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// Definition of private classes for RTL SSA -*- C++ -*-
// Copyright (C) 2020-2022 Free Software Foundation, Inc.
//
// 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
// <http://www.gnu.org/licenses/>.
namespace rtl_ssa {
// Information about a basic block's phi nodes. This class is only used when
// constructing the SSA form, it isn't meant to be kept up-to-date.
class function_info::bb_phi_info
{
public:
// The set of registers that need phi nodes.
bitmap_head regs;
// The number of registers in REGS.
unsigned int num_phis;
// The number of inputs to each phi node. Caching the information here
// is at best a minor optimisation, but it fills a 32-bit hole that would
// otherwise exist on 64-bit hosts.
unsigned int num_preds;
// An array of all the phi inputs for this block. It lists all inputs
// from the first incoming edge followed by all inputs for the next
// incoming edge, and so on. The inputs for a given edge are sorted
// by increasing register number.
set_info **inputs;
};
// Information used while constructing the SSA form and discarded
// afterwards.
class function_info::build_info
{
public:
build_info (unsigned int, unsigned int);
~build_info ();
set_info *current_reg_value (unsigned int) const;
set_info *current_mem_value () const;
void record_reg_def (def_info *);
void record_mem_def (def_info *);
// The block that we're currently processing.
bb_info *current_bb;
// The EBB that contains CURRENT_BB.
ebb_info *current_ebb;
// Except for the local exception noted below:
//
// - If register R has been defined in the current EBB, LAST_ACCESS[R + 1]
// is the last definition of R in the EBB.
//
// - Otherwise, if the current EBB is dominated by a definition of R,
// LAST_ACCESS[R + 1] is the nearest dominating definition.
//
// - Otherwise, LAST_ACCESS[R + 1] is null.
//
// Similarly:
//
// - If the current EBB has defined memory, LAST_ACCESS[0] is the last
// definition of memory in the EBB.
//
// - Otherwise LAST_ACCESS[0] is the value of memory that is live on
// - entry to the EBB.
//
// The exception is that while building instructions, LAST_ACCESS[I]
// can temporarily be the use of regno I - 1 by that instruction.
auto_vec<access_info *> last_access;
// A bitmap used to hold EBB_LIVE_IN_FOR_DEBUG.
auto_bitmap tmp_ebb_live_in_for_debug;
// If nonnull, a bitmap of registers that are live on entry to this EBB,
// with a tree view for quick lookup. This bitmap is calculated lazily
// and is only used if MAY_HAVE_DEBUG_INSNS.
bitmap ebb_live_in_for_debug;
// The set of registers that might need to have phis associated with them.
// Registers outside this set are known to have a single definition that
// dominates all uses.
//
// Before RA, about 5% of registers are typically in the set.
auto_sbitmap potential_phi_regs;
// A sparse bitmap representation of POTENTIAL_PHI_REGS. Only used if
// MAY_HAVE_DEBUG_INSNS.
auto_bitmap potential_phi_regs_for_debug;
// The set of registers that have been defined so far in the current EBB.
auto_bitmap ebb_def_regs;
// BB_PHIS[B] describes the phis for basic block B.
auto_vec<bb_phi_info> bb_phis;
// BB_MEM_LIVE_OUT[B] is the memory value that is live on exit from
// basic block B.
auto_vec<set_info *> bb_mem_live_out;
// BB_TO_RPO[B] gives the position of block B in a reverse postorder
// of the CFG. The RPO is a tweaked version of the one normally
// returned by pre_and_rev_post_order_compute, with all blocks in
// an EBB having consecutive positions.
auto_vec<int> bb_to_rpo;
// This stack is divided into sections, with one section for the
// current basic block and one section for each dominating block.
// Each element is a register definition.
//
// If the section for block B contains a definition D of a register R,
// then one of two things is true:
//
// - D occurs in B and no definition of R dominates B.
// - D dominates B and is the nearest dominating definition of R.
//
// The two cases are distinguished by the value of D->bb ().
auto_vec<def_info *> def_stack;
// The top of this stack records the start of the current block's
// section in DEF_STACK.
auto_vec<unsigned int> old_def_stack_limit;
};
}