mark these nodes so that they are not visited by the
- copying. */
- set_irn_link(get_irg_start(called_graph), pre_call);
- set_irn_visited(get_irg_start(called_graph), get_irg_visited(current_ir_graph));
- set_irn_link(get_irg_start_block(called_graph), get_nodes_block(pre_call));
- set_irn_visited(get_irg_start_block(called_graph), get_irg_visited(current_ir_graph));
- set_irn_link(get_irg_bad(called_graph), get_irg_bad(current_ir_graph));
- set_irn_visited(get_irg_bad(called_graph), get_irg_visited(current_ir_graph));
-
- /* Initialize for compaction of in arrays */
- inc_irg_block_visited(current_ir_graph);
-
- /* -- Replicate local entities of the called_graph -- */
- /* copy the entities. */
- called_frame = get_irg_frame_type(called_graph);
- for (i = 0; i < get_class_n_members(called_frame); i++) {
- ir_entity *new_ent, *old_ent;
- old_ent = get_class_member(called_frame, i);
- new_ent = copy_entity_own(old_ent, get_cur_frame_type());
- set_entity_link(old_ent, new_ent);
- }
-
- /* visited is > than that of called graph. With this trick visited will
- remain unchanged so that an outer walker, e.g., searching the call nodes
- to inline, calling this inline will not visit the inlined nodes. */
- set_irg_visited(current_ir_graph, get_irg_visited(current_ir_graph)-1);
-
- /* -- Performing dead node elimination inlines the graph -- */
- /* Copies the nodes to the obstack of current_ir_graph. Updates links to new
- entities. */
- irg_walk(get_irg_end(called_graph), copy_node_inline, copy_preds,
- get_irg_frame_type(called_graph));
-
- /* Repair called_graph */
- set_irg_visited(called_graph, get_irg_visited(current_ir_graph));
- set_irg_block_visited(called_graph, get_irg_block_visited(current_ir_graph));
- set_Block_block_visited(get_irg_start_block(called_graph), 0);
-
- /* -- Merge the end of the inlined procedure with the call site -- */
- /* We will turn the old Call node into a Tuple with the following
- predecessors:
- -1: Block of Tuple.
- 0: Phi of all Memories of Return statements.
- 1: Jmp from new Block that merges the control flow from all exception
- predecessors of the old end block.
- 2: Tuple of all arguments.
- 3: Phi of Exception memories.
- In case the old Call directly branches to End on an exception we don't
- need the block merging all exceptions nor the Phi of the exception
- memories.
- */
-
- /* -- Precompute some values -- */
- end_bl = get_new_node(get_irg_end_block(called_graph));
- end = get_new_node(get_irg_end(called_graph));
- arity = get_irn_arity(end_bl); /* arity = n_exc + n_ret */
- n_res = get_method_n_ress(get_Call_type(call));
-
- res_pred = xmalloc(n_res * sizeof(*res_pred));
- cf_pred = xmalloc(arity * sizeof(*res_pred));
-
- set_irg_current_block(current_ir_graph, post_bl); /* just to make sure */
-
- /* -- archive keepalives -- */
- irn_arity = get_irn_arity(end);
- for (i = 0; i < irn_arity; i++) {
- ir_node *ka = get_End_keepalive(end, i);
- if (! is_Bad(ka))
- add_End_keepalive(get_irg_end(current_ir_graph), ka);
- }
-
- /* The new end node will die. We need not free as the in array is on the obstack:
- copy_node() only generated 'D' arrays. */
-
- /* -- Replace Return nodes by Jump nodes. -- */
- n_ret = 0;
- for (i = 0; i < arity; i++) {
- ir_node *ret;
- ret = get_irn_n(end_bl, i);
- if (is_Return(ret)) {
- cf_pred[n_ret] = new_r_Jmp(current_ir_graph, get_nodes_block(ret));
- n_ret++;
- }
- }
- set_irn_in(post_bl, n_ret, cf_pred);
-
- /* -- Build a Tuple for all results of the method.
- Add Phi node if there was more than one Return. -- */
- turn_into_tuple(post_call, pn_Call_max);
- /* First the Memory-Phi */
- n_ret = 0;
- for (i = 0; i < arity; i++) {
- ret = get_irn_n(end_bl, i);
- if (is_Return(ret)) {
- cf_pred[n_ret] = get_Return_mem(ret);
- n_ret++;
- }
- }
- phi = new_Phi(n_ret, cf_pred, mode_M);
- set_Tuple_pred(call, pn_Call_M_regular, phi);
- /* Conserve Phi-list for further inlinings -- but might be optimized */
- if (get_nodes_block(phi) == post_bl) {
- set_irn_link(phi, get_irn_link(post_bl));
- set_irn_link(post_bl, phi);
- }
- /* Now the real results */
- if (n_res > 0) {
- for (j = 0; j < n_res; j++) {
- n_ret = 0;
- for (i = 0; i < arity; i++) {
- ret = get_irn_n(end_bl, i);
- if (get_irn_op(ret) == op_Return) {
- cf_pred[n_ret] = get_Return_res(ret, j);
- n_ret++;
- }
- }
- if (n_ret > 0)
- phi = new_Phi(n_ret, cf_pred, get_irn_mode(cf_pred[0]));
- else
- phi = new_Bad();
- res_pred[j] = phi;
- /* Conserve Phi-list for further inlinings -- but might be optimized */
- if (get_nodes_block(phi) == post_bl) {
- set_irn_link(phi, get_irn_link(post_bl));
- set_irn_link(post_bl, phi);
- }
- }
- set_Tuple_pred(call, pn_Call_T_result, new_Tuple(n_res, res_pred));
- } else {
- set_Tuple_pred(call, pn_Call_T_result, new_Bad());
- }
-
- /* For now, we cannot inline calls with value_base */
- set_Tuple_pred(call, pn_Call_P_value_res_base, new_Bad());
-
- /* Finally the exception control flow.
- We have two (three) possible situations:
- First if the Call branches to an exception handler: We need to add a Phi node to
- collect the memory containing the exception objects. Further we need
- to add another block to get a correct representation of this Phi. To
- this block we add a Jmp that resolves into the X output of the Call
- when the Call is turned into a tuple.
- Second the Call branches to End, the exception is not handled. Just
- add all inlined exception branches to the End node.
- Third: there is no Exception edge at all. Handle as case two. */
- if (exc_handling == exc_handler) {
- n_exc = 0;
- for (i = 0; i < arity; i++) {
- ir_node *ret, *irn;
- ret = get_irn_n(end_bl, i);
- irn = skip_Proj(ret);
- if (is_fragile_op(irn) || (get_irn_op(irn) == op_Raise)) {
- cf_pred[n_exc] = ret;
- ++n_exc;
- }
- }
- if (n_exc > 0) {
- new_Block(n_exc, cf_pred); /* watch it: current_block is changed! */
- set_Tuple_pred(call, pn_Call_X_except, new_Jmp());
- /* The Phi for the memories with the exception objects */
- n_exc = 0;
- for (i = 0; i < arity; i++) {
- ir_node *ret;
- ret = skip_Proj(get_irn_n(end_bl, i));
- if (is_Call(ret)) {
- cf_pred[n_exc] = new_r_Proj(current_ir_graph, get_nodes_block(ret), ret, mode_M, 3);
- n_exc++;
- } else if (is_fragile_op(ret)) {
- /* We rely that all cfops have the memory output at the same position. */
- cf_pred[n_exc] = new_r_Proj(current_ir_graph, get_nodes_block(ret), ret, mode_M, 0);
- n_exc++;
- } else if (get_irn_op(ret) == op_Raise) {
- cf_pred[n_exc] = new_r_Proj(current_ir_graph, get_nodes_block(ret), ret, mode_M, 1);
- n_exc++;
- }
- }
- set_Tuple_pred(call, pn_Call_M_except, new_Phi(n_exc, cf_pred, mode_M));
- } else {
- set_Tuple_pred(call, pn_Call_X_except, new_Bad());
- set_Tuple_pred(call, pn_Call_M_except, new_Bad());
- }
- set_Tuple_pred(call, pn_Call_X_regular, new_Bad());
- } else {
- ir_node *main_end_bl;
- int main_end_bl_arity;
- ir_node **end_preds;
-
- /* assert(exc_handling == 1 || no exceptions. ) */
- n_exc = 0;
- for (i = 0; i < arity; i++) {
- ir_node *ret = get_irn_n(end_bl, i);
- ir_node *irn = skip_Proj(ret);
-
- if (is_fragile_op(irn) || (get_irn_op(irn) == op_Raise)) {
- cf_pred[n_exc] = ret;
- n_exc++;
- }
- }
- main_end_bl = get_irg_end_block(current_ir_graph);
- main_end_bl_arity = get_irn_arity(main_end_bl);
- end_preds = xmalloc((n_exc + main_end_bl_arity) * sizeof(*end_preds));
-
- for (i = 0; i < main_end_bl_arity; ++i)
- end_preds[i] = get_irn_n(main_end_bl, i);
- for (i = 0; i < n_exc; ++i)
- end_preds[main_end_bl_arity + i] = cf_pred[i];
- set_irn_in(main_end_bl, n_exc + main_end_bl_arity, end_preds);
- set_Tuple_pred(call, pn_Call_X_regular, new_Bad());
- set_Tuple_pred(call, pn_Call_X_except, new_Bad());
- set_Tuple_pred(call, pn_Call_M_except, new_Bad());
- free(end_preds);
- }
- free(res_pred);
- free(cf_pred);
-
- /* -- Turn CSE back on. -- */
- set_optimize(rem_opt);
-
- return 1;
-}
-
-/********************************************************************/
-/* Apply inlineing to small methods. */
-/********************************************************************/
-
-/** Represents a possible inlinable call in a graph. */
-typedef struct _call_entry call_entry;
-struct _call_entry {
- ir_node *call; /**< the Call */
- ir_graph *callee; /**< the callee called here */
- call_entry *next; /**< for linking the next one */
-};
-
-/**
- * environment for inlining small irgs
- */
-typedef struct _inline_env_t {
- struct obstack obst; /**< an obstack where call_entries are allocated on. */
- call_entry *head; /**< the head of the call entry list */
- call_entry *tail; /**< the tail of the call entry list */
-} inline_env_t;