# include "config.h"
#endif
+#undef DEBUG_CONFIRM
+
#include "tv_t.h"
#include "iropt_t.h"
#include "iropt_dbg.h"
#include "opt_confirms.h"
+#include "irflag_t.h"
+#include "irprintf.h"
enum range_tags {
MIN_INCLUDED = 0x00, /**< [min, ... */
unsigned char flags; /**< border flags */
} interval_t;
-/**
+#ifdef DEBUG_CONFIRM
+
+#define compare_iv(l_iv, r_iv, pnc) compare_iv_dbg(l_iv, r_iv, pnc)
+
+/* forward */
+static tarval *compare_iv_dbg(const interval_t *l_iv, const interval_t *r_iv, pn_Cmp pnc);
+
+/* triangle */
+#define DBG_OUT_TR(l_pnc, l_bound, r_pnc, r_bound, pnc, v) \
+ ir_printf("In %e:\na %= %n && b %= %n ==> a %= b == %s\n", \
+ get_irg_entity(current_ir_graph), \
+ l_pnc, l_bound, r_pnc, r_bound, pnc, v);
+
+/* right side */
+#define DBG_OUT_R(r_pnc, r_bound, left, pnc, right, v) \
+ ir_printf("In %e:\na %= %n ==> %n %= %n == %s\n", \
+ get_irg_entity(current_ir_graph), \
+ r_pnc, r_bound, left, pnc, right, v);
+
+/* left side */
+#define DBG_OUT_L(l_pnc, l_bound, left, pnc, right, v) \
+ ir_printf("In %e:\na %= %n ==> %n %= %n == %s\n", \
+ get_irg_entity(current_ir_graph), \
+ l_pnc, l_bound, left, pnc, right, v);
+
+#else
+
+#define DBG_OUT_TR(l_pnc, l_bound, r_pnc, r_bound, pnc, v)
+#define DBG_OUT_R(r_pnc, r_bound, left, pnc, right, v)
+#define DBG_OUT_L(l_pnc, l_bound, left, pnc, right, v)
+
+#endif /* DEBUG_CONFIRM */
+
+/*
* Check, if the value of a node is != 0.
*
* This is a often needed case, so we handle here Confirm
* nodes too.
*/
-int value_not_zero(ir_node *n)
+int value_not_zero(ir_node *n, ir_node **confirm)
{
-#define RET_ON(x) if (x) return 1; break
+#define RET_ON(x) if (x) { *confirm = n; return 1; }; break
tarval *tv;
ir_mode *mode = get_irn_mode(n);
pn_Cmp pnc;
+ *confirm = NULL;
while (get_irn_op(n) == op_Confirm) {
/*
* Note: A Confirm is never after a Const. So,
- * we simply can check the bound for beeing a Const
+ * we simply can check the bound for being a Const
* without the fear that is might be hidden by a further Confirm.
*/
tv = value_of(get_Confirm_bound(n));
if (tv == tarval_bad)
return 0;
- pnc = tarval_cmp(tv, get_mode_null(mode));
+ pnc = tarval_cmp(tv, get_mode_null(mode));
/*
* Beware: C might by a NaN. It is not clear, what we should do
return (pnc != pn_Cmp_Eq) && (pnc != pn_Cmp_Uo);
#undef RET_ON
-}
+} /* value_not_zero */
+
+/*
+ * Check, if the value of a node cannot represent a NULL pointer.
+ *
+ * - Casts are skipped
+ * - If sel_based_null_check_elim is enabled, all
+ * Sel nodes can be skipped.
+ * - A SymConst(entity) is NEVER a NULL pointer
+ * - Confirms are evaluated
+ */
+int value_not_null(ir_node *n, ir_node **confirm)
+{
+ ir_op *op;
+
+ *confirm = NULL;
+ n = skip_Cast(n);
+ op = get_irn_op(n);
+ assert(mode_is_reference(get_irn_mode(n)));
+ if (get_opt_sel_based_null_check_elim()) {
+ /* skip all Sel nodes and Cast's */
+ while (op == op_Sel) {
+ n = skip_Cast(get_Sel_ptr(n));
+ op = get_irn_op(n);
+ }
+ }
+ if (op == op_SymConst && get_SymConst_kind(n) == symconst_addr_ent)
+ return 1;
+ if (op == op_Const) {
+ tarval *tv = get_Const_tarval(n);
+
+ if (tv != tarval_bad && classify_tarval(tv) != TV_CLASSIFY_NULL)
+ return 1;
+ }
+ else if (op == op_Confirm) {
+ if (get_Confirm_cmp(n) == pn_Cmp_Lg &&
+ classify_Const(get_Confirm_bound(n)) == CNST_NULL) {
+ *confirm = n;
+ return 1;
+ }
+ }
+ return 0;
+} /* value_not_null */
/*
* Check, if the value of a node can be confirmed >= 0 or <= 0,
* If the mode of the value did not honor signed zeros, else
* check for >= 0 or < 0.
*/
-value_classify classify_value_sign(ir_node *n)
+value_classify_sign classify_value_sign(ir_node *n)
{
tarval *tv, *c;
ir_mode *mode;
pn_Cmp cmp, ncmp;
if (get_irn_op(n) != op_Confirm)
- return VALUE_UNKNOWN;
+ return value_classified_unknown;
tv = value_of(get_Confirm_bound(n));
if (tv == tarval_bad)
- return VALUE_UNKNOWN;
+ return value_classified_unknown;
mode = get_irn_mode(n);
ncmp = pn_Cmp_Le;
if (cmp != (ncmp ^ pn_Cmp_Eq))
- return VALUE_UNKNOWN;
+ return value_classified_unknown;
/* yep, negative */
- return VALUE_NEGATIVE;
+ return value_classified_negative;
case pn_Cmp_Ge:
/*
ncmp = pn_Cmp_Ge;
if (cmp != (ncmp ^ pn_Cmp_Eq))
- return VALUE_UNKNOWN;
+ return value_classified_unknown;
}
else {
c = get_mode_minus_one(mode);
ncmp = tarval_cmp(tv, c);
if (ncmp != pn_Cmp_Eq && ncmp != pn_Cmp_Gt)
- return VALUE_UNKNOWN;
+ return value_classified_unknown;
}
/* yep, positive */
- return VALUE_POSITIVE;
+ return value_classified_positive;
default:
- return VALUE_UNKNOWN;
+ return value_classified_unknown;
}
-}
+} /* classify_value_sign */
/**
* construct an interval from a value
iv->flags = MIN_INCLUDED | MAX_INCLUDED;
return iv;
-}
+} /* get_interval_from_tv */
/**
* construct an interval from a Confirm
*
* @param iv an empty interval, will be filled
* @param bound the bound value
- * @param pnc the Confirm pnc relation
+ * @param pnc the Confirm compare relation
*
* @return the filled interval or NULL if no interval
* can be created (happens only on floating point
tarval *tv = value_of(bound);
if (tv == tarval_bad) {
- if (mode_is_float(mode)) {
- /* NaN could be included which we cannot handle */
- iv->min = tarval_bad;
- iv->max = tarval_bad;
- iv->flags = MIN_EXCLUDED | MAX_EXCLUDED;
- return NULL;
- }
- else {
- /* [-oo, +oo] */
- iv->min = get_mode_min(mode);
- iv->max = get_mode_max(mode);
- iv->flags = MIN_INCLUDED | MAX_INCLUDED;
- return iv;
- }
+ /* There is nothing we could do here. For integer
+ * modes we could return [-oo, +oo], but there is
+ * nothing we could deduct from such an interval.
+ * So, speed things up and return unknown.
+ */
+ iv->min = tarval_bad;
+ iv->max = tarval_bad;
+ iv->flags = MIN_EXCLUDED | MAX_EXCLUDED;
+ return NULL;
}
if (mode_is_float(mode)) {
iv->min =
iv->max = tv;
iv->flags = MIN_INCLUDED | MAX_INCLUDED;
- return iv;
+ break;
case pn_Cmp_Le:
/* [-oo, tv] */
iv->min = get_mode_min(mode);
iv->max = tv;
iv->flags = MIN_INCLUDED | MAX_INCLUDED;
- return iv;
+ break;
case pn_Cmp_Lt:
/* [-oo, tv) */
iv->min = get_mode_min(mode);
iv->max = tv;
iv->flags = MIN_INCLUDED | MAX_EXCLUDED;
- return iv;
+ break;
case pn_Cmp_Gt:
/* (tv, +oo] */
iv->min = tv;
iv->max = get_mode_max(mode);
iv->flags = MIN_EXCLUDED | MAX_INCLUDED;
- return iv;
+ break;
case pn_Cmp_Ge:
/* [tv, +oo] */
iv->min = tv;
iv->max = get_mode_max(mode);
iv->flags = MIN_INCLUDED | MAX_INCLUDED;
- return iv;
+ break;
case pn_Cmp_Leg:
/*
iv->min = get_mode_min(mode);
iv->max = get_mode_max(mode);
iv->flags = MIN_INCLUDED | MAX_INCLUDED;
- return iv;
+ break;
default:
/*
iv->flags = MIN_EXCLUDED | MAX_EXCLUDED;
return NULL;
}
-}
+
+ if (iv->min != tarval_bad && iv->max != tarval_bad)
+ return iv;
+ return NULL;
+} /* get_interval */
/**
* Try to evaluate l_iv pnc r_iv.
* tarval_b_true or tarval_b_false it it can be evaluated,
* tarval_bad else
*/
-static tarval *compare_iv(const interval_t *l_iv, const interval_t *r_iv, pn_Cmp pnc)
+static tarval *(compare_iv)(const interval_t *l_iv, const interval_t *r_iv, pn_Cmp pnc)
{
pn_Cmp res;
unsigned flags;
if (pnc & pn_Cmp_Uo) {
tarval *t;
- pnc = get_negated_pnc(pnc);
+ pnc = get_negated_pnc(pnc, get_tarval_mode(l_iv->min));
t = tv_true;
tv_true = tv_false;
tv_false = t;
/* two intervals can be compared for equality only if they are a single value */
if (l_iv->min == l_iv->max && r_iv->min == r_iv->max)
return tarval_cmp(l_iv->min, r_iv->min) == pn_Cmp_Eq ? tv_true : tv_false;
+
+ /* if both intervals do not intersect, it is never equal */
+ res = tarval_cmp(l_iv->max, r_iv->min);
+
+ /* b < c ==> [a,b] != [c,d] */
+ if (res == pn_Cmp_Lt)
+ return tv_false;
+
+ /* b <= c ==> [a,b) != [c,d] AND [a,b] != (c,d] */
+ if ((l_iv->flags & MAX_EXCLUDED || r_iv->flags & MIN_EXCLUDED)
+ && (res == pn_Cmp_Eq))
+ return tv_false;
+
+ res = tarval_cmp(r_iv->max, l_iv->min);
+
+ /* d < a ==> [c,d] != [a,b] */
+ if (res == pn_Cmp_Lt)
+ return tv_false;
+
+ /* d <= a ==> [c,d) != [a,b] AND [c,d] != (a,b] */
+ if ((r_iv->flags & MAX_EXCLUDED || l_iv->flags & MIN_EXCLUDED)
+ && (res == pn_Cmp_Eq))
+ return tv_false;
break;
case pn_Cmp_Lg:
return tarval_bad;
}
return tarval_bad;
-}
+} /* compare_iv */
+
+/**
+ * Returns non-zero, if a given relation is transitive.
+ */
+static int is_transitive(pn_Cmp pnc) {
+ return (pn_Cmp_False < pnc && pnc < pn_Cmp_Lg);
+} /* is_transitive */
+
/**
* Return the value of a Cmp if one or both predecessors
* are Confirm nodes.
*
+ * @param cmp the Cmp node
* @param left the left operand of the Cmp
* @param right the right operand of the Cmp
+ * @param pnc the compare relation
*/
tarval *computed_value_Cmp_Confirm(ir_node *cmp, ir_node *left, ir_node *right, pn_Cmp pnc)
{
ir_node *l_bound;
- pn_Cmp l_pnc;
+ pn_Cmp l_pnc, res_pnc, neg_pnc;
interval_t l_iv, r_iv;
tarval *tv;
+ ir_mode *mode;
if (get_irn_op(right) == op_Confirm) {
ir_node *t;
pn_Cmp r_pnc = get_Confirm_cmp(right);
/*
- * check for == or != can sometime be made WITHOUT constant bounds
- * Beware of NaN's.
+ * some check can be made WITHOUT constant bounds
*/
- if (! mode_is_float(get_irn_mode(left)) &&
- (pnc == pn_Cmp_Eq || pnc == pn_Cmp_Lg)) {
- /* l == r if bound(l) == bound(r) AND pnc(l) == pnc(r) == '=' */
- if (r_bound == l_bound && r_pnc == l_pnc && r_pnc == pn_Cmp_Eq) {
- DBG_EVAL_CONFIRM(cmp);
- return pnc == pn_Cmp_Eq ? tarval_b_true : tarval_b_false;
+ if (r_bound == l_bound) {
+ if (is_transitive(l_pnc)) {
+ pn_Cmp r_inc_pnc = get_inversed_pnc(r_pnc);
+
+ /*
+ * triangle inequality:
+ *
+ * a CMP B && B CMP b => a CMP b, !(a ~CMP b)
+ *
+ * We handle correctly cases with some <=/>= here
+ */
+ if ((l_pnc & ~pn_Cmp_Eq) == (r_inc_pnc & ~pn_Cmp_Eq)) {
+ res_pnc = (l_pnc & ~pn_Cmp_Eq) | (l_pnc & r_inc_pnc & pn_Cmp_Eq);
+
+ if ((pnc == res_pnc) || ((pnc & ~pn_Cmp_Eq) == res_pnc)) {
+ DBG_OUT_TR(l_pnc, l_bound, r_pnc, r_bound, pnc, "true");
+ DBG_EVAL_CONFIRM(cmp);
+ return tarval_b_true;
+ }
+ else {
+ pn_Cmp neg_pnc = get_negated_pnc(pnc, get_irn_mode(left));
+
+ if ((neg_pnc == res_pnc) || ((neg_pnc & ~pn_Cmp_Eq) == res_pnc)) {
+ DBG_OUT_TR(l_pnc, l_bound, r_pnc, r_bound, pnc, "false");
+ DBG_EVAL_CONFIRM(cmp);
+ return tarval_b_false;
+ }
+ }
+ }
}
+ }
+
+ /*
+ * Here, we check only the right Confirm, as the left Confirms are
+ * checked later anyway.
+ */
+ if (left == r_bound) {
/*
- * Here, we check only the right Confirm, as the left Confirms are
- * checked later anyway.
+ * l == bound(r) AND pnc(r) == pnc:
+ *
+ * We know that a CMP b and check for that
*/
+ if ((r_pnc == pnc) || (r_pnc == (pnc & ~pn_Cmp_Eq))) {
+ DBG_OUT_R(r_pnc, r_bound, left, pnc, right, "true");
+ DBG_EVAL_CONFIRM(cmp);
+ return tarval_b_true;
+ }
+ /*
+ * l == bound(r) AND pnc(r) != pnc:
+ *
+ * We know that a CMP b and check for a ~CMP b
+ */
+ else {
+ mode = get_irn_mode(left);
+ neg_pnc = get_negated_pnc(pnc, mode);
- if (left == r_bound && (r_pnc == pn_Cmp_Eq || r_pnc == pn_Cmp_Lg)) {
- /* l == bound(r) AND pnc(r) == pnc */
- if (r_pnc == pnc) {
- DBG_EVAL_CONFIRM(cmp);
- return tarval_b_true;
- }
- /* l == bound(r) AND pnc(r) != pnc */
- else {
+ if ((r_pnc == neg_pnc) || (r_pnc == (neg_pnc & ~pn_Cmp_Eq))) {
+ DBG_OUT_R(r_pnc, r_bound, left, pnc, right, "false");
DBG_EVAL_CONFIRM(cmp);
return tarval_b_false;
}
/* from Here, check only left Confirm */
/*
- * checks for == or != can sometime be made WITHOUT constant bounds
- * Beware of NaN's.
+ * some checks can be made WITHOUT constant bounds
*/
- if (! mode_is_float(get_irn_mode(left)) &&
- (pnc == pn_Cmp_Eq || pnc == pn_Cmp_Lg)) {
- if (right == l_bound && (l_pnc == pn_Cmp_Eq || l_pnc == pn_Cmp_Lg)) {
- /* r == bound(l) AND pnc(l) == pnc */
- if (l_pnc == pnc) {
- DBG_EVAL_CONFIRM(cmp);
- return tarval_b_true;
- }
- /* r == bound(l) AND pnc(l) != pnc */
- else {
+ if (right == l_bound) {
+ /*
+ * r == bound(l) AND pnc(l) == pnc:
+ *
+ * We know that a CMP b and check for that
+ */
+ if ((l_pnc == pnc) || (l_pnc == (pnc & ~pn_Cmp_Eq))) {
+ DBG_OUT_L(l_pnc, l_bound, left, pnc, right, "true");
+ DBG_EVAL_CONFIRM(cmp);
+ return tarval_b_true;
+ }
+ /*
+ * r == bound(l) AND pnc(l) is Not(pnc):
+ *
+ * We know that a CMP b and check for a ~CMP b
+ */
+ else {
+ mode = get_irn_mode(left);
+ neg_pnc = get_negated_pnc(pnc, mode);
+
+ if ((l_pnc == neg_pnc) || (l_pnc == (neg_pnc & ~pn_Cmp_Eq))) {
+ DBG_OUT_L(l_pnc, l_bound, left, pnc, right, "false");
DBG_EVAL_CONFIRM(cmp);
return tarval_b_false;
}
DBG_EVAL_CONFIRM(cmp);
return tv;
-}
+} /* computed_value_Cmp_Confirm */
+
+#ifdef DEBUG_CONFIRM
+/**
+ * For debugging. Prints an interval into a string.
+ *
+ * @param buf address of a string buffer
+ * @param len length of the string buffer
+ * @param iv the interval
+ */
+static int iv_snprintf(char *buf, size_t len, const interval_t *iv) {
+ char smin[64], smax[64];
+
+ if (iv) {
+ tarval_snprintf(smin, sizeof(smin), iv->min);
+
+ if (iv->min != iv->max || (iv->flags & (MIN_EXCLUDED|MAX_EXCLUDED))) {
+ tarval_snprintf(smax, sizeof(smax), iv->max);
+
+ return snprintf(buf, len, "%c%s, %s%c",
+ iv->flags & MIN_EXCLUDED ? '(' : '[',
+ smin, smax,
+ iv->flags & MAX_EXCLUDED ? ')' : ']'
+ );
+ }
+ else
+ return snprintf(buf, len, "%s", smin);
+ }
+ return snprintf(buf, len, "<UNKNOWN>");
+} /* iv_snprintf */
+
+/**
+ * For debugging. Prints an interval compare.
+ *
+ * @param l_iv the left interval
+ * @param r_iv the right interval
+ * @param pnc the compare relation
+ */
+static void print_iv_cmp(const interval_t *l_iv, const interval_t *r_iv, pn_Cmp pnc)
+{
+ char sl[128], sr[128];
+
+ iv_snprintf(sl, sizeof(sl), l_iv);
+ iv_snprintf(sr, sizeof(sr), r_iv);
+
+ ir_printf("%s %= %s", sl, pnc, sr);
+} /* print_iv_cmp */
+
+/**
+ * For debugging. call *compare_iv() and prints inputs and result.
+ *
+ * @param l_iv the left interval
+ * @param r_iv the right interval
+ * @param pnc the compare relation
+ */
+static tarval *compare_iv_dbg(const interval_t *l_iv, const interval_t *r_iv, pn_Cmp pnc)
+{
+ tarval *tv = (compare_iv)(l_iv, r_iv, pnc);
+
+ if (tv == tarval_bad)
+ return tv;
+
+ ir_printf("In %e:\n", get_irg_entity(current_ir_graph));
+ print_iv_cmp(l_iv, r_iv, pnc);
+ ir_printf(" = %T\n", tv);
+ return tv;
+} /* compare_iv_dbg */
+
+#endif /* DEBUG_CONFIRM */