cfg.c (free_edge): Add function argument and use it instead of cfun.

[thirdparty/gcc.git] / gcc / cfgloop.h

/* Natural loop functions
   Copyright (C) 1987-2015 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/>.  */

#ifndef GCC_CFGLOOP_H
#define GCC_CFGLOOP_H

#include "cfgloopmanip.h"

/* Structure to hold decision about unrolling/peeling.  */
enum lpt_dec
{
  LPT_NONE,
  LPT_UNROLL_CONSTANT,
  LPT_UNROLL_RUNTIME,
  LPT_UNROLL_STUPID
};

struct GTY (()) lpt_decision {
  enum lpt_dec decision;
  unsigned times;
};

/* The type of extend applied to an IV.  */
enum iv_extend_code
{
  IV_SIGN_EXTEND,
  IV_ZERO_EXTEND,
  IV_UNKNOWN_EXTEND
};

/* The structure describing a bound on number of iterations of a loop.  */

struct GTY ((chain_next ("%h.next"))) nb_iter_bound {
  /* The statement STMT is executed at most ...  */
  gimple *stmt;

  /* ... BOUND + 1 times (BOUND must be an unsigned constant).
     The + 1 is added for the following reasons:

     a) 0 would otherwise be unused, while we would need to care more about
        overflows (as MAX + 1 is sometimes produced as the estimate on number
        of executions of STMT).
     b) it is consistent with the result of number_of_iterations_exit.  */
  widest_int bound;

  /* True if the statement will cause the loop to be leaved the (at most)
     BOUND + 1-st time it is executed, that is, all the statements after it
     are executed at most BOUND times.  */
  bool is_exit;

  /* The next bound in the list.  */
  struct nb_iter_bound *next;
};

/* Description of the loop exit.  */

struct GTY ((for_user)) loop_exit {
  /* The exit edge.  */
  edge e;

  /* Previous and next exit in the list of the exits of the loop.  */
  struct loop_exit *prev;
  struct loop_exit *next;

  /* Next element in the list of loops from that E exits.  */
  struct loop_exit *next_e;
};

struct loop_exit_hasher : ggc_ptr_hash<loop_exit>
{
  typedef edge compare_type;

  static hashval_t hash (loop_exit *);
  static bool equal (loop_exit *, edge);
  static void remove (loop_exit *);
};

typedef struct loop *loop_p;

/* An integer estimation of the number of iterations.  Estimate_state
   describes what is the state of the estimation.  */
enum loop_estimation
{
  /* Estimate was not computed yet.  */
  EST_NOT_COMPUTED,
  /* Estimate is ready.  */
  EST_AVAILABLE,
  EST_LAST
};

/* The structure describing non-overflow control induction variable for
   loop's exit edge.  */
struct GTY ((chain_next ("%h.next"))) control_iv {
  tree base;
  tree step;
  struct control_iv *next;
};

/* Structure to hold information for each natural loop.  */
struct GTY ((chain_next ("%h.next"))) loop {
  /* Index into loops array.  */
  int num;

  /* Number of loop insns.  */
  unsigned ninsns;

  /* Basic block of loop header.  */
  basic_block header;

  /* Basic block of loop latch.  */
  basic_block latch;

  /* For loop unrolling/peeling decision.  */
  struct lpt_decision lpt_decision;

  /* Average number of executed insns per iteration.  */
  unsigned av_ninsns;

  /* Number of blocks contained within the loop.  */
  unsigned num_nodes;

  /* Superloops of the loop, starting with the outermost loop.  */
  vec<loop_p, va_gc> *superloops;

  /* The first inner (child) loop or NULL if innermost loop.  */
  struct loop *inner;

  /* Link to the next (sibling) loop.  */
  struct loop *next;

  /* Auxiliary info specific to a pass.  */
  PTR GTY ((skip (""))) aux;

  /* The number of times the latch of the loop is executed.  This can be an
     INTEGER_CST, or a symbolic expression representing the number of
     iterations like "N - 1", or a COND_EXPR containing the runtime
     conditions under which the number of iterations is non zero.

     Don't access this field directly: number_of_latch_executions
     computes and caches the computed information in this field.  */
  tree nb_iterations;

  /* An integer guaranteed to be greater or equal to nb_iterations.  Only
     valid if any_upper_bound is true.  */
  widest_int nb_iterations_upper_bound;

  /* An integer giving an estimate on nb_iterations.  Unlike
     nb_iterations_upper_bound, there is no guarantee that it is at least
     nb_iterations.  */
  widest_int nb_iterations_estimate;

  bool any_upper_bound;
  bool any_estimate;

  /* True if the loop can be parallel.  */
  bool can_be_parallel;

  /* True if -Waggressive-loop-optimizations warned about this loop
     already.  */
  bool warned_aggressive_loop_optimizations;

  /* An integer estimation of the number of iterations.  Estimate_state
     describes what is the state of the estimation.  */
  enum loop_estimation estimate_state;

  /* If > 0, an integer, where the user asserted that for any
     I in [ 0, nb_iterations ) and for any J in
     [ I, min ( I + safelen, nb_iterations ) ), the Ith and Jth iterations
     of the loop can be safely evaluated concurrently.  */
  int safelen;

  /* True if this loop should never be vectorized.  */
  bool dont_vectorize;

  /* True if we should try harder to vectorize this loop.  */
  bool force_vectorize;

  /* For SIMD loops, this is a unique identifier of the loop, referenced
     by IFN_GOMP_SIMD_VF, IFN_GOMP_SIMD_LANE and IFN_GOMP_SIMD_LAST_LANE
     builtins.  */
  tree simduid;

  /* Upper bound on number of iterations of a loop.  */
  struct nb_iter_bound *bounds;

  /* Non-overflow control ivs of a loop.  */
  struct control_iv *control_ivs;

  /* Head of the cyclic list of the exits of the loop.  */
  struct loop_exit *exits;

  /* Number of iteration analysis data for RTL.  */
  struct niter_desc *simple_loop_desc;

  /* For sanity checking during loop fixup we record here the former
     loop header for loops marked for removal.  Note that this prevents
     the basic-block from being collected but its index can still be
     reused.  */
  basic_block former_header;
};

/* Flags for state of loop structure.  */
enum
{
  LOOPS_HAVE_PREHEADERS = 1,
  LOOPS_HAVE_SIMPLE_LATCHES = 2,
  LOOPS_HAVE_MARKED_IRREDUCIBLE_REGIONS = 4,
  LOOPS_HAVE_RECORDED_EXITS = 8,
  LOOPS_MAY_HAVE_MULTIPLE_LATCHES = 16,
  LOOP_CLOSED_SSA = 32,
  LOOPS_NEED_FIXUP = 64,
  LOOPS_HAVE_FALLTHRU_PREHEADERS = 128
};

#define LOOPS_NORMAL (LOOPS_HAVE_PREHEADERS | LOOPS_HAVE_SIMPLE_LATCHES \
                      | LOOPS_HAVE_MARKED_IRREDUCIBLE_REGIONS)
#define AVOID_CFG_MODIFICATIONS (LOOPS_MAY_HAVE_MULTIPLE_LATCHES)

/* Structure to hold CFG information about natural loops within a function.  */
struct GTY (()) loops {
  /* State of loops.  */
  int state;

  /* Array of the loops.  */
  vec<loop_p, va_gc> *larray;

  /* Maps edges to the list of their descriptions as loop exits.  Edges
     whose sources or destinations have loop_father == NULL (which may
     happen during the cfg manipulations) should not appear in EXITS.  */
  hash_table<loop_exit_hasher> *GTY(()) exits;

  /* Pointer to root of loop hierarchy tree.  */
  struct loop *tree_root;
};

/* Loop recognition.  */
bool bb_loop_header_p (basic_block);
void init_loops_structure (struct function *, struct loops *, unsigned);
extern struct loops *flow_loops_find (struct loops *);
extern void disambiguate_loops_with_multiple_latches (void);
extern void flow_loops_free (struct loops *);
extern void flow_loops_dump (FILE *,
                             void (*)(const struct loop *, FILE *, int), int);
extern void flow_loop_dump (const struct loop *, FILE *,
                            void (*)(const struct loop *, FILE *, int), int);
struct loop *alloc_loop (void);
extern void flow_loop_free (struct loop *);
int flow_loop_nodes_find (basic_block, struct loop *);
unsigned fix_loop_structure (bitmap changed_bbs);
bool mark_irreducible_loops (void);
void release_recorded_exits (function *);
void record_loop_exits (void);
void rescan_loop_exit (edge, bool, bool);

/* Loop data structure manipulation/querying.  */
extern void flow_loop_tree_node_add (struct loop *, struct loop *);
extern void flow_loop_tree_node_remove (struct loop *);
extern bool flow_loop_nested_p  (const struct loop *, const struct loop *);
extern bool flow_bb_inside_loop_p (const struct loop *, const_basic_block);
extern struct loop * find_common_loop (struct loop *, struct loop *);
struct loop *superloop_at_depth (struct loop *, unsigned);
struct eni_weights;
extern int num_loop_insns (const struct loop *);
extern int average_num_loop_insns (const struct loop *);
extern unsigned get_loop_level (const struct loop *);
extern bool loop_exit_edge_p (const struct loop *, const_edge);
extern bool loop_exits_to_bb_p (struct loop *, basic_block);
extern bool loop_exits_from_bb_p (struct loop *, basic_block);
extern void mark_loop_exit_edges (void);
extern location_t get_loop_location (struct loop *loop);

/* Loops & cfg manipulation.  */
extern basic_block *get_loop_body (const struct loop *);
extern unsigned get_loop_body_with_size (const struct loop *, basic_block *,
                                         unsigned);
extern basic_block *get_loop_body_in_dom_order (const struct loop *);
extern basic_block *get_loop_body_in_bfs_order (const struct loop *);
extern basic_block *get_loop_body_in_custom_order (const struct loop *,
                               int (*) (const void *, const void *));

extern vec<edge> get_loop_exit_edges (const struct loop *);
extern edge single_exit (const struct loop *);
extern edge single_likely_exit (struct loop *loop);
extern unsigned num_loop_branches (const struct loop *);

extern edge loop_preheader_edge (const struct loop *);
extern edge loop_latch_edge (const struct loop *);

extern void add_bb_to_loop (basic_block, struct loop *);
extern void remove_bb_from_loops (basic_block);

extern void cancel_loop_tree (struct loop *);
extern void delete_loop (struct loop *);


extern void verify_loop_structure (void);

/* Loop analysis.  */
extern bool just_once_each_iteration_p (const struct loop *, const_basic_block);
gcov_type expected_loop_iterations_unbounded (const struct loop *);
extern unsigned expected_loop_iterations (const struct loop *);
extern rtx doloop_condition_get (rtx);

void mark_loop_for_removal (loop_p);

/* Induction variable analysis.  */

/* The description of induction variable.  The things are a bit complicated
   due to need to handle subregs and extends.  The value of the object described
   by it can be obtained as follows (all computations are done in extend_mode):

   Value in i-th iteration is
     delta + mult * extend_{extend_mode} (subreg_{mode} (base + i * step)).

   If first_special is true, the value in the first iteration is
     delta + mult * base

   If extend = UNKNOWN, first_special must be false, delta 0, mult 1 and value is
     subreg_{mode} (base + i * step)

   The get_iv_value function can be used to obtain these expressions.

   ??? Add a third mode field that would specify the mode in that inner
   computation is done, which would enable it to be different from the
   outer one?  */

struct rtx_iv
{
  /* Its base and step (mode of base and step is supposed to be extend_mode,
     see the description above).  */
  rtx base, step;

  /* The type of extend applied to it (IV_SIGN_EXTEND, IV_ZERO_EXTEND,
     or IV_UNKNOWN_EXTEND).  */
  enum iv_extend_code extend;

  /* Operations applied in the extended mode.  */
  rtx delta, mult;

  /* The mode it is extended to.  */
  machine_mode extend_mode;

  /* The mode the variable iterates in.  */
  machine_mode mode;

  /* Whether the first iteration needs to be handled specially.  */
  unsigned first_special : 1;
};

/* The description of an exit from the loop and of the number of iterations
   till we take the exit.  */

struct GTY(()) niter_desc
{
  /* The edge out of the loop.  */
  edge out_edge;

  /* The other edge leading from the condition.  */
  edge in_edge;

  /* True if we are able to say anything about number of iterations of the
     loop.  */
  bool simple_p;

  /* True if the loop iterates the constant number of times.  */
  bool const_iter;

  /* Number of iterations if constant.  */
  uint64_t niter;

  /* Assumptions under that the rest of the information is valid.  */
  rtx assumptions;

  /* Assumptions under that the loop ends before reaching the latch,
     even if value of niter_expr says otherwise.  */
  rtx noloop_assumptions;

  /* Condition under that the loop is infinite.  */
  rtx infinite;

  /* Whether the comparison is signed.  */
  bool signed_p;

  /* The mode in that niter_expr should be computed.  */
  machine_mode mode;

  /* The number of iterations of the loop.  */
  rtx niter_expr;
};

extern void iv_analysis_loop_init (struct loop *);
extern bool iv_analyze (rtx_insn *, rtx, struct rtx_iv *);
extern bool iv_analyze_result (rtx_insn *, rtx, struct rtx_iv *);
extern bool iv_analyze_expr (rtx_insn *, rtx, machine_mode,
                             struct rtx_iv *);
extern rtx get_iv_value (struct rtx_iv *, rtx);
extern bool biv_p (rtx_insn *, rtx);
extern void find_simple_exit (struct loop *, struct niter_desc *);
extern void iv_analysis_done (void);

extern struct niter_desc *get_simple_loop_desc (struct loop *loop);
extern void free_simple_loop_desc (struct loop *loop);

static inline struct niter_desc *
simple_loop_desc (struct loop *loop)
{
  return loop->simple_loop_desc;
}

/* Accessors for the loop structures.  */

/* Returns the loop with index NUM from FNs loop tree.  */

static inline struct loop *
get_loop (struct function *fn, unsigned num)
{
  return (*loops_for_fn (fn)->larray)[num];
}

/* Returns the number of superloops of LOOP.  */

static inline unsigned
loop_depth (const struct loop *loop)
{
  return vec_safe_length (loop->superloops);
}

/* Returns the immediate superloop of LOOP, or NULL if LOOP is the outermost
   loop.  */

static inline struct loop *
loop_outer (const struct loop *loop)
{
  unsigned n = vec_safe_length (loop->superloops);

  if (n == 0)
    return NULL;

  return (*loop->superloops)[n - 1];
}

/* Returns true if LOOP has at least one exit edge.  */

static inline bool
loop_has_exit_edges (const struct loop *loop)
{
  return loop->exits->next->e != NULL;
}

/* Returns the list of loops in FN.  */

inline vec<loop_p, va_gc> *
get_loops (struct function *fn)
{
  struct loops *loops = loops_for_fn (fn);
  if (!loops)
    return NULL;

  return loops->larray;
}

/* Returns the number of loops in FN (including the removed
   ones and the fake loop that forms the root of the loop tree).  */

static inline unsigned
number_of_loops (struct function *fn)
{
  struct loops *loops = loops_for_fn (fn);
  if (!loops)
    return 0;

  return vec_safe_length (loops->larray);
}

/* Returns true if state of the loops satisfies all properties
   described by FLAGS.  */

static inline bool
loops_state_satisfies_p (function *fn, unsigned flags)
{
  return (loops_for_fn (fn)->state & flags) == flags;
}

static inline bool
loops_state_satisfies_p (unsigned flags)
{
  return loops_state_satisfies_p (cfun, flags);
}

/* Sets FLAGS to the loops state.  */

static inline void
loops_state_set (function *fn, unsigned flags)
{
  loops_for_fn (fn)->state |= flags;
}

static inline void
loops_state_set (unsigned flags)
{
  loops_state_set (cfun, flags);
}

/* Clears FLAGS from the loops state.  */

static inline void
loops_state_clear (function *fn, unsigned flags)
{
  loops_for_fn (fn)->state &= ~flags;
}

static inline void
loops_state_clear (unsigned flags)
{
  if (!current_loops)
    return;
  loops_state_clear (cfun, flags);
}

/* Loop iterators.  */

/* Flags for loop iteration.  */

enum li_flags
{
  LI_INCLUDE_ROOT = 1,          /* Include the fake root of the loop tree.  */
  LI_FROM_INNERMOST = 2,        /* Iterate over the loops in the reverse order,
                                   starting from innermost ones.  */
  LI_ONLY_INNERMOST = 4         /* Iterate only over innermost loops.  */
};

/* The iterator for loops.  */

struct loop_iterator
{
  loop_iterator (function *fn, loop_p *loop, unsigned flags);
  ~loop_iterator ();

  inline loop_p next ();

  /* The function we are visiting.  */
  function *fn;

  /* The list of loops to visit.  */
  vec<int> to_visit;

  /* The index of the actual loop.  */
  unsigned idx;
};

inline loop_p
loop_iterator::next ()
{
  int anum;

  while (this->to_visit.iterate (this->idx, &anum))
    {
      this->idx++;
      loop_p loop = get_loop (fn, anum);
      if (loop)
        return loop;
    }

  return NULL;
}

inline
loop_iterator::loop_iterator (function *fn, loop_p *loop, unsigned flags)
{
  struct loop *aloop;
  unsigned i;
  int mn;

  this->idx = 0;
  this->fn = fn;
  if (!loops_for_fn (fn))
    {
      this->to_visit.create (0);
      *loop = NULL;
      return;
    }

  this->to_visit.create (number_of_loops (fn));
  mn = (flags & LI_INCLUDE_ROOT) ? 0 : 1;

  if (flags & LI_ONLY_INNERMOST)
    {
      for (i = 0; vec_safe_iterate (loops_for_fn (fn)->larray, i, &aloop); i++)
        if (aloop != NULL
            && aloop->inner == NULL
            && aloop->num >= mn)
          this->to_visit.quick_push (aloop->num);
    }
  else if (flags & LI_FROM_INNERMOST)
    {
      /* Push the loops to LI->TO_VISIT in postorder.  */
      for (aloop = loops_for_fn (fn)->tree_root;
           aloop->inner != NULL;
           aloop = aloop->inner)
        continue;

      while (1)
        {
          if (aloop->num >= mn)
            this->to_visit.quick_push (aloop->num);

          if (aloop->next)
            {
              for (aloop = aloop->next;
                   aloop->inner != NULL;
                   aloop = aloop->inner)
                continue;
            }
          else if (!loop_outer (aloop))
            break;
          else
            aloop = loop_outer (aloop);
        }
    }
  else
    {
      /* Push the loops to LI->TO_VISIT in preorder.  */
      aloop = loops_for_fn (fn)->tree_root;
      while (1)
        {
          if (aloop->num >= mn)
            this->to_visit.quick_push (aloop->num);

          if (aloop->inner != NULL)
            aloop = aloop->inner;
          else
            {
              while (aloop != NULL && aloop->next == NULL)
                aloop = loop_outer (aloop);
              if (aloop == NULL)
                break;
              aloop = aloop->next;
            }
        }
    }

  *loop = this->next ();
}

inline
loop_iterator::~loop_iterator ()
{
  this->to_visit.release ();
}

#define FOR_EACH_LOOP(LOOP, FLAGS) \
  for (loop_iterator li(cfun, &(LOOP), FLAGS); \
       (LOOP); \
       (LOOP) = li.next ())

#define FOR_EACH_LOOP_FN(FN, LOOP, FLAGS) \
  for (loop_iterator li(fn, &(LOOP), FLAGS); \
       (LOOP); \
       (LOOP) = li.next ())

/* The properties of the target.  */
struct target_cfgloop {
  /* Number of available registers.  */
  unsigned x_target_avail_regs;

  /* Number of available registers that are call-clobbered.  */
  unsigned x_target_clobbered_regs;

  /* Number of registers reserved for temporary expressions.  */
  unsigned x_target_res_regs;

  /* The cost for register when there still is some reserve, but we are
     approaching the number of available registers.  */
  unsigned x_target_reg_cost[2];

  /* The cost for register when we need to spill.  */
  unsigned x_target_spill_cost[2];
};

extern struct target_cfgloop default_target_cfgloop;
#if SWITCHABLE_TARGET
extern struct target_cfgloop *this_target_cfgloop;
#else
#define this_target_cfgloop (&default_target_cfgloop)
#endif

#define target_avail_regs \
  (this_target_cfgloop->x_target_avail_regs)
#define target_clobbered_regs \
  (this_target_cfgloop->x_target_clobbered_regs)
#define target_res_regs \
  (this_target_cfgloop->x_target_res_regs)
#define target_reg_cost \
  (this_target_cfgloop->x_target_reg_cost)
#define target_spill_cost \
  (this_target_cfgloop->x_target_spill_cost)

/* Register pressure estimation for induction variable optimizations & loop
   invariant motion.  */
extern unsigned estimate_reg_pressure_cost (unsigned, unsigned, bool, bool);
extern void init_set_costs (void);

/* Loop optimizer initialization.  */
extern void loop_optimizer_init (unsigned);
extern void loop_optimizer_finalize (function *);
inline void
loop_optimizer_finalize ()
{
  loop_optimizer_finalize (cfun);
}

/* Optimization passes.  */
enum
{
  UAP_UNROLL = 1,       /* Enables unrolling of loops if it seems profitable.  */
  UAP_UNROLL_ALL = 2    /* Enables unrolling of all loops.  */
};

extern void doloop_optimize_loops (void);
extern void move_loop_invariants (void);
extern vec<basic_block> get_loop_hot_path (const struct loop *loop);

/* Returns the outermost loop of the loop nest that contains LOOP.*/
static inline struct loop *
loop_outermost (struct loop *loop)
{
  unsigned n = vec_safe_length (loop->superloops);

  if (n <= 1)
    return loop;

  return (*loop->superloops)[1];
}

extern void record_niter_bound (struct loop *, const widest_int &, bool, bool);
extern HOST_WIDE_INT get_estimated_loop_iterations_int (struct loop *);
extern HOST_WIDE_INT get_max_loop_iterations_int (struct loop *);
extern bool get_estimated_loop_iterations (struct loop *loop, widest_int *nit);
extern bool get_max_loop_iterations (struct loop *loop, widest_int *nit);
extern int bb_loop_depth (const_basic_block);

/* Converts VAL to widest_int.  */

static inline widest_int
gcov_type_to_wide_int (gcov_type val)
{
  HOST_WIDE_INT a[2];

  a[0] = (unsigned HOST_WIDE_INT) val;
  /* If HOST_BITS_PER_WIDE_INT == HOST_BITS_PER_WIDEST_INT, avoid shifting by
     the size of type.  */
  val >>= HOST_BITS_PER_WIDE_INT - 1;
  val >>= 1;
  a[1] = (unsigned HOST_WIDE_INT) val;

  return widest_int::from_array (a, 2);
}
#endif /* GCC_CFGLOOP_H */