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binutils-gdb/gas/config/tc-ia64.c

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/* tc-ia64.c -- Assembler for the HP/Intel IA-64 architecture.
Copyright (C) 1998, 1999, 2000 Free Software Foundation.
Contributed by David Mosberger-Tang <davidm@hpl.hp.com>
This file is part of GAS, the GNU Assembler.
GAS 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 2, or (at your option)
any later version.
GAS 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 GAS; see the file COPYING. If not, write to
the Free Software Foundation, 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA. */
/*
TODO:
- optional operands
- directives:
.alias
.eb
.estate
.lb
.popsection
.previous
.psr
.pushsection
- labels are wrong if automatic alignment is introduced
(e.g., checkout the second real10 definition in test-data.s)
- DV-related stuff:
<reg>.safe_across_calls and any other DV-related directives I don't
have documentation for.
verify mod-sched-brs reads/writes are checked/marked (and other
notes)
*/
#include "as.h"
#include "dwarf2dbg.h"
#include "subsegs.h"
#include "opcode/ia64.h"
#include "elf/ia64.h"
#define NELEMS(a) ((int) (sizeof (a)/sizeof ((a)[0])))
#define MIN(a,b) ((a) < (b) ? (a) : (b))
#define NUM_SLOTS 4
#define PREV_SLOT md.slot[(md.curr_slot + NUM_SLOTS - 1) % NUM_SLOTS]
#define CURR_SLOT md.slot[md.curr_slot]
#define O_pseudo_fixup (O_max + 1)
enum special_section
{
SPECIAL_SECTION_BSS = 0,
SPECIAL_SECTION_SBSS,
SPECIAL_SECTION_SDATA,
SPECIAL_SECTION_RODATA,
SPECIAL_SECTION_COMMENT,
SPECIAL_SECTION_UNWIND,
SPECIAL_SECTION_UNWIND_INFO
};
enum reloc_func
{
FUNC_FPTR_RELATIVE,
FUNC_GP_RELATIVE,
FUNC_LT_RELATIVE,
FUNC_PC_RELATIVE,
FUNC_PLT_RELATIVE,
FUNC_SEC_RELATIVE,
FUNC_SEG_RELATIVE,
FUNC_LTV_RELATIVE,
FUNC_LT_FPTR_RELATIVE,
};
enum reg_symbol
{
REG_GR = 0,
REG_FR = (REG_GR + 128),
REG_AR = (REG_FR + 128),
REG_CR = (REG_AR + 128),
REG_P = (REG_CR + 128),
REG_BR = (REG_P + 64),
REG_IP = (REG_BR + 8),
REG_CFM,
REG_PR,
REG_PR_ROT,
REG_PSR,
REG_PSR_L,
REG_PSR_UM,
/* The following are pseudo-registers for use by gas only. */
IND_CPUID,
IND_DBR,
IND_DTR,
IND_ITR,
IND_IBR,
IND_MEM,
IND_MSR,
IND_PKR,
IND_PMC,
IND_PMD,
IND_RR,
/* The following pseudo-registers are used for unwind directives only: */
REG_PSP,
REG_PRIUNAT,
REG_NUM
};
enum dynreg_type
{
DYNREG_GR = 0, /* dynamic general purpose register */
DYNREG_FR, /* dynamic floating point register */
DYNREG_PR, /* dynamic predicate register */
DYNREG_NUM_TYPES
};
/* On the ia64, we can't know the address of a text label until the
instructions are packed into a bundle. To handle this, we keep
track of the list of labels that appear in front of each
instruction. */
struct label_fix
{
struct label_fix *next;
struct symbol *sym;
};
extern int target_big_endian;
/* Characters which always start a comment. */
const char comment_chars[] = "";
/* Characters which start a comment at the beginning of a line. */
const char line_comment_chars[] = "#";
/* Characters which may be used to separate multiple commands on a
single line. */
const char line_separator_chars[] = ";";
/* Characters which are used to indicate an exponent in a floating
point number. */
const char EXP_CHARS[] = "eE";
/* Characters which mean that a number is a floating point constant,
as in 0d1.0. */
const char FLT_CHARS[] = "rRsSfFdDxXpP";
/* ia64-specific option processing: */
const char *md_shortopts = "M:N:x::";
struct option md_longopts[] =
{
{ NULL, no_argument, NULL, 0}
};
size_t md_longopts_size = sizeof (md_longopts);
static struct
{
struct hash_control *pseudo_hash; /* pseudo opcode hash table */
struct hash_control *reg_hash; /* register name hash table */
struct hash_control *dynreg_hash; /* dynamic register hash table */
struct hash_control *const_hash; /* constant hash table */
struct hash_control *entry_hash; /* code entry hint hash table */
symbolS *regsym[REG_NUM];
/* If X_op is != O_absent, the registername for the instruction's
qualifying predicate. If NULL, p0 is assumed for instructions
that are predicatable. */
expressionS qp;
unsigned int
manual_bundling : 1,
debug_dv: 1,
detect_dv: 1,
explicit_mode : 1, /* which mode we're in */
default_explicit_mode : 1, /* which mode is the default */
mode_explicitly_set : 1, /* was the current mode explicitly set? */
auto_align : 1;
/* Each bundle consists of up to three instructions. We keep
track of four most recent instructions so we can correctly set
the end_of_insn_group for the last instruction in a bundle. */
int curr_slot;
int num_slots_in_use;
struct slot
{
unsigned int
end_of_insn_group : 1,
manual_bundling_on : 1,
manual_bundling_off : 1;
signed char user_template; /* user-selected template, if any */
unsigned char qp_regno; /* qualifying predicate */
/* This duplicates a good fraction of "struct fix" but we
can't use a "struct fix" instead since we can't call
fix_new_exp() until we know the address of the instruction. */
int num_fixups;
struct insn_fix
{
bfd_reloc_code_real_type code;
enum ia64_opnd opnd; /* type of operand in need of fix */
unsigned int is_pcrel : 1; /* is operand pc-relative? */
expressionS expr; /* the value to be inserted */
}
fixup[2]; /* at most two fixups per insn */
struct ia64_opcode *idesc;
struct label_fix *label_fixups;
struct unw_rec_list *unwind_record; /* Unwind directive. */
expressionS opnd[6];
char *src_file;
unsigned int src_line;
struct dwarf2_line_info debug_line;
}
slot[NUM_SLOTS];
segT last_text_seg;
struct dynreg
{
struct dynreg *next; /* next dynamic register */
const char *name;
unsigned short base; /* the base register number */
unsigned short num_regs; /* # of registers in this set */
}
*dynreg[DYNREG_NUM_TYPES], in, loc, out, rot;
flagword flags; /* ELF-header flags */
struct mem_offset {
unsigned hint:1; /* is this hint currently valid? */
bfd_vma offset; /* mem.offset offset */
bfd_vma base; /* mem.offset base */
} mem_offset;
int path; /* number of alt. entry points seen */
const char **entry_labels; /* labels of all alternate paths in
the current DV-checking block. */
int maxpaths; /* size currently allocated for
entry_labels */
}
md;
/* application registers: */
#define AR_K0 0
#define AR_K7 7
#define AR_RSC 16
#define AR_BSP 17
#define AR_BSPSTORE 18
#define AR_RNAT 19
#define AR_UNAT 36
#define AR_FPSR 40
#define AR_ITC 44
#define AR_PFS 64
#define AR_LC 65
static const struct
{
const char *name;
int regnum;
}
ar[] =
{
{"ar.k0", 0}, {"ar.k1", 1}, {"ar.k2", 2}, {"ar.k3", 3},
{"ar.k4", 4}, {"ar.k5", 5}, {"ar.k6", 6}, {"ar.k7", 7},
{"ar.rsc", 16}, {"ar.bsp", 17},
{"ar.bspstore", 18}, {"ar.rnat", 19},
{"ar.fcr", 21}, {"ar.eflag", 24},
{"ar.csd", 25}, {"ar.ssd", 26},
{"ar.cflg", 27}, {"ar.fsr", 28},
{"ar.fir", 29}, {"ar.fdr", 30},
{"ar.ccv", 32}, {"ar.unat", 36},
{"ar.fpsr", 40}, {"ar.itc", 44},
{"ar.pfs", 64}, {"ar.lc", 65},
{"ar.ec", 66},
};
#define CR_IPSR 16
#define CR_ISR 17
#define CR_IIP 19
#define CR_IFA 20
#define CR_ITIR 21
#define CR_IIPA 22
#define CR_IFS 23
#define CR_IIM 24
#define CR_IHA 25
#define CR_IVR 65
#define CR_TPR 66
#define CR_EOI 67
#define CR_IRR0 68
#define CR_IRR3 71
#define CR_LRR0 80
#define CR_LRR1 81
/* control registers: */
static const struct
{
const char *name;
int regnum;
}
cr[] =
{
{"cr.dcr", 0},
{"cr.itm", 1},
{"cr.iva", 2},
{"cr.pta", 8},
{"cr.gpta", 9},
{"cr.ipsr", 16},
{"cr.isr", 17},
{"cr.iip", 19},
{"cr.ifa", 20},
{"cr.itir", 21},
{"cr.iipa", 22},
{"cr.ifs", 23},
{"cr.iim", 24},
{"cr.iha", 25},
{"cr.lid", 64},
{"cr.ivr", 65},
{"cr.tpr", 66},
{"cr.eoi", 67},
{"cr.irr0", 68},
{"cr.irr1", 69},
{"cr.irr2", 70},
{"cr.irr3", 71},
{"cr.itv", 72},
{"cr.pmv", 73},
{"cr.cmcv", 74},
{"cr.lrr0", 80},
{"cr.lrr1", 81}
};
#define PSR_MFL 4
#define PSR_IC 13
#define PSR_DFL 18
#define PSR_CPL 32
static const struct const_desc
{
const char *name;
valueT value;
}
const_bits[] =
{
/* PSR constant masks: */
/* 0: reserved */
{"psr.be", ((valueT) 1) << 1},
{"psr.up", ((valueT) 1) << 2},
{"psr.ac", ((valueT) 1) << 3},
{"psr.mfl", ((valueT) 1) << 4},
{"psr.mfh", ((valueT) 1) << 5},
/* 6-12: reserved */
{"psr.ic", ((valueT) 1) << 13},
{"psr.i", ((valueT) 1) << 14},
{"psr.pk", ((valueT) 1) << 15},
/* 16: reserved */
{"psr.dt", ((valueT) 1) << 17},
{"psr.dfl", ((valueT) 1) << 18},
{"psr.dfh", ((valueT) 1) << 19},
{"psr.sp", ((valueT) 1) << 20},
{"psr.pp", ((valueT) 1) << 21},
{"psr.di", ((valueT) 1) << 22},
{"psr.si", ((valueT) 1) << 23},
{"psr.db", ((valueT) 1) << 24},
{"psr.lp", ((valueT) 1) << 25},
{"psr.tb", ((valueT) 1) << 26},
{"psr.rt", ((valueT) 1) << 27},
/* 28-31: reserved */
/* 32-33: cpl (current privilege level) */
{"psr.is", ((valueT) 1) << 34},
{"psr.mc", ((valueT) 1) << 35},
{"psr.it", ((valueT) 1) << 36},
{"psr.id", ((valueT) 1) << 37},
{"psr.da", ((valueT) 1) << 38},
{"psr.dd", ((valueT) 1) << 39},
{"psr.ss", ((valueT) 1) << 40},
/* 41-42: ri (restart instruction) */
{"psr.ed", ((valueT) 1) << 43},
{"psr.bn", ((valueT) 1) << 44},
};
/* indirect register-sets/memory: */
static const struct
{
const char *name;
int regnum;
}
indirect_reg[] =
{
{ "CPUID", IND_CPUID },
{ "cpuid", IND_CPUID },
{ "dbr", IND_DBR },
{ "dtr", IND_DTR },
{ "itr", IND_ITR },
{ "ibr", IND_IBR },
{ "msr", IND_MSR },
{ "pkr", IND_PKR },
{ "pmc", IND_PMC },
{ "pmd", IND_PMD },
{ "rr", IND_RR },
};
/* Pseudo functions used to indicate relocation types (these functions
start with an at sign (@). */
static struct
{
const char *name;
enum pseudo_type
{
PSEUDO_FUNC_NONE,
PSEUDO_FUNC_RELOC,
PSEUDO_FUNC_CONST,
PSEUDO_FUNC_REG,
PSEUDO_FUNC_FLOAT
}
type;
union
{
unsigned long ival;
symbolS *sym;
}
u;
}
pseudo_func[] =
{
/* reloc pseudo functions (these must come first!): */
{ "fptr", PSEUDO_FUNC_RELOC },
{ "gprel", PSEUDO_FUNC_RELOC },
{ "ltoff", PSEUDO_FUNC_RELOC },
{ "pcrel", PSEUDO_FUNC_RELOC },
{ "pltoff", PSEUDO_FUNC_RELOC },
{ "secrel", PSEUDO_FUNC_RELOC },
{ "segrel", PSEUDO_FUNC_RELOC },
{ "ltv", PSEUDO_FUNC_RELOC },
{ 0, }, /* placeholder for FUNC_LT_FPTR_RELATIVE */
/* mbtype4 constants: */
{ "alt", PSEUDO_FUNC_CONST, { 0xa } },
{ "brcst", PSEUDO_FUNC_CONST, { 0x0 } },
{ "mix", PSEUDO_FUNC_CONST, { 0x8 } },
{ "rev", PSEUDO_FUNC_CONST, { 0xb } },
{ "shuf", PSEUDO_FUNC_CONST, { 0x9 } },
/* fclass constants: */
{ "nat", PSEUDO_FUNC_CONST, { 0x100 } },
{ "qnan", PSEUDO_FUNC_CONST, { 0x080 } },
{ "snan", PSEUDO_FUNC_CONST, { 0x040 } },
{ "pos", PSEUDO_FUNC_CONST, { 0x001 } },
{ "neg", PSEUDO_FUNC_CONST, { 0x002 } },
{ "zero", PSEUDO_FUNC_CONST, { 0x004 } },
{ "unorm", PSEUDO_FUNC_CONST, { 0x008 } },
{ "norm", PSEUDO_FUNC_CONST, { 0x010 } },
{ "inf", PSEUDO_FUNC_CONST, { 0x020 } },
{ "natval", PSEUDO_FUNC_CONST, { 0x100 } }, /* old usage */
/* unwind-related constants: */
{ "svr4", PSEUDO_FUNC_CONST, { 0 } },
{ "hpux", PSEUDO_FUNC_CONST, { 1 } },
{ "nt", PSEUDO_FUNC_CONST, { 2 } },
/* unwind-related registers: */
{ "priunat",PSEUDO_FUNC_REG, { REG_PRIUNAT } }
};
/* 41-bit nop opcodes (one per unit): */
static const bfd_vma nop[IA64_NUM_UNITS] =
{
0x0000000000LL, /* NIL => break 0 */
0x0008000000LL, /* I-unit nop */
0x0008000000LL, /* M-unit nop */
0x4000000000LL, /* B-unit nop */
0x0008000000LL, /* F-unit nop */
0x0008000000LL, /* L-"unit" nop */
0x0008000000LL, /* X-unit nop */
};
/* Can't be `const' as it's passed to input routines (which have the
habit of setting temporary sentinels. */
static char special_section_name[][20] =
{
{".bss"}, {".sbss"}, {".sdata"}, {".rodata"}, {".comment"},
{".IA_64.unwind"}, {".IA_64.unwind_info"}
};
/* The best template for a particular sequence of up to three
instructions: */
#define N IA64_NUM_TYPES
static unsigned char best_template[N][N][N];
#undef N
/* Resource dependencies currently in effect */
static struct rsrc {
int depind; /* dependency index */
const struct ia64_dependency *dependency; /* actual dependency */
unsigned specific:1, /* is this a specific bit/regno? */
link_to_qp_branch:1; /* will a branch on the same QP clear it?*/
int index; /* specific regno/bit within dependency */
int note; /* optional qualifying note (0 if none) */
#define STATE_NONE 0
#define STATE_STOP 1
#define STATE_SRLZ 2
int insn_srlz; /* current insn serialization state */
int data_srlz; /* current data serialization state */
int qp_regno; /* qualifying predicate for this usage */
char *file; /* what file marked this dependency */
int line; /* what line marked this dependency */
struct mem_offset mem_offset; /* optional memory offset hint */
int path; /* corresponding code entry index */
} *regdeps = NULL;
static int regdepslen = 0;
static int regdepstotlen = 0;
static const char *dv_mode[] = { "RAW", "WAW", "WAR" };
static const char *dv_sem[] = { "none", "implied", "impliedf",
"data", "instr", "specific", "other" };
/* Current state of PR mutexation */
static struct qpmutex {
valueT prmask;
int path;
} *qp_mutexes = NULL; /* QP mutex bitmasks */
static int qp_mutexeslen = 0;
static int qp_mutexestotlen = 0;
static valueT qp_safe_across_calls = 0;
/* Current state of PR implications */
static struct qp_imply {
unsigned p1:6;
unsigned p2:6;
unsigned p2_branched:1;
int path;
} *qp_implies = NULL;
static int qp_implieslen = 0;
static int qp_impliestotlen = 0;
/* Keep track of static GR values so that indirect register usage can
sometimes be tracked. */
static struct gr {
unsigned known:1;
int path;
valueT value;
} gr_values[128] = {{ 1, 0 }};
/* These are the routines required to output the various types of
unwind records. */
typedef struct unw_rec_list {
unwind_record r;
unsigned long slot_number;
struct unw_rec_list *next;
} unw_rec_list;
#define SLOT_NUM_NOT_SET -1
static struct
{
unsigned long next_slot_number;
/* Maintain a list of unwind entries for the current function. */
unw_rec_list *list;
unw_rec_list *tail;
/* Any unwind entires that should be attached to the current slot
that an insn is being constructed for. */
unw_rec_list *current_entry;
/* These are used to create the unwind table entry for this function. */
symbolS *proc_start;
symbolS *proc_end;
symbolS *info; /* pointer to unwind info */
symbolS *personality_routine;
/* TRUE if processing unwind directives in a prologue region. */
int prologue;
} unwind;
typedef void (*vbyte_func) PARAMS ((int, char *, char *));
/* Forward delarations: */
static int ar_is_in_integer_unit PARAMS ((int regnum));
static void set_section PARAMS ((char *name));
static unsigned int set_regstack PARAMS ((unsigned int, unsigned int,
unsigned int, unsigned int));
static void dot_radix PARAMS ((int));
static void dot_special_section PARAMS ((int));
static void dot_proc PARAMS ((int));
static void dot_fframe PARAMS ((int));
static void dot_vframe PARAMS ((int));
static void dot_save PARAMS ((int));
static void dot_restore PARAMS ((int));
static void dot_handlerdata PARAMS ((int));
static void dot_unwentry PARAMS ((int));
static void dot_altrp PARAMS ((int));
static void dot_savemem PARAMS ((int));
static void dot_saveg PARAMS ((int));
static void dot_savef PARAMS ((int));
static void dot_saveb PARAMS ((int));
static void dot_savegf PARAMS ((int));
static void dot_spill PARAMS ((int));
static void dot_unwabi PARAMS ((int));
static void dot_personality PARAMS ((int));
static void dot_body PARAMS ((int));
static void dot_prologue PARAMS ((int));
static void dot_endp PARAMS ((int));
static void dot_template PARAMS ((int));
static void dot_regstk PARAMS ((int));
static void dot_rot PARAMS ((int));
static void dot_byteorder PARAMS ((int));
static void dot_psr PARAMS ((int));
static void dot_alias PARAMS ((int));
static void dot_ln PARAMS ((int));
static char *parse_section_name PARAMS ((void));
static void dot_xdata PARAMS ((int));
static void stmt_float_cons PARAMS ((int));
static void stmt_cons_ua PARAMS ((int));
static void dot_xfloat_cons PARAMS ((int));
static void dot_xstringer PARAMS ((int));
static void dot_xdata_ua PARAMS ((int));
static void dot_xfloat_cons_ua PARAMS ((int));
static void dot_pred_rel PARAMS ((int));
static void dot_reg_val PARAMS ((int));
static void dot_dv_mode PARAMS ((int));
static void dot_entry PARAMS ((int));
static void dot_mem_offset PARAMS ((int));
static void add_unwind_entry PARAMS((unw_rec_list *ptr));
static symbolS* declare_register PARAMS ((const char *name, int regnum));
static void declare_register_set PARAMS ((const char *, int, int));
static unsigned int operand_width PARAMS ((enum ia64_opnd));
static int operand_match PARAMS ((const struct ia64_opcode *idesc,
int index, expressionS *e));
static int parse_operand PARAMS ((expressionS *e));
static struct ia64_opcode * parse_operands PARAMS ((struct ia64_opcode *));
static void build_insn PARAMS ((struct slot *, bfd_vma *));
static void emit_one_bundle PARAMS ((void));
static void fix_insn PARAMS ((fixS *, const struct ia64_operand *, valueT));
static bfd_reloc_code_real_type ia64_gen_real_reloc_type PARAMS ((struct symbol *sym,
bfd_reloc_code_real_type r_type));
static void insn_group_break PARAMS ((int, int, int));
static void add_qp_mutex PARAMS((valueT mask));
static void add_qp_imply PARAMS((int p1, int p2));
static void clear_qp_branch_flag PARAMS((valueT mask));
static void clear_qp_mutex PARAMS((valueT mask));
static void clear_qp_implies PARAMS((valueT p1_mask, valueT p2_mask));
static void clear_register_values PARAMS ((void));
static void print_dependency PARAMS ((const char *action, int depind));
static int is_conditional_branch PARAMS ((struct ia64_opcode *));
static int is_interruption_or_rfi PARAMS ((struct ia64_opcode *));
static int check_dv PARAMS((struct ia64_opcode *idesc));
static void check_dependencies PARAMS((struct ia64_opcode *));
static void mark_resources PARAMS((struct ia64_opcode *));
static void update_dependencies PARAMS((struct ia64_opcode *));
static void note_register_values PARAMS((struct ia64_opcode *));
static void output_R3_format PARAMS ((vbyte_func, unw_record_type, unsigned long));
static void output_B3_format PARAMS ((vbyte_func, unsigned long, unsigned long));
static void output_B4_format PARAMS ((vbyte_func, unw_record_type, unsigned long));
/* Determine if application register REGNUM resides in the integer
unit (as opposed to the memory unit). */
static int
ar_is_in_integer_unit (reg)
int reg;
{
reg -= REG_AR;
return (reg == 64 /* pfs */
|| reg == 65 /* lc */
|| reg == 66 /* ec */
/* ??? ias accepts and puts these in the integer unit. */
|| (reg >= 112 && reg <= 127));
}
/* Switch to section NAME and create section if necessary. It's
rather ugly that we have to manipulate input_line_pointer but I
don't see any other way to accomplish the same thing without
changing obj-elf.c (which may be the Right Thing, in the end). */
static void
set_section (name)
char *name;
{
char *saved_input_line_pointer;
saved_input_line_pointer = input_line_pointer;
input_line_pointer = name;
obj_elf_section (0);
input_line_pointer = saved_input_line_pointer;
}
/* Map SHF_IA_64_SHORT to SEC_SMALL_DATA. */
flagword
ia64_elf_section_flags (flags, attr, type)
flagword flags;
int attr, type;
{
if (attr & SHF_IA_64_SHORT)
flags |= SEC_SMALL_DATA;
return flags;
}
static unsigned int
set_regstack (ins, locs, outs, rots)
unsigned int ins, locs, outs, rots;
{
unsigned int sof; /* size of frame */
sof = ins + locs + outs;
if (sof > 96)
{
as_bad ("Size of frame exceeds maximum of 96 registers");
return 0;
}
if (rots > sof)
{
as_warn ("Size of rotating registers exceeds frame size");
return 0;
}
md.in.base = REG_GR + 32;
md.loc.base = md.in.base + ins;
md.out.base = md.loc.base + locs;
md.in.num_regs = ins;
md.loc.num_regs = locs;
md.out.num_regs = outs;
md.rot.num_regs = rots;
return sof;
}
void
ia64_flush_insns ()
{
struct label_fix *lfix;
segT saved_seg;
subsegT saved_subseg;
if (!md.last_text_seg)
return;
saved_seg = now_seg;
saved_subseg = now_subseg;
subseg_set (md.last_text_seg, 0);
while (md.num_slots_in_use > 0)
emit_one_bundle (); /* force out queued instructions */
/* In case there are labels following the last instruction, resolve
those now: */
for (lfix = CURR_SLOT.label_fixups; lfix; lfix = lfix->next)
{
S_SET_VALUE (lfix->sym, frag_now_fix ());
symbol_set_frag (lfix->sym, frag_now);
}
CURR_SLOT.label_fixups = 0;
subseg_set (saved_seg, saved_subseg);
}
void
ia64_do_align (nbytes)
int nbytes;
{
char *saved_input_line_pointer = input_line_pointer;
input_line_pointer = "";
s_align_bytes (nbytes);
input_line_pointer = saved_input_line_pointer;
}
void
ia64_cons_align (nbytes)
int nbytes;
{
if (md.auto_align)
{
char *saved_input_line_pointer = input_line_pointer;
input_line_pointer = "";
s_align_bytes (nbytes);
input_line_pointer = saved_input_line_pointer;
}
}
/* Output COUNT bytes to a memory location. */
static unsigned char *vbyte_mem_ptr = NULL;
void
output_vbyte_mem (count, ptr, comment)
int count;
char *ptr;
char *comment;
{
int x;
if (vbyte_mem_ptr == NULL)
abort ();
if (count == 0)
return;
for (x = 0; x < count; x++)
*(vbyte_mem_ptr++) = ptr[x];
}
/* Count the number of bytes required for records. */
static int vbyte_count = 0;
void
count_output (count, ptr, comment)
int count;
char *ptr;
char *comment;
{
vbyte_count += count;
}
static void
output_R1_format (f, rtype, rlen)
vbyte_func f;
unw_record_type rtype;
int rlen;
{
int r = 0;
char byte;
if (rlen > 0x1f)
{
output_R3_format (f, rtype, rlen);
return;
}
if (rtype == body)
r = 1;
else if (rtype != prologue)
as_bad ("record type is not valid");
byte = UNW_R1 | (r << 5) | (rlen & 0x1f);
(*f) (1, &byte, NULL);
}
static void
output_R2_format (f, mask, grsave, rlen)
vbyte_func f;
int mask, grsave;
unsigned long rlen;
{
char bytes[20];
int count = 2;
mask = (mask & 0x0f);
grsave = (grsave & 0x7f);
bytes[0] = (UNW_R2 | (mask >> 1));
bytes[1] = (((mask & 0x01) << 7) | grsave);
count += output_leb128 (bytes + 2, rlen, 0);
(*f) (count, bytes, NULL);
}
static void
output_R3_format (f, rtype, rlen)
vbyte_func f;
unw_record_type rtype;
unsigned long rlen;
{
int r = 0, count;
char bytes[20];
if (rlen <= 0x1f)
{
output_R1_format (f, rtype, rlen);
return;
}
if (rtype == body)
r = 1;
else if (rtype != prologue)
as_bad ("record type is not valid");
bytes[0] = (UNW_R3 | r);
count = output_leb128 (bytes + 1, rlen, 0);
(*f) (count + 1, bytes, NULL);
}
static void
output_P1_format (f, brmask)
vbyte_func f;
int brmask;
{
char byte;
byte = UNW_P1 | (brmask & 0x1f);
(*f) (1, &byte, NULL);
}
static void
output_P2_format (f, brmask, gr)
vbyte_func f;
int brmask;
int gr;
{
char bytes[2];
brmask = (brmask & 0x1f);
bytes[0] = UNW_P2 | (brmask >> 1);
bytes[1] = (((brmask & 1) << 7) | gr);
(*f) (2, bytes, NULL);
}
static void
output_P3_format (f, rtype, reg)
vbyte_func f;
unw_record_type rtype;
int reg;
{
char bytes[2];
int r = 0;
reg = (reg & 0x7f);
switch (rtype)
{
case psp_gr:
r = 0;
break;
case rp_gr:
r = 1;
break;
case pfs_gr:
r = 2;
break;
case preds_gr:
r = 3;
break;
case unat_gr:
r = 4;
break;
case lc_gr:
r = 5;
break;
case rp_br:
r = 6;
break;
case rnat_gr:
r = 7;
break;
case bsp_gr:
r = 8;
break;
case bspstore_gr:
r = 9;
break;
case fpsr_gr:
r = 10;
break;
case priunat_gr:
r = 11;
break;
default:
as_bad ("Invalid record type for P3 format.");
}
bytes[0] = (UNW_P3 | (r >> 1));
bytes[1] = (((r & 1) << 7) | reg);
(*f) (2, bytes, NULL);
}
static void
output_P4_format (f, imask, imask_size)
vbyte_func f;
unsigned char *imask;
unsigned long imask_size;
{
imask[0] = UNW_P4;
(*f) (imask_size, imask, NULL);
}
static void
output_P5_format (f, grmask, frmask)
vbyte_func f;
int grmask;
unsigned long frmask;
{
char bytes[4];
grmask = (grmask & 0x0f);
bytes[0] = UNW_P5;
bytes[1] = ((grmask << 4) | ((frmask & 0x000f0000) >> 16));
bytes[2] = ((frmask & 0x0000ff00) >> 8);
bytes[3] = (frmask & 0x000000ff);
(*f) (4, bytes, NULL);
}
static void
output_P6_format (f, rtype, rmask)
vbyte_func f;
unw_record_type rtype;
int rmask;
{
char byte;
int r = 0;
if (rtype == gr_mem)
r = 1;
else if (rtype != fr_mem)
as_bad ("Invalid record type for format P6");
byte = (UNW_P6 | (r << 4) | (rmask & 0x0f));
(*f) (1, &byte, NULL);
}
static void
output_P7_format (f, rtype, w1, w2)
vbyte_func f;
unw_record_type rtype;
unsigned long w1;
unsigned long w2;
{
char bytes[20];
int count = 1;
int r = 0;
count += output_leb128 (bytes + 1, w1, 0);
switch (rtype)
{
case mem_stack_f:
r = 0;
count += output_leb128 (bytes + count, w2 >> 4, 0);
break;
case mem_stack_v:
r = 1;
break;
case spill_base:
r = 2;
break;
case psp_sprel:
r = 3;
break;
case rp_when:
r = 4;
break;
case rp_psprel:
r = 5;
break;
case pfs_when:
r = 6;
break;
case pfs_psprel:
r = 7;
break;
case preds_when:
r = 8;
break;
case preds_psprel:
r = 9;
break;
case lc_when:
r = 10;
break;
case lc_psprel:
r = 11;
break;
case unat_when:
r = 12;
break;
case unat_psprel:
r = 13;
break;
case fpsr_when:
r = 14;
break;
case fpsr_psprel:
r = 15;
break;
default:
break;
}
bytes[0] = (UNW_P7 | r);
(*f) (count, bytes, NULL);
}
static void
output_P8_format (f, rtype, t)
vbyte_func f;
unw_record_type rtype;
unsigned long t;
{
char bytes[20];
int r = 0;
int count = 2;
bytes[0] = UNW_P8;
switch (rtype)
{
case rp_sprel:
r = 1;
break;
case pfs_sprel:
r = 2;
break;
case preds_sprel:
r = 3;
break;
case lc_sprel:
r = 4;
break;
case unat_sprel:
r = 5;
break;
case fpsr_sprel:
r = 6;
break;
case bsp_when:
r = 7;
break;
case bsp_psprel:
r = 8;
break;
case bsp_sprel:
r = 9;
break;
case bspstore_when:
r = 10;
break;
case bspstore_psprel:
r = 11;
break;
case bspstore_sprel:
r = 12;
break;
case rnat_when:
r = 13;
break;
case rnat_psprel:
r = 14;
break;
case rnat_sprel:
r = 15;
break;
case priunat_when_gr:
r = 16;
break;
case priunat_psprel:
r = 17;
break;
case priunat_sprel:
r = 18;
break;
case priunat_when_mem:
r = 19;
break;
default:
break;
}
bytes[1] = r;
count += output_leb128 (bytes + 2, t, 0);
(*f) (count, bytes, NULL);
}
static void
output_P9_format (f, grmask, gr)
vbyte_func f;
int grmask;
int gr;
{
char bytes[3];
bytes[0] = UNW_P9;
bytes[1] = (grmask & 0x0f);
bytes[2] = (gr & 0x7f);
(*f) (3, bytes, NULL);
}
static void
output_P10_format (f, abi, context)
vbyte_func f;
int abi;
int context;
{
char bytes[3];
bytes[0] = UNW_P10;
bytes[1] = (abi & 0xff);
bytes[2] = (context & 0xff);
(*f) (3, bytes, NULL);
}
static void
output_B1_format (f, rtype, label)
vbyte_func f;
unw_record_type rtype;
unsigned long label;
{
char byte;
int r = 0;
if (label > 0x1f)
{
output_B4_format (f, rtype, label);
return;
}
if (rtype == copy_state)
r = 1;
else if (rtype != label_state)
as_bad ("Invalid record type for format B1");
byte = (UNW_B1 | (r << 5) | (label & 0x1f));
(*f) (1, &byte, NULL);
}
static void
output_B2_format (f, ecount, t)
vbyte_func f;
unsigned long ecount;
unsigned long t;
{
char bytes[20];
int count = 1;
if (ecount > 0x1f)
{
output_B3_format (f, ecount, t);
return;
}
bytes[0] = (UNW_B2 | (ecount & 0x1f));
count += output_leb128 (bytes + 1, t, 0);
(*f) (count, bytes, NULL);
}
static void
output_B3_format (f, ecount, t)
vbyte_func f;
unsigned long ecount;
unsigned long t;
{
char bytes[20];
int count = 1;
if (ecount <= 0x1f)
{
output_B2_format (f, ecount, t);
return;
}
bytes[0] = UNW_B3;
count += output_leb128 (bytes + 1, t, 0);
count += output_leb128 (bytes + count, ecount, 0);
(*f) (count, bytes, NULL);
}
static void
output_B4_format (f, rtype, label)
vbyte_func f;
unw_record_type rtype;
unsigned long label;
{
char bytes[20];
int r = 0;
int count = 1;
if (label <= 0x1f)
{
output_B1_format (f, rtype, label);
return;
}
if (rtype == copy_state)
r = 1;
else if (rtype != label_state)
as_bad ("Invalid record type for format B1");
bytes[0] = (UNW_B4 | (r << 3));
count += output_leb128 (bytes + 1, label, 0);
(*f) (count, bytes, NULL);
}
static char
format_ab_reg (ab, reg)
int ab;
int reg;
{
int ret;
ab = (ab & 3);
reg = (reg & 0x1f);
ret = (ab << 5) | reg;
return ret;
}
static void
output_X1_format (f, rtype, ab, reg, t, w1)
vbyte_func f;
unw_record_type rtype;
int ab, reg;
unsigned long t;
unsigned long w1;
{
char bytes[20];
int r = 0;
int count = 2;
bytes[0] = UNW_X1;
if (rtype == spill_sprel)
r = 1;
else if (rtype != spill_psprel)
as_bad ("Invalid record type for format X1");
bytes[1] = ((r << 7) | format_ab_reg (ab, reg));
count += output_leb128 (bytes + 2, t, 0);
count += output_leb128 (bytes + count, w1, 0);
(*f) (count, bytes, NULL);
}
static void
output_X2_format (f, ab, reg, x, y, treg, t)
vbyte_func f;
int ab, reg;
int x, y, treg;
unsigned long t;
{
char bytes[20];
int count = 3;
bytes[0] = UNW_X2;
bytes[1] = (((x & 1) << 7) | format_ab_reg (ab, reg));
bytes[2] = (((y & 1) << 7) | (treg & 0x7f));
count += output_leb128 (bytes + 3, t, 0);
(*f) (count, bytes, NULL);
}
static void
output_X3_format (f, rtype, qp, ab, reg, t, w1)
vbyte_func f;
unw_record_type rtype;
int qp;
int ab, reg;
unsigned long t;
unsigned long w1;
{
char bytes[20];
int r = 0;
int count = 3;
bytes[0] = UNW_X3;
if (rtype == spill_sprel_p)
r = 1;
else if (rtype != spill_psprel_p)
as_bad ("Invalid record type for format X3");
bytes[1] = ((r << 7) | (qp & 0x3f));
bytes[2] = format_ab_reg (ab, reg);
count += output_leb128 (bytes + 3, t, 0);
count += output_leb128 (bytes + count, w1, 0);
(*f) (count, bytes, NULL);
}
static void
output_X4_format (f, qp, ab, reg, x, y, treg, t)
vbyte_func f;
int qp;
int ab, reg;
int x, y, treg;
unsigned long t;
{
char bytes[20];
int count = 4;
bytes[0] = UNW_X4;
bytes[1] = (qp & 0x3f);
bytes[2] = (((x & 1) << 7) | format_ab_reg (ab, reg));
bytes[3] = (((y & 1) << 7) | (treg & 0x7f));
count += output_leb128 (bytes + 4, t, 0);
(*f) (count, bytes, NULL);
}
/* This function allocates a record list structure, and initializes fields. */
static unw_rec_list *
alloc_record (unw_record_type t)
{
unw_rec_list *ptr;
ptr = xmalloc (sizeof (*ptr));
ptr->next = NULL;
ptr->slot_number = SLOT_NUM_NOT_SET;
ptr->r.type = t;
return ptr;
}
/* This function frees an entire list of record structures. */
void
free_list_records (unw_rec_list *first)
{
unw_rec_list *ptr;
for (ptr = first; ptr != NULL; )
{
unw_rec_list *tmp = ptr;
if ((tmp->r.type == prologue || tmp->r.type == prologue_gr)
&& tmp->r.record.r.mask.i)
free (tmp->r.record.r.mask.i);
ptr = ptr->next;
free (tmp);
}
}
static unw_rec_list *
output_prologue ()
{
unw_rec_list *ptr = alloc_record (prologue);
memset (&ptr->r.record.r.mask, 0, sizeof (ptr->r.record.r.mask));
return ptr;
}
static unw_rec_list *
output_prologue_gr (saved_mask, reg)
unsigned int saved_mask;
unsigned int reg;
{
unw_rec_list *ptr = alloc_record (prologue_gr);
memset (&ptr->r.record.r.mask, 0, sizeof (ptr->r.record.r.mask));
ptr->r.record.r.grmask = saved_mask;
ptr->r.record.r.grsave = reg;
return ptr;
}
static unw_rec_list *
output_body ()
{
unw_rec_list *ptr = alloc_record (body);
return ptr;
}
static unw_rec_list *
output_mem_stack_f (size)
unsigned int size;
{
unw_rec_list *ptr = alloc_record (mem_stack_f);
ptr->r.record.p.size = size;
return ptr;
}
static unw_rec_list *
output_mem_stack_v ()
{
unw_rec_list *ptr = alloc_record (mem_stack_v);
return ptr;
}
static unw_rec_list *
output_psp_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (psp_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_psp_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (psp_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_rp_when ()
{
unw_rec_list *ptr = alloc_record (rp_when);
return ptr;
}
static unw_rec_list *
output_rp_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (rp_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_rp_br (br)
unsigned int br;
{
unw_rec_list *ptr = alloc_record (rp_br);
ptr->r.record.p.br = br;
return ptr;
}
static unw_rec_list *
output_rp_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (rp_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_rp_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (rp_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_pfs_when ()
{
unw_rec_list *ptr = alloc_record (pfs_when);
return ptr;
}
static unw_rec_list *
output_pfs_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (pfs_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_pfs_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (pfs_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_pfs_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (pfs_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_preds_when ()
{
unw_rec_list *ptr = alloc_record (preds_when);
return ptr;
}
static unw_rec_list *
output_preds_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (preds_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_preds_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (preds_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_preds_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (preds_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_fr_mem (mask)
unsigned int mask;
{
unw_rec_list *ptr = alloc_record (fr_mem);
ptr->r.record.p.rmask = mask;
return ptr;
}
static unw_rec_list *
output_frgr_mem (gr_mask, fr_mask)
unsigned int gr_mask;
unsigned int fr_mask;
{
unw_rec_list *ptr = alloc_record (frgr_mem);
ptr->r.record.p.grmask = gr_mask;
ptr->r.record.p.frmask = fr_mask;
return ptr;
}
static unw_rec_list *
output_gr_gr (mask, reg)
unsigned int mask;
unsigned int reg;
{
unw_rec_list *ptr = alloc_record (gr_gr);
ptr->r.record.p.grmask = mask;
ptr->r.record.p.gr = reg;
return ptr;
}
static unw_rec_list *
output_gr_mem (mask)
unsigned int mask;
{
unw_rec_list *ptr = alloc_record (gr_mem);
ptr->r.record.p.rmask = mask;
return ptr;
}
static unw_rec_list *
output_br_mem (unsigned int mask)
{
unw_rec_list *ptr = alloc_record (br_mem);
ptr->r.record.p.brmask = mask;
return ptr;
}
static unw_rec_list *
output_br_gr (save_mask, reg)
unsigned int save_mask;
unsigned int reg;
{
unw_rec_list *ptr = alloc_record (br_gr);
ptr->r.record.p.brmask = save_mask;
ptr->r.record.p.gr = reg;
return ptr;
}
static unw_rec_list *
output_spill_base (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (spill_base);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_unat_when ()
{
unw_rec_list *ptr = alloc_record (unat_when);
return ptr;
}
static unw_rec_list *
output_unat_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (unat_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_unat_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (unat_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_unat_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (unat_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_lc_when ()
{
unw_rec_list *ptr = alloc_record (lc_when);
return ptr;
}
static unw_rec_list *
output_lc_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (lc_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_lc_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (lc_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_lc_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (lc_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_fpsr_when ()
{
unw_rec_list *ptr = alloc_record (fpsr_when);
return ptr;
}
static unw_rec_list *
output_fpsr_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (fpsr_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_fpsr_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (fpsr_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_fpsr_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (fpsr_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_priunat_when_gr ()
{
unw_rec_list *ptr = alloc_record (priunat_when_gr);
return ptr;
}
static unw_rec_list *
output_priunat_when_mem ()
{
unw_rec_list *ptr = alloc_record (priunat_when_mem);
return ptr;
}
static unw_rec_list *
output_priunat_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (priunat_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_priunat_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (priunat_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_priunat_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (priunat_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_bsp_when ()
{
unw_rec_list *ptr = alloc_record (bsp_when);
return ptr;
}
static unw_rec_list *
output_bsp_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (bsp_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_bsp_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (bsp_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_bsp_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (bsp_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_bspstore_when ()
{
unw_rec_list *ptr = alloc_record (bspstore_when);
return ptr;
}
static unw_rec_list *
output_bspstore_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (bspstore_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_bspstore_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (bspstore_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_bspstore_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (bspstore_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_rnat_when ()
{
unw_rec_list *ptr = alloc_record (rnat_when);
return ptr;
}
static unw_rec_list *
output_rnat_gr (gr)
unsigned int gr;
{
unw_rec_list *ptr = alloc_record (rnat_gr);
ptr->r.record.p.gr = gr;
return ptr;
}
static unw_rec_list *
output_rnat_psprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (rnat_psprel);
ptr->r.record.p.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_rnat_sprel (offset)
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (rnat_sprel);
ptr->r.record.p.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_unwabi (abi, context)
unsigned long abi;
unsigned long context;
{
unw_rec_list *ptr = alloc_record (unwabi);
ptr->r.record.p.abi = abi;
ptr->r.record.p.context = context;
return ptr;
}
static unw_rec_list *
output_epilogue (unsigned long ecount)
{
unw_rec_list *ptr = alloc_record (epilogue);
ptr->r.record.b.ecount = ecount;
return ptr;
}
static unw_rec_list *
output_label_state (unsigned long label)
{
unw_rec_list *ptr = alloc_record (label_state);
ptr->r.record.b.label = label;
return ptr;
}
static unw_rec_list *
output_copy_state (unsigned long label)
{
unw_rec_list *ptr = alloc_record (copy_state);
ptr->r.record.b.label = label;
return ptr;
}
static unw_rec_list *
output_spill_psprel (ab, reg, offset)
unsigned int ab;
unsigned int reg;
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (spill_psprel);
ptr->r.record.x.ab = ab;
ptr->r.record.x.reg = reg;
ptr->r.record.x.pspoff = offset/4;
return ptr;
}
static unw_rec_list *
output_spill_sprel (ab, reg, offset)
unsigned int ab;
unsigned int reg;
unsigned int offset;
{
unw_rec_list *ptr = alloc_record (spill_sprel);
ptr->r.record.x.ab = ab;
ptr->r.record.x.reg = reg;
ptr->r.record.x.spoff = offset/4;
return ptr;
}
static unw_rec_list *
output_spill_psprel_p (ab, reg, offset, predicate)
unsigned int ab;
unsigned int reg;
unsigned int offset;
unsigned int predicate;
{
unw_rec_list *ptr = alloc_record (spill_psprel_p);
ptr->r.record.x.ab = ab;
ptr->r.record.x.reg = reg;
ptr->r.record.x.pspoff = offset/4;
ptr->r.record.x.qp = predicate;
return ptr;
}
static unw_rec_list *
output_spill_sprel_p (ab, reg, offset, predicate)
unsigned int ab;
unsigned int reg;
unsigned int offset;
unsigned int predicate;
{
unw_rec_list *ptr = alloc_record (spill_sprel_p);
ptr->r.record.x.ab = ab;
ptr->r.record.x.reg = reg;
ptr->r.record.x.spoff = offset/4;
ptr->r.record.x.qp = predicate;
return ptr;
}
static unw_rec_list *
output_spill_reg (ab, reg, targ_reg, xy)
unsigned int ab;
unsigned int reg;
unsigned int targ_reg;
unsigned int xy;
{
unw_rec_list *ptr = alloc_record (spill_reg);
ptr->r.record.x.ab = ab;
ptr->r.record.x.reg = reg;
ptr->r.record.x.treg = targ_reg;
ptr->r.record.x.xy = xy;
return ptr;
}
static unw_rec_list *
output_spill_reg_p (ab, reg, targ_reg, xy, predicate)
unsigned int ab;
unsigned int reg;
unsigned int targ_reg;
unsigned int xy;
unsigned int predicate;
{
unw_rec_list *ptr = alloc_record (spill_reg_p);
ptr->r.record.x.ab = ab;
ptr->r.record.x.reg = reg;
ptr->r.record.x.treg = targ_reg;
ptr->r.record.x.xy = xy;
ptr->r.record.x.qp = predicate;
return ptr;
}
/* Given a unw_rec_list process the correct format with the
specified function. */
static void
process_one_record (ptr, f)
unw_rec_list *ptr;
vbyte_func f;
{
unsigned long fr_mask, gr_mask;
switch (ptr->r.type)
{
case gr_mem:
case fr_mem:
case br_mem:
case frgr_mem:
/* these are taken care of by prologue/prologue_gr */
break;
case prologue_gr:
case prologue:
if (ptr->r.type == prologue_gr)
output_R2_format (f, ptr->r.record.r.grmask,
ptr->r.record.r.grsave, ptr->r.record.r.rlen);
else
output_R1_format (f, ptr->r.type, ptr->r.record.r.rlen);
/* output descriptor(s) for union of register spills (if any): */
gr_mask = ptr->r.record.r.mask.gr_mem;
fr_mask = ptr->r.record.r.mask.fr_mem;
if (fr_mask)
{
if ((fr_mask & ~0xfUL) == 0)
output_P6_format (f, fr_mem, fr_mask);
else
{
output_P5_format (f, gr_mask, fr_mask);
gr_mask = 0;
}
}
if (gr_mask)
output_P6_format (f, gr_mem, gr_mask);
if (ptr->r.record.r.mask.br_mem)
output_P1_format (f, ptr->r.record.r.mask.br_mem);
/* output imask descriptor if necessary: */
if (ptr->r.record.r.mask.i)
output_P4_format (f, ptr->r.record.r.mask.i,
ptr->r.record.r.imask_size);
break;
case body:
output_R1_format (f, ptr->r.type, ptr->r.record.r.rlen);
break;
case mem_stack_f:
case mem_stack_v:
output_P7_format (f, ptr->r.type, ptr->r.record.p.t,
ptr->r.record.p.size);
break;
case psp_gr:
case rp_gr:
case pfs_gr:
case preds_gr:
case unat_gr:
case lc_gr:
case fpsr_gr:
case priunat_gr:
case bsp_gr:
case bspstore_gr:
case rnat_gr:
output_P3_format (f, ptr->r.type, ptr->r.record.p.gr);
break;
case rp_br:
output_P3_format (f, rp_br, ptr->r.record.p.br);
break;
case psp_sprel:
output_P7_format (f, psp_sprel, ptr->r.record.p.spoff, 0);
break;
case rp_when:
case pfs_when:
case preds_when:
case unat_when:
case lc_when:
case fpsr_when:
output_P7_format (f, ptr->r.type, ptr->r.record.p.t, 0);
break;
case rp_psprel:
case pfs_psprel:
case preds_psprel:
case unat_psprel:
case lc_psprel:
case fpsr_psprel:
case spill_base:
output_P7_format (f, ptr->r.type, ptr->r.record.p.pspoff, 0);
break;
case rp_sprel:
case pfs_sprel:
case preds_sprel:
case unat_sprel:
case lc_sprel:
case fpsr_sprel:
case priunat_sprel:
case bsp_sprel:
case bspstore_sprel:
case rnat_sprel:
output_P8_format (f, ptr->r.type, ptr->r.record.p.spoff);
break;
case gr_gr:
output_P9_format (f, ptr->r.record.p.grmask, ptr->r.record.p.gr);
break;
case br_gr:
output_P2_format (f, ptr->r.record.p.brmask, ptr->r.record.p.gr);
break;
case spill_mask:
as_bad ("spill_mask record unimplemented.");
break;
case priunat_when_gr:
case priunat_when_mem:
case bsp_when:
case bspstore_when:
case rnat_when:
output_P8_format (f, ptr->r.type, ptr->r.record.p.t);
break;
case priunat_psprel:
case bsp_psprel:
case bspstore_psprel:
case rnat_psprel:
output_P8_format (f, ptr->r.type, ptr->r.record.p.pspoff);
break;
case unwabi:
output_P10_format (f, ptr->r.record.p.abi, ptr->r.record.p.context);
break;
case epilogue:
output_B3_format (f, ptr->r.record.b.ecount, ptr->r.record.b.t);
break;
case label_state:
case copy_state:
output_B4_format (f, ptr->r.type, ptr->r.record.b.label);
break;
case spill_psprel:
output_X1_format (f, ptr->r.type, ptr->r.record.x.ab,
ptr->r.record.x.reg, ptr->r.record.x.t,
ptr->r.record.x.pspoff);
break;
case spill_sprel:
output_X1_format (f, ptr->r.type, ptr->r.record.x.ab,
ptr->r.record.x.reg, ptr->r.record.x.t,
ptr->r.record.x.spoff);
break;
case spill_reg:
output_X2_format (f, ptr->r.record.x.ab, ptr->r.record.x.reg,
ptr->r.record.x.xy >> 1, ptr->r.record.x.xy,
ptr->r.record.x.treg, ptr->r.record.x.t);
break;
case spill_psprel_p:
output_X3_format (f, ptr->r.type, ptr->r.record.x.qp,
ptr->r.record.x.ab, ptr->r.record.x.reg,
ptr->r.record.x.t, ptr->r.record.x.pspoff);
break;
case spill_sprel_p:
output_X3_format (f, ptr->r.type, ptr->r.record.x.qp,
ptr->r.record.x.ab, ptr->r.record.x.reg,
ptr->r.record.x.t, ptr->r.record.x.spoff);
break;
case spill_reg_p:
output_X4_format (f, ptr->r.record.x.qp, ptr->r.record.x.ab,
ptr->r.record.x.reg, ptr->r.record.x.xy >> 1,
ptr->r.record.x.xy, ptr->r.record.x.treg,
ptr->r.record.x.t);
break;
default:
as_bad ("record_type_not_valid");
break;
}
}
/* Given a unw_rec_list list, process all the records with
the specified function. */
static void
process_unw_records (list, f)
unw_rec_list *list;
vbyte_func f;
{
unw_rec_list *ptr;
for (ptr = list; ptr; ptr = ptr->next)
process_one_record (ptr, f);
}
/* Determine the size of a record list in bytes. */
static int
calc_record_size (list)
unw_rec_list *list;
{
vbyte_count = 0;
process_unw_records (list, count_output);
return vbyte_count;
}
/* Update IMASK bitmask to reflect the fact that one or more registers
of type TYPE are saved starting at instruction with index T. If N
bits are set in REGMASK, it is assumed that instructions T through
T+N-1 save these registers.
TYPE values:
0: no save
1: instruction saves next fp reg
2: instruction saves next general reg
3: instruction saves next branch reg */
static void
set_imask (region, regmask, t, type)
unw_rec_list *region;
unsigned long regmask;
unsigned long t;
unsigned int type;
{
unsigned char *imask;
unsigned long imask_size;
unsigned int i;
int pos;
imask = region->r.record.r.mask.i;
imask_size = region->r.record.r.imask_size;
if (!imask)
{
imask_size = (region->r.record.r.rlen*2 + 7)/8 + 1;
imask = xmalloc (imask_size);
memset (imask, 0, imask_size);
region->r.record.r.imask_size = imask_size;
region->r.record.r.mask.i = imask;
}
i = (t/4) + 1;
pos = 2*(3 - t%4);
while (regmask)
{
if (i >= imask_size)
{
as_bad ("Ignoring attempt to spill beyond end of region");
return;
}
imask[i] |= (type & 0x3) << pos;
regmask &= (regmask - 1);
pos -= 2;
if (pos < 0)
{
pos = 0;
++i;
}
}
}
static int
count_bits (unsigned long mask)
{
int n = 0;
while (mask)
{
mask &= mask - 1;
++n;
}
return n;
}
unsigned long
slot_index (unsigned long slot_addr, unsigned long first_addr)
{
return (3*((slot_addr >> 4) - (first_addr >> 4))
+ ((slot_addr & 0x3) - (first_addr & 0x3)));
}
/* Given a complete record list, process any records which have
unresolved fields, (ie length counts for a prologue). After
this has been run, all neccessary information should be available
within each record to generate an image. */
static void
fixup_unw_records (list)
unw_rec_list *list;
{
unw_rec_list *ptr, *region = 0;
unsigned long first_addr = 0, rlen = 0, t;
for (ptr = list; ptr; ptr = ptr->next)
{
if (ptr->slot_number == SLOT_NUM_NOT_SET)
as_bad (" Insn slot not set in unwind record.");
t = slot_index (ptr->slot_number, first_addr);
switch (ptr->r.type)
{
case prologue:
case prologue_gr:
case body:
{
unw_rec_list *last;
int size, dir_len = 0;
unsigned long last_addr;
first_addr = ptr->slot_number;
ptr->slot_number = 0;
/* Find either the next body/prologue start, or the end of
the list, and determine the size of the region. */
last_addr = unwind.next_slot_number;
for (last = ptr->next; last != NULL; last = last->next)
if (last->r.type == prologue || last->r.type == prologue_gr
|| last->r.type == body)
{
last_addr = last->slot_number;
break;
}
else if (!last->next)
{
/* In the absence of an explicit .body directive,
the prologue ends after the last instruction
covered by an unwind directive. */
if (ptr->r.type != body)
{
last_addr = last->slot_number;
switch (last->r.type)
{
case frgr_mem:
dir_len = (count_bits (last->r.record.p.frmask)
+ count_bits (last->r.record.p.grmask));
break;
case fr_mem:
case gr_mem:
dir_len += count_bits (last->r.record.p.rmask);
break;
case br_mem:
case br_gr:
dir_len += count_bits (last->r.record.p.brmask);
break;
case gr_gr:
dir_len += count_bits (last->r.record.p.grmask);
break;
default:
dir_len = 1;
break;
}
}
break;
}
size = slot_index (last_addr, first_addr) + dir_len;
rlen = ptr->r.record.r.rlen = size;
region = ptr;
break;
}
case epilogue:
ptr->r.record.b.t = rlen - 1 - t;
break;
case mem_stack_f:
case mem_stack_v:
case rp_when:
case pfs_when:
case preds_when:
case unat_when:
case lc_when:
case fpsr_when:
case priunat_when_gr:
case priunat_when_mem:
case bsp_when:
case bspstore_when:
case rnat_when:
ptr->r.record.p.t = t;
break;
case spill_reg:
case spill_sprel:
case spill_psprel:
case spill_reg_p:
case spill_sprel_p:
case spill_psprel_p:
ptr->r.record.x.t = t;
break;
case frgr_mem:
if (!region)
{
as_bad ("frgr_mem record before region record!\n");
return;
}
region->r.record.r.mask.fr_mem |= ptr->r.record.p.frmask;
region->r.record.r.mask.gr_mem |= ptr->r.record.p.grmask;
set_imask (region, ptr->r.record.p.frmask, t, 1);
set_imask (region, ptr->r.record.p.grmask, t, 2);
break;
case fr_mem:
if (!region)
{
as_bad ("fr_mem record before region record!\n");
return;
}
region->r.record.r.mask.fr_mem |= ptr->r.record.p.rmask;
set_imask (region, ptr->r.record.p.rmask, t, 1);
break;
case gr_mem:
if (!region)
{
as_bad ("gr_mem record before region record!\n");
return;
}
region->r.record.r.mask.gr_mem |= ptr->r.record.p.rmask;
set_imask (region, ptr->r.record.p.rmask, t, 2);
break;
case br_mem:
if (!region)
{
as_bad ("br_mem record before region record!\n");
return;
}
region->r.record.r.mask.br_mem |= ptr->r.record.p.brmask;
set_imask (region, ptr->r.record.p.brmask, t, 3);
break;
case gr_gr:
if (!region)
{
as_bad ("gr_gr record before region record!\n");
return;
}
set_imask (region, ptr->r.record.p.grmask, t, 2);
break;
case br_gr:
if (!region)
{
as_bad ("br_gr record before region record!\n");
return;
}
set_imask (region, ptr->r.record.p.brmask, t, 3);
break;
default:
break;
}
}
}
/* Generate an unwind image from a record list. Returns the number of
bytes in the resulting image. The memory image itselof is returned
in the 'ptr' parameter. */
static int
output_unw_records (list, ptr)
unw_rec_list *list;
void **ptr;
{
int size, x, extra = 0;
unsigned char *mem;
fixup_unw_records (list);
size = calc_record_size (list);
/* pad to 8 byte boundry. */
x = size % 8;
if (x != 0)
extra = 8 - x;
/* Add 8 for the header + 8 more bytes for the personality offset. */
mem = xmalloc (size + extra + 16);
vbyte_mem_ptr = mem + 8;
/* Clear the padding area and personality. */
memset (mem + 8 + size, 0 , extra + 8);
/* Initialize the header area. */
md_number_to_chars (mem, ( ((bfd_vma) 1 << 48) /* version */
| ((bfd_vma) 3 << 32) /* U & E handler flags */
| ((size + extra) / 8)), /* length (dwords) */
8);
process_unw_records (list, output_vbyte_mem);
*ptr = mem;
return size + extra + 16;
}
static int
convert_expr_to_ab_reg (e, ab, regp)
expressionS *e;
unsigned int *ab;
unsigned int *regp;
{
unsigned int reg;
if (e->X_op != O_register)
return 0;
reg = e->X_add_number;
if (reg >= REG_GR + 4 && reg <= REG_GR + 7)
{
*ab = 0;
*regp = reg - REG_GR;
}
else if ((reg >= REG_FR + 2 && reg <= REG_FR + 5)
|| (reg >= REG_FR + 16 && reg <= REG_FR + 31))
{
*ab = 1;
*regp = reg - REG_FR;
}
else if (reg >= REG_BR + 1 && reg <= REG_BR + 5)
{
*ab = 2;
*regp = reg - REG_BR;
}
else
{
*ab = 3;
switch (reg)
{
case REG_PR: *regp = 0; break;
case REG_PSP: *regp = 1; break;
case REG_PRIUNAT: *regp = 2; break;
case REG_BR + 0: *regp = 3; break;
case REG_AR + AR_BSP: *regp = 4; break;
case REG_AR + AR_BSPSTORE: *regp = 5; break;
case REG_AR + AR_RNAT: *regp = 6; break;
case REG_AR + AR_UNAT: *regp = 7; break;
case REG_AR + AR_FPSR: *regp = 8; break;
case REG_AR + AR_PFS: *regp = 9; break;
case REG_AR + AR_LC: *regp = 10; break;
default:
return 0;
}
}
return 1;
}
static int
convert_expr_to_xy_reg (e, xy, regp)
expressionS *e;
unsigned int *xy;
unsigned int *regp;
{
unsigned int reg;
if (e->X_op != O_register)
return 0;
reg = e->X_add_number;
if (reg >= REG_GR && reg <= REG_GR + 127)
{
*xy = 0;
*regp = reg - REG_GR;
}
else if (reg >= REG_FR && reg <= REG_FR + 127)
{
*xy = 1;
*regp = reg - REG_FR;
}
else if (reg >= REG_BR && reg <= REG_BR + 7)
{
*xy = 2;
*regp = reg - REG_BR;
}
else
return -1;
return 1;
}
static void
dot_radix (dummy)
int dummy;
{
int radix;
SKIP_WHITESPACE ();
radix = *input_line_pointer++;
if (radix != 'C' && !is_end_of_line[(unsigned char) radix])
{
as_bad ("Radix `%c' unsupported", *input_line_pointer);
ignore_rest_of_line ();
return;
}
}
/* .sbss, .bss etc. are macros that expand into ".section SECNAME". */
static void
dot_special_section (which)
int which;
{
set_section ((char *) special_section_name[which]);
}
static void
add_unwind_entry (ptr)
unw_rec_list *ptr;
{
if (unwind.tail)
unwind.tail->next = ptr;
else
unwind.list = ptr;
unwind.tail = ptr;
/* The current entry can in fact be a chain of unwind entries. */
if (unwind.current_entry == NULL)
unwind.current_entry = ptr;
}
static void
dot_fframe (dummy)
int dummy;
{
expressionS e;
parse_operand (&e);
if (e.X_op != O_constant)
as_bad ("Operand to .fframe must be a constant");
else
add_unwind_entry (output_mem_stack_f (e.X_add_number));
}
static void
dot_vframe (dummy)
int dummy;
{
expressionS e;
unsigned reg;
parse_operand (&e);
reg = e.X_add_number - REG_GR;
if (e.X_op == O_register && reg < 128)
{
add_unwind_entry (output_mem_stack_v ());
add_unwind_entry (output_psp_gr (reg));
}
else
as_bad ("First operand to .vframe must be a general register");
}
static void
dot_vframesp (dummy)
int dummy;
{
expressionS e;
parse_operand (&e);
if (e.X_op == O_constant)
{
add_unwind_entry (output_mem_stack_v ());
add_unwind_entry (output_psp_sprel (e.X_add_number));
}
else
as_bad ("First operand to .vframesp must be a general register");
}
static void
dot_vframepsp (dummy)
int dummy;
{
expressionS e;
parse_operand (&e);
if (e.X_op == O_constant)
{
add_unwind_entry (output_mem_stack_v ());
add_unwind_entry (output_psp_sprel (e.X_add_number));
}
else
as_bad ("First operand to .vframepsp must be a general register");
}
static void
dot_save (dummy)
int dummy;
{
expressionS e1, e2;
int sep;
int reg1, reg2;
sep = parse_operand (&e1);
if (sep != ',')
as_bad ("No second operand to .save");
sep = parse_operand (&e2);
reg1 = e1.X_add_number;
reg2 = e2.X_add_number - REG_GR;
/* Make sure its a valid ar.xxx reg, OR its br0, aka 'rp'. */
if (e1.X_op == O_register)
{
if (e2.X_op == O_register && reg2 >=0 && reg2 < 128)
{
switch (reg1)
{
case REG_AR + AR_BSP:
add_unwind_entry (output_bsp_when ());
add_unwind_entry (output_bsp_gr (reg2));
break;
case REG_AR + AR_BSPSTORE:
add_unwind_entry (output_bspstore_when ());
add_unwind_entry (output_bspstore_gr (reg2));
break;
case REG_AR + AR_RNAT:
add_unwind_entry (output_rnat_when ());
add_unwind_entry (output_rnat_gr (reg2));
break;
case REG_AR+AR_UNAT:
add_unwind_entry (output_unat_when ());
add_unwind_entry (output_unat_gr (reg2));
break;
case REG_AR+AR_FPSR:
add_unwind_entry (output_fpsr_when ());
add_unwind_entry (output_fpsr_gr (reg2));
break;
case REG_AR+AR_PFS:
add_unwind_entry (output_pfs_when ());
add_unwind_entry (output_pfs_gr (reg2));
break;
case REG_AR+AR_LC:
add_unwind_entry (output_lc_when ());
add_unwind_entry (output_lc_gr (reg2));
break;
case REG_BR:
add_unwind_entry (output_rp_when ());
add_unwind_entry (output_rp_gr (reg2));
break;
case REG_PR:
add_unwind_entry (output_preds_when ());
add_unwind_entry (output_preds_gr (reg2));
break;
case REG_PRIUNAT:
add_unwind_entry (output_priunat_when_gr ());
add_unwind_entry (output_priunat_gr (reg2));
break;
default:
as_bad ("First operand not a valid register");
}
}
else
as_bad (" Second operand not a valid register");
}
else
as_bad ("First operand not a register");
}
static void
dot_restore (dummy)
int dummy;
{
expressionS e1, e2;
unsigned long ecount = 0;
int sep;
sep = parse_operand (&e1);
if (e1.X_op != O_register || e1.X_add_number != REG_GR + 12)
{
as_bad ("First operand to .restore must be stack pointer (sp)");
return;
}
if (sep == ',')
{
parse_operand (&e2);
if (e1.X_op != O_constant)
{
as_bad ("Second operand to .restore must be constant");
return;
}
ecount = e1.X_op;
}
add_unwind_entry (output_epilogue (ecount));
}
static void
dot_restorereg (dummy)
int dummy;
{
unsigned int ab, reg;
expressionS e;
parse_operand (&e);
if (!convert_expr_to_ab_reg (&e, &ab, &reg))
{
as_bad ("First operand to .restorereg must be a preserved register");
return;
}
add_unwind_entry (output_spill_reg (ab, reg, 0, 0));
}
static void
dot_restorereg_p (dummy)
int dummy;
{
unsigned int qp, ab, reg;
expressionS e1, e2;
int sep;
sep = parse_operand (&e1);
if (sep != ',')
{
as_bad ("No second operand to .restorereg.p");
return;
}
parse_operand (&e2);
qp = e1.X_add_number - REG_P;
if (e1.X_op != O_register || qp > 63)
{
as_bad ("First operand to .restorereg.p must be a predicate");
return;
}
if (!convert_expr_to_ab_reg (&e2, &ab, &reg))
{
as_bad ("Second operand to .restorereg.p must be a preserved register");
return;
}
add_unwind_entry (output_spill_reg_p (ab, reg, 0, 0, qp));
}
static int
generate_unwind_image ()
{
int size;
unsigned char *unw_rec;
/* Generate the unwind record. */
size = output_unw_records (unwind.list, &unw_rec);
if (size % 8 != 0)
as_bad ("Unwind record is not a multiple of 8 bytes.");
/* If there are unwind records, switch sections, and output the info. */
if (size != 0)
{
unsigned char *where;
expressionS exp;
set_section ((char *) special_section_name[SPECIAL_SECTION_UNWIND_INFO]);
/* Set expression which points to start of unwind descriptor area. */
unwind.info = expr_build_dot ();
where = (unsigned char *)frag_more (size);
/* Issue a label for this address, and keep track of it to put it
in the unwind section. */
/* Copy the information from the unwind record into this section. The
data is already in the correct byte order. */
memcpy (where, unw_rec, size);
/* Add the personality address to the image. */
if (unwind.personality_routine != 0)
{
exp.X_op = O_symbol;
exp.X_add_symbol = unwind.personality_routine;
exp.X_add_number = 0;
fix_new_exp (frag_now, frag_now_fix () - 8, 8,
&exp, 0, BFD_RELOC_IA64_LTOFF_FPTR64LSB);
unwind.personality_routine = 0;
}
obj_elf_previous (0);
}
free_list_records (unwind.list);
unwind.list = unwind.tail = unwind.current_entry = NULL;
return size;
}
static void
dot_handlerdata (dummy)
int dummy;
{
generate_unwind_image ();
demand_empty_rest_of_line ();
}
static void
dot_unwentry (dummy)
int dummy;
{
demand_empty_rest_of_line ();
}
static void
dot_altrp (dummy)
int dummy;
{
expressionS e;
unsigned reg;
parse_operand (&e);
reg = e.X_add_number - REG_BR;
if (e.X_op == O_register && reg < 8)
add_unwind_entry (output_rp_br (reg));
else
as_bad ("First operand not a valid branch register");
}
static void
dot_savemem (psprel)
int psprel;
{
expressionS e1, e2;
int sep;
int reg1, val;
sep = parse_operand (&e1);
if (sep != ',')
as_bad ("No second operand to .save%ssp", psprel ? "p" : "");
sep = parse_operand (&e2);
reg1 = e1.X_add_number;
val = e2.X_add_number;
/* Make sure its a valid ar.xxx reg, OR its br0, aka 'rp'. */
if (e1.X_op == O_register)
{
if (e2.X_op == O_constant)
{
switch (reg1)
{
case REG_AR + AR_BSP:
add_unwind_entry (output_bsp_when ());
add_unwind_entry ((psprel
? output_bsp_psprel
: output_bsp_sprel) (val));
break;
case REG_AR + AR_BSPSTORE:
add_unwind_entry (output_bspstore_when ());
add_unwind_entry ((psprel
? output_bspstore_psprel
: output_bspstore_sprel) (val));
break;
case REG_AR + AR_RNAT:
add_unwind_entry (output_rnat_when ());
add_unwind_entry ((psprel
? output_rnat_psprel
: output_rnat_sprel) (val));
break;
case REG_AR + AR_UNAT:
add_unwind_entry (output_unat_when ());
add_unwind_entry ((psprel
? output_unat_psprel
: output_unat_sprel) (val));
break;
case REG_AR + AR_FPSR:
add_unwind_entry (output_fpsr_when ());
add_unwind_entry ((psprel
? output_fpsr_psprel
: output_fpsr_sprel) (val));
break;
case REG_AR + AR_PFS:
add_unwind_entry (output_pfs_when ());
add_unwind_entry ((psprel
? output_pfs_psprel
: output_pfs_sprel) (val));
break;
case REG_AR + AR_LC:
add_unwind_entry (output_lc_when ());
add_unwind_entry ((psprel
? output_lc_psprel
: output_lc_sprel) (val));
break;
case REG_BR:
add_unwind_entry (output_rp_when ());
add_unwind_entry ((psprel
? output_rp_psprel
: output_rp_sprel) (val));
break;
case REG_PR:
add_unwind_entry (output_preds_when ());
add_unwind_entry ((psprel
? output_preds_psprel
: output_preds_sprel) (val));
break;
case REG_PRIUNAT:
add_unwind_entry (output_priunat_when_mem ());
add_unwind_entry ((psprel
? output_priunat_psprel
: output_priunat_sprel) (val));
break;
default:
as_bad ("First operand not a valid register");
}
}
else
as_bad (" Second operand not a valid constant");
}
else
as_bad ("First operand not a register");
}
static void
dot_saveg (dummy)
int dummy;
{
expressionS e1, e2;
int sep;
sep = parse_operand (&e1);
if (sep == ',')
parse_operand (&e2);
if (e1.X_op != O_constant)
as_bad ("First operand to .save.g must be a constant.");
else
{
int grmask = e1.X_add_number;
if (sep != ',')
add_unwind_entry (output_gr_mem (grmask));
else
{
int reg = e2.X_add_number - REG_GR;
if (e2.X_op == O_register && reg >=0 && reg < 128)
add_unwind_entry (output_gr_gr (grmask, reg));
else
as_bad ("Second operand is an invalid register.");
}
}
}
static void
dot_savef (dummy)
int dummy;
{
expressionS e1;
int sep;
sep = parse_operand (&e1);
if (e1.X_op != O_constant)
as_bad ("Operand to .save.f must be a constant.");
else
add_unwind_entry (output_fr_mem (e1.X_add_number));
}
static void
dot_saveb (dummy)
int dummy;
{
expressionS e1, e2;
unsigned int reg;
unsigned char sep;
int brmask;
sep = parse_operand (&e1);
if (e1.X_op != O_constant)
{
as_bad ("First operand to .save.b must be a constant.");
return;
}
brmask = e1.X_add_number;
if (sep == ',')
{
sep = parse_operand (&e2);
reg = e2.X_add_number - REG_GR;
if (e2.X_op != O_register || reg > 127)
{
as_bad ("Second operand to .save.b must be a general register.");
return;
}
add_unwind_entry (output_br_gr (brmask, e2.X_add_number));
}
else
add_unwind_entry (output_br_mem (brmask));
if (!is_end_of_line[sep] && !is_it_end_of_statement ())
ignore_rest_of_line ();
}
static void
dot_savegf (dummy)
int dummy;
{
expressionS e1, e2;
int sep;
sep = parse_operand (&e1);
if (sep == ',')
parse_operand (&e2);
if (e1.X_op != O_constant || sep != ',' || e2.X_op != O_constant)
as_bad ("Both operands of .save.gf must be constants.");
else
{
int grmask = e1.X_add_number;
int frmask = e2.X_add_number;
add_unwind_entry (output_frgr_mem (grmask, frmask));
}
}
static void
dot_spill (dummy)
int dummy;
{
expressionS e;
unsigned char sep;
sep = parse_operand (&e);
if (!is_end_of_line[sep] && !is_it_end_of_statement ())
ignore_rest_of_line ();
if (e.X_op != O_constant)
as_bad ("Operand to .spill must be a constant");
else
add_unwind_entry (output_spill_base (e.X_add_number));
}
static void
dot_spillreg (dummy)
int dummy;
{
int sep, ab, xy, reg, treg;
expressionS e1, e2;
sep = parse_operand (&e1);
if (sep != ',')
{
as_bad ("No second operand to .spillreg");
return;
}
parse_operand (&e2);
if (!convert_expr_to_ab_reg (&e1, &ab, &reg))
{
as_bad ("First operand to .spillreg must be a preserved register");
return;
}
if (!convert_expr_to_xy_reg (&e2, &xy, &treg))
{
as_bad ("Second operand to .spillreg must be a register");
return;
}
add_unwind_entry (output_spill_reg (ab, reg, treg, xy));
}
static void
dot_spillmem (psprel)
int psprel;
{
expressionS e1, e2;
int sep, ab, reg;
sep = parse_operand (&e1);
if (sep != ',')
{
as_bad ("Second operand missing");
return;
}
parse_operand (&e2);
if (!convert_expr_to_ab_reg (&e1, &ab, &reg))
{
as_bad ("First operand to .spill%s must be a preserved register",
psprel ? "psp" : "sp");
return;
}
if (e2.X_op != O_constant)
{
as_bad ("Second operand to .spill%s must be a constant",
psprel ? "psp" : "sp");
return;
}
if (psprel)
add_unwind_entry (output_spill_psprel (ab, reg, e2.X_add_number));
else
add_unwind_entry (output_spill_sprel (ab, reg, e2.X_add_number));
}
static void
dot_spillreg_p (dummy)
int dummy;
{
int sep, ab, xy, reg, treg;
expressionS e1, e2, e3;
unsigned int qp;
sep = parse_operand (&e1);
if (sep != ',')
{
as_bad ("No second and third operand to .spillreg.p");
return;
}
sep = parse_operand (&e2);
if (sep != ',')
{
as_bad ("No third operand to .spillreg.p");
return;
}
parse_operand (&e3);
qp = e1.X_add_number - REG_P;
if (e1.X_op != O_register || qp > 63)
{
as_bad ("First operand to .spillreg.p must be a predicate");
return;
}
if (!convert_expr_to_ab_reg (&e2, &ab, &reg))
{
as_bad ("Second operand to .spillreg.p must be a preserved register");
return;
}
if (!convert_expr_to_xy_reg (&e3, &xy, &treg))
{
as_bad ("Third operand to .spillreg.p must be a register");
return;
}
add_unwind_entry (output_spill_reg_p (ab, reg, treg, xy, qp));
}
static void
dot_spillmem_p (psprel)
int psprel;
{
expressionS e1, e2, e3;
int sep, ab, reg;
unsigned int qp;
sep = parse_operand (&e1);
if (sep != ',')
{
as_bad ("Second operand missing");
return;
}
parse_operand (&e2);
if (sep != ',')
{
as_bad ("Second operand missing");
return;
}
parse_operand (&e3);
qp = e1.X_add_number - REG_P;
if (e1.X_op != O_register || qp > 63)
{
as_bad ("First operand to .spill%s_p must be a predicate",
psprel ? "psp" : "sp");
return;
}
if (!convert_expr_to_ab_reg (&e2, &ab, &reg))
{
as_bad ("Second operand to .spill%s_p must be a preserved register",
psprel ? "psp" : "sp");
return;
}
if (e3.X_op != O_constant)
{
as_bad ("Third operand to .spill%s_p must be a constant",
psprel ? "psp" : "sp");
return;
}
if (psprel)
add_unwind_entry (output_spill_psprel_p (qp, ab, reg, e3.X_add_number));
else
add_unwind_entry (output_spill_sprel_p (qp, ab, reg, e3.X_add_number));
}
static void
dot_label_state (dummy)
int dummy;
{
expressionS e;
parse_operand (&e);
if (e.X_op != O_constant)
{
as_bad ("Operand to .label_state must be a constant");
return;
}
add_unwind_entry (output_label_state (e.X_add_number));
}
static void
dot_copy_state (dummy)
int dummy;
{
expressionS e;
parse_operand (&e);
if (e.X_op != O_constant)
{
as_bad ("Operand to .copy_state must be a constant");
return;
}
add_unwind_entry (output_copy_state (e.X_add_number));
}
static void
dot_unwabi (dummy)
int dummy;
{
expressionS e1, e2;
unsigned char sep;
sep = parse_operand (&e1);
if (sep != ',')
{
as_bad ("Second operand to .unwabi missing");
return;
}
sep = parse_operand (&e2);
if (!is_end_of_line[sep] && !is_it_end_of_statement ())
ignore_rest_of_line ();
if (e1.X_op != O_constant)
{
as_bad ("First operand to .unwabi must be a constant");
return;
}
if (e2.X_op != O_constant)
{
as_bad ("Second operand to .unwabi must be a constant");
return;
}
add_unwind_entry (output_unwabi (e1.X_add_number, e2.X_add_number));
}
static void
dot_personality (dummy)
int dummy;
{
char *name, *p, c;
SKIP_WHITESPACE ();
name = input_line_pointer;
c = get_symbol_end ();
p = input_line_pointer;
unwind.personality_routine = symbol_find_or_make (name);
*p = c;
SKIP_WHITESPACE ();
demand_empty_rest_of_line ();
}
static void
dot_proc (dummy)
int dummy;
{
char *name, *p, c;
symbolS *sym;
unwind.proc_start = expr_build_dot ();
/* Parse names of main and alternate entry points and mark them as
function symbols: */
while (1)
{
SKIP_WHITESPACE ();
name = input_line_pointer;
c = get_symbol_end ();
p = input_line_pointer;
sym = symbol_find_or_make (name);
if (unwind.proc_start == 0)
{
unwind.proc_start = sym;
}
symbol_get_bfdsym (sym)->flags |= BSF_FUNCTION;
*p = c;
SKIP_WHITESPACE ();
if (*input_line_pointer != ',')
break;
++input_line_pointer;
}
demand_empty_rest_of_line ();
ia64_do_align (16);
unwind.list = unwind.tail = unwind.current_entry = NULL;
unwind.personality_routine = 0;
}
static void
dot_body (dummy)
int dummy;
{
unwind.prologue = 0;
add_unwind_entry (output_body ());
demand_empty_rest_of_line ();
}
static void
dot_prologue (dummy)
int dummy;
{
unsigned char sep;
unwind.prologue = 1;
if (!is_it_end_of_statement ())
{
expressionS e1, e2;
sep = parse_operand (&e1);
if (sep != ',')
as_bad ("No second operand to .prologue");
sep = parse_operand (&e2);
if (!is_end_of_line[sep] && !is_it_end_of_statement ())
ignore_rest_of_line ();
if (e1.X_op == O_constant)
{
if (e2.X_op == O_constant)
{
int mask = e1.X_add_number;
int reg = e2.X_add_number;
add_unwind_entry (output_prologue_gr (mask, reg));
}
else
as_bad ("Second operand not a constant");
}
else
as_bad ("First operand not a constant");
}
else
add_unwind_entry (output_prologue ());
}
static void
dot_endp (dummy)
int dummy;
{
expressionS e;
unsigned char *ptr;
long where;
segT saved_seg;
subsegT saved_subseg;
saved_seg = now_seg;
saved_subseg = now_subseg;
expression (&e);
demand_empty_rest_of_line ();
insn_group_break (1, 0, 0);
ia64_flush_insns ();
/* If there was a .handlerdata, we haven't generated an image yet. */
if (unwind.info == 0)
{
generate_unwind_image ();
}
subseg_set (md.last_text_seg, 0);
unwind.proc_end = expr_build_dot ();
set_section ((char *) special_section_name[SPECIAL_SECTION_UNWIND]);
ptr = frag_more (24);
where = frag_now_fix () - 24;
/* Issue the values of a) Proc Begin, b) Proc End, c) Unwind Record. */
e.X_op = O_pseudo_fixup;
e.X_op_symbol = pseudo_func[FUNC_SEG_RELATIVE].u.sym;
e.X_add_number = 0;
e.X_add_symbol = unwind.proc_start;
ia64_cons_fix_new (frag_now, where, 8, &e);
e.X_op = O_pseudo_fixup;
e.X_op_symbol = pseudo_func[FUNC_SEG_RELATIVE].u.sym;
e.X_add_number = 0;
e.X_add_symbol = unwind.proc_end;
ia64_cons_fix_new (frag_now, where + 8, 8, &e);
if (unwind.info != 0)
{
e.X_op = O_pseudo_fixup;
e.X_op_symbol = pseudo_func[FUNC_SEG_RELATIVE].u.sym;
e.X_add_number = 0;
e.X_add_symbol = unwind.info;
ia64_cons_fix_new (frag_now, where + 16, 8, &e);
}
else
md_number_to_chars (ptr + 16, 0, 8);
subseg_set (saved_seg, saved_subseg);
unwind.proc_start = unwind.proc_end = unwind.info = 0;
}
static void
dot_template (template)
int template;
{
CURR_SLOT.user_template = template;
}
static void
dot_regstk (dummy)
int dummy;
{
int ins, locs, outs, rots;
if (is_it_end_of_statement ())
ins = locs = outs = rots = 0;
else
{
ins = get_absolute_expression ();
if (*input_line_pointer++ != ',')
goto err;
locs = get_absolute_expression ();
if (*input_line_pointer++ != ',')
goto err;
outs = get_absolute_expression ();
if (*input_line_pointer++ != ',')
goto err;
rots = get_absolute_expression ();
}
set_regstack (ins, locs, outs, rots);
return;
err:
as_bad ("Comma expected");
ignore_rest_of_line ();
}
static void
dot_rot (type)
int type;
{
unsigned num_regs, num_alloced = 0;
struct dynreg **drpp, *dr;
int ch, base_reg = 0;
char *name, *start;
size_t len;
switch (type)
{
case DYNREG_GR: base_reg = REG_GR + 32; break;
case DYNREG_FR: base_reg = REG_FR + 32; break;
case DYNREG_PR: base_reg = REG_P + 16; break;
default: break;
}
/* first, remove existing names from hash table: */
for (dr = md.dynreg[type]; dr && dr->num_regs; dr = dr->next)
{
hash_delete (md.dynreg_hash, dr->name);
dr->num_regs = 0;
}
drpp = &md.dynreg[type];
while (1)
{
start = input_line_pointer;
ch = get_symbol_end ();
*input_line_pointer = ch;
len = (input_line_pointer - start);
SKIP_WHITESPACE ();
if (*input_line_pointer != '[')
{
as_bad ("Expected '['");
goto err;
}
++input_line_pointer; /* skip '[' */
num_regs = get_absolute_expression ();
if (*input_line_pointer++ != ']')
{
as_bad ("Expected ']'");
goto err;
}
SKIP_WHITESPACE ();
num_alloced += num_regs;
switch (type)
{
case DYNREG_GR:
if (num_alloced > md.rot.num_regs)
{
as_bad ("Used more than the declared %d rotating registers",
md.rot.num_regs);
goto err;
}
break;
case DYNREG_FR:
if (num_alloced > 96)
{
as_bad ("Used more than the available 96 rotating registers");
goto err;
}
break;
case DYNREG_PR:
if (num_alloced > 48)
{
as_bad ("Used more than the available 48 rotating registers");
goto err;
}
break;
default:
break;
}
name = obstack_alloc (&notes, len + 1);
memcpy (name, start, len);
name[len] = '\0';
if (!*drpp)
{
*drpp = obstack_alloc (&notes, sizeof (*dr));
memset (*drpp, 0, sizeof (*dr));
}
dr = *drpp;
dr->name = name;
dr->num_regs = num_regs;
dr->base = base_reg;
drpp = &dr->next;
base_reg += num_regs;
if (hash_insert (md.dynreg_hash, name, dr))
{
as_bad ("Attempt to redefine register set `%s'", name);
goto err;
}
if (*input_line_pointer != ',')
break;
++input_line_pointer; /* skip comma */
SKIP_WHITESPACE ();
}
demand_empty_rest_of_line ();
return;
err:
ignore_rest_of_line ();
}
static void
dot_byteorder (byteorder)
int byteorder;
{
target_big_endian = byteorder;
}
static void
dot_psr (dummy)
int dummy;
{
char *option;
int ch;
while (1)
{
option = input_line_pointer;
ch = get_symbol_end ();
if (strcmp (option, "lsb") == 0)
md.flags &= ~EF_IA_64_BE;
else if (strcmp (option, "msb") == 0)
md.flags |= EF_IA_64_BE;
else if (strcmp (option, "abi32") == 0)
md.flags &= ~EF_IA_64_ABI64;
else if (strcmp (option, "abi64") == 0)
md.flags |= EF_IA_64_ABI64;
else
as_bad ("Unknown psr option `%s'", option);
*input_line_pointer = ch;
SKIP_WHITESPACE ();
if (*input_line_pointer != ',')
break;
++input_line_pointer;
SKIP_WHITESPACE ();
}
demand_empty_rest_of_line ();
}
static void
dot_alias (dummy)
int dummy;
{
as_bad (".alias not implemented yet");
}
static void
dot_ln (dummy)
int dummy;
{
new_logical_line (0, get_absolute_expression ());
demand_empty_rest_of_line ();
}
static char*
parse_section_name ()
{
char *name;
int len;
SKIP_WHITESPACE ();
if (*input_line_pointer != '"')
{
as_bad ("Missing section name");
ignore_rest_of_line ();
return 0;
}
name = demand_copy_C_string (&len);
if (!name)
{
ignore_rest_of_line ();
return 0;
}
SKIP_WHITESPACE ();
if (*input_line_pointer != ',')
{
as_bad ("Comma expected after section name");
ignore_rest_of_line ();
return 0;
}
++input_line_pointer; /* skip comma */
return name;
}
static void
dot_xdata (size)
int size;
{
char *name = parse_section_name ();
if (!name)
return;
set_section (name);
cons (size);
obj_elf_previous (0);
}
/* Why doesn't float_cons() call md_cons_align() the way cons() does? */
static void
stmt_float_cons (kind)
int kind;
{
size_t size;
switch (kind)
{
case 'd': size = 8; break;
case 'x': size = 10; break;
case 'f':
default:
size = 4;
break;
}
ia64_do_align (size);
float_cons (kind);
}
static void
stmt_cons_ua (size)
int size;
{
int saved_auto_align = md.auto_align;
md.auto_align = 0;
cons (size);
md.auto_align = saved_auto_align;
}
static void
dot_xfloat_cons (kind)
int kind;
{
char *name = parse_section_name ();
if (!name)
return;
set_section (name);
stmt_float_cons (kind);
obj_elf_previous (0);
}
static void
dot_xstringer (zero)
int zero;
{
char *name = parse_section_name ();
if (!name)
return;
set_section (name);
stringer (zero);
obj_elf_previous (0);
}
static void
dot_xdata_ua (size)
int size;
{
int saved_auto_align = md.auto_align;
char *name = parse_section_name ();
if (!name)
return;
set_section (name);
md.auto_align = 0;
cons (size);
md.auto_align = saved_auto_align;
obj_elf_previous (0);
}
static void
dot_xfloat_cons_ua (kind)
int kind;
{
int saved_auto_align = md.auto_align;
char *name = parse_section_name ();
if (!name)
return;
set_section (name);
md.auto_align = 0;
stmt_float_cons (kind);
md.auto_align = saved_auto_align;
obj_elf_previous (0);
}
/* .reg.val <regname>,value */
static void
dot_reg_val (dummy)
int dummy;
{
expressionS reg;
expression (&reg);
if (reg.X_op != O_register)
{
as_bad (_("Register name expected"));
ignore_rest_of_line ();
}
else if (*input_line_pointer++ != ',')
{
as_bad (_("Comma expected"));
ignore_rest_of_line ();
}
else
{
valueT value = get_absolute_expression ();
int regno = reg.X_add_number;
if (regno < REG_GR || regno > REG_GR+128)
as_warn (_("Register value annotation ignored"));
else
{
gr_values[regno-REG_GR].known = 1;
gr_values[regno-REG_GR].value = value;
gr_values[regno-REG_GR].path = md.path;
}
}
demand_empty_rest_of_line ();
}
/* select dv checking mode
.auto
.explicit
.default
A stop is inserted when changing modes
*/
static void
dot_dv_mode (type)
int type;
{
if (md.manual_bundling)
as_warn (_("Directive invalid within a bundle"));
if (type == 'E' || type == 'A')
md.mode_explicitly_set = 0;
else
md.mode_explicitly_set = 1;
md.detect_dv = 1;
switch (type)
{
case 'A':
case 'a':
if (md.explicit_mode)
insn_group_break (1, 0, 0);
md.explicit_mode = 0;
break;
case 'E':
case 'e':
if (!md.explicit_mode)
insn_group_break (1, 0, 0);
md.explicit_mode = 1;
break;
default:
case 'd':
if (md.explicit_mode != md.default_explicit_mode)
insn_group_break (1, 0, 0);
md.explicit_mode = md.default_explicit_mode;
md.mode_explicitly_set = 0;
break;
}
}
static void
print_prmask (mask)
valueT mask;
{
int regno;
char *comma = "";
for (regno = 0;regno < 64;regno++)
{
if (mask & ((valueT)1<<regno))
{
fprintf (stderr, "%s p%d", comma, regno);
comma = ",";
}
}
}
/*
.pred.rel.clear [p1 [,p2 [,...]]] (also .pred.rel "clear")
.pred.rel.imply p1, p2 (also .pred.rel "imply")
.pred.rel.mutex p1, p2 [,...] (also .pred.rel "mutex")
.pred.safe_across_calls p1 [, p2 [,...]]
*/
static void
dot_pred_rel (type)
int type;
{
valueT mask = 0;
int count = 0;
int p1 = -1, p2 = -1;
if (type == 0)
{
if (*input_line_pointer != '"')
{
as_bad (_("Missing predicate relation type"));
ignore_rest_of_line ();
return;
}
else
{
int len;
char *form = demand_copy_C_string (&len);
if (strcmp (form, "mutex") == 0)
type = 'm';
else if (strcmp (form, "clear") == 0)
type = 'c';
else if (strcmp (form, "imply") == 0)
type = 'i';
else
{
as_bad (_("Unrecognized predicate relation type"));
ignore_rest_of_line ();
return;
}
}
if (*input_line_pointer == ',')
++input_line_pointer;
SKIP_WHITESPACE ();
}
SKIP_WHITESPACE ();
while (1)
{
valueT bit = 1;
int regno;
if (toupper (*input_line_pointer) != 'P'
|| (regno = atoi (++input_line_pointer)) < 0
|| regno > 63)
{
as_bad (_("Predicate register expected"));
ignore_rest_of_line ();
return;
}
while (isdigit (*input_line_pointer))
++input_line_pointer;
if (p1 == -1)
p1 = regno;
else if (p2 == -1)
p2 = regno;
bit <<= regno;
if (mask & bit)
as_warn (_("Duplicate predicate register ignored"));
mask |= bit; count++;
/* see if it's a range */
if (*input_line_pointer == '-')
{
valueT stop = 1;
++input_line_pointer;
if (toupper (*input_line_pointer) != 'P'
|| (regno = atoi (++input_line_pointer)) < 0
|| regno > 63)
{
as_bad (_("Predicate register expected"));
ignore_rest_of_line ();
return;
}
while (isdigit (*input_line_pointer))
++input_line_pointer;
stop <<= regno;
if (bit >= stop)
{
as_bad (_("Bad register range"));
ignore_rest_of_line ();
return;
}
while (bit < stop)
{
bit <<= 1;
mask |= bit; count++;
}
SKIP_WHITESPACE ();
}
if (*input_line_pointer != ',')
break;
++input_line_pointer;
SKIP_WHITESPACE ();
}
switch (type)
{
case 'c':
if (count == 0)
mask = ~(valueT)0;
clear_qp_mutex (mask);
clear_qp_implies (mask, (valueT)0);
break;
case 'i':
if (count != 2 || p1 == -1 || p2 == -1)
as_bad (_("Predicate source and target required"));
else if (p1 == 0 || p2 == 0)
as_bad (_("Use of p0 is not valid in this context"));
else
add_qp_imply (p1, p2);
break;
case 'm':
if (count < 2)
{
as_bad (_("At least two PR arguments expected"));
break;
}
else if (mask & 1)
{
as_bad (_("Use of p0 is not valid in this context"));
break;
}
add_qp_mutex (mask);
break;
case 's':
/* note that we don't override any existing relations */
if (count == 0)
{
as_bad (_("At least one PR argument expected"));
break;
}
if (md.debug_dv)
{
fprintf (stderr, "Safe across calls: ");
print_prmask (mask);
fprintf (stderr, "\n");
}
qp_safe_across_calls = mask;
break;
}
demand_empty_rest_of_line ();
}
/* .entry label [, label [, ...]]
Hint to DV code that the given labels are to be considered entry points.
Otherwise, only global labels are considered entry points.
*/
static void
dot_entry (dummy)
int dummy;
{
const char *err;
char *name;
int c;
symbolS *symbolP;
do
{
name = input_line_pointer;
c = get_symbol_end ();
symbolP = symbol_find_or_make (name);
err = hash_insert (md.entry_hash, S_GET_NAME (symbolP), (PTR) symbolP);
if (err)
as_fatal (_("Inserting \"%s\" into entry hint table failed: %s"),
name, err);
*input_line_pointer = c;
SKIP_WHITESPACE ();
c = *input_line_pointer;
if (c == ',')
{
input_line_pointer++;
SKIP_WHITESPACE ();
if (*input_line_pointer == '\n')
c = '\n';
}
}
while (c == ',');
demand_empty_rest_of_line ();
}
/* .mem.offset offset, base
"base" is used to distinguish between offsets from a different base.
*/
static void
dot_mem_offset (dummy)
int dummy;
{
md.mem_offset.hint = 1;
md.mem_offset.offset = get_absolute_expression ();
if (*input_line_pointer != ',')
{
as_bad (_("Comma expected"));
ignore_rest_of_line ();
return;
}
++input_line_pointer;
md.mem_offset.base = get_absolute_expression ();
demand_empty_rest_of_line ();
}
/* ia64-specific pseudo-ops: */
const pseudo_typeS md_pseudo_table[] =
{
{ "radix", dot_radix, 0 },
{ "lcomm", s_lcomm_bytes, 1 },
{ "bss", dot_special_section, SPECIAL_SECTION_BSS },
{ "sbss", dot_special_section, SPECIAL_SECTION_SBSS },
{ "sdata", dot_special_section, SPECIAL_SECTION_SDATA },
{ "rodata", dot_special_section, SPECIAL_SECTION_RODATA },
{ "comment", dot_special_section, SPECIAL_SECTION_COMMENT },
{ "ia_64.unwind", dot_special_section, SPECIAL_SECTION_UNWIND },
{ "ia_64.unwind_info", dot_special_section, SPECIAL_SECTION_UNWIND_INFO },
{ "proc", dot_proc, 0 },
{ "body", dot_body, 0 },
{ "prologue", dot_prologue, 0 },
{ "endp", dot_endp },
{ "file", dwarf2_directive_file },
{ "loc", dwarf2_directive_loc },
{ "fframe", dot_fframe },
{ "vframe", dot_vframe },
{ "vframesp", dot_vframesp },
{ "vframepsp", dot_vframepsp },
{ "save", dot_save },
{ "restore", dot_restore },
{ "restorereg", dot_restorereg },
{ "restorereg.p", dot_restorereg_p },
{ "handlerdata", dot_handlerdata },
{ "unwentry", dot_unwentry },
{ "altrp", dot_altrp },
{ "savesp", dot_savemem, 0 },
{ "savepsp", dot_savemem, 1 },
{ "save.g", dot_saveg },
{ "save.f", dot_savef },
{ "save.b", dot_saveb },
{ "save.gf", dot_savegf },
{ "spill", dot_spill },
{ "spillreg", dot_spillreg },
{ "spillsp", dot_spillmem, 0 },
{ "spillpsp", dot_spillmem, 1 },
{ "spillreg.p", dot_spillreg_p },
{ "spillsp.p", dot_spillmem_p, 0 },
{ "spillpsp.p", dot_spillmem_p, 1 },
{ "label_state", dot_label_state },
{ "copy_state", dot_copy_state },
{ "unwabi", dot_unwabi },
{ "personality", dot_personality },
#if 0
{ "estate", dot_estate },
#endif
{ "mii", dot_template, 0x0 },
{ "mli", dot_template, 0x2 }, /* old format, for compatibility */
{ "mlx", dot_template, 0x2 },
{ "mmi", dot_template, 0x4 },
{ "mfi", dot_template, 0x6 },
{ "mmf", dot_template, 0x7 },
{ "mib", dot_template, 0x8 },
{ "mbb", dot_template, 0x9 },
{ "bbb", dot_template, 0xb },
{ "mmb", dot_template, 0xc },
{ "mfb", dot_template, 0xe },
#if 0
{ "lb", dot_scope, 0 },
{ "le", dot_scope, 1 },
#endif
{ "align", s_align_bytes, 0 },
{ "regstk", dot_regstk, 0 },
{ "rotr", dot_rot, DYNREG_GR },
{ "rotf", dot_rot, DYNREG_FR },
{ "rotp", dot_rot, DYNREG_PR },
{ "lsb", dot_byteorder, 0 },
{ "msb", dot_byteorder, 1 },
{ "psr", dot_psr, 0 },
{ "alias", dot_alias, 0 },
{ "ln", dot_ln, 0 }, /* source line info (for debugging) */
{ "xdata1", dot_xdata, 1 },
{ "xdata2", dot_xdata, 2 },
{ "xdata4", dot_xdata, 4 },
{ "xdata8", dot_xdata, 8 },
{ "xreal4", dot_xfloat_cons, 'f' },
{ "xreal8", dot_xfloat_cons, 'd' },
{ "xreal10", dot_xfloat_cons, 'x' },
{ "xstring", dot_xstringer, 0 },
{ "xstringz", dot_xstringer, 1 },
/* unaligned versions: */
{ "xdata2.ua", dot_xdata_ua, 2 },
{ "xdata4.ua", dot_xdata_ua, 4 },
{ "xdata8.ua", dot_xdata_ua, 8 },
{ "xreal4.ua", dot_xfloat_cons_ua, 'f' },
{ "xreal8.ua", dot_xfloat_cons_ua, 'd' },
{ "xreal10.ua", dot_xfloat_cons_ua, 'x' },
/* annotations/DV checking support */
{ "entry", dot_entry, 0 },
{ "mem.offset", dot_mem_offset },
{ "pred.rel", dot_pred_rel, 0 },
{ "pred.rel.clear", dot_pred_rel, 'c' },
{ "pred.rel.imply", dot_pred_rel, 'i' },
{ "pred.rel.mutex", dot_pred_rel, 'm' },
{ "pred.safe_across_calls", dot_pred_rel, 's' },
{ "reg.val", dot_reg_val },
{ "auto", dot_dv_mode, 'a' },
{ "explicit", dot_dv_mode, 'e' },
{ "default", dot_dv_mode, 'd' },
{ NULL, 0, 0 }
};
static const struct pseudo_opcode
{
const char *name;
void (*handler) (int);
int arg;
}
pseudo_opcode[] =
{
/* these are more like pseudo-ops, but don't start with a dot */
{ "data1", cons, 1 },
{ "data2", cons, 2 },
{ "data4", cons, 4 },
{ "data8", cons, 8 },
{ "real4", stmt_float_cons, 'f' },
{ "real8", stmt_float_cons, 'd' },
{ "real10", stmt_float_cons, 'x' },
{ "string", stringer, 0 },
{ "stringz", stringer, 1 },
/* unaligned versions: */
{ "data2.ua", stmt_cons_ua, 2 },
{ "data4.ua", stmt_cons_ua, 4 },
{ "data8.ua", stmt_cons_ua, 8 },
{ "real4.ua", float_cons, 'f' },
{ "real8.ua", float_cons, 'd' },
{ "real10.ua", float_cons, 'x' },
};
/* Declare a register by creating a symbol for it and entering it in
the symbol table. */
static symbolS*
declare_register (name, regnum)
const char *name;
int regnum;
{
const char *err;
symbolS *sym;
sym = symbol_new (name, reg_section, regnum, &zero_address_frag);
err = hash_insert (md.reg_hash, S_GET_NAME (sym), (PTR) sym);
if (err)
as_fatal ("Inserting \"%s\" into register table failed: %s",
name, err);
return sym;
}
static void
declare_register_set (prefix, num_regs, base_regnum)
const char *prefix;
int num_regs;
int base_regnum;
{
char name[8];
int i;
for (i = 0; i < num_regs; ++i)
{
sprintf (name, "%s%u", prefix, i);
declare_register (name, base_regnum + i);
}
}
static unsigned int
operand_width (opnd)
enum ia64_opnd opnd;
{
const struct ia64_operand *odesc = &elf64_ia64_operands[opnd];
unsigned int bits = 0;
int i;
bits = 0;
for (i = 0; i < NELEMS (odesc->field) && odesc->field[i].bits; ++i)
bits += odesc->field[i].bits;
return bits;
}
static int
operand_match (idesc, index, e)
const struct ia64_opcode *idesc;
int index;
expressionS *e;
{
enum ia64_opnd opnd = idesc->operands[index];
int bits, relocatable = 0;
struct insn_fix *fix;
bfd_signed_vma val;
switch (opnd)
{
/* constants: */
case IA64_OPND_AR_CCV:
if (e->X_op == O_register && e->X_add_number == REG_AR + 32)
return 1;
break;
case IA64_OPND_AR_PFS:
if (e->X_op == O_register && e->X_add_number == REG_AR + 64)
return 1;
break;
case IA64_OPND_GR0:
if (e->X_op == O_register && e->X_add_number == REG_GR + 0)
return 1;
break;
case IA64_OPND_IP:
if (e->X_op == O_register && e->X_add_number == REG_IP)
return 1;
break;
case IA64_OPND_PR:
if (e->X_op == O_register && e->X_add_number == REG_PR)
return 1;
break;
case IA64_OPND_PR_ROT:
if (e->X_op == O_register && e->X_add_number == REG_PR_ROT)
return 1;
break;
case IA64_OPND_PSR:
if (e->X_op == O_register && e->X_add_number == REG_PSR)
return 1;
break;
case IA64_OPND_PSR_L:
if (e->X_op == O_register && e->X_add_number == REG_PSR_L)
return 1;
break;
case IA64_OPND_PSR_UM:
if (e->X_op == O_register && e->X_add_number == REG_PSR_UM)
return 1;
break;
case IA64_OPND_C1:
if (e->X_op == O_constant && e->X_add_number == 1)
return 1;
break;
case IA64_OPND_C8:
if (e->X_op == O_constant && e->X_add_number == 8)
return 1;
break;
case IA64_OPND_C16:
if (e->X_op == O_constant && e->X_add_number == 16)
return 1;
break;
/* register operands: */
case IA64_OPND_AR3:
if (e->X_op == O_register && e->X_add_number >= REG_AR
&& e->X_add_number < REG_AR + 128)
return 1;
break;
case IA64_OPND_B1:
case IA64_OPND_B2:
if (e->X_op == O_register && e->X_add_number >= REG_BR
&& e->X_add_number < REG_BR + 8)
return 1;
break;
case IA64_OPND_CR3:
if (e->X_op == O_register && e->X_add_number >= REG_CR
&& e->X_add_number < REG_CR + 128)
return 1;
break;
case IA64_OPND_F1:
case IA64_OPND_F2:
case IA64_OPND_F3:
case IA64_OPND_F4:
if (e->X_op == O_register && e->X_add_number >= REG_FR
&& e->X_add_number < REG_FR + 128)
return 1;
break;
case IA64_OPND_P1:
case IA64_OPND_P2:
if (e->X_op == O_register && e->X_add_number >= REG_P
&& e->X_add_number < REG_P + 64)
return 1;
break;
case IA64_OPND_R1:
case IA64_OPND_R2:
case IA64_OPND_R3:
if (e->X_op == O_register && e->X_add_number >= REG_GR
&& e->X_add_number < REG_GR + 128)
return 1;
break;
case IA64_OPND_R3_2:
if (e->X_op == O_register && e->X_add_number >= REG_GR
&& e->X_add_number < REG_GR + 4)
return 1;
break;
/* indirect operands: */
case IA64_OPND_CPUID_R3:
case IA64_OPND_DBR_R3:
case IA64_OPND_DTR_R3:
case IA64_OPND_ITR_R3:
case IA64_OPND_IBR_R3:
case IA64_OPND_MSR_R3:
case IA64_OPND_PKR_R3:
case IA64_OPND_PMC_R3:
case IA64_OPND_PMD_R3:
case IA64_OPND_RR_R3:
if (e->X_op == O_index && e->X_op_symbol
&& (S_GET_VALUE (e->X_op_symbol) - IND_CPUID
== opnd - IA64_OPND_CPUID_R3))
return 1;
break;
case IA64_OPND_MR3:
if (e->X_op == O_index && !e->X_op_symbol)
return 1;
break;
/* immediate operands: */
case IA64_OPND_CNT2a:
case IA64_OPND_LEN4:
case IA64_OPND_LEN6:
bits = operand_width (idesc->operands[index]);
if (e->X_op == O_constant
&& (bfd_vma) (e->X_add_number - 1) < ((bfd_vma) 1 << bits))
return 1;
break;
case IA64_OPND_CNT2b:
if (e->X_op == O_constant
&& (bfd_vma) (e->X_add_number - 1) < 3)
return 1;
break;
case IA64_OPND_CNT2c:
val = e->X_add_number;
if (e->X_op == O_constant
&& (val == 0 || val == 7 || val == 15 || val == 16))
return 1;
break;
case IA64_OPND_SOR:
/* SOR must be an integer multiple of 8 */
if (e->X_add_number & 0x7)
break;
case IA64_OPND_SOF:
case IA64_OPND_SOL:
if (e->X_op == O_constant &&
(bfd_vma) e->X_add_number <= 96)
return 1;
break;
case IA64_OPND_IMMU62:
if (e->X_op == O_constant)
{
if ((bfd_vma) e->X_add_number < ((bfd_vma) 1 << 62))
return 1;
}
else
{
/* FIXME -- need 62-bit relocation type */
as_bad (_("62-bit relocation not yet implemented"));
}
break;
case IA64_OPND_IMMU64:
if (e->X_op == O_symbol || e->X_op == O_pseudo_fixup
|| e->X_op == O_subtract)
{
fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
fix->code = BFD_RELOC_IA64_IMM64;
if (e->X_op != O_subtract)
{
fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
if (e->X_op == O_pseudo_fixup)
e->X_op = O_symbol;
}
fix->opnd = idesc->operands[index];
fix->expr = *e;
fix->is_pcrel = 0;
++CURR_SLOT.num_fixups;
return 1;
}
else if (e->X_op == O_constant)
return 1;
break;
case IA64_OPND_CCNT5:
case IA64_OPND_CNT5:
case IA64_OPND_CNT6:
case IA64_OPND_CPOS6a:
case IA64_OPND_CPOS6b:
case IA64_OPND_CPOS6c:
case IA64_OPND_IMMU2:
case IA64_OPND_IMMU7a:
case IA64_OPND_IMMU7b:
case IA64_OPND_IMMU21:
case IA64_OPND_IMMU24:
case IA64_OPND_MBTYPE4:
case IA64_OPND_MHTYPE8:
case IA64_OPND_POS6:
bits = operand_width (idesc->operands[index]);
if (e->X_op == O_constant
&& (bfd_vma) e->X_add_number < ((bfd_vma) 1 << bits))
return 1;
break;
case IA64_OPND_IMMU9:
bits = operand_width (idesc->operands[index]);
if (e->X_op == O_constant
&& (bfd_vma) e->X_add_number < ((bfd_vma) 1 << bits))
{
int lobits = e->X_add_number & 0x3;
if (((bfd_vma) e->X_add_number & 0x3C) != 0 && lobits == 0)
e->X_add_number |= (bfd_vma)0x3;
return 1;
}
break;
case IA64_OPND_IMM44:
/* least 16 bits must be zero */
if ((e->X_add_number & 0xffff) != 0)
as_warn (_("lower 16 bits of mask ignored"));
if (e->X_op == O_constant
&& ((e->X_add_number >= 0
&& e->X_add_number < ((bfd_vma) 1 << 44))
|| (e->X_add_number < 0
&& -e->X_add_number <= ((bfd_vma) 1 << 44))))
{
/* sign-extend */
if (e->X_add_number >= 0
&& (e->X_add_number & ((bfd_vma) 1 << 43)) != 0)
{
e->X_add_number |= ~(((bfd_vma) 1 << 44) - 1);
}
return 1;
}
break;
case IA64_OPND_IMM17:
/* bit 0 is a don't care (pr0 is hardwired to 1) */
if (e->X_op == O_constant
&& ((e->X_add_number >= 0
&& e->X_add_number < ((bfd_vma) 1 << 17))
|| (e->X_add_number < 0
&& -e->X_add_number <= ((bfd_vma) 1 << 17))))
{
/* sign-extend */
if (e->X_add_number >= 0
&& (e->X_add_number & ((bfd_vma) 1 << 16)) != 0)
{
e->X_add_number |= ~(((bfd_vma)1 << 17) - 1);
}
return 1;
}
break;
case IA64_OPND_IMM14:
case IA64_OPND_IMM22:
relocatable = 1;
case IA64_OPND_IMM1:
case IA64_OPND_IMM8:
case IA64_OPND_IMM8U4:
case IA64_OPND_IMM8M1:
case IA64_OPND_IMM8M1U4:
case IA64_OPND_IMM8M1U8:
case IA64_OPND_IMM9a:
case IA64_OPND_IMM9b:
bits = operand_width (idesc->operands[index]);
if (relocatable && (e->X_op == O_symbol
|| e->X_op == O_subtract
|| e->X_op == O_pseudo_fixup))
{
fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
if (idesc->operands[index] == IA64_OPND_IMM14)
fix->code = BFD_RELOC_IA64_IMM14;
else
fix->code = BFD_RELOC_IA64_IMM22;
if (e->X_op != O_subtract)
{
fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
if (e->X_op == O_pseudo_fixup)
e->X_op = O_symbol;
}
fix->opnd = idesc->operands[index];
fix->expr = *e;
fix->is_pcrel = 0;
++CURR_SLOT.num_fixups;
return 1;
}
else if (e->X_op != O_constant
&& ! (e->X_op == O_big && opnd == IA64_OPND_IMM8M1U8))
return 0;
if (opnd == IA64_OPND_IMM8M1U4)
{
/* Zero is not valid for unsigned compares that take an adjusted
constant immediate range. */
if (e->X_add_number == 0)
return 0;
/* Sign-extend 32-bit unsigned numbers, so that the following range
checks will work. */
val = e->X_add_number;
if (((val & (~(bfd_vma)0 << 32)) == 0)
&& ((val & ((bfd_vma)1 << 31)) != 0))
val = ((val << 32) >> 32);
/* Check for 0x100000000. This is valid because
0x100000000-1 is the same as ((uint32_t) -1). */
if (val == ((bfd_signed_vma) 1 << 32))
return 1;
val = val - 1;
}
else if (opnd == IA64_OPND_IMM8M1U8)
{
/* Zero is not valid for unsigned compares that take an adjusted
constant immediate range. */
if (e->X_add_number == 0)
return 0;
/* Check for 0x10000000000000000. */
if (e->X_op == O_big)
{
if (generic_bignum[0] == 0
&& generic_bignum[1] == 0
&& generic_bignum[2] == 0
&& generic_bignum[3] == 0
&& generic_bignum[4] == 1)
return 1;
else
return 0;
}
else
val = e->X_add_number - 1;
}
else if (opnd == IA64_OPND_IMM8M1)
val = e->X_add_number - 1;
else if (opnd == IA64_OPND_IMM8U4)
{
/* Sign-extend 32-bit unsigned numbers, so that the following range
checks will work. */
val = e->X_add_number;
if (((val & (~(bfd_vma)0 << 32)) == 0)
&& ((val & ((bfd_vma)1 << 31)) != 0))
val = ((val << 32) >> 32);
}
else
val = e->X_add_number;
if ((val >= 0 && val < ((bfd_vma) 1 << (bits - 1)))
|| (val < 0 && -val <= ((bfd_vma) 1 << (bits - 1))))
return 1;
break;
case IA64_OPND_INC3:
/* +/- 1, 4, 8, 16 */
val = e->X_add_number;
if (val < 0)
val = -val;
if (e->X_op == O_constant
&& (val == 1 || val == 4 || val == 8 || val == 16))
return 1;
break;
case IA64_OPND_TGT25:
case IA64_OPND_TGT25b:
case IA64_OPND_TGT25c:
case IA64_OPND_TGT64:
if (e->X_op == O_symbol)
{
fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
if (opnd == IA64_OPND_TGT25)
fix->code = BFD_RELOC_IA64_PCREL21F;
else if (opnd == IA64_OPND_TGT25b)
fix->code = BFD_RELOC_IA64_PCREL21M;
else if (opnd == IA64_OPND_TGT25c)
fix->code = BFD_RELOC_IA64_PCREL21B;
else if (opnd == IA64_OPND_TGT64)
fix->code = BFD_RELOC_IA64_PCREL60B;
else
abort ();
fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, fix->code);
fix->opnd = idesc->operands[index];
fix->expr = *e;
fix->is_pcrel = 1;
++CURR_SLOT.num_fixups;
return 1;
}
case IA64_OPND_TAG13:
case IA64_OPND_TAG13b:
switch (e->X_op)
{
case O_constant:
return 1;
case O_symbol:
fix = CURR_SLOT.fixup + CURR_SLOT.num_fixups;
fix->code = ia64_gen_real_reloc_type (e->X_op_symbol, 0);
fix->opnd = idesc->operands[index];
fix->expr = *e;
fix->is_pcrel = 1;
++CURR_SLOT.num_fixups;
return 1;
default:
break;
}
break;
default:
break;
}
return 0;
}
static int
parse_operand (e)
expressionS *e;
{
int sep = '\0';
memset (e, 0, sizeof (*e));
e->X_op = O_absent;
SKIP_WHITESPACE ();
if (*input_line_pointer != '}')
expression (e);
sep = *input_line_pointer++;
if (sep == '}')
{
if (!md.manual_bundling)
as_warn ("Found '}' when manual bundling is off");
else
CURR_SLOT.manual_bundling_off = 1;
md.manual_bundling = 0;
sep = '\0';
}
return sep;
}
/* Returns the next entry in the opcode table that matches the one in
IDESC, and frees the entry in IDESC. If no matching entry is
found, NULL is returned instead. */
static struct ia64_opcode *
get_next_opcode (struct ia64_opcode *idesc)
{
struct ia64_opcode *next = ia64_find_next_opcode (idesc);
ia64_free_opcode (idesc);
return next;
}
/* Parse the operands for the opcode and find the opcode variant that
matches the specified operands, or NULL if no match is possible. */
static struct ia64_opcode*
parse_operands (idesc)
struct ia64_opcode *idesc;
{
int i = 0, highest_unmatched_operand, num_operands = 0, num_outputs = 0;
int sep = 0;
enum ia64_opnd expected_operand = IA64_OPND_NIL;
char mnemonic[129];
char *first_arg = 0, *end, *saved_input_pointer;
unsigned int sof;
assert (strlen (idesc->name) <= 128);
strcpy (mnemonic, idesc->name);
if (idesc->operands[2] == IA64_OPND_SOF)
{
/* To make the common idiom "alloc loc?=ar.pfs,0,1,0,0" work, we
can't parse the first operand until we have parsed the
remaining operands of the "alloc" instruction. */
SKIP_WHITESPACE ();
first_arg = input_line_pointer;
end = strchr (input_line_pointer, '=');
if (!end)
{
as_bad ("Expected separator `='");
return 0;
}
input_line_pointer = end + 1;
++i;
++num_outputs;
}
for (; i < NELEMS (CURR_SLOT.opnd); ++i)
{
sep = parse_operand (CURR_SLOT.opnd + i);
if (CURR_SLOT.opnd[i].X_op == O_absent)
break;
++num_operands;
if (sep != '=' && sep != ',')
break;
if (sep == '=')
{
if (num_outputs > 0)
as_bad ("Duplicate equal sign (=) in instruction");
else
num_outputs = i + 1;
}
}
if (sep != '\0')
{
as_bad ("Illegal operand separator `%c'", sep);
return 0;
}
if (idesc->operands[2] == IA64_OPND_SOF)
{
/* map alloc r1=ar.pfs,i,l,o,r to alloc r1=ar.pfs,(i+l+o),(i+l),r */
know (strcmp (idesc->name, "alloc") == 0);
if (num_operands == 5 /* first_arg not included in this count! */
&& CURR_SLOT.opnd[2].X_op == O_constant
&& CURR_SLOT.opnd[3].X_op == O_constant
&& CURR_SLOT.opnd[4].X_op == O_constant
&& CURR_SLOT.opnd[5].X_op == O_constant)
{
sof = set_regstack (CURR_SLOT.opnd[2].X_add_number,
CURR_SLOT.opnd[3].X_add_number,
CURR_SLOT.opnd[4].X_add_number,
CURR_SLOT.opnd[5].X_add_number);
/* now we can parse the first arg: */
saved_input_pointer = input_line_pointer;
input_line_pointer = first_arg;
sep = parse_operand (CURR_SLOT.opnd + 0);
if (sep != '=')
--num_outputs; /* force error */
input_line_pointer = saved_input_pointer;
CURR_SLOT.opnd[2].X_add_number = sof;
CURR_SLOT.opnd[3].X_add_number
= sof - CURR_SLOT.opnd[4].X_add_number;
CURR_SLOT.opnd[4] = CURR_SLOT.opnd[5];
}
}
highest_unmatched_operand = 0;
expected_operand = idesc->operands[0];
for (; idesc; idesc = get_next_opcode (idesc))
{
if (num_outputs != idesc->num_outputs)
continue; /* mismatch in # of outputs */
CURR_SLOT.num_fixups = 0;
for (i = 0; i < num_operands && idesc->operands[i]; ++i)
if (!operand_match (idesc, i, CURR_SLOT.opnd + i))
break;
if (i != num_operands)
{
if (i > highest_unmatched_operand)
{
highest_unmatched_operand = i;
expected_operand = idesc->operands[i];
}
continue;
}
if (num_operands < NELEMS (idesc->operands)
&& idesc->operands[num_operands])
continue; /* mismatch in number of arguments */
break;
}
if (!idesc)
{
if (expected_operand)
as_bad ("Operand %u of `%s' should be %s",
highest_unmatched_operand + 1, mnemonic,
elf64_ia64_operands[expected_operand].desc);
else
as_bad ("Operand mismatch");
return 0;
}
return idesc;
}
static void
build_insn (slot, insnp)
struct slot *slot;
bfd_vma *insnp;
{
const struct ia64_operand *odesc, *o2desc;
struct ia64_opcode *idesc = slot->idesc;
bfd_signed_vma insn, val;
const char *err;
int i;
insn = idesc->opcode | slot->qp_regno;
for (i = 0; i < NELEMS (idesc->operands) && idesc->operands[i]; ++i)
{
if (slot->opnd[i].X_op == O_register
|| slot->opnd[i].X_op == O_constant
|| slot->opnd[i].X_op == O_index)
val = slot->opnd[i].X_add_number;
else if (slot->opnd[i].X_op == O_big)
{
/* This must be the value 0x10000000000000000. */
assert (idesc->operands[i] == IA64_OPND_IMM8M1U8);
val = 0;
}
else
val = 0;
switch (idesc->operands[i])
{
case IA64_OPND_IMMU64:
*insnp++ = (val >> 22) & 0x1ffffffffffLL;
insn |= (((val & 0x7f) << 13) | (((val >> 7) & 0x1ff) << 27)
| (((val >> 16) & 0x1f) << 22) | (((val >> 21) & 0x1) << 21)
| (((val >> 63) & 0x1) << 36));
continue;
case IA64_OPND_IMMU62:
val &= 0x3fffffffffffffffULL;
if (val != slot->opnd[i].X_add_number)
as_warn (_("Value truncated to 62 bits"));
*insnp++ = (val >> 21) & 0x1ffffffffffLL;
insn |= (((val & 0xfffff) << 6) | (((val >> 20) & 0x1) << 36));
continue;
case IA64_OPND_TGT64:
val >>= 4;
*insnp++ = ((val >> 20) & 0x7fffffffffLL) << 2;
insn |= ((((val >> 59) & 0x1) << 36)
| (((val >> 0) & 0xfffff) << 13));
continue;
case IA64_OPND_AR3:
val -= REG_AR;
break;
case IA64_OPND_B1:
case IA64_OPND_B2:
val -= REG_BR;
break;
case IA64_OPND_CR3:
val -= REG_CR;
break;
case IA64_OPND_F1:
case IA64_OPND_F2:
case IA64_OPND_F3:
case IA64_OPND_F4:
val -= REG_FR;
break;
case IA64_OPND_P1:
case IA64_OPND_P2:
val -= REG_P;
break;
case IA64_OPND_R1:
case IA64_OPND_R2:
case IA64_OPND_R3:
case IA64_OPND_R3_2:
case IA64_OPND_CPUID_R3:
case IA64_OPND_DBR_R3:
case IA64_OPND_DTR_R3:
case IA64_OPND_ITR_R3:
case IA64_OPND_IBR_R3:
case IA64_OPND_MR3:
case IA64_OPND_MSR_R3:
case IA64_OPND_PKR_R3:
case IA64_OPND_PMC_R3:
case IA64_OPND_PMD_R3:
case IA64_OPND_RR_R3:
val -= REG_GR;
break;
default:
break;
}
odesc = elf64_ia64_operands + idesc->operands[i];
err = (*odesc->insert) (odesc, val, &insn);
if (err)
as_bad_where (slot->src_file, slot->src_line,
"Bad operand value: %s", err);
if (idesc->flags & IA64_OPCODE_PSEUDO)
{
if ((idesc->flags & IA64_OPCODE_F2_EQ_F3)
&& odesc == elf64_ia64_operands + IA64_OPND_F3)
{
o2desc = elf64_ia64_operands + IA64_OPND_F2;
(*o2desc->insert) (o2desc, val, &insn);
}
if ((idesc->flags & IA64_OPCODE_LEN_EQ_64MCNT)
&& (odesc == elf64_ia64_operands + IA64_OPND_CPOS6a
|| odesc == elf64_ia64_operands + IA64_OPND_POS6))
{
o2desc = elf64_ia64_operands + IA64_OPND_LEN6;
(*o2desc->insert) (o2desc, 64 - val, &insn);
}
}
}
*insnp = insn;
}
static void
emit_one_bundle ()
{
unsigned int manual_bundling_on = 0, manual_bundling_off = 0;
unsigned int manual_bundling = 0;
enum ia64_unit required_unit, insn_unit = 0;
enum ia64_insn_type type[3], insn_type;
unsigned int template, orig_template;
bfd_vma insn[3] = {-1, -1, -1};
struct ia64_opcode *idesc;
int end_of_insn_group = 0, user_template = -1;
int n, i, j, first, curr;
unw_rec_list *ptr, *prev;
bfd_vma t0 = 0, t1 = 0;
struct label_fix *lfix;
struct insn_fix *ifix;
char mnemonic[16];
fixS *fix;
char *f;
first = (md.curr_slot + NUM_SLOTS - md.num_slots_in_use) % NUM_SLOTS;
know (first >= 0 & first < NUM_SLOTS);
n = MIN (3, md.num_slots_in_use);
/* Determine template: user user_template if specified, best match
otherwise: */
if (md.slot[first].user_template >= 0)
user_template = template = md.slot[first].user_template;
else
{
/* auto select appropriate template */
memset (type, 0, sizeof (type));
curr = first;
for (i = 0; i < n; ++i)
{
type[i] = md.slot[curr].idesc->type;
curr = (curr + 1) % NUM_SLOTS;
}
template = best_template[type[0]][type[1]][type[2]];
}
/* initialize instructions with appropriate nops: */
for (i = 0; i < 3; ++i)
insn[i] = nop[ia64_templ_desc[template].exec_unit[i]];
f = frag_more (16);
/* now fill in slots with as many insns as possible: */
curr = first;
idesc = md.slot[curr].idesc;
end_of_insn_group = 0;
for (i = 0; i < 3 && md.num_slots_in_use > 0; ++i)
{
/* Set the slot number for prologue/body records now as those
refer to the current point, not the point after the
instruction has been issued: */
prev = 0;
for (ptr = md.slot[curr].unwind_record; ptr; ptr = ptr->next)
{
if (ptr->r.type == prologue || ptr->r.type == prologue_gr
|| ptr->r.type == body)
{
ptr->slot_number = (unsigned long) f + i;
if (prev)
prev->next = ptr->next;
else
md.slot[curr].unwind_record = ptr->next;
}
else
prev = ptr;
}
if (idesc->flags & IA64_OPCODE_SLOT2)
{
if (manual_bundling && i != 2)
as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
"`%s' must be last in bundle", idesc->name);
else
i = 2;
}
if (idesc->flags & IA64_OPCODE_LAST)
{
int required_slot, required_template;
/* If we need a stop bit after an M slot, our only choice is
template 5 (M;;MI). If we need a stop bit after a B
slot, our only choice is to place it at the end of the
bundle, because the only available templates are MIB,
MBB, BBB, MMB, and MFB. We don't handle anything other
than M and B slots because these are the only kind of
instructions that can have the IA64_OPCODE_LAST bit set. */
required_template = template;
switch (idesc->type)
{
case IA64_TYPE_M:
required_slot = 0;
required_template = 5;
break;
case IA64_TYPE_B:
required_slot = 2;
break;
default:
as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
"Internal error: don't know how to force %s to end"
"of instruction group", idesc->name);
required_slot = i;
break;
}
if (manual_bundling && i != required_slot)
as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
"`%s' must be last in instruction group",
idesc->name);
if (required_slot < i)
/* Can't fit this instruction. */
break;
i = required_slot;
if (required_template != template)
{
/* If we switch the template, we need to reset the NOPs
after slot i. The slot-types of the instructions ahead
of i never change, so we don't need to worry about
changing NOPs in front of this slot. */
for (j = i; j < 3; ++j)
insn[j] = nop[ia64_templ_desc[required_template].exec_unit[j]];
}
template = required_template;
}
if (curr != first && md.slot[curr].label_fixups)
{
if (manual_bundling_on)
as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
"Label must be first in a bundle");
/* This insn must go into the first slot of a bundle. */
break;
}
manual_bundling_on = md.slot[curr].manual_bundling_on;
manual_bundling_off = md.slot[curr].manual_bundling_off;
if (manual_bundling_on)
{
if (curr == first)
manual_bundling = 1;
else
break; /* need to start a new bundle */
}
if (end_of_insn_group && md.num_slots_in_use >= 1)
{
/* We need an instruction group boundary in the middle of a
bundle. See if we can switch to an other template with
an appropriate boundary. */
orig_template = template;
if (i == 1 && (user_template == 4
|| (user_template < 0
&& (ia64_templ_desc[template].exec_unit[0]
== IA64_UNIT_M))))
{
template = 5;
end_of_insn_group = 0;
}
else if (i == 2 && (user_template == 0
|| (user_template < 0
&& (ia64_templ_desc[template].exec_unit[1]
== IA64_UNIT_I)))
/* This test makes sure we don't switch the template if
the next instruction is one that needs to be first in
an instruction group. Since all those instructions are
in the M group, there is no way such an instruction can
fit in this bundle even if we switch the template. The
reason we have to check for this is that otherwise we
may end up generating "MI;;I M.." which has the deadly
effect that the second M instruction is no longer the
first in the bundle! --davidm 99/12/16 */
&& (idesc->flags & IA64_OPCODE_FIRST) == 0)
{
template = 1;
end_of_insn_group = 0;
}
else if (curr != first)
/* can't fit this insn */
break;
if (template != orig_template)
/* if we switch the template, we need to reset the NOPs
after slot i. The slot-types of the instructions ahead
of i never change, so we don't need to worry about
changing NOPs in front of this slot. */
for (j = i; j < 3; ++j)
insn[j] = nop[ia64_templ_desc[template].exec_unit[j]];
}
required_unit = ia64_templ_desc[template].exec_unit[i];
/* resolve dynamic opcodes such as "break" and "nop": */
if (idesc->type == IA64_TYPE_DYN)
{
if ((strcmp (idesc->name, "nop") == 0)
|| (strcmp (idesc->name, "break") == 0))
insn_unit = required_unit;
else if (strcmp (idesc->name, "chk.s") == 0)
{
insn_unit = IA64_UNIT_M;
if (required_unit == IA64_UNIT_I)
insn_unit = IA64_UNIT_I;
}
else
as_fatal ("emit_one_bundle: unexpected dynamic op");
sprintf (mnemonic, "%s.%c", idesc->name, "?imbf??"[insn_unit]);
md.slot[curr].idesc = idesc = ia64_find_opcode (mnemonic);
#if 0
know (!idesc->next); /* no resolved dynamic ops have collisions */
#endif
}
else
{
insn_type = idesc->type;
insn_unit = IA64_UNIT_NIL;
switch (insn_type)
{
case IA64_TYPE_A:
if (required_unit == IA64_UNIT_I || required_unit == IA64_UNIT_M)
insn_unit = required_unit;
break;
case IA64_TYPE_X: insn_unit = IA64_UNIT_L; break;
case IA64_TYPE_I: insn_unit = IA64_UNIT_I; break;
case IA64_TYPE_M: insn_unit = IA64_UNIT_M; break;
case IA64_TYPE_B: insn_unit = IA64_UNIT_B; break;
case IA64_TYPE_F: insn_unit = IA64_UNIT_F; break;
default: break;
}
}
if (insn_unit != required_unit)
{
if (required_unit == IA64_UNIT_L
&& insn_unit == IA64_UNIT_I
&& !(idesc->flags & IA64_OPCODE_X_IN_MLX))
{
/* we got ourselves an MLX template but the current
instruction isn't an X-unit, or an I-unit instruction
that can go into the X slot of an MLX template. Duh. */
if (md.num_slots_in_use >= NUM_SLOTS)
{
as_bad_where (md.slot[curr].src_file,
md.slot[curr].src_line,
"`%s' can't go in X slot of "
"MLX template", idesc->name);
/* drop this insn so we don't livelock: */
--md.num_slots_in_use;
}
break;
}
continue; /* try next slot */
}
if (debug_type == DEBUG_DWARF2)
{
bfd_vma addr;
addr = frag_now->fr_address + frag_now_fix () - 16 + 1*i;
dwarf2_gen_line_info (addr, &md.slot[curr].debug_line);
}
build_insn (md.slot + curr, insn + i);
/* Set slot counts for unwind records. */
while (md.slot[curr].unwind_record)
{
md.slot[curr].unwind_record->slot_number = (unsigned long) f + i;
md.slot[curr].unwind_record = md.slot[curr].unwind_record->next;
}
unwind.next_slot_number = (unsigned long) f + i + ((i == 2)?(0x10-2):1);
if (required_unit == IA64_UNIT_L)
{
know (i == 1);
/* skip one slot for long/X-unit instructions */
++i;
}
--md.num_slots_in_use;
/* now is a good time to fix up the labels for this insn: */
for (lfix = md.slot[curr].label_fixups; lfix; lfix = lfix->next)
{
S_SET_VALUE (lfix->sym, frag_now_fix () - 16);
symbol_set_frag (lfix->sym, frag_now);
}
for (j = 0; j < md.slot[curr].num_fixups; ++j)
{
ifix = md.slot[curr].fixup + j;
fix = fix_new_exp (frag_now, frag_now_fix () - 16 + i, 4,
&ifix->expr, ifix->is_pcrel, ifix->code);
fix->tc_fix_data.opnd = ifix->opnd;
fix->fx_plt = (fix->fx_r_type == BFD_RELOC_IA64_PLTOFF22);
fix->fx_file = md.slot[curr].src_file;
fix->fx_line = md.slot[curr].src_line;
}
end_of_insn_group = md.slot[curr].end_of_insn_group;
/* clear slot: */
ia64_free_opcode (md.slot[curr].idesc);
memset (md.slot + curr, 0, sizeof (md.slot[curr]));
md.slot[curr].user_template = -1;
if (manual_bundling_off)
{
manual_bundling = 0;
break;
}
curr = (curr + 1) % NUM_SLOTS;
idesc = md.slot[curr].idesc;
}
if (manual_bundling)
{
if (md.num_slots_in_use > 0)
as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
"`%s' does not fit into %s template",
idesc->name, ia64_templ_desc[template].name);
else
as_bad_where (md.slot[curr].src_file, md.slot[curr].src_line,
"Missing '}' at end of file");
}
know (md.num_slots_in_use < NUM_SLOTS);
t0 = end_of_insn_group | (template << 1) | (insn[0] << 5) | (insn[1] << 46);
t1 = ((insn[1] >> 18) & 0x7fffff) | (insn[2] << 23);
md_number_to_chars (f + 0, t0, 8);
md_number_to_chars (f + 8, t1, 8);
}
int
md_parse_option (c, arg)
int c;
char *arg;
{
/* Switches from the Intel assembler. */
switch (c)
{
case 'M':
if (strcmp (arg, "ilp64") == 0
|| strcmp (arg, "lp64") == 0
|| strcmp (arg, "p64") == 0)
{
md.flags |= EF_IA_64_ABI64;
}
else if (strcmp (arg, "ilp32") == 0)
{
md.flags &= ~EF_IA_64_ABI64;
}
else if (strcmp (arg, "le") == 0)
{
md.flags &= ~EF_IA_64_BE;
}
else if (strcmp (arg, "be") == 0)
{
md.flags |= EF_IA_64_BE;
}
else
return 0;
break;
case 'N':
if (strcmp (arg, "so") == 0)
{
/* Suppress signon message. */
}
else if (strcmp (arg, "pi") == 0)
{
/* Reject privileged instructions. FIXME */
}
else if (strcmp (arg, "us") == 0)
{
/* Allow union of signed and unsigned range. FIXME */
}
else if (strcmp (arg, "close_fcalls") == 0)
{
/* Do not resolve global function calls. */
}
else
return 0;
break;
case 'C':
/* temp[="prefix"] Insert temporary labels into the object file
symbol table prefixed by "prefix".
Default prefix is ":temp:".
*/
break;
case 'a':
/* ??? Conflicts with gas' listing option. */
/* indirect=<tgt> Assume unannotated indirect branches behavior
according to <tgt> --
exit: branch out from the current context (default)
labels: all labels in context may be branch targets
*/
break;
case 'x':
/* -X conflicts with an ignored option, use -x instead */
md.detect_dv = 1;
if (!arg || strcmp (arg, "explicit") == 0)
{
/* set default mode to explicit */
md.default_explicit_mode = 1;
break;
}
else if (strcmp (arg, "auto") == 0)
{
md.default_explicit_mode = 0;
}
else if (strcmp (arg, "debug") == 0)
{
md.debug_dv = 1;
}
else if (strcmp (arg, "debugx") == 0)
{
md.default_explicit_mode = 1;
md.debug_dv = 1;
}
else
{
as_bad (_("Unrecognized option '-x%s'"), arg);
}
break;
case 'S':
/* nops Print nops statistics. */
break;
default:
return 0;
}
return 1;
}
void
md_show_usage (stream)
FILE *stream;
{
fputs(_("\
IA-64 options:\n\
-Milp32|-Milp64|-Mlp64|-Mp64 select data model (default -Mlp64)\n\
-Mle | -Mbe select little- or big-endian byte order (default -Mle)\n\
-x | -xexplicit turn on dependency violation checking (default)\n\
-xauto automagically remove dependency violations\n\
-xdebug debug dependency violation checker\n"),
stream);
}
static inline int
match (int templ, int type, int slot)
{
enum ia64_unit unit;
int result;
unit = ia64_templ_desc[templ].exec_unit[slot];
switch (type)
{
case IA64_TYPE_DYN: result = 1; break; /* for nop and break */
case IA64_TYPE_A:
result = (unit == IA64_UNIT_I || unit == IA64_UNIT_M);
break;
case IA64_TYPE_X: result = (unit == IA64_UNIT_L); break;
case IA64_TYPE_I: result = (unit == IA64_UNIT_I); break;
case IA64_TYPE_M: result = (unit == IA64_UNIT_M); break;
case IA64_TYPE_B: result = (unit == IA64_UNIT_B); break;
case IA64_TYPE_F: result = (unit == IA64_UNIT_F); break;
default: result = 0; break;
}
return result;
}
/* This function is called once, at assembler startup time. It sets
up all the tables, etc. that the MD part of the assembler will need
that can be determined before arguments are parsed. */
void
md_begin ()
{
int i, j, k, t, total, ar_base, cr_base, goodness, best, regnum;
const char *err;
char name[8];
md.auto_align = 1;
md.explicit_mode = md.default_explicit_mode;
bfd_set_section_alignment (stdoutput, text_section, 4);
target_big_endian = 0;
pseudo_func[FUNC_FPTR_RELATIVE].u.sym =
symbol_new (".<fptr>", undefined_section, FUNC_FPTR_RELATIVE,
&zero_address_frag);
pseudo_func[FUNC_GP_RELATIVE].u.sym =
symbol_new (".<gprel>", undefined_section, FUNC_GP_RELATIVE,
&zero_address_frag);
pseudo_func[FUNC_LT_RELATIVE].u.sym =
symbol_new (".<ltoff>", undefined_section, FUNC_LT_RELATIVE,
&zero_address_frag);
pseudo_func[FUNC_PC_RELATIVE].u.sym =
symbol_new (".<pcrel>", undefined_section, FUNC_PC_RELATIVE,
&zero_address_frag);
pseudo_func[FUNC_PLT_RELATIVE].u.sym =
symbol_new (".<pltoff>", undefined_section, FUNC_PLT_RELATIVE,
&zero_address_frag);
pseudo_func[FUNC_SEC_RELATIVE].u.sym =
symbol_new (".<secrel>", undefined_section, FUNC_SEC_RELATIVE,
&zero_address_frag);
pseudo_func[FUNC_SEG_RELATIVE].u.sym =
symbol_new (".<segrel>", undefined_section, FUNC_SEG_RELATIVE,
&zero_address_frag);
pseudo_func[FUNC_LTV_RELATIVE].u.sym =
symbol_new (".<ltv>", undefined_section, FUNC_LTV_RELATIVE,
&zero_address_frag);
pseudo_func[FUNC_LT_FPTR_RELATIVE].u.sym =
symbol_new (".<ltoff.fptr>", undefined_section, FUNC_LT_FPTR_RELATIVE,
&zero_address_frag);
/* compute the table of best templates: */
for (i = 0; i < IA64_NUM_TYPES; ++i)
for (j = 0; j < IA64_NUM_TYPES; ++j)
for (k = 0; k < IA64_NUM_TYPES; ++k)
{
best = 0;
for (t = 0; t < NELEMS (ia64_templ_desc); ++t)
{
goodness = 0;
if (match (t, i, 0))
{
if (match (t, j, 1))
{
if (match (t, k, 2))
goodness = 3;
else
goodness = 2;
}
else if (match (t, j, 2))
goodness = 2;
else
goodness = 1;
}
else if (match (t, i, 1))
{
if (match (t, j, 2))
goodness = 2;
else
goodness = 1;
}
else if (match (t, i, 2))
goodness = 1;
if (goodness > best)
{
best = goodness;
best_template[i][j][k] = t;
}
}
}
for (i = 0; i < NUM_SLOTS; ++i)
md.slot[i].user_template = -1;
md.pseudo_hash = hash_new ();
for (i = 0; i < NELEMS (pseudo_opcode); ++i)
{
err = hash_insert (md.pseudo_hash, pseudo_opcode[i].name,
(void *) (pseudo_opcode + i));
if (err)
as_fatal ("ia64.md_begin: can't hash `%s': %s",
pseudo_opcode[i].name, err);
}
md.reg_hash = hash_new ();
md.dynreg_hash = hash_new ();
md.const_hash = hash_new ();
md.entry_hash = hash_new ();
/* general registers: */
total = 128;
for (i = 0; i < total; ++i)
{
sprintf (name, "r%d", i - REG_GR);
md.regsym[i] = declare_register (name, i);
}
/* floating point registers: */
total += 128;
for (; i < total; ++i)
{
sprintf (name, "f%d", i - REG_FR);
md.regsym[i] = declare_register (name, i);
}
/* application registers: */
total += 128;
ar_base = i;
for (; i < total; ++i)
{
sprintf (name, "ar%d", i - REG_AR);
md.regsym[i] = declare_register (name, i);
}
/* control registers: */
total += 128;
cr_base = i;
for (; i < total; ++i)
{
sprintf (name, "cr%d", i - REG_CR);
md.regsym[i] = declare_register (name, i);
}
/* predicate registers: */
total += 64;
for (; i < total; ++i)
{
sprintf (name, "p%d", i - REG_P);
md.regsym[i] = declare_register (name, i);
}
/* branch registers: */
total += 8;
for (; i < total; ++i)
{
sprintf (name, "b%d", i - REG_BR);
md.regsym[i] = declare_register (name, i);
}
md.regsym[REG_IP] = declare_register ("ip", REG_IP);
md.regsym[REG_CFM] = declare_register ("cfm", REG_CFM);
md.regsym[REG_PR] = declare_register ("pr", REG_PR);
md.regsym[REG_PR_ROT] = declare_register ("pr.rot", REG_PR_ROT);
md.regsym[REG_PSR] = declare_register ("psr", REG_PSR);
md.regsym[REG_PSR_L] = declare_register ("psr.l", REG_PSR_L);
md.regsym[REG_PSR_UM] = declare_register ("psr.um", REG_PSR_UM);
for (i = 0; i < NELEMS (indirect_reg); ++i)
{
regnum = indirect_reg[i].regnum;
md.regsym[regnum] = declare_register (indirect_reg[i].name, regnum);
}
/* define synonyms for application registers: */
for (i = REG_AR; i < REG_AR + NELEMS (ar); ++i)
md.regsym[i] = declare_register (ar[i - REG_AR].name,
REG_AR + ar[i - REG_AR].regnum);
/* define synonyms for control registers: */
for (i = REG_CR; i < REG_CR + NELEMS (cr); ++i)
md.regsym[i] = declare_register (cr[i - REG_CR].name,
REG_CR + cr[i - REG_CR].regnum);
declare_register ("gp", REG_GR + 1);
declare_register ("sp", REG_GR + 12);
declare_register ("rp", REG_BR + 0);
/* pseudo-registers used to specify unwind info: */
declare_register ("psp", REG_PSP);
declare_register_set ("ret", 4, REG_GR + 8);
declare_register_set ("farg", 8, REG_FR + 8);
declare_register_set ("fret", 8, REG_FR + 8);
for (i = 0; i < NELEMS (const_bits); ++i)
{
err = hash_insert (md.const_hash, const_bits[i].name,
(PTR) (const_bits + i));
if (err)
as_fatal ("Inserting \"%s\" into constant hash table failed: %s",
name, err);
}
/* Default to 64-bit mode. */
md.flags = EF_IA_64_ABI64;
md.mem_offset.hint = 0;
md.path = 0;
md.maxpaths = 0;
md.entry_labels = NULL;
}
void
ia64_end_of_source ()
{
/* terminate insn group upon reaching end of file: */
insn_group_break (1, 0, 0);
/* emits slots we haven't written yet: */
ia64_flush_insns ();
bfd_set_private_flags (stdoutput, md.flags);
if (debug_type == DEBUG_DWARF2)
dwarf2_finish ();
md.mem_offset.hint = 0;
}
void
ia64_start_line ()
{
md.qp.X_op = O_absent;
if (ignore_input ())
return;
if (input_line_pointer[0] == ';' && input_line_pointer[-1] == ';')
{
if (md.detect_dv && !md.explicit_mode)
as_warn (_("Explicit stops are ignored in auto mode"));
else
insn_group_break (1, 0, 0);
}
}
int
ia64_unrecognized_line (ch)
int ch;
{
switch (ch)
{
case '(':
expression (&md.qp);
if (*input_line_pointer++ != ')')
{
as_bad ("Expected ')'");
return 0;
}
if (md.qp.X_op != O_register)
{
as_bad ("Qualifying predicate expected");
return 0;
}
if (md.qp.X_add_number < REG_P || md.qp.X_add_number >= REG_P + 64)
{
as_bad ("Predicate register expected");
return 0;
}
return 1;
case '{':
if (md.manual_bundling)
as_warn ("Found '{' when manual bundling is already turned on");
else
CURR_SLOT.manual_bundling_on = 1;
md.manual_bundling = 1;
/* bundling is only acceptable in explicit mode
or when in default automatic mode */
if (md.detect_dv && !md.explicit_mode)
{
if (!md.mode_explicitly_set
&& !md.default_explicit_mode)
dot_dv_mode ('E');
else
as_warn (_("Found '{' after explicit switch to automatic mode"));
}
return 1;
case '}':
if (!md.manual_bundling)
as_warn ("Found '}' when manual bundling is off");
else
PREV_SLOT.manual_bundling_off = 1;
md.manual_bundling = 0;
/* switch back to automatic mode, if applicable */
if (md.detect_dv
&& md.explicit_mode
&& !md.mode_explicitly_set
&& !md.default_explicit_mode)
dot_dv_mode ('A');
/* Allow '{' to follow on the same line. We also allow ";;", but that
happens automatically because ';' is an end of line marker. */
SKIP_WHITESPACE ();
if (input_line_pointer[0] == '{')
{
input_line_pointer++;
return ia64_unrecognized_line ('{');
}
demand_empty_rest_of_line ();
return 1;
default:
break;
}
return 0; /* not a valid line */
}
void
ia64_frob_label (sym)
struct symbol *sym;
{
struct label_fix *fix;
if (bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE)
{
md.last_text_seg = now_seg;
fix = obstack_alloc (&notes, sizeof (*fix));
fix->sym = sym;
fix->next = CURR_SLOT.label_fixups;
CURR_SLOT.label_fixups = fix;
/* keep track of how many code entry points we've seen */
if (md.path == md.maxpaths)
{
md.maxpaths += 20;
md.entry_labels = (const char **)
xrealloc ((void *)md.entry_labels, md.maxpaths * sizeof (char *));
}
md.entry_labels[md.path++] = S_GET_NAME (sym);
}
}
void
ia64_flush_pending_output ()
{
if (bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE)
{
/* ??? This causes many unnecessary stop bits to be emitted.
Unfortunately, it isn't clear if it is safe to remove this. */
insn_group_break (1, 0, 0);
ia64_flush_insns ();
}
}
/* Do ia64-specific expression optimization. All that's done here is
to transform index expressions that are either due to the indexing
of rotating registers or due to the indexing of indirect register
sets. */
int
ia64_optimize_expr (l, op, r)
expressionS *l;
operatorT op;
expressionS *r;
{
unsigned num_regs;
if (op == O_index)
{
if (l->X_op == O_register && r->X_op == O_constant)
{
num_regs = (l->X_add_number >> 16);
if ((unsigned) r->X_add_number >= num_regs)
{
if (!num_regs)
as_bad ("No current frame");
else
as_bad ("Index out of range 0..%u", num_regs - 1);
r->X_add_number = 0;
}
l->X_add_number = (l->X_add_number & 0xffff) + r->X_add_number;
return 1;
}
else if (l->X_op == O_register && r->X_op == O_register)
{
if (l->X_add_number < IND_CPUID || l->X_add_number > IND_RR
|| l->X_add_number == IND_MEM)
{
as_bad ("Indirect register set name expected");
l->X_add_number = IND_CPUID;
}
l->X_op = O_index;
l->X_op_symbol = md.regsym[l->X_add_number];
l->X_add_number = r->X_add_number;
return 1;
}
}
return 0;
}
int
ia64_parse_name (name, e)
char *name;
expressionS *e;
{
struct const_desc *cdesc;
struct dynreg *dr = 0;
unsigned int regnum;
struct symbol *sym;
char *end;
/* first see if NAME is a known register name: */
sym = hash_find (md.reg_hash, name);
if (sym)
{
e->X_op = O_register;
e->X_add_number = S_GET_VALUE (sym);
return 1;
}
cdesc = hash_find (md.const_hash, name);
if (cdesc)
{
e->X_op = O_constant;
e->X_add_number = cdesc->value;
return 1;
}
/* check for inN, locN, or outN: */
switch (name[0])
{
case 'i':
if (name[1] == 'n' && isdigit (name[2]))
{
dr = &md.in;
name += 2;
}
break;
case 'l':
if (name[1] == 'o' && name[2] == 'c' && isdigit (name[3]))
{
dr = &md.loc;
name += 3;
}
break;
case 'o':
if (name[1] == 'u' && name[2] == 't' && isdigit (name[3]))
{
dr = &md.out;
name += 3;
}
break;
default:
break;
}
if (dr)
{
/* the name is inN, locN, or outN; parse the register number: */
regnum = strtoul (name, &end, 10);
if (end > name && *end == '\0')
{
if ((unsigned) regnum >= dr->num_regs)
{
if (!dr->num_regs)
as_bad ("No current frame");
else
as_bad ("Register number out of range 0..%u", dr->num_regs-1);
regnum = 0;
}
e->X_op = O_register;
e->X_add_number = dr->base + regnum;
return 1;
}
}
if ((dr = hash_find (md.dynreg_hash, name)))
{
/* We've got ourselves the name of a rotating register set.
Store the base register number in the low 16 bits of
X_add_number and the size of the register set in the top 16
bits. */
e->X_op = O_register;
e->X_add_number = dr->base | (dr->num_regs << 16);
return 1;
}
return 0;
}
/* Remove the '#' suffix that indicates a symbol as opposed to a register. */
char *
ia64_canonicalize_symbol_name (name)
char *name;
{
size_t len = strlen(name);
if (len > 1 && name[len-1] == '#')
name[len-1] = '\0';
return name;
}
static int
is_conditional_branch (idesc)
struct ia64_opcode *idesc;
{
return (strncmp (idesc->name, "br", 2) == 0
&& (strcmp (idesc->name, "br") == 0
|| strncmp (idesc->name, "br.cond", 7) == 0
|| strncmp (idesc->name, "br.call", 7) == 0
|| strncmp (idesc->name, "br.ret", 6) == 0
|| strcmp (idesc->name, "brl") == 0
|| strncmp (idesc->name, "brl.cond", 7) == 0
|| strncmp (idesc->name, "brl.call", 7) == 0
|| strncmp (idesc->name, "brl.ret", 6) == 0));
}
/* Return whether the given opcode is a taken branch. If there's any doubt,
returns zero */
static int
is_taken_branch (idesc)
struct ia64_opcode *idesc;
{
return ((is_conditional_branch (idesc) && CURR_SLOT.qp_regno == 0)
|| strncmp (idesc->name, "br.ia", 5) == 0);
}
/* Return whether the given opcode is an interruption or rfi. If there's any
doubt, returns zero */
static int
is_interruption_or_rfi (idesc)
struct ia64_opcode *idesc;
{
if (strcmp (idesc->name, "rfi") == 0)
return 1;
return 0;
}
/* Returns the index of the given dependency in the opcode's list of chks, or
-1 if there is no dependency. */
static int
depends_on (depind, idesc)
int depind;
struct ia64_opcode *idesc;
{
int i;
const struct ia64_opcode_dependency *dep = idesc->dependencies;
for (i = 0;i < dep->nchks; i++)
{
if (depind == DEP(dep->chks[i]))
return i;
}
return -1;
}
/* Determine a set of specific resources used for a particular resource
class. Returns the number of specific resources identified For those
cases which are not determinable statically, the resource returned is
marked nonspecific.
Meanings of value in 'NOTE':
1) only read/write when the register number is explicitly encoded in the
insn.
2) only read CFM when accessing a rotating GR, FR, or PR. mov pr only
accesses CFM when qualifying predicate is in the rotating region.
3) general register value is used to specify an indirect register; not
determinable statically.
4) only read the given resource when bits 7:0 of the indirect index
register value does not match the register number of the resource; not
determinable statically.
5) all rules are implementation specific.
6) only when both the index specified by the reader and the index specified
by the writer have the same value in bits 63:61; not determinable
statically.
7) only access the specified resource when the corresponding mask bit is
set
8) PSR.dfh is only read when these insns reference FR32-127. PSR.dfl is
only read when these insns reference FR2-31
9) PSR.mfl is only written when these insns write FR2-31. PSR.mfh is only
written when these insns write FR32-127
10) The PSR.bn bit is only accessed when one of GR16-31 is specified in the
instruction
11) The target predicates are written independently of PR[qp], but source
registers are only read if PR[qp] is true. Since the state of PR[qp]
cannot statically be determined, all source registers are marked used.
12) This insn only reads the specified predicate register when that
register is the PR[qp].
13) This reference to ld-c only applies to teh GR whose value is loaded
with data returned from memory, not the post-incremented address register.
14) The RSE resource includes the implementation-specific RSE internal
state resources. At least one (and possibly more) of these resources are
read by each instruction listed in IC:rse-readers. At least one (and
possibly more) of these resources are written by each insn listed in
IC:rse-writers.
15+16) Represents reserved instructions, which the assembler does not
generate.
Memory resources (i.e. locations in memory) are *not* marked or tracked by
this code; there are no dependency violations based on memory access.
*/
#define MAX_SPECS 256
#define DV_CHK 1
#define DV_REG 0
static int
specify_resource (dep, idesc, type, specs, note, path)
const struct ia64_dependency *dep;
struct ia64_opcode *idesc;
int type; /* is this a DV chk or a DV reg? */
struct rsrc specs[MAX_SPECS]; /* returned specific resources */
int note; /* resource note for this insn's usage */
int path; /* which execution path to examine */
{
int count = 0;
int i;
int rsrc_write = 0;
struct rsrc tmpl;
if (dep->mode == IA64_DV_WAW
|| (dep->mode == IA64_DV_RAW && type == DV_REG)
|| (dep->mode == IA64_DV_WAR && type == DV_CHK))
rsrc_write = 1;
/* template for any resources we identify */
tmpl.dependency = dep;
tmpl.note = note;
tmpl.insn_srlz = tmpl.data_srlz = 0;
tmpl.qp_regno = CURR_SLOT.qp_regno;
tmpl.link_to_qp_branch = 1;
tmpl.mem_offset.hint = 0;
tmpl.specific = 1;
tmpl.index = 0;
#define UNHANDLED \
as_warn (_("Unhandled dependency %s for %s (%s), note %d"), \
dep->name, idesc->name, (rsrc_write?"write":"read"), note)
#define KNOWN(REG) (gr_values[REG].known && gr_values[REG].path >= path)
/* we don't need to track these */
if (dep->semantics == IA64_DVS_NONE)
return 0;
switch (dep->specifier)
{
case IA64_RS_AR_K:
if (note == 1)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
if (regno >= 0 && regno <= 7)
{
specs[count] = tmpl;
specs[count++].index = regno;
}
}
}
else if (note == 0)
{
for(i=0;i < 8;i++)
{
specs[count] = tmpl;
specs[count++].index = i;
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_AR_UNAT:
/* This is a mov =AR or mov AR= instruction. */
if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
if (regno == AR_UNAT)
{
specs[count++] = tmpl;
}
}
else
{
/* This is a spill/fill, or other instruction that modifies the
unat register. */
/* Unless we can determine the specific bits used, mark the whole
thing; bits 8:3 of the memory address indicate the bit used in
UNAT. The .mem.offset hint may be used to eliminate a small
subset of conflicts. */
specs[count] = tmpl;
if (md.mem_offset.hint)
{
if (md.debug_dv)
fprintf (stderr, " Using hint for spill/fill\n");
/* the index isn't actually used, just set it to something
approximating the bit index */
specs[count].index = (md.mem_offset.offset >> 3) & 0x3F;
specs[count].mem_offset.hint = 1;
specs[count].mem_offset.offset = md.mem_offset.offset;
specs[count++].mem_offset.base = md.mem_offset.base;
}
else
{
specs[count++].specific = 0;
}
}
break;
case IA64_RS_AR:
if (note == 1)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
if ((regno >= 8 && regno <= 15)
|| (regno >= 20 && regno <= 23)
|| (regno >= 31 && regno <= 39)
|| (regno >= 41 && regno <= 47)
|| (regno >= 67 && regno <= 111))
{
specs[count] = tmpl;
specs[count++].index = regno;
}
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_ARb:
if (note == 1)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
if ((regno >= 48 && regno <= 63)
|| (regno >= 112 && regno <= 127))
{
specs[count] = tmpl;
specs[count++].index = regno;
}
}
}
else if (note == 0)
{
for (i=48;i < 64;i++)
{
specs[count] = tmpl;
specs[count++].index = i;
}
for (i=112;i < 128;i++)
{
specs[count] = tmpl;
specs[count++].index = i;
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_BR:
if (note != 1)
{
UNHANDLED;
}
else
{
if (rsrc_write)
{
for (i=0;i < idesc->num_outputs;i++)
if (idesc->operands[i] == IA64_OPND_B1
|| idesc->operands[i] == IA64_OPND_B2)
{
specs[count] = tmpl;
specs[count++].index =
CURR_SLOT.opnd[i].X_add_number - REG_BR;
}
}
else
{
for (i = idesc->num_outputs;i < NELEMS(idesc->operands);i++)
if (idesc->operands[i] == IA64_OPND_B1
|| idesc->operands[i] == IA64_OPND_B2)
{
specs[count] = tmpl;
specs[count++].index =
CURR_SLOT.opnd[i].X_add_number - REG_BR;
}
}
}
break;
case IA64_RS_CPUID: /* four or more registers */
if (note == 3)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_CPUID_R3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
if (regno >= 0 && regno < NELEMS(gr_values)
&& KNOWN(regno))
{
specs[count] = tmpl;
specs[count++].index = gr_values[regno].value & 0xFF;
}
else
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_DBR: /* four or more registers */
if (note == 3)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_DBR_R3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
if (regno >= 0 && regno < NELEMS(gr_values)
&& KNOWN(regno))
{
specs[count] = tmpl;
specs[count++].index = gr_values[regno].value & 0xFF;
}
else
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
}
else if (note == 0 && !rsrc_write)
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
else
{
UNHANDLED;
}
break;
case IA64_RS_IBR: /* four or more registers */
if (note == 3)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_IBR_R3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
if (regno >= 0 && regno < NELEMS(gr_values)
&& KNOWN(regno))
{
specs[count] = tmpl;
specs[count++].index = gr_values[regno].value & 0xFF;
}
else
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_MSR:
if (note == 5)
{
/* These are implementation specific. Force all references to
conflict with all other references. */
specs[count] = tmpl;
specs[count++].specific = 0;
}
else
{
UNHANDLED;
}
break;
case IA64_RS_PKR: /* 16 or more registers */
if (note == 3 || note == 4)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_PKR_R3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
if (regno >= 0 && regno < NELEMS(gr_values)
&& KNOWN(regno))
{
if (note == 3)
{
specs[count] = tmpl;
specs[count++].index = gr_values[regno].value & 0xFF;
}
else for (i=0;i < NELEMS(gr_values);i++)
{
/* uses all registers *except* the one in R3 */
if (i != (gr_values[regno].value & 0xFF))
{
specs[count] = tmpl;
specs[count++].index = i;
}
}
}
else
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
}
else if (note == 0)
{
/* probe et al. */
specs[count] = tmpl;
specs[count++].specific = 0;
}
break;
case IA64_RS_PMC: /* four or more registers */
if (note == 3)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_PMC_R3
|| (!rsrc_write && idesc->operands[1] == IA64_OPND_PMD_R3))
{
int index = ((idesc->operands[1] == IA64_OPND_R3 && !rsrc_write)
? 1 : !rsrc_write);
int regno = CURR_SLOT.opnd[index].X_add_number - REG_GR;
if (regno >= 0 && regno < NELEMS(gr_values)
&& KNOWN(regno))
{
specs[count] = tmpl;
specs[count++].index = gr_values[regno].value & 0xFF;
}
else
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_PMD: /* four or more registers */
if (note == 3)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_PMD_R3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
if (regno >= 0 && regno < NELEMS(gr_values)
&& KNOWN(regno))
{
specs[count] = tmpl;
specs[count++].index = gr_values[regno].value & 0xFF;
}
else
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_RR: /* eight registers */
if (note == 6)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_RR_R3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_GR;
if (regno >= 0 && regno < NELEMS(gr_values)
&& KNOWN(regno))
{
specs[count] = tmpl;
specs[count++].index = (gr_values[regno].value >> 61) & 0x7;
}
else
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
}
else if (note == 0 && !rsrc_write)
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
else
{
UNHANDLED;
}
break;
case IA64_RS_CR_IRR:
if (note == 0)
{
/* handle mov-from-CR-IVR; it's a read that writes CR[IRR] */
int regno = CURR_SLOT.opnd[1].X_add_number - REG_CR;
if (rsrc_write
&& idesc->operands[1] == IA64_OPND_CR3
&& regno == CR_IVR)
{
for(i=0;i < 4;i++)
{
specs[count] = tmpl;
specs[count++].index = CR_IRR0 + i;
}
}
}
else if (note == 1)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
if (idesc->operands[!rsrc_write] == IA64_OPND_CR3
&& regno >= CR_IRR0
&& regno <= CR_IRR3)
{
specs[count] = tmpl;
specs[count++].index = regno;
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_CR_LRR:
if (note != 1)
{
UNHANDLED;
}
else
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
if (idesc->operands[!rsrc_write] == IA64_OPND_CR3
&& (regno == CR_LRR0 || regno == CR_LRR1))
{
specs[count] = tmpl;
specs[count++].index = regno;
}
}
break;
case IA64_RS_CR:
if (note == 1)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_CR3)
{
specs[count] = tmpl;
specs[count++].index =
CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_FR:
case IA64_RS_FRb:
if (note != 1)
{
UNHANDLED;
}
else if (rsrc_write)
{
if (dep->specifier == IA64_RS_FRb
&& idesc->operands[0] == IA64_OPND_F1)
{
specs[count] = tmpl;
specs[count++].index = CURR_SLOT.opnd[0].X_add_number - REG_FR;
}
}
else
{
for (i=idesc->num_outputs;i < NELEMS(idesc->operands);i++)
{
if (idesc->operands[i] == IA64_OPND_F2
|| idesc->operands[i] == IA64_OPND_F3
|| idesc->operands[i] == IA64_OPND_F4)
{
specs[count] = tmpl;
specs[count++].index =
CURR_SLOT.opnd[i].X_add_number - REG_FR;
}
}
}
break;
case IA64_RS_GR:
if (note == 13)
{
/* This reference applies only to the GR whose value is loaded with
data returned from memory */
specs[count] = tmpl;
specs[count++].index = CURR_SLOT.opnd[0].X_add_number - REG_GR;
}
else if (note == 1)
{
if (rsrc_write)
{
for (i=0;i < idesc->num_outputs;i++)
{
if (idesc->operands[i] == IA64_OPND_R1
|| idesc->operands[i] == IA64_OPND_R2
|| idesc->operands[i] == IA64_OPND_R3)
{
specs[count] = tmpl;
specs[count++].index =
CURR_SLOT.opnd[i].X_add_number - REG_GR;
}
}
}
else
{
/* Look for anything that reads a GR */
for (i=0;i < NELEMS(idesc->operands);i++)
{
if (idesc->operands[i] == IA64_OPND_MR3
|| idesc->operands[i] == IA64_OPND_CPUID_R3
|| idesc->operands[i] == IA64_OPND_DBR_R3
|| idesc->operands[i] == IA64_OPND_IBR_R3
|| idesc->operands[i] == IA64_OPND_MSR_R3
|| idesc->operands[i] == IA64_OPND_PKR_R3
|| idesc->operands[i] == IA64_OPND_PMC_R3
|| idesc->operands[i] == IA64_OPND_PMD_R3
|| idesc->operands[i] == IA64_OPND_RR_R3
|| ((i >= idesc->num_outputs)
&& (idesc->operands[i] == IA64_OPND_R1
|| idesc->operands[i] == IA64_OPND_R2
|| idesc->operands[i] == IA64_OPND_R3)))
{
specs[count] = tmpl;
specs[count++].index =
CURR_SLOT.opnd[i].X_add_number - REG_GR;
}
}
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_PR:
if (note == 0)
{
if (idesc->operands[0] == IA64_OPND_PR_ROT)
{
for (i=16;i < 63;i++)
{
specs[count] = tmpl;
specs[count++].index = i;
}
}
else
{
for (i=1;i < 63;i++)
{
specs[count] = tmpl;
specs[count++].index = i;
}
}
}
else if (note == 7)
{
valueT mask = 0;
/* mark only those registers indicated by the mask */
if (rsrc_write
&& idesc->operands[0] == IA64_OPND_PR)
{
mask = CURR_SLOT.opnd[2].X_add_number;
if (mask & ((valueT)1<<16))
mask |= ~(valueT)0xffff;
for (i=1;i < 63;i++)
{
if (mask & ((valueT)1<<i))
{
specs[count] = tmpl;
specs[count++].index = i;
}
}
}
else if (rsrc_write
&& idesc->operands[0] == IA64_OPND_PR_ROT)
{
for (i=16;i < 63;i++)
{
specs[count] = tmpl;
specs[count++].index = i;
}
}
else
{
UNHANDLED;
}
}
else if (note == 11) /* note 11 implies note 1 as well */
{
if (rsrc_write)
{
for (i=0;i < idesc->num_outputs;i++)
{
if (idesc->operands[i] == IA64_OPND_P1
|| idesc->operands[i] == IA64_OPND_P2)
{
int regno = CURR_SLOT.opnd[i].X_add_number - REG_P;
if (regno != 0)
{
specs[count] = tmpl;
specs[count++].index = regno;
}
}
}
}
else
{
UNHANDLED;
}
}
else if (note == 12)
{
if (CURR_SLOT.qp_regno != 0)
{
specs[count] = tmpl;
specs[count++].index = CURR_SLOT.qp_regno;
}
}
else if (note == 1)
{
if (rsrc_write)
{
int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
if ((idesc->operands[0] == IA64_OPND_P1
|| idesc->operands[0] == IA64_OPND_P2)
&& p1 != 0 && p1 != 63)
{
specs[count] = tmpl;
specs[count++].index = p1;
}
if ((idesc->operands[1] == IA64_OPND_P1
|| idesc->operands[1] == IA64_OPND_P2)
&& p2 != 0 && p2 != 63)
{
specs[count] = tmpl;
specs[count++].index = p2;
}
}
else
{
if (CURR_SLOT.qp_regno != 0)
{
specs[count] = tmpl;
specs[count++].index = CURR_SLOT.qp_regno;
}
if (idesc->operands[1] == IA64_OPND_PR)
{
for (i=1;i < 63;i++)
{
specs[count] = tmpl;
specs[count++].index = i;
}
}
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_PSR:
/* Verify that the instruction is using the PSR bit indicated in
dep->regindex */
if (note == 0)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_PSR_UM)
{
if (dep->regindex < 6)
{
specs[count++] = tmpl;
}
}
else if (idesc->operands[!rsrc_write] == IA64_OPND_PSR)
{
if (dep->regindex < 32
|| dep->regindex == 35
|| dep->regindex == 36
|| (!rsrc_write && dep->regindex == PSR_CPL))
{
specs[count++] = tmpl;
}
}
else if (idesc->operands[!rsrc_write] == IA64_OPND_PSR_L)
{
if (dep->regindex < 32
|| dep->regindex == 35
|| dep->regindex == 36
|| (rsrc_write && dep->regindex == PSR_CPL))
{
specs[count++] = tmpl;
}
}
else
{
/* Several PSR bits have very specific dependencies. */
switch (dep->regindex)
{
default:
specs[count++] = tmpl;
break;
case PSR_IC:
if (rsrc_write)
{
specs[count++] = tmpl;
}
else
{
/* Only certain CR accesses use PSR.ic */
if (idesc->operands[0] == IA64_OPND_CR3
|| idesc->operands[1] == IA64_OPND_CR3)
{
int index =
((idesc->operands[0] == IA64_OPND_CR3)
? 0 : 1);
int regno =
CURR_SLOT.opnd[index].X_add_number - REG_CR;
switch (regno)
{
default:
break;
case CR_ITIR:
case CR_IFS:
case CR_IIM:
case CR_IIP:
case CR_IPSR:
case CR_ISR:
case CR_IFA:
case CR_IHA:
case CR_IIPA:
specs[count++] = tmpl;
break;
}
}
}
break;
case PSR_CPL:
if (rsrc_write)
{
specs[count++] = tmpl;
}
else
{
/* Only some AR accesses use cpl */
if (idesc->operands[0] == IA64_OPND_AR3
|| idesc->operands[1] == IA64_OPND_AR3)
{
int index =
((idesc->operands[0] == IA64_OPND_AR3)
? 0 : 1);
int regno =
CURR_SLOT.opnd[index].X_add_number - REG_AR;
if (regno == AR_ITC
|| (index == 0
&& (regno == AR_ITC
|| regno == AR_RSC
|| (regno >= AR_K0
&& regno <= AR_K7))))
{
specs[count++] = tmpl;
}
}
else
{
specs[count++] = tmpl;
}
break;
}
}
}
}
else if (note == 7)
{
valueT mask = 0;
if (idesc->operands[0] == IA64_OPND_IMMU24)
{
mask = CURR_SLOT.opnd[0].X_add_number;
}
else
{
UNHANDLED;
}
if (mask & ((valueT)1<<dep->regindex))
{
specs[count++] = tmpl;
}
}
else if (note == 8)
{
int min = dep->regindex == PSR_DFL ? 2 : 32;
int max = dep->regindex == PSR_DFL ? 31 : 127;
/* dfh is read on FR32-127; dfl is read on FR2-31 */
for (i=0;i < NELEMS(idesc->operands);i++)
{
if (idesc->operands[i] == IA64_OPND_F1
|| idesc->operands[i] == IA64_OPND_F2
|| idesc->operands[i] == IA64_OPND_F3
|| idesc->operands[i] == IA64_OPND_F4)
{
int reg = CURR_SLOT.opnd[i].X_add_number - REG_FR;
if (reg >= min && reg <= max)
{
specs[count++] = tmpl;
}
}
}
}
else if (note == 9)
{
int min = dep->regindex == PSR_MFL ? 2 : 32;
int max = dep->regindex == PSR_MFL ? 31 : 127;
/* mfh is read on writes to FR32-127; mfl is read on writes to
FR2-31 */
for (i=0;i < idesc->num_outputs;i++)
{
if (idesc->operands[i] == IA64_OPND_F1)
{
int reg = CURR_SLOT.opnd[i].X_add_number - REG_FR;
if (reg >= min && reg <= max)
{
specs[count++] = tmpl;
}
}
}
}
else if (note == 10)
{
for (i=0;i < NELEMS(idesc->operands);i++)
{
if (idesc->operands[i] == IA64_OPND_R1
|| idesc->operands[i] == IA64_OPND_R2
|| idesc->operands[i] == IA64_OPND_R3)
{
int regno = CURR_SLOT.opnd[i].X_add_number - REG_GR;
if (regno >= 16 && regno <= 31)
{
specs[count++] = tmpl;
}
}
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_AR_FPSR:
if (idesc->operands[!rsrc_write] == IA64_OPND_AR3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
if (regno == AR_FPSR)
{
specs[count++] = tmpl;
}
}
else
{
specs[count++] = tmpl;
}
break;
case IA64_RS_ARX:
/* Handle all AR[REG] resources */
if (note == 0 || note == 1)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_AR;
if (idesc->operands[!rsrc_write] == IA64_OPND_AR3
&& regno == dep->regindex)
{
specs[count++] = tmpl;
}
/* other AR[REG] resources may be affected by AR accesses */
else if (idesc->operands[0] == IA64_OPND_AR3)
{
/* AR[] writes */
regno = CURR_SLOT.opnd[0].X_add_number - REG_AR;
switch (dep->regindex)
{
default:
break;
case AR_BSP:
case AR_RNAT:
if (regno == AR_BSPSTORE)
{
specs[count++] = tmpl;
}
case AR_RSC:
if (!rsrc_write &&
(regno == AR_BSPSTORE
|| regno == AR_RNAT))
{
specs[count++] = tmpl;
}
break;
}
}
else if (idesc->operands[1] == IA64_OPND_AR3)
{
/* AR[] reads */
regno = CURR_SLOT.opnd[1].X_add_number - REG_AR;
switch (dep->regindex)
{
default:
break;
case AR_RSC:
if (regno == AR_BSPSTORE || regno == AR_RNAT)
{
specs[count++] = tmpl;
}
break;
}
}
else
{
specs[count++] = tmpl;
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_CRX:
/* Handle all CR[REG] resources */
if (note == 0 || note == 1)
{
if (idesc->operands[!rsrc_write] == IA64_OPND_CR3)
{
int regno = CURR_SLOT.opnd[!rsrc_write].X_add_number - REG_CR;
if (regno == dep->regindex)
{
specs[count++] = tmpl;
}
else if (!rsrc_write)
{
/* Reads from CR[IVR] affect other resources. */
if (regno == CR_IVR)
{
if ((dep->regindex >= CR_IRR0
&& dep->regindex <= CR_IRR3)
|| dep->regindex == CR_TPR)
{
specs[count++] = tmpl;
}
}
}
}
else
{
specs[count++] = tmpl;
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_INSERVICE:
/* look for write of EOI (67) or read of IVR (65) */
if ((idesc->operands[0] == IA64_OPND_CR3
&& CURR_SLOT.opnd[0].X_add_number - REG_CR == CR_EOI)
|| (idesc->operands[1] == IA64_OPND_CR3
&& CURR_SLOT.opnd[1].X_add_number - REG_CR == CR_IVR))
{
specs[count++] = tmpl;
}
break;
case IA64_RS_GR0:
if (note == 1)
{
specs[count++] = tmpl;
}
else
{
UNHANDLED;
}
break;
case IA64_RS_CFM:
if (note != 2)
{
specs[count++] = tmpl;
}
else
{
/* Check if any of the registers accessed are in the rotating region.
mov to/from pr accesses CFM only when qp_regno is in the rotating
region */
for (i=0;i < NELEMS(idesc->operands);i++)
{
if (idesc->operands[i] == IA64_OPND_R1
|| idesc->operands[i] == IA64_OPND_R2
|| idesc->operands[i] == IA64_OPND_R3)
{
int num = CURR_SLOT.opnd[i].X_add_number - REG_GR;
/* Assumes that md.rot.num_regs is always valid */
if (md.rot.num_regs > 0
&& num > 31
&& num < 31 + md.rot.num_regs)
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
else if (idesc->operands[i] == IA64_OPND_F1
|| idesc->operands[i] == IA64_OPND_F2
|| idesc->operands[i] == IA64_OPND_F3
|| idesc->operands[i] == IA64_OPND_F4)
{
int num = CURR_SLOT.opnd[i].X_add_number - REG_FR;
if (num > 31)
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
else if (idesc->operands[i] == IA64_OPND_P1
|| idesc->operands[i] == IA64_OPND_P2)
{
int num = CURR_SLOT.opnd[i].X_add_number - REG_P;
if (num > 15)
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
}
if (CURR_SLOT.qp_regno > 15)
{
specs[count] = tmpl;
specs[count++].specific = 0;
}
}
break;
case IA64_RS_PR63:
if (note == 0)
{
specs[count++] = tmpl;
}
else if (note == 11)
{
if ((idesc->operands[0] == IA64_OPND_P1
&& CURR_SLOT.opnd[0].X_add_number - REG_P == 63)
|| (idesc->operands[1] == IA64_OPND_P2
&& CURR_SLOT.opnd[1].X_add_number - REG_P == 63))
{
specs[count++] = tmpl;
}
}
else if (note == 12)
{
if (CURR_SLOT.qp_regno == 63)
{
specs[count++] = tmpl;
}
}
else if (note == 7)
{
valueT mask = 0;
if (idesc->operands[2] == IA64_OPND_IMM17)
mask = CURR_SLOT.opnd[2].X_add_number;
if (mask & ((valueT)1<<63))
{
specs[count++] = tmpl;
}
}
else if (note == 1)
{
if (rsrc_write)
{
for (i=0;i < idesc->num_outputs;i++)
if ((idesc->operands[i] == IA64_OPND_P1
|| idesc->operands[i] == IA64_OPND_P2)
&& CURR_SLOT.opnd[i].X_add_number - REG_P == 63)
{
specs[count++] = tmpl;
}
}
else
{
if (CURR_SLOT.qp_regno == 63)
{
specs[count++] = tmpl;
}
}
}
else
{
UNHANDLED;
}
break;
case IA64_RS_RSE:
/* FIXME we can identify some individual RSE written resources, but RSE
read resources have not yet been completely identified, so for now
treat RSE as a single resource */
if (strncmp (idesc->name, "mov", 3) == 0)
{
if (rsrc_write)
{
if (idesc->operands[0] == IA64_OPND_AR3
&& CURR_SLOT.opnd[0].X_add_number - REG_AR == AR_BSPSTORE)
{
specs[count] = tmpl;
specs[count++].index = 0; /* IA64_RSE_BSPLOAD/RNATBITINDEX */
}
}
else
{
if (idesc->operands[0] == IA64_OPND_AR3)
{
if (CURR_SLOT.opnd[0].X_add_number - REG_AR == AR_BSPSTORE
|| CURR_SLOT.opnd[0].X_add_number - REG_AR == AR_RNAT)
{
specs[count++] = tmpl;
}
}
else if (idesc->operands[1] == IA64_OPND_AR3)
{
if (CURR_SLOT.opnd[1].X_add_number - REG_AR == AR_BSP
|| CURR_SLOT.opnd[1].X_add_number - REG_AR == AR_BSPSTORE
|| CURR_SLOT.opnd[1].X_add_number - REG_AR == AR_RNAT)
{
specs[count++] = tmpl;
}
}
}
}
else
{
specs[count++] = tmpl;
}
break;
case IA64_RS_ANY:
/* FIXME -- do any of these need to be non-specific? */
specs[count++] = tmpl;
break;
default:
as_bad (_("Unrecognized dependency specifier %d\n"), dep->specifier);
break;
}
return count;
}
/* Clear branch flags on marked resources. This breaks the link between the
QP of the marking instruction and a subsequent branch on the same QP.
*/
static void
clear_qp_branch_flag (mask)
valueT mask;
{
int i;
for (i = 0;i < regdepslen;i++)
{
valueT bit = ((valueT)1 << regdeps[i].qp_regno);
if ((bit & mask) != 0)
{
regdeps[i].link_to_qp_branch = 0;
}
}
}
/* Remove any mutexes which contain any of the PRs indicated in the mask.
Any changes to a PR clears the mutex relations which include that PR.
*/
static void
clear_qp_mutex (mask)
valueT mask;
{
int i;
i = 0;
while (i < qp_mutexeslen)
{
if ((qp_mutexes[i].prmask & mask) != 0)
{
if (md.debug_dv)
{
fprintf (stderr, " Clearing mutex relation");
print_prmask (qp_mutexes[i].prmask);
fprintf (stderr, "\n");
}
qp_mutexes[i] = qp_mutexes[--qp_mutexeslen];
}
else
++i;
}
}
/* Clear implies relations which contain PRs in the given masks.
P1_MASK indicates the source of the implies relation, while P2_MASK
indicates the implied PR.
*/
static void
clear_qp_implies (p1_mask, p2_mask)
valueT p1_mask;
valueT p2_mask;
{
int i;
i = 0;
while (i < qp_implieslen)
{
if ((((valueT)1 << qp_implies[i].p1) & p1_mask) != 0
|| (((valueT)1 << qp_implies[i].p2) & p2_mask) != 0)
{
if (md.debug_dv)
fprintf (stderr, "Clearing implied relation PR%d->PR%d\n",
qp_implies[i].p1, qp_implies[i].p2);
qp_implies[i] = qp_implies[--qp_implieslen];
}
else
++i;
}
}
/* add the PRs specified to the list of implied relations */
static void
add_qp_imply (p1, p2)
int p1, p2;
{
valueT mask;
valueT bit;
int i;
/* p0 is not meaningful here */
if (p1 == 0 || p2 == 0)
abort ();
if (p1 == p2)
return;
/* if it exists already, ignore it */
for (i=0;i < qp_implieslen;i++)
{
if (qp_implies[i].p1 == p1
&& qp_implies[i].p2 == p2
&& qp_implies[i].path == md.path
&& !qp_implies[i].p2_branched)
return;
}
if (qp_implieslen == qp_impliestotlen)
{
qp_impliestotlen += 20;
qp_implies = (struct qp_imply *)
xrealloc ((void *)qp_implies,
qp_impliestotlen * sizeof (struct qp_imply));
}
if (md.debug_dv)
fprintf (stderr, " Registering PR%d implies PR%d\n", p1, p2);
qp_implies[qp_implieslen].p1 = p1;
qp_implies[qp_implieslen].p2 = p2;
qp_implies[qp_implieslen].path = md.path;
qp_implies[qp_implieslen++].p2_branched = 0;
/* Add in the implied transitive relations; for everything that p2 implies,
make p1 imply that, too; for everything that implies p1, make it imply p2
as well. */
for (i=0;i < qp_implieslen;i++)
{
if (qp_implies[i].p1 == p2)
add_qp_imply (p1, qp_implies[i].p2);
if (qp_implies[i].p2 == p1)
add_qp_imply (qp_implies[i].p1, p2);
}
/* Add in mutex relations implied by this implies relation; for each mutex
relation containing p2, duplicate it and replace p2 with p1. */
bit = (valueT)1 << p1;
mask = (valueT)1 << p2;
for (i=0;i < qp_mutexeslen;i++)
{
if (qp_mutexes[i].prmask & mask)
add_qp_mutex ((qp_mutexes[i].prmask & ~mask) | bit);
}
}
/* Add the PRs specified in the mask to the mutex list; this means that only
one of the PRs can be true at any time. PR0 should never be included in
the mask. */
static void
add_qp_mutex (mask)
valueT mask;
{
if (mask & 0x1)
abort ();
if (qp_mutexeslen == qp_mutexestotlen)
{
qp_mutexestotlen += 20;
qp_mutexes = (struct qpmutex *)
xrealloc ((void *)qp_mutexes,
qp_mutexestotlen * sizeof (struct qpmutex));
}
if (md.debug_dv)
{
fprintf (stderr, " Registering mutex on");
print_prmask (mask);
fprintf (stderr, "\n");
}
qp_mutexes[qp_mutexeslen].path = md.path;
qp_mutexes[qp_mutexeslen++].prmask = mask;
}
static void
clear_register_values ()
{
int i;
if (md.debug_dv)
fprintf (stderr, " Clearing register values\n");
for (i=1;i < NELEMS(gr_values);i++)
gr_values[i].known = 0;
}
/* Keep track of register values/changes which affect DV tracking.
optimization note: should add a flag to classes of insns where otherwise we
have to examine a group of strings to identify them.
*/
static void
note_register_values (idesc)
struct ia64_opcode *idesc;
{
valueT qp_changemask = 0;
int i;
/* invalidate values for registers being written to */
for (i=0;i < idesc->num_outputs;i++)
{
if (idesc->operands[i] == IA64_OPND_R1
|| idesc->operands[i] == IA64_OPND_R2
|| idesc->operands[i] == IA64_OPND_R3)
{
int regno = CURR_SLOT.opnd[i].X_add_number - REG_GR;
if (regno > 0 && regno < NELEMS(gr_values))
gr_values[regno].known = 0;
}
else if (idesc->operands[i] == IA64_OPND_P1
|| idesc->operands[i] == IA64_OPND_P2)
{
int regno = CURR_SLOT.opnd[i].X_add_number - REG_P;
qp_changemask |= (valueT)1 << regno;
}
else if (idesc->operands[i] == IA64_OPND_PR)
{
if (idesc->operands[2] & (valueT)0x10000)
qp_changemask = ~(valueT)0x1FFFF | idesc->operands[2];
else
qp_changemask = idesc->operands[2];
break;
}
else if (idesc->operands[i] == IA64_OPND_PR_ROT)
{
if (idesc->operands[1] & ((valueT)1 << 43))
qp_changemask = ~(valueT)0xFFFFFFFFFFF | idesc->operands[1];
else
qp_changemask = idesc->operands[1];
qp_changemask &= ~(valueT)0xFFFF;
break;
}
}
/* Always clear qp branch flags on any PR change */
/* FIXME there may be exceptions for certain compares */
clear_qp_branch_flag (qp_changemask);
/* invalidate rotating registers on insns which affect RRBs in CFM */
if (idesc->flags & IA64_OPCODE_MOD_RRBS)
{
qp_changemask |= ~(valueT)0xFFFF;
if (strcmp (idesc->name, "clrrrb.pr") != 0)
{
for (i=32;i < 32+md.rot.num_regs;i++)
gr_values[i].known = 0;
}
clear_qp_mutex (qp_changemask);
clear_qp_implies (qp_changemask, qp_changemask);
}
/* after a call, all register values are undefined, except those marked
as "safe" */
else if (strncmp (idesc->name, "br.call", 6) == 0
|| strncmp (idesc->name, "brl.call", 7) == 0)
{
// FIXME keep GR values which are marked as "safe_across_calls"
clear_register_values ();
clear_qp_mutex (~qp_safe_across_calls);
clear_qp_implies (~qp_safe_across_calls, ~qp_safe_across_calls);
clear_qp_branch_flag (~qp_safe_across_calls);
}
/* Look for mutex and implies relations */
else if ((idesc->operands[0] == IA64_OPND_P1
|| idesc->operands[0] == IA64_OPND_P2)
&& (idesc->operands[1] == IA64_OPND_P1
|| idesc->operands[1] == IA64_OPND_P2))
{
int p1 = CURR_SLOT.opnd[0].X_add_number - REG_P;
int p2 = CURR_SLOT.opnd[1].X_add_number - REG_P;
valueT p1mask = (valueT)1 << p1;
valueT p2mask = (valueT)1 << p2;
/* if one of the PRs is PR0, we can't really do anything */
if (p1 == 0 || p2 == 0)
{
if (md.debug_dv)
fprintf (stderr, " Ignoring PRs due to inclusion of p0\n");
}
/* In general, clear mutexes and implies which include P1 or P2,
with the following exceptions */
else if (strstr (idesc->name, ".or.andcm") != NULL)
{
add_qp_mutex (p1mask | p2mask);
clear_qp_implies (p2mask, p1mask);
}
else if (strstr (idesc->name, ".and.orcm") != NULL)
{
add_qp_mutex (p1mask | p2mask);
clear_qp_implies (p1mask, p2mask);
}
else if (strstr (idesc->name, ".and") != NULL)
{
clear_qp_implies (0, p1mask | p2mask);
}
else if (strstr (idesc->name, ".or") != NULL)
{
clear_qp_mutex (p1mask | p2mask);
clear_qp_implies (p1mask | p2mask, 0);
}
else
{
clear_qp_implies (p1mask | p2mask, p1mask | p2mask);
if (strstr (idesc->name, ".unc") != NULL)
{
add_qp_mutex (p1mask | p2mask);
if (CURR_SLOT.qp_regno != 0)
{
add_qp_imply (CURR_SLOT.opnd[0].X_add_number - REG_P,
CURR_SLOT.qp_regno);
add_qp_imply (CURR_SLOT.opnd[1].X_add_number - REG_P,
CURR_SLOT.qp_regno);
}
}
else if (CURR_SLOT.qp_regno == 0)
{
add_qp_mutex (p1mask | p2mask);
}
else
{
clear_qp_mutex (p1mask | p2mask);
}
}
}
/* Look for mov imm insns into GRs */
else if (idesc->operands[0] == IA64_OPND_R1
&& (idesc->operands[1] == IA64_OPND_IMM22
|| idesc->operands[1] == IA64_OPND_IMMU64)
&& (strcmp(idesc->name, "mov") == 0
|| strcmp(idesc->name, "movl") == 0))
{
int regno = CURR_SLOT.opnd[0].X_add_number - REG_GR;
if (regno > 0 && regno < NELEMS(gr_values))
{
gr_values[regno].known = 1;
gr_values[regno].value = CURR_SLOT.opnd[1].X_add_number;
gr_values[regno].path = md.path;
if (md.debug_dv)
fprintf (stderr, " Know gr%d = 0x%llx\n",
regno, gr_values[regno].value);
}
}
else
{
clear_qp_mutex (qp_changemask);
clear_qp_implies (qp_changemask, qp_changemask);
}
}
/* Return whether the given predicate registers are currently mutex */
static int
qp_mutex (p1, p2, path)
int p1;
int p2;
int path;
{
int i;
valueT mask;
if (p1 != p2)
{
mask = ((valueT)1<<p1) | (valueT)1<<p2;
for (i=0;i < qp_mutexeslen;i++)
{
if (qp_mutexes[i].path >= path
&& (qp_mutexes[i].prmask & mask) == mask)
return 1;
}
}
return 0;
}
/* Return whether the given resource is in the given insn's list of chks
Return 1 if the conflict is absolutely determined, 2 if it's a potential
conflict.
*/
static int
resources_match (rs, idesc, note, qp_regno, path)
struct rsrc *rs;
struct ia64_opcode *idesc;
int note;
int qp_regno;
int path;
{
struct rsrc specs[MAX_SPECS];
int count;
/* If the marked resource's qp_regno and the given qp_regno are mutex,
we don't need to check. One exception is note 11, which indicates that
target predicates are written regardless of PR[qp]. */
if (qp_mutex (rs->qp_regno, qp_regno, path)
&& note != 11)
return 0;
count = specify_resource (rs->dependency, idesc, DV_CHK, specs, note, path);
while (count-- > 0)
{
/* UNAT checking is a bit more specific than other resources */
if (rs->dependency->specifier == IA64_RS_AR_UNAT
&& specs[count].mem_offset.hint
&& rs->mem_offset.hint)
{
if (rs->mem_offset.base == specs[count].mem_offset.base)
{
if (((rs->mem_offset.offset >> 3) & 0x3F) ==
((specs[count].mem_offset.offset >> 3) & 0x3F))
return 1;
else
continue;
}
}
/* If either resource is not specific, conservatively assume a conflict
*/
if (!specs[count].specific || !rs->specific)
return 2;
else if (specs[count].index == rs->index)
return 1;
}
#if 0
if (md.debug_dv)
fprintf (stderr, " No %s conflicts\n", rs->dependency->name);
#endif
return 0;
}
/* Indicate an instruction group break; if INSERT_STOP is non-zero, then
insert a stop to create the break. Update all resource dependencies
appropriately. If QP_REGNO is non-zero, only apply the break to resources
which use the same QP_REGNO and have the link_to_qp_branch flag set.
If SAVE_CURRENT is non-zero, don't affect resources marked by the current
instruction.
*/
static void
insn_group_break (insert_stop, qp_regno, save_current)
int insert_stop;
int qp_regno;
int save_current;
{
int i;
if (insert_stop && md.num_slots_in_use > 0)
PREV_SLOT.end_of_insn_group = 1;
if (md.debug_dv)
{
fprintf (stderr, " Insn group break%s",
(insert_stop ? " (w/stop)" : ""));
if (qp_regno != 0)
fprintf (stderr, " effective for QP=%d", qp_regno);
fprintf (stderr, "\n");
}
i = 0;
while (i < regdepslen)
{
const struct ia64_dependency *dep = regdeps[i].dependency;
if (qp_regno != 0
&& regdeps[i].qp_regno != qp_regno)
{
++i;
continue;
}
if (save_current
&& CURR_SLOT.src_file == regdeps[i].file
&& CURR_SLOT.src_line == regdeps[i].line)
{
++i;
continue;
}
/* clear dependencies which are automatically cleared by a stop, or
those that have reached the appropriate state of insn serialization */
if (dep->semantics == IA64_DVS_IMPLIED
|| dep->semantics == IA64_DVS_IMPLIEDF
|| regdeps[i].insn_srlz == STATE_SRLZ)
{
print_dependency ("Removing", i);
regdeps[i] = regdeps[--regdepslen];
}
else
{
if (dep->semantics == IA64_DVS_DATA
|| dep->semantics == IA64_DVS_INSTR
|| dep->semantics == IA64_DVS_SPECIFIC)
{
if (regdeps[i].insn_srlz == STATE_NONE)
regdeps[i].insn_srlz = STATE_STOP;
if (regdeps[i].data_srlz == STATE_NONE)
regdeps[i].data_srlz = STATE_STOP;
}
++i;
}
}
}
/* Add the given resource usage spec to the list of active dependencies */
static void
mark_resource (idesc, dep, spec, depind, path)
struct ia64_opcode *idesc;
const struct ia64_dependency *dep;
struct rsrc *spec;
int depind;
int path;
{
if (regdepslen == regdepstotlen)
{
regdepstotlen += 20;
regdeps = (struct rsrc *)
xrealloc ((void *)regdeps,
regdepstotlen * sizeof(struct rsrc));
}
regdeps[regdepslen] = *spec;
regdeps[regdepslen].depind = depind;
regdeps[regdepslen].path = path;
regdeps[regdepslen].file = CURR_SLOT.src_file;
regdeps[regdepslen].line = CURR_SLOT.src_line;
print_dependency ("Adding", regdepslen);
++regdepslen;
}
static void
print_dependency (action, depind)
const char *action;
int depind;
{
if (md.debug_dv)
{
fprintf (stderr, " %s %s '%s'",
action, dv_mode[(regdeps[depind].dependency)->mode],
(regdeps[depind].dependency)->name);
if (regdeps[depind].specific && regdeps[depind].index != 0)
fprintf (stderr, " (%d)", regdeps[depind].index);
if (regdeps[depind].mem_offset.hint)
fprintf (stderr, " 0x%llx+0x%llx",
regdeps[depind].mem_offset.base,
regdeps[depind].mem_offset.offset);
fprintf (stderr, "\n");
}
}
static void
instruction_serialization ()
{
int i;
if (md.debug_dv)
fprintf (stderr, " Instruction serialization\n");
for (i=0;i < regdepslen;i++)
if (regdeps[i].insn_srlz == STATE_STOP)
regdeps[i].insn_srlz = STATE_SRLZ;
}
static void
data_serialization ()
{
int i = 0;
if (md.debug_dv)
fprintf (stderr, " Data serialization\n");
while (i < regdepslen)
{
if (regdeps[i].data_srlz == STATE_STOP
/* Note: as of 991210, all "other" dependencies are cleared by a
data serialization. This might change with new tables */
|| (regdeps[i].dependency)->semantics == IA64_DVS_OTHER)
{
print_dependency ("Removing", i);
regdeps[i] = regdeps[--regdepslen];
}
else
++i;
}
}
/* Insert stops and serializations as needed to avoid DVs */
static void
remove_marked_resource (rs)
struct rsrc *rs;
{
switch (rs->dependency->semantics)
{
case IA64_DVS_SPECIFIC:
if (md.debug_dv)
fprintf (stderr, "Implementation-specific, assume worst case...\n");
/* ...fall through... */
case IA64_DVS_INSTR:
if (md.debug_dv)
fprintf (stderr, "Inserting instr serialization\n");
if (rs->insn_srlz < STATE_STOP)
insn_group_break (1, 0, 0);
if (rs->insn_srlz < STATE_SRLZ)
{
int oldqp = CURR_SLOT.qp_regno;
struct ia64_opcode *oldidesc = CURR_SLOT.idesc;
/* Manually jam a srlz.i insn into the stream */
CURR_SLOT.qp_regno = 0;
CURR_SLOT.idesc = ia64_find_opcode ("srlz.i");
instruction_serialization ();
md.curr_slot = (md.curr_slot + 1) % NUM_SLOTS;
if (++md.num_slots_in_use >= NUM_SLOTS)
emit_one_bundle ();
CURR_SLOT.qp_regno = oldqp;
CURR_SLOT.idesc = oldidesc;
}
insn_group_break (1, 0, 0);
break;
case IA64_DVS_OTHER: /* as of rev2 (991220) of the DV tables, all
"other" types of DV are eliminated
by a data serialization */
case IA64_DVS_DATA:
if (md.debug_dv)
fprintf (stderr, "Inserting data serialization\n");
if (rs->data_srlz < STATE_STOP)
insn_group_break (1, 0, 0);
{
int oldqp = CURR_SLOT.qp_regno;
struct ia64_opcode *oldidesc = CURR_SLOT.idesc;
/* Manually jam a srlz.d insn into the stream */
CURR_SLOT.qp_regno = 0;
CURR_SLOT.idesc = ia64_find_opcode ("srlz.d");
data_serialization ();
md.curr_slot = (md.curr_slot + 1) % NUM_SLOTS;
if (++md.num_slots_in_use >= NUM_SLOTS)
emit_one_bundle ();
CURR_SLOT.qp_regno = oldqp;
CURR_SLOT.idesc = oldidesc;
}
break;
case IA64_DVS_IMPLIED:
case IA64_DVS_IMPLIEDF:
if (md.debug_dv)
fprintf (stderr, "Inserting stop\n");
insn_group_break (1, 0, 0);
break;
default:
break;
}
}
/* Check the resources used by the given opcode against the current dependency
list.
The check is run once for each execution path encountered. In this case,
a unique execution path is the sequence of instructions following a code
entry point, e.g. the following has three execution paths, one starting
at L0, one at L1, and one at L2.
L0: nop
L1: add
L2: add
br.ret
*/
static void
check_dependencies (idesc)
struct ia64_opcode *idesc;
{
const struct ia64_opcode_dependency *opdeps = idesc->dependencies;
int path;
int i;
/* Note that the number of marked resources may change within the
loop if in auto mode. */
i = 0;
while (i < regdepslen)
{
struct rsrc *rs = &regdeps[i];
const struct ia64_dependency *dep = rs->dependency;
int chkind;
int note;
int start_over = 0;
if (dep->semantics == IA64_DVS_NONE
|| (chkind = depends_on (rs->depind, idesc)) == -1)
{
++i; continue;
}
note = NOTE(opdeps->chks[chkind]);
/* Check this resource against each execution path seen thus far */
for (path=0;path <= md.path;path++)
{
int matchtype;
/* If the dependency wasn't on the path being checked, ignore it */
if (rs->path < path)
continue;
/* If the QP for this insn implies a QP which has branched, don't
bother checking. Ed. NOTE: I don't think this check is terribly
useful; what's the point of generating code which will only be
reached if its QP is zero?
This code was specifically inserted to handle the following code,
based on notes from Intel's DV checking code, where p1 implies p2.
mov r4 = 2
(p2) br.cond L
(p1) mov r4 = 7
*/
if (CURR_SLOT.qp_regno != 0)
{
int skip = 0;
int implies;
for (implies=0;implies < qp_implieslen;implies++)
{
if (qp_implies[implies].path >= path
&& qp_implies[implies].p1 == CURR_SLOT.qp_regno
&& qp_implies[implies].p2_branched)
{
skip = 1;
break;
}
}
if (skip)
continue;
}
if ((matchtype = resources_match (rs, idesc, note,
CURR_SLOT.qp_regno, path)) != 0)
{
char msg[1024];
char pathmsg[256] = "";
char indexmsg[256] = "";
int certain = (matchtype == 1 && CURR_SLOT.qp_regno == 0);
if (path != 0)
sprintf (pathmsg, " when entry is at label '%s'",
md.entry_labels[path-1]);
if (rs->specific && rs->index != 0)
sprintf (indexmsg, ", specific resource number is %d",
rs->index);
sprintf (msg, "Use of '%s' %s %s dependency '%s' (%s)%s%s",
idesc->name,
(certain ? "violates" : "may violate"),
dv_mode[dep->mode], dep->name,
dv_sem[dep->semantics],
pathmsg, indexmsg);
if (md.explicit_mode)
{
as_warn ("%s", msg);
if (path < md.path)
as_warn (_("Only the first path encountering the conflict "
"is reported"));
as_warn_where (rs->file, rs->line,
_("This is the location of the "
"conflicting usage"));
/* Don't bother checking other paths, to avoid duplicating
the same warning */
break;
}
else
{
if (md.debug_dv)
fprintf(stderr, "%s @ %s:%d\n", msg, rs->file, rs->line);
remove_marked_resource (rs);
/* since the set of dependencies has changed, start over */
/* FIXME -- since we're removing dvs as we go, we
probably don't really need to start over... */
start_over = 1;
break;
}
}
}
if (start_over)
i = 0;
else
++i;
}
}
/* register new dependencies based on the given opcode */
static void
mark_resources (idesc)
struct ia64_opcode *idesc;
{
int i;
const struct ia64_opcode_dependency *opdeps = idesc->dependencies;
int add_only_qp_reads = 0;
/* A conditional branch only uses its resources if it is taken; if it is
taken, we stop following that path. The other branch types effectively
*always* write their resources. If it's not taken, register only QP
reads. */
if (is_conditional_branch (idesc) || is_interruption_or_rfi (idesc))
{
add_only_qp_reads = 1;
}
if (md.debug_dv)
fprintf (stderr, "Registering '%s' resource usage\n", idesc->name);
for (i=0;i < opdeps->nregs;i++)
{
const struct ia64_dependency *dep;
struct rsrc specs[MAX_SPECS];
int note;
int path;
int count;
dep = ia64_find_dependency (opdeps->regs[i]);
note = NOTE(opdeps->regs[i]);
if (add_only_qp_reads
&& !(dep->mode == IA64_DV_WAR
&& (dep->specifier == IA64_RS_PR
|| dep->specifier == IA64_RS_PR63)))
continue;
count = specify_resource (dep, idesc, DV_REG, specs, note, md.path);
#if 0
if (md.debug_dv && !count)
fprintf (stderr, " No %s %s usage found (path %d)\n",
dv_mode[dep->mode], dep->name, md.path);
#endif
while (count-- > 0)
{
mark_resource (idesc, dep, &specs[count],
DEP(opdeps->regs[i]), md.path);
}
/* The execution path may affect register values, which may in turn
affect which indirect-access resources are accessed. */
switch (dep->specifier)
{
default:
break;
case IA64_RS_CPUID:
case IA64_RS_DBR:
case IA64_RS_IBR:
case IA64_RS_MSR:
case IA64_RS_PKR:
case IA64_RS_PMC:
case IA64_RS_PMD:
case IA64_RS_RR:
for (path=0;path < md.path;path++)
{
count = specify_resource (dep, idesc, DV_REG, specs, note, path);
while (count-- > 0)
mark_resource (idesc, dep, &specs[count],
DEP(opdeps->regs[i]), path);
}
break;
}
}
}
/* remove dependencies when they no longer apply */
static void
update_dependencies (idesc)
struct ia64_opcode *idesc;
{
int i;
if (strcmp (idesc->name, "srlz.i") == 0)
{
instruction_serialization ();
}
else if (strcmp (idesc->name, "srlz.d") == 0)
{
data_serialization ();
}
else if (is_interruption_or_rfi (idesc)
|| is_taken_branch (idesc))
{
/* although technically the taken branch doesn't clear dependencies
which require a srlz.[id], we don't follow the branch; the next
instruction is assumed to start with a clean slate */
regdepslen = 0;
clear_register_values ();
clear_qp_mutex (~(valueT)0);
clear_qp_implies (~(valueT)0, ~(valueT)0);
md.path = 0;
}
else if (is_conditional_branch (idesc)
&& CURR_SLOT.qp_regno != 0)
{
int is_call = strstr (idesc->name, ".call") != NULL;
for (i=0;i < qp_implieslen;i++)
{
/* if the conditional branch's predicate is implied by the predicate
in an existing dependency, remove that dependency */
if (qp_implies[i].p2 == CURR_SLOT.qp_regno)
{
int depind = 0;
/* note that this implied predicate takes a branch so that if
a later insn generates a DV but its predicate implies this
one, we can avoid the false DV warning */
qp_implies[i].p2_branched = 1;
while (depind < regdepslen)
{
if (regdeps[depind].qp_regno == qp_implies[i].p1)
{
print_dependency ("Removing", depind);
regdeps[depind] = regdeps[--regdepslen];
}
else
++depind;
}
}
}
/* Any marked resources which have this same predicate should be
cleared, provided that the QP hasn't been modified between the
marking instruction and the branch.
*/
if (is_call)
{
insn_group_break (0, CURR_SLOT.qp_regno, 1);
}
else
{
i = 0;
while (i < regdepslen)
{
if (regdeps[i].qp_regno == CURR_SLOT.qp_regno
&& regdeps[i].link_to_qp_branch
&& (regdeps[i].file != CURR_SLOT.src_file
|| regdeps[i].line != CURR_SLOT.src_line))
{
/* Treat like a taken branch */
print_dependency ("Removing", i);
regdeps[i] = regdeps[--regdepslen];
}
else
++i;
}
}
}
}
/* Examine the current instruction for dependency violations. */
static int
check_dv (idesc)
struct ia64_opcode *idesc;
{
if (md.debug_dv)
{
fprintf (stderr, "Checking %s for violations (line %d, %d/%d)\n",
idesc->name, CURR_SLOT.src_line,
idesc->dependencies->nchks,
idesc->dependencies->nregs);
}
/* Look through the list of currently marked resources; if the current
instruction has the dependency in its chks list which uses that resource,
check against the specific resources used.
*/
check_dependencies (idesc);
/*
Look up the instruction's regdeps (RAW writes, WAW writes, and WAR reads),
then add them to the list of marked resources.
*/
mark_resources (idesc);
/* There are several types of dependency semantics, and each has its own
requirements for being cleared
Instruction serialization (insns separated by interruption, rfi, or
writer + srlz.i + reader, all in separate groups) clears DVS_INSTR.
Data serialization (instruction serialization, or writer + srlz.d +
reader, where writer and srlz.d are in separate groups) clears
DVS_DATA. (This also clears DVS_OTHER, but that is not guaranteed to
always be the case).
Instruction group break (groups separated by stop, taken branch,
interruption or rfi) clears DVS_IMPLIED and DVS_IMPLIEDF.
*/
update_dependencies (idesc);
/* Sometimes, knowing a register value allows us to avoid giving a false DV
warning. Keep track of as many as possible that are useful. */
note_register_values (idesc);
/* We don't need or want this anymore. */
md.mem_offset.hint = 0;
return 0;
}
/* Translate one line of assembly. Pseudo ops and labels do not show
here. */
void
md_assemble (str)
char *str;
{
char *saved_input_line_pointer, *mnemonic;
const struct pseudo_opcode *pdesc;
struct ia64_opcode *idesc;
unsigned char qp_regno;
unsigned int flags;
int ch;
saved_input_line_pointer = input_line_pointer;
input_line_pointer = str;
/* extract the opcode (mnemonic): */
mnemonic = input_line_pointer;
ch = get_symbol_end ();
pdesc = (struct pseudo_opcode *) hash_find (md.pseudo_hash, mnemonic);
if (pdesc)
{
*input_line_pointer = ch;
(*pdesc->handler) (pdesc->arg);
goto done;
}
/* find the instruction descriptor matching the arguments: */
idesc = ia64_find_opcode (mnemonic);
*input_line_pointer = ch;
if (!idesc)
{
as_bad ("Unknown opcode `%s'", mnemonic);
goto done;
}
idesc = parse_operands (idesc);
if (!idesc)
goto done;
/* Handle the dynamic ops we can handle now: */
if (idesc->type == IA64_TYPE_DYN)
{
if (strcmp (idesc->name, "add") == 0)
{
if (CURR_SLOT.opnd[2].X_op == O_register
&& CURR_SLOT.opnd[2].X_add_number < 4)
mnemonic = "addl";
else
mnemonic = "adds";
idesc = ia64_find_opcode (mnemonic);
#if 0
know (!idesc->next);
#endif
}
else if (strcmp (idesc->name, "mov") == 0)
{
enum ia64_opnd opnd1, opnd2;
int rop;
opnd1 = idesc->operands[0];
opnd2 = idesc->operands[1];
if (opnd1 == IA64_OPND_AR3)
rop = 0;
else if (opnd2 == IA64_OPND_AR3)
rop = 1;
else
abort ();
if (CURR_SLOT.opnd[rop].X_op == O_register
&& ar_is_in_integer_unit (CURR_SLOT.opnd[rop].X_add_number))
mnemonic = "mov.i";
else
mnemonic = "mov.m";
idesc = ia64_find_opcode (mnemonic);
while (idesc != NULL
&& (idesc->operands[0] != opnd1
|| idesc->operands[1] != opnd2))
idesc = get_next_opcode (idesc);
}
}
qp_regno = 0;
if (md.qp.X_op == O_register)
qp_regno = md.qp.X_add_number - REG_P;
flags = idesc->flags;
if ((flags & IA64_OPCODE_FIRST) != 0)
insn_group_break (1, 0, 0);
if ((flags & IA64_OPCODE_NO_PRED) != 0 && qp_regno != 0)
{
as_bad ("`%s' cannot be predicated", idesc->name);
goto done;
}
/* build the instruction: */
CURR_SLOT.qp_regno = qp_regno;
CURR_SLOT.idesc = idesc;
as_where (&CURR_SLOT.src_file, &CURR_SLOT.src_line);
if (debug_type == DEBUG_DWARF2)
dwarf2_where (&CURR_SLOT.debug_line);
/* Add unwind entry, if there is one. */
if (unwind.current_entry)
{
CURR_SLOT.unwind_record = unwind.current_entry;
unwind.current_entry = NULL;
}
/* check for dependency violations */
if (md.detect_dv)
check_dv(idesc);
md.curr_slot = (md.curr_slot + 1) % NUM_SLOTS;
if (++md.num_slots_in_use >= NUM_SLOTS)
emit_one_bundle ();
if ((flags & IA64_OPCODE_LAST) != 0)
insn_group_break (1, 0, 0);
md.last_text_seg = now_seg;
done:
input_line_pointer = saved_input_line_pointer;
}
/* Called when symbol NAME cannot be found in the symbol table.
Should be used for dynamic valued symbols only. */
symbolS*
md_undefined_symbol (name)
char *name;
{
return 0;
}
/* Called for any expression that can not be recognized. When the
function is called, `input_line_pointer' will point to the start of
the expression. */
void
md_operand (e)
expressionS *e;
{
enum pseudo_type pseudo_type;
const char *name;
size_t len;
int ch, i;
switch (*input_line_pointer)
{
case '@':
/* find what relocation pseudo-function we're dealing with: */
pseudo_type = 0;
ch = *++input_line_pointer;
for (i = 0; i < NELEMS (pseudo_func); ++i)
if (pseudo_func[i].name && pseudo_func[i].name[0] == ch)
{
len = strlen (pseudo_func[i].name);
if (strncmp (pseudo_func[i].name + 1,
input_line_pointer + 1, len - 1) == 0
&& !is_part_of_name (input_line_pointer[len]))
{
input_line_pointer += len;
pseudo_type = pseudo_func[i].type;
break;
}
}
switch (pseudo_type)
{
case PSEUDO_FUNC_RELOC:
SKIP_WHITESPACE ();
if (*input_line_pointer != '(')
{
as_bad ("Expected '('");
goto err;
}
++input_line_pointer; /* skip '(' */
expression (e);
if (*input_line_pointer++ != ')')
{
as_bad ("Missing ')'");
goto err;
}
if (e->X_op != O_symbol)
{
if (e->X_op != O_pseudo_fixup)
{
as_bad ("Not a symbolic expression");
goto err;
}
if (S_GET_VALUE (e->X_op_symbol) == FUNC_FPTR_RELATIVE
&& i == FUNC_LT_RELATIVE)
i = FUNC_LT_FPTR_RELATIVE;
else
{
as_bad ("Illegal combination of relocation functions");
goto err;
}
}
/* make sure gas doesn't get rid of local symbols that are used
in relocs: */
e->X_op = O_pseudo_fixup;
e->X_op_symbol = pseudo_func[i].u.sym;
break;
case PSEUDO_FUNC_CONST:
e->X_op = O_constant;
e->X_add_number = pseudo_func[i].u.ival;
break;
case PSEUDO_FUNC_REG:
e->X_op = O_register;
e->X_add_number = pseudo_func[i].u.ival;
break;
default:
name = input_line_pointer - 1;
get_symbol_end ();
as_bad ("Unknown pseudo function `%s'", name);
goto err;
}
break;
case '[':
++input_line_pointer;
expression (e);
if (*input_line_pointer != ']')
{
as_bad ("Closing bracket misssing");
goto err;
}
else
{
if (e->X_op != O_register)
as_bad ("Register expected as index");
++input_line_pointer;
e->X_op = O_index;
}
break;
default:
break;
}
return;
err:
ignore_rest_of_line ();
}
/* Return 1 if it's OK to adjust a reloc by replacing the symbol with
a section symbol plus some offset. For relocs involving @fptr(),
directives we don't want such adjustments since we need to have the
original symbol's name in the reloc. */
int
ia64_fix_adjustable (fix)
fixS *fix;
{
/* Prevent all adjustments to global symbols */
if (S_IS_EXTERN (fix->fx_addsy) || S_IS_WEAK (fix->fx_addsy))
return 0;
switch (fix->fx_r_type)
{
case BFD_RELOC_IA64_FPTR64I:
case BFD_RELOC_IA64_FPTR32MSB:
case BFD_RELOC_IA64_FPTR32LSB:
case BFD_RELOC_IA64_FPTR64MSB:
case BFD_RELOC_IA64_FPTR64LSB:
case BFD_RELOC_IA64_LTOFF_FPTR22:
case BFD_RELOC_IA64_LTOFF_FPTR64I:
return 0;
default:
break;
}
return 1;
}
int
ia64_force_relocation (fix)
fixS *fix;
{
switch (fix->fx_r_type)
{
case BFD_RELOC_IA64_FPTR64I:
case BFD_RELOC_IA64_FPTR32MSB:
case BFD_RELOC_IA64_FPTR32LSB:
case BFD_RELOC_IA64_FPTR64MSB:
case BFD_RELOC_IA64_FPTR64LSB:
case BFD_RELOC_IA64_LTOFF22:
case BFD_RELOC_IA64_LTOFF64I:
case BFD_RELOC_IA64_LTOFF_FPTR22:
case BFD_RELOC_IA64_LTOFF_FPTR64I:
case BFD_RELOC_IA64_PLTOFF22:
case BFD_RELOC_IA64_PLTOFF64I:
case BFD_RELOC_IA64_PLTOFF64MSB:
case BFD_RELOC_IA64_PLTOFF64LSB:
return 1;
default:
return 0;
}
return 0;
}
/* Decide from what point a pc-relative relocation is relative to,
relative to the pc-relative fixup. Er, relatively speaking. */
long
ia64_pcrel_from_section (fix, sec)
fixS *fix;
segT sec;
{
unsigned long off = fix->fx_frag->fr_address + fix->fx_where;
if (bfd_get_section_flags (stdoutput, sec) & SEC_CODE)
off &= ~0xfUL;
return off;
}
/* This is called whenever some data item (not an instruction) needs a
fixup. We pick the right reloc code depending on the byteorder
currently in effect. */
void
ia64_cons_fix_new (f, where, nbytes, exp)
fragS *f;
int where;
int nbytes;
expressionS *exp;
{
bfd_reloc_code_real_type code;
fixS *fix;
switch (nbytes)
{
/* There are no reloc for 8 and 16 bit quantities, but we allow
them here since they will work fine as long as the expression
is fully defined at the end of the pass over the source file. */
case 1: code = BFD_RELOC_8; break;
case 2: code = BFD_RELOC_16; break;
case 4:
if (target_big_endian)
code = BFD_RELOC_IA64_DIR32MSB;
else
code = BFD_RELOC_IA64_DIR32LSB;
break;
case 8:
if (target_big_endian)
code = BFD_RELOC_IA64_DIR64MSB;
else
code = BFD_RELOC_IA64_DIR64LSB;
break;
default:
as_bad ("Unsupported fixup size %d", nbytes);
ignore_rest_of_line ();
return;
}
if (exp->X_op == O_pseudo_fixup)
{
/* ??? */
exp->X_op = O_symbol;
code = ia64_gen_real_reloc_type (exp->X_op_symbol, code);
}
fix = fix_new_exp (f, where, nbytes, exp, 0, code);
/* We need to store the byte order in effect in case we're going
to fix an 8 or 16 bit relocation (for which there no real
relocs available). See md_apply_fix(). */
fix->tc_fix_data.bigendian = target_big_endian;
}
/* Return the actual relocation we wish to associate with the pseudo
reloc described by SYM and R_TYPE. SYM should be one of the
symbols in the pseudo_func array, or NULL. */
static bfd_reloc_code_real_type
ia64_gen_real_reloc_type (sym, r_type)
struct symbol *sym;
bfd_reloc_code_real_type r_type;
{
bfd_reloc_code_real_type new = 0;
if (sym == NULL)
{
return r_type;
}
switch (S_GET_VALUE (sym))
{
case FUNC_FPTR_RELATIVE:
switch (r_type)
{
case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_FPTR64I; break;
case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_FPTR32MSB; break;
case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_FPTR32LSB; break;
case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_FPTR64MSB; break;
case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_FPTR64LSB; break;
default: break;
}
break;
case FUNC_GP_RELATIVE:
switch (r_type)
{
case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_GPREL22; break;
case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_GPREL64I; break;
case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_GPREL32MSB; break;
case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_GPREL32LSB; break;
case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_GPREL64MSB; break;
case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_GPREL64LSB; break;
default: break;
}
break;
case FUNC_LT_RELATIVE:
switch (r_type)
{
case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_LTOFF22; break;
case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_LTOFF64I; break;
default: break;
}
break;
case FUNC_PC_RELATIVE:
switch (r_type)
{
case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_PCREL22; break;
case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_PCREL64I; break;
case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_PCREL32MSB; break;
case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_PCREL32LSB; break;
case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_PCREL64MSB; break;
case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_PCREL64LSB; break;
default: break;
}
break;
case FUNC_PLT_RELATIVE:
switch (r_type)
{
case BFD_RELOC_IA64_IMM22: new = BFD_RELOC_IA64_PLTOFF22; break;
case BFD_RELOC_IA64_IMM64: new = BFD_RELOC_IA64_PLTOFF64I; break;
case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_PLTOFF64MSB;break;
case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_PLTOFF64LSB;break;
default: break;
}
break;
case FUNC_SEC_RELATIVE:
switch (r_type)
{
case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_SECREL32MSB;break;
case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_SECREL32LSB;break;
case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_SECREL64MSB;break;
case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_SECREL64LSB;break;
default: break;
}
break;
case FUNC_SEG_RELATIVE:
switch (r_type)
{
case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_SEGREL32MSB;break;
case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_SEGREL32LSB;break;
case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_SEGREL64MSB;break;
case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_SEGREL64LSB;break;
default: break;
}
break;
case FUNC_LTV_RELATIVE:
switch (r_type)
{
case BFD_RELOC_IA64_DIR32MSB: new = BFD_RELOC_IA64_LTV32MSB; break;
case BFD_RELOC_IA64_DIR32LSB: new = BFD_RELOC_IA64_LTV32LSB; break;
case BFD_RELOC_IA64_DIR64MSB: new = BFD_RELOC_IA64_LTV64MSB; break;
case BFD_RELOC_IA64_DIR64LSB: new = BFD_RELOC_IA64_LTV64LSB; break;
default: break;
}
break;
case FUNC_LT_FPTR_RELATIVE:
switch (r_type)
{
case BFD_RELOC_IA64_IMM22:
new = BFD_RELOC_IA64_LTOFF_FPTR22; break;
case BFD_RELOC_IA64_IMM64:
new = BFD_RELOC_IA64_LTOFF_FPTR64I; break;
default:
break;
}
break;
default:
abort ();
}
/* Hmmmm. Should this ever occur? */
if (new)
return new;
else
return r_type;
}
/* Here is where generate the appropriate reloc for pseudo relocation
functions. */
void
ia64_validate_fix (fix)
fixS *fix;
{
switch (fix->fx_r_type)
{
case BFD_RELOC_IA64_FPTR64I:
case BFD_RELOC_IA64_FPTR32MSB:
case BFD_RELOC_IA64_FPTR64LSB:
case BFD_RELOC_IA64_LTOFF_FPTR22:
case BFD_RELOC_IA64_LTOFF_FPTR64I:
if (fix->fx_offset != 0)
as_bad_where (fix->fx_file, fix->fx_line,
"No addend allowed in @fptr() relocation");
break;
default:
break;
}
return;
}
static void
fix_insn (fix, odesc, value)
fixS *fix;
const struct ia64_operand *odesc;
valueT value;
{
bfd_vma insn[3], t0, t1, control_bits;
const char *err;
char *fixpos;
long slot;
slot = fix->fx_where & 0x3;
fixpos = fix->fx_frag->fr_literal + (fix->fx_where - slot);
/* Bundles are always in little-endian byte order */
t0 = bfd_getl64 (fixpos);
t1 = bfd_getl64 (fixpos + 8);
control_bits = t0 & 0x1f;
insn[0] = (t0 >> 5) & 0x1ffffffffffLL;
insn[1] = ((t0 >> 46) & 0x3ffff) | ((t1 & 0x7fffff) << 18);
insn[2] = (t1 >> 23) & 0x1ffffffffffLL;
err = NULL;
if (odesc - elf64_ia64_operands == IA64_OPND_IMMU64)
{
insn[1] = (value >> 22) & 0x1ffffffffffLL;
insn[2] |= (((value & 0x7f) << 13)
| (((value >> 7) & 0x1ff) << 27)
| (((value >> 16) & 0x1f) << 22)
| (((value >> 21) & 0x1) << 21)
| (((value >> 63) & 0x1) << 36));
}
else if (odesc - elf64_ia64_operands == IA64_OPND_IMMU62)
{
if (value & ~0x3fffffffffffffffULL)
err = "integer operand out of range";
insn[1] = (value >> 21) & 0x1ffffffffffLL;
insn[2] |= (((value & 0xfffff) << 6) | (((value >> 20) & 0x1) << 36));
}
else if (odesc - elf64_ia64_operands == IA64_OPND_TGT64)
{
value >>= 4;
insn[1] = ((value >> 20) & 0x7fffffffffLL) << 2;
insn[2] |= ((((value >> 59) & 0x1) << 36)
| (((value >> 0) & 0xfffff) << 13));
}
else
err = (*odesc->insert) (odesc, value, insn + slot);
if (err)
as_bad_where (fix->fx_file, fix->fx_line, err);
t0 = control_bits | (insn[0] << 5) | (insn[1] << 46);
t1 = ((insn[1] >> 18) & 0x7fffff) | (insn[2] << 23);
md_number_to_chars (fixpos + 0, t0, 8);
md_number_to_chars (fixpos + 8, t1, 8);
}
/* Attempt to simplify or even eliminate a fixup. The return value is
ignored; perhaps it was once meaningful, but now it is historical.
To indicate that a fixup has been eliminated, set FIXP->FX_DONE.
If fixp->fx_addsy is non-NULL, we'll have to generate a reloc entry
(if possible). */
int
md_apply_fix3 (fix, valuep, seg)
fixS *fix;
valueT *valuep;
segT seg;
{
char *fixpos;
valueT value = *valuep;
int adjust = 0;
fixpos = fix->fx_frag->fr_literal + fix->fx_where;
if (fix->fx_pcrel)
{
switch (fix->fx_r_type)
{
case BFD_RELOC_IA64_DIR32MSB:
fix->fx_r_type = BFD_RELOC_IA64_PCREL32MSB;
adjust = 1;
break;
case BFD_RELOC_IA64_DIR32LSB:
fix->fx_r_type = BFD_RELOC_IA64_PCREL32LSB;
adjust = 1;
break;
case BFD_RELOC_IA64_DIR64MSB:
fix->fx_r_type = BFD_RELOC_IA64_PCREL64MSB;
adjust = 1;
break;
case BFD_RELOC_IA64_DIR64LSB:
fix->fx_r_type = BFD_RELOC_IA64_PCREL64LSB;
adjust = 1;
break;
default:
break;
}
}
if (fix->fx_addsy)
{
switch (fix->fx_r_type)
{
case 0:
as_bad_where (fix->fx_file, fix->fx_line,
"%s must have a constant value",
elf64_ia64_operands[fix->tc_fix_data.opnd].desc);
break;
default:
break;
}
/* ??? This is a hack copied from tc-i386.c to make PCREL relocs
work. There should be a better way to handle this. */
if (adjust)
fix->fx_offset += fix->fx_where + fix->fx_frag->fr_address;
}
else if (fix->tc_fix_data.opnd == IA64_OPND_NIL)
{
if (fix->tc_fix_data.bigendian)
number_to_chars_bigendian (fixpos, value, fix->fx_size);
else
number_to_chars_littleendian (fixpos, value, fix->fx_size);
fix->fx_done = 1;
return 1;
}
else
{
fix_insn (fix, elf64_ia64_operands + fix->tc_fix_data.opnd, value);
fix->fx_done = 1;
return 1;
}
return 1;
}
/* Generate the BFD reloc to be stuck in the object file from the
fixup used internally in the assembler. */
arelent*
tc_gen_reloc (sec, fixp)
asection *sec;
fixS *fixp;
{
arelent *reloc;
reloc = xmalloc (sizeof (*reloc));
reloc->sym_ptr_ptr = (asymbol **) xmalloc (sizeof (asymbol *));
*reloc->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy);
reloc->address = fixp->fx_frag->fr_address + fixp->fx_where;
reloc->addend = fixp->fx_offset;
reloc->howto = bfd_reloc_type_lookup (stdoutput, fixp->fx_r_type);
if (!reloc->howto)
{
as_bad_where (fixp->fx_file, fixp->fx_line,
"Cannot represent %s relocation in object file",
bfd_get_reloc_code_name (fixp->fx_r_type));
}
return reloc;
}
/* Turn a string in input_line_pointer into a floating point constant
of type type, and store the appropriate bytes in *lit. The number
of LITTLENUMS emitted is stored in *size. An error message is
returned, or NULL on OK. */
#define MAX_LITTLENUMS 5
char*
md_atof (type, lit, size)
int type;
char *lit;
int *size;
{
LITTLENUM_TYPE words[MAX_LITTLENUMS];
LITTLENUM_TYPE *word;
char *t;
int prec;
switch (type)
{
/* IEEE floats */
case 'f':
case 'F':
case 's':
case 'S':
prec = 2;
break;
case 'd':
case 'D':
case 'r':
case 'R':
prec = 4;
break;
case 'x':
case 'X':
case 'p':
case 'P':
prec = 5;
break;
default:
*size = 0;
return "Bad call to MD_ATOF()";
}
t = atof_ieee (input_line_pointer, type, words);
if (t)
input_line_pointer = t;
*size = prec * sizeof (LITTLENUM_TYPE);
for (word = words + prec - 1; prec--;)
{
md_number_to_chars (lit, (long) (*word--), sizeof (LITTLENUM_TYPE));
lit += sizeof (LITTLENUM_TYPE);
}
return 0;
}
/* Round up a section's size to the appropriate boundary. */
valueT
md_section_align (seg, size)
segT seg;
valueT size;
{
int align = bfd_get_section_alignment (stdoutput, seg);
valueT mask = ((valueT)1 << align) - 1;
return (size + mask) & ~mask;
}
/* Handle ia64 specific semantics of the align directive. */
int
ia64_md_do_align (n, fill, len, max)
int n;
const char *fill;
int len;
int max;
{
/* Fill any pending bundle with nops. */
if (bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE)
ia64_flush_insns ();
/* When we align code in a text section, emit a bundle of 3 nops instead of
zero bytes. We can only do this if a multiple of 16 bytes was requested.
N is log base 2 of the requested alignment. */
if (fill == NULL
&& bfd_get_section_flags (stdoutput, now_seg) & SEC_CODE
&& n > 4)
{
/* Use mfi bundle of nops with no stop bits. */
static const unsigned char be_nop[]
= { 0x00, 0x04, 0x00, 0x00, 0x00, 0x00, 0x02, 0x00,
0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x0c};
static const unsigned char le_nop[]
= { 0x0c, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00,
0x00, 0x02, 0x00, 0x00, 0x00, 0x00, 0x04, 0x00};
/* Make sure we are on a 16-byte boundary, in case someone has been
putting data into a text section. */
frag_align (4, 0, 0);
if (target_big_endian)
frag_align_pattern (n, be_nop, 16, max);
else
frag_align_pattern (n, le_nop, 16, max);
return 1;
}
return 0;
}
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