Subversion Repositories openrisc

/* Form lists of pseudo register references for autoinc optimization

   for GNU compiler.  This is part of flow optimization.

   Copyright (C) 1999, 2000, 2001, 2003, 2004, 2005, 2006, 2007, 2008,

   2009, 2010  Free Software Foundation, Inc.

   Originally contributed by Michael P. Hayes

             (m.hayes@elec.canterbury.ac.nz, mhayes@redhat.com)

   Major rewrite contributed by Danny Berlin (dberlin@dberlin.org)

             and Kenneth Zadeck (zadeck@naturalbridge.com).

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_DF_H

#define GCC_DF_H

#include "bitmap.h"

#include "basic-block.h"

#include "alloc-pool.h"

#include "timevar.h"

struct dataflow;

struct df;

struct df_problem;

struct df_link;

struct df_insn_info;

union df_ref_d;

/* Data flow problems.  All problems must have a unique id here.  */

/* Scanning is not really a dataflow problem, but it is useful to have

   the basic block functions in the vector so that things get done in

   a uniform manner.  The last four problems can be added or deleted

   at any time are always defined (though LIVE is always there at -O2

   or higher); the others are always there.  */

#define DF_SCAN    0

#define DF_LR      1      /* Live Registers backward. */

#define DF_LIVE    2      /* Live Registers & Uninitialized Registers */

#define DF_RD      3      /* Reaching Defs. */

#define DF_CHAIN   4      /* Def-Use and/or Use-Def Chains. */

#define DF_BYTE_LR 5      /* Subreg tracking lr.  */

#define DF_NOTE    6      /* REG_DEF and REG_UNUSED notes. */

#define DF_MD      7      /* Multiple Definitions. */

#define DF_LAST_PROBLEM_PLUS1 (DF_MD + 1)

/* Dataflow direction.  */

enum df_flow_dir

  {

    DF_NONE,

    DF_FORWARD,

    DF_BACKWARD

  };

/* Used in the byte scanning to determine if may or must info is to be

   returned.  */

enum df_mm

  {

    DF_MM_MAY,

    DF_MM_MUST

  };

/* Descriminator for the various df_ref types.  */

enum df_ref_class {DF_REF_BASE, DF_REF_ARTIFICIAL, DF_REF_REGULAR, DF_REF_EXTRACT};

/* The first of these us a set of a registers.  The remaining three

   are all uses of a register (the mem_load and mem_store relate to

   how the register as an addressing operand).  */

enum df_ref_type {DF_REF_REG_DEF, DF_REF_REG_USE,

                  DF_REF_REG_MEM_LOAD, DF_REF_REG_MEM_STORE};

enum df_ref_flags

  {

    /* This flag is set if this ref occurs inside of a conditional

       execution instruction.  */

    DF_REF_CONDITIONAL = 1 << 0,

    /* If this flag is set for an artificial use or def, that ref

       logically happens at the top of the block.  If it is not set

       for an artificial use or def, that ref logically happens at the

       bottom of the block.  This is never set for regular refs.  */

    DF_REF_AT_TOP = 1 << 1,

    /* This flag is set if the use is inside a REG_EQUAL or REG_EQUIV

       note.  */

    DF_REF_IN_NOTE = 1 << 2,

    /* This bit is true if this ref can make regs_ever_live true for

       this regno.  */

    DF_HARD_REG_LIVE = 1 << 3,

    /* This flag is set if this ref is a partial use or def of the

       associated register.  */

    DF_REF_PARTIAL = 1 << 4,

    /* Read-modify-write refs generate both a use and a def and

       these are marked with this flag to show that they are not

       independent.  */

    DF_REF_READ_WRITE = 1 << 5,

    /* This flag is set if this ref, generally a def, may clobber the

       referenced register.  This is generally only set for hard

       registers that cross a call site.  With better information

       about calls, some of these could be changed in the future to

       DF_REF_MUST_CLOBBER.  */

    DF_REF_MAY_CLOBBER = 1 << 6,

    /* This flag is set if this ref, generally a def, is a real

       clobber. This is not currently set for registers live across a

       call because that clobbering may or may not happen.

       Most of the uses of this are with sets that have a

       GET_CODE(..)==CLOBBER.  Note that this is set even if the

       clobber is to a subreg.  So in order to tell if the clobber

       wipes out the entire register, it is necessary to also check

       the DF_REF_PARTIAL flag.  */

    DF_REF_MUST_CLOBBER = 1 << 7,

    /* If the ref has one of the following two flags set, then the

       struct df_ref can be cast to struct df_ref_extract to access

       the width and offset fields.  */

    /* This flag is set if the ref contains a SIGN_EXTRACT.  */

    DF_REF_SIGN_EXTRACT = 1 << 8,

    /* This flag is set if the ref contains a ZERO_EXTRACT.  */

    DF_REF_ZERO_EXTRACT = 1 << 9,

    /* This flag is set if the ref contains a STRICT_LOW_PART.  */

    DF_REF_STRICT_LOW_PART = 1 << 10,

    /* This flag is set if the ref contains a SUBREG.  */

    DF_REF_SUBREG = 1 << 11,

    /* This bit is true if this ref is part of a multiword hardreg.  */

    DF_REF_MW_HARDREG = 1 << 12,

    /* This flag is set if this ref is a usage of the stack pointer by

       a function call.  */

    DF_REF_CALL_STACK_USAGE = 1 << 13,

    /* This flag is used for verification of existing refs. */

    DF_REF_REG_MARKER = 1 << 14,

    /* This flag is set if this ref is inside a pre/post modify.  */

    DF_REF_PRE_POST_MODIFY = 1 << 15

  };

/* The possible ordering of refs within the df_ref_info.  */

enum df_ref_order

  {

    /* There is not table.  */

    DF_REF_ORDER_NO_TABLE,

    /* There is a table of refs but it is not (or no longer) organized

       by one of the following methods.  */

    DF_REF_ORDER_UNORDERED,

    DF_REF_ORDER_UNORDERED_WITH_NOTES,

    /* Organize the table by reg order, all of the refs with regno 0

       followed by all of the refs with regno 1 ... .  Within all of

       the regs for a particular regno, the refs are unordered.  */

    DF_REF_ORDER_BY_REG,

    /* For uses, the refs within eq notes may be added for

       DF_REF_ORDER_BY_REG.  */

    DF_REF_ORDER_BY_REG_WITH_NOTES,

    /* Organize the refs in insn order.  The insns are ordered within a

       block, and the blocks are ordered by FOR_ALL_BB.  */

    DF_REF_ORDER_BY_INSN,

    /* For uses, the refs within eq notes may be added for

       DF_REF_ORDER_BY_INSN.  */

    DF_REF_ORDER_BY_INSN_WITH_NOTES

  };

/* Function prototypes added to df_problem instance.  */

/* Allocate the problem specific data.  */

typedef void (*df_alloc_function) (bitmap);

/* This function is called if the problem has global data that needs

   to be cleared when ever the set of blocks changes.  The bitmap

   contains the set of blocks that may require special attention.

   This call is only made if some of the blocks are going to change.

   If everything is to be deleted, the wholesale deletion mechanisms

   apply. */

typedef void (*df_reset_function) (bitmap);

/* Free the basic block info.  Called from the block reordering code

   to get rid of the blocks that have been squished down.   */

typedef void (*df_free_bb_function) (basic_block, void *);

/* Local compute function.  */

typedef void (*df_local_compute_function) (bitmap);

/* Init the solution specific data.  */

typedef void (*df_init_function) (bitmap);

/* Iterative dataflow function.  */

typedef void (*df_dataflow_function) (struct dataflow *, bitmap, int *, int);

/* Confluence operator for blocks with 0 out (or in) edges.  */

typedef void (*df_confluence_function_0) (basic_block);

/* Confluence operator for blocks with 1 or more out (or in) edges.  */

typedef void (*df_confluence_function_n) (edge);

/* Transfer function for blocks.  */

typedef bool (*df_transfer_function) (int);

/* Function to massage the information after the problem solving.  */

typedef void (*df_finalizer_function) (bitmap);

/* Function to free all of the problem specific datastructures.  */

typedef void (*df_free_function) (void);

/* Function to remove this problem from the stack of dataflow problems

   without effecting the other problems in the stack except for those

   that depend on this problem.  */

typedef void (*df_remove_problem_function) (void);

/* Function to dump basic block independent results to FILE.  */

typedef void (*df_dump_problem_function) (FILE *);

/* Function to dump top or bottom of basic block results to FILE.  */

typedef void (*df_dump_bb_problem_function) (basic_block, FILE *);

/* Function to dump top or bottom of basic block results to FILE.  */

typedef void (*df_verify_solution_start) (void);

/* Function to dump top or bottom of basic block results to FILE.  */

typedef void (*df_verify_solution_end) (void);

/* The static description of a dataflow problem to solve.  See above

   typedefs for doc for the function fields.  */

struct df_problem {

  /* The unique id of the problem.  This is used it index into

     df->defined_problems to make accessing the problem data easy.  */

  unsigned int id;

  enum df_flow_dir dir;                 /* Dataflow direction.  */

  df_alloc_function alloc_fun;

  df_reset_function reset_fun;

  df_free_bb_function free_bb_fun;

  df_local_compute_function local_compute_fun;

  df_init_function init_fun;

  df_dataflow_function dataflow_fun;

  df_confluence_function_0 con_fun_0;

  df_confluence_function_n con_fun_n;

  df_transfer_function trans_fun;

  df_finalizer_function finalize_fun;

  df_free_function free_fun;

  df_remove_problem_function remove_problem_fun;

  df_dump_problem_function dump_start_fun;

  df_dump_bb_problem_function dump_top_fun;

  df_dump_bb_problem_function dump_bottom_fun;

  df_verify_solution_start verify_start_fun;

  df_verify_solution_end verify_end_fun;

  struct df_problem *dependent_problem;

  /* The timevar id associated with this pass.  */

  timevar_id_t tv_id;

  /* True if the df_set_blocks should null out the basic block info if

     this block drops out of df->blocks_to_analyze.  */

  bool free_blocks_on_set_blocks;

};

/* The specific instance of the problem to solve.  */

struct dataflow

{

  struct df_problem *problem;           /* The problem to be solved.  */

  /* Array indexed by bb->index, that contains basic block problem and

     solution specific information.  */

  void **block_info;

  unsigned int block_info_size;

  /* The pool to allocate the block_info from. */

  alloc_pool block_pool;

  /* The lr and live problems have their transfer functions recomputed

     only if necessary.  This is possible for them because, the

     problems are kept active for the entire backend and their

     transfer functions are indexed by the REGNO.  These are not

     defined for any other problem.  */

  bitmap out_of_date_transfer_functions;

  /* Other problem specific data that is not on a per basic block

     basis.  The structure is generally defined privately for the

     problem.  The exception being the scanning problem where it is

     fully public.  */

  void *problem_data;

  /* Local flags for some of the problems. */

  unsigned int local_flags;

  /* True if this problem of this instance has been initialized.  This

     is used by the dumpers to keep garbage out of the dumps if, for

     debugging a dump is produced before the first call to

     df_analyze after a new problem is added.  */

  bool computed;

  /* True if the something has changed which invalidates the dataflow

     solutions.  Note that this bit is always true for all problems except

     lr and live.  */

  bool solutions_dirty;

  /* If true, this pass is deleted by df_finish_pass.  This is never

     true for DF_SCAN and DF_LR.  It is true for DF_LIVE if optimize >

     1.  It is always true for the other problems.  */

  bool optional_p;

};

/* The set of multiword hardregs used as operands to this

   instruction. These are factored into individual uses and defs but

   the aggregate is still needed to service the REG_DEAD and

   REG_UNUSED notes.  */

struct df_mw_hardreg

{

  rtx mw_reg;                   /* The multiword hardreg.  */

  /* These two bitfields are intentionally oversized, in the hope that

     accesses to 16-bit fields will usually be quicker.  */

  ENUM_BITFIELD(df_ref_type) type : 16;

                                /* Used to see if the ref is read or write.  */

  int flags : 16;               /* Various df_ref_flags.  */

  unsigned int start_regno;     /* First word of the multi word subreg.  */

  unsigned int end_regno;       /* Last word of the multi word subreg.  */

  unsigned int mw_order;        /* Same as df_ref.ref_order.  */

};

/* Define a register reference structure.  One of these is allocated

    for every register reference (use or def).  Note some register

    references (e.g., post_inc, subreg) generate both a def and a use.  */

struct df_base_ref

{

  /* These three bitfields are intentionally oversized, in the hope that

     accesses to 8 and 16-bit fields will usually be quicker.  */

  ENUM_BITFIELD(df_ref_class) cl : 8;

  ENUM_BITFIELD(df_ref_type) type : 8;

                                /* Type of ref.  */

  int flags : 16;               /* Various df_ref_flags.  */

  rtx reg;                      /* The register referenced.  */

  struct df_link *chain;        /* Head of def-use, use-def.  */

  /* Pointer to the insn info of the containing instruction.  FIXME!

     Currently this is NULL for artificial refs but this will be used

     when FUDs are added.  */

  struct df_insn_info *insn_info;

  /* For each regno, there are three chains of refs, one for the uses,

     the eq_uses and the defs.  These chains go thru the refs

     themselves rather than using an external structure.  */

  union df_ref_d *next_reg;     /* Next ref with same regno and type.  */

  union df_ref_d *prev_reg;     /* Prev ref with same regno and type.  */

  unsigned int regno;           /* The register number referenced.  */

  /* Location in the ref table.  This is only valid after a call to

     df_maybe_reorganize_[use,def]_refs which is an expensive operation.  */

  int id;

  /* The index at which the operand was scanned in the insn.  This is

     used to totally order the refs in an insn.  */

  unsigned int ref_order;

};

/* The three types of df_refs.  Note that the df_ref_extract is an

   extension of the df_regular_ref, not the df_base_ref.  */

struct df_artificial_ref

{

  struct df_base_ref base;

  /* Artificial refs do not have an insn, so to get the basic block,

     it must be explicitly here.  */

  basic_block bb;

};

struct df_regular_ref

{

  struct df_base_ref base;

  /* The loc is the address in the insn of the reg.  This is not

     defined for special registers, such as clobbers and stack

     pointers that are also associated with call insns and so those

     just use the base.  */

  rtx *loc;

};

/* A df_ref_extract is just a df_ref with a width and offset field at

   the end of it.  It is used to hold this information if the ref was

   wrapped by a SIGN_EXTRACT or a ZERO_EXTRACT and to pass this info

   to passes that wish to process partial regs precisely.  */

struct df_extract_ref

{

  struct df_regular_ref base;

  int width;

  int offset;

  enum machine_mode mode;

};

/* Union of the different kinds of defs/uses placeholders.  */

union df_ref_d

{

  struct df_base_ref base;

  struct df_regular_ref regular_ref;

  struct df_artificial_ref artificial_ref;

  struct df_extract_ref extract_ref;

};

typedef union df_ref_d *df_ref;

/* One of these structures is allocated for every insn.  */

struct df_insn_info

{

  rtx insn;                     /* The insn this info comes from.  */

  df_ref *defs;                 /* Head of insn-def chain.  */

  df_ref *uses;                 /* Head of insn-use chain.  */

  /* Head of insn-use chain for uses in REG_EQUAL/EQUIV notes.  */

  df_ref *eq_uses;

  struct df_mw_hardreg **mw_hardregs;

  /* The logical uid of the insn in the basic block.  This is valid

     after any call to df_analyze but may rot after insns are added,

     deleted or moved. */

  int luid;

};

/* These links are used for ref-ref chains.  Currently only DEF-USE and

   USE-DEF chains can be built by DF.  */

struct df_link

{

  df_ref ref;

  struct df_link *next;

};

enum df_chain_flags

{

  /* Flags that control the building of chains.  */

  DF_DU_CHAIN      =  1, /* Build DU chains.  */

  DF_UD_CHAIN      =  2  /* Build UD chains.  */

};

enum df_changeable_flags

{

  /* Scanning flags.  */

  /* Flag to control the running of dce as a side effect of building LR.  */

  DF_LR_RUN_DCE           = 1 << 0, /* Run DCE.  */

  DF_NO_HARD_REGS         = 1 << 1, /* Skip hard registers in RD and CHAIN Building.  */

  DF_EQ_NOTES             = 1 << 2, /* Build chains with uses present in EQUIV/EQUAL notes. */

  DF_NO_REGS_EVER_LIVE    = 1 << 3, /* Do not compute the regs_ever_live.  */

  /* Cause df_insn_rescan df_notes_rescan and df_insn_delete, to

  return immediately.  This is used by passes that know how to update

  the scanning them selves.  */

  DF_NO_INSN_RESCAN       = 1 << 4,

  /* Cause df_insn_rescan df_notes_rescan and df_insn_delete, to

  return after marking the insn for later processing.  This allows all

  rescans to be batched.  */

  DF_DEFER_INSN_RESCAN    = 1 << 5,

  DF_VERIFY_SCHEDULED     = 1 << 6

};

/* Two of these structures are inline in df, one for the uses and one

   for the defs.  This structure is only contains the refs within the

   boundary of the df_set_blocks if that has been defined.  */

struct df_ref_info

{

  df_ref *refs;                 /* Ref table, indexed by id.  */

  unsigned int *begin;          /* First ref_index for this pseudo.  */

  unsigned int *count;          /* Count of refs for this pseudo.  */

  unsigned int refs_size;       /* Size of currently allocated refs table.  */

  /* Table_size is the number of elements in the refs table.  This

     will also be the width of the bitvectors in the rd and ru

     problems.  Total_size is the number of refs.  These will be the

     same if the focus has not been reduced by df_set_blocks.  If the

     focus has been reduced, table_size will be smaller since it only

     contains the refs in the set blocks.  */

  unsigned int table_size;

  unsigned int total_size;

  enum df_ref_order ref_order;

};

/* Three of these structures are allocated for every pseudo reg. One

   for the uses, one for the eq_uses and one for the defs.  */

struct df_reg_info

{

  /* Head of chain for refs of that type and regno.  */

  df_ref reg_chain;

  /* Number of refs in the chain.  */

  unsigned int n_refs;

};

/*----------------------------------------------------------------------------

   Problem data for the scanning dataflow problem.  Unlike the other

   dataflow problems, the problem data for scanning is fully exposed and

   used by owners of the problem.

----------------------------------------------------------------------------*/

struct df

{

  /* The set of problems to be solved is stored in two arrays.  In

     PROBLEMS_IN_ORDER, the problems are stored in the order that they

     are solved.  This is an internally dense array that may have

     nulls at the end of it.  In PROBLEMS_BY_INDEX, the problem is

     stored by the value in df_problem.id.  These are used to access

     the problem local data without having to search the first

     array.  */

  struct dataflow *problems_in_order[DF_LAST_PROBLEM_PLUS1];

  struct dataflow *problems_by_index[DF_LAST_PROBLEM_PLUS1];

  /* If not NULL, this subset of blocks of the program to be

     considered for analysis.  At certain times, this will contain all

     the blocks in the function so it cannot be used as an indicator

     of if we are analyzing a subset.  See analyze_subset.  */

  bitmap blocks_to_analyze;

  /* The following information is really the problem data for the

     scanning instance but it is used too often by the other problems

     to keep getting it from there.  */

  struct df_ref_info def_info;   /* Def info.  */

  struct df_ref_info use_info;   /* Use info.  */

  /* The following three arrays are allocated in parallel.   They contain

     the sets of refs of each type for each reg.  */

  struct df_reg_info **def_regs;       /* Def reg info.  */

  struct df_reg_info **use_regs;       /* Eq_use reg info.  */

  struct df_reg_info **eq_use_regs;    /* Eq_use info.  */

  unsigned int regs_size;       /* Size of currently allocated regs table.  */

  unsigned int regs_inited;     /* Number of regs with reg_infos allocated.  */

  struct df_insn_info **insns;   /* Insn table, indexed by insn UID.  */

  unsigned int insns_size;       /* Size of insn table.  */

  int num_problems_defined;

  bitmap hardware_regs_used;     /* The set of hardware registers used.  */

  /* The set of hard regs that are in the artificial uses at the end

     of a regular basic block.  */

  bitmap regular_block_artificial_uses;

  /* The set of hard regs that are in the artificial uses at the end

     of a basic block that has an EH pred.  */

  bitmap eh_block_artificial_uses;

  /* The set of hardware registers live on entry to the function.  */

  bitmap entry_block_defs;

  bitmap exit_block_uses;        /* The set of hardware registers used in exit block.  */

  /* Insns to delete, rescan or reprocess the notes at next

     df_rescan_all or df_process_deferred_rescans. */

  bitmap insns_to_delete;

  bitmap insns_to_rescan;

  bitmap insns_to_notes_rescan;

  int *postorder;                /* The current set of basic blocks

                                    in reverse postorder.  */

  int *postorder_inverted;       /* The current set of basic blocks

                                    in reverse postorder of inverted CFG.  */

  int n_blocks;                  /* The number of blocks in reverse postorder.  */

  int n_blocks_inverted;         /* The number of blocks

                                    in reverse postorder of inverted CFG.  */

  /* An array [FIRST_PSEUDO_REGISTER], indexed by regno, of the number

     of refs that qualify as being real hard regs uses.  Artificial

     uses and defs as well as refs in eq notes are ignored.  If the

     ref is a def, it cannot be a MAY_CLOBBER def.  If the ref is a

     use, it cannot be the emim_reg_set or be the frame or arg pointer

     register.

     IT IS NOT ACCEPTABLE TO MANUALLY CHANGE THIS ARRAY.  This array

     always reflects the actual number of refs in the insn stream that

     satisfy the above criteria.  */

  unsigned int *hard_regs_live_count;

  /* This counter provides a way to totally order refs without using

     addresses.  It is incremented whenever a ref is created.  */

  unsigned int ref_order;

  /* Problem specific control information.  This is a combination of

     enum df_changeable_flags values.  */

  int changeable_flags : 8;

  /* If this is true, then only a subset of the blocks of the program

     is considered to compute the solutions of dataflow problems.  */

  bool analyze_subset;

  /* True if someone added or deleted something from regs_ever_live so

     that the entry and exit blocks need be reprocessed.  */

  bool redo_entry_and_exit;

};

#define DF_SCAN_BB_INFO(BB) (df_scan_get_bb_info((BB)->index))

#define DF_RD_BB_INFO(BB) (df_rd_get_bb_info((BB)->index))

#define DF_LR_BB_INFO(BB) (df_lr_get_bb_info((BB)->index))

#define DF_LIVE_BB_INFO(BB) (df_live_get_bb_info((BB)->index))

#define DF_BYTE_LR_BB_INFO(BB) (df_byte_lr_get_bb_info((BB)->index))

#define DF_MD_BB_INFO(BB) (df_md_get_bb_info((BB)->index))

/* Most transformations that wish to use live register analysis will

   use these macros.  This info is the and of the lr and live sets.  */

#define DF_LIVE_IN(BB) (DF_LIVE_BB_INFO(BB)->in)

#define DF_LIVE_OUT(BB) (DF_LIVE_BB_INFO(BB)->out)

/* These macros are used by passes that are not tolerant of

   uninitialized variables.  This intolerance should eventually

   be fixed.  */

#define DF_LR_IN(BB) (DF_LR_BB_INFO(BB)->in)

#define DF_LR_OUT(BB) (DF_LR_BB_INFO(BB)->out)

/* These macros are used by passes that are not tolerant of

   uninitialized variables.  This intolerance should eventually

   be fixed.  */

#define DF_BYTE_LR_IN(BB) (DF_BYTE_LR_BB_INFO(BB)->in)

#define DF_BYTE_LR_OUT(BB) (DF_BYTE_LR_BB_INFO(BB)->out)

/* Macros to access the elements within the ref structure.  */

#define DF_REF_REAL_REG(REF) (GET_CODE ((REF)->base.reg) == SUBREG \

                                ? SUBREG_REG ((REF)->base.reg) : ((REF)->base.reg))

#define DF_REF_REGNO(REF) ((REF)->base.regno)

#define DF_REF_REAL_LOC(REF) (GET_CODE (*((REF)->regular_ref.loc)) == SUBREG \

                               ? &SUBREG_REG (*((REF)->regular_ref.loc)) : ((REF)->regular_ref.loc))

#define DF_REF_REG(REF) ((REF)->base.reg)

#define DF_REF_LOC(REF) ((DF_REF_CLASS(REF) == DF_REF_REGULAR || DF_REF_CLASS(REF) == DF_REF_EXTRACT) ? \

                         (REF)->regular_ref.loc : NULL)

#define DF_REF_BB(REF) (DF_REF_IS_ARTIFICIAL(REF) ? \

                        (REF)->artificial_ref.bb : BLOCK_FOR_INSN (DF_REF_INSN(REF)))

#define DF_REF_BBNO(REF) (DF_REF_BB (REF)->index)

#define DF_REF_INSN_INFO(REF) ((REF)->base.insn_info)

#define DF_REF_INSN(REF) ((REF)->base.insn_info->insn)

#define DF_REF_INSN_UID(REF) (INSN_UID (DF_REF_INSN(REF)))

#define DF_REF_CLASS(REF) ((REF)->base.cl)

#define DF_REF_TYPE(REF) ((REF)->base.type)

#define DF_REF_CHAIN(REF) ((REF)->base.chain)

#define DF_REF_ID(REF) ((REF)->base.id)

#define DF_REF_FLAGS(REF) ((REF)->base.flags)

#define DF_REF_FLAGS_IS_SET(REF, v) ((DF_REF_FLAGS (REF) & (v)) != 0)

#define DF_REF_FLAGS_SET(REF, v) (DF_REF_FLAGS (REF) |= (v))

#define DF_REF_FLAGS_CLEAR(REF, v) (DF_REF_FLAGS (REF) &= ~(v))

#define DF_REF_ORDER(REF) ((REF)->base.ref_order)

/* If DF_REF_IS_ARTIFICIAL () is true, this is not a real

   definition/use, but an artificial one created to model always live

   registers, eh uses, etc.  */

#define DF_REF_IS_ARTIFICIAL(REF) (DF_REF_CLASS(REF) == DF_REF_ARTIFICIAL)

#define DF_REF_REG_MARK(REF) (DF_REF_FLAGS_SET ((REF),DF_REF_REG_MARKER))

#define DF_REF_REG_UNMARK(REF) (DF_REF_FLAGS_CLEAR ((REF),DF_REF_REG_MARKER))

#define DF_REF_IS_REG_MARKED(REF) (DF_REF_FLAGS_IS_SET ((REF),DF_REF_REG_MARKER))

#define DF_REF_NEXT_REG(REF) ((REF)->base.next_reg)

#define DF_REF_PREV_REG(REF) ((REF)->base.prev_reg)

/* The following two macros may only be applied if one of

   DF_REF_SIGN_EXTRACT | DF_REF_ZERO_EXTRACT is true. */

#define DF_REF_EXTRACT_WIDTH(REF) ((REF)->extract_ref.width)

#define DF_REF_EXTRACT_OFFSET(REF) ((REF)->extract_ref.offset)

#define DF_REF_EXTRACT_MODE(REF) ((REF)->extract_ref.mode)

/* Macros to determine the reference type.  */

#define DF_REF_REG_DEF_P(REF) (DF_REF_TYPE (REF) == DF_REF_REG_DEF)

#define DF_REF_REG_USE_P(REF) ((REF) && !DF_REF_REG_DEF_P (REF))

#define DF_REF_REG_MEM_STORE_P(REF) (DF_REF_TYPE (REF) == DF_REF_REG_MEM_STORE)

#define DF_REF_REG_MEM_LOAD_P(REF) (DF_REF_TYPE (REF) == DF_REF_REG_MEM_LOAD)

#define DF_REF_REG_MEM_P(REF) (DF_REF_REG_MEM_STORE_P (REF) \

                               || DF_REF_REG_MEM_LOAD_P (REF))

#define DF_MWS_REG_DEF_P(MREF) (DF_MWS_TYPE (MREF) == DF_REF_REG_DEF)

#define DF_MWS_REG_USE_P(MREF) ((MREF) && !DF_MWS_REG_DEF_P (MREF))

#define DF_MWS_TYPE(MREF) ((MREF)->type)

/* Macros to get the refs out of def_info or use_info refs table.  If

   the focus of the dataflow has been set to some subset of blocks

   with df_set_blocks, these macros will only find the uses and defs

   in that subset of blocks.

   These macros should be used with care.  The def macros are only

   usable after a call to df_maybe_reorganize_def_refs and the use

   macros are only usable after a call to

   df_maybe_reorganize_use_refs.  HOWEVER, BUILDING AND USING THESE

   ARRAYS ARE A CACHE LOCALITY KILLER.  */

#define DF_DEFS_TABLE_SIZE() (df->def_info.table_size)

#define DF_DEFS_GET(ID) (df->def_info.refs[(ID)])

#define DF_DEFS_SET(ID,VAL) (df->def_info.refs[(ID)]=(VAL))

#define DF_DEFS_COUNT(ID) (df->def_info.count[(ID)])

#define DF_DEFS_BEGIN(ID) (df->def_info.begin[(ID)])

#define DF_USES_TABLE_SIZE() (df->use_info.table_size)

#define DF_USES_GET(ID) (df->use_info.refs[(ID)])

#define DF_USES_SET(ID,VAL) (df->use_info.refs[(ID)]=(VAL))

#define DF_USES_COUNT(ID) (df->use_info.count[(ID)])

#define DF_USES_BEGIN(ID) (df->use_info.begin[(ID)])

/* Macros to access the register information from scan dataflow record.  */

#define DF_REG_SIZE(DF) (df->regs_inited)

#define DF_REG_DEF_GET(REG) (df->def_regs[(REG)])

#define DF_REG_DEF_CHAIN(REG) (df->def_regs[(REG)]->reg_chain)

#define DF_REG_DEF_COUNT(REG) (df->def_regs[(REG)]->n_refs)

#define DF_REG_USE_GET(REG) (df->use_regs[(REG)])

#define DF_REG_USE_CHAIN(REG) (df->use_regs[(REG)]->reg_chain)

#define DF_REG_USE_COUNT(REG) (df->use_regs[(REG)]->n_refs)

#define DF_REG_EQ_USE_GET(REG) (df->eq_use_regs[(REG)])

#define DF_REG_EQ_USE_CHAIN(REG) (df->eq_use_regs[(REG)]->reg_chain)

#define DF_REG_EQ_USE_COUNT(REG) (df->eq_use_regs[(REG)]->n_refs)

/* Macros to access the elements within the reg_info structure table.  */

#define DF_REGNO_FIRST_DEF(REGNUM) \

(DF_REG_DEF_GET(REGNUM) ? DF_REG_DEF_GET(REGNUM) : 0)

#define DF_REGNO_LAST_USE(REGNUM) \

(DF_REG_USE_GET(REGNUM) ? DF_REG_USE_GET(REGNUM) : 0)

/* Macros to access the elements within the insn_info structure table.  */

#define DF_INSN_SIZE() ((df)->insns_size)

#define DF_INSN_INFO_GET(INSN) (df->insns[(INSN_UID(INSN))])

#define DF_INSN_INFO_SET(INSN,VAL) (df->insns[(INSN_UID (INSN))]=(VAL))

#define DF_INSN_INFO_LUID(II) ((II)->luid)

#define DF_INSN_INFO_DEFS(II) ((II)->defs)

#define DF_INSN_INFO_USES(II) ((II)->uses)

#define DF_INSN_INFO_EQ_USES(II) ((II)->eq_uses)

#define DF_INSN_LUID(INSN) (DF_INSN_INFO_LUID (DF_INSN_INFO_GET(INSN)))

#define DF_INSN_DEFS(INSN) (DF_INSN_INFO_DEFS (DF_INSN_INFO_GET(INSN)))

#define DF_INSN_USES(INSN) (DF_INSN_INFO_USES (DF_INSN_INFO_GET(INSN)))

#define DF_INSN_EQ_USES(INSN) (DF_INSN_INFO_EQ_USES (DF_INSN_INFO_GET(INSN)))

#define DF_INSN_UID_GET(UID) (df->insns[(UID)])

#define DF_INSN_UID_SET(UID,VAL) (df->insns[(UID)]=(VAL))

#define DF_INSN_UID_SAFE_GET(UID) (((unsigned)(UID) < DF_INSN_SIZE())   \

                                     ? DF_INSN_UID_GET (UID) \

                                     : NULL)

#define DF_INSN_UID_LUID(INSN) (DF_INSN_UID_GET(INSN)->luid)

#define DF_INSN_UID_DEFS(INSN) (DF_INSN_UID_GET(INSN)->defs)

#define DF_INSN_UID_USES(INSN) (DF_INSN_UID_GET(INSN)->uses)

#define DF_INSN_UID_EQ_USES(INSN) (DF_INSN_UID_GET(INSN)->eq_uses)

#define DF_INSN_UID_MWS(INSN) (DF_INSN_UID_GET(INSN)->mw_hardregs)

/* An obstack for bitmap not related to specific dataflow problems.

   This obstack should e.g. be used for bitmaps with a short life time

   such as temporary bitmaps.  This obstack is declared in df-core.c.  */

extern bitmap_obstack df_bitmap_obstack;

/* One of these structures is allocated for every basic block.  */

struct df_scan_bb_info

{

  /* The entry block has many artificial defs and these are at the

     bottom of the block.

     Blocks that are targets of exception edges may have some

     artificial defs.  These are logically located at the top of the

     block.

     Blocks that are the targets of non-local goto's have the hard

     frame pointer defined at the top of the block.  */

  df_ref *artificial_defs;

  /* Blocks that are targets of exception edges may have some

     artificial uses.  These are logically at the top of the block.

     Most blocks have artificial uses at the bottom of the block.  */

  df_ref *artificial_uses;

};

/* Reaching definitions.  All bitmaps are indexed by the id field of

   the ref except sparse_kill which is indexed by regno.  */

struct df_rd_bb_info

{

  /* Local sets to describe the basic blocks.   */

  bitmap kill;

  bitmap sparse_kill;

  bitmap gen;   /* The set of defs generated in this block.  */

  /* The results of the dataflow problem.  */