# include "irnode_t.h"
# include "irgraph_t.h"
+# include "irmode_t.h"
# include "iropt_t.h"
-# include "ircons.h"
+# include "ircons_t.h"
# include "irgmod.h"
# include "irvrfy.h"
-# include "tv.h"
+# include "tv_t.h"
# include "dbginfo_t.h"
# include "iropt_dbg.h"
# include "irflag_t.h"
# include "firmstat.h"
+# include "irarch.h"
/* Make types visible to allow most efficient access */
# include "entity_t.h"
}
/**
- * Returns the tarval of a Const node or tarval_bad for all other nodes.
+ * return the value of a Constant
*/
-static INLINE tarval *
-value_of (ir_node *n)
-{
- if ((n != NULL) && (get_irn_op(n) == op_Const))
- return get_Const_tarval(n); /* might return tarval_bad */
- else
- return tarval_bad;
-}
-
static tarval *computed_value_Const(ir_node *n)
{
return get_Const_tarval(n);
}
+/**
+ * return the value of a 'sizeof' SymConst
+ */
static tarval *computed_value_SymConst(ir_node *n)
{
- if ((get_SymConst_kind(n) == size) &&
+ if ((get_SymConst_kind(n) == symconst_size) &&
(get_type_state(get_SymConst_type(n))) == layout_fixed)
- return new_tarval_from_long (get_type_size(get_SymConst_type(n)), mode_Is);
+ return new_tarval_from_long(get_type_size_bytes(get_SymConst_type(n)), get_irn_mode(n));
return tarval_bad;
}
+/**
+ * return the value of an Add
+ */
static tarval *computed_value_Add(ir_node *n)
{
ir_node *a = get_Add_left(n);
return tarval_bad;
}
+/**
+ * return the value of a Sub
+ * Special case: a - a
+ */
static tarval *computed_value_Sub(ir_node *n)
{
ir_node *a = get_Sub_left(n);
ir_node *b = get_Sub_right(n);
+ tarval *ta;
+ tarval *tb;
- tarval *ta = value_of(a);
- tarval *tb = value_of(b);
+ /* a - a */
+ if (a == b)
+ return get_tarval_null(get_irn_mode(n));
+
+ ta = value_of(a);
+ tb = value_of(b);
if ((ta != tarval_bad) && (tb != tarval_bad)
&& (get_irn_mode(a) == get_irn_mode(b))
return tarval_bad;
}
+/**
+ * return the value of an unary Minus
+ */
static tarval *computed_value_Minus(ir_node *n)
{
ir_node *a = get_Minus_op(n);
return tarval_bad;
}
+/**
+ * return the value of a Mul
+ */
static tarval *computed_value_Mul(ir_node *n)
{
ir_node *a = get_Mul_left(n);
&& (v == get_mode_null(get_tarval_mode(v))) )
|| ( ((v = tb) != tarval_bad)
&& (v == get_mode_null(get_tarval_mode(v))) )) {
- return v;
+ return v;
}
}
return tarval_bad;
}
+/**
+ * return the value of a floating point Quot
+ */
static tarval *computed_value_Quot(ir_node *n)
{
ir_node *a = get_Quot_left(n);
return tarval_bad;
}
-static tarval *computed_value_Div(ir_node *n)
+/**
+ * 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)
{
- ir_node *a = get_Div_left(n);
- ir_node *b = get_Div_right(n);
-
tarval *ta = value_of(a);
tarval *tb = value_of(b);
- /* This was missing in original implementation. Why? */
- if ((ta != tarval_bad) && (tb != tarval_bad) && (get_irn_mode(a) == get_irn_mode(b))) {
- if (tb != get_mode_null(get_tarval_mode(tb))) /* div by zero: return tarval_bad */
+ /* Compute c1 / c2 or 0 / a, a != 0 */
+ if ((ta != tarval_bad) && (tb != get_mode_null(get_irn_mode(b)))) {
+ if (tb != tarval_bad) /* 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;
}
-static tarval *computed_value_Mod(ir_node *n)
+/**
+ * return the value of an integer Div
+ */
+static tarval *computed_value_Div(ir_node *n)
{
- ir_node *a = get_Mod_left(n);
- ir_node *b = get_Mod_right(n);
+ return do_computed_value_Div(get_Div_left(n), get_Div_right(n));
+}
+/**
+ * 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);
- /* This was missing in original implementation. Why? */
- if ((ta != tarval_bad) && (tb != tarval_bad) && (get_irn_mode(a) == get_irn_mode(b))) {
- if (tb != get_mode_null(get_tarval_mode(tb))) /* div by zero: return tarval_bad */
+ /* 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;
}
+/**
+ * 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));
+}
+
+/**
+ * return the value of an Abs
+ */
static tarval *computed_value_Abs(ir_node *n)
{
ir_node *a = get_Abs_op(n);
return tarval_bad;
}
+/**
+ * return the value of an And
+ * Special case: a & 0, 0 & b
+ */
static tarval *computed_value_And(ir_node *n)
{
ir_node *a = get_And_left(n);
} else {
tarval *v;
- if ( (tarval_classify ((v = computed_value (a))) == TV_CLASSIFY_NULL)
- || (tarval_classify ((v = computed_value (b))) == TV_CLASSIFY_NULL)) {
+ if ( (classify_tarval ((v = computed_value (a))) == TV_CLASSIFY_NULL)
+ || (classify_tarval ((v = computed_value (b))) == TV_CLASSIFY_NULL)) {
return v;
}
}
return tarval_bad;
}
+/**
+ * return the value of an Or
+ * Special case: a | 1...1, 1...1 | b
+ */
static tarval *computed_value_Or(ir_node *n)
{
ir_node *a = get_Or_left(n);
return tarval_or (ta, tb);
} else {
tarval *v;
- if ( (tarval_classify ((v = computed_value (a))) == TV_CLASSIFY_ALL_ONE)
- || (tarval_classify ((v = computed_value (b))) == TV_CLASSIFY_ALL_ONE)) {
+ if ( (classify_tarval ((v = computed_value (a))) == TV_CLASSIFY_ALL_ONE)
+ || (classify_tarval ((v = computed_value (b))) == TV_CLASSIFY_ALL_ONE)) {
return v;
}
}
return tarval_bad;
}
+/**
+ * return the value of an Eor
+ */
static tarval *computed_value_Eor(ir_node *n)
{
ir_node *a = get_Eor_left(n);
return tarval_bad;
}
+/**
+ * return the value of a Not
+ */
static tarval *computed_value_Not(ir_node *n)
{
ir_node *a = get_Not_op(n);
return tarval_bad;
}
+/**
+ * return the value of a Shl
+ */
static tarval *computed_value_Shl(ir_node *n)
{
ir_node *a = get_Shl_left(n);
return tarval_bad;
}
+/**
+ * return the value of a Shr
+ */
static tarval *computed_value_Shr(ir_node *n)
{
ir_node *a = get_Shr_left(n);
return tarval_bad;
}
+/**
+ * return the value of a Shrs
+ */
static tarval *computed_value_Shrs(ir_node *n)
{
ir_node *a = get_Shrs_left(n);
return tarval_bad;
}
+/**
+ * return the value of a Rot
+ */
static tarval *computed_value_Rot(ir_node *n)
{
ir_node *a = get_Rot_left(n);
tarval *tb = value_of(b);
if ((ta != tarval_bad) && (tb != tarval_bad)) {
- /* return tarval_rot (ta, tb); */
+ return tarval_rot (ta, tb);
}
return tarval_bad;
}
+/**
+ * return the value of a Conv
+ */
static tarval *computed_value_Conv(ir_node *n)
{
ir_node *a = get_Conv_op(n);
return tarval_bad;
}
+/**
+ * return the value of a Proj, handle Proj(Cmp), Proj(Div), Proj(Mod), Proj(DivMod)
+ */
static tarval *computed_value_Proj(ir_node *n)
{
- ir_node *a = get_Proj_pred(n), *b;
+ ir_node *a = get_Proj_pred(n);
ir_node *aa, *ab;
+ long proj_nr;
/* Optimize Cmp nodes.
This performs a first step of unreachable code elimination.
only 1 is used.
There are several case where we can evaluate a Cmp node:
1. The nodes compared are both the same. If we compare for
- equal, greater equal, ... this will return true, else it
- will return false. This step relies on cse.
+ equal, greater equal, ... this will return true, else it
+ will return false. This step relies on cse.
2. The predecessors of Cmp are target values. We can evaluate
- the Cmp.
+ the Cmp.
3. The predecessors are Allocs or void* constants. Allocs never
- return NULL, they raise an exception. Therefore we can predict
- the Cmp result. */
- if (get_irn_op(a) == op_Cmp) {
+ return NULL, they raise an exception. Therefore we can predict
+ the Cmp result. */
+ switch (get_irn_opcode(a)) {
+ case iro_Cmp:
aa = get_Cmp_left(a);
ab = get_Cmp_right(a);
+ proj_nr = get_Proj_proj(n);
if (aa == ab) { /* 1.: */
- /* This is a tric with the bits used for encoding the Cmp
- Proj numbers, the following statement is not the same:
- return new_tarval_from_long ((get_Proj_proj(n) == Eq), mode_b) */
- return new_tarval_from_long ((get_Proj_proj(n) & Eq), mode_b);
+ /* This is a trick with the bits used for encoding the Cmp
+ Proj numbers, the following statement is not the same:
+ return new_tarval_from_long (proj_nr == Eq, mode_b) */
+ return new_tarval_from_long (proj_nr & Eq, mode_b);
} else {
tarval *taa = computed_value (aa);
tarval *tab = computed_value (ab);
if ((taa != tarval_bad) && (tab != tarval_bad)) { /* 2.: */
- /* strange checks... */
- pnc_number flags = tarval_cmp (taa, tab);
- if (flags != False) {
- return new_tarval_from_long (get_Proj_proj(n) & flags, mode_b);
- }
+ /* strange checks... */
+ pnc_number flags = tarval_cmp (taa, tab);
+ if (flags != False) {
+ return new_tarval_from_long (proj_nr & flags, mode_b);
+ }
} else { /* check for 3.: */
- ir_node *aaa = skip_nop(skip_Proj(aa));
- ir_node *aba = skip_nop(skip_Proj(ab));
-
- if ( ( (/* aa is ProjP and aaa is Alloc */
- (get_irn_op(aa) == op_Proj)
- && (mode_is_reference(get_irn_mode(aa)))
- && (get_irn_op(aaa) == op_Alloc))
- && ( (/* ab is constant void */
- (get_irn_op(ab) == op_Const)
- && (mode_is_reference(get_irn_mode(ab)))
- && (get_Const_tarval(ab) == get_mode_null(get_irn_mode(ab))))
- || (/* ab is other Alloc */
- (get_irn_op(ab) == op_Proj)
- && (mode_is_reference(get_irn_mode(ab)))
- && (get_irn_op(aba) == op_Alloc)
- && (aaa != aba))))
- || (/* aa is void and aba is Alloc */
- (get_irn_op(aa) == op_Const)
- && (mode_is_reference(get_irn_mode(aa)))
- && (get_Const_tarval(aa) == get_mode_null(get_irn_mode(aa)))
- && (get_irn_op(ab) == op_Proj)
- && (mode_is_reference(get_irn_mode(ab)))
- && (get_irn_op(aba) == op_Alloc)))
- /* 3.: */
- return new_tarval_from_long (get_Proj_proj(n) & Ne, mode_b);
+ ir_node *aaa = skip_Id(skip_Proj(aa));
+ ir_node *aba = skip_Id(skip_Proj(ab));
+
+ if ( ( (/* aa is ProjP and aaa is Alloc */
+ (get_irn_op(aa) == op_Proj)
+ && (mode_is_reference(get_irn_mode(aa)))
+ && (get_irn_op(aaa) == op_Alloc))
+ && ( (/* ab is constant void */
+ (get_irn_op(ab) == op_Const)
+ && (mode_is_reference(get_irn_mode(ab)))
+ && (get_Const_tarval(ab) == get_mode_null(get_irn_mode(ab))))
+ || (/* ab is other Alloc */
+ (get_irn_op(ab) == op_Proj)
+ && (mode_is_reference(get_irn_mode(ab)))
+ && (get_irn_op(aba) == op_Alloc)
+ && (aaa != aba))))
+ || (/* aa is void and aba is Alloc */
+ (get_irn_op(aa) == op_Const)
+ && (mode_is_reference(get_irn_mode(aa)))
+ && (get_Const_tarval(aa) == get_mode_null(get_irn_mode(aa)))
+ && (get_irn_op(ab) == op_Proj)
+ && (mode_is_reference(get_irn_mode(ab)))
+ && (get_irn_op(aba) == op_Alloc)))
+ /* 3.: */
+ return new_tarval_from_long (proj_nr & Ne, mode_b);
}
}
- } else if (get_irn_op(a) == op_DivMod) {
- tarval *tb = value_of(b = get_DivMod_right(a));
- tarval *ta = value_of(a = get_DivMod_left(a));
-
- if ((ta != tarval_bad) && (tb != tarval_bad) && (get_irn_mode(a) == get_irn_mode(b))) {
- if (tb == get_mode_null(get_tarval_mode(tb))) /* div by zero: return tarval_bad */
- return tarval_bad;
- if (get_Proj_proj(n)== 0) /* Div */
- return tarval_div(ta, tb);
- else /* Mod */
- return tarval_mod(ta, tb);
- }
+ break;
+
+ 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;
+
+ case iro_Div:
+ if (get_Proj_proj(n) == pn_Div_res)
+ return computed_value(a);
+ break;
+
+ case iro_Mod:
+ if (get_Proj_proj(n) == pn_Mod_res)
+ return computed_value(a);
+ break;
+
+ default:
+ return tarval_bad;
}
return tarval_bad;
}
* If the parameter n can be computed, return its value, else tarval_bad.
* Performs constant folding.
*
- * GL: Only if n is arithmetic operator?
+ * @param n The node this should be evaluated
*/
tarval *computed_value(ir_node *n)
{
*/
static ir_op *firm_set_default_computed_value(ir_op *op)
{
-#define CASE(a) \
- case iro_##a: \
- op->computed_value = computed_value_##a; \
+#define CASE(a) \
+ case iro_##a: \
+ op->computed_value = computed_value_##a; \
break
switch (op->code) {
ir_node *a1 = get_Proj_pred (a);
ir_node *b1 = get_Proj_pred (b);
if (a1 != b1 && get_irn_op (a1) == op_Alloc
- && get_irn_op (b1) == op_Alloc)
+ && get_irn_op (b1) == op_Alloc)
return 1;
}
return 0;
{
ir_node *oldn = n;
- /* The Block constructor does not call optimize, but mature_block
+ /* The Block constructor does not call optimize, but mature_immBlock
calls the optimization. */
assert(get_Block_matured(n));
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 ((get_Block_n_cfgpreds(n) == 1) &&
- (get_irn_op(get_Block_cfgpred(n, 0)) == op_Jmp) &&
- (get_opt_control_flow_straightening())) {
- n = get_nodes_Block(get_Block_cfgpred(n, 0)); DBG_OPT_STG;
-
- } else if ((get_Block_n_cfgpreds(n) == 2) &&
- (get_opt_control_flow_weak_simplification())) {
+ if ((get_Block_n_cfgpreds(n) == 1) &&
+ (get_irn_op(get_Block_cfgpred(n, 0)) == op_Jmp)) {
+ 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 = new_Bad();
+ DBG_OPT_DEAD(oldn, n);
+ } else if (get_opt_control_flow_straightening()) {
+ n = predblock;
+ DBG_OPT_STG(oldn, n);
+ }
+ }
+ else if ((get_Block_n_cfgpreds(n) == 1) &&
+ (get_irn_op(skip_Proj(get_Block_cfgpred(n, 0))) == op_Cond)) {
+ 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 = new_Bad();
+ DBG_OPT_DEAD(oldn, n);
+ }
+ }
+ else if ((get_Block_n_cfgpreds(n) == 2) &&
+ (get_opt_control_flow_weak_simplification())) {
/* Test whether Cond jumps twice to this block
@@@ we could do this also with two loops finding two preds from several ones. */
ir_node *a = get_Block_cfgpred(n, 0);
ir_node *b = get_Block_cfgpred(n, 1);
if ((get_irn_op(a) == op_Proj) &&
- (get_irn_op(b) == op_Proj) &&
- (get_Proj_pred(a) == get_Proj_pred(b)) &&
- (get_irn_op(get_Proj_pred(a)) == op_Cond) &&
- (get_irn_mode(get_Cond_selector(get_Proj_pred(a))) == mode_b)) {
+ (get_irn_op(b) == op_Proj) &&
+ (get_Proj_pred(a) == get_Proj_pred(b)) &&
+ (get_irn_op(get_Proj_pred(a)) == op_Cond) &&
+ (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(a); DBG_OPT_IFSIM;
+ twice the same operand and will be optimized away. */
+ n = get_nodes_block(a);
+ DBG_OPT_IFSIM(oldn, a, b, n);
}
} else if (get_opt_unreachable_code() &&
- (n != current_ir_graph->start_block) &&
- (n != current_ir_graph->end_block) ) {
+ (n != current_ir_graph->start_block) &&
+ (n != current_ir_graph->end_block) ) {
int i;
/* If all inputs are dead, this block is dead too, except if it is
the start or end block. This is a step of unreachable code
return n;
}
+/**
+ * Returns a equivalent node for a Jmp, a Bad :-)
+ * Of course this only happens if the Block of the Jmp is Bad.
+ */
static ir_node *equivalent_node_Jmp(ir_node *n)
{
/* GL: Why not same for op_Raise?? */
/* unreachable code elimination */
- if (is_Bad(get_nodes_Block(n)))
+ if (is_Bad(get_nodes_block(n)))
n = new_Bad();
return n;
return n;
}
+/**
+ * Use algebraic simplification a v a = a.
+ */
static ir_node *equivalent_node_Or(ir_node *n)
{
ir_node *oldn = n;
/* remove a v a */
if (a == b) {
- n = a; DBG_OPT_ALGSIM1;
+ n = a;
+
+ DBG_OPT_ALGSIM1(oldn, a, b, n);
}
return n;
}
/**
- * optimize operations that are commutative and have neutral 0.
+ * 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)
{
/* After running compute_node there is only one constant predecessor.
Find this predecessors value and remember the other node: */
- if ((tv = computed_value (a)) != tarval_bad) {
+ if ((tv = computed_value(a)) != tarval_bad) {
on = b;
- } else if ((tv = computed_value (b)) != tarval_bad) {
+ } else if ((tv = computed_value(b)) != tarval_bad) {
on = a;
} else
return n;
/* If this predecessors constant value is zero, the operation is
unnecessary. Remove it: */
- if (tarval_classify (tv) == TV_CLASSIFY_NULL) {
- n = on; DBG_OPT_ALGSIM1;
+ if (classify_tarval (tv) == TV_CLASSIFY_NULL) {
+ n = on;
+
+ DBG_OPT_ALGSIM1(oldn, a, b, n);
}
return n;
}
-static ir_node *equivalent_node_Add(ir_node *n)
-{
- return equivalent_node_neutral_zero(n);
-}
-
-static ir_node *equivalent_node_Eor(ir_node *n)
-{
- return equivalent_node_neutral_zero(n);
-}
+#define equivalent_node_Add equivalent_node_neutral_zero
+#define equivalent_node_Eor equivalent_node_neutral_zero
/**
- * optimize operations that are not commutative but have neutral 0 on left.
- * Test only one predecessor.
+ * optimize operations that are not commutative but have neutral 0 on left,
+ * so a op 0 = a.
*/
static ir_node *equivalent_node_left_zero(ir_node *n)
{
ir_node *a = get_binop_left(n);
ir_node *b = get_binop_right(n);
- if (tarval_classify (computed_value (b)) == TV_CLASSIFY_NULL) {
- n = a; DBG_OPT_ALGSIM1;
+ if (classify_tarval(computed_value(b)) == TV_CLASSIFY_NULL) {
+ n = a;
+
+ DBG_OPT_ALGSIM1(oldn, a, b, n);
}
return n;
}
-static ir_node *equivalent_node_Sub(ir_node *n)
-{
- return equivalent_node_left_zero(n);
-}
-
-static ir_node *equivalent_node_Shl(ir_node *n)
-{
- return equivalent_node_left_zero(n);
-}
-
-static ir_node *equivalent_node_Shr(ir_node *n)
-{
- return equivalent_node_left_zero(n);
-}
-
-static ir_node *equivalent_node_Shrs(ir_node *n)
-{
- return equivalent_node_left_zero(n);
-}
-
-static ir_node *equivalent_node_Rot(ir_node *n)
-{
- return equivalent_node_left_zero(n);
-}
+#define equivalent_node_Sub equivalent_node_left_zero
+#define equivalent_node_Shl equivalent_node_left_zero
+#define equivalent_node_Shr equivalent_node_left_zero
+#define equivalent_node_Shrs equivalent_node_left_zero
+#define equivalent_node_Rot equivalent_node_left_zero
+/**
+ * Er, a "symmetic unop", ie op(op(n)) = n.
+ */
static ir_node *equivalent_node_symmetric_unop(ir_node *n)
{
ir_node *oldn = n;
+ ir_node *pred = get_unop_op(n);
/* optimize symmetric unop */
- if (get_irn_op(get_unop_op(n)) == get_irn_op(n)) {
- n = get_unop_op(get_unop_op(n)); DBG_OPT_ALGSIM2;
+ if (get_irn_op(pred) == get_irn_op(n)) {
+ n = get_unop_op(pred);
+ DBG_OPT_ALGSIM2(oldn, pred, n);
}
return n;
}
-static ir_node *equivalent_node_Not(ir_node *n)
-{
- /* NotNot x == x */
- return equivalent_node_symmetric_unop(n);
-}
+/* NotNot x == x */
+#define equivalent_node_Not equivalent_node_symmetric_unop
-static ir_node *equivalent_node_Minus(ir_node *n)
-{
- /* --x == x */ /* ??? Is this possible or can --x raise an
- out of bounds exception if min =! max? */
- return equivalent_node_symmetric_unop(n);
-}
+/* --x == x */ /* ??? Is this possible or can --x raise an
+ out of bounds exception if min =! max? */
+#define equivalent_node_Minus equivalent_node_symmetric_unop
+/**
+ * Optimize a * 1 = 1 * a = a.
+ */
static ir_node *equivalent_node_Mul(ir_node *n)
{
ir_node *oldn = n;
ir_node *b = get_Mul_right(n);
/* Mul is commutative and has again an other neutral element. */
- if (tarval_classify (computed_value (a)) == TV_CLASSIFY_ONE) {
- n = b; DBG_OPT_ALGSIM1;
- } else if (tarval_classify (computed_value (b)) == TV_CLASSIFY_ONE) {
- n = a; DBG_OPT_ALGSIM1;
+ if (classify_tarval (computed_value (a)) == TV_CLASSIFY_ONE) {
+ n = b;
+ DBG_OPT_ALGSIM1(oldn, a, b, n);
+ } else if (classify_tarval (computed_value (b)) == TV_CLASSIFY_ONE) {
+ n = a;
+ DBG_OPT_ALGSIM1(oldn, a, b, n);
}
return n;
}
+/**
+ * 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 (tarval_classify (computed_value (b)) == TV_CLASSIFY_ONE) { /* div(x, 1) == x */
+ if (classify_tarval(computed_value(b)) == TV_CLASSIFY_ONE) { /* div(x, 1) == x */
/* Turn Div into a tuple (mem, bad, a) */
ir_node *mem = get_Div_mem(n);
turn_into_tuple(n, 3);
set_Tuple_pred(n, pn_Div_M, mem);
- set_Tuple_pred(n, pn_Div_X_except, new_Bad()); /* no exception */
+ set_Tuple_pred(n, pn_Div_X_except, new_Bad()); /* no exception */
set_Tuple_pred(n, pn_Div_res, a);
}
return n;
}
+/**
+ * Optimize a / 1 = a.
+ */
+static ir_node *equivalent_node_DivMod(ir_node *n)
+{
+ ir_node *a = get_DivMod_left(n);
+ ir_node *b = get_DivMod_right(n);
+
+ /* Div is not commutative. */
+ if (classify_tarval(computed_value(b)) == TV_CLASSIFY_ONE) { /* div(x, 1) == x */
+ /* Turn DivMod into a tuple (mem, bad, a, 0) */
+ ir_node *mem = get_Div_mem(n);
+ ir_mode *mode = get_irn_mode(b);
+
+ turn_into_tuple(n, 4);
+ set_Tuple_pred(n, pn_DivMod_M, mem);
+ 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;
+}
+
+/**
+ * Optimize a & 0b1...1 = 0b1...1 & a = a & a = a.
+ */
static ir_node *equivalent_node_And(ir_node *n)
{
ir_node *oldn = n;
if (a == b) {
n = a; /* And has it's own neutral element */
- } else if (tarval_classify (computed_value (a)) == TV_CLASSIFY_ALL_ONE) {
+ } else if (classify_tarval(computed_value(a)) == TV_CLASSIFY_ALL_ONE) {
n = b;
- } else if (tarval_classify (computed_value (b)) == TV_CLASSIFY_ALL_ONE) {
+ DBG_OPT_ALGSIM1(oldn, a, b, n);
+ } else if (classify_tarval(computed_value(b)) == TV_CLASSIFY_ALL_ONE) {
n = a;
+ DBG_OPT_ALGSIM1(oldn, a, b, n);
}
- if (n != oldn) DBG_OPT_ALGSIM1;
return n;
}
+/**
+ * Try to remove useless conv's:
+ */
static ir_node *equivalent_node_Conv(ir_node *n)
{
ir_node *oldn = n;
ir_mode *a_mode = get_irn_mode(a);
if (n_mode == a_mode) { /* No Conv necessary */
- n = a; DBG_OPT_ALGSIM3;
+ n = a;
+ DBG_OPT_ALGSIM3(oldn, a, n);
} else if (get_irn_op(a) == op_Conv) { /* Conv(Conv(b)) */
ir_mode *b_mode;
if (n_mode == b_mode) {
if (n_mode == mode_b) {
- n = b; /* Convb(Conv*(xxxb(...))) == xxxb(...) */ DBG_OPT_ALGSIM1;
+ n = b; /* Convb(Conv*(xxxb(...))) == xxxb(...) */
+ DBG_OPT_ALGSIM1(oldn, a, b, n);
}
else if (mode_is_int(n_mode) || mode_is_character(n_mode)) {
- if (smaller_mode(b_mode, a_mode)){
- n = b; /* ConvS(ConvL(xxxS(...))) == xxxS(...) */ DBG_OPT_ALGSIM1;
- }
+ if (smaller_mode(b_mode, a_mode)){
+ n = b; /* ConvS(ConvL(xxxS(...))) == xxxS(...) */
+ DBG_OPT_ALGSIM1(oldn, a, b, n);
+ }
}
}
}
return n;
}
+static ir_node *equivalent_node_Cast(ir_node *n) {
+ ir_node *pred = get_Cast_op(n);
+ if (get_irn_type(pred) == get_Cast_type(n))
+ n = pred;
+ return n;
+}
+
static ir_node *equivalent_node_Phi(ir_node *n)
{
/* 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.
+ themselves.
*/
int i, n_preds;
n_preds = get_Phi_n_preds(n);
- block = get_nodes_Block(n);
+ block = get_nodes_block(n);
/* @@@ fliegt 'raus, sollte aber doch immer wahr sein!!!
assert(get_irn_arity(block) == n_preds && "phi in wrong block!"); */
if ((is_Bad(block)) || /* Control dead */
(block == current_ir_graph->start_block)) /* There should be no Phi nodes */
- return new_Bad(); /* in the Start Block. */
+ return new_Bad(); /* in the Start Block. */
if (n_preds == 0) return n; /* Phi of dead Region without predecessors. */
value that is known at a certain point. This is useful for
dataflow analysis. */
if (n_preds == 2) {
- ir_node *a = follow_Id (get_Phi_pred(n, 0));
- ir_node *b = follow_Id (get_Phi_pred(n, 1));
+ ir_node *a = get_Phi_pred(n, 0);
+ ir_node *b = get_Phi_pred(n, 1);
if ( (get_irn_op(a) == op_Confirm)
- && (get_irn_op(b) == op_Confirm)
- && follow_Id (get_irn_n(a, 0) == get_irn_n(b, 0))
- && (get_irn_n(a, 1) == get_irn_n (b, 1))
- && (a->data.num == (~b->data.num & irpn_True) )) {
+ && (get_irn_op(b) == op_Confirm)
+ && follow_Id (get_irn_n(a, 0) == get_irn_n(b, 0))
+ && (get_irn_n(a, 1) == get_irn_n (b, 1))
+ && (a->data.num == (~b->data.num & irpn_True) )) {
return get_irn_n(a, 0);
}
}
#endif
+ /* 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 = follow_Id(get_Phi_pred(n, i));
- /* skip Id's */
- set_Phi_pred(n, i, first_val);
+ first_val = get_Phi_pred(n, i);
if ( (first_val != n) /* not self pointer */
- && (get_irn_op(first_val) != op_Bad) /* value not dead */
- && !(is_Bad (get_Block_cfgpred(block, i))) ) { /* not dead control flow */
- break; /* then found first value. */
+#if 1
+ && (get_irn_op(first_val) != op_Bad)
+#endif
+ ) { /* value not dead */
+ break; /* then found first value. */
}
}
/* follow_Id () for rest of inputs, determine if any of these
are non-self-referencing */
while (++i < n_preds) {
- scnd_val = follow_Id(get_Phi_pred(n, i));
- /* skip Id's */
- set_Phi_pred(n, i, scnd_val);
+ scnd_val = get_Phi_pred(n, i);
if ( (scnd_val != n)
- && (scnd_val != first_val)
- && (get_irn_op(scnd_val) != op_Bad)
- && !(is_Bad (get_Block_cfgpred(block, i))) ) {
+ && (scnd_val != first_val)
+#if 1
+ && (get_irn_op(scnd_val) != op_Bad)
+#endif
+ ) {
break;
}
}
/* Fold, if no multiple distinct non-self-referencing inputs */
if (i >= n_preds) {
- n = first_val; DBG_OPT_PHI;
+ n = first_val;
+ DBG_OPT_PHI(oldn, first_val, n);
} else {
- /* skip the remaining Ids. */
- while (++i < n_preds) {
- set_Phi_pred(n, i, follow_Id(get_Phi_pred(n, i)));
- }
- }
- return n;
-}
-
-static ir_node *equivalent_node_Load(ir_node *n)
-{
-#if 0 /* Is an illegal transformation: different nodes can
- represent the same pointer value!! */
- ir_node *a = skip_Proj(get_Load_mem(n));
- ir_node *b = get_Load_ptr(n);
-
- if (get_irn_op(a) == op_Store) {
- if ( different_identity (b, get_Store_ptr(a))) {
- /* load and store use different pointers, therefore load
- needs not take store's memory but the state before. */
- set_Load_mem (n, get_Store_mem(a));
- } else if (( 0 /* ???didn't get cryptic test that returns 0 */ )) {
- }
- }
-#endif
- return n;
-}
-
-static ir_node *equivalent_node_Store(ir_node *n)
-{
- ir_node *oldn = n;
-
- /* remove unnecessary store. */
- ir_node *a = skip_Proj(get_Store_mem(n));
- ir_node *b = get_Store_ptr(n);
- ir_node *c = skip_Proj(get_Store_value(n));
-
- if (get_irn_op(a) == op_Store
- && get_Store_ptr(a) == b
- && skip_Proj(get_Store_value(a)) == c) {
- /* We have twice exactly the same store -- a write after write. */
- n = a; DBG_OPT_WAW;
- } else if (get_irn_op(c) == op_Load
- && (a == c || skip_Proj(get_Load_mem(c)) == a)
- && get_Load_ptr(c) == b ) {
- /* We just loaded the value from the same memory, i.e., the store
- doesn't change the memory -- a write after read. */
- a = get_Store_mem(n);
- turn_into_tuple(n, 2);
- set_Tuple_pred(n, pn_Store_M, a);
- set_Tuple_pred(n, pn_Store_X_except, new_Bad()); DBG_OPT_WAR;
+ /* skip the remaining Ids (done in get_Phi_pred). */
+ /* superfluous, since we walk all to propagate Block's Bads.
+ while (++i < n_preds) get_Phi_pred(n, i); */
}
return n;
}
+/**
+ * optimize Proj(Tuple) and gigo for ProjX in Bad block
+ */
static ir_node *equivalent_node_Proj(ir_node *n)
{
ir_node *oldn = n;
if ( get_irn_op(a) == op_Tuple) {
/* Remove the Tuple/Proj combination. */
if ( get_Proj_proj(n) <= get_Tuple_n_preds(a) ) {
- n = get_Tuple_pred(a, get_Proj_proj(n)); DBG_OPT_TUPLE;
+ n = get_Tuple_pred(a, get_Proj_proj(n));
+ DBG_OPT_TUPLE(oldn, a, n);
} else {
assert(0); /* This should not happen! */
n = new_Bad();
}
} else if (get_irn_mode(n) == mode_X &&
- is_Bad(get_nodes_Block(n))) {
+ is_Bad(get_nodes_block(n))) {
/* Remove dead control flow -- early gigo. */
n = new_Bad();
}
return n;
}
+/**
+ * Remove Id's.
+ */
static ir_node *equivalent_node_Id(ir_node *n)
{
ir_node *oldn = n;
- n = follow_Id (n); DBG_OPT_ID;
+ n = follow_Id(n);
+ DBG_OPT_ID(oldn, n);
return n;
}
-/*
-case iro_Mod, Quot, DivMod
- DivMod allocates new nodes --> it's treated in transform node.
- What about Quot, DivMod?
-*/
-
/**
* 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
* in array fits, we transform n into a tuple (e.g., Div).
*/
ir_node *
-equivalent_node (ir_node *n)
+equivalent_node(ir_node *n)
{
if (n->op->equivalent_node)
return n->op->equivalent_node(n);
*/
static ir_op *firm_set_default_equivalent_node(ir_op *op)
{
-#define CASE(a) \
- case iro_##a: \
- op->equivalent_node = equivalent_node_##a; \
+#define CASE(a) \
+ case iro_##a: \
+ op->equivalent_node = equivalent_node_##a; \
break
switch (op->code) {
CASE(Minus);
CASE(Mul);
CASE(Div);
+ CASE(DivMod);
CASE(And);
CASE(Conv);
+ CASE(Cast);
CASE(Phi);
- CASE(Load);
- CASE(Store);
CASE(Proj);
CASE(Id);
default:
} /* end switch */
}
+/** Do architecture dependend optimizations on Mul nodes */
+static ir_node *transform_node_Mul(ir_node *n) {
+ return arch_dep_replace_mul_with_shifts(n);
+}
+
static ir_node *transform_node_Div(ir_node *n)
{
- tarval *ta = computed_value(n);
+ tarval *tv = computed_value(n);
+ ir_node *value = n;
+
+ /* BEWARE: it is NOT possible to optimize a/a to 1, as this may cause a exception */
- if (ta != tarval_bad) {
+ if (tv != tarval_bad)
+ value = new_Const(get_tarval_mode(tv), tv);
+ else /* Try architecture dependand optimization */
+ value = arch_dep_replace_div_by_const(n);
+
+ if (value != n) {
/* Turn Div into a tuple (mem, bad, value) */
ir_node *mem = get_Div_mem(n);
turn_into_tuple(n, 3);
set_Tuple_pred(n, pn_Div_M, mem);
set_Tuple_pred(n, pn_Div_X_except, new_Bad());
- set_Tuple_pred(n, pn_Div_res, new_Const(get_tarval_mode(ta), ta));
+ set_Tuple_pred(n, pn_Div_res, value);
}
return n;
}
static ir_node *transform_node_Mod(ir_node *n)
{
- tarval *ta = computed_value(n);
+ tarval *tv = computed_value(n);
+ ir_node *value = n;
+
+ /* BEWARE: it is NOT possible to optimize a%a to 0, as this may cause a exception */
+
+ if (tv != tarval_bad)
+ value = new_Const(get_tarval_mode(tv), tv);
+ else /* Try architecture dependand optimization */
+ value = arch_dep_replace_mod_by_const(n);
- if (ta != tarval_bad) {
+ if (value != n) {
/* Turn Mod into a tuple (mem, bad, value) */
ir_node *mem = get_Mod_mem(n);
+
turn_into_tuple(n, 3);
set_Tuple_pred(n, pn_Mod_M, mem);
set_Tuple_pred(n, pn_Mod_X_except, new_Bad());
- set_Tuple_pred(n, pn_Mod_res, new_Const(get_tarval_mode(ta), ta));
+ set_Tuple_pred(n, pn_Mod_res, value);
}
return n;
}
ir_node *a = get_DivMod_left(n);
ir_node *b = get_DivMod_right(n);
ir_mode *mode = get_irn_mode(a);
+ tarval *ta = value_of(a);
+ tarval *tb = value_of(b);
if (!(mode_is_int(mode) && mode_is_int(get_irn_mode(b))))
return n;
- if (a == b) {
- a = new_Const(mode, get_mode_one(mode));
- b = new_Const(mode, get_mode_null(mode));
- evaluated = 1;
- } else {
- tarval *ta = value_of(a);
- tarval *tb = value_of(b);
-
- if (tb != tarval_bad) {
- if (tb == get_mode_one(get_tarval_mode(tb))) {
- b = new_Const (mode, get_mode_null(mode));
- evaluated = 1;
- } else if (ta != tarval_bad) {
- tarval *resa, *resb;
- resa = tarval_div (ta, tb);
- if (resa == tarval_bad) return n; /* Causes exception!!! Model by replacing through
- Jmp for X result!? */
- resb = tarval_mod (ta, tb);
- if (resb == tarval_bad) return n; /* Causes exception! */
- a = new_Const (mode, resa);
- b = new_Const (mode, resb);
- evaluated = 1;
- }
- } else if (ta == get_mode_null(get_tarval_mode(ta))) {
- b = a;
+ /* BEWARE: it is NOT possible to optimize a/a to 1, as this may cause a exception */
+
+ if (tb != tarval_bad) {
+ if (tb == get_mode_one(get_tarval_mode(tb))) {
+ b = new_Const (mode, get_mode_null(mode));
+ evaluated = 1;
+ } else if (ta != tarval_bad) {
+ tarval *resa, *resb;
+ resa = tarval_div (ta, tb);
+ if (resa == tarval_bad) return n; /* Causes exception!!! Model by replacing through
+ Jmp for X result!? */
+ resb = tarval_mod (ta, tb);
+ if (resb == tarval_bad) return n; /* Causes exception! */
+ a = new_Const (mode, resa);
+ b = new_Const (mode, resb);
evaluated = 1;
}
+ else { /* Try architecture dependand optimization */
+ arch_dep_replace_divmod_by_const(&a, &b, n);
+ evaluated = a != NULL;
+ }
+ } else if (ta == get_mode_null(mode)) {
+ /* 0 / non-Const = 0 */
+ b = a;
+ evaluated = 1;
}
+
if (evaluated) { /* replace by tuple */
ir_node *mem = get_DivMod_mem(n);
turn_into_tuple(n, 4);
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, b);
- assert(get_nodes_Block(n));
+ assert(get_nodes_block(n));
}
return n;
(get_irn_mode(a) == mode_b) &&
(get_opt_unreachable_code())) {
/* It's a boolean Cond, branching on a boolean constant.
- Replace it by a tuple (Bad, Jmp) or (Jmp, Bad) */
- jmp = new_r_Jmp(current_ir_graph, get_nodes_Block(n));
+ Replace it by a tuple (Bad, Jmp) or (Jmp, Bad) */
+ jmp = new_r_Jmp(current_ir_graph, get_nodes_block(n));
turn_into_tuple(n, 2);
if (ta == tarval_b_true) {
set_Tuple_pred(n, pn_Cond_false, new_Bad());
set_Tuple_pred(n, pn_Cond_true, new_Bad());
}
/* We might generate an endless loop, so keep it alive. */
- add_End_keepalive(get_irg_end(current_ir_graph), get_nodes_Block(n));
+ add_End_keepalive(get_irg_end(current_ir_graph), get_nodes_block(n));
} else if ((ta != tarval_bad) &&
- (get_irn_mode(a) == mode_Iu) &&
- (get_Cond_kind(n) == dense) &&
- (get_opt_unreachable_code())) {
+ (get_irn_mode(a) == mode_Iu) &&
+ (get_Cond_kind(n) == dense) &&
+ (get_opt_unreachable_code())) {
/* I don't want to allow Tuples smaller than the biggest Proj.
Also this tuple might get really big...
I generate the Jmp here, and remember it in link. Link is used
when optimizing Proj. */
- set_irn_link(n, new_r_Jmp(current_ir_graph, get_nodes_Block(n)));
+ set_irn_link(n, new_r_Jmp(current_ir_graph, get_nodes_block(n)));
/* We might generate an endless loop, so keep it alive. */
- add_End_keepalive(get_irg_end(current_ir_graph), get_nodes_Block(n));
+ add_End_keepalive(get_irg_end(current_ir_graph), get_nodes_block(n));
} else if ((get_irn_op(a) == op_Eor)
- && (get_irn_mode(a) == mode_b)
- && (tarval_classify(computed_value(get_Eor_right(a))) == TV_CLASSIFY_ONE)) {
+ && (get_irn_mode(a) == mode_b)
+ && (classify_tarval(computed_value(get_Eor_right(a))) == TV_CLASSIFY_ONE)) {
/* The Eor is a negate. Generate a new Cond without the negate,
simulate the negate by exchanging the results. */
- set_irn_link(n, new_r_Cond(current_ir_graph, get_nodes_Block(n),
- get_Eor_left(a)));
+ set_irn_link(n, new_r_Cond(current_ir_graph, get_nodes_block(n),
+ get_Eor_left(a)));
} else if ((get_irn_op(a) == op_Not)
- && (get_irn_mode(a) == mode_b)) {
+ && (get_irn_mode(a) == mode_b)) {
/* A Not before the Cond. Generate a new Cond without the Not,
simulate the Not by exchanging the results. */
- set_irn_link(n, new_r_Cond(current_ir_graph, get_nodes_Block(n),
- get_Not_op(a)));
+ set_irn_link(n, new_r_Cond(current_ir_graph, get_nodes_block(n),
+ get_Not_op(a)));
}
return n;
}
if ((get_irn_mode(n) == mode_b)
&& (get_irn_op(a) == op_Proj)
&& (get_irn_mode(a) == mode_b)
- && (tarval_classify (computed_value (b)) == TV_CLASSIFY_ONE)
+ && (classify_tarval (computed_value (b)) == TV_CLASSIFY_ONE)
&& (get_irn_op(get_Proj_pred(a)) == op_Cmp))
/* The Eor negates a Cmp. The Cmp has the negated result anyways! */
- n = new_r_Proj(current_ir_graph, get_nodes_Block(n), get_Proj_pred(a),
- mode_b, get_negated_pnc(get_Proj_proj(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)));
else if ((get_irn_mode(n) == mode_b)
- && (tarval_classify (computed_value (b)) == TV_CLASSIFY_ONE))
+ && (classify_tarval (computed_value (b)) == TV_CLASSIFY_ONE))
/* The Eor is a Not. Replace it by a Not. */
/* ????!!!Extend to bitfield 1111111. */
- n = new_r_Not(current_ir_graph, get_nodes_Block(n), a, mode_b);
+ n = new_r_Not(current_ir_graph, get_nodes_block(n), a, mode_b);
return n;
}
+/**
+ * Transform a boolean Not.
+ */
static ir_node *transform_node_Not(ir_node *n)
{
ir_node *a = get_Not_op(n);
&& (get_irn_mode(a) == mode_b)
&& (get_irn_op(get_Proj_pred(a)) == op_Cmp))
/* We negate a Cmp. The Cmp has the negated result anyways! */
- n = new_r_Proj(current_ir_graph, get_nodes_Block(n), get_Proj_pred(a),
- mode_b, get_negated_pnc(get_Proj_proj(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)));
+
+ return n;
+}
+
+static ir_node *transform_node_Cast(ir_node *n) {
+ ir_node *pred = get_Cast_op(n);
+ type *tp = get_irn_type(pred);
+ if (get_irn_op(pred) == op_Const && get_Const_type(pred) != tp) {
+ n = new_rd_Const_type(NULL, current_ir_graph, get_nodes_block(pred), get_irn_mode(pred),
+ get_Const_tarval(pred), tp);
+ } else if ((get_irn_op(pred) == op_SymConst) && (get_SymConst_value_type(pred) != tp)) {
+ n = new_rd_SymConst_type(NULL, current_ir_graph, get_nodes_block(pred), get_SymConst_symbol(pred),
+ get_SymConst_kind(pred), tp);
+ }
+ return n;
+}
+
+/**
+ * Transform a Div/Mod/DivMod with a non-zero constant. Must be
+ * done here instead of equivalent node because it creates new
+ * nodes.
+ * Removes the exceptions and routes the memory to the initial mem.
+ *
+ * Further, it optimizes jump tables by removing all impossible cases.
+ */
+static ir_node *transform_node_Proj(ir_node *proj)
+{
+ ir_node *n = get_Proj_pred(proj);
+ ir_node *b;
+ tarval *tb;
+ long proj_nr;
+
+ switch (get_irn_opcode(n)) {
+ case iro_Div:
+ b = get_Div_right(n);
+ tb = computed_value(b);
+
+ if (tb != tarval_bad && classify_tarval(tb) != TV_CLASSIFY_NULL) { /* div(x, c) && c != 0 */
+ proj_nr = get_Proj_proj(proj);
+
+ /* this node may float */
+ set_irn_pinned(n, op_pin_state_floats);
+
+ if (proj_nr == pn_Div_X_except) {
+ /* we found an exception handler, remove it */
+ return new_Bad();
+ }
+ else {
+ /* the memory Proj can be removed */
+ ir_node *res = get_Div_mem(n);
+ set_Div_mem(n, get_irg_initial_mem(current_ir_graph));
+
+ if (proj_nr == pn_Div_M)
+ return res;
+ }
+ }
+ break;
+ case iro_Mod:
+ b = get_Mod_right(n);
+ tb = computed_value(b);
+
+ if (tb != tarval_bad && classify_tarval(tb) != TV_CLASSIFY_NULL) { /* mod(x, c) && c != 0 */
+ proj_nr = get_Proj_proj(proj);
+
+ /* this node may float */
+ set_irn_pinned(n, op_pin_state_floats);
+
+ if (proj_nr == pn_Mod_X_except) {
+ /* we found an exception handler, remove it */
+ return new_Bad();
+ }
+ else {
+ /* the memory Proj can be removed */
+ ir_node *res = get_Mod_mem(n);
+ set_Mod_mem(n, get_irg_initial_mem(current_ir_graph));
+ if (proj_nr == pn_Mod_M)
+ return res;
+ }
+ }
+ break;
+ case iro_DivMod:
+ b = get_DivMod_right(n);
+ tb = computed_value(b);
+
+ if (tb != tarval_bad && classify_tarval(tb) != TV_CLASSIFY_NULL) { /* DivMod(x, c) && c != 0 */
+ proj_nr = get_Proj_proj(proj);
+
+ /* this node may float */
+ set_irn_pinned(n, op_pin_state_floats);
+
+ if (proj_nr == pn_DivMod_X_except) {
+ /* we found an exception handler, remove it */
+ return new_Bad();
+ }
+ else {
+ /* the memory Proj can be removed */
+ ir_node *res = get_DivMod_mem(n);
+ set_DivMod_mem(n, get_irg_initial_mem(current_ir_graph));
+ if (proj_nr == pn_DivMod_M)
+ return res;
+ }
+ }
+ break;
+
+ case iro_Cond:
+ if (get_opt_unreachable_code()) {
+ b = get_Cond_selector(n);
+ tb = computed_value(b);
+
+ if (tb != tarval_bad && mode_is_int(get_tarval_mode(tb))) {
+ /* we have a constant switch */
+ long num = get_Proj_proj(proj);
+
+ if (num != get_Cond_defaultProj(n)) { /* we cannot optimize default Proj's yet */
+ if (get_tarval_long(tb) == num) {
+ /* Do NOT create a jump here, or we will have 2 control flow ops
+ * in a block. This case is optimized away in optimize_cf(). */
+ return proj;
+ }
+ else
+ return new_Bad();
+ }
+ }
+ }
+ return proj;
+
+ case iro_Tuple:
+ /* should not happen, but if it does will be optimized away */
+ break;
+
+ default:
+ /* do nothing */
+ return proj;
+ }
+
+ /* we have added a Tuple, optimize it for the current Proj away */
+ return equivalent_node_Proj(proj);
+}
+
+/**
+ * returns the operands of a commutative bin-op, if one operand is
+ * a const, it is returned as the second one.
+ */
+static void get_comm_Binop_Ops(ir_node *binop, ir_node **a, ir_node **c)
+{
+ ir_node *op_a = get_binop_left(binop);
+ ir_node *op_b = get_binop_right(binop);
+
+ assert(is_op_commutative(get_irn_op(binop)));
+
+ if (get_irn_op(op_a) == op_Const) {
+ *a = op_b;
+ *c = op_a;
+ }
+ else {
+ *a = op_a;
+ *c = op_b;
+ }
+}
+
+/**
+ * Optimize a Or(And(Or(And(v,c4),c3),c2),c1) pattern if possible.
+ * Such pattern may arise in bitfield stores.
+ *
+ * value c4 value c4 & c2
+ * AND c3 AND c1 | c3
+ * OR c2 ===> OR
+ * AND c1
+ * OR
+ */
+static ir_node *transform_node_Or(ir_node *or)
+{
+ ir_node *and, *c1;
+ ir_node *or_l, *c2;
+ ir_node *and_l, *c3;
+ ir_node *value, *c4;
+ ir_node *new_and, *new_const, *block;
+ ir_mode *mode = get_irn_mode(or);
+
+ tarval *tv1, *tv2, *tv3, *tv4, *tv, *n_tv4, *n_tv2;
+
+ get_comm_Binop_Ops(or, &and, &c1);
+ if ((get_irn_op(c1) != op_Const) || (get_irn_op(and) != op_And))
+ return or;
+
+ get_comm_Binop_Ops(and, &or_l, &c2);
+ if ((get_irn_op(c2) != op_Const) || (get_irn_op(or_l) != op_Or))
+ return or;
+
+ get_comm_Binop_Ops(or_l, &and_l, &c3);
+ if ((get_irn_op(c3) != op_Const) || (get_irn_op(and_l) != op_And))
+ return or;
+
+ get_comm_Binop_Ops(and_l, &value, &c4);
+ if (get_irn_op(c4) != op_Const)
+ return or;
+
+ /* ok, found the pattern, check for conditions */
+ assert(mode == get_irn_mode(and));
+ assert(mode == get_irn_mode(or_l));
+ assert(mode == get_irn_mode(and_l));
+
+ tv1 = get_Const_tarval(c1);
+ tv2 = get_Const_tarval(c2);
+ tv3 = get_Const_tarval(c3);
+ tv4 = get_Const_tarval(c4);
+
+ tv = tarval_or(tv4, tv2);
+ if (classify_tarval(tv) != TV_CLASSIFY_ALL_ONE) {
+ /* have at least one 0 at the same bit position */
+ return or;
+ }
+
+ n_tv4 = tarval_not(tv4);
+ if (tv3 != tarval_and(tv3, n_tv4)) {
+ /* bit in the or_mask is outside the and_mask */
+ return or;
+ }
+
+ n_tv2 = tarval_not(tv2);
+ if (tv1 != tarval_and(tv1, n_tv2)) {
+ /* bit in the or_mask is outside the and_mask */
+ return or;
+ }
+
+ /* ok, all conditions met */
+ block = get_nodes_block(or);
+
+ new_and = new_r_And(current_ir_graph, block,
+ value, new_r_Const(current_ir_graph, block, mode, tarval_and(tv4, tv2)), mode);
+
+ new_const = new_r_Const(current_ir_graph, block, mode, tarval_or(tv3, tv1));
+
+ set_Or_left(or, new_and);
+ set_Or_right(or, new_const);
+
+ /* check for more */
+ return transform_node_Or(or);
+}
+
+/* forward */
+static ir_node *transform_node(ir_node *n);
+
+/**
+ * Optimize (a >> c1) >> c2), works for Shr, Shrs, Shl
+ */
+static ir_node * transform_node_shift(ir_node *n)
+{
+ ir_node *left;
+ tarval *tv1, *tv2, *res;
+ ir_mode *mode;
+ int modulo_shf, flag;
+
+ left = get_binop_left(n);
+
+ /* different operations */
+ if (get_irn_op(left) != get_irn_op(n))
+ return n;
+
+ tv1 = computed_value(get_binop_right(n));
+ if (tv1 == tarval_bad)
+ return n;
+
+ tv2 = computed_value(get_binop_right(left));
+ if (tv2 == tarval_bad)
+ return n;
+
+ res = tarval_add(tv1, tv2);
+
+ /* beware: a simple replacement works only, if res < modulo shift */
+ mode = get_irn_mode(n);
+ flag = 0;
+
+ modulo_shf = get_mode_modulo_shift(mode);
+ if (modulo_shf > 0) {
+ tarval *modulo = new_tarval_from_long(modulo_shf, get_tarval_mode(res));
+
+ if (tarval_cmp(res, modulo) & Lt)
+ flag = 1;
+ }
+ else
+ flag = 1;
+
+ if (flag) {
+ /* ok, we can replace it */
+ ir_node *in[2], *irn, *block = get_nodes_block(n);
+
+ in[0] = get_binop_left(left);
+ in[1] = new_r_Const(current_ir_graph, block, get_tarval_mode(res), res);
+
+ irn = new_ir_node(NULL, current_ir_graph, block, get_irn_op(n), mode, 2, in);
+
+ return transform_node(irn);
+ }
return n;
}
*/
static ir_op *firm_set_default_transform_node(ir_op *op)
{
-#define CASE(a) \
- case iro_##a: \
- op->transform_node = transform_node_##a; \
+#define CASE(a) \
+ case iro_##a: \
+ op->transform_node = transform_node_##a; \
break
switch (op->code) {
+ CASE(Mul);
CASE(Div);
CASE(Mod);
CASE(DivMod);
CASE(Cond);
CASE(Eor);
CASE(Not);
+ CASE(Cast);
+ CASE(Proj);
+ CASE(Or);
+ case iro_Shr:
+ case iro_Shrs:
+ case iro_Shl:
+ op->transform_node = transform_node_shift;
+ break;
default:
op->transform_node = NULL;
}
in a graph. */
#define N_IR_NODES 512
+/** Compares the attributes of two Const nodes. */
static int node_cmp_attr_Const(ir_node *a, ir_node *b)
{
return (get_Const_tarval(a) != get_Const_tarval(b))
|| (get_Const_type(a) != get_Const_type(b));
}
+/** Compares the attributes of two Proj nodes. */
static int node_cmp_attr_Proj(ir_node *a, ir_node *b)
{
return get_irn_proj_attr (a) != get_irn_proj_attr (b);
}
+/** Compares the attributes of two Filter nodes. */
static int node_cmp_attr_Filter(ir_node *a, ir_node *b)
{
return get_Filter_proj(a) != get_Filter_proj(b);
}
+/** Compares the attributes of two Alloc nodes. */
static int node_cmp_attr_Alloc(ir_node *a, ir_node *b)
{
return (get_irn_alloc_attr(a).where != get_irn_alloc_attr(b).where)
- || (get_irn_alloc_attr(a).type != get_irn_alloc_attr(b).type);
+ || (get_irn_alloc_attr(a).type != get_irn_alloc_attr(b).type);
}
+/** Compares the attributes of two Free nodes. */
static int node_cmp_attr_Free(ir_node *a, ir_node *b)
{
return (get_irn_free_attr(a) != get_irn_free_attr(b));
}
+/** Compares the attributes of two SymConst nodes. */
static int node_cmp_attr_SymConst(ir_node *a, ir_node *b)
{
return (get_irn_symconst_attr(a).num != get_irn_symconst_attr(b).num)
- || (get_irn_symconst_attr(a).tori.typ != get_irn_symconst_attr(b).tori.typ);
+ || (get_irn_symconst_attr(a).sym.type_p != get_irn_symconst_attr(b).sym.type_p)
+ || (get_irn_symconst_attr(a).tp != get_irn_symconst_attr(b).tp);
}
+/** Compares the attributes of two Call nodes. */
static int node_cmp_attr_Call(ir_node *a, ir_node *b)
{
return (get_irn_call_attr(a) != get_irn_call_attr(b));
}
+/** Compares the attributes of two FuncCall nodes. */
static int node_cmp_attr_FuncCall(ir_node *a, ir_node *b)
{
return (get_irn_funccall_attr(a) != get_irn_funccall_attr(b));
}
+/** Compares the attributes of two Sel nodes. */
static int node_cmp_attr_Sel(ir_node *a, ir_node *b)
{
- return (get_irn_sel_attr(a).ent->kind != get_irn_sel_attr(b).ent->kind)
- || (get_irn_sel_attr(a).ent->name != get_irn_sel_attr(b).ent->name)
- || (get_irn_sel_attr(a).ent->owner != get_irn_sel_attr(b).ent->owner)
+ return (get_irn_sel_attr(a).ent->kind != get_irn_sel_attr(b).ent->kind)
+ || (get_irn_sel_attr(a).ent->name != get_irn_sel_attr(b).ent->name)
+ || (get_irn_sel_attr(a).ent->owner != get_irn_sel_attr(b).ent->owner)
|| (get_irn_sel_attr(a).ent->ld_name != get_irn_sel_attr(b).ent->ld_name)
- || (get_irn_sel_attr(a).ent->type != get_irn_sel_attr(b).ent->type);
+ || (get_irn_sel_attr(a).ent->type != get_irn_sel_attr(b).ent->type);
}
+/** Compares the attributes of two Phi nodes. */
static int node_cmp_attr_Phi(ir_node *a, ir_node *b)
{
return get_irn_phi_attr (a) != get_irn_phi_attr (b);
}
+/** Compares the attributes of two Cast nodes. */
static int node_cmp_attr_Cast(ir_node *a, ir_node *b)
{
return get_Cast_type(a) != get_Cast_type(b);
}
+/** Compares the attributes of two Load nodes. */
+static int node_cmp_attr_Load(ir_node *a, ir_node *b)
+{
+ if (get_Load_volatility(a) == volatility_is_volatile ||
+ get_Load_volatility(b) == volatility_is_volatile)
+ /* NEVER do CSE on volatile Loads */
+ return 1;
+
+ return get_Load_mode(a) != get_Load_mode(b);
+}
+
+/** Compares the attributes of two Store nodes. */
+static int node_cmp_attr_Store(ir_node *a, ir_node *b)
+{
+ /* NEVER do CSE on volatile Stores */
+ return (get_Store_volatility(a) == volatility_is_volatile ||
+ get_Store_volatility(b) == volatility_is_volatile);
+}
+
/**
* set the default node attribute compare operation
*/
static ir_op *firm_set_default_node_cmp_attr(ir_op *op)
{
-#define CASE(a) \
- case iro_##a: \
- op->node_cmp_attr = node_cmp_attr_##a; \
+#define CASE(a) \
+ case iro_##a: \
+ op->node_cmp_attr = node_cmp_attr_##a; \
break
switch (op->code) {
CASE(Sel);
CASE(Phi);
CASE(Cast);
+ CASE(Load);
+ CASE(Store);
default:
op->node_cmp_attr = NULL;
}
if (irn_arity_a != get_irn_arity(b))
return 1;
- /* for block-local cse and pinned nodes: */
- if (!get_opt_global_cse() || (get_op_pinned(get_irn_op(a)) == pinned)) {
+ /* for block-local cse and op_pin_state_pinned nodes: */
+ if (!get_opt_global_cse() || (get_irn_pinned(a) == op_pin_state_pinned)) {
if (get_irn_n(a, -1) != get_irn_n(b, -1))
return 1;
}
return 0;
}
-/**
+/*
* Calculate a hash value of a node.
*/
-static unsigned
+unsigned
ir_node_hash (ir_node *node)
{
unsigned h;
int i, irn_arity;
- /* hash table value = 9*(9*(9*(9*(9*arity+in[0])+in[1])+ ...)+mode)+code */
- h = irn_arity = get_irn_arity(node);
+ if (node->op == op_Const) {
+ /* special value for const, as they only differ in their tarval. */
+ h = ((unsigned) node->attr.con.tv)>>3 ;
+ h = 9*h + (unsigned)get_irn_mode(node);
+ } else if (node->op == op_SymConst) {
+ /* special value for const, as they only differ in their symbol. */
+ h = ((unsigned) node->attr.i.sym.type_p)>>3 ;
+ h = 9*h + (unsigned)get_irn_mode(node);
+ } else {
- /* consider all in nodes... except the block. */
- for (i = 0; i < irn_arity; i++) {
- h = 9*h + (unsigned long)get_irn_n(node, i);
- }
+ /* hash table value = 9*(9*(9*(9*(9*arity+in[0])+in[1])+ ...)+mode)+code */
+ h = irn_arity = get_irn_arity(node);
- /* ...mode,... */
- h = 9*h + (unsigned long) get_irn_mode (node);
- /* ...and code */
- h = 9*h + (unsigned long) get_irn_op (node);
+ /* consider all in nodes... except the block. */
+ for (i = 0; i < irn_arity; i++) {
+ h = 9*h + (unsigned)get_irn_n(node, i);
+ }
+
+ /* ...mode,... */
+ h = 9*h + (unsigned) get_irn_mode (node);
+ /* ...and code */
+ h = 9*h + (unsigned) get_irn_op (node);
+ }
return h;
}
/**
* Return the canonical node computing the same value as n.
* Looks up the node in a hash table.
+ *
+ * For Const nodes this is performed in the constructor, too. Const
+ * nodes are extremely time critical because of their frequent use in
+ * constant string arrays.
*/
static INLINE ir_node *
identify (pset *value_table, ir_node *n)
if (!value_table) return n;
- /* TODO: use a generic commutative attribute */
if (get_opt_reassociation()) {
if (is_op_commutative(get_irn_op(n))) {
+ ir_node *l = get_binop_left(n);
+ ir_node *r = get_binop_right(n);
+
/* for commutative operators perform a OP b == b OP a */
- if (get_binop_left(n) > get_binop_right(n)) {
- ir_node *h = get_binop_left(n);
- set_binop_left(n, get_binop_right(n));
- set_binop_right(n, h);
+ if (l > r) {
+ set_binop_left(n, r);
+ set_binop_right(n, l);
}
}
}
o = pset_find (value_table, n, ir_node_hash (n));
if (!o) return n;
+ DBG_OPT_CSE(n, o);
+
return o;
}
/**
- * During construction we set the pinned flag in the graph right when the
- * optimizatin is performed. The flag turning on procedure global cse could
+ * During construction we set the op_pin_state_pinned flag in the graph right when the
+ * optimization is performed. The flag turning on procedure global cse could
* be changed between two allocations. This way we are safe.
*/
static INLINE ir_node *
identify_cons (pset *value_table, ir_node *n) {
ir_node *old = n;
+
n = identify(value_table, n);
if (get_irn_n(old, -1) != get_irn_n(n, -1))
- set_irg_pinned(current_ir_graph, floats);
+ set_irg_pinned(current_ir_graph, op_pin_state_floats);
return n;
}
* if it isn't there yet.
*/
static ir_node *
-identify_remember (pset *value_table, ir_node *node)
+identify_remember (pset *value_table, ir_node *n)
{
ir_node *o = NULL;
- if (!value_table) return node;
+ if (!value_table) return n;
+
+ if (get_opt_reassociation()) {
+ if (is_op_commutative(get_irn_op(n))) {
+ ir_node *l = get_binop_left(n);
+ ir_node *r = get_binop_right(n);
+
+ /* for commutative operators perform a OP b == b OP a */
+ if (l > r) {
+ set_binop_left(n, r);
+ set_binop_right(n, l);
+ }
+ }
+ }
/* lookup or insert in hash table with given hash key. */
- o = pset_insert (value_table, node, ir_node_hash (node));
+ o = pset_insert (value_table, n, ir_node_hash (n));
- if (o == node) return node;
+ if (o != n) {
+ DBG_OPT_CSE(n, o);
+ }
return o;
}
void
add_identities (pset *value_table, ir_node *node) {
- identify_remember (value_table, node);
+ if (get_opt_cse() && (get_irn_opcode(node) != iro_Block))
+ identify_remember (value_table, node);
}
/**
if (get_irn_op(block) == op_Block && get_Block_matured(block)) {
irn_arity = get_irn_arity(block);
for (i = 0; i < irn_arity; i++) {
- if (!is_Bad(get_irn_n(block, i))) break;
+ if (!is_Bad(get_irn_n(block, i))) break;
}
if (i == irn_arity) return new_Bad();
}
ir_node *oldn = n;
opcode iro = get_irn_opcode(n);
+ type *old_tp = get_irn_type(n);
+ {
+ int i, arity = get_irn_arity(n);
+ for (i = 0; i < arity && !old_tp; ++i)
+ old_tp = get_irn_type(get_irn_n(n, i));
+ }
+
/* Allways optimize Phi nodes: part of the construction. */
if ((!get_opt_optimize()) && (iro != iro_Phi)) return n;
/* constant expression evaluation / constant folding */
if (get_opt_constant_folding()) {
/* constants can not be evaluated */
- if (get_irn_op(n) != op_Const) {
+ if (iro != iro_Const) {
/* try to evaluate */
tv = computed_value (n);
if ((get_irn_mode(n) != mode_T) && (tv != tarval_bad)) {
- /*
- * we MUST copy the node here temparary, because it's still needed
- * for DBG_OPT_ALGSIM0
- */
- ir_node x = *n;
- oldn = &x;
- /* evaluation was succesful -- replace the node. */
- obstack_free (current_ir_graph->obst, n);
- n = new_Const (get_tarval_mode (tv), tv);
- DBG_OPT_ALGSIM0;
- return n;
+ /*
+ * we MUST copy the node here temporary, because it's still needed
+ * for DBG_OPT_ALGSIM0
+ */
+ int node_size = offsetof(ir_node, attr) + n->op->attr_size;
+ oldn = alloca(node_size);
+
+ memcpy(oldn, n, node_size);
+ CLONE_ARR_A(ir_node *, oldn->in, n->in);
+
+ /* ARG, copy the in array, we need it for statistics */
+ memcpy(oldn->in, n->in, ARR_LEN(n->in) * sizeof(n->in[0]));
+
+ /* evaluation was successful -- replace the node. */
+ obstack_free (current_ir_graph->obst, n);
+ n = new_Const (get_tarval_mode (tv), tv);
+ if (old_tp && get_type_mode(old_tp) == get_tarval_mode (tv))
+ set_Const_type(n, old_tp);
+ DBG_OPT_ALGSIM0(oldn, n);
+ return n;
}
}
}
/** common subexpression elimination **/
/* Checks whether n is already available. */
/* The block input is used to distinguish different subexpressions. Right
- now all nodes are pinned to blocks, i.e., the cse only finds common
+ 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_cons (current_ir_graph->value_table, n);
ir_node *oldn = n;
opcode iro = get_irn_opcode(n);
+ type *old_tp = get_irn_type(n);
+ {
+ int i, arity = get_irn_arity(n);
+ for (i = 0; i < arity && !old_tp; ++i)
+ old_tp = get_irn_type(get_irn_n(n, i));
+ }
+
if (!get_opt_optimize() && (get_irn_op(n) != op_Phi)) return n;
/* if not optimize return n */
return n;
}
-
/* constant expression evaluation / constant folding */
if (get_opt_constant_folding()) {
/* constants can not be evaluated */
/* try to evaluate */
tv = computed_value (n);
if ((get_irn_mode(n) != mode_T) && (tv != tarval_bad)) {
- /* evaluation was succesful -- replace the node. */
- n = new_Const (get_tarval_mode (tv), tv);
- DBG_OPT_ALGSIM0;
- return n;
+ /* evaluation was successful -- replace the node. */
+ n = new_Const (get_tarval_mode (tv), tv);
+ if (old_tp && get_type_mode(old_tp) == get_tarval_mode (tv))
+ set_Const_type(n, old_tp);
+ DBG_OPT_ALGSIM0(oldn, n);
+ return n;
}
}
}
/* remove unnecessary nodes */
- /*if (get_opt_constant_folding()) */
if (get_opt_constant_folding() ||
(iro == iro_Phi) || /* always optimize these nodes. */
(iro == iro_Id) || /* ... */
/** common subexpression elimination **/
/* Checks whether n is already available. */
/* The block input is used to distinguish different subexpressions. Right
- now all nodes are pinned to blocks, i.e., the cse only finds common
+ 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 (current_ir_graph->value_table, n);
assert(get_irg_phase_state(current_ir_graph) != phase_building);
if (get_opt_global_cse())
- set_irg_pinned(current_ir_graph, floats);
+ set_irg_pinned(current_ir_graph, op_pin_state_floats);
if (get_irg_outs_state(current_ir_graph) == outs_consistent)
set_irg_outs_inconsistent(current_ir_graph);
+
/* Maybe we could also test whether optimizing the node can
change the control graph. */
if (get_irg_dom_state(current_ir_graph) == dom_consistent)