/* Support routines for vrange storage. 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 "tree.h" #include "gimple.h" #include "ssa.h" #include "tree-pretty-print.h" #include "fold-const.h" #include "gimple-range.h" #include "value-range-storage.h" // Return a newly allocated slot holding R, or NULL if storing a range // of R's type is not supported. void * vrange_storage::alloc_slot (const vrange &r) { gcc_checking_assert (m_alloc); if (is_a (r)) return irange_storage_slot::alloc_slot (*m_alloc, as_a (r)); if (is_a (r)) return frange_storage_slot::alloc_slot (*m_alloc, as_a (r)); return NULL; } // Set SLOT to R. void vrange_storage::set_vrange (void *slot, const vrange &r) { if (is_a (r)) { irange_storage_slot *s = static_cast (slot); gcc_checking_assert (s->fits_p (as_a (r))); s->set_irange (as_a (r)); } else if (is_a (r)) { frange_storage_slot *s = static_cast (slot); gcc_checking_assert (s->fits_p (as_a (r))); s->set_frange (as_a (r)); } else gcc_unreachable (); } // Restore R from SLOT. TYPE is the type of R. void vrange_storage::get_vrange (const void *slot, vrange &r, tree type) { if (is_a (r)) { const irange_storage_slot *s = static_cast (slot); s->get_irange (as_a (r), type); } else if (is_a (r)) { const frange_storage_slot *s = static_cast (slot); s->get_frange (as_a (r), type); } else gcc_unreachable (); } // Return TRUE if SLOT can fit R. bool vrange_storage::fits_p (const void *slot, const vrange &r) { if (is_a (r)) { const irange_storage_slot *s = static_cast (slot); return s->fits_p (as_a (r)); } if (is_a (r)) { const frange_storage_slot *s = static_cast (slot); return s->fits_p (as_a (r)); } gcc_unreachable (); return false; } // Factory that creates a new irange_storage_slot object containing R. // This is the only way to construct an irange slot as stack creation // is disallowed. irange_storage_slot * irange_storage_slot::alloc_slot (vrange_allocator &allocator, const irange &r) { size_t size = irange_storage_slot::size (r); irange_storage_slot *p = static_cast (allocator.alloc (size)); new (p) irange_storage_slot (r); return p; } // Initialize the current slot with R. irange_storage_slot::irange_storage_slot (const irange &r) { gcc_checking_assert (!r.undefined_p ()); unsigned prec = TYPE_PRECISION (r.type ()); unsigned n = num_wide_ints_needed (r); if (n > MAX_INTS) { int_range squash (r); m_ints.set_precision (prec, num_wide_ints_needed (squash)); set_irange (squash); } else { m_ints.set_precision (prec, n); set_irange (r); } } // Store R into the current slot. void irange_storage_slot::set_irange (const irange &r) { gcc_checking_assert (fits_p (r)); // Avoid calling unsupported get_nonzero_bits on legacy. if (r.legacy_mode_p ()) m_ints[0] = -1; else m_ints[0] = r.get_nonzero_bits (); unsigned pairs = r.num_pairs (); for (unsigned i = 0; i < pairs; ++i) { m_ints[i*2 + 1] = r.lower_bound (i); m_ints[i*2 + 2] = r.upper_bound (i); } } // Restore a range of TYPE from the current slot into R. void irange_storage_slot::get_irange (irange &r, tree type) const { gcc_checking_assert (TYPE_PRECISION (type) == m_ints.get_precision ()); r.set_undefined (); unsigned nelements = m_ints.num_elements (); for (unsigned i = 1; i < nelements; i += 2) { int_range<2> tmp (type, m_ints[i], m_ints[i + 1]); r.union_ (tmp); } r.set_nonzero_bits (get_nonzero_bits ()); } // Return the size in bytes to allocate a slot that can hold R. size_t irange_storage_slot::size (const irange &r) { gcc_checking_assert (!r.undefined_p ()); unsigned prec = TYPE_PRECISION (r.type ()); unsigned n = num_wide_ints_needed (r); if (n > MAX_INTS) n = MAX_INTS; return (sizeof (irange_storage_slot) + trailing_wide_ints::extra_size (prec, n)); } // Return the number of wide ints needed to represent R. unsigned int irange_storage_slot::num_wide_ints_needed (const irange &r) { return r.num_pairs () * 2 + 1; } // Return TRUE if R fits in the current slot. bool irange_storage_slot::fits_p (const irange &r) const { return m_ints.num_elements () >= num_wide_ints_needed (r); } // Dump the current slot. void irange_storage_slot::dump () const { fprintf (stderr, "raw irange_storage_slot:\n"); for (unsigned i = 1; i < m_ints.num_elements (); i += 2) { m_ints[i].dump (); m_ints[i + 1].dump (); } fprintf (stderr, "NONZERO "); wide_int nz = get_nonzero_bits (); nz.dump (); } DEBUG_FUNCTION void debug (const irange_storage_slot &storage) { storage.dump (); fprintf (stderr, "\n"); } // Implementation of frange_storage_slot. frange_storage_slot * frange_storage_slot::alloc_slot (vrange_allocator &allocator, const frange &r) { size_t size = sizeof (frange_storage_slot); frange_storage_slot *p = static_cast (allocator.alloc (size)); new (p) frange_storage_slot (r); return p; } void frange_storage_slot::set_frange (const frange &r) { gcc_checking_assert (fits_p (r)); gcc_checking_assert (!r.undefined_p ()); m_props = r.m_props; } void frange_storage_slot::get_frange (frange &r, tree type) const { gcc_checking_assert (r.supports_type_p (type)); r.set_varying (type); r.m_props = m_props; r.normalize_kind (); if (flag_checking) r.verify_range (); } bool frange_storage_slot::fits_p (const frange &) const { return true; }