/* Floating point range operators. Copyright (C) 2022 Free Software Foundation, Inc. Contributed by Aldy Hernandez . This file is part of GCC. GCC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GCC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GCC; see the file COPYING3. If not see . */ #include "config.h" #include "system.h" #include "coretypes.h" #include "backend.h" #include "insn-codes.h" #include "rtl.h" #include "tree.h" #include "gimple.h" #include "cfghooks.h" #include "tree-pass.h" #include "ssa.h" #include "optabs-tree.h" #include "gimple-pretty-print.h" #include "diagnostic-core.h" #include "flags.h" #include "fold-const.h" #include "stor-layout.h" #include "calls.h" #include "cfganal.h" #include "gimple-iterator.h" #include "gimple-fold.h" #include "tree-eh.h" #include "gimple-walk.h" #include "tree-cfg.h" #include "wide-int.h" #include "value-relation.h" #include "range-op.h" // Default definitions for floating point operators. bool range_operator_float::fold_range (frange &r ATTRIBUTE_UNUSED, tree type ATTRIBUTE_UNUSED, const frange &lh ATTRIBUTE_UNUSED, const frange &rh ATTRIBUTE_UNUSED, relation_kind rel ATTRIBUTE_UNUSED) const { return false; } bool range_operator_float::fold_range (irange &r ATTRIBUTE_UNUSED, tree type ATTRIBUTE_UNUSED, const frange &lh ATTRIBUTE_UNUSED, const irange &rh ATTRIBUTE_UNUSED, relation_kind rel ATTRIBUTE_UNUSED) const { return false; } bool range_operator_float::fold_range (irange &r ATTRIBUTE_UNUSED, tree type ATTRIBUTE_UNUSED, const frange &lh ATTRIBUTE_UNUSED, const frange &rh ATTRIBUTE_UNUSED, relation_kind rel ATTRIBUTE_UNUSED) const { return false; } bool range_operator_float::op1_range (frange &r ATTRIBUTE_UNUSED, tree type ATTRIBUTE_UNUSED, const frange &lhs ATTRIBUTE_UNUSED, const frange &op2 ATTRIBUTE_UNUSED, relation_kind rel ATTRIBUTE_UNUSED) const { return false; } bool range_operator_float::op1_range (frange &r ATTRIBUTE_UNUSED, tree type ATTRIBUTE_UNUSED, const irange &lhs ATTRIBUTE_UNUSED, const frange &op2 ATTRIBUTE_UNUSED, relation_kind rel ATTRIBUTE_UNUSED) const { return false; } bool range_operator_float::op2_range (frange &r ATTRIBUTE_UNUSED, tree type ATTRIBUTE_UNUSED, const frange &lhs ATTRIBUTE_UNUSED, const frange &op1 ATTRIBUTE_UNUSED, relation_kind rel ATTRIBUTE_UNUSED) const { return false; } bool range_operator_float::op2_range (frange &r ATTRIBUTE_UNUSED, tree type ATTRIBUTE_UNUSED, const irange &lhs ATTRIBUTE_UNUSED, const frange &op1 ATTRIBUTE_UNUSED, relation_kind rel ATTRIBUTE_UNUSED) const { return false; } relation_kind range_operator_float::lhs_op1_relation (const frange &lhs ATTRIBUTE_UNUSED, const frange &op1 ATTRIBUTE_UNUSED, const frange &op2 ATTRIBUTE_UNUSED, relation_kind) const { return VREL_VARYING; } relation_kind range_operator_float::lhs_op1_relation (const irange &lhs ATTRIBUTE_UNUSED, const frange &op1 ATTRIBUTE_UNUSED, const frange &op2 ATTRIBUTE_UNUSED, relation_kind) const { return VREL_VARYING; } relation_kind range_operator_float::lhs_op2_relation (const irange &lhs ATTRIBUTE_UNUSED, const frange &op1 ATTRIBUTE_UNUSED, const frange &op2 ATTRIBUTE_UNUSED, relation_kind) const { return VREL_VARYING; } relation_kind range_operator_float::lhs_op2_relation (const frange &lhs ATTRIBUTE_UNUSED, const frange &op1 ATTRIBUTE_UNUSED, const frange &op2 ATTRIBUTE_UNUSED, relation_kind) const { return VREL_VARYING; } relation_kind range_operator_float::op1_op2_relation (const irange &lhs ATTRIBUTE_UNUSED) const { return VREL_VARYING; } // Return TRUE if OP1 is known to be free of NANs. static inline bool finite_operand_p (const frange &op1) { return flag_finite_math_only || !op1.maybe_isnan (); } // Return TRUE if OP1 and OP2 are known to be free of NANs. static inline bool finite_operands_p (const frange &op1, const frange &op2) { return flag_finite_math_only || (!op1.maybe_isnan () && !op2.maybe_isnan ()); } // Floating version of relop_early_resolve that takes into account NAN // and -ffinite-math-only. inline bool frelop_early_resolve (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel, relation_kind my_rel) { // If either operand is undefined, return VARYING. if (empty_range_varying (r, type, op1, op2)) return true; // We can fold relations from the oracle when we know both operands // are free of NANs, or when -ffinite-math-only. return (finite_operands_p (op1, op2) && relop_early_resolve (r, type, op1, op2, rel, my_rel)); } // Crop R to [-INF, MAX] where MAX is the maximum representable number // for TYPE. static inline void frange_drop_inf (frange &r, tree type) { REAL_VALUE_TYPE max = real_max_representable (type); frange tmp (type, r.lower_bound (), max); r.intersect (tmp); } // Crop R to [MIN, +INF] where MIN is the minimum representable number // for TYPE. static inline void frange_drop_ninf (frange &r, tree type) { REAL_VALUE_TYPE min = real_min_representable (type); frange tmp (type, min, r.upper_bound ()); r.intersect (tmp); } // If zero is in R, make sure both -0.0 and +0.0 are in the range. static inline void frange_add_zeros (frange &r, tree type) { if (r.undefined_p () || r.known_isnan ()) return; if (HONOR_SIGNED_ZEROS (type) && (real_iszero (&r.lower_bound ()) || real_iszero (&r.upper_bound ()))) { frange zero; zero.set_zero (type); r.union_ (zero); } } // Build a range that is <= VAL and store it in R. static bool build_le (frange &r, tree type, const frange &val) { gcc_checking_assert (!val.known_isnan ()); REAL_VALUE_TYPE ninf = frange_val_min (type); r.set (type, ninf, val.upper_bound ()); // Add both zeros if there's the possibility of zero equality. frange_add_zeros (r, type); return true; } // Build a range that is < VAL and store it in R. static bool build_lt (frange &r, tree type, const frange &val) { gcc_checking_assert (!val.known_isnan ()); // < -INF is outside the range. if (real_isinf (&val.upper_bound (), 1)) { if (HONOR_NANS (type)) r.set_nan (type); else r.set_undefined (); return false; } // We only support closed intervals. REAL_VALUE_TYPE ninf = frange_val_min (type); r.set (type, ninf, val.upper_bound ()); return true; } // Build a range that is >= VAL and store it in R. static bool build_ge (frange &r, tree type, const frange &val) { gcc_checking_assert (!val.known_isnan ()); REAL_VALUE_TYPE inf = frange_val_max (type); r.set (type, val.lower_bound (), inf); // Add both zeros if there's the possibility of zero equality. frange_add_zeros (r, type); return true; } // Build a range that is > VAL and store it in R. static bool build_gt (frange &r, tree type, const frange &val) { gcc_checking_assert (!val.known_isnan ()); // > +INF is outside the range. if (real_isinf (&val.lower_bound (), 0)) { if (HONOR_NANS (type)) r.set_nan (type); else r.set_undefined (); return false; } // We only support closed intervals. REAL_VALUE_TYPE inf = frange_val_max (type); r.set (type, val.lower_bound (), inf); return true; } class foperator_identity : public range_operator_float { using range_operator_float::fold_range; using range_operator_float::op1_range; bool fold_range (frange &r, tree type ATTRIBUTE_UNUSED, const frange &op1, const frange &op2 ATTRIBUTE_UNUSED, relation_kind) const final override { r = op1; return true; } bool op1_range (frange &r, tree type ATTRIBUTE_UNUSED, const frange &lhs, const frange &op2 ATTRIBUTE_UNUSED, relation_kind) const final override { r = lhs; return true; } public: } fop_identity; class foperator_equal : public range_operator_float { using range_operator_float::fold_range; using range_operator_float::op1_range; using range_operator_float::op2_range; bool fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const final override; relation_kind op1_op2_relation (const irange &lhs) const final override { return equal_op1_op2_relation (lhs); } bool op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const final override; bool op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind rel) const final override { return op1_range (r, type, lhs, op1, rel); } } fop_equal; bool foperator_equal::fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const { if (frelop_early_resolve (r, type, op1, op2, rel, VREL_EQ)) return true; if (op1.known_isnan () || op2.known_isnan ()) r = range_false (type); // We can be sure the values are always equal or not if both ranges // consist of a single value, and then compare them. else if (op1.singleton_p () && op2.singleton_p ()) { if (op1 == op2) r = range_true (type); else r = range_false (type); } else if (finite_operands_p (op1, op2)) { // If ranges do not intersect, we know the range is not equal, // otherwise we don't know anything for sure. frange tmp = op1; tmp.intersect (op2); if (tmp.undefined_p ()) r = range_false (type); else r = range_true_and_false (type); } else r = range_true_and_false (type); return true; } bool foperator_equal::op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of x == NAN is unreachable. if (op2.known_isnan ()) r.set_undefined (); else { // If it's true, the result is the same as OP2. r = op2; // Add both zeros if there's the possibility of zero equality. frange_add_zeros (r, type); // The TRUE side of op1 == op2 implies op1 is !NAN. r.clear_nan (); } break; case BRS_FALSE: // The FALSE side of op1 == op1 implies op1 is a NAN. if (rel == VREL_EQ) r.set_nan (type); // On the FALSE side of x == NAN, we know nothing about x. else if (op2.known_isnan ()) r.set_varying (type); // If the result is false, the only time we know anything is // if OP2 is a constant. else if (op2.singleton_p () || (finite_operand_p (op2) && op2.zero_p ())) { REAL_VALUE_TYPE tmp = op2.lower_bound (); r.set (type, tmp, tmp, VR_ANTI_RANGE); } else r.set_varying (type); break; default: break; } return true; } class foperator_not_equal : public range_operator_float { using range_operator_float::fold_range; using range_operator_float::op1_range; bool fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const final override; relation_kind op1_op2_relation (const irange &lhs) const final override { return not_equal_op1_op2_relation (lhs); } bool op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const final override; } fop_not_equal; bool foperator_not_equal::fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const { if (frelop_early_resolve (r, type, op1, op2, rel, VREL_NE)) return true; // x != NAN is always TRUE. if (op1.known_isnan () || op2.known_isnan ()) r = range_true (type); // We can be sure the values are always equal or not if both ranges // consist of a single value, and then compare them. else if (op1.singleton_p () && op2.singleton_p ()) { if (op1 != op2) r = range_true (type); else r = range_false (type); } else if (finite_operands_p (op1, op2)) { // If ranges do not intersect, we know the range is not equal, // otherwise we don't know anything for sure. frange tmp = op1; tmp.intersect (op2); if (tmp.undefined_p ()) r = range_true (type); else r = range_true_and_false (type); } else r = range_true_and_false (type); return true; } bool foperator_not_equal::op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // If the result is true, the only time we know anything is if // OP2 is a constant. if (op2.singleton_p ()) { // This is correct even if op1 is NAN, because the following // range would be ~[tmp, tmp] with the NAN property set to // maybe (VARYING). REAL_VALUE_TYPE tmp = op2.lower_bound (); r.set (type, tmp, tmp, VR_ANTI_RANGE); } else r.set_varying (type); break; case BRS_FALSE: // The FALSE side of x != NAN is impossible. if (op2.known_isnan ()) r.set_undefined (); else { // If it's false, the result is the same as OP2. r = op2; // Add both zeros if there's the possibility of zero equality. frange_add_zeros (r, type); // The FALSE side of op1 != op2 implies op1 is !NAN. r.clear_nan (); } break; default: break; } return true; } class foperator_lt : public range_operator_float { using range_operator_float::fold_range; using range_operator_float::op1_range; using range_operator_float::op2_range; bool fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const final override; relation_kind op1_op2_relation (const irange &lhs) const final override { return lt_op1_op2_relation (lhs); } bool op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const final override; bool op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind rel) const final override; } fop_lt; bool foperator_lt::fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const { if (frelop_early_resolve (r, type, op1, op2, rel, VREL_LT)) return true; if (op1.known_isnan () || op2.known_isnan ()) r = range_false (type); else if (finite_operands_p (op1, op2)) { if (real_less (&op1.upper_bound (), &op2.lower_bound ())) r = range_true (type); else if (finite_operands_p (op1, op2) && !real_less (&op1.lower_bound (), &op2.upper_bound ())) r = range_false (type); else r = range_true_and_false (type); } else r = range_true_and_false (type); return true; } bool foperator_lt::op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of x < NAN is unreachable. if (op2.known_isnan ()) r.set_undefined (); else if (build_lt (r, type, op2)) { r.clear_nan (); // x < y implies x is not +INF. frange_drop_inf (r, type); } break; case BRS_FALSE: // On the FALSE side of x < NAN, we know nothing about x. if (op2.known_isnan ()) r.set_varying (type); else build_ge (r, type, op2); break; default: break; } return true; } bool foperator_lt::op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of NAN < x is unreachable. if (op1.known_isnan ()) r.set_undefined (); else if (build_gt (r, type, op1)) { r.clear_nan (); // x < y implies y is not -INF. frange_drop_ninf (r, type); } break; case BRS_FALSE: // On the FALSE side of NAN < x, we know nothing about x. if (op1.known_isnan ()) r.set_varying (type); else build_le (r, type, op1); break; default: break; } return true; } class foperator_le : public range_operator_float { using range_operator_float::fold_range; using range_operator_float::op1_range; using range_operator_float::op2_range; bool fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const final override; relation_kind op1_op2_relation (const irange &lhs) const final override { return le_op1_op2_relation (lhs); } bool op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const final override; bool op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind rel) const final override; } fop_le; bool foperator_le::fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const { if (frelop_early_resolve (r, type, op1, op2, rel, VREL_LE)) return true; if (op1.known_isnan () || op2.known_isnan ()) r = range_false (type); else if (finite_operands_p (op1, op2)) { if (real_compare (LE_EXPR, &op1.upper_bound (), &op2.lower_bound ())) r = range_true (type); else if (finite_operands_p (op1, op2) && !real_compare (LE_EXPR, &op1.lower_bound (), &op2.upper_bound ())) r = range_false (type); else r = range_true_and_false (type); } else r = range_true_and_false (type); return true; } bool foperator_le::op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of x <= NAN is unreachable. if (op2.known_isnan ()) r.set_undefined (); else if (build_le (r, type, op2)) r.clear_nan (); break; case BRS_FALSE: // On the FALSE side of x <= NAN, we know nothing about x. if (op2.known_isnan ()) r.set_varying (type); else build_gt (r, type, op2); break; default: break; } return true; } bool foperator_le::op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of NAN <= x is unreachable. if (op1.known_isnan ()) r.set_undefined (); else if (build_ge (r, type, op1)) r.clear_nan (); break; case BRS_FALSE: // On the FALSE side of NAN <= x, we know nothing about x. if (op1.known_isnan ()) r.set_varying (type); else build_lt (r, type, op1); break; default: break; } return true; } class foperator_gt : public range_operator_float { using range_operator_float::fold_range; using range_operator_float::op1_range; using range_operator_float::op2_range; bool fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const final override; relation_kind op1_op2_relation (const irange &lhs) const final override { return gt_op1_op2_relation (lhs); } bool op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const final override; bool op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind rel) const final override; } fop_gt; bool foperator_gt::fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const { if (frelop_early_resolve (r, type, op1, op2, rel, VREL_GT)) return true; if (op1.known_isnan () || op2.known_isnan ()) r = range_false (type); else if (finite_operands_p (op1, op2)) { if (real_compare (GT_EXPR, &op1.lower_bound (), &op2.upper_bound ())) r = range_true (type); else if (finite_operands_p (op1, op2) && !real_compare (GT_EXPR, &op1.upper_bound (), &op2.lower_bound ())) r = range_false (type); else r = range_true_and_false (type); } else r = range_true_and_false (type); return true; } bool foperator_gt::op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of x > NAN is unreachable. if (op2.known_isnan ()) r.set_undefined (); else if (build_gt (r, type, op2)) { r.clear_nan (); // x > y implies x is not -INF. frange_drop_ninf (r, type); } break; case BRS_FALSE: // On the FALSE side of x > NAN, we know nothing about x. if (op2.known_isnan ()) r.set_varying (type); else build_le (r, type, op2); break; default: break; } return true; } bool foperator_gt::op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of NAN > x is unreachable. if (op1.known_isnan ()) r.set_undefined (); else if (build_lt (r, type, op1)) { r.clear_nan (); // x > y implies y is not +INF. frange_drop_inf (r, type); } break; case BRS_FALSE: // On The FALSE side of NAN > x, we know nothing about x. if (op1.known_isnan ()) r.set_varying (type); else build_ge (r, type, op1); break; default: break; } return true; } class foperator_ge : public range_operator_float { using range_operator_float::fold_range; using range_operator_float::op1_range; using range_operator_float::op2_range; bool fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const final override; relation_kind op1_op2_relation (const irange &lhs) const final override { return ge_op1_op2_relation (lhs); } bool op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const final override; bool op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind rel) const final override; } fop_ge; bool foperator_ge::fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const { if (frelop_early_resolve (r, type, op1, op2, rel, VREL_GE)) return true; if (op1.known_isnan () || op2.known_isnan ()) r = range_false (type); else if (finite_operands_p (op1, op2)) { if (real_compare (GE_EXPR, &op1.lower_bound (), &op2.upper_bound ())) r = range_true (type); else if (finite_operands_p (op1, op2) && !real_compare (GE_EXPR, &op1.upper_bound (), &op2.lower_bound ())) r = range_false (type); else r = range_true_and_false (type); } else r = range_true_and_false (type); return true; } bool foperator_ge::op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of x >= NAN is unreachable. if (op2.known_isnan ()) r.set_undefined (); else if (build_ge (r, type, op2)) r.clear_nan (); break; case BRS_FALSE: // On the FALSE side of x >= NAN, we know nothing about x. if (op2.known_isnan ()) r.set_varying (type); else build_lt (r, type, op2); break; default: break; } return true; } bool foperator_ge::op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of NAN >= x is unreachable. if (op1.known_isnan ()) r.set_undefined (); else { build_le (r, type, op1); r.clear_nan (); } break; case BRS_FALSE: // On the FALSE side of NAN >= x, we know nothing about x. if (op1.known_isnan ()) r.set_varying (type); else build_gt (r, type, op1); break; default: break; } return true; } // UNORDERED_EXPR comparison. class foperator_unordered : public range_operator_float { using range_operator_float::fold_range; using range_operator_float::op1_range; using range_operator_float::op2_range; public: bool fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const final override; bool op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const final override; bool op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind rel) const final override { return op1_range (r, type, lhs, op1, rel); } } fop_unordered; bool foperator_unordered::fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind) const { // UNORDERED is TRUE if either operand is a NAN. if (op1.known_isnan () || op2.known_isnan ()) r = range_true (type); // UNORDERED is FALSE if neither operand is a NAN. else if (!op1.maybe_isnan () && !op2.maybe_isnan ()) r = range_false (type); else r = range_true_and_false (type); return true; } bool foperator_unordered::op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // Since at least one operand must be NAN, if one of them is // not, the other must be. if (!op2.maybe_isnan ()) r.set_nan (type); else r.set_varying (type); break; case BRS_FALSE: // A false UNORDERED means both operands are !NAN, so it's // impossible for op2 to be a NAN. if (op2.known_isnan ()) r.set_undefined (); else { r.set_varying (type); r.clear_nan (); } break; default: break; } return true; } // ORDERED_EXPR comparison. class foperator_ordered : public range_operator_float { using range_operator_float::fold_range; using range_operator_float::op1_range; using range_operator_float::op2_range; public: bool fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind rel) const final override; bool op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const final override; bool op2_range (frange &r, tree type, const irange &lhs, const frange &op1, relation_kind rel) const final override { return op1_range (r, type, lhs, op1, rel); } } fop_ordered; bool foperator_ordered::fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind) const { if (op1.known_isnan () || op2.known_isnan ()) r = range_false (type); else if (!op1.maybe_isnan () && !op2.maybe_isnan ()) r = range_true (type); else r = range_true_and_false (type); return true; } bool foperator_ordered::op1_range (frange &r, tree type, const irange &lhs, const frange &op2, relation_kind rel) const { switch (get_bool_state (r, lhs, type)) { case BRS_TRUE: // The TRUE side of ORDERED means both operands are !NAN, so // it's impossible for op2 to be a NAN. if (op2.known_isnan ()) r.set_undefined (); else { r.set_varying (type); r.clear_nan (); } break; case BRS_FALSE: r.set_varying (type); // The FALSE side of op1 ORDERED op1 implies op1 is !NAN. if (rel == VREL_EQ) r.clear_nan (); break; default: break; } return true; } // Placeholder for unimplemented relational operators. class foperator_relop_unknown : public range_operator_float { using range_operator_float::fold_range; public: bool fold_range (irange &r, tree type, const frange &op1, const frange &op2, relation_kind) const final override { if (op1.known_isnan () || op2.known_isnan ()) r = range_true (type); else r.set_varying (type); return true; } } fop_unordered_relop_unknown; // Instantiate a range_op_table for floating point operations. static floating_op_table global_floating_table; // Pointer to the float table so the dispatch code can access it. floating_op_table *floating_tree_table = &global_floating_table; floating_op_table::floating_op_table () { set (SSA_NAME, fop_identity); set (PAREN_EXPR, fop_identity); set (OBJ_TYPE_REF, fop_identity); set (REAL_CST, fop_identity); // All the relational operators are expected to work, because the // calculation of ranges on outgoing edges expect the handlers to be // present. set (EQ_EXPR, fop_equal); set (NE_EXPR, fop_not_equal); set (LT_EXPR, fop_lt); set (LE_EXPR, fop_le); set (GT_EXPR, fop_gt); set (GE_EXPR, fop_ge); set (UNLE_EXPR, fop_unordered_relop_unknown); set (UNLT_EXPR, fop_unordered_relop_unknown); set (UNGE_EXPR, fop_unordered_relop_unknown); set (UNGT_EXPR, fop_unordered_relop_unknown); set (UNEQ_EXPR, fop_unordered_relop_unknown); set (ORDERED_EXPR, fop_ordered); set (UNORDERED_EXPR, fop_unordered); } // Return a pointer to the range_operator_float instance, if there is // one associated with tree_code CODE. range_operator_float * floating_op_table::operator[] (enum tree_code code) { return m_range_tree[code]; } // Add OP to the handler table for CODE. void floating_op_table::set (enum tree_code code, range_operator_float &op) { gcc_checking_assert (m_range_tree[code] == NULL); m_range_tree[code] = &op; }