value_of_func value_of_ptr = default_value_of;
+/* * Set a new value_of function. */
void set_value_of_func(value_of_func func) {
if (func != NULL)
value_of_ptr = func;
/**
* Return the value of a Constant.
*/
-static tarval *computed_value_Const(ir_node *n) {
+static tarval *computed_value_Const(const ir_node *n) {
return get_Const_tarval(n);
} /* computed_value_Const */
/**
* Return the value of a 'sizeof', 'alignof' or 'offsetof' SymConst.
*/
-static tarval *computed_value_SymConst(ir_node *n) {
+static tarval *computed_value_SymConst(const ir_node *n) {
ir_type *type;
ir_entity *ent;
/**
* Return the value of an Add.
*/
-static tarval *computed_value_Add(ir_node *n) {
+static tarval *computed_value_Add(const ir_node *n) {
ir_node *a = get_Add_left(n);
ir_node *b = get_Add_right(n);
* Return the value of a Sub.
* Special case: a - a
*/
-static tarval *computed_value_Sub(ir_node *n) {
+static tarval *computed_value_Sub(const ir_node *n) {
ir_mode *mode = get_irn_mode(n);
ir_node *a = get_Sub_left(n);
ir_node *b = get_Sub_right(n);
* Return the value of a Carry.
* Special : a op 0, 0 op b
*/
-static tarval *computed_value_Carry(ir_node *n) {
+static tarval *computed_value_Carry(const ir_node *n) {
ir_node *a = get_binop_left(n);
ir_node *b = get_binop_right(n);
ir_mode *m = get_irn_mode(n);
* Return the value of a Borrow.
* Special : a op 0
*/
-static tarval *computed_value_Borrow(ir_node *n) {
+static tarval *computed_value_Borrow(const ir_node *n) {
ir_node *a = get_binop_left(n);
ir_node *b = get_binop_right(n);
ir_mode *m = get_irn_mode(n);
/**
* Return the value of an unary Minus.
*/
-static tarval *computed_value_Minus(ir_node *n) {
+static tarval *computed_value_Minus(const ir_node *n) {
ir_node *a = get_Minus_op(n);
tarval *ta = value_of(a);
/**
* Return the value of a Mul.
*/
-static tarval *computed_value_Mul(ir_node *n) {
+static tarval *computed_value_Mul(const ir_node *n) {
ir_node *a = get_Mul_left(n);
ir_node *b = get_Mul_right(n);
ir_mode *mode;
return tarval_bad;
} /* computed_value_Mul */
-/**
- * Return the value of a floating point Quot.
- */
-static tarval *computed_value_Quot(ir_node *n) {
- ir_node *a = get_Quot_left(n);
- ir_node *b = get_Quot_right(n);
-
- tarval *ta = value_of(a);
- tarval *tb = value_of(b);
-
- if ((ta != tarval_bad) && (tb != tarval_bad)) {
- if (tb != get_mode_null(get_tarval_mode(tb))) /* div by zero: return tarval_bad */
- return tarval_quo(ta, tb);
- }
- return tarval_bad;
-} /* computed_value_Quot */
-
-/**
- * Calculate the value of an integer Div of two nodes.
- * Special case: 0 / b
- */
-static tarval *do_computed_value_Div(ir_node *a, ir_node *b) {
- tarval *ta = value_of(a);
- tarval *tb = value_of(b);
-
- /* Compute c1 / c2 or 0 / a, a != 0 */
- if (ta != tarval_bad) {
- if ((tb != tarval_bad) && (tb != get_mode_null(get_irn_mode(b)))) /* div by zero: return tarval_bad */
- return tarval_div(ta, tb);
- else if (ta == get_mode_null(get_tarval_mode(ta))) /* 0 / b == 0 */
- return ta;
- }
- return tarval_bad;
-} /* do_computed_value_Div */
-
-/**
- * Return the value of an integer Div.
- */
-static tarval *computed_value_Div(ir_node *n) {
- return do_computed_value_Div(get_Div_left(n), get_Div_right(n));
-} /* computed_value_Div */
-
-/**
- * Calculate the value of an integer Mod of two nodes.
- * Special case: a % 1
- */
-static tarval *do_computed_value_Mod(ir_node *a, ir_node *b) {
- tarval *ta = value_of(a);
- tarval *tb = value_of(b);
-
- /* Compute c1 % c2 or a % 1 */
- if (tb != tarval_bad) {
- if ((ta != tarval_bad) && (tb != get_mode_null(get_tarval_mode(tb)))) /* div by zero: return tarval_bad */
- return tarval_mod(ta, tb);
- else if (tb == get_mode_one(get_tarval_mode(tb))) /* x mod 1 == 0 */
- return get_mode_null(get_irn_mode(a));
- }
- return tarval_bad;
-} /* do_computed_value_Mod */
-
-/**
- * Return the value of an integer Mod.
- */
-static tarval *computed_value_Mod(ir_node *n) {
- return do_computed_value_Mod(get_Mod_left(n), get_Mod_right(n));
-} /* computed_value_Mod */
-
/**
* Return the value of an Abs.
*/
-static tarval *computed_value_Abs(ir_node *n) {
+static tarval *computed_value_Abs(const ir_node *n) {
ir_node *a = get_Abs_op(n);
tarval *ta = value_of(a);
* Return the value of an And.
* Special case: a & 0, 0 & b
*/
-static tarval *computed_value_And(ir_node *n) {
+static tarval *computed_value_And(const ir_node *n) {
ir_node *a = get_And_left(n);
ir_node *b = get_And_right(n);
* Return the value of an Or.
* Special case: a | 1...1, 1...1 | b
*/
-static tarval *computed_value_Or(ir_node *n) {
+static tarval *computed_value_Or(const ir_node *n) {
ir_node *a = get_Or_left(n);
ir_node *b = get_Or_right(n);
/**
* Return the value of an Eor.
*/
-static tarval *computed_value_Eor(ir_node *n) {
+static tarval *computed_value_Eor(const ir_node *n) {
ir_node *a = get_Eor_left(n);
ir_node *b = get_Eor_right(n);
/**
* Return the value of a Not.
*/
-static tarval *computed_value_Not(ir_node *n) {
+static tarval *computed_value_Not(const ir_node *n) {
ir_node *a = get_Not_op(n);
tarval *ta = value_of(a);
/**
* Return the value of a Shl.
*/
-static tarval *computed_value_Shl(ir_node *n) {
+static tarval *computed_value_Shl(const ir_node *n) {
ir_node *a = get_Shl_left(n);
ir_node *b = get_Shl_right(n);
/**
* Return the value of a Shr.
*/
-static tarval *computed_value_Shr(ir_node *n) {
+static tarval *computed_value_Shr(const ir_node *n) {
ir_node *a = get_Shr_left(n);
ir_node *b = get_Shr_right(n);
/**
* Return the value of a Shrs.
*/
-static tarval *computed_value_Shrs(ir_node *n) {
+static tarval *computed_value_Shrs(const ir_node *n) {
ir_node *a = get_Shrs_left(n);
ir_node *b = get_Shrs_right(n);
/**
* Return the value of a Rotl.
*/
-static tarval *computed_value_Rotl(ir_node *n) {
+static tarval *computed_value_Rotl(const ir_node *n) {
ir_node *a = get_Rotl_left(n);
ir_node *b = get_Rotl_right(n);
/**
* Return the value of a Conv.
*/
-static tarval *computed_value_Conv(ir_node *n) {
+static tarval *computed_value_Conv(const ir_node *n) {
ir_node *a = get_Conv_op(n);
tarval *ta = value_of(a);
return tarval_bad;
} /* computed_value_Conv */
+/**
+ * Calculate the value of a Mux: can be evaluated, if the
+ * sel and the right input are known.
+ */
+static tarval *computed_value_Mux(const ir_node *n) {
+ ir_node *sel = get_Mux_sel(n);
+ tarval *ts = value_of(sel);
+
+ if (ts == get_tarval_b_true()) {
+ ir_node *v = get_Mux_true(n);
+ return value_of(v);
+ }
+ else if (ts == get_tarval_b_false()) {
+ ir_node *v = get_Mux_false(n);
+ return value_of(v);
+ }
+ return tarval_bad;
+} /* computed_value_Mux */
+
+/**
+ * Calculate the value of a Confirm: can be evaluated,
+ * if it has the form Confirm(x, '=', Const).
+ */
+static tarval *computed_value_Confirm(const ir_node *n) {
+ /*
+ * Beware: we might produce Phi(Confirm(x == true), Confirm(x == false)).
+ * Do NOT optimize them away (CondEval wants them), so wait until
+ * remove_confirm is activated.
+ */
+ if (get_opt_remove_confirm()) {
+ if (get_Confirm_cmp(n) == pn_Cmp_Eq) {
+ tarval *tv = value_of(get_Confirm_bound(n));
+ if (tv != tarval_bad)
+ return tv;
+ }
+ }
+ return value_of(get_Confirm_value(n));
+} /* computed_value_Confirm */
+
/**
* Return the value of a Proj(Cmp).
*
* only 1 is used.
* There are several case where we can evaluate a Cmp node, see later.
*/
-static tarval *computed_value_Proj_Cmp(ir_node *n) {
+static tarval *computed_value_Proj_Cmp(const ir_node *n) {
ir_node *a = get_Proj_pred(n);
ir_node *aa = get_Cmp_left(a);
ir_node *ab = get_Cmp_right(a);
* the Cmp result.
*/
else {
- ir_node *aaa = skip_Id(skip_Proj(aa));
- ir_node *aba = skip_Id(skip_Proj(ab));
+ ir_node *aaa = skip_Proj(aa);
+ ir_node *aba = skip_Proj(ab);
if ( ( (/* aa is ProjP and aaa is Alloc */
is_Proj(aa)
&& mode_is_reference(get_irn_mode(aa))
&& is_Alloc(aaa))
&& ( (/* ab is NULL */
- is_Const(ab)
- && mode_is_reference(get_irn_mode(ab))
- && is_Const_null(ab))
+ mode_is_reference(get_irn_mode(ab))
+ && tarval_is_null(tab))
|| (/* ab is other Alloc */
is_Proj(ab)
&& mode_is_reference(get_irn_mode(ab))
&& is_Alloc(aba)
&& (aaa != aba))))
|| (/* aa is NULL and aba is Alloc */
- is_Const(aa)
- && mode_is_reference(get_irn_mode(aa))
- && is_Const_null(aa)
+ mode_is_reference(get_irn_mode(aa))
+ && tarval_is_null(taa)
&& is_Proj(ab)
&& mode_is_reference(get_irn_mode(ab))
&& is_Alloc(aba)))
/* 3.: */
- return new_tarval_from_long(proj_nr & pn_Cmp_Ne, mode_b);
+ return new_tarval_from_long(proj_nr & pn_Cmp_Lg, mode_b);
}
}
return computed_value_Cmp_Confirm(a, aa, ab, proj_nr);
} /* computed_value_Proj_Cmp */
/**
- * Return the value of a Proj, handle Proj(Cmp), Proj(Div), Proj(Mod),
- * Proj(DivMod) and Proj(Quot).
+ * Return the value of a floating point Quot.
*/
-static tarval *computed_value_Proj(ir_node *n) {
- ir_node *a = get_Proj_pred(n);
- long proj_nr;
+static tarval *do_computed_value_Quot(const ir_node *a, const ir_node *b) {
+ tarval *ta = value_of(a);
+ tarval *tb = value_of(b);
- switch (get_irn_opcode(a)) {
- case iro_Cmp:
- return computed_value_Proj_Cmp(n);
-
- case iro_DivMod:
- /* compute either the Div or the Mod part */
- proj_nr = get_Proj_proj(n);
- if (proj_nr == pn_DivMod_res_div)
- return do_computed_value_Div(get_DivMod_left(a), get_DivMod_right(a));
- else if (proj_nr == pn_DivMod_res_mod)
- return do_computed_value_Mod(get_DivMod_left(a), get_DivMod_right(a));
- break;
+ /* cannot optimize 0 / b = 0 because of NaN */
+ if (ta != tarval_bad && tb != tarval_bad)
+ return tarval_quo(ta, tb);
+ return tarval_bad;
+} /* do_computed_value_Quot */
- case iro_Div:
- if (get_Proj_proj(n) == pn_Div_res)
- return computed_value(a);
- break;
+/**
+ * Calculate the value of an integer Div of two nodes.
+ * Special case: 0 / b
+ */
+static tarval *do_computed_value_Div(const ir_node *a, const ir_node *b) {
+ tarval *ta = value_of(a);
+ tarval *tb;
+ const ir_node *dummy;
- case iro_Mod:
- if (get_Proj_proj(n) == pn_Mod_res)
- return computed_value(a);
- break;
+ /* Compute c1 / c2 or 0 / a, a != 0 */
+ if (tarval_is_null(ta) && value_not_zero(b, &dummy))
+ return ta; /* 0 / b == 0 */
+ tb = value_of(b);
+ if (ta != tarval_bad && tb != tarval_bad)
+ return tarval_div(ta, tb);
+ return tarval_bad;
+} /* do_computed_value_Div */
- case iro_Quot:
- if (get_Proj_proj(n) == pn_Quot_res)
- return computed_value(a);
- break;
+/**
+ * Calculate the value of an integer Mod of two nodes.
+ * Special case: a % 1
+ */
+static tarval *do_computed_value_Mod(const ir_node *a, const ir_node *b) {
+ tarval *ta = value_of(a);
+ tarval *tb = value_of(b);
- default:
- return tarval_bad;
- }
+ /* Compute a % 1 or c1 % c2 */
+ if (tarval_is_one(tb))
+ return get_mode_null(get_irn_mode(a));
+ if (ta != tarval_bad && tb != tarval_bad)
+ return tarval_mod(ta, tb);
return tarval_bad;
-} /* computed_value_Proj */
+} /* do_computed_value_Mod */
/**
- * Calculate the value of a Mux: can be evaluated, if the
- * sel and the right input are known.
+ * Return the value of a Proj(DivMod).
*/
-static tarval *computed_value_Mux(ir_node *n) {
- ir_node *sel = get_Mux_sel(n);
- tarval *ts = value_of(sel);
+static tarval *computed_value_Proj_DivMod(const ir_node *n) {
+ long proj_nr = get_Proj_proj(n);
- if (ts == get_tarval_b_true()) {
- ir_node *v = get_Mux_true(n);
- return value_of(v);
+ /* compute either the Div or the Mod part */
+ if (proj_nr == pn_DivMod_res_div) {
+ const ir_node *a = get_Proj_pred(n);
+ return do_computed_value_Div(get_DivMod_left(a), get_DivMod_right(a));
+ } else if (proj_nr == pn_DivMod_res_mod) {
+ const ir_node *a = get_Proj_pred(n);
+ return do_computed_value_Mod(get_DivMod_left(a), get_DivMod_right(a));
}
- else if (ts == get_tarval_b_false()) {
- ir_node *v = get_Mux_false(n);
- return value_of(v);
+ return tarval_bad;
+} /* computed_value_Proj_DivMod */
+
+/**
+ * Return the value of a Proj(Div).
+ */
+static tarval *computed_value_Proj_Div(const ir_node *n) {
+ long proj_nr = get_Proj_proj(n);
+
+ if (proj_nr == pn_Div_res) {
+ const ir_node *a = get_Proj_pred(n);
+ return do_computed_value_Div(get_Div_left(a), get_Div_right(a));
}
return tarval_bad;
-} /* computed_value_Mux */
+} /* computed_value_Proj_Div */
/**
- * Calculate the value of a Psi: can be evaluated, if a condition is true
- * and all previous conditions are false. If all conditions are false
- * we evaluate to the default one.
+ * Return the value of a Proj(Mod).
*/
-static tarval *computed_value_Psi(ir_node *n) {
- if (is_Mux(n))
- return computed_value_Mux(n);
+static tarval *computed_value_Proj_Mod(const ir_node *n) {
+ long proj_nr = get_Proj_proj(n);
+
+ if (proj_nr == pn_Mod_res) {
+ const ir_node *a = get_Proj_pred(n);
+ return do_computed_value_Mod(get_Mod_left(a), get_Mod_right(a));
+ }
return tarval_bad;
-} /* computed_value_Psi */
+} /* computed_value_Proj_Mod */
/**
- * Calculate the value of a Confirm: can be evaluated,
- * if it has the form Confirm(x, '=', Const).
+ * Return the value of a Proj(Quot).
*/
-static tarval *computed_value_Confirm(ir_node *n) {
- /*
- * Beware: we might produce Phi(Confirm(x == true), Confirm(x == false)).
- * Do NOT optimize them away (CondEval wants them), so wait until
- * remove_confirm is activated.
- */
- if (get_opt_remove_confirm()) {
- return get_Confirm_cmp(n) == pn_Cmp_Eq ?
- value_of(get_Confirm_bound(n)) : tarval_bad;
+static tarval *computed_value_Proj_Quot(const ir_node *n) {
+ long proj_nr = get_Proj_proj(n);
+
+ if (proj_nr == pn_Quot_res) {
+ const ir_node *a = get_Proj_pred(n);
+ return do_computed_value_Quot(get_Quot_left(a), get_Quot_right(a));
}
return tarval_bad;
-} /* computed_value_Confirm */
+} /* computed_value_Proj_Quot */
+
+/**
+ * Return the value of a Proj.
+ */
+static tarval *computed_value_Proj(const ir_node *proj) {
+ ir_node *n = get_Proj_pred(proj);
+
+ if (n->op->ops.computed_value_Proj != NULL)
+ return n->op->ops.computed_value_Proj(proj);
+ return tarval_bad;
+} /* computed_value_Proj */
/**
* If the parameter n can be computed, return its value, else tarval_bad.
*
* @param n The node this should be evaluated
*/
-tarval *computed_value(ir_node *n) {
+tarval *computed_value(const ir_node *n) {
if (n->op->ops.computed_value)
return n->op->ops.computed_value(n);
return tarval_bad;
*/
static ir_op_ops *firm_set_default_computed_value(ir_opcode code, ir_op_ops *ops)
{
-#define CASE(a) \
- case iro_##a: \
- ops->computed_value = computed_value_##a; \
+#define CASE(a) \
+ case iro_##a: \
+ ops->computed_value = computed_value_##a; \
+ break
+#define CASE_PROJ(a) \
+ case iro_##a: \
+ ops->computed_value_Proj = computed_value_Proj_##a; \
break
switch (code) {
CASE(SymConst);
CASE(Add);
CASE(Sub);
+ CASE(Carry);
+ CASE(Borrow);
CASE(Minus);
CASE(Mul);
- CASE(Quot);
- CASE(Div);
- CASE(Mod);
CASE(Abs);
CASE(And);
CASE(Or);
CASE(Shr);
CASE(Shrs);
CASE(Rotl);
- CASE(Carry);
- CASE(Borrow);
CASE(Conv);
- CASE(Proj);
CASE(Mux);
- CASE(Psi);
CASE(Confirm);
+ CASE_PROJ(Cmp);
+ CASE_PROJ(DivMod);
+ CASE_PROJ(Div);
+ CASE_PROJ(Mod);
+ CASE_PROJ(Quot);
+ CASE(Proj);
default:
/* leave NULL */;
}
return ops;
+#undef CASE_PROJ
#undef CASE
} /* firm_set_default_computed_value */
This should be true, as the block is matured before optimize is called.
But what about Phi-cycles with the Phi0/Id that could not be resolved?
Remaining Phi nodes are just Ids. */
- if (n_preds == 1 && is_Jmp(get_Block_cfgpred(n, 0))) {
- ir_node *predblock = get_nodes_block(get_Block_cfgpred(n, 0));
- if (predblock == oldn) {
- /* Jmp jumps into the block it is in -- deal self cycle. */
- n = set_Block_dead(n);
- DBG_OPT_DEAD_BLOCK(oldn, n);
- } else if (get_opt_control_flow_straightening()) {
- n = predblock;
- DBG_OPT_STG(oldn, n);
- }
- } else if (n_preds == 1 && is_Cond(skip_Proj(get_Block_cfgpred(n, 0)))) {
- ir_node *predblock = get_Block_cfgpred_block(n, 0);
- if (predblock == oldn) {
- /* Jmp jumps into the block it is in -- deal self cycle. */
- n = set_Block_dead(n);
- DBG_OPT_DEAD_BLOCK(oldn, n);
+ if (n_preds == 1) {
+ ir_node *pred = skip_Proj(get_Block_cfgpred(n, 0));
+
+ if (is_Jmp(pred)) {
+ ir_node *predblock = get_nodes_block(pred);
+ if (predblock == oldn) {
+ /* Jmp jumps into the block it is in -- deal self cycle. */
+ n = set_Block_dead(n);
+ DBG_OPT_DEAD_BLOCK(oldn, n);
+ } else if (get_opt_control_flow_straightening()) {
+ n = predblock;
+ DBG_OPT_STG(oldn, n);
+ }
+ } else if (is_Cond(pred)) {
+ ir_node *predblock = get_nodes_block(pred);
+ if (predblock == oldn) {
+ /* Jmp jumps into the block it is in -- deal self cycle. */
+ n = set_Block_dead(n);
+ DBG_OPT_DEAD_BLOCK(oldn, n);
+ }
}
} else if ((n_preds == 2) &&
(get_opt_control_flow_weak_simplification())) {
ir_node *a = get_Block_cfgpred(n, 0);
ir_node *b = get_Block_cfgpred(n, 1);
- if (is_Proj(a) &&
- is_Proj(b) &&
- (get_Proj_pred(a) == get_Proj_pred(b)) &&
- is_Cond(get_Proj_pred(a)) &&
- (get_irn_mode(get_Cond_selector(get_Proj_pred(a))) == mode_b)) {
- /* Also a single entry Block following a single exit Block. Phis have
- twice the same operand and will be optimized away. */
- n = get_nodes_block(get_Proj_pred(a));
- DBG_OPT_IFSIM1(oldn, a, b, n);
+ if (is_Proj(a) && is_Proj(b)) {
+ ir_node *cond = get_Proj_pred(a);
+
+ if (cond == get_Proj_pred(b) && is_Cond(cond) &&
+ get_irn_mode(get_Cond_selector(cond)) == mode_b) {
+ /* Also a single entry Block following a single exit Block. Phis have
+ twice the same operand and will be optimized away. */
+ n = get_nodes_block(cond);
+ DBG_OPT_IFSIM1(oldn, a, b, n);
+ }
}
} else if (get_opt_unreachable_code() &&
(n != get_irg_start_block(current_ir_graph)) &&
* Of course this only happens if the Block of the Jmp is dead.
*/
static ir_node *equivalent_node_Jmp(ir_node *n) {
- /* unreachable code elimination */
- if (is_Block_dead(get_nodes_block(n)))
- n = new_Bad();
+ ir_node *oldn = n;
+ /* unreachable code elimination */
+ if (is_Block_dead(get_nodes_block(n))) {
+ n = get_irg_bad(current_ir_graph);
+ DBG_OPT_DEAD_BLOCK(oldn, n);
+ }
return n;
} /* equivalent_node_Jmp */
* Optimize operations that are commutative and have neutral 0,
* so a op 0 = 0 op a = a.
*/
-static ir_node *equivalent_node_neutral_zero(ir_node *n)
-{
+static ir_node *equivalent_node_neutral_zero(ir_node *n) {
ir_node *oldn = n;
ir_node *a = get_binop_left(n);
/**
* Eor is commutative and has neutral 0.
*/
-static ir_node *equivalent_node_Eor(ir_node *n)
-{
+static ir_node *equivalent_node_Eor(ir_node *n) {
ir_node *oldn = n;
ir_node *a;
ir_node *b;
return n;
}
}
-
return n;
}
static ir_node *equivalent_node_left_zero(ir_node *n) {
ir_node *oldn = n;
- ir_node *a = get_binop_left(n);
- ir_node *b = get_binop_right(n);
+ ir_node *a = get_binop_left(n);
+ ir_node *b = get_binop_right(n);
+ tarval *tb = value_of(b);
- if (is_Const(b) && is_Const_null(b)) {
+ if (tarval_is_null(tb)) {
n = a;
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_NEUTRAL_0);
ir_node *oldn = n;
ir_node *b;
ir_mode *mode = get_irn_mode(n);
+ tarval *tb;
/* for FP these optimizations are only allowed if fp_strict_algebraic is disabled */
if (mode_is_float(mode) && (get_irg_fp_model(current_ir_graph) & fp_strict_algebraic))
return n;
- b = get_Sub_right(n);
+ b = get_Sub_right(n);
+ tb = value_of(b);
/* Beware: modes might be different */
- if (is_Const(b) && is_Const_null(b)) {
+ if (tarval_is_null(tb)) {
ir_node *a = get_Sub_left(n);
if (mode == get_irn_mode(a)) {
n = a;
/* we can handle here only the n * n = n bit cases */
if (get_irn_mode(n) == get_irn_mode(a)) {
ir_node *b = get_Mul_right(n);
+ tarval *tv;
- /* Mul is commutative and has again an other neutral element. */
- if (is_Const(a) && is_Const_one(a)) {
- n = b;
- DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_NEUTRAL_1);
- } else if (is_Const(b) && is_Const_one(b)) {
+ /*
+ * Mul is commutative and has again an other neutral element.
+ * Constants are place right, so check this case first.
+ */
+ tv = value_of(b);
+ if (tarval_is_one(tv)) {
n = a;
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_NEUTRAL_1);
+ } else {
+ tv = value_of(a);
+ if (tarval_is_one(tv)) {
+ n = b;
+ DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_NEUTRAL_1);
+ }
}
}
return n;
} /* equivalent_node_Mul */
-/**
- * Optimize a / 1 = a.
- */
-static ir_node *equivalent_node_Div(ir_node *n) {
- ir_node *a = get_Div_left(n);
- ir_node *b = get_Div_right(n);
-
- /* Div is not commutative. */
- if (is_Const(b) && is_Const_one(b)) { /* div(x, 1) == x */
- /* Turn Div into a tuple (mem, bad, a) */
- ir_node *mem = get_Div_mem(n);
- ir_node *blk = get_irn_n(n, -1);
- turn_into_tuple(n, pn_Div_max);
- set_Tuple_pred(n, pn_Div_M, mem);
- set_Tuple_pred(n, pn_Div_X_regular, new_r_Jmp(current_ir_graph, blk));
- set_Tuple_pred(n, pn_Div_X_except, new_Bad()); /* no exception */
- set_Tuple_pred(n, pn_Div_res, a);
- }
- return n;
-} /* equivalent_node_Div */
-
-/**
- * Optimize a / 1.0 = a.
- */
-static ir_node *equivalent_node_Quot(ir_node *n) {
- ir_node *a = get_Quot_left(n);
- ir_node *b = get_Quot_right(n);
-
- /* Div is not commutative. */
- if (is_Const(b) && is_Const_one(b)) { /* Quot(x, 1) == x */
- /* Turn Quot into a tuple (mem, jmp, bad, a) */
- ir_node *mem = get_Quot_mem(n);
- ir_node *blk = get_irn_n(n, -1);
- turn_into_tuple(n, pn_Quot_max);
- set_Tuple_pred(n, pn_Quot_M, mem);
- set_Tuple_pred(n, pn_Quot_X_regular, new_r_Jmp(current_ir_graph, blk));
- set_Tuple_pred(n, pn_Quot_X_except, new_Bad()); /* no exception */
- set_Tuple_pred(n, pn_Quot_res, a);
- }
- return n;
-} /* equivalent_node_Quot */
-
-/**
- * Optimize a / 1 = a.
- */
-static ir_node *equivalent_node_DivMod(ir_node *n) {
- ir_node *b = get_DivMod_right(n);
-
- /* Div is not commutative. */
- if (is_Const(b) && is_Const_one(b)) { /* div(x, 1) == x */
- /* Turn DivMod into a tuple (mem, jmp, bad, a, 0) */
- ir_node *a = get_DivMod_left(n);
- ir_node *mem = get_Div_mem(n);
- ir_node *blk = get_irn_n(n, -1);
- ir_mode *mode = get_DivMod_resmode(n);
-
- turn_into_tuple(n, pn_DivMod_max);
- set_Tuple_pred(n, pn_DivMod_M, mem);
- set_Tuple_pred(n, pn_DivMod_X_regular, new_r_Jmp(current_ir_graph, blk));
- set_Tuple_pred(n, pn_DivMod_X_except, new_Bad()); /* no exception */
- set_Tuple_pred(n, pn_DivMod_res_div, a);
- set_Tuple_pred(n, pn_DivMod_res_mod, new_Const(mode, get_mode_null(mode)));
- }
- return n;
-} /* equivalent_node_DivMod */
-
/**
* Use algebraic simplification a | a = a | 0 = 0 | a = a.
*/
ir_node *a = get_Or_left(n);
ir_node *b = get_Or_right(n);
+ tarval *tv;
if (a == b) {
n = a; /* Or has it's own neutral element */
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_OR);
- } else if (is_Const(a) && is_Const_null(a)) {
- n = b;
- DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_OR);
- } else if (is_Const(b) && is_Const_null(b)) {
+ return n;
+ }
+ /* constants are cormalized to right, check this site first */
+ tv = value_of(b);
+ if (tarval_is_null(tv)) {
n = a;
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_OR);
+ return n;
+ }
+ tv = value_of(a);
+ if (tarval_is_null(tv)) {
+ n = b;
+ DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_OR);
+ return n;
}
return n;
ir_node *a = get_And_left(n);
ir_node *b = get_And_right(n);
+ tarval *tv;
if (a == b) {
n = a; /* And has it's own neutral element */
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_AND);
return n;
}
- if (is_Const(a) && is_Const_all_one(a)) {
- n = b;
+ /* constants are cormalized to right, check this site first */
+ tv = value_of(b);
+ if (tarval_is_all_one(tv)) {
+ n = a;
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_AND);
return n;
}
- if (is_Const(b) && is_Const_all_one(b)) {
- n = a;
+ tv = value_of(a);
+ if (tarval_is_all_one(tv)) {
+ n = b;
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_AND);
return n;
}
return n;
}
}
-
return n;
} /* equivalent_node_And */
goto restart;
}
/* else both are strict conv, second is superfluous */
- } else if (is_Proj(a)) {
- ir_node *pred = get_Proj_pred(a);
- if (is_Load(pred)) {
- /* loads always return with the exact precision of n_mode */
- assert(get_Load_mode(pred) == n_mode);
- return a;
+ } else {
+ if (is_Proj(a)) {
+ ir_node *pred = get_Proj_pred(a);
+ if (is_Load(pred)) {
+ /* loads always return with the exact precision of n_mode */
+ assert(get_Load_mode(pred) == n_mode);
+ return a;
+ }
}
+ /* leave strict floating point Conv's */
+ return n;
}
-
- /* leave strict floating point Conv's */
- return n;
}
n = a;
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_CONV);
}
}
}
- if (mode_is_int(n_mode) && mode_is_float(a_mode)) {
+ if (get_mode_arithmetic(n_mode) == irma_twos_complement &&
+ get_mode_arithmetic(a_mode) == irma_ieee754) {
/* ConvI(ConvF(I)) -> I, iff float mantissa >= int mode */
- size_t int_mantissa = get_mode_size_bits(n_mode) - (mode_is_signed(n_mode) ? 1 : 0);
- size_t float_mantissa;
- /* FIXME There is no way to get the mantissa size of a mode */
- switch (get_mode_size_bits(a_mode)) {
- case 32: float_mantissa = 23 + 1; break; // + 1 for implicit 1
- case 64: float_mantissa = 52 + 1; break;
- case 80: float_mantissa = 64 + 1; break;
- default: float_mantissa = 0; break;
- }
- if (float_mantissa != 0 && float_mantissa >= int_mantissa) {
+ unsigned int_mantissa = get_mode_size_bits(n_mode) - (mode_is_signed(n_mode) ? 1 : 0);
+ unsigned float_mantissa = tarval_ieee754_get_mantissa_size(a_mode);
+
+ if (float_mantissa >= int_mantissa) {
n = b;
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_CONV);
return n;
} /* equivalent_node_Cast */
/**
- * Several optimizations:
- * - no Phi in start block.
- * - remove Id operators that are inputs to Phi
* - fold Phi-nodes, iff they have only one predecessor except
* themselves.
*/
n_preds = get_Phi_n_preds(n);
block = get_nodes_block(n);
- if ((is_Block_dead(block)) || /* Control dead */
- (block == get_irg_start_block(current_ir_graph))) /* There should be no Phi nodes */
- return new_Bad(); /* in the Start Block. */
+ if (is_Block_dead(block)) /* Control dead */
+ return get_irg_bad(current_ir_graph);
if (n_preds == 0) return n; /* Phi of dead Region without predecessors. */
- /* If the Block has a Bad pred, we also have one. */
- for (i = 0; i < n_preds; ++i)
- if (is_Bad(get_Block_cfgpred(block, i)))
- set_Phi_pred(n, i, new_Bad());
-
/* Find first non-self-referencing input */
for (i = 0; i < n_preds; ++i) {
first_val = get_Phi_pred(n, i);
* This is not that bad as it sounds, optimize_cf() removes bad control flow
* (and bad Phi predecessors), so live code is optimized later.
*/
- && (! is_Bad(first_val))
+ && (! is_Bad(get_Block_cfgpred(block, i)))
#endif
) { /* value not dead */
break; /* then found first value. */
if (i >= n_preds) {
/* A totally Bad or self-referencing Phi (we didn't break the above loop) */
- return new_Bad();
+ return get_irg_bad(current_ir_graph);
}
/* search for rest of inputs, determine if any of these
&& (scnd_val != first_val)
#if 0
/* see above */
- && (! is_Bad(scnd_val))
+ && (! is_Bad(get_Block_cfgpred(block, i)))
#endif
) {
break;
} /* equivalent_node_Phi */
/**
- * Several optimizations:
- * - no Sync in start block.
- * - fold Sync-nodes, iff they have only one predecessor except
- * themselves.
+ * Several optimizations:
+ * - fold Sync-nodes, iff they have only one predecessor except
+ * themselves.
+ */
+static ir_node *equivalent_node_Sync(ir_node *n) {
+ int arity = get_Sync_n_preds(n);
+ int i;
+
+ for (i = 0; i < arity;) {
+ ir_node *pred = get_Sync_pred(n, i);
+ int j;
+
+ /* Remove Bad predecessors */
+ if (is_Bad(pred)) {
+ del_Sync_n(n, i);
+ --arity;
+ continue;
+ }
+
+ /* Remove duplicate predecessors */
+ for (j = 0;; ++j) {
+ if (j >= i) {
+ ++i;
+ break;
+ }
+ if (get_Sync_pred(n, j) == pred) {
+ del_Sync_n(n, i);
+ --arity;
+ break;
+ }
+ }
+ }
+
+ if (arity == 0) return get_irg_bad(current_ir_graph);
+ if (arity == 1) return get_Sync_pred(n, 0);
+ return n;
+} /* equivalent_node_Sync */
+
+/**
+ * Optimize Proj(Tuple).
+ */
+static ir_node *equivalent_node_Proj_Tuple(ir_node *proj) {
+ ir_node *oldn = proj;
+ ir_node *tuple = get_Proj_pred(proj);
+
+ /* Remove the Tuple/Proj combination. */
+ proj = get_Tuple_pred(tuple, get_Proj_proj(proj));
+ DBG_OPT_TUPLE(oldn, tuple, proj);
+
+ return proj;
+} /* equivalent_node_Proj_Tuple */
+
+/**
+ * Optimize a / 1 = a.
+ */
+static ir_node *equivalent_node_Proj_Div(ir_node *proj) {
+ ir_node *oldn = proj;
+ ir_node *div = get_Proj_pred(proj);
+ ir_node *b = get_Div_right(div);
+ tarval *tb = value_of(b);
+
+ /* Div is not commutative. */
+ if (tarval_is_one(tb)) { /* div(x, 1) == x */
+ switch (get_Proj_proj(proj)) {
+ case pn_Div_M:
+ proj = get_Div_mem(div);
+ DBG_OPT_ALGSIM0(oldn, proj, FS_OPT_NEUTRAL_1);
+ return proj;
+
+ case pn_Div_res:
+ proj = get_Div_left(div);
+ DBG_OPT_ALGSIM0(oldn, proj, FS_OPT_NEUTRAL_1);
+ return proj;
+
+ default:
+ /* we cannot replace the exception Proj's here, this is done in
+ transform_node_Proj_Div() */
+ return proj;
+ }
+ }
+ return proj;
+} /* equivalent_node_Proj_Div */
+
+/**
+ * Optimize a / 1.0 = a.
+ */
+static ir_node *equivalent_node_Proj_Quot(ir_node *proj) {
+ ir_node *oldn = proj;
+ ir_node *quot = get_Proj_pred(proj);
+ ir_node *b = get_Quot_right(quot);
+ tarval *tb = value_of(b);
+
+ /* Div is not commutative. */
+ if (tarval_is_one(tb)) { /* Quot(x, 1) == x */
+ switch (get_Proj_proj(proj)) {
+ case pn_Quot_M:
+ proj = get_Quot_mem(quot);
+ DBG_OPT_ALGSIM0(oldn, proj, FS_OPT_NEUTRAL_1);
+ return proj;
+
+ case pn_Quot_res:
+ proj = get_Quot_left(quot);
+ DBG_OPT_ALGSIM0(oldn, proj, FS_OPT_NEUTRAL_1);
+ return proj;
+
+ default:
+ /* we cannot replace the exception Proj's here, this is done in
+ transform_node_Proj_Quot() */
+ return proj;
+ }
+ }
+ return proj;
+} /* equivalent_node_Proj_Quot */
+
+/**
+ * Optimize a / 1 = a.
+ */
+static ir_node *equivalent_node_Proj_DivMod(ir_node *proj) {
+ ir_node *oldn = proj;
+ ir_node *divmod = get_Proj_pred(proj);
+ ir_node *b = get_DivMod_right(divmod);
+ tarval *tb = value_of(b);
+
+ /* Div is not commutative. */
+ if (tarval_is_one(tb)) { /* div(x, 1) == x */
+ switch (get_Proj_proj(proj)) {
+ case pn_DivMod_M:
+ proj = get_DivMod_mem(divmod);
+ DBG_OPT_ALGSIM0(oldn, proj, FS_OPT_NEUTRAL_1);
+ return proj;
+
+ case pn_DivMod_res_div:
+ proj = get_DivMod_left(divmod);
+ DBG_OPT_ALGSIM0(oldn, proj, FS_OPT_NEUTRAL_1);
+ return proj;
+
+ default:
+ /* we cannot replace the exception Proj's here, this is done in
+ transform_node_Proj_DivMod().
+ Note further that the pn_DivMod_res_div case is handled in
+ computed_value_Proj(). */
+ return proj;
+ }
+ }
+ return proj;
+} /* equivalent_node_Proj_DivMod */
+
+/**
+ * Optimize CopyB(mem, x, x) into a Nop.
+ */
+static ir_node *equivalent_node_Proj_CopyB(ir_node *proj) {
+ ir_node *oldn = proj;
+ ir_node *copyb = get_Proj_pred(proj);
+ ir_node *a = get_CopyB_dst(copyb);
+ ir_node *b = get_CopyB_src(copyb);
+
+ if (a == b) {
+ /* Turn CopyB into a tuple (mem, jmp, bad, bad) */
+ switch (get_Proj_proj(proj)) {
+ case pn_CopyB_M_regular:
+ proj = get_CopyB_mem(copyb);
+ DBG_OPT_ALGSIM0(oldn, proj, FS_OPT_NOP);
+ break;
+
+ case pn_CopyB_M_except:
+ case pn_CopyB_X_except:
+ DBG_OPT_EXC_REM(proj);
+ proj = get_irg_bad(current_ir_graph);
+ break;
+ }
+ }
+ return proj;
+} /* equivalent_node_Proj_CopyB */
+
+/**
+ * Optimize Bounds(idx, idx, upper) into idx.
+ */
+static ir_node *equivalent_node_Proj_Bound(ir_node *proj) {
+ ir_node *oldn = proj;
+ ir_node *bound = get_Proj_pred(proj);
+ ir_node *idx = get_Bound_index(bound);
+ ir_node *pred = skip_Proj(idx);
+ int ret_tuple = 0;
+
+ if (idx == get_Bound_lower(bound))
+ ret_tuple = 1;
+ else if (is_Bound(pred)) {
+ /*
+ * idx was Bounds checked in the same MacroBlock previously,
+ * it is still valid if lower <= pred_lower && pred_upper <= upper.
+ */
+ ir_node *lower = get_Bound_lower(bound);
+ ir_node *upper = get_Bound_upper(bound);
+ if (get_Bound_lower(pred) == lower &&
+ get_Bound_upper(pred) == upper &&
+ get_irn_MacroBlock(bound) == get_irn_MacroBlock(pred)) {
+ /*
+ * One could expect that we simply return the previous
+ * Bound here. However, this would be wrong, as we could
+ * add an exception Proj to a new location then.
+ * So, we must turn in into a tuple.
+ */
+ ret_tuple = 1;
+ }
+ }
+ if (ret_tuple) {
+ /* Turn Bound into a tuple (mem, jmp, bad, idx) */
+ switch (get_Proj_proj(proj)) {
+ case pn_Bound_M:
+ DBG_OPT_EXC_REM(proj);
+ proj = get_Bound_mem(bound);
+ break;
+ case pn_Bound_X_except:
+ DBG_OPT_EXC_REM(proj);
+ proj = get_irg_bad(current_ir_graph);
+ break;
+ case pn_Bound_res:
+ proj = idx;
+ DBG_OPT_ALGSIM0(oldn, proj, FS_OPT_NOP);
+ break;
+ default:
+ /* cannot optimize pn_Bound_X_regular, handled in transform ... */
+ ;
+ }
+ }
+ return proj;
+} /* equivalent_node_Proj_Bound */
+
+/**
+ * Optimize an Exception Proj(Load) with a non-null address.
*/
-static ir_node *equivalent_node_Sync(ir_node *n) {
- int arity = get_Sync_n_preds(n);
- int i;
+static ir_node *equivalent_node_Proj_Load(ir_node *proj) {
+ if (get_opt_ldst_only_null_ptr_exceptions()) {
+ if (get_irn_mode(proj) == mode_X) {
+ ir_node *load = get_Proj_pred(proj);
- for (i = 0; i < arity;) {
- ir_node *pred = get_Sync_pred(n, i);
- int j;
+ /* get the Load address */
+ const ir_node *addr = get_Load_ptr(load);
+ const ir_node *confirm;
- /* Remove Bad predecessors */
- if (is_Bad(pred)) {
- del_Sync_n(n, i);
- --arity;
- continue;
+ if (value_not_null(addr, &confirm)) {
+ if (get_Proj_proj(proj) == pn_Load_X_except) {
+ DBG_OPT_EXC_REM(proj);
+ return get_irg_bad(current_ir_graph);
+ }
+ }
}
+ }
+ return proj;
+} /* equivalent_node_Proj_Load */
- /* Remove duplicate predecessors */
- for (j = 0;; ++j) {
- if (j >= i) {
- ++i;
- break;
- }
- if (get_Sync_pred(n, j) == pred) {
- del_Sync_n(n, i);
- --arity;
- break;
+/**
+ * Optimize an Exception Proj(Store) with a non-null address.
+ */
+static ir_node *equivalent_node_Proj_Store(ir_node *proj) {
+ if (get_opt_ldst_only_null_ptr_exceptions()) {
+ if (get_irn_mode(proj) == mode_X) {
+ ir_node *store = get_Proj_pred(proj);
+
+ /* get the load/store address */
+ const ir_node *addr = get_Store_ptr(store);
+ const ir_node *confirm;
+
+ if (value_not_null(addr, &confirm)) {
+ if (get_Proj_proj(proj) == pn_Store_X_except) {
+ DBG_OPT_EXC_REM(proj);
+ return get_irg_bad(current_ir_graph);
+ }
}
}
}
-
- if (arity == 0) return new_Bad();
- if (arity == 1) return get_Sync_pred(n, 0);
- return n;
-} /* equivalent_node_Sync */
+ return proj;
+} /* equivalent_node_Proj_Store */
/**
- * Optimize Proj(Tuple) and gigo() for ProjX in Bad block,
- * ProjX(Load) and ProjX(Store).
+ * Does all optimizations on nodes that must be done on it's Proj's
+ * because of creating new nodes.
*/
static ir_node *equivalent_node_Proj(ir_node *proj) {
- ir_node *oldn = proj;
- ir_node *a = get_Proj_pred(proj);
+ ir_node *n = get_Proj_pred(proj);
- if (is_Tuple(a)) {
- /* Remove the Tuple/Proj combination. */
- if ( get_Proj_proj(proj) <= get_Tuple_n_preds(a) ) {
- proj = get_Tuple_pred(a, get_Proj_proj(proj));
- DBG_OPT_TUPLE(oldn, a, proj);
- } else {
- /* This should not happen! */
- assert(! "found a Proj with higher number than Tuple predecessors");
- proj = new_Bad();
- }
- } else if (get_irn_mode(proj) == mode_X) {
- if (is_Block_dead(get_nodes_block(skip_Proj(proj)))) {
+ if (get_irn_mode(proj) == mode_X) {
+ if (is_Block_dead(get_nodes_block(n))) {
/* Remove dead control flow -- early gigo(). */
- proj = new_Bad();
- } else if (get_opt_ldst_only_null_ptr_exceptions()) {
- if (is_Load(a)) {
- /* get the Load address */
- ir_node *addr = get_Load_ptr(a);
- ir_node *blk = get_irn_n(a, -1);
- ir_node *confirm;
-
- if (value_not_null(addr, &confirm)) {
- if (confirm == NULL) {
- /* this node may float if it did not depend on a Confirm */
- set_irn_pinned(a, op_pin_state_floats);
- }
- if (get_Proj_proj(proj) == pn_Load_X_except) {
- DBG_OPT_EXC_REM(proj);
- return new_Bad();
- } else
- return new_r_Jmp(current_ir_graph, blk);
- }
- } else if (is_Store(a)) {
- /* get the load/store address */
- ir_node *addr = get_Store_ptr(a);
- ir_node *blk = get_irn_n(a, -1);
- ir_node *confirm;
-
- if (value_not_null(addr, &confirm)) {
- if (confirm == NULL) {
- /* this node may float if it did not depend on a Confirm */
- set_irn_pinned(a, op_pin_state_floats);
- }
- if (get_Proj_proj(proj) == pn_Store_X_except) {
- DBG_OPT_EXC_REM(proj);
- return new_Bad();
- } else
- return new_r_Jmp(current_ir_graph, blk);
- }
- }
+ return get_irg_bad(current_ir_graph);
}
}
-
+ if (n->op->ops.equivalent_node_Proj)
+ return n->op->ops.equivalent_node_Proj(proj);
return proj;
} /* equivalent_node_Proj */
do {
n = get_Id_pred(n);
- } while (get_irn_op(n) == op_Id);
+ } while (is_Id(n));
DBG_OPT_ID(oldn, n);
return n;
switch (proj_nr) {
case pn_Cmp_Eq:
- if ((cmp_l == t && cmp_r == f) || /* Psi(t == f, t, f) -> f */
- (cmp_l == f && cmp_r == t)) { /* Psi(f == t, t, f) -> f */
+ if ((cmp_l == t && cmp_r == f) || /* Mux(t == f, t, f) -> f */
+ (cmp_l == f && cmp_r == t)) { /* Mux(f == t, t, f) -> f */
n = f;
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_MUX_TRANSFORM);
return n;
case pn_Cmp_Lg:
case pn_Cmp_Ne:
- if ((cmp_l == t && cmp_r == f) || /* Psi(t != f, t, f) -> t */
- (cmp_l == f && cmp_r == t)) { /* Psi(f != t, t, f) -> t */
+ if ((cmp_l == t && cmp_r == f) || /* Mux(t != f, t, f) -> t */
+ (cmp_l == f && cmp_r == t)) { /* Mux(f != t, t, f) -> t */
n = t;
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_MUX_TRANSFORM);
return n;
* Note: normalization puts the constant on the right side,
* so we check only one case.
*/
- if (cmp_l == t && is_Const(cmp_r) && is_Const_null(cmp_r)) {
+ if (cmp_l == t && tarval_is_null(value_of(cmp_r))) {
/* Mux(t CMP 0, X, t) */
if (is_Minus(f) && get_Minus_op(f) == t) {
/* Mux(t CMP 0, -t, t) */
return n;
} /* equivalent_node_Mux */
-/**
- * Returns a equivalent node of a Psi: if a condition is true
- * and all previous conditions are false we know its value.
- * If all conditions are false its value is the default one.
- */
-static ir_node *equivalent_node_Psi(ir_node *n) {
- if (is_Mux(n))
- return equivalent_node_Mux(n);
- return n;
-} /* equivalent_node_Psi */
-
-/**
- * Optimize -a CMP -b into b CMP a.
- * This works only for for modes where unary Minus
- * cannot Overflow.
- * Note that two-complement integers can Overflow
- * so it will NOT work.
- *
- * For == and != can be handled in Proj(Cmp)
- */
-static ir_node *equivalent_node_Cmp(ir_node *n) {
- ir_node *left = get_Cmp_left(n);
- ir_node *right = get_Cmp_right(n);
-
- if (is_Minus(left) && is_Minus(right) &&
- !mode_overflow_on_unary_Minus(get_irn_mode(left))) {
- left = get_Minus_op(left);
- right = get_Minus_op(right);
- set_Cmp_left(n, right);
- set_Cmp_right(n, left);
- }
- return n;
-} /* equivalent_node_Cmp */
-
/**
* Remove Confirm nodes if setting is on.
* Replace Confirms(x, '=', Constlike) by Constlike.
ir_node *pred = get_Confirm_value(n);
pn_Cmp pnc = get_Confirm_cmp(n);
- if (is_Confirm(pred) && pnc == get_Confirm_cmp(pred)) {
+ while (is_Confirm(pred) && pnc == get_Confirm_cmp(pred)) {
/*
* rare case: two identical Confirms one after another,
* replace the second one with the first.
*/
- n = pred;
+ n = pred;
+ pred = get_Confirm_value(n);
+ pnc = get_Confirm_cmp(n);
}
if (get_opt_remove_confirm())
return get_Confirm_value(n);
return n;
}
-/**
- * Optimize CopyB(mem, x, x) into a Nop.
- */
-static ir_node *equivalent_node_CopyB(ir_node *n) {
- ir_node *a = get_CopyB_dst(n);
- ir_node *b = get_CopyB_src(n);
-
- if (a == b) {
- /* Turn CopyB into a tuple (mem, jmp, bad, bad) */
- ir_node *mem = get_CopyB_mem(n);
- ir_node *blk = get_nodes_block(n);
- turn_into_tuple(n, pn_CopyB_max);
- set_Tuple_pred(n, pn_CopyB_M, mem);
- set_Tuple_pred(n, pn_CopyB_X_regular, new_r_Jmp(current_ir_graph, blk));
- set_Tuple_pred(n, pn_CopyB_X_except, new_Bad()); /* no exception */
- set_Tuple_pred(n, pn_CopyB_M_except, new_Bad());
- }
- return n;
-} /* equivalent_node_CopyB */
-
-/**
- * Optimize Bounds(idx, idx, upper) into idx.
- */
-static ir_node *equivalent_node_Bound(ir_node *n) {
- ir_node *idx = get_Bound_index(n);
- ir_node *pred = skip_Proj(idx);
- int ret_tuple = 0;
-
- if (is_Bound(pred)) {
- /*
- * idx was Bounds checked in the same MacroBlock previously,
- * it is still valid if lower <= pred_lower && pred_upper <= upper.
- */
- ir_node *lower = get_Bound_lower(n);
- ir_node *upper = get_Bound_upper(n);
- if (get_Bound_lower(pred) == lower &&
- get_Bound_upper(pred) == upper &&
- get_irn_MacroBlock(n) == get_irn_MacroBlock(pred)) {
- /*
- * One could expect that we simply return the previous
- * Bound here. However, this would be wrong, as we could
- * add an exception Proj to a new location then.
- * So, we must turn in into a tuple.
- */
- ret_tuple = 1;
- }
- }
- if (ret_tuple) {
- /* Turn Bound into a tuple (mem, jmp, bad, idx) */
- ir_node *mem = get_Bound_mem(n);
- ir_node *blk = get_nodes_block(n);
- turn_into_tuple(n, pn_Bound_max);
- set_Tuple_pred(n, pn_Bound_M, mem);
- set_Tuple_pred(n, pn_Bound_X_regular, new_r_Jmp(current_ir_graph, blk)); /* no exception */
- set_Tuple_pred(n, pn_Bound_X_except, new_Bad()); /* no exception */
- set_Tuple_pred(n, pn_Bound_res, idx);
- }
- return n;
-} /* equivalent_node_Bound */
-
/**
* equivalent_node() returns a node equivalent to input n. It skips all nodes that
* perform no actual computation, as, e.g., the Id nodes. It does not create
case iro_##a: \
ops->equivalent_node = equivalent_node_##a; \
break
+#define CASE_PROJ(a) \
+ case iro_##a: \
+ ops->equivalent_node_Proj = equivalent_node_Proj_##a; \
+ break
switch (code) {
CASE(Block);
CASE(Jmp);
CASE(Raise);
- CASE(Or);
- CASE(Add);
CASE(Eor);
- CASE(Sub);
+ CASE(Add);
CASE(Shl);
CASE(Shr);
CASE(Shrs);
CASE(Rotl);
+ CASE(Sub);
CASE(Not);
CASE(Minus);
CASE(Mul);
- CASE(Div);
- CASE(Quot);
- CASE(DivMod);
+ CASE(Or);
CASE(And);
CASE(Conv);
CASE(Cast);
CASE(Phi);
CASE(Sync);
+ CASE_PROJ(Tuple);
+ CASE_PROJ(Div);
+ CASE_PROJ(Quot);
+ CASE_PROJ(DivMod);
+ CASE_PROJ(CopyB);
+ CASE_PROJ(Bound);
+ CASE_PROJ(Load);
+ CASE_PROJ(Store);
CASE(Proj);
CASE(Id);
CASE(Mux);
- CASE(Psi);
- CASE(Cmp);
CASE(Confirm);
- CASE(CopyB);
- CASE(Bound);
default:
/* leave NULL */;
}
return ops;
#undef CASE
+#undef CASE_PROJ
} /* firm_set_default_equivalent_node */
/**
if (! is_Phi(n) || get_irn_arity(n) == 0)
return 0;
- for (i = get_irn_arity(n) - 1; i >= 0; --i)
+ for (i = get_irn_arity(n) - 1; i >= 0; --i) {
if (! is_Const(get_irn_n(n, i)))
return 0;
- return 1;
+ }
+ return 1;
} /* is_const_Phi */
typedef tarval *(*tarval_sub_type)(tarval *a, tarval *b, ir_mode *mode);
n = new_rd_Sub(
get_irn_dbg_info(n),
current_ir_graph,
- get_irn_n(n, -1),
+ get_nodes_block(n),
b,
get_Minus_op(a),
mode);
n = new_rd_Sub(
get_irn_dbg_info(n),
current_ir_graph,
- get_irn_n(n, -1),
+ get_nodes_block(n),
a,
get_Minus_op(b),
mode);
if (is_Const(b) && is_Const_one(b)) {
/* ~x + 1 = -x */
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, blk, op, mode);
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_NOT_PLUS_1);
return n;
}
if (op == b) {
/* ~x + x = -1 */
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_r_Const(current_ir_graph, blk, mode, get_mode_minus_one(mode));
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_ADD_X_NOT_X);
return n;
if (op == a) {
/* x + ~x = -1 */
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_r_Const(current_ir_graph, blk, mode, get_mode_minus_one(mode));
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_ADD_X_NOT_X);
return n;
if (is_Const(b) && is_Const_null(b) && mode_is_reference(lmode)) {
/* a Sub(a, NULL) is a hidden Conv */
dbg_info *dbg = get_irn_dbg_info(n);
- return new_rd_Conv(dbg, current_ir_graph, get_nodes_block(n), a, mode);
+ n = new_rd_Conv(dbg, current_ir_graph, get_nodes_block(n), a, mode);
+ DBG_OPT_ALGSIM0(oldn, n, FS_OPT_SUB_TO_CONV);
+ return n;
+ }
+
+ if (mode == lmode &&
+ get_mode_arithmetic(mode) == irma_twos_complement &&
+ is_Const(a) &&
+ get_Const_tarval(a) == get_mode_minus_one(mode)) {
+ /* -1 - x -> ~x */
+ dbg_info *dbg = get_irn_dbg_info(n);
+ n = new_rd_Not(dbg, current_ir_graph, get_nodes_block(n), b, mode);
+ DBG_OPT_ALGSIM0(oldn, n, FS_OPT_SUB_TO_NOT);
+ return n;
}
}
n = new_rd_Add(dbg, irg, block, a, right, mode);
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_SUB_MINUS);
return n;
- } else if (is_Sub(b)) { /* a - (b - c) -> a + (c - b) */
+ } else if (is_Sub(b)) {
+ /* a - (b - c) -> a + (c - b)
+ * -> (a - b) + c iff (b - c) is a pointer */
ir_graph *irg = current_ir_graph;
dbg_info *s_dbg = get_irn_dbg_info(b);
ir_node *s_block = get_nodes_block(b);
- ir_node *s_left = get_Sub_right(b);
- ir_node *s_right = get_Sub_left(b);
+ ir_node *s_left = get_Sub_left(b);
+ ir_node *s_right = get_Sub_right(b);
ir_mode *s_mode = get_irn_mode(b);
- ir_node *sub = new_rd_Sub(s_dbg, irg, s_block, s_left, s_right, s_mode);
- dbg_info *a_dbg = get_irn_dbg_info(n);
- ir_node *a_block = get_nodes_block(n);
+ if (s_mode == mode_P) {
+ ir_node *sub = new_rd_Sub(s_dbg, irg, s_block, a, s_left, mode);
+ dbg_info *a_dbg = get_irn_dbg_info(n);
+ ir_node *a_block = get_nodes_block(n);
+
+ if (s_mode != mode)
+ s_right = new_r_Conv(irg, a_block, s_right, mode);
+ n = new_rd_Add(a_dbg, irg, a_block, sub, s_right, mode);
+ } else {
+ ir_node *sub = new_rd_Sub(s_dbg, irg, s_block, s_right, s_left, s_mode);
+ dbg_info *a_dbg = get_irn_dbg_info(n);
+ ir_node *a_block = get_nodes_block(n);
- n = new_rd_Add(a_dbg, irg, a_block, a, sub, mode);
+ n = new_rd_Add(a_dbg, irg, a_block, a, sub, mode);
+ }
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_SUB_TO_ADD);
return n;
} else if (is_Mul(b)) { /* a - (b * C) -> a + (b * -C) */
n = new_rd_Minus(
get_irn_dbg_info(n),
current_ir_graph,
- get_irn_n(n, -1),
+ get_nodes_block(n),
b,
mode);
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_SUB_0_A);
if (left == b) {
if (mode != get_irn_mode(right)) {
/* This Sub is an effective Cast */
- right = new_r_Conv(get_irn_irg(n), get_irn_n(n, -1), right, mode);
+ right = new_r_Conv(get_irn_irg(n), get_nodes_block(n), right, mode);
}
n = right;
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_ADD_SUB);
} else if (right == b) {
if (mode != get_irn_mode(left)) {
/* This Sub is an effective Cast */
- left = new_r_Conv(get_irn_irg(n), get_irn_n(n, -1), left, mode);
+ left = new_r_Conv(get_irn_irg(n), get_nodes_block(n), left, mode);
}
n = left;
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_ADD_SUB);
if (left == a) {
ir_mode *r_mode = get_irn_mode(right);
- n = new_r_Minus(get_irn_irg(n), get_irn_n(n, -1), right, r_mode);
+ n = new_r_Minus(get_irn_irg(n), get_nodes_block(n), right, r_mode);
if (mode != r_mode) {
/* This Sub is an effective Cast */
- n = new_r_Conv(get_irn_irg(n), get_irn_n(n, -1), n, mode);
+ n = new_r_Conv(get_irn_irg(n), get_nodes_block(n), n, mode);
}
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_ADD_SUB);
return n;
} else if (right == a) {
ir_mode *l_mode = get_irn_mode(left);
- n = new_r_Minus(get_irn_irg(n), get_irn_n(n, -1), left, l_mode);
+ n = new_r_Minus(get_irn_irg(n), get_nodes_block(n), left, l_mode);
if (mode != l_mode) {
/* This Sub is an effective Cast */
- n = new_r_Conv(get_irn_irg(n), get_irn_n(n, -1), n, mode);
+ n = new_r_Conv(get_irn_irg(n), get_nodes_block(n), n, mode);
}
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_ADD_SUB);
return n;
ir_node *mb = get_Mul_right(a);
if (ma == b) {
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_rd_Mul(
get_irn_dbg_info(n),
current_ir_graph, blk,
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_SUB_MUL_A_X_A);
return n;
} else if (mb == b) {
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_rd_Mul(
get_irn_dbg_info(n),
current_ir_graph, blk,
if (is_Sub(a)) { /* (x - y) - b -> x - (y + b) */
ir_node *x = get_Sub_left(a);
ir_node *y = get_Sub_right(a);
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
ir_mode *m_b = get_irn_mode(b);
ir_mode *m_y = get_irn_mode(y);
ir_mode *add_mode;
tv = tarval_add(tv, get_mode_one(mode));
if (tv != tarval_bad) {
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
ir_node *c = new_r_Const(current_ir_graph, blk, mode, tv);
n = new_rd_Add(get_irn_dbg_info(n), current_ir_graph, blk, get_Not_op(b), c, mode);
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_SUB_C_NOT_X);
if (ta == get_mode_one(smode)) {
/* (L)1 * (L)b = (L)b */
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_rd_Conv(get_irn_dbg_info(n), current_ir_graph, blk, b, mode);
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_NEUTRAL_1);
return n;
}
else if (ta == get_mode_minus_one(smode)) {
/* (L)-1 * (L)b = (L)b */
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, blk, b, smode);
n = new_rd_Conv(get_irn_dbg_info(n), current_ir_graph, blk, n, mode);
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_MUL_MINUS_1);
}
else if (tb == get_mode_minus_one(smode)) {
/* (L)a * (L)-1 = (L)-a */
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, blk, a, smode);
n = new_rd_Conv(get_irn_dbg_info(n), current_ir_graph, blk, n, mode);
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_MUL_MINUS_1);
else if (value_of(b) == get_mode_minus_one(mode))
r = a;
if (r) {
- n = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, get_irn_n(n, -1), r, mode);
+ n = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, get_nodes_block(n), r, mode);
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_MUL_MINUS_1);
return n;
}
if (get_mode_arithmetic(mode) == irma_ieee754) {
if (is_Const(a)) {
tarval *tv = get_Const_tarval(a);
- if (tarval_ieee754_get_exponent(tv) == 1 && tarval_ieee754_zero_mantissa(tv)) {
+ if (tarval_ieee754_get_exponent(tv) == 1 && tarval_ieee754_zero_mantissa(tv)
+ && !tarval_is_negative(tv)) {
/* 2.0 * b = b + b */
n = new_rd_Add(get_irn_dbg_info(n), current_ir_graph, get_nodes_block(n), b, b, mode);
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_ADD_A_A);
}
else if (is_Const(b)) {
tarval *tv = get_Const_tarval(b);
- if (tarval_ieee754_get_exponent(tv) == 1 && tarval_ieee754_zero_mantissa(tv)) {
+ if (tarval_ieee754_get_exponent(tv) == 1 && tarval_ieee754_zero_mantissa(tv)
+ && !tarval_is_negative(tv)) {
/* a * 2.0 = a + a */
n = new_rd_Add(get_irn_dbg_info(n), current_ir_graph, get_nodes_block(n), a, a, mode);
DBG_OPT_ALGSIM1(oldn, a, b, n, FS_OPT_ADD_A_A);
DBG_OPT_CSTEVAL(n, value);
goto make_tuple;
} else {
- ir_node *a = get_Div_left(n);
- ir_node *b = get_Div_right(n);
- ir_node *dummy;
+ ir_node *a = get_Div_left(n);
+ ir_node *b = get_Div_right(n);
+ const ir_node *dummy;
if (a == b && value_not_zero(a, &dummy)) {
/* BEWARE: we can optimize a/a to 1 only if this cannot cause a exception */
if (tv == get_mode_minus_one(mode)) {
/* a / -1 */
- value = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, get_irn_n(n, -1), a, mode);
+ value = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, get_nodes_block(n), a, mode);
DBG_OPT_CSTEVAL(n, value);
goto make_tuple;
}
make_tuple:
/* Turn Div into a tuple (mem, jmp, bad, value) */
mem = get_Div_mem(n);
- blk = get_irn_n(n, -1);
+ blk = get_nodes_block(n);
/* skip a potential Pin */
- if (is_Pin(mem))
- mem = get_Pin_op(mem);
+ mem = skip_Pin(mem);
turn_into_tuple(n, pn_Div_max);
set_Tuple_pred(n, pn_Div_M, mem);
set_Tuple_pred(n, pn_Div_X_regular, new_r_Jmp(current_ir_graph, blk));
DBG_OPT_CSTEVAL(n, value);
goto make_tuple;
} else {
- ir_node *a = get_Mod_left(n);
- ir_node *b = get_Mod_right(n);
- ir_node *dummy;
+ ir_node *a = get_Mod_left(n);
+ ir_node *b = get_Mod_right(n);
+ const ir_node *dummy;
if (a == b && value_not_zero(a, &dummy)) {
/* BEWARE: we can optimize a%a to 0 only if this cannot cause a exception */
make_tuple:
/* Turn Mod into a tuple (mem, jmp, bad, value) */
mem = get_Mod_mem(n);
- blk = get_irn_n(n, -1);
+ blk = get_nodes_block(n);
/* skip a potential Pin */
- if (is_Pin(mem))
- mem = get_Pin_op(mem);
+ mem = skip_Pin(mem);
turn_into_tuple(n, pn_Mod_max);
set_Tuple_pred(n, pn_Mod_M, mem);
set_Tuple_pred(n, pn_Mod_X_regular, new_r_Jmp(current_ir_graph, blk));
* Transform a DivMod node.
*/
static ir_node *transform_node_DivMod(ir_node *n) {
- ir_node *dummy;
- ir_node *a = get_DivMod_left(n);
- ir_node *b = get_DivMod_right(n);
- ir_mode *mode = get_DivMod_resmode(n);
- tarval *ta, *tb;
- int evaluated = 0;
- ir_node *va, *vb;
+ const ir_node *dummy;
+ ir_node *a = get_DivMod_left(n);
+ ir_node *b = get_DivMod_right(n);
+ ir_mode *mode = get_DivMod_resmode(n);
+ ir_node *va, *vb;
+ tarval *ta, *tb;
+ int evaluated = 0;
if (is_Const(b) && is_const_Phi(a)) {
/* check for Div(Phi, Const) */
DBG_OPT_CSTEVAL(n, vb);
goto make_tuple;
} else if (mode_is_signed(mode) && tb == get_mode_minus_one(mode)) {
- va = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, get_irn_n(n, -1), a, mode);
+ va = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, get_nodes_block(n), a, mode);
vb = new_Const(mode, get_mode_null(mode));
DBG_OPT_CSTEVAL(n, va);
DBG_OPT_CSTEVAL(n, vb);
make_tuple:
mem = get_DivMod_mem(n);
/* skip a potential Pin */
- if (is_Pin(mem))
- mem = get_Pin_op(mem);
+ mem = skip_Pin(mem);
- blk = get_irn_n(n, -1);
+ blk = get_nodes_block(n);
turn_into_tuple(n, pn_DivMod_max);
set_Tuple_pred(n, pn_DivMod_M, mem);
set_Tuple_pred(n, pn_DivMod_X_regular, new_r_Jmp(current_ir_graph, blk));
if (get_mode_arithmetic(mode) == irma_ieee754) {
ir_node *b = get_Quot_right(n);
+ tarval *tv = value_of(b);
- if (is_Const(b)) {
- tarval *tv = get_Const_tarval(b);
+ if (tv != tarval_bad) {
int rem;
/*
using strict rules. */
if (tv != tarval_bad &&
(tarval_ieee754_get_exact() || (get_irg_fp_model(current_ir_graph) & fp_strict_algebraic) == 0)) {
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
ir_node *c = new_r_Const(current_ir_graph, blk, mode, tv);
ir_node *a = get_Quot_left(n);
ir_node *m = new_rd_Mul(get_irn_dbg_info(n), current_ir_graph, blk, a, c, mode);
ir_node *mem = get_Quot_mem(n);
/* skip a potential Pin */
- if (is_Pin(mem))
- mem = get_Pin_op(mem);
+ mem = skip_Pin(mem);
turn_into_tuple(n, pn_Quot_max);
set_Tuple_pred(n, pn_Quot_M, mem);
set_Tuple_pred(n, pn_Quot_X_regular, new_r_Jmp(current_ir_graph, blk));
return n;
} /* transform_node_Abs */
+/**
+ * Optimize -a CMP -b into b CMP a.
+ * This works only for for modes where unary Minus
+ * cannot Overflow.
+ * Note that two-complement integers can Overflow
+ * so it will NOT work.
+ *
+ * For == and != can be handled in Proj(Cmp)
+ */
+static ir_node *transform_node_Cmp(ir_node *n) {
+ ir_node *oldn = n;
+ ir_node *left = get_Cmp_left(n);
+ ir_node *right = get_Cmp_right(n);
+
+ if (is_Minus(left) && is_Minus(right) &&
+ !mode_overflow_on_unary_Minus(get_irn_mode(left))) {
+ ir_node *const new_left = get_Minus_op(right);
+ ir_node *const new_right = get_Minus_op(left);
+ n = new_rd_Cmp(get_irn_dbg_info(n), current_ir_graph,
+ get_nodes_block(n), new_left, new_right);
+ DBG_OPT_ALGSIM0(oldn, n, FS_OPT_CMP_OP_OP);
+ }
+ return n;
+} /* transform_node_Cmp */
+
+
/**
* Transform a Cond node.
*
ir_mode *a_mode = get_irn_mode(a_op);
ir_mode *b_mode = get_irn_mode(b_op);
if(a_mode == b_mode && (mode_is_int(a_mode) || a_mode == mode_b)) {
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = exact_copy(n);
set_binop_left(n, a_op);
if (c != NULL) {
/* (a sop c) & (b sop c) => (a & b) sop c */
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
ir_node *new_n = exact_copy(n);
set_binop_left(new_n, op1);
if (a == b) {
/* a ^ a = 0 */
- n = new_rd_Const(get_irn_dbg_info(n), current_ir_graph, get_irn_n(n, -1),
+ n = new_rd_Const(get_irn_dbg_info(n), current_ir_graph, get_nodes_block(n),
mode, get_mode_null(mode));
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_EOR_A_A);
} else if (mode == mode_b &&
is_Const(b) && is_Const_one(b) &&
is_Cmp(get_Proj_pred(a))) {
/* The Eor negates a Cmp. The Cmp has the negated result anyways! */
- n = new_r_Proj(current_ir_graph, get_irn_n(n, -1), get_Proj_pred(a),
+ n = new_r_Proj(current_ir_graph, get_nodes_block(n), get_Proj_pred(a),
mode_b, get_negated_pnc(get_Proj_proj(a), mode));
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_EOR_TO_NOT_BOOL);
is_Proj(a) &&
is_Cmp(get_Proj_pred(a))) {
/* We negate a Cmp. The Cmp has the negated result anyways! */
- n = new_r_Proj(current_ir_graph, get_irn_n(n, -1), get_Proj_pred(a),
+ n = new_r_Proj(current_ir_graph, get_nodes_block(n), get_Proj_pred(a),
mode_b, get_negated_pnc(get_Proj_proj(a), mode_b));
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_NOT_CMP);
return n;
if (is_Const(add_r) && is_Const_all_one(add_r)) {
/* ~(x + -1) = -x */
ir_node *op = get_Add_left(a);
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph, blk, op, get_irn_mode(n));
DBG_OPT_ALGSIM0(oldn, n, FS_OPT_NOT_MINUS_1);
}
/* -(~x) = x + 1 */
ir_node *op = get_Not_op(a);
tarval *tv = get_mode_one(mode);
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
ir_node *c = new_r_Const(current_ir_graph, blk, mode, tv);
n = new_rd_Add(get_irn_dbg_info(n), current_ir_graph, blk, op, c, mode);
DBG_OPT_ALGSIM2(oldn, a, n, FS_OPT_MINUS_NOT);
/* -(a >>u (size-1)) = a >>s (size-1) */
ir_node *v = get_Shr_left(a);
- n = new_rd_Shrs(get_irn_dbg_info(n), current_ir_graph, get_irn_n(n, -1), v, c, mode);
+ n = new_rd_Shrs(get_irn_dbg_info(n), current_ir_graph, get_nodes_block(n), v, c, mode);
DBG_OPT_ALGSIM2(oldn, a, n, FS_OPT_PREDICATE);
return n;
}
/* -(a >>s (size-1)) = a >>u (size-1) */
ir_node *v = get_Shrs_left(a);
- n = new_rd_Shr(get_irn_dbg_info(n), current_ir_graph, get_irn_n(n, -1), v, c, mode);
+ n = new_rd_Shr(get_irn_dbg_info(n), current_ir_graph, get_nodes_block(n), v, c, mode);
DBG_OPT_ALGSIM2(oldn, a, n, FS_OPT_PREDICATE);
return n;
}
/* - (a-b) = b - a */
ir_node *la = get_Sub_left(a);
ir_node *ra = get_Sub_right(a);
- ir_node *blk = get_irn_n(n, -1);
+ ir_node *blk = get_nodes_block(n);
n = new_rd_Sub(get_irn_dbg_info(n), current_ir_graph, blk, ra, la, mode);
DBG_OPT_ALGSIM2(oldn, a, n, FS_OPT_MINUS_SUB);
if (is_Mul(a)) { /* -(a * const) -> a * -const */
ir_node *mul_l = get_Mul_left(a);
ir_node *mul_r = get_Mul_right(a);
- if (is_Const(mul_r)) {
- tarval *tv = tarval_neg(get_Const_tarval(mul_r));
- if(tv != tarval_bad) {
+ tarval *tv = value_of(mul_r);
+ if (tv != tarval_bad) {
+ tv = tarval_neg(tv);
+ if (tv != tarval_bad) {
ir_node *cnst = new_Const(mode, tv);
dbg_info *dbg = get_irn_dbg_info(a);
ir_graph *irg = current_ir_graph;
return n;
} /* transform_node_Cast */
+/**
+ * Transform a Proj(Load) with a non-null address.
+ */
+static ir_node *transform_node_Proj_Load(ir_node *proj) {
+ if (get_opt_ldst_only_null_ptr_exceptions()) {
+ if (get_irn_mode(proj) == mode_X) {
+ ir_node *load = get_Proj_pred(proj);
+
+ /* get the Load address */
+ const ir_node *addr = get_Load_ptr(load);
+ const ir_node *confirm;
+
+ if (value_not_null(addr, &confirm)) {
+ if (confirm == NULL) {
+ /* this node may float if it did not depend on a Confirm */
+ set_irn_pinned(load, op_pin_state_floats);
+ }
+ if (get_Proj_proj(proj) == pn_Load_X_except) {
+ DBG_OPT_EXC_REM(proj);
+ return get_irg_bad(current_ir_graph);
+ } else {
+ ir_node *blk = get_nodes_block(load);
+ return new_r_Jmp(current_ir_graph, blk);
+ }
+ }
+ }
+ }
+ return proj;
+} /* transform_node_Proj_Load */
+
+/**
+ * Transform a Proj(Store) with a non-null address.
+ */
+static ir_node *transform_node_Proj_Store(ir_node *proj) {
+ if (get_opt_ldst_only_null_ptr_exceptions()) {
+ if (get_irn_mode(proj) == mode_X) {
+ ir_node *store = get_Proj_pred(proj);
+
+ /* get the load/store address */
+ const ir_node *addr = get_Store_ptr(store);
+ const ir_node *confirm;
+
+ if (value_not_null(addr, &confirm)) {
+ if (confirm == NULL) {
+ /* this node may float if it did not depend on a Confirm */
+ set_irn_pinned(store, op_pin_state_floats);
+ }
+ if (get_Proj_proj(proj) == pn_Store_X_except) {
+ DBG_OPT_EXC_REM(proj);
+ return get_irg_bad(current_ir_graph);
+ } else {
+ ir_node *blk = get_nodes_block(store);
+ return new_r_Jmp(current_ir_graph, blk);
+ }
+ }
+ }
+ }
+ return proj;
+} /* transform_node_Proj_Store */
+
/**
* Transform a Proj(Div) with a non-zero value.
* Removes the exceptions and routes the memory to the NoMem node.
static ir_node *transform_node_Proj_Div(ir_node *proj) {
ir_node *div = get_Proj_pred(proj);
ir_node *b = get_Div_right(div);
- ir_node *confirm, *res, *new_mem;
+ ir_node *res, *new_mem;
+ const ir_node *confirm;
long proj_nr;
if (value_not_zero(b, &confirm)) {
if (confirm == NULL) {
/* we are sure we have a Const != 0 */
new_mem = get_Div_mem(div);
- if (is_Pin(new_mem))
- new_mem = get_Pin_op(new_mem);
+ new_mem = skip_Pin(new_mem);
set_Div_mem(div, new_mem);
set_irn_pinned(div, op_pin_state_floats);
}
static ir_node *transform_node_Proj_Mod(ir_node *proj) {
ir_node *mod = get_Proj_pred(proj);
ir_node *b = get_Mod_right(mod);
- ir_node *confirm, *res, *new_mem;
+ ir_node *res, *new_mem;
+ const ir_node *confirm;
long proj_nr;
if (value_not_zero(b, &confirm)) {
if (confirm == NULL) {
/* we are sure we have a Const != 0 */
new_mem = get_Mod_mem(mod);
- if (is_Pin(new_mem))
- new_mem = get_Pin_op(new_mem);
+ new_mem = skip_Pin(new_mem);
set_Mod_mem(mod, new_mem);
set_irn_pinned(mod, op_pin_state_floats);
}
static ir_node *transform_node_Proj_DivMod(ir_node *proj) {
ir_node *divmod = get_Proj_pred(proj);
ir_node *b = get_DivMod_right(divmod);
- ir_node *confirm, *res, *new_mem;
+ ir_node *res, *new_mem;
+ const ir_node *confirm;
long proj_nr;
if (value_not_zero(b, &confirm)) {
if (confirm == NULL) {
/* we are sure we have a Const != 0 */
new_mem = get_DivMod_mem(divmod);
- if (is_Pin(new_mem))
- new_mem = get_Pin_op(new_mem);
+ new_mem = skip_Pin(new_mem);
set_DivMod_mem(divmod, new_mem);
set_irn_pinned(divmod, op_pin_state_floats);
}
return proj;
} else {
/* this case will NEVER be taken, kill it */
- return new_Bad();
+ return get_irg_bad(current_ir_graph);
}
}
}
* later and may help to normalize more compares.
* Of course this is only possible for integer values.
*/
- if (is_Const(right)) {
+ tv = value_of(right);
+ if (tv != tarval_bad) {
mode = get_irn_mode(right);
- tv = get_Const_tarval(right);
/* TODO extend to arbitrary constants */
if (is_Conv(left) && tarval_is_null(tv)) {
else if (proj_nr == pn_Cmp_Le || proj_nr == pn_Cmp_Lt) {
if (tv != tarval_bad) {
/* c >= 0 : Abs(a) <= c ==> (unsigned)(a + c) <= 2*c */
- if (get_irn_op(left) == op_Abs) { // TODO something is missing here
+ if (is_Abs(left)) { // TODO something is missing here
}
}
}
}
if (changed) {
- ir_node *block = get_irn_n(n, -1); /* Beware of get_nodes_Block() */
+ ir_node *block = get_nodes_block(n);
/* create a new compare */
n = new_rd_Cmp(get_irn_dbg_info(n), current_ir_graph, block, left, right);
} /* transform_node_Proj_Cmp */
/**
- * Does all optimizations on nodes that must be done on it's Proj's
- * because of creating new nodes.
+ * Optimize CopyB(mem, x, x) into a Nop.
*/
-static ir_node *transform_node_Proj(ir_node *proj) {
- ir_node *n = get_Proj_pred(proj);
-
- switch (get_irn_opcode(n)) {
- case iro_Div:
- return transform_node_Proj_Div(proj);
+static ir_node *transform_node_Proj_CopyB(ir_node *proj) {
+ ir_node *copyb = get_Proj_pred(proj);
+ ir_node *a = get_CopyB_dst(copyb);
+ ir_node *b = get_CopyB_src(copyb);
- case iro_Mod:
- return transform_node_Proj_Mod(proj);
-
- case iro_DivMod:
- return transform_node_Proj_DivMod(proj);
+ if (a == b) {
+ switch (get_Proj_proj(proj)) {
+ case pn_CopyB_X_regular:
+ /* Turn CopyB into a tuple (mem, jmp, bad, bad) */
+ DBG_OPT_EXC_REM(proj);
+ proj = new_r_Jmp(current_ir_graph, get_nodes_block(copyb));
+ break;
+ case pn_CopyB_M_except:
+ case pn_CopyB_X_except:
+ DBG_OPT_EXC_REM(proj);
+ proj = get_irg_bad(current_ir_graph);
+ break;
+ default:
+ break;
+ }
+ }
+ return proj;
+} /* transform_node_Proj_CopyB */
- case iro_Cond:
- return transform_node_Proj_Cond(proj);
+/**
+ * Optimize Bounds(idx, idx, upper) into idx.
+ */
+static ir_node *transform_node_Proj_Bound(ir_node *proj) {
+ ir_node *oldn = proj;
+ ir_node *bound = get_Proj_pred(proj);
+ ir_node *idx = get_Bound_index(bound);
+ ir_node *pred = skip_Proj(idx);
+ int ret_tuple = 0;
- case iro_Cmp:
- return transform_node_Proj_Cmp(proj);
+ if (idx == get_Bound_lower(bound))
+ ret_tuple = 1;
+ else if (is_Bound(pred)) {
+ /*
+ * idx was Bounds checked in the same MacroBlock previously,
+ * it is still valid if lower <= pred_lower && pred_upper <= upper.
+ */
+ ir_node *lower = get_Bound_lower(bound);
+ ir_node *upper = get_Bound_upper(bound);
+ if (get_Bound_lower(pred) == lower &&
+ get_Bound_upper(pred) == upper &&
+ get_irn_MacroBlock(bound) == get_irn_MacroBlock(pred)) {
+ /*
+ * One could expect that we simply return the previous
+ * Bound here. However, this would be wrong, as we could
+ * add an exception Proj to a new location then.
+ * So, we must turn in into a tuple.
+ */
+ ret_tuple = 1;
+ }
+ }
+ if (ret_tuple) {
+ /* Turn Bound into a tuple (mem, jmp, bad, idx) */
+ switch (get_Proj_proj(proj)) {
+ case pn_Bound_M:
+ DBG_OPT_EXC_REM(proj);
+ proj = get_Bound_mem(bound);
+ break;
+ case pn_Bound_X_except:
+ DBG_OPT_EXC_REM(proj);
+ proj = get_irg_bad(current_ir_graph);
+ break;
+ case pn_Bound_res:
+ proj = idx;
+ DBG_OPT_ALGSIM0(oldn, proj, FS_OPT_NOP);
+ break;
+ case pn_Bound_X_regular:
+ DBG_OPT_EXC_REM(proj);
+ proj = new_r_Jmp(current_ir_graph, get_nodes_block(bound));
+ break;
+ default:
+ break;
+ }
+ }
+ return proj;
+} /* transform_node_Proj_Bound */
- case iro_Tuple:
- /* should not happen, but if it does will be optimized away */
- return equivalent_node_Proj(proj);
+/**
+ * Does all optimizations on nodes that must be done on it's Proj's
+ * because of creating new nodes.
+ */
+static ir_node *transform_node_Proj(ir_node *proj) {
+ ir_node *n = get_Proj_pred(proj);
- default:
- /* do nothing */
- return proj;
- }
+ if (n->op->ops.transform_node_Proj)
+ return n->op->ops.transform_node_Proj(proj);
+ return proj;
} /* transform_node_Proj */
/**
} else if (is_irn_pinned_in_irg(ka) && is_Block_dead(get_nodes_block(ka))) {
continue;
}
- /* FIXME: beabi need to keep a Proj(M) */
- if (is_Phi(ka) || is_irn_keep(ka) || is_Proj(ka))
- in[j++] = ka;
+ in[j++] = ka;
}
if (j != n_keepalives)
set_End_keepalives(n, j, in);
ir_node *t = get_Mux_true(n);
ir_node *f = get_Mux_false(n);
ir_graph *irg = current_ir_graph;
- ir_node *conds[1], *vals[2];
/* first normalization step: move a possible zero to the false case */
if (is_Proj(sel)) {
if (is_Cmp(cmp)) {
if (is_Const(t) && is_Const_null(t)) {
- /* Psi(x, 0, y) => Psi(x, y, 0) */
+ ir_node *tmp;
+
+ /* Mux(x, 0, y) => Mux(x, y, 0) */
pn_Cmp pnc = get_Proj_proj(sel);
sel = new_r_Proj(irg, get_nodes_block(cmp), cmp, mode_b,
get_negated_pnc(pnc, get_irn_mode(get_Cmp_left(cmp))));
- conds[0] = sel;
- vals[0] = f;
- vals[1] = t;
- n = new_rd_Psi(get_irn_dbg_info(n), irg, get_nodes_block(n), 1, conds, vals, mode);
- t = vals[0];
- f = vals[1];
+ n = new_rd_Mux(get_irn_dbg_info(n), irg, get_nodes_block(n), sel, t, f, mode);
+ tmp = t;
+ t = f;
+ f = tmp;
}
}
}
dbg_info *dbg = get_irn_dbg_info(n);
ir_node *block = get_nodes_block(n);
ir_graph *irg = current_ir_graph;
-
-
- conds[0] = sel;
- vals[0] = new_Const(mode, tarval_sub(a, min, NULL));
- vals[1] = new_Const(mode, tarval_sub(b, min, NULL));
- n = new_rd_Psi(dbg, irg, block, 1, conds, vals, mode);
+ ir_node *t = new_Const(mode, tarval_sub(a, min, NULL));
+ ir_node *f = new_Const(mode, tarval_sub(b, min, NULL));
+ n = new_rd_Mux(dbg, irg, block, sel, f, t, mode);
n = new_rd_Add(dbg, irg, block, n, new_Const(mode, min), mode);
return n;
}
if ( (cmp_l == t && (pn == pn_Cmp_Ge || pn == pn_Cmp_Gt))
|| (cmp_l == f && (pn == pn_Cmp_Le || pn == pn_Cmp_Lt)))
{
- /* Psi(a >/>= 0, a, -a) = Psi(a </<= 0, -a, a) ==> Abs(a) */
+ /* Mux(a >/>= 0, a, -a) = Mux(a </<= 0, -a, a) ==> Abs(a) */
n = new_rd_Abs(get_irn_dbg_info(n), current_ir_graph, block,
cmp_l, mode);
DBG_OPT_ALGSIM1(oldn, cmp, sel, n, FS_OPT_MUX_TO_ABS);
} else if ((cmp_l == t && (pn == pn_Cmp_Le || pn == pn_Cmp_Lt))
|| (cmp_l == f && (pn == pn_Cmp_Ge || pn == pn_Cmp_Gt)))
{
- /* Psi(a </<= 0, a, -a) = Psi(a >/>= 0, -a, a) ==> -Abs(a) */
+ /* Mux(a </<= 0, a, -a) = Mux(a >/>= 0, -a, a) ==> -Abs(a) */
n = new_rd_Abs(get_irn_dbg_info(n), current_ir_graph, block,
cmp_l, mode);
n = new_rd_Minus(get_irn_dbg_info(n), current_ir_graph,
if (mode_is_int(mode)) {
/* integer only */
if ((pn == pn_Cmp_Lg || pn == pn_Cmp_Eq) && is_And(cmp_l)) {
- /* Psi((a & b) != 0, c, 0) */
+ /* Mux((a & b) != 0, c, 0) */
ir_node *and_r = get_And_right(cmp_l);
ir_node *and_l;
if (and_r == t && f == cmp_r) {
if (is_Const(t) && tarval_is_single_bit(get_Const_tarval(t))) {
if (pn == pn_Cmp_Lg) {
- /* Psi((a & 2^C) != 0, 2^C, 0) */
+ /* Mux((a & 2^C) != 0, 2^C, 0) */
n = cmp_l;
+ DBG_OPT_ALGSIM1(oldn, cmp, sel, n, FS_OPT_MUX_TO_BITOP);
} else {
- /* Psi((a & 2^C) == 0, 2^C, 0) */
+ /* Mux((a & 2^C) == 0, 2^C, 0) */
n = new_rd_Eor(get_irn_dbg_info(n), current_ir_graph,
block, cmp_l, t, mode);
+ DBG_OPT_ALGSIM1(oldn, cmp, sel, n, FS_OPT_MUX_TO_BITOP);
}
return n;
}
if (pn == pn_Cmp_Lg) {
/* (a & (1 << n)) != 0, (1 << n), 0) */
n = cmp_l;
+ DBG_OPT_ALGSIM1(oldn, cmp, sel, n, FS_OPT_MUX_TO_BITOP);
} else {
/* (a & (1 << n)) == 0, (1 << n), 0) */
n = new_rd_Eor(get_irn_dbg_info(n), current_ir_graph,
block, cmp_l, t, mode);
+ DBG_OPT_ALGSIM1(oldn, cmp, sel, n, FS_OPT_MUX_TO_BITOP);
}
return n;
}
if (pn == pn_Cmp_Lg) {
/* ((1 << n) & a) != 0, (1 << n), 0) */
n = cmp_l;
+ DBG_OPT_ALGSIM1(oldn, cmp, sel, n, FS_OPT_MUX_TO_BITOP);
} else {
/* ((1 << n) & a) == 0, (1 << n), 0) */
n = new_rd_Eor(get_irn_dbg_info(n), current_ir_graph,
block, cmp_l, t, mode);
+ DBG_OPT_ALGSIM1(oldn, cmp, sel, n, FS_OPT_MUX_TO_BITOP);
}
return n;
}
} /* transform_node_Mux */
/**
- * Optimize a Psi into some simpler cases.
- */
-static ir_node *transform_node_Psi(ir_node *n) {
- if (is_Mux(n))
- return transform_node_Mux(n);
-
- return n;
-} /* transform_node_Psi */
-
-/**
- * optimize sync nodes that have other syncs as input we simply add the inputs
+ * optimize Sync nodes that have other syncs as input we simply add the inputs
* of the other sync to our own inputs
*/
static ir_node *transform_node_Sync(ir_node *n) {
*/
static ir_op_ops *firm_set_default_transform_node(ir_opcode code, ir_op_ops *ops)
{
-#define CASE(a) \
- case iro_##a: \
- ops->transform_node = transform_node_##a; \
+#define CASE(a) \
+ case iro_##a: \
+ ops->transform_node = transform_node_##a; \
+ break
+#define CASE_PROJ(a) \
+ case iro_##a: \
+ ops->transform_node_Proj = transform_node_Proj_##a; \
+ break
+#define CASE_PROJ_EX(a) \
+ case iro_##a: \
+ ops->transform_node = transform_node_##a; \
+ ops->transform_node_Proj = transform_node_Proj_##a; \
break
switch (code) {
CASE(Add);
CASE(Sub);
CASE(Mul);
- CASE(Div);
- CASE(Mod);
- CASE(DivMod);
+ CASE_PROJ_EX(Div);
+ CASE_PROJ_EX(Mod);
+ CASE_PROJ_EX(DivMod);
CASE(Quot);
CASE(Abs);
- CASE(Cond);
+ CASE_PROJ_EX(Cmp);
+ CASE_PROJ_EX(Cond);
CASE(And);
- CASE(Or);
CASE(Eor);
- CASE(Minus);
CASE(Not);
+ CASE(Minus);
CASE(Cast);
+ CASE_PROJ(Load);
+ CASE_PROJ(Store);
+ CASE_PROJ(Bound);
+ CASE_PROJ(CopyB);
CASE(Proj);
CASE(Phi);
+ CASE(Or);
CASE(Sel);
CASE(Shr);
CASE(Shrs);
CASE(Conv);
CASE(End);
CASE(Mux);
- CASE(Psi);
CASE(Sync);
default:
/* leave NULL */;
}
return ops;
+#undef CASE_PROJ_EX
+#undef CASE_PROJ
#undef CASE
} /* firm_set_default_transform_node */
static int node_cmp_attr_Sel(ir_node *a, ir_node *b) {
const ir_entity *a_ent = get_Sel_entity(a);
const ir_entity *b_ent = get_Sel_entity(b);
+#if 0
return
(a_ent->kind != b_ent->kind) ||
(a_ent->name != b_ent->name) ||
(a_ent->owner != b_ent->owner) ||
(a_ent->ld_name != b_ent->ld_name) ||
(a_ent->type != b_ent->type);
+#endif
+ /* Matze: inlining of functions can produce 2 entities with same type,
+ * name, etc. */
+ return a_ent != b_ent;
} /* node_cmp_attr_Sel */
/** Compares the attributes of two Phi nodes. */
if (o != n) {
update_known_irn(o, n);
- DBG_OPT_CSE(n, o);
}
return o;
/* Now we have a legal, useful node. Enter it in hash table for CSE */
if (get_opt_cse() && (get_irn_opcode(n) != iro_Block)) {
- n = identify_remember(current_ir_graph->value_table, n);
+ ir_node *o = n;
+ n = identify_remember(current_ir_graph->value_table, o);
+ if (o != n)
+ DBG_OPT_CSE(o, n);
}
return n;
now all nodes are op_pin_state_pinned to blocks, i.e., the cse only finds common
subexpressions within a block. */
if (get_opt_cse()) {
- n = identify_remember(current_ir_graph->value_table, n);
+ ir_node *o = n;
+ n = identify_remember(current_ir_graph->value_table, o);
+ if (o != n)
+ DBG_OPT_CSE(o, n);
}
/* Some more constant expression evaluation. */
/* Now we have a legal, useful node. Enter it in hash table for cse.
Blocks should be unique anyways. (Except the successor of start:
is cse with the start block!) */
- if (get_opt_cse() && (get_irn_opcode(n) != iro_Block))
- n = identify_remember(current_ir_graph->value_table, n);
+ if (get_opt_cse() && (get_irn_opcode(n) != iro_Block)) {
+ ir_node *o = n;
+ n = identify_remember(current_ir_graph->value_table, o);
+ if (o != n)
+ DBG_OPT_CSE(o, n);
+ }
return n;
} /* optimize_in_place_2 */
projects / libfirm / blobdiff