/* Rtl-level induction variable analysis.
Copyright (C) 2004-2020 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
. */
/* This is a simple analysis of induction variables of the loop. The major use
is for determining the number of iterations of a loop for loop unrolling,
doloop optimization and branch prediction. The iv information is computed
on demand.
Induction variables are analyzed by walking the use-def chains. When
a basic induction variable (biv) is found, it is cached in the bivs
hash table. When register is proved to be a biv, its description
is stored to DF_REF_DATA of the def reference.
The analysis works always with one loop -- you must call
iv_analysis_loop_init (loop) for it. All the other functions then work with
this loop. When you need to work with another loop, just call
iv_analysis_loop_init for it. When you no longer need iv analysis, call
iv_analysis_done () to clean up the memory.
The available functions are:
iv_analyze (insn, mode, reg, iv): Stores the description of the induction
variable corresponding to the use of register REG in INSN to IV, given
that REG has mode MODE. Returns true if REG is an induction variable
in INSN. false otherwise. If a use of REG is not found in INSN,
the following insns are scanned (so that we may call this function
on insns returned by get_condition).
iv_analyze_result (insn, def, iv): Stores to IV the description of the iv
corresponding to DEF, which is a register defined in INSN.
iv_analyze_expr (insn, mode, expr, iv): Stores to IV the description of iv
corresponding to expression EXPR evaluated at INSN. All registers used bu
EXPR must also be used in INSN. MODE is the mode of EXPR.
*/
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "backend.h"
#include "rtl.h"
#include "df.h"
#include "memmodel.h"
#include "emit-rtl.h"
#include "diagnostic-core.h"
#include "cfgloop.h"
#include "intl.h"
#include "dumpfile.h"
#include "rtl-iter.h"
#include "tree-ssa-loop-niter.h"
#include "regs.h"
#include "function-abi.h"
/* Possible return values of iv_get_reaching_def. */
enum iv_grd_result
{
/* More than one reaching def, or reaching def that does not
dominate the use. */
GRD_INVALID,
/* The use is trivial invariant of the loop, i.e. is not changed
inside the loop. */
GRD_INVARIANT,
/* The use is reached by initial value and a value from the
previous iteration. */
GRD_MAYBE_BIV,
/* The use has single dominating def. */
GRD_SINGLE_DOM
};
/* Information about a biv. */
class biv_entry
{
public:
unsigned regno; /* The register of the biv. */
class rtx_iv iv; /* Value of the biv. */
};
static bool clean_slate = true;
static unsigned int iv_ref_table_size = 0;
/* Table of rtx_ivs indexed by the df_ref uid field. */
static class rtx_iv ** iv_ref_table;
/* Induction variable stored at the reference. */
#define DF_REF_IV(REF) iv_ref_table[DF_REF_ID (REF)]
#define DF_REF_IV_SET(REF, IV) iv_ref_table[DF_REF_ID (REF)] = (IV)
/* The current loop. */
static class loop *current_loop;
/* Hashtable helper. */
struct biv_entry_hasher : free_ptr_hash
{
typedef rtx_def *compare_type;
static inline hashval_t hash (const biv_entry *);
static inline bool equal (const biv_entry *, const rtx_def *);
};
/* Returns hash value for biv B. */
inline hashval_t
biv_entry_hasher::hash (const biv_entry *b)
{
return b->regno;
}
/* Compares biv B and register R. */
inline bool
biv_entry_hasher::equal (const biv_entry *b, const rtx_def *r)
{
return b->regno == REGNO (r);
}
/* Bivs of the current loop. */
static hash_table *bivs;
static bool iv_analyze_op (rtx_insn *, scalar_int_mode, rtx, class rtx_iv *);
/* Return the RTX code corresponding to the IV extend code EXTEND. */
static inline enum rtx_code
iv_extend_to_rtx_code (enum iv_extend_code extend)
{
switch (extend)
{
case IV_SIGN_EXTEND:
return SIGN_EXTEND;
case IV_ZERO_EXTEND:
return ZERO_EXTEND;
case IV_UNKNOWN_EXTEND:
return UNKNOWN;
}
gcc_unreachable ();
}
/* Dumps information about IV to FILE. */
extern void dump_iv_info (FILE *, class rtx_iv *);
void
dump_iv_info (FILE *file, class rtx_iv *iv)
{
if (!iv->base)
{
fprintf (file, "not simple");
return;
}
if (iv->step == const0_rtx
&& !iv->first_special)
fprintf (file, "invariant ");
print_rtl (file, iv->base);
if (iv->step != const0_rtx)
{
fprintf (file, " + ");
print_rtl (file, iv->step);
fprintf (file, " * iteration");
}
fprintf (file, " (in %s)", GET_MODE_NAME (iv->mode));
if (iv->mode != iv->extend_mode)
fprintf (file, " %s to %s",
rtx_name[iv_extend_to_rtx_code (iv->extend)],
GET_MODE_NAME (iv->extend_mode));
if (iv->mult != const1_rtx)
{
fprintf (file, " * ");
print_rtl (file, iv->mult);
}
if (iv->delta != const0_rtx)
{
fprintf (file, " + ");
print_rtl (file, iv->delta);
}
if (iv->first_special)
fprintf (file, " (first special)");
}
static void
check_iv_ref_table_size (void)
{
if (iv_ref_table_size < DF_DEFS_TABLE_SIZE ())
{
unsigned int new_size = DF_DEFS_TABLE_SIZE () + (DF_DEFS_TABLE_SIZE () / 4);
iv_ref_table = XRESIZEVEC (class rtx_iv *, iv_ref_table, new_size);
memset (&iv_ref_table[iv_ref_table_size], 0,
(new_size - iv_ref_table_size) * sizeof (class rtx_iv *));
iv_ref_table_size = new_size;
}
}
/* Checks whether REG is a well-behaved register. */
static bool
simple_reg_p (rtx reg)
{
unsigned r;
if (GET_CODE (reg) == SUBREG)
{
if (!subreg_lowpart_p (reg))
return false;
reg = SUBREG_REG (reg);
}
if (!REG_P (reg))
return false;
r = REGNO (reg);
if (HARD_REGISTER_NUM_P (r))
return false;
if (GET_MODE_CLASS (GET_MODE (reg)) != MODE_INT)
return false;
return true;
}
/* Clears the information about ivs stored in df. */
static void
clear_iv_info (void)
{
unsigned i, n_defs = DF_DEFS_TABLE_SIZE ();
class rtx_iv *iv;
check_iv_ref_table_size ();
for (i = 0; i < n_defs; i++)
{
iv = iv_ref_table[i];
if (iv)
{
free (iv);
iv_ref_table[i] = NULL;
}
}
bivs->empty ();
}
/* Prepare the data for an induction variable analysis of a LOOP. */
void
iv_analysis_loop_init (class loop *loop)
{
current_loop = loop;
/* Clear the information from the analysis of the previous loop. */
if (clean_slate)
{
df_set_flags (DF_EQ_NOTES + DF_DEFER_INSN_RESCAN);
bivs = new hash_table (10);
clean_slate = false;
}
else
clear_iv_info ();
/* Get rid of the ud chains before processing the rescans. Then add
the problem back. */
df_remove_problem (df_chain);
df_process_deferred_rescans ();
df_set_flags (DF_RD_PRUNE_DEAD_DEFS);
df_chain_add_problem (DF_UD_CHAIN);
df_note_add_problem ();
df_analyze_loop (loop);
if (dump_file)
df_dump_region (dump_file);
check_iv_ref_table_size ();
}
/* Finds the definition of REG that dominates loop latch and stores
it to DEF. Returns false if there is not a single definition
dominating the latch. If REG has no definition in loop, DEF
is set to NULL and true is returned. */
static bool
latch_dominating_def (rtx reg, df_ref *def)
{
df_ref single_rd = NULL, adef;
unsigned regno = REGNO (reg);
class df_rd_bb_info *bb_info = DF_RD_BB_INFO (current_loop->latch);
for (adef = DF_REG_DEF_CHAIN (regno); adef; adef = DF_REF_NEXT_REG (adef))
{
if (!bitmap_bit_p (df->blocks_to_analyze, DF_REF_BBNO (adef))
|| !bitmap_bit_p (&bb_info->out, DF_REF_ID (adef)))
continue;
/* More than one reaching definition. */
if (single_rd)
return false;
if (!just_once_each_iteration_p (current_loop, DF_REF_BB (adef)))
return false;
single_rd = adef;
}
*def = single_rd;
return true;
}
/* Gets definition of REG reaching its use in INSN and stores it to DEF. */
static enum iv_grd_result
iv_get_reaching_def (rtx_insn *insn, rtx reg, df_ref *def)
{
df_ref use, adef;
basic_block def_bb, use_bb;
rtx_insn *def_insn;
bool dom_p;
*def = NULL;
if (!simple_reg_p (reg))
return GRD_INVALID;
if (GET_CODE (reg) == SUBREG)
reg = SUBREG_REG (reg);
gcc_assert (REG_P (reg));
use = df_find_use (insn, reg);
gcc_assert (use != NULL);
if (!DF_REF_CHAIN (use))
return GRD_INVARIANT;
/* More than one reaching def. */
if (DF_REF_CHAIN (use)->next)
return GRD_INVALID;
adef = DF_REF_CHAIN (use)->ref;
/* We do not handle setting only part of the register. */
if (DF_REF_FLAGS (adef) & DF_REF_READ_WRITE)
return GRD_INVALID;
def_insn = DF_REF_INSN (adef);
def_bb = DF_REF_BB (adef);
use_bb = BLOCK_FOR_INSN (insn);
if (use_bb == def_bb)
dom_p = (DF_INSN_LUID (def_insn) < DF_INSN_LUID (insn));
else
dom_p = dominated_by_p (CDI_DOMINATORS, use_bb, def_bb);
if (dom_p)
{
*def = adef;
return GRD_SINGLE_DOM;
}
/* The definition does not dominate the use. This is still OK if
this may be a use of a biv, i.e. if the def_bb dominates loop
latch. */
if (just_once_each_iteration_p (current_loop, def_bb))
return GRD_MAYBE_BIV;
return GRD_INVALID;
}
/* Sets IV to invariant CST in MODE. Always returns true (just for
consistency with other iv manipulation functions that may fail). */
static bool
iv_constant (class rtx_iv *iv, scalar_int_mode mode, rtx cst)
{
iv->mode = mode;
iv->base = cst;
iv->step = const0_rtx;
iv->first_special = false;
iv->extend = IV_UNKNOWN_EXTEND;
iv->extend_mode = iv->mode;
iv->delta = const0_rtx;
iv->mult = const1_rtx;
return true;
}
/* Evaluates application of subreg to MODE on IV. */
static bool
iv_subreg (class rtx_iv *iv, scalar_int_mode mode)
{
/* If iv is invariant, just calculate the new value. */
if (iv->step == const0_rtx
&& !iv->first_special)
{
rtx val = get_iv_value (iv, const0_rtx);
val = lowpart_subreg (mode, val,
iv->extend == IV_UNKNOWN_EXTEND
? iv->mode : iv->extend_mode);
iv->base = val;
iv->extend = IV_UNKNOWN_EXTEND;
iv->mode = iv->extend_mode = mode;
iv->delta = const0_rtx;
iv->mult = const1_rtx;
return true;
}
if (iv->extend_mode == mode)
return true;
if (GET_MODE_BITSIZE (mode) > GET_MODE_BITSIZE (iv->mode))
return false;
iv->extend = IV_UNKNOWN_EXTEND;
iv->mode = mode;
iv->base = simplify_gen_binary (PLUS, iv->extend_mode, iv->delta,
simplify_gen_binary (MULT, iv->extend_mode,
iv->base, iv->mult));
iv->step = simplify_gen_binary (MULT, iv->extend_mode, iv->step, iv->mult);
iv->mult = const1_rtx;
iv->delta = const0_rtx;
iv->first_special = false;
return true;
}
/* Evaluates application of EXTEND to MODE on IV. */
static bool
iv_extend (class rtx_iv *iv, enum iv_extend_code extend, scalar_int_mode mode)
{
/* If iv is invariant, just calculate the new value. */
if (iv->step == const0_rtx
&& !iv->first_special)
{
rtx val = get_iv_value (iv, const0_rtx);
if (iv->extend_mode != iv->mode
&& iv->extend != IV_UNKNOWN_EXTEND
&& iv->extend != extend)
val = lowpart_subreg (iv->mode, val, iv->extend_mode);
val = simplify_gen_unary (iv_extend_to_rtx_code (extend), mode,
val,
iv->extend == extend
? iv->extend_mode : iv->mode);
iv->base = val;
iv->extend = IV_UNKNOWN_EXTEND;
iv->mode = iv->extend_mode = mode;
iv->delta = const0_rtx;
iv->mult = const1_rtx;
return true;
}
if (mode != iv->extend_mode)
return false;
if (iv->extend != IV_UNKNOWN_EXTEND
&& iv->extend != extend)
return false;
iv->extend = extend;
return true;
}
/* Evaluates negation of IV. */
static bool
iv_neg (class rtx_iv *iv)
{
if (iv->extend == IV_UNKNOWN_EXTEND)
{
iv->base = simplify_gen_unary (NEG, iv->extend_mode,
iv->base, iv->extend_mode);
iv->step = simplify_gen_unary (NEG, iv->extend_mode,
iv->step, iv->extend_mode);
}
else
{
iv->delta = simplify_gen_unary (NEG, iv->extend_mode,
iv->delta, iv->extend_mode);
iv->mult = simplify_gen_unary (NEG, iv->extend_mode,
iv->mult, iv->extend_mode);
}
return true;
}
/* Evaluates addition or subtraction (according to OP) of IV1 to IV0. */
static bool
iv_add (class rtx_iv *iv0, class rtx_iv *iv1, enum rtx_code op)
{
scalar_int_mode mode;
rtx arg;
/* Extend the constant to extend_mode of the other operand if necessary. */
if (iv0->extend == IV_UNKNOWN_EXTEND
&& iv0->mode == iv0->extend_mode
&& iv0->step == const0_rtx
&& GET_MODE_SIZE (iv0->extend_mode) < GET_MODE_SIZE (iv1->extend_mode))
{
iv0->extend_mode = iv1->extend_mode;
iv0->base = simplify_gen_unary (ZERO_EXTEND, iv0->extend_mode,
iv0->base, iv0->mode);
}
if (iv1->extend == IV_UNKNOWN_EXTEND
&& iv1->mode == iv1->extend_mode
&& iv1->step == const0_rtx
&& GET_MODE_SIZE (iv1->extend_mode) < GET_MODE_SIZE (iv0->extend_mode))
{
iv1->extend_mode = iv0->extend_mode;
iv1->base = simplify_gen_unary (ZERO_EXTEND, iv1->extend_mode,
iv1->base, iv1->mode);
}
mode = iv0->extend_mode;
if (mode != iv1->extend_mode)
return false;
if (iv0->extend == IV_UNKNOWN_EXTEND
&& iv1->extend == IV_UNKNOWN_EXTEND)
{
if (iv0->mode != iv1->mode)
return false;
iv0->base = simplify_gen_binary (op, mode, iv0->base, iv1->base);
iv0->step = simplify_gen_binary (op, mode, iv0->step, iv1->step);
return true;
}
/* Handle addition of constant. */
if (iv1->extend == IV_UNKNOWN_EXTEND
&& iv1->mode == mode
&& iv1->step == const0_rtx)
{
iv0->delta = simplify_gen_binary (op, mode, iv0->delta, iv1->base);
return true;
}
if (iv0->extend == IV_UNKNOWN_EXTEND
&& iv0->mode == mode
&& iv0->step == const0_rtx)
{
arg = iv0->base;
*iv0 = *iv1;
if (op == MINUS
&& !iv_neg (iv0))
return false;
iv0->delta = simplify_gen_binary (PLUS, mode, iv0->delta, arg);
return true;
}
return false;
}
/* Evaluates multiplication of IV by constant CST. */
static bool
iv_mult (class rtx_iv *iv, rtx mby)
{
scalar_int_mode mode = iv->extend_mode;
if (GET_MODE (mby) != VOIDmode
&& GET_MODE (mby) != mode)
return false;
if (iv->extend == IV_UNKNOWN_EXTEND)
{
iv->base = simplify_gen_binary (MULT, mode, iv->base, mby);
iv->step = simplify_gen_binary (MULT, mode, iv->step, mby);
}
else
{
iv->delta = simplify_gen_binary (MULT, mode, iv->delta, mby);
iv->mult = simplify_gen_binary (MULT, mode, iv->mult, mby);
}
return true;
}
/* Evaluates shift of IV by constant CST. */
static bool
iv_shift (class rtx_iv *iv, rtx mby)
{
scalar_int_mode mode = iv->extend_mode;
if (GET_MODE (mby) != VOIDmode
&& GET_MODE (mby) != mode)
return false;
if (iv->extend == IV_UNKNOWN_EXTEND)
{
iv->base = simplify_gen_binary (ASHIFT, mode, iv->base, mby);
iv->step = simplify_gen_binary (ASHIFT, mode, iv->step, mby);
}
else
{
iv->delta = simplify_gen_binary (ASHIFT, mode, iv->delta, mby);
iv->mult = simplify_gen_binary (ASHIFT, mode, iv->mult, mby);
}
return true;
}
/* The recursive part of get_biv_step. Gets the value of the single value
defined by DEF wrto initial value of REG inside loop, in shape described
at get_biv_step. */
static bool
get_biv_step_1 (df_ref def, scalar_int_mode outer_mode, rtx reg,
rtx *inner_step, scalar_int_mode *inner_mode,
enum iv_extend_code *extend,
rtx *outer_step)
{
rtx set, rhs, op0 = NULL_RTX, op1 = NULL_RTX;
rtx next, nextr;
enum rtx_code code;
rtx_insn *insn = DF_REF_INSN (def);
df_ref next_def;
enum iv_grd_result res;
set = single_set (insn);
if (!set)
return false;
rhs = find_reg_equal_equiv_note (insn);
if (rhs)
rhs = XEXP (rhs, 0);
else
rhs = SET_SRC (set);
code = GET_CODE (rhs);
switch (code)
{
case SUBREG:
case REG:
next = rhs;
break;
case PLUS:
case MINUS:
op0 = XEXP (rhs, 0);
op1 = XEXP (rhs, 1);
if (code == PLUS && CONSTANT_P (op0))
std::swap (op0, op1);
if (!simple_reg_p (op0)
|| !CONSTANT_P (op1))
return false;
if (GET_MODE (rhs) != outer_mode)
{
/* ppc64 uses expressions like
(set x:SI (plus:SI (subreg:SI y:DI) 1)).
this is equivalent to
(set x':DI (plus:DI y:DI 1))
(set x:SI (subreg:SI (x':DI)). */
if (GET_CODE (op0) != SUBREG)
return false;
if (GET_MODE (SUBREG_REG (op0)) != outer_mode)
return false;
}
next = op0;
break;
case SIGN_EXTEND:
case ZERO_EXTEND:
if (GET_MODE (rhs) != outer_mode)
return false;
op0 = XEXP (rhs, 0);
if (!simple_reg_p (op0))
return false;
next = op0;
break;
default:
return false;
}
if (GET_CODE (next) == SUBREG)
{
if (!subreg_lowpart_p (next))
return false;
nextr = SUBREG_REG (next);
if (GET_MODE (nextr) != outer_mode)
return false;
}
else
nextr = next;
res = iv_get_reaching_def (insn, nextr, &next_def);
if (res == GRD_INVALID || res == GRD_INVARIANT)
return false;
if (res == GRD_MAYBE_BIV)
{
if (!rtx_equal_p (nextr, reg))
return false;
*inner_step = const0_rtx;
*extend = IV_UNKNOWN_EXTEND;
*inner_mode = outer_mode;
*outer_step = const0_rtx;
}
else if (!get_biv_step_1 (next_def, outer_mode, reg,
inner_step, inner_mode, extend,
outer_step))
return false;
if (GET_CODE (next) == SUBREG)
{
scalar_int_mode amode;
if (!is_a (GET_MODE (next), &amode)
|| GET_MODE_SIZE (amode) > GET_MODE_SIZE (*inner_mode))
return false;
*inner_mode = amode;
*inner_step = simplify_gen_binary (PLUS, outer_mode,
*inner_step, *outer_step);
*outer_step = const0_rtx;
*extend = IV_UNKNOWN_EXTEND;
}
switch (code)
{
case REG:
case SUBREG:
break;
case PLUS:
case MINUS:
if (*inner_mode == outer_mode
/* See comment in previous switch. */
|| GET_MODE (rhs) != outer_mode)
*inner_step = simplify_gen_binary (code, outer_mode,
*inner_step, op1);
else
*outer_step = simplify_gen_binary (code, outer_mode,
*outer_step, op1);
break;
case SIGN_EXTEND:
case ZERO_EXTEND:
gcc_assert (GET_MODE (op0) == *inner_mode
&& *extend == IV_UNKNOWN_EXTEND
&& *outer_step == const0_rtx);
*extend = (code == SIGN_EXTEND) ? IV_SIGN_EXTEND : IV_ZERO_EXTEND;
break;
default:
return false;
}
return true;
}
/* Gets the operation on register REG inside loop, in shape
OUTER_STEP + EXTEND_{OUTER_MODE} (SUBREG_{INNER_MODE} (REG + INNER_STEP))
If the operation cannot be described in this shape, return false.
LAST_DEF is the definition of REG that dominates loop latch. */
static bool
get_biv_step (df_ref last_def, scalar_int_mode outer_mode, rtx reg,
rtx *inner_step, scalar_int_mode *inner_mode,
enum iv_extend_code *extend, rtx *outer_step)
{
if (!get_biv_step_1 (last_def, outer_mode, reg,
inner_step, inner_mode, extend,
outer_step))
return false;
gcc_assert ((*inner_mode == outer_mode) != (*extend != IV_UNKNOWN_EXTEND));
gcc_assert (*inner_mode != outer_mode || *outer_step == const0_rtx);
return true;
}
/* Records information that DEF is induction variable IV. */
static void
record_iv (df_ref def, class rtx_iv *iv)
{
class rtx_iv *recorded_iv = XNEW (class rtx_iv);
*recorded_iv = *iv;
check_iv_ref_table_size ();
DF_REF_IV_SET (def, recorded_iv);
}
/* If DEF was already analyzed for bivness, store the description of the biv to
IV and return true. Otherwise return false. */
static bool
analyzed_for_bivness_p (rtx def, class rtx_iv *iv)
{
class biv_entry *biv = bivs->find_with_hash (def, REGNO (def));
if (!biv)
return false;
*iv = biv->iv;
return true;
}
static void
record_biv (rtx def, class rtx_iv *iv)
{
class biv_entry *biv = XNEW (class biv_entry);
biv_entry **slot = bivs->find_slot_with_hash (def, REGNO (def), INSERT);
biv->regno = REGNO (def);
biv->iv = *iv;
gcc_assert (!*slot);
*slot = biv;
}
/* Determines whether DEF is a biv and if so, stores its description
to *IV. OUTER_MODE is the mode of DEF. */
static bool
iv_analyze_biv (scalar_int_mode outer_mode, rtx def, class rtx_iv *iv)
{
rtx inner_step, outer_step;
scalar_int_mode inner_mode;
enum iv_extend_code extend;
df_ref last_def;
if (dump_file)
{
fprintf (dump_file, "Analyzing ");
print_rtl (dump_file, def);
fprintf (dump_file, " for bivness.\n");
}
if (!REG_P (def))
{
if (!CONSTANT_P (def))
return false;
return iv_constant (iv, outer_mode, def);
}
if (!latch_dominating_def (def, &last_def))
{
if (dump_file)
fprintf (dump_file, " not simple.\n");
return false;
}
if (!last_def)
return iv_constant (iv, outer_mode, def);
if (analyzed_for_bivness_p (def, iv))
{
if (dump_file)
fprintf (dump_file, " already analysed.\n");
return iv->base != NULL_RTX;
}
if (!get_biv_step (last_def, outer_mode, def, &inner_step, &inner_mode,
&extend, &outer_step))
{
iv->base = NULL_RTX;
goto end;
}
/* Loop transforms base to es (base + inner_step) + outer_step,
where es means extend of subreg between inner_mode and outer_mode.
The corresponding induction variable is
es ((base - outer_step) + i * (inner_step + outer_step)) + outer_step */
iv->base = simplify_gen_binary (MINUS, outer_mode, def, outer_step);
iv->step = simplify_gen_binary (PLUS, outer_mode, inner_step, outer_step);
iv->mode = inner_mode;
iv->extend_mode = outer_mode;
iv->extend = extend;
iv->mult = const1_rtx;
iv->delta = outer_step;
iv->first_special = inner_mode != outer_mode;
end:
if (dump_file)
{
fprintf (dump_file, " ");
dump_iv_info (dump_file, iv);
fprintf (dump_file, "\n");
}
record_biv (def, iv);
return iv->base != NULL_RTX;
}
/* Analyzes expression RHS used at INSN and stores the result to *IV.
The mode of the induction variable is MODE. */
bool
iv_analyze_expr (rtx_insn *insn, scalar_int_mode mode, rtx rhs,
class rtx_iv *iv)
{
rtx mby = NULL_RTX;
rtx op0 = NULL_RTX, op1 = NULL_RTX;
class rtx_iv iv0, iv1;
enum rtx_code code = GET_CODE (rhs);
scalar_int_mode omode = mode;
iv->base = NULL_RTX;
iv->step = NULL_RTX;
gcc_assert (GET_MODE (rhs) == mode || GET_MODE (rhs) == VOIDmode);
if (CONSTANT_P (rhs)
|| REG_P (rhs)
|| code == SUBREG)
return iv_analyze_op (insn, mode, rhs, iv);
switch (code)
{
case REG:
op0 = rhs;
break;
case SIGN_EXTEND:
case ZERO_EXTEND:
case NEG:
op0 = XEXP (rhs, 0);
/* We don't know how many bits there are in a sign-extended constant. */
if (!is_a (GET_MODE (op0), &omode))
return false;
break;
case PLUS:
case MINUS:
op0 = XEXP (rhs, 0);
op1 = XEXP (rhs, 1);
break;
case MULT:
op0 = XEXP (rhs, 0);
mby = XEXP (rhs, 1);
if (!CONSTANT_P (mby))
std::swap (op0, mby);
if (!CONSTANT_P (mby))
return false;
break;
case ASHIFT:
op0 = XEXP (rhs, 0);
mby = XEXP (rhs, 1);
if (!CONSTANT_P (mby))
return false;
break;
default:
return false;
}
if (op0
&& !iv_analyze_expr (insn, omode, op0, &iv0))
return false;
if (op1
&& !iv_analyze_expr (insn, omode, op1, &iv1))
return false;
switch (code)
{
case SIGN_EXTEND:
if (!iv_extend (&iv0, IV_SIGN_EXTEND, mode))
return false;
break;
case ZERO_EXTEND:
if (!iv_extend (&iv0, IV_ZERO_EXTEND, mode))
return false;
break;
case NEG:
if (!iv_neg (&iv0))
return false;
break;
case PLUS:
case MINUS:
if (!iv_add (&iv0, &iv1, code))
return false;
break;
case MULT:
if (!iv_mult (&iv0, mby))
return false;
break;
case ASHIFT:
if (!iv_shift (&iv0, mby))
return false;
break;
default:
break;
}
*iv = iv0;
return iv->base != NULL_RTX;
}
/* Analyzes iv DEF and stores the result to *IV. */
static bool
iv_analyze_def (df_ref def, class rtx_iv *iv)
{
rtx_insn *insn = DF_REF_INSN (def);
rtx reg = DF_REF_REG (def);
rtx set, rhs;
if (dump_file)
{
fprintf (dump_file, "Analyzing def of ");
print_rtl (dump_file, reg);
fprintf (dump_file, " in insn ");
print_rtl_single (dump_file, insn);
}
check_iv_ref_table_size ();
if (DF_REF_IV (def))
{
if (dump_file)
fprintf (dump_file, " already analysed.\n");
*iv = *DF_REF_IV (def);
return iv->base != NULL_RTX;
}
iv->base = NULL_RTX;
iv->step = NULL_RTX;
scalar_int_mode mode;
if (!REG_P (reg) || !is_a (GET_MODE (reg), &mode))
return false;
set = single_set (insn);
if (!set)
return false;
if (!REG_P (SET_DEST (set)))
return false;
gcc_assert (SET_DEST (set) == reg);
rhs = find_reg_equal_equiv_note (insn);
if (rhs)
rhs = XEXP (rhs, 0);
else
rhs = SET_SRC (set);
iv_analyze_expr (insn, mode, rhs, iv);
record_iv (def, iv);
if (dump_file)
{
print_rtl (dump_file, reg);
fprintf (dump_file, " in insn ");
print_rtl_single (dump_file, insn);
fprintf (dump_file, " is ");
dump_iv_info (dump_file, iv);
fprintf (dump_file, "\n");
}
return iv->base != NULL_RTX;
}
/* Analyzes operand OP of INSN and stores the result to *IV. MODE is the
mode of OP. */
static bool
iv_analyze_op (rtx_insn *insn, scalar_int_mode mode, rtx op, class rtx_iv *iv)
{
df_ref def = NULL;
enum iv_grd_result res;
if (dump_file)
{
fprintf (dump_file, "Analyzing operand ");
print_rtl (dump_file, op);
fprintf (dump_file, " of insn ");
print_rtl_single (dump_file, insn);
}
if (function_invariant_p (op))
res = GRD_INVARIANT;
else if (GET_CODE (op) == SUBREG)
{
scalar_int_mode inner_mode;
if (!subreg_lowpart_p (op)
|| !is_a (GET_MODE (SUBREG_REG (op)), &inner_mode))
return false;
if (!iv_analyze_op (insn, inner_mode, SUBREG_REG (op), iv))
return false;
return iv_subreg (iv, mode);
}
else
{
res = iv_get_reaching_def (insn, op, &def);
if (res == GRD_INVALID)
{
if (dump_file)
fprintf (dump_file, " not simple.\n");
return false;
}
}
if (res == GRD_INVARIANT)
{
iv_constant (iv, mode, op);
if (dump_file)
{
fprintf (dump_file, " ");
dump_iv_info (dump_file, iv);
fprintf (dump_file, "\n");
}
return true;
}
if (res == GRD_MAYBE_BIV)
return iv_analyze_biv (mode, op, iv);
return iv_analyze_def (def, iv);
}
/* Analyzes value VAL at INSN and stores the result to *IV. MODE is the
mode of VAL. */
bool
iv_analyze (rtx_insn *insn, scalar_int_mode mode, rtx val, class rtx_iv *iv)
{
rtx reg;
/* We must find the insn in that val is used, so that we get to UD chains.
Since the function is sometimes called on result of get_condition,
this does not necessarily have to be directly INSN; scan also the
following insns. */
if (simple_reg_p (val))
{
if (GET_CODE (val) == SUBREG)
reg = SUBREG_REG (val);
else
reg = val;
while (!df_find_use (insn, reg))
insn = NEXT_INSN (insn);
}
return iv_analyze_op (insn, mode, val, iv);
}
/* Analyzes definition of DEF in INSN and stores the result to IV. */
bool
iv_analyze_result (rtx_insn *insn, rtx def, class rtx_iv *iv)
{
df_ref adef;
adef = df_find_def (insn, def);
if (!adef)
return false;
return iv_analyze_def (adef, iv);
}
/* Checks whether definition of register REG in INSN is a basic induction
variable. MODE is the mode of REG.
IV analysis must have been initialized (via a call to
iv_analysis_loop_init) for this function to produce a result. */
bool
biv_p (rtx_insn *insn, scalar_int_mode mode, rtx reg)
{
class rtx_iv iv;
df_ref def, last_def;
if (!simple_reg_p (reg))
return false;
def = df_find_def (insn, reg);
gcc_assert (def != NULL);
if (!latch_dominating_def (reg, &last_def))
return false;
if (last_def != def)
return false;
if (!iv_analyze_biv (mode, reg, &iv))
return false;
return iv.step != const0_rtx;
}
/* Calculates value of IV at ITERATION-th iteration. */
rtx
get_iv_value (class rtx_iv *iv, rtx iteration)
{
rtx val;
/* We would need to generate some if_then_else patterns, and so far
it is not needed anywhere. */
gcc_assert (!iv->first_special);
if (iv->step != const0_rtx && iteration != const0_rtx)
val = simplify_gen_binary (PLUS, iv->extend_mode, iv->base,
simplify_gen_binary (MULT, iv->extend_mode,
iv->step, iteration));
else
val = iv->base;
if (iv->extend_mode == iv->mode)
return val;
val = lowpart_subreg (iv->mode, val, iv->extend_mode);
if (iv->extend == IV_UNKNOWN_EXTEND)
return val;
val = simplify_gen_unary (iv_extend_to_rtx_code (iv->extend),
iv->extend_mode, val, iv->mode);
val = simplify_gen_binary (PLUS, iv->extend_mode, iv->delta,
simplify_gen_binary (MULT, iv->extend_mode,
iv->mult, val));
return val;
}
/* Free the data for an induction variable analysis. */
void
iv_analysis_done (void)
{
if (!clean_slate)
{
clear_iv_info ();
clean_slate = true;
df_finish_pass (true);
delete bivs;
bivs = NULL;
free (iv_ref_table);
iv_ref_table = NULL;
iv_ref_table_size = 0;
}
}
/* Computes inverse to X modulo (1 << MOD). */
static uint64_t
inverse (uint64_t x, int mod)
{
uint64_t mask =
((uint64_t) 1 << (mod - 1) << 1) - 1;
uint64_t rslt = 1;
int i;
for (i = 0; i < mod - 1; i++)
{
rslt = (rslt * x) & mask;
x = (x * x) & mask;
}
return rslt;
}
/* Checks whether any register in X is in set ALT. */
static bool
altered_reg_used (const_rtx x, bitmap alt)
{
subrtx_iterator::array_type array;
FOR_EACH_SUBRTX (iter, array, x, NONCONST)
{
const_rtx x = *iter;
if (REG_P (x) && REGNO_REG_SET_P (alt, REGNO (x)))
return true;
}
return false;
}
/* Marks registers altered by EXPR in set ALT. */
static void
mark_altered (rtx expr, const_rtx by ATTRIBUTE_UNUSED, void *alt)
{
if (GET_CODE (expr) == SUBREG)
expr = SUBREG_REG (expr);
if (!REG_P (expr))
return;
SET_REGNO_REG_SET ((bitmap) alt, REGNO (expr));
}
/* Checks whether RHS is simple enough to process. */
static bool
simple_rhs_p (rtx rhs)
{
rtx op0, op1;
if (function_invariant_p (rhs)
|| (REG_P (rhs) && !HARD_REGISTER_P (rhs)))
return true;
switch (GET_CODE (rhs))
{
case PLUS:
case MINUS:
case AND:
op0 = XEXP (rhs, 0);
op1 = XEXP (rhs, 1);
/* Allow reg OP const and reg OP reg. */
if (!(REG_P (op0) && !HARD_REGISTER_P (op0))
&& !function_invariant_p (op0))
return false;
if (!(REG_P (op1) && !HARD_REGISTER_P (op1))
&& !function_invariant_p (op1))
return false;
return true;
case ASHIFT:
case ASHIFTRT:
case LSHIFTRT:
case MULT:
op0 = XEXP (rhs, 0);
op1 = XEXP (rhs, 1);
/* Allow reg OP const. */
if (!(REG_P (op0) && !HARD_REGISTER_P (op0)))
return false;
if (!function_invariant_p (op1))
return false;
return true;
default:
return false;
}
}
/* If REGNO has a single definition, return its known value, otherwise return
null. */
static rtx
find_single_def_src (unsigned int regno)
{
rtx src = NULL_RTX;
/* Don't look through unbounded number of single definition REG copies,
there might be loops for sources with uninitialized variables. */
for (int cnt = 0; cnt < 128; cnt++)
{
df_ref adef = DF_REG_DEF_CHAIN (regno);
if (adef == NULL || DF_REF_NEXT_REG (adef) != NULL
|| DF_REF_IS_ARTIFICIAL (adef))
return NULL_RTX;
rtx set = single_set (DF_REF_INSN (adef));
if (set == NULL || !REG_P (SET_DEST (set))
|| REGNO (SET_DEST (set)) != regno)
return NULL_RTX;
rtx note = find_reg_equal_equiv_note (DF_REF_INSN (adef));
if (note && function_invariant_p (XEXP (note, 0)))
{
src = XEXP (note, 0);
break;
}
src = SET_SRC (set);
if (REG_P (src))
{
regno = REGNO (src);
continue;
}
break;
}
if (!function_invariant_p (src))
return NULL_RTX;
return src;
}
/* If any registers in *EXPR that have a single definition, try to replace
them with the known-equivalent values. */
static void
replace_single_def_regs (rtx *expr)
{
subrtx_var_iterator::array_type array;
repeat:
FOR_EACH_SUBRTX_VAR (iter, array, *expr, NONCONST)
{
rtx x = *iter;
if (REG_P (x))
if (rtx new_x = find_single_def_src (REGNO (x)))
{
*expr = simplify_replace_rtx (*expr, x, new_x);
goto repeat;
}
}
}
/* A subroutine of simplify_using_initial_values, this function examines INSN
to see if it contains a suitable set that we can use to make a replacement.
If it is suitable, return true and set DEST and SRC to the lhs and rhs of
the set; return false otherwise. */
static bool
suitable_set_for_replacement (rtx_insn *insn, rtx *dest, rtx *src)
{
rtx set = single_set (insn);
rtx lhs = NULL_RTX, rhs;
if (!set)
return false;
lhs = SET_DEST (set);
if (!REG_P (lhs))
return false;
rhs = find_reg_equal_equiv_note (insn);
if (rhs)
rhs = XEXP (rhs, 0);
else
rhs = SET_SRC (set);
if (!simple_rhs_p (rhs))
return false;
*dest = lhs;
*src = rhs;
return true;
}
/* Using the data returned by suitable_set_for_replacement, replace DEST
with SRC in *EXPR and return the new expression. Also call
replace_single_def_regs if the replacement changed something. */
static void
replace_in_expr (rtx *expr, rtx dest, rtx src)
{
rtx old = *expr;
*expr = simplify_replace_rtx (*expr, dest, src);
if (old == *expr)
return;
replace_single_def_regs (expr);
}
/* Checks whether A implies B. */
static bool
implies_p (rtx a, rtx b)
{
rtx op0, op1, opb0, opb1;
machine_mode mode;
if (rtx_equal_p (a, b))
return true;
if (GET_CODE (a) == EQ)
{
op0 = XEXP (a, 0);
op1 = XEXP (a, 1);
if (REG_P (op0)
|| (GET_CODE (op0) == SUBREG
&& REG_P (SUBREG_REG (op0))))
{
rtx r = simplify_replace_rtx (b, op0, op1);
if (r == const_true_rtx)
return true;
}
if (REG_P (op1)
|| (GET_CODE (op1) == SUBREG
&& REG_P (SUBREG_REG (op1))))
{
rtx r = simplify_replace_rtx (b, op1, op0);
if (r == const_true_rtx)
return true;
}
}
if (b == const_true_rtx)
return true;
if ((GET_RTX_CLASS (GET_CODE (a)) != RTX_COMM_COMPARE
&& GET_RTX_CLASS (GET_CODE (a)) != RTX_COMPARE)
|| (GET_RTX_CLASS (GET_CODE (b)) != RTX_COMM_COMPARE
&& GET_RTX_CLASS (GET_CODE (b)) != RTX_COMPARE))
return false;
op0 = XEXP (a, 0);
op1 = XEXP (a, 1);
opb0 = XEXP (b, 0);
opb1 = XEXP (b, 1);
mode = GET_MODE (op0);
if (mode != GET_MODE (opb0))
mode = VOIDmode;
else if (mode == VOIDmode)
{
mode = GET_MODE (op1);
if (mode != GET_MODE (opb1))
mode = VOIDmode;
}
/* A < B implies A + 1 <= B. */
if ((GET_CODE (a) == GT || GET_CODE (a) == LT)
&& (GET_CODE (b) == GE || GET_CODE (b) == LE))
{
if (GET_CODE (a) == GT)
std::swap (op0, op1);
if (GET_CODE (b) == GE)
std::swap (opb0, opb1);
if (SCALAR_INT_MODE_P (mode)
&& rtx_equal_p (op1, opb1)
&& simplify_gen_binary (MINUS, mode, opb0, op0) == const1_rtx)
return true;
return false;
}
/* A < B or A > B imply A != B. TODO: Likewise
A + n < B implies A != B + n if neither wraps. */
if (GET_CODE (b) == NE
&& (GET_CODE (a) == GT || GET_CODE (a) == GTU
|| GET_CODE (a) == LT || GET_CODE (a) == LTU))
{
if (rtx_equal_p (op0, opb0)
&& rtx_equal_p (op1, opb1))
return true;
}
/* For unsigned comparisons, A != 0 implies A > 0 and A >= 1. */
if (GET_CODE (a) == NE
&& op1 == const0_rtx)
{
if ((GET_CODE (b) == GTU
&& opb1 == const0_rtx)
|| (GET_CODE (b) == GEU
&& opb1 == const1_rtx))
return rtx_equal_p (op0, opb0);
}
/* A != N is equivalent to A - (N + 1) 0. */
if (GET_CODE (a) == NE
&& CONST_INT_P (op1))
{
if (GET_CODE (b) == GTU
&& GET_CODE (opb0) == PLUS
&& opb1 == const0_rtx
&& CONST_INT_P (XEXP (opb0, 1))
/* Avoid overflows. */
&& ((unsigned HOST_WIDE_INT) INTVAL (XEXP (opb0, 1))
!= (HOST_WIDE_INT_1U << (HOST_BITS_PER_WIDE_INT - 1)))
&& rtx_equal_p (XEXP (opb0, 0), op0))
return INTVAL (op1) == -INTVAL (XEXP (opb0, 1));
if (GET_CODE (b) == GEU
&& GET_CODE (opb0) == PLUS
&& opb1 == const1_rtx
&& CONST_INT_P (XEXP (opb0, 1))
/* Avoid overflows. */
&& ((unsigned HOST_WIDE_INT) INTVAL (XEXP (opb0, 1))
!= (HOST_WIDE_INT_1U << (HOST_BITS_PER_WIDE_INT - 1)))
&& rtx_equal_p (XEXP (opb0, 0), op0))
return INTVAL (op1) == -INTVAL (XEXP (opb0, 1));
}
/* A >s X, where X is positive, implies A = 0)
&& GET_CODE (b) == LTU
&& CONST_INT_P (opb1)
&& rtx_equal_p (op0, opb0))
return INTVAL (opb1) < 0;
return false;
}
/* Canonicalizes COND so that
(1) Ensure that operands are ordered according to
swap_commutative_operands_p.
(2) (LE x const) will be replaced with (LT x ) and similarly
for GE, GEU, and LEU. */
rtx
canon_condition (rtx cond)
{
rtx op0, op1;
enum rtx_code code;
machine_mode mode;
code = GET_CODE (cond);
op0 = XEXP (cond, 0);
op1 = XEXP (cond, 1);
if (swap_commutative_operands_p (op0, op1))
{
code = swap_condition (code);
std::swap (op0, op1);
}
mode = GET_MODE (op0);
if (mode == VOIDmode)
mode = GET_MODE (op1);
gcc_assert (mode != VOIDmode);
if (CONST_SCALAR_INT_P (op1) && GET_MODE_CLASS (mode) != MODE_CC)
{
rtx_mode_t const_val (op1, mode);
switch (code)
{
case LE:
if (wi::ne_p (const_val, wi::max_value (mode, SIGNED)))
{
code = LT;
op1 = immed_wide_int_const (wi::add (const_val, 1), mode);
}
break;
case GE:
if (wi::ne_p (const_val, wi::min_value (mode, SIGNED)))
{
code = GT;
op1 = immed_wide_int_const (wi::sub (const_val, 1), mode);
}
break;
case LEU:
if (wi::ne_p (const_val, -1))
{
code = LTU;
op1 = immed_wide_int_const (wi::add (const_val, 1), mode);
}
break;
case GEU:
if (wi::ne_p (const_val, 0))
{
code = GTU;
op1 = immed_wide_int_const (wi::sub (const_val, 1), mode);
}
break;
default:
break;
}
}
if (op0 != XEXP (cond, 0)
|| op1 != XEXP (cond, 1)
|| code != GET_CODE (cond)
|| GET_MODE (cond) != SImode)
cond = gen_rtx_fmt_ee (code, SImode, op0, op1);
return cond;
}
/* Reverses CONDition; returns NULL if we cannot. */
static rtx
reversed_condition (rtx cond)
{
enum rtx_code reversed;
reversed = reversed_comparison_code (cond, NULL);
if (reversed == UNKNOWN)
return NULL_RTX;
else
return gen_rtx_fmt_ee (reversed,
GET_MODE (cond), XEXP (cond, 0),
XEXP (cond, 1));
}
/* Tries to use the fact that COND holds to simplify EXPR. ALTERED is the
set of altered regs. */
void
simplify_using_condition (rtx cond, rtx *expr, regset altered)
{
rtx rev, reve, exp = *expr;
/* If some register gets altered later, we do not really speak about its
value at the time of comparison. */
if (altered && altered_reg_used (cond, altered))
return;
if (GET_CODE (cond) == EQ
&& REG_P (XEXP (cond, 0)) && CONSTANT_P (XEXP (cond, 1)))
{
*expr = simplify_replace_rtx (*expr, XEXP (cond, 0), XEXP (cond, 1));
return;
}
if (!COMPARISON_P (exp))
return;
rev = reversed_condition (cond);
reve = reversed_condition (exp);
cond = canon_condition (cond);
exp = canon_condition (exp);
if (rev)
rev = canon_condition (rev);
if (reve)
reve = canon_condition (reve);
if (rtx_equal_p (exp, cond))
{
*expr = const_true_rtx;
return;
}
if (rev && rtx_equal_p (exp, rev))
{
*expr = const0_rtx;
return;
}
if (implies_p (cond, exp))
{
*expr = const_true_rtx;
return;
}
if (reve && implies_p (cond, reve))
{
*expr = const0_rtx;
return;
}
/* A proof by contradiction. If *EXPR implies (not cond), *EXPR must
be false. */
if (rev && implies_p (exp, rev))
{
*expr = const0_rtx;
return;
}
/* Similarly, If (not *EXPR) implies (not cond), *EXPR must be true. */
if (rev && reve && implies_p (reve, rev))
{
*expr = const_true_rtx;
return;
}
/* We would like to have some other tests here. TODO. */
return;
}
/* Use relationship between A and *B to eventually eliminate *B.
OP is the operation we consider. */
static void
eliminate_implied_condition (enum rtx_code op, rtx a, rtx *b)
{
switch (op)
{
case AND:
/* If A implies *B, we may replace *B by true. */
if (implies_p (a, *b))
*b = const_true_rtx;
break;
case IOR:
/* If *B implies A, we may replace *B by false. */
if (implies_p (*b, a))
*b = const0_rtx;
break;
default:
gcc_unreachable ();
}
}
/* Eliminates the conditions in TAIL that are implied by HEAD. OP is the
operation we consider. */
static void
eliminate_implied_conditions (enum rtx_code op, rtx *head, rtx tail)
{
rtx elt;
for (elt = tail; elt; elt = XEXP (elt, 1))
eliminate_implied_condition (op, *head, &XEXP (elt, 0));
for (elt = tail; elt; elt = XEXP (elt, 1))
eliminate_implied_condition (op, XEXP (elt, 0), head);
}
/* Simplifies *EXPR using initial values at the start of the LOOP. If *EXPR
is a list, its elements are assumed to be combined using OP. */
static void
simplify_using_initial_values (class loop *loop, enum rtx_code op, rtx *expr)
{
bool expression_valid;
rtx head, tail, last_valid_expr;
rtx_expr_list *cond_list;
rtx_insn *insn;
rtx neutral, aggr;
regset altered, this_altered;
edge e;
if (!*expr)
return;
if (CONSTANT_P (*expr))
return;
if (GET_CODE (*expr) == EXPR_LIST)
{
head = XEXP (*expr, 0);
tail = XEXP (*expr, 1);
eliminate_implied_conditions (op, &head, tail);
switch (op)
{
case AND:
neutral = const_true_rtx;
aggr = const0_rtx;
break;
case IOR:
neutral = const0_rtx;
aggr = const_true_rtx;
break;
default:
gcc_unreachable ();
}
simplify_using_initial_values (loop, UNKNOWN, &head);
if (head == aggr)
{
XEXP (*expr, 0) = aggr;
XEXP (*expr, 1) = NULL_RTX;
return;
}
else if (head == neutral)
{
*expr = tail;
simplify_using_initial_values (loop, op, expr);
return;
}
simplify_using_initial_values (loop, op, &tail);
if (tail && XEXP (tail, 0) == aggr)
{
*expr = tail;
return;
}
XEXP (*expr, 0) = head;
XEXP (*expr, 1) = tail;
return;
}
gcc_assert (op == UNKNOWN);
replace_single_def_regs (expr);
if (CONSTANT_P (*expr))
return;
e = loop_preheader_edge (loop);
if (e->src == ENTRY_BLOCK_PTR_FOR_FN (cfun))
return;
altered = ALLOC_REG_SET (®_obstack);
this_altered = ALLOC_REG_SET (®_obstack);
expression_valid = true;
last_valid_expr = *expr;
cond_list = NULL;
while (1)
{
insn = BB_END (e->src);
if (any_condjump_p (insn))
{
rtx cond = get_condition (BB_END (e->src), NULL, false, true);
if (cond && (e->flags & EDGE_FALLTHRU))
cond = reversed_condition (cond);
if (cond)
{
rtx old = *expr;
simplify_using_condition (cond, expr, altered);
if (old != *expr)
{
rtx note;
if (CONSTANT_P (*expr))
goto out;
for (note = cond_list; note; note = XEXP (note, 1))
{
simplify_using_condition (XEXP (note, 0), expr, altered);
if (CONSTANT_P (*expr))
goto out;
}
}
cond_list = alloc_EXPR_LIST (0, cond, cond_list);
}
}
FOR_BB_INSNS_REVERSE (e->src, insn)
{
rtx src, dest;
rtx old = *expr;
if (!INSN_P (insn))
continue;
CLEAR_REG_SET (this_altered);
note_stores (insn, mark_altered, this_altered);
if (CALL_P (insn))
{
/* Kill all registers that might be clobbered by the call.
We don't track modes of hard registers, so we need to be
conservative and assume that partial kills are full kills. */
function_abi callee_abi = insn_callee_abi (insn);
IOR_REG_SET_HRS (this_altered,
callee_abi.full_and_partial_reg_clobbers ());
}
if (suitable_set_for_replacement (insn, &dest, &src))
{
rtx_expr_list **pnote, **pnote_next;
replace_in_expr (expr, dest, src);
if (CONSTANT_P (*expr))
goto out;
for (pnote = &cond_list; *pnote; pnote = pnote_next)
{
rtx_expr_list *note = *pnote;
rtx old_cond = XEXP (note, 0);
pnote_next = (rtx_expr_list **)&XEXP (note, 1);
replace_in_expr (&XEXP (note, 0), dest, src);
/* We can no longer use a condition that has been simplified
to a constant, and simplify_using_condition will abort if
we try. */
if (CONSTANT_P (XEXP (note, 0)))
{
*pnote = *pnote_next;
pnote_next = pnote;
free_EXPR_LIST_node (note);
}
/* Retry simplifications with this condition if either the
expression or the condition changed. */
else if (old_cond != XEXP (note, 0) || old != *expr)
simplify_using_condition (XEXP (note, 0), expr, altered);
}
}
else
{
rtx_expr_list **pnote, **pnote_next;
/* If we did not use this insn to make a replacement, any overlap
between stores in this insn and our expression will cause the
expression to become invalid. */
if (altered_reg_used (*expr, this_altered))
goto out;
/* Likewise for the conditions. */
for (pnote = &cond_list; *pnote; pnote = pnote_next)
{
rtx_expr_list *note = *pnote;
rtx old_cond = XEXP (note, 0);
pnote_next = (rtx_expr_list **)&XEXP (note, 1);
if (altered_reg_used (old_cond, this_altered))
{
*pnote = *pnote_next;
pnote_next = pnote;
free_EXPR_LIST_node (note);
}
}
}
if (CONSTANT_P (*expr))
goto out;
IOR_REG_SET (altered, this_altered);
/* If the expression now contains regs that have been altered, we
can't return it to the caller. However, it is still valid for
further simplification, so keep searching to see if we can
eventually turn it into a constant. */
if (altered_reg_used (*expr, altered))
expression_valid = false;
if (expression_valid)
last_valid_expr = *expr;
}
if (!single_pred_p (e->src)
|| single_pred (e->src) == ENTRY_BLOCK_PTR_FOR_FN (cfun))
break;
e = single_pred_edge (e->src);
}
out:
free_EXPR_LIST_list (&cond_list);
if (!CONSTANT_P (*expr))
*expr = last_valid_expr;
FREE_REG_SET (altered);
FREE_REG_SET (this_altered);
}
/* Transforms invariant IV into MODE. Adds assumptions based on the fact
that IV occurs as left operands of comparison COND and its signedness
is SIGNED_P to DESC. */
static void
shorten_into_mode (class rtx_iv *iv, scalar_int_mode mode,
enum rtx_code cond, bool signed_p, class niter_desc *desc)
{
rtx mmin, mmax, cond_over, cond_under;
get_mode_bounds (mode, signed_p, iv->extend_mode, &mmin, &mmax);
cond_under = simplify_gen_relational (LT, SImode, iv->extend_mode,
iv->base, mmin);
cond_over = simplify_gen_relational (GT, SImode, iv->extend_mode,
iv->base, mmax);
switch (cond)
{
case LE:
case LT:
case LEU:
case LTU:
if (cond_under != const0_rtx)
desc->infinite =
alloc_EXPR_LIST (0, cond_under, desc->infinite);
if (cond_over != const0_rtx)
desc->noloop_assumptions =
alloc_EXPR_LIST (0, cond_over, desc->noloop_assumptions);
break;
case GE:
case GT:
case GEU:
case GTU:
if (cond_over != const0_rtx)
desc->infinite =
alloc_EXPR_LIST (0, cond_over, desc->infinite);
if (cond_under != const0_rtx)
desc->noloop_assumptions =
alloc_EXPR_LIST (0, cond_under, desc->noloop_assumptions);
break;
case NE:
if (cond_over != const0_rtx)
desc->infinite =
alloc_EXPR_LIST (0, cond_over, desc->infinite);
if (cond_under != const0_rtx)
desc->infinite =
alloc_EXPR_LIST (0, cond_under, desc->infinite);
break;
default:
gcc_unreachable ();
}
iv->mode = mode;
iv->extend = signed_p ? IV_SIGN_EXTEND : IV_ZERO_EXTEND;
}
/* Transforms IV0 and IV1 compared by COND so that they are both compared as
subregs of the same mode if possible (sometimes it is necessary to add
some assumptions to DESC). */
static bool
canonicalize_iv_subregs (class rtx_iv *iv0, class rtx_iv *iv1,
enum rtx_code cond, class niter_desc *desc)
{
scalar_int_mode comp_mode;
bool signed_p;
/* If the ivs behave specially in the first iteration, or are
added/multiplied after extending, we ignore them. */
if (iv0->first_special || iv0->mult != const1_rtx || iv0->delta != const0_rtx)
return false;
if (iv1->first_special || iv1->mult != const1_rtx || iv1->delta != const0_rtx)
return false;
/* If there is some extend, it must match signedness of the comparison. */
switch (cond)
{
case LE:
case LT:
if (iv0->extend == IV_ZERO_EXTEND
|| iv1->extend == IV_ZERO_EXTEND)
return false;
signed_p = true;
break;
case LEU:
case LTU:
if (iv0->extend == IV_SIGN_EXTEND
|| iv1->extend == IV_SIGN_EXTEND)
return false;
signed_p = false;
break;
case NE:
if (iv0->extend != IV_UNKNOWN_EXTEND
&& iv1->extend != IV_UNKNOWN_EXTEND
&& iv0->extend != iv1->extend)
return false;
signed_p = false;
if (iv0->extend != IV_UNKNOWN_EXTEND)
signed_p = iv0->extend == IV_SIGN_EXTEND;
if (iv1->extend != IV_UNKNOWN_EXTEND)
signed_p = iv1->extend == IV_SIGN_EXTEND;
break;
default:
gcc_unreachable ();
}
/* Values of both variables should be computed in the same mode. These
might indeed be different, if we have comparison like
(compare (subreg:SI (iv0)) (subreg:SI (iv1)))
and iv0 and iv1 are both ivs iterating in SI mode, but calculated
in different modes. This does not seem impossible to handle, but
it hardly ever occurs in practice.
The only exception is the case when one of operands is invariant.
For example pentium 3 generates comparisons like
(lt (subreg:HI (reg:SI)) 100). Here we assign HImode to 100, but we
definitely do not want this prevent the optimization. */
comp_mode = iv0->extend_mode;
if (GET_MODE_BITSIZE (comp_mode) < GET_MODE_BITSIZE (iv1->extend_mode))
comp_mode = iv1->extend_mode;
if (iv0->extend_mode != comp_mode)
{
if (iv0->mode != iv0->extend_mode
|| iv0->step != const0_rtx)
return false;
iv0->base = simplify_gen_unary (signed_p ? SIGN_EXTEND : ZERO_EXTEND,
comp_mode, iv0->base, iv0->mode);
iv0->extend_mode = comp_mode;
}
if (iv1->extend_mode != comp_mode)
{
if (iv1->mode != iv1->extend_mode
|| iv1->step != const0_rtx)
return false;
iv1->base = simplify_gen_unary (signed_p ? SIGN_EXTEND : ZERO_EXTEND,
comp_mode, iv1->base, iv1->mode);
iv1->extend_mode = comp_mode;
}
/* Check that both ivs belong to a range of a single mode. If one of the
operands is an invariant, we may need to shorten it into the common
mode. */
if (iv0->mode == iv0->extend_mode
&& iv0->step == const0_rtx
&& iv0->mode != iv1->mode)
shorten_into_mode (iv0, iv1->mode, cond, signed_p, desc);
if (iv1->mode == iv1->extend_mode
&& iv1->step == const0_rtx
&& iv0->mode != iv1->mode)
shorten_into_mode (iv1, iv0->mode, swap_condition (cond), signed_p, desc);
if (iv0->mode != iv1->mode)
return false;
desc->mode = iv0->mode;
desc->signed_p = signed_p;
return true;
}
/* Tries to estimate the maximum number of iterations in LOOP, and return the
result. This function is called from iv_number_of_iterations with
a number of fields in DESC already filled in. OLD_NITER is the original
expression for the number of iterations, before we tried to simplify it. */
static uint64_t
determine_max_iter (class loop *loop, class niter_desc *desc, rtx old_niter)
{
rtx niter = desc->niter_expr;
rtx mmin, mmax, cmp;
uint64_t nmax, inc;
uint64_t andmax = 0;
/* We used to look for constant operand 0 of AND,
but canonicalization should always make this impossible. */
gcc_checking_assert (GET_CODE (niter) != AND
|| !CONST_INT_P (XEXP (niter, 0)));
if (GET_CODE (niter) == AND
&& CONST_INT_P (XEXP (niter, 1)))
{
andmax = UINTVAL (XEXP (niter, 1));
niter = XEXP (niter, 0);
}
get_mode_bounds (desc->mode, desc->signed_p, desc->mode, &mmin, &mmax);
nmax = UINTVAL (mmax) - UINTVAL (mmin);
if (GET_CODE (niter) == UDIV)
{
if (!CONST_INT_P (XEXP (niter, 1)))
return nmax;
inc = INTVAL (XEXP (niter, 1));
niter = XEXP (niter, 0);
}
else
inc = 1;
/* We could use a binary search here, but for now improving the upper
bound by just one eliminates one important corner case. */
cmp = simplify_gen_relational (desc->signed_p ? LT : LTU, VOIDmode,
desc->mode, old_niter, mmax);
simplify_using_initial_values (loop, UNKNOWN, &cmp);
if (cmp == const_true_rtx)
{
nmax--;
if (dump_file)
fprintf (dump_file, ";; improved upper bound by one.\n");
}
nmax /= inc;
if (andmax)
nmax = MIN (nmax, andmax);
if (dump_file)
fprintf (dump_file, ";; Determined upper bound %" PRId64".\n",
nmax);
return nmax;
}
/* Computes number of iterations of the CONDITION in INSN in LOOP and stores
the result into DESC. Very similar to determine_number_of_iterations
(basically its rtl version), complicated by things like subregs. */
static void
iv_number_of_iterations (class loop *loop, rtx_insn *insn, rtx condition,
class niter_desc *desc)
{
rtx op0, op1, delta, step, bound, may_xform, tmp, tmp0, tmp1;
class rtx_iv iv0, iv1;
rtx assumption, may_not_xform;
enum rtx_code cond;
machine_mode nonvoid_mode;
scalar_int_mode comp_mode;
rtx mmin, mmax, mode_mmin, mode_mmax;
uint64_t s, size, d, inv, max, up, down;
int64_t inc, step_val;
int was_sharp = false;
rtx old_niter;
bool step_is_pow2;
/* The meaning of these assumptions is this:
if !assumptions
then the rest of information does not have to be valid
if noloop_assumptions then the loop does not roll
if infinite then this exit is never used */
desc->assumptions = NULL_RTX;
desc->noloop_assumptions = NULL_RTX;
desc->infinite = NULL_RTX;
desc->simple_p = true;
desc->const_iter = false;
desc->niter_expr = NULL_RTX;
cond = GET_CODE (condition);
gcc_assert (COMPARISON_P (condition));
nonvoid_mode = GET_MODE (XEXP (condition, 0));
if (nonvoid_mode == VOIDmode)
nonvoid_mode = GET_MODE (XEXP (condition, 1));
/* The constant comparisons should be folded. */
gcc_assert (nonvoid_mode != VOIDmode);
/* We only handle integers or pointers. */
scalar_int_mode mode;
if (!is_a (nonvoid_mode, &mode))
goto fail;
op0 = XEXP (condition, 0);
if (!iv_analyze (insn, mode, op0, &iv0))
goto fail;
op1 = XEXP (condition, 1);
if (!iv_analyze (insn, mode, op1, &iv1))
goto fail;
if (GET_MODE_BITSIZE (iv0.extend_mode) > HOST_BITS_PER_WIDE_INT
|| GET_MODE_BITSIZE (iv1.extend_mode) > HOST_BITS_PER_WIDE_INT)
goto fail;
/* Check condition and normalize it. */
switch (cond)
{
case GE:
case GT:
case GEU:
case GTU:
std::swap (iv0, iv1);
cond = swap_condition (cond);
break;
case NE:
case LE:
case LEU:
case LT:
case LTU:
break;
default:
goto fail;
}
/* Handle extends. This is relatively nontrivial, so we only try in some
easy cases, when we can canonicalize the ivs (possibly by adding some
assumptions) to shape subreg (base + i * step). This function also fills
in desc->mode and desc->signed_p. */
if (!canonicalize_iv_subregs (&iv0, &iv1, cond, desc))
goto fail;
comp_mode = iv0.extend_mode;
mode = iv0.mode;
size = GET_MODE_PRECISION (mode);
get_mode_bounds (mode, (cond == LE || cond == LT), comp_mode, &mmin, &mmax);
mode_mmin = lowpart_subreg (mode, mmin, comp_mode);
mode_mmax = lowpart_subreg (mode, mmax, comp_mode);
if (!CONST_INT_P (iv0.step) || !CONST_INT_P (iv1.step))
goto fail;
/* We can take care of the case of two induction variables chasing each other
if the test is NE. I have never seen a loop using it, but still it is
cool. */
if (iv0.step != const0_rtx && iv1.step != const0_rtx)
{
if (cond != NE)
goto fail;
iv0.step = simplify_gen_binary (MINUS, comp_mode, iv0.step, iv1.step);
iv1.step = const0_rtx;
}
iv0.step = lowpart_subreg (mode, iv0.step, comp_mode);
iv1.step = lowpart_subreg (mode, iv1.step, comp_mode);
/* This is either infinite loop or the one that ends immediately, depending
on initial values. Unswitching should remove this kind of conditions. */
if (iv0.step == const0_rtx && iv1.step == const0_rtx)
goto fail;
if (cond != NE)
{
if (iv0.step == const0_rtx)
step_val = -INTVAL (iv1.step);
else
step_val = INTVAL (iv0.step);
/* Ignore loops of while (i-- < 10) type. */
if (step_val < 0)
goto fail;
step_is_pow2 = !(step_val & (step_val - 1));
}
else
{
/* We do not care about whether the step is power of two in this
case. */
step_is_pow2 = false;
step_val = 0;
}
/* Some more condition normalization. We must record some assumptions
due to overflows. */
switch (cond)
{
case LT:
case LTU:
/* We want to take care only of non-sharp relationals; this is easy,
as in cases the overflow would make the transformation unsafe
the loop does not roll. Seemingly it would make more sense to want
to take care of sharp relationals instead, as NE is more similar to
them, but the problem is that here the transformation would be more
difficult due to possibly infinite loops. */
if (iv0.step == const0_rtx)
{
tmp = lowpart_subreg (mode, iv0.base, comp_mode);
assumption = simplify_gen_relational (EQ, SImode, mode, tmp,
mode_mmax);
if (assumption == const_true_rtx)
goto zero_iter_simplify;
iv0.base = simplify_gen_binary (PLUS, comp_mode,
iv0.base, const1_rtx);
}
else
{
tmp = lowpart_subreg (mode, iv1.base, comp_mode);
assumption = simplify_gen_relational (EQ, SImode, mode, tmp,
mode_mmin);
if (assumption == const_true_rtx)
goto zero_iter_simplify;
iv1.base = simplify_gen_binary (PLUS, comp_mode,
iv1.base, constm1_rtx);
}
if (assumption != const0_rtx)
desc->noloop_assumptions =
alloc_EXPR_LIST (0, assumption, desc->noloop_assumptions);
cond = (cond == LT) ? LE : LEU;
/* It will be useful to be able to tell the difference once more in
LE -> NE reduction. */
was_sharp = true;
break;
default: ;
}
/* Take care of trivially infinite loops. */
if (cond != NE)
{
if (iv0.step == const0_rtx)
{
tmp = lowpart_subreg (mode, iv0.base, comp_mode);
if (rtx_equal_p (tmp, mode_mmin))
{
desc->infinite =
alloc_EXPR_LIST (0, const_true_rtx, NULL_RTX);
/* Fill in the remaining fields somehow. */
goto zero_iter_simplify;
}
}
else
{
tmp = lowpart_subreg (mode, iv1.base, comp_mode);
if (rtx_equal_p (tmp, mode_mmax))
{
desc->infinite =
alloc_EXPR_LIST (0, const_true_rtx, NULL_RTX);
/* Fill in the remaining fields somehow. */
goto zero_iter_simplify;
}
}
}
/* If we can we want to take care of NE conditions instead of size
comparisons, as they are much more friendly (most importantly
this takes care of special handling of loops with step 1). We can
do it if we first check that upper bound is greater or equal to
lower bound, their difference is constant c modulo step and that
there is not an overflow. */
if (cond != NE)
{
if (iv0.step == const0_rtx)
step = simplify_gen_unary (NEG, comp_mode, iv1.step, comp_mode);
else
step = iv0.step;
step = lowpart_subreg (mode, step, comp_mode);
delta = simplify_gen_binary (MINUS, comp_mode, iv1.base, iv0.base);
delta = lowpart_subreg (mode, delta, comp_mode);
delta = simplify_gen_binary (UMOD, mode, delta, step);
may_xform = const0_rtx;
may_not_xform = const_true_rtx;
if (CONST_INT_P (delta))
{
if (was_sharp && INTVAL (delta) == INTVAL (step) - 1)
{
/* A special case. We have transformed condition of type
for (i = 0; i < 4; i += 4)
into
for (i = 0; i <= 3; i += 4)
obviously if the test for overflow during that transformation
passed, we cannot overflow here. Most importantly any
loop with sharp end condition and step 1 falls into this
category, so handling this case specially is definitely
worth the troubles. */
may_xform = const_true_rtx;
}
else if (iv0.step == const0_rtx)
{
bound = simplify_gen_binary (PLUS, comp_mode, mmin, step);
bound = simplify_gen_binary (MINUS, comp_mode, bound, delta);
bound = lowpart_subreg (mode, bound, comp_mode);
tmp = lowpart_subreg (mode, iv0.base, comp_mode);
may_xform = simplify_gen_relational (cond, SImode, mode,
bound, tmp);
may_not_xform = simplify_gen_relational (reverse_condition (cond),
SImode, mode,
bound, tmp);
}
else
{
bound = simplify_gen_binary (MINUS, comp_mode, mmax, step);
bound = simplify_gen_binary (PLUS, comp_mode, bound, delta);
bound = lowpart_subreg (mode, bound, comp_mode);
tmp = lowpart_subreg (mode, iv1.base, comp_mode);
may_xform = simplify_gen_relational (cond, SImode, mode,
tmp, bound);
may_not_xform = simplify_gen_relational (reverse_condition (cond),
SImode, mode,
tmp, bound);
}
}
if (may_xform != const0_rtx)
{
/* We perform the transformation always provided that it is not
completely senseless. This is OK, as we would need this assumption
to determine the number of iterations anyway. */
if (may_xform != const_true_rtx)
{
/* If the step is a power of two and the final value we have
computed overflows, the cycle is infinite. Otherwise it
is nontrivial to compute the number of iterations. */
if (step_is_pow2)
desc->infinite = alloc_EXPR_LIST (0, may_not_xform,
desc->infinite);
else
desc->assumptions = alloc_EXPR_LIST (0, may_xform,
desc->assumptions);
}
/* We are going to lose some information about upper bound on
number of iterations in this step, so record the information
here. */
inc = INTVAL (iv0.step) - INTVAL (iv1.step);
if (CONST_INT_P (iv1.base))
up = INTVAL (iv1.base);
else
up = INTVAL (mode_mmax) - inc;
down = INTVAL (CONST_INT_P (iv0.base)
? iv0.base
: mode_mmin);
max = (up - down) / inc + 1;
if (!desc->infinite
&& !desc->assumptions)
record_niter_bound (loop, max, false, true);
if (iv0.step == const0_rtx)
{
iv0.base = simplify_gen_binary (PLUS, comp_mode, iv0.base, delta);
iv0.base = simplify_gen_binary (MINUS, comp_mode, iv0.base, step);
}
else
{
iv1.base = simplify_gen_binary (MINUS, comp_mode, iv1.base, delta);
iv1.base = simplify_gen_binary (PLUS, comp_mode, iv1.base, step);
}
tmp0 = lowpart_subreg (mode, iv0.base, comp_mode);
tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
assumption = simplify_gen_relational (reverse_condition (cond),
SImode, mode, tmp0, tmp1);
if (assumption == const_true_rtx)
goto zero_iter_simplify;
else if (assumption != const0_rtx)
desc->noloop_assumptions =
alloc_EXPR_LIST (0, assumption, desc->noloop_assumptions);
cond = NE;
}
}
/* Count the number of iterations. */
if (cond == NE)
{
/* Everything we do here is just arithmetics modulo size of mode. This
makes us able to do more involved computations of number of iterations
than in other cases. First transform the condition into shape
s * i <> c, with s positive. */
iv1.base = simplify_gen_binary (MINUS, comp_mode, iv1.base, iv0.base);
iv0.base = const0_rtx;
iv0.step = simplify_gen_binary (MINUS, comp_mode, iv0.step, iv1.step);
iv1.step = const0_rtx;
if (INTVAL (iv0.step) < 0)
{
iv0.step = simplify_gen_unary (NEG, comp_mode, iv0.step, comp_mode);
iv1.base = simplify_gen_unary (NEG, comp_mode, iv1.base, comp_mode);
}
iv0.step = lowpart_subreg (mode, iv0.step, comp_mode);
/* Let nsd (s, size of mode) = d. If d does not divide c, the loop
is infinite. Otherwise, the number of iterations is
(inverse(s/d) * (c/d)) mod (size of mode/d). */
s = INTVAL (iv0.step); d = 1;
while (s % 2 != 1)
{
s /= 2;
d *= 2;
size--;
}
bound = GEN_INT (((uint64_t) 1 << (size - 1 ) << 1) - 1);
tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
tmp = simplify_gen_binary (UMOD, mode, tmp1, gen_int_mode (d, mode));
assumption = simplify_gen_relational (NE, SImode, mode, tmp, const0_rtx);
desc->infinite = alloc_EXPR_LIST (0, assumption, desc->infinite);
tmp = simplify_gen_binary (UDIV, mode, tmp1, gen_int_mode (d, mode));
inv = inverse (s, size);
tmp = simplify_gen_binary (MULT, mode, tmp, gen_int_mode (inv, mode));
desc->niter_expr = simplify_gen_binary (AND, mode, tmp, bound);
}
else
{
if (iv1.step == const0_rtx)
/* Condition in shape a + s * i <= b
We must know that b + s does not overflow and a <= b + s and then we
can compute number of iterations as (b + s - a) / s. (It might
seem that we in fact could be more clever about testing the b + s
overflow condition using some information about b - a mod s,
but it was already taken into account during LE -> NE transform). */
{
step = iv0.step;
tmp0 = lowpart_subreg (mode, iv0.base, comp_mode);
tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
bound = simplify_gen_binary (MINUS, mode, mode_mmax,
lowpart_subreg (mode, step,
comp_mode));
if (step_is_pow2)
{
rtx t0, t1;
/* If s is power of 2, we know that the loop is infinite if
a % s <= b % s and b + s overflows. */
assumption = simplify_gen_relational (reverse_condition (cond),
SImode, mode,
tmp1, bound);
t0 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp0), step);
t1 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp1), step);
tmp = simplify_gen_relational (cond, SImode, mode, t0, t1);
assumption = simplify_gen_binary (AND, SImode, assumption, tmp);
desc->infinite =
alloc_EXPR_LIST (0, assumption, desc->infinite);
}
else
{
assumption = simplify_gen_relational (cond, SImode, mode,
tmp1, bound);
desc->assumptions =
alloc_EXPR_LIST (0, assumption, desc->assumptions);
}
tmp = simplify_gen_binary (PLUS, comp_mode, iv1.base, iv0.step);
tmp = lowpart_subreg (mode, tmp, comp_mode);
assumption = simplify_gen_relational (reverse_condition (cond),
SImode, mode, tmp0, tmp);
delta = simplify_gen_binary (PLUS, mode, tmp1, step);
delta = simplify_gen_binary (MINUS, mode, delta, tmp0);
}
else
{
/* Condition in shape a <= b - s * i
We must know that a - s does not overflow and a - s <= b and then
we can again compute number of iterations as (b - (a - s)) / s. */
step = simplify_gen_unary (NEG, mode, iv1.step, mode);
tmp0 = lowpart_subreg (mode, iv0.base, comp_mode);
tmp1 = lowpart_subreg (mode, iv1.base, comp_mode);
bound = simplify_gen_binary (PLUS, mode, mode_mmin,
lowpart_subreg (mode, step, comp_mode));
if (step_is_pow2)
{
rtx t0, t1;
/* If s is power of 2, we know that the loop is infinite if
a % s <= b % s and a - s overflows. */
assumption = simplify_gen_relational (reverse_condition (cond),
SImode, mode,
bound, tmp0);
t0 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp0), step);
t1 = simplify_gen_binary (UMOD, mode, copy_rtx (tmp1), step);
tmp = simplify_gen_relational (cond, SImode, mode, t0, t1);
assumption = simplify_gen_binary (AND, SImode, assumption, tmp);
desc->infinite =
alloc_EXPR_LIST (0, assumption, desc->infinite);
}
else
{
assumption = simplify_gen_relational (cond, SImode, mode,
bound, tmp0);
desc->assumptions =
alloc_EXPR_LIST (0, assumption, desc->assumptions);
}
tmp = simplify_gen_binary (PLUS, comp_mode, iv0.base, iv1.step);
tmp = lowpart_subreg (mode, tmp, comp_mode);
assumption = simplify_gen_relational (reverse_condition (cond),
SImode, mode,
tmp, tmp1);
delta = simplify_gen_binary (MINUS, mode, tmp0, step);
delta = simplify_gen_binary (MINUS, mode, tmp1, delta);
}
if (assumption == const_true_rtx)
goto zero_iter_simplify;
else if (assumption != const0_rtx)
desc->noloop_assumptions =
alloc_EXPR_LIST (0, assumption, desc->noloop_assumptions);
delta = simplify_gen_binary (UDIV, mode, delta, step);
desc->niter_expr = delta;
}
old_niter = desc->niter_expr;
simplify_using_initial_values (loop, AND, &desc->assumptions);
if (desc->assumptions
&& XEXP (desc->assumptions, 0) == const0_rtx)
goto fail;
simplify_using_initial_values (loop, IOR, &desc->noloop_assumptions);
simplify_using_initial_values (loop, IOR, &desc->infinite);
simplify_using_initial_values (loop, UNKNOWN, &desc->niter_expr);
/* Rerun the simplification. Consider code (created by copying loop headers)
i = 0;
if (0 < n)
{
do
{
i++;
} while (i < n);
}
The first pass determines that i = 0, the second pass uses it to eliminate
noloop assumption. */
simplify_using_initial_values (loop, AND, &desc->assumptions);
if (desc->assumptions
&& XEXP (desc->assumptions, 0) == const0_rtx)
goto fail;
simplify_using_initial_values (loop, IOR, &desc->noloop_assumptions);
simplify_using_initial_values (loop, IOR, &desc->infinite);
simplify_using_initial_values (loop, UNKNOWN, &desc->niter_expr);
if (desc->noloop_assumptions
&& XEXP (desc->noloop_assumptions, 0) == const_true_rtx)
goto zero_iter;
if (CONST_INT_P (desc->niter_expr))
{
uint64_t val = INTVAL (desc->niter_expr);
desc->const_iter = true;
desc->niter = val & GET_MODE_MASK (desc->mode);
if (!desc->infinite
&& !desc->assumptions)
record_niter_bound (loop, desc->niter, false, true);
}
else
{
max = determine_max_iter (loop, desc, old_niter);
if (!max)
goto zero_iter_simplify;
if (!desc->infinite
&& !desc->assumptions)
record_niter_bound (loop, max, false, true);
/* simplify_using_initial_values does a copy propagation on the registers
in the expression for the number of iterations. This prolongs life
ranges of registers and increases register pressure, and usually
brings no gain (and if it happens to do, the cse pass will take care
of it anyway). So prevent this behavior, unless it enabled us to
derive that the number of iterations is a constant. */
desc->niter_expr = old_niter;
}
return;
zero_iter_simplify:
/* Simplify the assumptions. */
simplify_using_initial_values (loop, AND, &desc->assumptions);
if (desc->assumptions
&& XEXP (desc->assumptions, 0) == const0_rtx)
goto fail;
simplify_using_initial_values (loop, IOR, &desc->infinite);
/* Fallthru. */
zero_iter:
desc->const_iter = true;
desc->niter = 0;
record_niter_bound (loop, 0, true, true);
desc->noloop_assumptions = NULL_RTX;
desc->niter_expr = const0_rtx;
return;
fail:
desc->simple_p = false;
return;
}
/* Checks whether E is a simple exit from LOOP and stores its description
into DESC. */
static void
check_simple_exit (class loop *loop, edge e, class niter_desc *desc)
{
basic_block exit_bb;
rtx condition;
rtx_insn *at;
edge ein;
exit_bb = e->src;
desc->simple_p = false;
/* It must belong directly to the loop. */
if (exit_bb->loop_father != loop)
return;
/* It must be tested (at least) once during any iteration. */
if (!dominated_by_p (CDI_DOMINATORS, loop->latch, exit_bb))
return;
/* It must end in a simple conditional jump. */
if (!any_condjump_p (BB_END (exit_bb)))
return;
ein = EDGE_SUCC (exit_bb, 0);
if (ein == e)
ein = EDGE_SUCC (exit_bb, 1);
desc->out_edge = e;
desc->in_edge = ein;
/* Test whether the condition is suitable. */
if (!(condition = get_condition (BB_END (ein->src), &at, false, false)))
return;
if (ein->flags & EDGE_FALLTHRU)
{
condition = reversed_condition (condition);
if (!condition)
return;
}
/* Check that we are able to determine number of iterations and fill
in information about it. */
iv_number_of_iterations (loop, at, condition, desc);
}
/* Finds a simple exit of LOOP and stores its description into DESC. */
static void
find_simple_exit (class loop *loop, class niter_desc *desc)
{
unsigned i;
basic_block *body;
edge e;
class niter_desc act;
bool any = false;
edge_iterator ei;
desc->simple_p = false;
body = get_loop_body (loop);
for (i = 0; i < loop->num_nodes; i++)
{
FOR_EACH_EDGE (e, ei, body[i]->succs)
{
if (flow_bb_inside_loop_p (loop, e->dest))
continue;
check_simple_exit (loop, e, &act);
if (!act.simple_p)
continue;
if (!any)
any = true;
else
{
/* Prefer constant iterations; the less the better. */
if (!act.const_iter
|| (desc->const_iter && act.niter >= desc->niter))
continue;
/* Also if the actual exit may be infinite, while the old one
not, prefer the old one. */
if (act.infinite && !desc->infinite)
continue;
}
*desc = act;
}
}
if (dump_file)
{
if (desc->simple_p)
{
fprintf (dump_file, "Loop %d is simple:\n", loop->num);
fprintf (dump_file, " simple exit %d -> %d\n",
desc->out_edge->src->index,
desc->out_edge->dest->index);
if (desc->assumptions)
{
fprintf (dump_file, " assumptions: ");
print_rtl (dump_file, desc->assumptions);
fprintf (dump_file, "\n");
}
if (desc->noloop_assumptions)
{
fprintf (dump_file, " does not roll if: ");
print_rtl (dump_file, desc->noloop_assumptions);
fprintf (dump_file, "\n");
}
if (desc->infinite)
{
fprintf (dump_file, " infinite if: ");
print_rtl (dump_file, desc->infinite);
fprintf (dump_file, "\n");
}
fprintf (dump_file, " number of iterations: ");
print_rtl (dump_file, desc->niter_expr);
fprintf (dump_file, "\n");
fprintf (dump_file, " upper bound: %li\n",
(long)get_max_loop_iterations_int (loop));
fprintf (dump_file, " likely upper bound: %li\n",
(long)get_likely_max_loop_iterations_int (loop));
fprintf (dump_file, " realistic bound: %li\n",
(long)get_estimated_loop_iterations_int (loop));
}
else
fprintf (dump_file, "Loop %d is not simple.\n", loop->num);
}
/* Fix up the finiteness if possible. We can only do it for single exit,
since the loop is finite, but it's possible that we predicate one loop
exit to be finite which can not be determined as finite in middle-end as
well. It results in incorrect predicate information on the exit condition
expression. For example, if says [(int) _1 + -8, + , -8] != 0 finite,
it means _1 can exactly divide -8. */
if (desc->infinite && single_exit (loop) && finite_loop_p (loop))
{
desc->infinite = NULL_RTX;
if (dump_file)
fprintf (dump_file, " infinite updated to finite.\n");
}
free (body);
}
/* Creates a simple loop description of LOOP if it was not computed
already. */
class niter_desc *
get_simple_loop_desc (class loop *loop)
{
class niter_desc *desc = simple_loop_desc (loop);
if (desc)
return desc;
/* At least desc->infinite is not always initialized by
find_simple_loop_exit. */
desc = ggc_cleared_alloc ();
iv_analysis_loop_init (loop);
find_simple_exit (loop, desc);
loop->simple_loop_desc = desc;
return desc;
}
/* Releases simple loop description for LOOP. */
void
free_simple_loop_desc (class loop *loop)
{
class niter_desc *desc = simple_loop_desc (loop);
if (!desc)
return;
ggc_free (desc);
loop->simple_loop_desc = NULL;
}