}
#if 0 /* Old version. Avoids Ids.
- This is not necessary: we do a postwalk, and get_irn_n
+ This is not necessary: we do a post walk, and get_irn_n
removes ids anyways. So it's much cheaper to call the
optimization less often and use the exchange() algorithm. */
static void
set_irg_loopinfo_inconsistent(current_ir_graph);
- /* Clean the value_table in irg for the cse. */
+ /* Clean the value_table in irg for the CSE. */
del_identities(current_ir_graph->value_table);
current_ir_graph->value_table = new_identities();
for (i = -1; i < irn_arity; i++)
set_irn_n (nn, i, get_new_node(get_irn_n(n, i)));
}
- /* Now the new node is complete. We can add it to the hash table for cse.
+ /* Now the new node is complete. We can add it to the hash table for CSE.
@@@ inlinening aborts if we identify End. Why? */
if(get_irn_op(nn) != op_End)
add_identities (current_ir_graph->value_table, nn);
* from block nodes and the corresponding inputs from Phi nodes.
* Merges single exit blocks with single entry blocks and removes
* 1-input Phis.
- * Adds all new nodes to a new hash table for cse. Does not
- * perform cse, so the hash table might contain common subexpressions.
+ * Adds all new nodes to a new hash table for CSE. Does not
+ * perform CSE, so the hash table might contain common subexpressions.
*/
void
dead_node_elimination(ir_graph *irg) {
}
/**
- * Relink bad predeseccors of a block and store the old in array to the
+ * 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.
int i, new_irn_n, old_irn_arity, new_irn_arity = 0;
/* if link field of block is NULL, look for bad predecessors otherwise
- this is allready done */
+ this is already done */
if (get_irn_op(n) == op_Block &&
get_irn_link(n) == NULL) {
keep the old one to update Phis. */
new_in = NEW_ARR_D (ir_node *, current_ir_graph->obst, (new_irn_arity+1));
- /* set new predeseccors in array */
+ /* set new predecessors in array */
new_in[0] = NULL;
new_irn_n = 1;
for (i = 0; i < old_irn_arity; i++) {
} /* Block is not relinked */
}
-/*
- * Relinks Bad predecesors from Bocks and Phis called by walker
+/**
+ * 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 Phinode, call also the relinking
+ * 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 Phinode.
+ * 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 predeseccors of a block */
+ /* 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 predeseccors of phi's block */
+ /* 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 predeseccors if count of predeseccors changed */
+ /* Relink Phi predecessors if count of predecessors changed */
if (old_irn_arity != ARR_LEN(get_irn_in(block))) {
- /* set new predeseccors in array
+ /* set new predecessors in array
n->in[0] remains the same block */
new_irn_arity = 1;
for(i = 1; i < old_irn_arity; i++)
}
/*
- * Removes Bad Bad predecesors from Blocks and the corresponding
+ * 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
}
#endif
- /* -- Turn cse back on. -- */
+ /* -- Turn CSE back on. -- */
set_optimize(rem_opt);
return 1;
int n_callers_orig; /**< for statistics */
} inline_irg_env;
+/**
+ * Allocate a new nvironment for inlining.
+ */
static inline_irg_env *new_inline_irg_env(void) {
- inline_irg_env *env = xmalloc(sizeof(*env));
- env->n_nodes = -2; /* uncount Start, End */
- env->n_nodes_orig = -2; /* uncount Start, End */
- env->call_nodes = eset_create();
- env->n_call_nodes = 0;
+ inline_irg_env *env = xmalloc(sizeof(*env));
+ env->n_nodes = -2; /* do not count count Start, End */
+ env->n_nodes_orig = -2; /* do not count Start, End */
+ env->call_nodes = eset_create();
+ env->n_call_nodes = 0;
env->n_call_nodes_orig = 0;
- env->n_callers = 0;
- env->n_callers_orig = 0;
+ env->n_callers = 0;
+ env->n_callers_orig = 0;
return env;
}
+/**
+ * destroy an environment for inlining.
+ */
static void free_inline_irg_env(inline_irg_env *env) {
eset_destroy(env->call_nodes);
free(env);
}
+/**
+ * post-walker: collect all calls in the inline-environment
+ * of a graph and sum some statistics.
+ */
static void collect_calls2(ir_node *call, void *env) {
inline_irg_env *x = (inline_irg_env *)env;
ir_op *op = get_irn_op(call);
ir_graph *callee;
- /* count nodes in irg */
+ /* count meaningful nodes in irg */
if (op != op_Proj && op != op_Tuple && op != op_Sync) {
x->n_nodes++;
x->n_nodes_orig++;
/* count all static callers */
callee = get_call_called_irg(call);
if (callee) {
- ((inline_irg_env *)get_irg_link(callee))->n_callers++;
- ((inline_irg_env *)get_irg_link(callee))->n_callers_orig++;
+ inline_irg_env *callee_env = get_irg_link(callee);
+ callee_env->n_callers++;
+ callee_env->n_callers_orig++;
}
}
+/**
+ * Returns TRUE if the number of callers in 0 in the irg's environment,
+ * hence this irg is a leave.
+ */
INLINE static int is_leave(ir_graph *irg) {
return (((inline_irg_env *)get_irg_link(irg))->n_call_nodes == 0);
}
+/**
+ * Returns TRUE if the number of callers is smaller size in the irg's environment.
+ */
INLINE static int is_smaller(ir_graph *callee, int size) {
return (((inline_irg_env *)get_irg_link(callee))->n_nodes < size);
}
for (call = eset_first(env->call_nodes); call; call = eset_next(env->call_nodes)) {
ir_graph *callee;
- if (get_irn_op(call) == op_Tuple) continue; /* We already inlined. */
+ if (get_irn_op(call) == op_Tuple) continue; /* We already have inlined this call. */
callee = get_call_called_irg(call);
if (env->n_nodes > maxsize) continue; // break;
return calc_dca(dca, block);
}
+/* FIXME: the name clashes here with the function from ana/field_temperature.c
+ * please rename. */
static INLINE int get_irn_loop_depth(ir_node *n) {
return get_loop_depth(get_irn_loop(n));
}
* `optimal' Block between the latest and earliest legal block.
* The `optimal' block is the dominance-deepest block of those
* with the least loop-nesting-depth. This places N out of as many
- * loops as possible and then makes it as control dependant as
+ * loops as possible and then makes it as control dependent as
* possible.
*/
static void
}
/* Add predecessors of all non-floating nodes on list. (Those of floating
- nodes are placeded already and therefore are marked.) */
+ nodes are placeed already and therefore are marked.) */
for (i = 0; i < get_irn_n_outs(n); i++) {
ir_node *succ = get_irn_out(n, i);
if (irn_not_visited(get_irn_out(n, i))) {