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/* Define control and data flow tables, and regsets.

   Copyright (C) 1987, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004,

   2005, 2006, 2007, 2008, 2009, 2010 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_BASIC_BLOCK_H

#define GCC_BASIC_BLOCK_H

#include "bitmap.h"

#include "sbitmap.h"

#include "varray.h"

#include "partition.h"

#include "hard-reg-set.h"

#include "predict.h"

#include "vec.h"

#include "function.h"

/* Head of register set linked list.  */

typedef bitmap_head regset_head;

/* A pointer to a regset_head.  */

typedef bitmap regset;

/* Allocate a register set with oballoc.  */

#define ALLOC_REG_SET(OBSTACK) BITMAP_ALLOC (OBSTACK)

/* Do any cleanup needed on a regset when it is no longer used.  */

#define FREE_REG_SET(REGSET) BITMAP_FREE (REGSET)

/* Initialize a new regset.  */

#define INIT_REG_SET(HEAD) bitmap_initialize (HEAD, &reg_obstack)

/* Clear a register set by freeing up the linked list.  */

#define CLEAR_REG_SET(HEAD) bitmap_clear (HEAD)

/* Copy a register set to another register set.  */

#define COPY_REG_SET(TO, FROM) bitmap_copy (TO, FROM)

/* Compare two register sets.  */

#define REG_SET_EQUAL_P(A, B) bitmap_equal_p (A, B)

/* `and' a register set with a second register set.  */

#define AND_REG_SET(TO, FROM) bitmap_and_into (TO, FROM)

/* `and' the complement of a register set with a register set.  */

#define AND_COMPL_REG_SET(TO, FROM) bitmap_and_compl_into (TO, FROM)

/* Inclusive or a register set with a second register set.  */

#define IOR_REG_SET(TO, FROM) bitmap_ior_into (TO, FROM)

/* Exclusive or a register set with a second register set.  */

#define XOR_REG_SET(TO, FROM) bitmap_xor_into (TO, FROM)

/* Or into TO the register set FROM1 `and'ed with the complement of FROM2.  */

#define IOR_AND_COMPL_REG_SET(TO, FROM1, FROM2) \

  bitmap_ior_and_compl_into (TO, FROM1, FROM2)

/* Clear a single register in a register set.  */

#define CLEAR_REGNO_REG_SET(HEAD, REG) bitmap_clear_bit (HEAD, REG)

/* Set a single register in a register set.  */

#define SET_REGNO_REG_SET(HEAD, REG) bitmap_set_bit (HEAD, REG)

/* Return true if a register is set in a register set.  */

#define REGNO_REG_SET_P(TO, REG) bitmap_bit_p (TO, REG)

/* Copy the hard registers in a register set to the hard register set.  */

extern void reg_set_to_hard_reg_set (HARD_REG_SET *, const_bitmap);

#define REG_SET_TO_HARD_REG_SET(TO, FROM)                               \

do {                                                                    \

  CLEAR_HARD_REG_SET (TO);                                              \

  reg_set_to_hard_reg_set (&TO, FROM);                                  \

} while (0)

typedef bitmap_iterator reg_set_iterator;

/* Loop over all registers in REGSET, starting with MIN, setting REGNUM to the

   register number and executing CODE for all registers that are set.  */

#define EXECUTE_IF_SET_IN_REG_SET(REGSET, MIN, REGNUM, RSI)     \

  EXECUTE_IF_SET_IN_BITMAP (REGSET, MIN, REGNUM, RSI)

/* Loop over all registers in REGSET1 and REGSET2, starting with MIN, setting

   REGNUM to the register number and executing CODE for all registers that are

   set in the first regset and not set in the second.  */

#define EXECUTE_IF_AND_COMPL_IN_REG_SET(REGSET1, REGSET2, MIN, REGNUM, RSI) \

  EXECUTE_IF_AND_COMPL_IN_BITMAP (REGSET1, REGSET2, MIN, REGNUM, RSI)

/* Loop over all registers in REGSET1 and REGSET2, starting with MIN, setting

   REGNUM to the register number and executing CODE for all registers that are

   set in both regsets.  */

#define EXECUTE_IF_AND_IN_REG_SET(REGSET1, REGSET2, MIN, REGNUM, RSI) \

  EXECUTE_IF_AND_IN_BITMAP (REGSET1, REGSET2, MIN, REGNUM, RSI) \

/* Same information as REGS_INVALIDATED_BY_CALL but in regset form to be used

   in dataflow more conveniently.  */

extern regset regs_invalidated_by_call_regset;

/* Type we use to hold basic block counters.  Should be at least

   64bit.  Although a counter cannot be negative, we use a signed

   type, because erroneous negative counts can be generated when the

   flow graph is manipulated by various optimizations.  A signed type

   makes those easy to detect.  */

typedef HOST_WIDEST_INT gcov_type;

/* Control flow edge information.  */

struct GTY(()) edge_def {

  /* The two blocks at the ends of the edge.  */

  struct basic_block_def *src;

  struct basic_block_def *dest;

  /* Instructions queued on the edge.  */

  union edge_def_insns {

    gimple_seq GTY ((tag ("true"))) g;

    rtx GTY ((tag ("false"))) r;

  } GTY ((desc ("current_ir_type () == IR_GIMPLE"))) insns;

  /* Auxiliary info specific to a pass.  */

  PTR GTY ((skip (""))) aux;

  /* Location of any goto implicit in the edge and associated BLOCK.  */

  tree goto_block;

  location_t goto_locus;

  /* The index number corresponding to this edge in the edge vector

     dest->preds.  */

  unsigned int dest_idx;

  int flags;                    /* see EDGE_* below  */

  int probability;              /* biased by REG_BR_PROB_BASE */

  gcov_type count;              /* Expected number of executions calculated

                                   in profile.c  */

};

DEF_VEC_P(edge);

DEF_VEC_ALLOC_P(edge,gc);

DEF_VEC_ALLOC_P(edge,heap);

#define EDGE_FALLTHRU           1       /* 'Straight line' flow */

#define EDGE_ABNORMAL           2       /* Strange flow, like computed

                                           label, or eh */

#define EDGE_ABNORMAL_CALL      4       /* Call with abnormal exit

                                           like an exception, or sibcall */

#define EDGE_EH                 8       /* Exception throw */

#define EDGE_FAKE               16      /* Not a real edge (profile.c) */

#define EDGE_DFS_BACK           32      /* A backwards edge */

#define EDGE_CAN_FALLTHRU       64      /* Candidate for straight line

                                           flow.  */

#define EDGE_IRREDUCIBLE_LOOP   128     /* Part of irreducible loop.  */

#define EDGE_SIBCALL            256     /* Edge from sibcall to exit.  */

#define EDGE_LOOP_EXIT          512     /* Exit of a loop.  */

#define EDGE_TRUE_VALUE         1024    /* Edge taken when controlling

                                           predicate is nonzero.  */

#define EDGE_FALSE_VALUE        2048    /* Edge taken when controlling

                                           predicate is zero.  */

#define EDGE_EXECUTABLE         4096    /* Edge is executable.  Only

                                           valid during SSA-CCP.  */

#define EDGE_CROSSING           8192    /* Edge crosses between hot

                                           and cold sections, when we

                                           do partitioning.  */

#define EDGE_ALL_FLAGS         16383

#define EDGE_COMPLEX    (EDGE_ABNORMAL | EDGE_ABNORMAL_CALL | EDGE_EH)

/* Counter summary from the last set of coverage counts read by

   profile.c.  */

extern const struct gcov_ctr_summary *profile_info;

/* Declared in cfgloop.h.  */

struct loop;

/* Declared in tree-flow.h.  */

struct edge_prediction;

struct rtl_bb_info;

/* A basic block is a sequence of instructions with only entry and

   only one exit.  If any one of the instructions are executed, they

   will all be executed, and in sequence from first to last.

   There may be COND_EXEC instructions in the basic block.  The

   COND_EXEC *instructions* will be executed -- but if the condition

   is false the conditionally executed *expressions* will of course

   not be executed.  We don't consider the conditionally executed

   expression (which might have side-effects) to be in a separate

   basic block because the program counter will always be at the same

   location after the COND_EXEC instruction, regardless of whether the

   condition is true or not.

   Basic blocks need not start with a label nor end with a jump insn.

   For example, a previous basic block may just "conditionally fall"

   into the succeeding basic block, and the last basic block need not

   end with a jump insn.  Block 0 is a descendant of the entry block.

   A basic block beginning with two labels cannot have notes between

   the labels.

   Data for jump tables are stored in jump_insns that occur in no

   basic block even though these insns can follow or precede insns in

   basic blocks.  */

/* Basic block information indexed by block number.  */

struct GTY((chain_next ("%h.next_bb"), chain_prev ("%h.prev_bb"))) basic_block_def {

  /* The edges into and out of the block.  */

  VEC(edge,gc) *preds;

  VEC(edge,gc) *succs;

  /* Auxiliary info specific to a pass.  */

  PTR GTY ((skip (""))) aux;

  /* Innermost loop containing the block.  */

  struct loop *loop_father;

  /* The dominance and postdominance information node.  */

  struct et_node * GTY ((skip (""))) dom[2];

  /* Previous and next blocks in the chain.  */

  struct basic_block_def *prev_bb;

  struct basic_block_def *next_bb;

  union basic_block_il_dependent {

      struct gimple_bb_info * GTY ((tag ("0"))) gimple;

      struct rtl_bb_info * GTY ((tag ("1"))) rtl;

    } GTY ((desc ("((%1.flags & BB_RTL) != 0)"))) il;

  /* Expected number of executions: calculated in profile.c.  */

  gcov_type count;

  /* The index of this block.  */

  int index;

  /* The loop depth of this block.  */

  int loop_depth;

  /* Expected frequency.  Normalized to be in range 0 to BB_FREQ_MAX.  */

  int frequency;

  /* The discriminator for this block.  */

  int discriminator;

  /* Various flags.  See BB_* below.  */

  int flags;

};

struct GTY(()) rtl_bb_info {

  /* The first and last insns of the block.  */

  rtx head_;

  rtx end_;

  /* In CFGlayout mode points to insn notes/jumptables to be placed just before

     and after the block.   */

  rtx header;

  rtx footer;

  /* This field is used by the bb-reorder and tracer passes.  */

  int visited;

};

struct GTY(()) gimple_bb_info {

  /* Sequence of statements in this block.  */

  gimple_seq seq;

  /* PHI nodes for this block.  */

  gimple_seq phi_nodes;

};

DEF_VEC_P(basic_block);

DEF_VEC_ALLOC_P(basic_block,gc);

DEF_VEC_ALLOC_P(basic_block,heap);

#define BB_FREQ_MAX 10000

/* Masks for basic_block.flags.

   BB_HOT_PARTITION and BB_COLD_PARTITION should be preserved throughout

   the compilation, so they are never cleared.

   All other flags may be cleared by clear_bb_flags().  It is generally

   a bad idea to rely on any flags being up-to-date.  */

enum bb_flags

{

  /* Only set on blocks that have just been created by create_bb.  */

  BB_NEW = 1 << 0,

  /* Set by find_unreachable_blocks.  Do not rely on this being set in any

     pass.  */

  BB_REACHABLE = 1 << 1,

  /* Set for blocks in an irreducible loop by loop analysis.  */

  BB_IRREDUCIBLE_LOOP = 1 << 2,

  /* Set on blocks that may actually not be single-entry single-exit block.  */

  BB_SUPERBLOCK = 1 << 3,

  /* Set on basic blocks that the scheduler should not touch.  This is used

     by SMS to prevent other schedulers from messing with the loop schedule.  */

  BB_DISABLE_SCHEDULE = 1 << 4,

  /* Set on blocks that should be put in a hot section.  */

  BB_HOT_PARTITION = 1 << 5,

  /* Set on blocks that should be put in a cold section.  */

  BB_COLD_PARTITION = 1 << 6,

  /* Set on block that was duplicated.  */

  BB_DUPLICATED = 1 << 7,

  /* Set if the label at the top of this block is the target of a non-local goto.  */

  BB_NON_LOCAL_GOTO_TARGET = 1 << 8,

  /* Set on blocks that are in RTL format.  */

  BB_RTL = 1 << 9 ,

  /* Set on blocks that are forwarder blocks.

     Only used in cfgcleanup.c.  */

  BB_FORWARDER_BLOCK = 1 << 10,

  /* Set on blocks that cannot be threaded through.

     Only used in cfgcleanup.c.  */

  BB_NONTHREADABLE_BLOCK = 1 << 11

};

/* Dummy flag for convenience in the hot/cold partitioning code.  */

#define BB_UNPARTITIONED        0

/* Partitions, to be used when partitioning hot and cold basic blocks into

   separate sections.  */

#define BB_PARTITION(bb) ((bb)->flags & (BB_HOT_PARTITION|BB_COLD_PARTITION))

#define BB_SET_PARTITION(bb, part) do {                                 \

  basic_block bb_ = (bb);                                               \

  bb_->flags = ((bb_->flags & ~(BB_HOT_PARTITION|BB_COLD_PARTITION))    \

                | (part));                                              \

} while (0)

#define BB_COPY_PARTITION(dstbb, srcbb) \

  BB_SET_PARTITION (dstbb, BB_PARTITION (srcbb))

/* State of dominance information.  */

enum dom_state

{

  DOM_NONE,             /* Not computed at all.  */

  DOM_NO_FAST_QUERY,    /* The data is OK, but the fast query data are not usable.  */

  DOM_OK                /* Everything is ok.  */

};

/* What sort of profiling information we have.  */

enum profile_status_d

{

  PROFILE_ABSENT,

  PROFILE_GUESSED,

  PROFILE_READ

};

/* A structure to group all the per-function control flow graph data.

   The x_* prefixing is necessary because otherwise references to the

   fields of this struct are interpreted as the defines for backward

   source compatibility following the definition of this struct.  */

struct GTY(()) control_flow_graph {

  /* Block pointers for the exit and entry of a function.

     These are always the head and tail of the basic block list.  */

  basic_block x_entry_block_ptr;

  basic_block x_exit_block_ptr;

  /* Index by basic block number, get basic block struct info.  */

  VEC(basic_block,gc) *x_basic_block_info;

  /* Number of basic blocks in this flow graph.  */

  int x_n_basic_blocks;

  /* Number of edges in this flow graph.  */

  int x_n_edges;

  /* The first free basic block number.  */

  int x_last_basic_block;

  /* Mapping of labels to their associated blocks.  At present

     only used for the gimple CFG.  */

  VEC(basic_block,gc) *x_label_to_block_map;

  enum profile_status_d x_profile_status;

  /* Whether the dominators and the postdominators are available.  */

  enum dom_state x_dom_computed[2];

  /* Number of basic blocks in the dominance tree.  */

  unsigned x_n_bbs_in_dom_tree[2];

  /* Maximal number of entities in the single jumptable.  Used to estimate

     final flowgraph size.  */

  int max_jumptable_ents;

  /* UIDs for LABEL_DECLs.  */

  int last_label_uid;

};

/* Defines for accessing the fields of the CFG structure for function FN.  */

#define ENTRY_BLOCK_PTR_FOR_FUNCTION(FN)     ((FN)->cfg->x_entry_block_ptr)

#define EXIT_BLOCK_PTR_FOR_FUNCTION(FN)      ((FN)->cfg->x_exit_block_ptr)

#define basic_block_info_for_function(FN)    ((FN)->cfg->x_basic_block_info)

#define n_basic_blocks_for_function(FN)      ((FN)->cfg->x_n_basic_blocks)

#define n_edges_for_function(FN)             ((FN)->cfg->x_n_edges)

#define last_basic_block_for_function(FN)    ((FN)->cfg->x_last_basic_block)

#define label_to_block_map_for_function(FN)  ((FN)->cfg->x_label_to_block_map)

#define profile_status_for_function(FN)      ((FN)->cfg->x_profile_status)

#define BASIC_BLOCK_FOR_FUNCTION(FN,N) \

  (VEC_index (basic_block, basic_block_info_for_function(FN), (N)))

#define SET_BASIC_BLOCK_FOR_FUNCTION(FN,N,BB) \

  (VEC_replace (basic_block, basic_block_info_for_function(FN), (N), (BB)))

/* Defines for textual backward source compatibility.  */

#define ENTRY_BLOCK_PTR         (cfun->cfg->x_entry_block_ptr)

#define EXIT_BLOCK_PTR          (cfun->cfg->x_exit_block_ptr)

#define basic_block_info        (cfun->cfg->x_basic_block_info)

#define n_basic_blocks          (cfun->cfg->x_n_basic_blocks)

#define n_edges                 (cfun->cfg->x_n_edges)

#define last_basic_block        (cfun->cfg->x_last_basic_block)

#define label_to_block_map      (cfun->cfg->x_label_to_block_map)

#define profile_status          (cfun->cfg->x_profile_status)

#define BASIC_BLOCK(N)          (VEC_index (basic_block, basic_block_info, (N)))

#define SET_BASIC_BLOCK(N,BB)   (VEC_replace (basic_block, basic_block_info, (N), (BB)))

/* For iterating over basic blocks.  */

#define FOR_BB_BETWEEN(BB, FROM, TO, DIR) \

  for (BB = FROM; BB != TO; BB = BB->DIR)

#define FOR_EACH_BB_FN(BB, FN) \

  FOR_BB_BETWEEN (BB, (FN)->cfg->x_entry_block_ptr->next_bb, (FN)->cfg->x_exit_block_ptr, next_bb)

#define FOR_EACH_BB(BB) FOR_EACH_BB_FN (BB, cfun)

#define FOR_EACH_BB_REVERSE_FN(BB, FN) \

  FOR_BB_BETWEEN (BB, (FN)->cfg->x_exit_block_ptr->prev_bb, (FN)->cfg->x_entry_block_ptr, prev_bb)

#define FOR_EACH_BB_REVERSE(BB) FOR_EACH_BB_REVERSE_FN(BB, cfun)

/* For iterating over insns in basic block.  */

#define FOR_BB_INSNS(BB, INSN)                  \

  for ((INSN) = BB_HEAD (BB);                   \

       (INSN) && (INSN) != NEXT_INSN (BB_END (BB));     \

       (INSN) = NEXT_INSN (INSN))

/* For iterating over insns in basic block when we might remove the

   current insn.  */

#define FOR_BB_INSNS_SAFE(BB, INSN, CURR)                       \

  for ((INSN) = BB_HEAD (BB), (CURR) = (INSN) ? NEXT_INSN ((INSN)): NULL;       \

       (INSN) && (INSN) != NEXT_INSN (BB_END (BB));     \

       (INSN) = (CURR), (CURR) = (INSN) ? NEXT_INSN ((INSN)) : NULL)

#define FOR_BB_INSNS_REVERSE(BB, INSN)          \

  for ((INSN) = BB_END (BB);                    \

       (INSN) && (INSN) != PREV_INSN (BB_HEAD (BB));    \

       (INSN) = PREV_INSN (INSN))

#define FOR_BB_INSNS_REVERSE_SAFE(BB, INSN, CURR)       \

  for ((INSN) = BB_END (BB),(CURR) = (INSN) ? PREV_INSN ((INSN)) : NULL;        \

       (INSN) && (INSN) != PREV_INSN (BB_HEAD (BB));    \

       (INSN) = (CURR), (CURR) = (INSN) ? PREV_INSN ((INSN)) : NULL)

/* Cycles through _all_ basic blocks, even the fake ones (entry and

   exit block).  */

#define FOR_ALL_BB(BB) \

  for (BB = ENTRY_BLOCK_PTR; BB; BB = BB->next_bb)

#define FOR_ALL_BB_FN(BB, FN) \

  for (BB = ENTRY_BLOCK_PTR_FOR_FUNCTION (FN); BB; BB = BB->next_bb)

extern bitmap_obstack reg_obstack;

/* Stuff for recording basic block info.  */

#define BB_HEAD(B)      (B)->il.rtl->head_

#define BB_END(B)       (B)->il.rtl->end_

/* Special block numbers [markers] for entry and exit.

   Neither of them is supposed to hold actual statements.  */

#define ENTRY_BLOCK (0)

#define EXIT_BLOCK (1)

/* The two blocks that are always in the cfg.  */

#define NUM_FIXED_BLOCKS (2)

#define set_block_for_insn(INSN, BB)  (BLOCK_FOR_INSN (INSN) = BB)

extern void compute_bb_for_insn (void);

extern unsigned int free_bb_for_insn (void);

extern void update_bb_for_insn (basic_block);

extern void insert_insn_on_edge (rtx, edge);

basic_block split_edge_and_insert (edge, rtx);

extern void commit_one_edge_insertion (edge e);

extern void commit_edge_insertions (void);

extern void remove_fake_edges (void);

extern void remove_fake_exit_edges (void);

extern void add_noreturn_fake_exit_edges (void);

extern void connect_infinite_loops_to_exit (void);

extern edge unchecked_make_edge (basic_block, basic_block, int);

extern edge cached_make_edge (sbitmap, basic_block, basic_block, int);

extern edge make_edge (basic_block, basic_block, int);

extern edge make_single_succ_edge (basic_block, basic_block, int);

extern void remove_edge_raw (edge);

extern void redirect_edge_succ (edge, basic_block);

extern edge redirect_edge_succ_nodup (edge, basic_block);

extern void redirect_edge_pred (edge, basic_block);

extern basic_block create_basic_block_structure (rtx, rtx, rtx, basic_block);

extern void clear_bb_flags (void);

extern int post_order_compute (int *, bool, bool);

extern int inverted_post_order_compute (int *);

extern int pre_and_rev_post_order_compute (int *, int *, bool);

extern int dfs_enumerate_from (basic_block, int,

                               bool (*)(const_basic_block, const void *),

                               basic_block *, int, const void *);

extern void compute_dominance_frontiers (bitmap *);

extern bitmap compute_idf (bitmap, bitmap *);

extern void dump_bb_info (basic_block, bool, bool, int, const char *, FILE *);

extern void dump_edge_info (FILE *, edge, int);

extern void brief_dump_cfg (FILE *);

extern void clear_edges (void);

extern void scale_bbs_frequencies_int (basic_block *, int, int, int);

extern void scale_bbs_frequencies_gcov_type (basic_block *, int, gcov_type,

                                             gcov_type);

/* Structure to group all of the information to process IF-THEN and

   IF-THEN-ELSE blocks for the conditional execution support.  This

   needs to be in a public file in case the IFCVT macros call

   functions passing the ce_if_block data structure.  */

typedef struct ce_if_block

{

  basic_block test_bb;                  /* First test block.  */

  basic_block then_bb;                  /* THEN block.  */

  basic_block else_bb;                  /* ELSE block or NULL.  */

  basic_block join_bb;                  /* Join THEN/ELSE blocks.  */

  basic_block last_test_bb;             /* Last bb to hold && or || tests.  */

  int num_multiple_test_blocks;         /* # of && and || basic blocks.  */

  int num_and_and_blocks;               /* # of && blocks.  */

  int num_or_or_blocks;                 /* # of || blocks.  */

  int num_multiple_test_insns;          /* # of insns in && and || blocks.  */

  int and_and_p;                        /* Complex test is &&.  */

  int num_then_insns;                   /* # of insns in THEN block.  */

  int num_else_insns;                   /* # of insns in ELSE block.  */

  int pass;                             /* Pass number.  */

#ifdef IFCVT_EXTRA_FIELDS

  IFCVT_EXTRA_FIELDS                    /* Any machine dependent fields.  */

#endif

} ce_if_block_t;

/* This structure maintains an edge list vector.  */

struct edge_list

{

  int num_blocks;

  int num_edges;

  edge *index_to_edge;

};

/* The base value for branch probability notes and edge probabilities.  */

#define REG_BR_PROB_BASE  10000

/* This is the value which indicates no edge is present.  */

#define EDGE_INDEX_NO_EDGE      -1

/* EDGE_INDEX returns an integer index for an edge, or EDGE_INDEX_NO_EDGE

   if there is no edge between the 2 basic blocks.  */

#define EDGE_INDEX(el, pred, succ) (find_edge_index ((el), (pred), (succ)))

/* INDEX_EDGE_PRED_BB and INDEX_EDGE_SUCC_BB return a pointer to the basic

   block which is either the pred or succ end of the indexed edge.  */

#define INDEX_EDGE_PRED_BB(el, index)   ((el)->index_to_edge[(index)]->src)

#define INDEX_EDGE_SUCC_BB(el, index)   ((el)->index_to_edge[(index)]->dest)

/* INDEX_EDGE returns a pointer to the edge.  */

#define INDEX_EDGE(el, index)           ((el)->index_to_edge[(index)])

/* Number of edges in the compressed edge list.  */

#define NUM_EDGES(el)                   ((el)->num_edges)

/* BB is assumed to contain conditional jump.  Return the fallthru edge.  */

#define FALLTHRU_EDGE(bb)               (EDGE_SUCC ((bb), 0)->flags & EDGE_FALLTHRU \

                                         ? EDGE_SUCC ((bb), 0) : EDGE_SUCC ((bb), 1))

/* BB is assumed to contain conditional jump.  Return the branch edge.  */

#define BRANCH_EDGE(bb)                 (EDGE_SUCC ((bb), 0)->flags & EDGE_FALLTHRU \

                                         ? EDGE_SUCC ((bb), 1) : EDGE_SUCC ((bb), 0))

/* Return expected execution frequency of the edge E.  */

#define EDGE_FREQUENCY(e)               (((e)->src->frequency \

                                          * (e)->probability \

                                          + REG_BR_PROB_BASE / 2) \

                                         / REG_BR_PROB_BASE)

/* Return nonzero if edge is critical.  */

#define EDGE_CRITICAL_P(e)              (EDGE_COUNT ((e)->src->succs) >= 2 \

                                         && EDGE_COUNT ((e)->dest->preds) >= 2)

#define EDGE_COUNT(ev)                  VEC_length (edge, (ev))

#define EDGE_I(ev,i)                    VEC_index  (edge, (ev), (i))

#define EDGE_PRED(bb,i)                 VEC_index  (edge, (bb)->preds, (i))

#define EDGE_SUCC(bb,i)                 VEC_index  (edge, (bb)->succs, (i))

/* Returns true if BB has precisely one successor.  */

static inline bool

single_succ_p (const_basic_block bb)

{

  return EDGE_COUNT (bb->succs) == 1;

}

/* Returns true if BB has precisely one predecessor.  */

static inline bool

single_pred_p (const_basic_block bb)

{

  return EDGE_COUNT (bb->preds) == 1;

}

/* Returns the single successor edge of basic block BB.  Aborts if

   BB does not have exactly one successor.  */

static inline edge

single_succ_edge (const_basic_block bb)

{

  gcc_assert (single_succ_p (bb));

  return EDGE_SUCC (bb, 0);

}

/* Returns the single predecessor edge of basic block BB.  Aborts

   if BB does not have exactly one predecessor.  */

static inline edge

single_pred_edge (const_basic_block bb)

{

  gcc_assert (single_pred_p (bb));

  return EDGE_PRED (bb, 0);

}

/* Returns the single successor block of basic block BB.  Aborts

   if BB does not have exactly one successor.  */

static inline basic_block

single_succ (const_basic_block bb)

{

  return single_succ_edge (bb)->dest;

}

/* Returns the single predecessor block of basic block BB.  Aborts

   if BB does not have exactly one predecessor.*/

static inline basic_block

single_pred (const_basic_block bb)

{

  return single_pred_edge (bb)->src;

}

/* Iterator object for edges.  */

typedef struct {

  unsigned index;

  VEC(edge,gc) **container;

} edge_iterator;

static inline VEC(edge,gc) *

ei_container (edge_iterator i)

{

  gcc_assert (i.container);

  return *i.container;

}

#define ei_start(iter) ei_start_1 (&(iter))

#define ei_last(iter) ei_last_1 (&(iter))

/* Return an iterator pointing to the start of an edge vector.  */

static inline edge_iterator

ei_start_1 (VEC(edge,gc) **ev)

{

  edge_iterator i;

  i.index = 0;

  i.container = ev;

  return i;

}

/* Return an iterator pointing to the last element of an edge

   vector.  */

static inline edge_iterator

ei_last_1 (VEC(edge,gc) **ev)

{

  edge_iterator i;

  i.index = EDGE_COUNT (*ev) - 1;

  i.container = ev;

  return i;

}

/* Is the iterator `i' at the end of the sequence?  */

static inline bool

ei_end_p (edge_iterator i)

{

  return (i.index == EDGE_COUNT (ei_container (i)));

}

/* Is the iterator `i' at one position before the end of the

   sequence?  */

static inline bool

ei_one_before_end_p (edge_iterator i)

{

  return (i.index + 1 == EDGE_COUNT (ei_container (i)));

}

/* Advance the iterator to the next element.  */

static inline void

ei_next (edge_iterator *i)

{

  gcc_assert (i->index < EDGE_COUNT (ei_container (*i)));