/* aarch64-opc.c -- AArch64 opcode support.
Copyright (C) 2009-2020 Free Software Foundation, Inc.
Contributed by ARM Ltd.
This file is part of the GNU opcodes library.
This library is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3, or (at your option)
any later version.
It 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 this program; see the file COPYING3. If not,
see . */
#include "sysdep.h"
#include
#include
#include
#include "bfd_stdint.h"
#include
#include
#include "opintl.h"
#include "libiberty.h"
#include "aarch64-opc.h"
#ifdef DEBUG_AARCH64
int debug_dump = FALSE;
#endif /* DEBUG_AARCH64 */
/* The enumeration strings associated with each value of a 5-bit SVE
pattern operand. A null entry indicates a reserved meaning. */
const char *const aarch64_sve_pattern_array[32] = {
/* 0-7. */
"pow2",
"vl1",
"vl2",
"vl3",
"vl4",
"vl5",
"vl6",
"vl7",
/* 8-15. */
"vl8",
"vl16",
"vl32",
"vl64",
"vl128",
"vl256",
0,
0,
/* 16-23. */
0,
0,
0,
0,
0,
0,
0,
0,
/* 24-31. */
0,
0,
0,
0,
0,
"mul4",
"mul3",
"all"
};
/* The enumeration strings associated with each value of a 4-bit SVE
prefetch operand. A null entry indicates a reserved meaning. */
const char *const aarch64_sve_prfop_array[16] = {
/* 0-7. */
"pldl1keep",
"pldl1strm",
"pldl2keep",
"pldl2strm",
"pldl3keep",
"pldl3strm",
0,
0,
/* 8-15. */
"pstl1keep",
"pstl1strm",
"pstl2keep",
"pstl2strm",
"pstl3keep",
"pstl3strm",
0,
0
};
/* Helper functions to determine which operand to be used to encode/decode
the size:Q fields for AdvSIMD instructions. */
static inline bfd_boolean
vector_qualifier_p (enum aarch64_opnd_qualifier qualifier)
{
return ((qualifier >= AARCH64_OPND_QLF_V_8B
&& qualifier <= AARCH64_OPND_QLF_V_1Q) ? TRUE
: FALSE);
}
static inline bfd_boolean
fp_qualifier_p (enum aarch64_opnd_qualifier qualifier)
{
return ((qualifier >= AARCH64_OPND_QLF_S_B
&& qualifier <= AARCH64_OPND_QLF_S_Q) ? TRUE
: FALSE);
}
enum data_pattern
{
DP_UNKNOWN,
DP_VECTOR_3SAME,
DP_VECTOR_LONG,
DP_VECTOR_WIDE,
DP_VECTOR_ACROSS_LANES,
};
static const char significant_operand_index [] =
{
0, /* DP_UNKNOWN, by default using operand 0. */
0, /* DP_VECTOR_3SAME */
1, /* DP_VECTOR_LONG */
2, /* DP_VECTOR_WIDE */
1, /* DP_VECTOR_ACROSS_LANES */
};
/* Given a sequence of qualifiers in QUALIFIERS, determine and return
the data pattern.
N.B. QUALIFIERS is a possible sequence of qualifiers each of which
corresponds to one of a sequence of operands. */
static enum data_pattern
get_data_pattern (const aarch64_opnd_qualifier_seq_t qualifiers)
{
if (vector_qualifier_p (qualifiers[0]) == TRUE)
{
/* e.g. v.4s, v.4s, v.4s
or v.4h, v.4h, v.h[3]. */
if (qualifiers[0] == qualifiers[1]
&& vector_qualifier_p (qualifiers[2]) == TRUE
&& (aarch64_get_qualifier_esize (qualifiers[0])
== aarch64_get_qualifier_esize (qualifiers[1]))
&& (aarch64_get_qualifier_esize (qualifiers[0])
== aarch64_get_qualifier_esize (qualifiers[2])))
return DP_VECTOR_3SAME;
/* e.g. v.8h, v.8b, v.8b.
or v.4s, v.4h, v.h[2].
or v.8h, v.16b. */
if (vector_qualifier_p (qualifiers[1]) == TRUE
&& aarch64_get_qualifier_esize (qualifiers[0]) != 0
&& (aarch64_get_qualifier_esize (qualifiers[0])
== aarch64_get_qualifier_esize (qualifiers[1]) << 1))
return DP_VECTOR_LONG;
/* e.g. v.8h, v.8h, v.8b. */
if (qualifiers[0] == qualifiers[1]
&& vector_qualifier_p (qualifiers[2]) == TRUE
&& aarch64_get_qualifier_esize (qualifiers[0]) != 0
&& (aarch64_get_qualifier_esize (qualifiers[0])
== aarch64_get_qualifier_esize (qualifiers[2]) << 1)
&& (aarch64_get_qualifier_esize (qualifiers[0])
== aarch64_get_qualifier_esize (qualifiers[1])))
return DP_VECTOR_WIDE;
}
else if (fp_qualifier_p (qualifiers[0]) == TRUE)
{
/* e.g. SADDLV , .. */
if (vector_qualifier_p (qualifiers[1]) == TRUE
&& qualifiers[2] == AARCH64_OPND_QLF_NIL)
return DP_VECTOR_ACROSS_LANES;
}
return DP_UNKNOWN;
}
/* Select the operand to do the encoding/decoding of the 'size:Q' fields in
the AdvSIMD instructions. */
/* N.B. it is possible to do some optimization that doesn't call
get_data_pattern each time when we need to select an operand. We can
either buffer the caculated the result or statically generate the data,
however, it is not obvious that the optimization will bring significant
benefit. */
int
aarch64_select_operand_for_sizeq_field_coding (const aarch64_opcode *opcode)
{
return
significant_operand_index [get_data_pattern (opcode->qualifiers_list[0])];
}
const aarch64_field fields[] =
{
{ 0, 0 }, /* NIL. */
{ 0, 4 }, /* cond2: condition in truly conditional-executed inst. */
{ 0, 4 }, /* nzcv: flag bit specifier, encoded in the "nzcv" field. */
{ 5, 5 }, /* defgh: d:e:f:g:h bits in AdvSIMD modified immediate. */
{ 16, 3 }, /* abc: a:b:c bits in AdvSIMD modified immediate. */
{ 5, 19 }, /* imm19: e.g. in CBZ. */
{ 5, 19 }, /* immhi: e.g. in ADRP. */
{ 29, 2 }, /* immlo: e.g. in ADRP. */
{ 22, 2 }, /* size: in most AdvSIMD and floating-point instructions. */
{ 10, 2 }, /* vldst_size: size field in the AdvSIMD load/store inst. */
{ 29, 1 }, /* op: in AdvSIMD modified immediate instructions. */
{ 30, 1 }, /* Q: in most AdvSIMD instructions. */
{ 0, 5 }, /* Rt: in load/store instructions. */
{ 0, 5 }, /* Rd: in many integer instructions. */
{ 5, 5 }, /* Rn: in many integer instructions. */
{ 10, 5 }, /* Rt2: in load/store pair instructions. */
{ 10, 5 }, /* Ra: in fp instructions. */
{ 5, 3 }, /* op2: in the system instructions. */
{ 8, 4 }, /* CRm: in the system instructions. */
{ 12, 4 }, /* CRn: in the system instructions. */
{ 16, 3 }, /* op1: in the system instructions. */
{ 19, 2 }, /* op0: in the system instructions. */
{ 10, 3 }, /* imm3: in add/sub extended reg instructions. */
{ 12, 4 }, /* cond: condition flags as a source operand. */
{ 12, 4 }, /* opcode: in advsimd load/store instructions. */
{ 12, 4 }, /* cmode: in advsimd modified immediate instructions. */
{ 13, 3 }, /* asisdlso_opcode: opcode in advsimd ld/st single element. */
{ 13, 2 }, /* len: in advsimd tbl/tbx instructions. */
{ 16, 5 }, /* Rm: in ld/st reg offset and some integer inst. */
{ 16, 5 }, /* Rs: in load/store exclusive instructions. */
{ 13, 3 }, /* option: in ld/st reg offset + add/sub extended reg inst. */
{ 12, 1 }, /* S: in load/store reg offset instructions. */
{ 21, 2 }, /* hw: in move wide constant instructions. */
{ 22, 2 }, /* opc: in load/store reg offset instructions. */
{ 23, 1 }, /* opc1: in load/store reg offset instructions. */
{ 22, 2 }, /* shift: in add/sub reg/imm shifted instructions. */
{ 22, 2 }, /* type: floating point type field in fp data inst. */
{ 30, 2 }, /* ldst_size: size field in ld/st reg offset inst. */
{ 10, 6 }, /* imm6: in add/sub reg shifted instructions. */
{ 15, 6 }, /* imm6_2: in rmif instructions. */
{ 11, 4 }, /* imm4: in advsimd ext and advsimd ins instructions. */
{ 0, 4 }, /* imm4_2: in rmif instructions. */
{ 10, 4 }, /* imm4_3: in adddg/subg instructions. */
{ 16, 5 }, /* imm5: in conditional compare (immediate) instructions. */
{ 15, 7 }, /* imm7: in load/store pair pre/post index instructions. */
{ 13, 8 }, /* imm8: in floating-point scalar move immediate inst. */
{ 12, 9 }, /* imm9: in load/store pre/post index instructions. */
{ 10, 12 }, /* imm12: in ld/st unsigned imm or add/sub shifted inst. */
{ 5, 14 }, /* imm14: in test bit and branch instructions. */
{ 5, 16 }, /* imm16: in exception instructions. */
{ 0, 16 }, /* imm16_2: in udf instruction. */
{ 0, 26 }, /* imm26: in unconditional branch instructions. */
{ 10, 6 }, /* imms: in bitfield and logical immediate instructions. */
{ 16, 6 }, /* immr: in bitfield and logical immediate instructions. */
{ 16, 3 }, /* immb: in advsimd shift by immediate instructions. */
{ 19, 4 }, /* immh: in advsimd shift by immediate instructions. */
{ 22, 1 }, /* S: in LDRAA and LDRAB instructions. */
{ 22, 1 }, /* N: in logical (immediate) instructions. */
{ 11, 1 }, /* index: in ld/st inst deciding the pre/post-index. */
{ 24, 1 }, /* index2: in ld/st pair inst deciding the pre/post-index. */
{ 31, 1 }, /* sf: in integer data processing instructions. */
{ 30, 1 }, /* lse_size: in LSE extension atomic instructions. */
{ 11, 1 }, /* H: in advsimd scalar x indexed element instructions. */
{ 21, 1 }, /* L: in advsimd scalar x indexed element instructions. */
{ 20, 1 }, /* M: in advsimd scalar x indexed element instructions. */
{ 31, 1 }, /* b5: in the test bit and branch instructions. */
{ 19, 5 }, /* b40: in the test bit and branch instructions. */
{ 10, 6 }, /* scale: in the fixed-point scalar to fp converting inst. */
{ 4, 1 }, /* SVE_M_4: Merge/zero select, bit 4. */
{ 14, 1 }, /* SVE_M_14: Merge/zero select, bit 14. */
{ 16, 1 }, /* SVE_M_16: Merge/zero select, bit 16. */
{ 17, 1 }, /* SVE_N: SVE equivalent of N. */
{ 0, 4 }, /* SVE_Pd: p0-p15, bits [3,0]. */
{ 10, 3 }, /* SVE_Pg3: p0-p7, bits [12,10]. */
{ 5, 4 }, /* SVE_Pg4_5: p0-p15, bits [8,5]. */
{ 10, 4 }, /* SVE_Pg4_10: p0-p15, bits [13,10]. */
{ 16, 4 }, /* SVE_Pg4_16: p0-p15, bits [19,16]. */
{ 16, 4 }, /* SVE_Pm: p0-p15, bits [19,16]. */
{ 5, 4 }, /* SVE_Pn: p0-p15, bits [8,5]. */
{ 0, 4 }, /* SVE_Pt: p0-p15, bits [3,0]. */
{ 5, 5 }, /* SVE_Rm: SVE alternative position for Rm. */
{ 16, 5 }, /* SVE_Rn: SVE alternative position for Rn. */
{ 0, 5 }, /* SVE_Vd: Scalar SIMD&FP register, bits [4,0]. */
{ 5, 5 }, /* SVE_Vm: Scalar SIMD&FP register, bits [9,5]. */
{ 5, 5 }, /* SVE_Vn: Scalar SIMD&FP register, bits [9,5]. */
{ 5, 5 }, /* SVE_Za_5: SVE vector register, bits [9,5]. */
{ 16, 5 }, /* SVE_Za_16: SVE vector register, bits [20,16]. */
{ 0, 5 }, /* SVE_Zd: SVE vector register. bits [4,0]. */
{ 5, 5 }, /* SVE_Zm_5: SVE vector register, bits [9,5]. */
{ 16, 5 }, /* SVE_Zm_16: SVE vector register, bits [20,16]. */
{ 5, 5 }, /* SVE_Zn: SVE vector register, bits [9,5]. */
{ 0, 5 }, /* SVE_Zt: SVE vector register, bits [4,0]. */
{ 5, 1 }, /* SVE_i1: single-bit immediate. */
{ 22, 1 }, /* SVE_i3h: high bit of 3-bit immediate. */
{ 11, 1 }, /* SVE_i3l: low bit of 3-bit immediate. */
{ 19, 2 }, /* SVE_i3h2: two high bits of 3bit immediate, bits [20,19]. */
{ 20, 1 }, /* SVE_i2h: high bit of 2bit immediate, bits. */
{ 16, 3 }, /* SVE_imm3: 3-bit immediate field. */
{ 16, 4 }, /* SVE_imm4: 4-bit immediate field. */
{ 5, 5 }, /* SVE_imm5: 5-bit immediate field. */
{ 16, 5 }, /* SVE_imm5b: secondary 5-bit immediate field. */
{ 16, 6 }, /* SVE_imm6: 6-bit immediate field. */
{ 14, 7 }, /* SVE_imm7: 7-bit immediate field. */
{ 5, 8 }, /* SVE_imm8: 8-bit immediate field. */
{ 5, 9 }, /* SVE_imm9: 9-bit immediate field. */
{ 11, 6 }, /* SVE_immr: SVE equivalent of immr. */
{ 5, 6 }, /* SVE_imms: SVE equivalent of imms. */
{ 10, 2 }, /* SVE_msz: 2-bit shift amount for ADR. */
{ 5, 5 }, /* SVE_pattern: vector pattern enumeration. */
{ 0, 4 }, /* SVE_prfop: prefetch operation for SVE PRF[BHWD]. */
{ 16, 1 }, /* SVE_rot1: 1-bit rotation amount. */
{ 10, 2 }, /* SVE_rot2: 2-bit rotation amount. */
{ 10, 1 }, /* SVE_rot3: 1-bit rotation amount at bit 10. */
{ 22, 1 }, /* SVE_sz: 1-bit element size select. */
{ 17, 2 }, /* SVE_size: 2-bit element size, bits [18,17]. */
{ 30, 1 }, /* SVE_sz2: 1-bit element size select. */
{ 16, 4 }, /* SVE_tsz: triangular size select. */
{ 22, 2 }, /* SVE_tszh: triangular size select high, bits [23,22]. */
{ 8, 2 }, /* SVE_tszl_8: triangular size select low, bits [9,8]. */
{ 19, 2 }, /* SVE_tszl_19: triangular size select low, bits [20,19]. */
{ 14, 1 }, /* SVE_xs_14: UXTW/SXTW select (bit 14). */
{ 22, 1 }, /* SVE_xs_22: UXTW/SXTW select (bit 22). */
{ 11, 2 }, /* rotate1: FCMLA immediate rotate. */
{ 13, 2 }, /* rotate2: Indexed element FCMLA immediate rotate. */
{ 12, 1 }, /* rotate3: FCADD immediate rotate. */
{ 12, 2 }, /* SM3: Indexed element SM3 2 bits index immediate. */
{ 22, 1 }, /* sz: 1-bit element size select. */
};
enum aarch64_operand_class
aarch64_get_operand_class (enum aarch64_opnd type)
{
return aarch64_operands[type].op_class;
}
const char *
aarch64_get_operand_name (enum aarch64_opnd type)
{
return aarch64_operands[type].name;
}
/* Get operand description string.
This is usually for the diagnosis purpose. */
const char *
aarch64_get_operand_desc (enum aarch64_opnd type)
{
return aarch64_operands[type].desc;
}
/* Table of all conditional affixes. */
const aarch64_cond aarch64_conds[16] =
{
{{"eq", "none"}, 0x0},
{{"ne", "any"}, 0x1},
{{"cs", "hs", "nlast"}, 0x2},
{{"cc", "lo", "ul", "last"}, 0x3},
{{"mi", "first"}, 0x4},
{{"pl", "nfrst"}, 0x5},
{{"vs"}, 0x6},
{{"vc"}, 0x7},
{{"hi", "pmore"}, 0x8},
{{"ls", "plast"}, 0x9},
{{"ge", "tcont"}, 0xa},
{{"lt", "tstop"}, 0xb},
{{"gt"}, 0xc},
{{"le"}, 0xd},
{{"al"}, 0xe},
{{"nv"}, 0xf},
};
const aarch64_cond *
get_cond_from_value (aarch64_insn value)
{
assert (value < 16);
return &aarch64_conds[(unsigned int) value];
}
const aarch64_cond *
get_inverted_cond (const aarch64_cond *cond)
{
return &aarch64_conds[cond->value ^ 0x1];
}
/* Table describing the operand extension/shifting operators; indexed by
enum aarch64_modifier_kind.
The value column provides the most common values for encoding modifiers,
which enables table-driven encoding/decoding for the modifiers. */
const struct aarch64_name_value_pair aarch64_operand_modifiers [] =
{
{"none", 0x0},
{"msl", 0x0},
{"ror", 0x3},
{"asr", 0x2},
{"lsr", 0x1},
{"lsl", 0x0},
{"uxtb", 0x0},
{"uxth", 0x1},
{"uxtw", 0x2},
{"uxtx", 0x3},
{"sxtb", 0x4},
{"sxth", 0x5},
{"sxtw", 0x6},
{"sxtx", 0x7},
{"mul", 0x0},
{"mul vl", 0x0},
{NULL, 0},
};
enum aarch64_modifier_kind
aarch64_get_operand_modifier (const struct aarch64_name_value_pair *desc)
{
return desc - aarch64_operand_modifiers;
}
aarch64_insn
aarch64_get_operand_modifier_value (enum aarch64_modifier_kind kind)
{
return aarch64_operand_modifiers[kind].value;
}
enum aarch64_modifier_kind
aarch64_get_operand_modifier_from_value (aarch64_insn value,
bfd_boolean extend_p)
{
if (extend_p == TRUE)
return AARCH64_MOD_UXTB + value;
else
return AARCH64_MOD_LSL - value;
}
bfd_boolean
aarch64_extend_operator_p (enum aarch64_modifier_kind kind)
{
return (kind > AARCH64_MOD_LSL && kind <= AARCH64_MOD_SXTX)
? TRUE : FALSE;
}
static inline bfd_boolean
aarch64_shift_operator_p (enum aarch64_modifier_kind kind)
{
return (kind >= AARCH64_MOD_ROR && kind <= AARCH64_MOD_LSL)
? TRUE : FALSE;
}
const struct aarch64_name_value_pair aarch64_barrier_options[16] =
{
{ "#0x00", 0x0 },
{ "oshld", 0x1 },
{ "oshst", 0x2 },
{ "osh", 0x3 },
{ "#0x04", 0x4 },
{ "nshld", 0x5 },
{ "nshst", 0x6 },
{ "nsh", 0x7 },
{ "#0x08", 0x8 },
{ "ishld", 0x9 },
{ "ishst", 0xa },
{ "ish", 0xb },
{ "#0x0c", 0xc },
{ "ld", 0xd },
{ "st", 0xe },
{ "sy", 0xf },
};
/* Table describing the operands supported by the aliases of the HINT
instruction.
The name column is the operand that is accepted for the alias. The value
column is the hint number of the alias. The list of operands is terminated
by NULL in the name column. */
const struct aarch64_name_value_pair aarch64_hint_options[] =
{
/* BTI. This is also the F_DEFAULT entry for AARCH64_OPND_BTI_TARGET. */
{ " ", HINT_ENCODE (HINT_OPD_F_NOPRINT, 0x20) },
{ "csync", HINT_OPD_CSYNC }, /* PSB CSYNC. */
{ "c", HINT_OPD_C }, /* BTI C. */
{ "j", HINT_OPD_J }, /* BTI J. */
{ "jc", HINT_OPD_JC }, /* BTI JC. */
{ NULL, HINT_OPD_NULL },
};
/* op -> op: load = 0 instruction = 1 store = 2
l -> level: 1-3
t -> temporal: temporal (retained) = 0 non-temporal (streaming) = 1 */
#define B(op,l,t) (((op) << 3) | (((l) - 1) << 1) | (t))
const struct aarch64_name_value_pair aarch64_prfops[32] =
{
{ "pldl1keep", B(0, 1, 0) },
{ "pldl1strm", B(0, 1, 1) },
{ "pldl2keep", B(0, 2, 0) },
{ "pldl2strm", B(0, 2, 1) },
{ "pldl3keep", B(0, 3, 0) },
{ "pldl3strm", B(0, 3, 1) },
{ NULL, 0x06 },
{ NULL, 0x07 },
{ "plil1keep", B(1, 1, 0) },
{ "plil1strm", B(1, 1, 1) },
{ "plil2keep", B(1, 2, 0) },
{ "plil2strm", B(1, 2, 1) },
{ "plil3keep", B(1, 3, 0) },
{ "plil3strm", B(1, 3, 1) },
{ NULL, 0x0e },
{ NULL, 0x0f },
{ "pstl1keep", B(2, 1, 0) },
{ "pstl1strm", B(2, 1, 1) },
{ "pstl2keep", B(2, 2, 0) },
{ "pstl2strm", B(2, 2, 1) },
{ "pstl3keep", B(2, 3, 0) },
{ "pstl3strm", B(2, 3, 1) },
{ NULL, 0x16 },
{ NULL, 0x17 },
{ NULL, 0x18 },
{ NULL, 0x19 },
{ NULL, 0x1a },
{ NULL, 0x1b },
{ NULL, 0x1c },
{ NULL, 0x1d },
{ NULL, 0x1e },
{ NULL, 0x1f },
};
#undef B
/* Utilities on value constraint. */
static inline int
value_in_range_p (int64_t value, int low, int high)
{
return (value >= low && value <= high) ? 1 : 0;
}
/* Return true if VALUE is a multiple of ALIGN. */
static inline int
value_aligned_p (int64_t value, int align)
{
return (value % align) == 0;
}
/* A signed value fits in a field. */
static inline int
value_fit_signed_field_p (int64_t value, unsigned width)
{
assert (width < 32);
if (width < sizeof (value) * 8)
{
int64_t lim = (uint64_t) 1 << (width - 1);
if (value >= -lim && value < lim)
return 1;
}
return 0;
}
/* An unsigned value fits in a field. */
static inline int
value_fit_unsigned_field_p (int64_t value, unsigned width)
{
assert (width < 32);
if (width < sizeof (value) * 8)
{
int64_t lim = (uint64_t) 1 << width;
if (value >= 0 && value < lim)
return 1;
}
return 0;
}
/* Return 1 if OPERAND is SP or WSP. */
int
aarch64_stack_pointer_p (const aarch64_opnd_info *operand)
{
return ((aarch64_get_operand_class (operand->type)
== AARCH64_OPND_CLASS_INT_REG)
&& operand_maybe_stack_pointer (aarch64_operands + operand->type)
&& operand->reg.regno == 31);
}
/* Return 1 if OPERAND is XZR or WZP. */
int
aarch64_zero_register_p (const aarch64_opnd_info *operand)
{
return ((aarch64_get_operand_class (operand->type)
== AARCH64_OPND_CLASS_INT_REG)
&& !operand_maybe_stack_pointer (aarch64_operands + operand->type)
&& operand->reg.regno == 31);
}
/* Return true if the operand *OPERAND that has the operand code
OPERAND->TYPE and been qualified by OPERAND->QUALIFIER can be also
qualified by the qualifier TARGET. */
static inline int
operand_also_qualified_p (const struct aarch64_opnd_info *operand,
aarch64_opnd_qualifier_t target)
{
switch (operand->qualifier)
{
case AARCH64_OPND_QLF_W:
if (target == AARCH64_OPND_QLF_WSP && aarch64_stack_pointer_p (operand))
return 1;
break;
case AARCH64_OPND_QLF_X:
if (target == AARCH64_OPND_QLF_SP && aarch64_stack_pointer_p (operand))
return 1;
break;
case AARCH64_OPND_QLF_WSP:
if (target == AARCH64_OPND_QLF_W
&& operand_maybe_stack_pointer (aarch64_operands + operand->type))
return 1;
break;
case AARCH64_OPND_QLF_SP:
if (target == AARCH64_OPND_QLF_X
&& operand_maybe_stack_pointer (aarch64_operands + operand->type))
return 1;
break;
default:
break;
}
return 0;
}
/* Given qualifier sequence list QSEQ_LIST and the known qualifier KNOWN_QLF
for operand KNOWN_IDX, return the expected qualifier for operand IDX.
Return NIL if more than one expected qualifiers are found. */
aarch64_opnd_qualifier_t
aarch64_get_expected_qualifier (const aarch64_opnd_qualifier_seq_t *qseq_list,
int idx,
const aarch64_opnd_qualifier_t known_qlf,
int known_idx)
{
int i, saved_i;
/* Special case.
When the known qualifier is NIL, we have to assume that there is only
one qualifier sequence in the *QSEQ_LIST and return the corresponding
qualifier directly. One scenario is that for instruction
PRFM , [, #:lo12:]
which has only one possible valid qualifier sequence
NIL, S_D
the caller may pass NIL in KNOWN_QLF to obtain S_D so that it can
determine the correct relocation type (i.e. LDST64_LO12) for PRFM.
Because the qualifier NIL has dual roles in the qualifier sequence:
it can mean no qualifier for the operand, or the qualifer sequence is
not in use (when all qualifiers in the sequence are NILs), we have to
handle this special case here. */
if (known_qlf == AARCH64_OPND_NIL)
{
assert (qseq_list[0][known_idx] == AARCH64_OPND_NIL);
return qseq_list[0][idx];
}
for (i = 0, saved_i = -1; i < AARCH64_MAX_QLF_SEQ_NUM; ++i)
{
if (qseq_list[i][known_idx] == known_qlf)
{
if (saved_i != -1)
/* More than one sequences are found to have KNOWN_QLF at
KNOWN_IDX. */
return AARCH64_OPND_NIL;
saved_i = i;
}
}
return qseq_list[saved_i][idx];
}
enum operand_qualifier_kind
{
OQK_NIL,
OQK_OPD_VARIANT,
OQK_VALUE_IN_RANGE,
OQK_MISC,
};
/* Operand qualifier description. */
struct operand_qualifier_data
{
/* The usage of the three data fields depends on the qualifier kind. */
int data0;
int data1;
int data2;
/* Description. */
const char *desc;
/* Kind. */
enum operand_qualifier_kind kind;
};
/* Indexed by the operand qualifier enumerators. */
struct operand_qualifier_data aarch64_opnd_qualifiers[] =
{
{0, 0, 0, "NIL", OQK_NIL},
/* Operand variant qualifiers.
First 3 fields:
element size, number of elements and common value for encoding. */
{4, 1, 0x0, "w", OQK_OPD_VARIANT},
{8, 1, 0x1, "x", OQK_OPD_VARIANT},
{4, 1, 0x0, "wsp", OQK_OPD_VARIANT},
{8, 1, 0x1, "sp", OQK_OPD_VARIANT},
{1, 1, 0x0, "b", OQK_OPD_VARIANT},
{2, 1, 0x1, "h", OQK_OPD_VARIANT},
{4, 1, 0x2, "s", OQK_OPD_VARIANT},
{8, 1, 0x3, "d", OQK_OPD_VARIANT},
{16, 1, 0x4, "q", OQK_OPD_VARIANT},
{4, 1, 0x0, "4b", OQK_OPD_VARIANT},
{4, 1, 0x0, "2h", OQK_OPD_VARIANT},
{1, 4, 0x0, "4b", OQK_OPD_VARIANT},
{1, 8, 0x0, "8b", OQK_OPD_VARIANT},
{1, 16, 0x1, "16b", OQK_OPD_VARIANT},
{2, 2, 0x0, "2h", OQK_OPD_VARIANT},
{2, 4, 0x2, "4h", OQK_OPD_VARIANT},
{2, 8, 0x3, "8h", OQK_OPD_VARIANT},
{4, 2, 0x4, "2s", OQK_OPD_VARIANT},
{4, 4, 0x5, "4s", OQK_OPD_VARIANT},
{8, 1, 0x6, "1d", OQK_OPD_VARIANT},
{8, 2, 0x7, "2d", OQK_OPD_VARIANT},
{16, 1, 0x8, "1q", OQK_OPD_VARIANT},
{0, 0, 0, "z", OQK_OPD_VARIANT},
{0, 0, 0, "m", OQK_OPD_VARIANT},
/* Qualifier for scaled immediate for Tag granule (stg,st2g,etc). */
{16, 0, 0, "tag", OQK_OPD_VARIANT},
/* Qualifiers constraining the value range.
First 3 fields:
Lower bound, higher bound, unused. */
{0, 15, 0, "CR", OQK_VALUE_IN_RANGE},
{0, 7, 0, "imm_0_7" , OQK_VALUE_IN_RANGE},
{0, 15, 0, "imm_0_15", OQK_VALUE_IN_RANGE},
{0, 31, 0, "imm_0_31", OQK_VALUE_IN_RANGE},
{0, 63, 0, "imm_0_63", OQK_VALUE_IN_RANGE},
{1, 32, 0, "imm_1_32", OQK_VALUE_IN_RANGE},
{1, 64, 0, "imm_1_64", OQK_VALUE_IN_RANGE},
/* Qualifiers for miscellaneous purpose.
First 3 fields:
unused, unused and unused. */
{0, 0, 0, "lsl", 0},
{0, 0, 0, "msl", 0},
{0, 0, 0, "retrieving", 0},
};
static inline bfd_boolean
operand_variant_qualifier_p (aarch64_opnd_qualifier_t qualifier)
{
return (aarch64_opnd_qualifiers[qualifier].kind == OQK_OPD_VARIANT)
? TRUE : FALSE;
}
static inline bfd_boolean
qualifier_value_in_range_constraint_p (aarch64_opnd_qualifier_t qualifier)
{
return (aarch64_opnd_qualifiers[qualifier].kind == OQK_VALUE_IN_RANGE)
? TRUE : FALSE;
}
const char*
aarch64_get_qualifier_name (aarch64_opnd_qualifier_t qualifier)
{
return aarch64_opnd_qualifiers[qualifier].desc;
}
/* Given an operand qualifier, return the expected data element size
of a qualified operand. */
unsigned char
aarch64_get_qualifier_esize (aarch64_opnd_qualifier_t qualifier)
{
assert (operand_variant_qualifier_p (qualifier) == TRUE);
return aarch64_opnd_qualifiers[qualifier].data0;
}
unsigned char
aarch64_get_qualifier_nelem (aarch64_opnd_qualifier_t qualifier)
{
assert (operand_variant_qualifier_p (qualifier) == TRUE);
return aarch64_opnd_qualifiers[qualifier].data1;
}
aarch64_insn
aarch64_get_qualifier_standard_value (aarch64_opnd_qualifier_t qualifier)
{
assert (operand_variant_qualifier_p (qualifier) == TRUE);
return aarch64_opnd_qualifiers[qualifier].data2;
}
static int
get_lower_bound (aarch64_opnd_qualifier_t qualifier)
{
assert (qualifier_value_in_range_constraint_p (qualifier) == TRUE);
return aarch64_opnd_qualifiers[qualifier].data0;
}
static int
get_upper_bound (aarch64_opnd_qualifier_t qualifier)
{
assert (qualifier_value_in_range_constraint_p (qualifier) == TRUE);
return aarch64_opnd_qualifiers[qualifier].data1;
}
#ifdef DEBUG_AARCH64
void
aarch64_verbose (const char *str, ...)
{
va_list ap;
va_start (ap, str);
printf ("#### ");
vprintf (str, ap);
printf ("\n");
va_end (ap);
}
static inline void
dump_qualifier_sequence (const aarch64_opnd_qualifier_t *qualifier)
{
int i;
printf ("#### \t");
for (i = 0; i < AARCH64_MAX_OPND_NUM; ++i, ++qualifier)
printf ("%s,", aarch64_get_qualifier_name (*qualifier));
printf ("\n");
}
static void
dump_match_qualifiers (const struct aarch64_opnd_info *opnd,
const aarch64_opnd_qualifier_t *qualifier)
{
int i;
aarch64_opnd_qualifier_t curr[AARCH64_MAX_OPND_NUM];
aarch64_verbose ("dump_match_qualifiers:");
for (i = 0; i < AARCH64_MAX_OPND_NUM; ++i)
curr[i] = opnd[i].qualifier;
dump_qualifier_sequence (curr);
aarch64_verbose ("against");
dump_qualifier_sequence (qualifier);
}
#endif /* DEBUG_AARCH64 */
/* This function checks if the given instruction INSN is a destructive
instruction based on the usage of the registers. It does not recognize
unary destructive instructions. */
bfd_boolean
aarch64_is_destructive_by_operands (const aarch64_opcode *opcode)
{
int i = 0;
const enum aarch64_opnd *opnds = opcode->operands;
if (opnds[0] == AARCH64_OPND_NIL)
return FALSE;
while (opnds[++i] != AARCH64_OPND_NIL)
if (opnds[i] == opnds[0])
return TRUE;
return FALSE;
}
/* TODO improve this, we can have an extra field at the runtime to
store the number of operands rather than calculating it every time. */
int
aarch64_num_of_operands (const aarch64_opcode *opcode)
{
int i = 0;
const enum aarch64_opnd *opnds = opcode->operands;
while (opnds[i++] != AARCH64_OPND_NIL)
;
--i;
assert (i >= 0 && i <= AARCH64_MAX_OPND_NUM);
return i;
}
/* Find the best matched qualifier sequence in *QUALIFIERS_LIST for INST.
If succeeds, fill the found sequence in *RET, return 1; otherwise return 0.
N.B. on the entry, it is very likely that only some operands in *INST
have had their qualifiers been established.
If STOP_AT is not -1, the function will only try to match
the qualifier sequence for operands before and including the operand
of index STOP_AT; and on success *RET will only be filled with the first
(STOP_AT+1) qualifiers.
A couple examples of the matching algorithm:
X,W,NIL should match
X,W,NIL
NIL,NIL should match
X ,NIL
Apart from serving the main encoding routine, this can also be called
during or after the operand decoding. */
int
aarch64_find_best_match (const aarch64_inst *inst,
const aarch64_opnd_qualifier_seq_t *qualifiers_list,
int stop_at, aarch64_opnd_qualifier_t *ret)
{
int found = 0;
int i, num_opnds;
const aarch64_opnd_qualifier_t *qualifiers;
num_opnds = aarch64_num_of_operands (inst->opcode);
if (num_opnds == 0)
{
DEBUG_TRACE ("SUCCEED: no operand");
return 1;
}
if (stop_at < 0 || stop_at >= num_opnds)
stop_at = num_opnds - 1;
/* For each pattern. */
for (i = 0; i < AARCH64_MAX_QLF_SEQ_NUM; ++i, ++qualifiers_list)
{
int j;
qualifiers = *qualifiers_list;
/* Start as positive. */
found = 1;
DEBUG_TRACE ("%d", i);
#ifdef DEBUG_AARCH64
if (debug_dump)
dump_match_qualifiers (inst->operands, qualifiers);
#endif
/* Most opcodes has much fewer patterns in the list.
First NIL qualifier indicates the end in the list. */
if (empty_qualifier_sequence_p (qualifiers) == TRUE)
{
DEBUG_TRACE_IF (i == 0, "SUCCEED: empty qualifier list");
if (i)
found = 0;
break;
}
for (j = 0; j < num_opnds && j <= stop_at; ++j, ++qualifiers)
{
if (inst->operands[j].qualifier == AARCH64_OPND_QLF_NIL)
{
/* Either the operand does not have qualifier, or the qualifier
for the operand needs to be deduced from the qualifier
sequence.
In the latter case, any constraint checking related with
the obtained qualifier should be done later in
operand_general_constraint_met_p. */
continue;
}
else if (*qualifiers != inst->operands[j].qualifier)
{
/* Unless the target qualifier can also qualify the operand
(which has already had a non-nil qualifier), non-equal
qualifiers are generally un-matched. */
if (operand_also_qualified_p (inst->operands + j, *qualifiers))
continue;
else
{
found = 0;
break;
}
}
else
continue; /* Equal qualifiers are certainly matched. */
}
/* Qualifiers established. */
if (found == 1)
break;
}
if (found == 1)
{
/* Fill the result in *RET. */
int j;
qualifiers = *qualifiers_list;
DEBUG_TRACE ("complete qualifiers using list %d", i);
#ifdef DEBUG_AARCH64
if (debug_dump)
dump_qualifier_sequence (qualifiers);
#endif
for (j = 0; j <= stop_at; ++j, ++qualifiers)
ret[j] = *qualifiers;
for (; j < AARCH64_MAX_OPND_NUM; ++j)
ret[j] = AARCH64_OPND_QLF_NIL;
DEBUG_TRACE ("SUCCESS");
return 1;
}
DEBUG_TRACE ("FAIL");
return 0;
}
/* Operand qualifier matching and resolving.
Return 1 if the operand qualifier(s) in *INST match one of the qualifier
sequences in INST->OPCODE->qualifiers_list; otherwise return 0.
if UPDATE_P == TRUE, update the qualifier(s) in *INST after the matching
succeeds. */
static int
match_operands_qualifier (aarch64_inst *inst, bfd_boolean update_p)
{
int i, nops;
aarch64_opnd_qualifier_seq_t qualifiers;
if (!aarch64_find_best_match (inst, inst->opcode->qualifiers_list, -1,
qualifiers))
{
DEBUG_TRACE ("matching FAIL");
return 0;
}
if (inst->opcode->flags & F_STRICT)
{
/* Require an exact qualifier match, even for NIL qualifiers. */
nops = aarch64_num_of_operands (inst->opcode);
for (i = 0; i < nops; ++i)
if (inst->operands[i].qualifier != qualifiers[i])
return FALSE;
}
/* Update the qualifiers. */
if (update_p == TRUE)
for (i = 0; i < AARCH64_MAX_OPND_NUM; ++i)
{
if (inst->opcode->operands[i] == AARCH64_OPND_NIL)
break;
DEBUG_TRACE_IF (inst->operands[i].qualifier != qualifiers[i],
"update %s with %s for operand %d",
aarch64_get_qualifier_name (inst->operands[i].qualifier),
aarch64_get_qualifier_name (qualifiers[i]), i);
inst->operands[i].qualifier = qualifiers[i];
}
DEBUG_TRACE ("matching SUCCESS");
return 1;
}
/* Return TRUE if VALUE is a wide constant that can be moved into a general
register by MOVZ.
IS32 indicates whether value is a 32-bit immediate or not.
If SHIFT_AMOUNT is not NULL, on the return of TRUE, the logical left shift
amount will be returned in *SHIFT_AMOUNT. */
bfd_boolean
aarch64_wide_constant_p (uint64_t value, int is32, unsigned int *shift_amount)
{
int amount;
DEBUG_TRACE ("enter with 0x%" PRIx64 "(%" PRIi64 ")", value, value);
if (is32)
{
/* Allow all zeros or all ones in top 32-bits, so that
32-bit constant expressions like ~0x80000000 are
permitted. */
if (value >> 32 != 0 && value >> 32 != 0xffffffff)
/* Immediate out of range. */
return FALSE;
value &= 0xffffffff;
}
/* first, try movz then movn */
amount = -1;
if ((value & ((uint64_t) 0xffff << 0)) == value)
amount = 0;
else if ((value & ((uint64_t) 0xffff << 16)) == value)
amount = 16;
else if (!is32 && (value & ((uint64_t) 0xffff << 32)) == value)
amount = 32;
else if (!is32 && (value & ((uint64_t) 0xffff << 48)) == value)
amount = 48;
if (amount == -1)
{
DEBUG_TRACE ("exit FALSE with 0x%" PRIx64 "(%" PRIi64 ")", value, value);
return FALSE;
}
if (shift_amount != NULL)
*shift_amount = amount;
DEBUG_TRACE ("exit TRUE with amount %d", amount);
return TRUE;
}
/* Build the accepted values for immediate logical SIMD instructions.
The standard encodings of the immediate value are:
N imms immr SIMD size R S
1 ssssss rrrrrr 64 UInt(rrrrrr) UInt(ssssss)
0 0sssss 0rrrrr 32 UInt(rrrrr) UInt(sssss)
0 10ssss 00rrrr 16 UInt(rrrr) UInt(ssss)
0 110sss 000rrr 8 UInt(rrr) UInt(sss)
0 1110ss 0000rr 4 UInt(rr) UInt(ss)
0 11110s 00000r 2 UInt(r) UInt(s)
where all-ones value of S is reserved.
Let's call E the SIMD size.
The immediate value is: S+1 bits '1' rotated to the right by R.
The total of valid encodings is 64*63 + 32*31 + ... + 2*1 = 5334
(remember S != E - 1). */
#define TOTAL_IMM_NB 5334
typedef struct
{
uint64_t imm;
aarch64_insn encoding;
} simd_imm_encoding;
static simd_imm_encoding simd_immediates[TOTAL_IMM_NB];
static int
simd_imm_encoding_cmp(const void *i1, const void *i2)
{
const simd_imm_encoding *imm1 = (const simd_imm_encoding *)i1;
const simd_imm_encoding *imm2 = (const simd_imm_encoding *)i2;
if (imm1->imm < imm2->imm)
return -1;
if (imm1->imm > imm2->imm)
return +1;
return 0;
}
/* immediate bitfield standard encoding
imm13<12> imm13<5:0> imm13<11:6> SIMD size R S
1 ssssss rrrrrr 64 rrrrrr ssssss
0 0sssss 0rrrrr 32 rrrrr sssss
0 10ssss 00rrrr 16 rrrr ssss
0 110sss 000rrr 8 rrr sss
0 1110ss 0000rr 4 rr ss
0 11110s 00000r 2 r s */
static inline int
encode_immediate_bitfield (int is64, uint32_t s, uint32_t r)
{
return (is64 << 12) | (r << 6) | s;
}
static void
build_immediate_table (void)
{
uint32_t log_e, e, s, r, s_mask;
uint64_t mask, imm;
int nb_imms;
int is64;
nb_imms = 0;
for (log_e = 1; log_e <= 6; log_e++)
{
/* Get element size. */
e = 1u << log_e;
if (log_e == 6)
{
is64 = 1;
mask = 0xffffffffffffffffull;
s_mask = 0;
}
else
{
is64 = 0;
mask = (1ull << e) - 1;
/* log_e s_mask
1 ((1 << 4) - 1) << 2 = 111100
2 ((1 << 3) - 1) << 3 = 111000
3 ((1 << 2) - 1) << 4 = 110000
4 ((1 << 1) - 1) << 5 = 100000
5 ((1 << 0) - 1) << 6 = 000000 */
s_mask = ((1u << (5 - log_e)) - 1) << (log_e + 1);
}
for (s = 0; s < e - 1; s++)
for (r = 0; r < e; r++)
{
/* s+1 consecutive bits to 1 (s < 63) */
imm = (1ull << (s + 1)) - 1;
/* rotate right by r */
if (r != 0)
imm = (imm >> r) | ((imm << (e - r)) & mask);
/* replicate the constant depending on SIMD size */
switch (log_e)
{
case 1: imm = (imm << 2) | imm;
/* Fall through. */
case 2: imm = (imm << 4) | imm;
/* Fall through. */
case 3: imm = (imm << 8) | imm;
/* Fall through. */
case 4: imm = (imm << 16) | imm;
/* Fall through. */
case 5: imm = (imm << 32) | imm;
/* Fall through. */
case 6: break;
default: abort ();
}
simd_immediates[nb_imms].imm = imm;
simd_immediates[nb_imms].encoding =
encode_immediate_bitfield(is64, s | s_mask, r);
nb_imms++;
}
}
assert (nb_imms == TOTAL_IMM_NB);
qsort(simd_immediates, nb_imms,
sizeof(simd_immediates[0]), simd_imm_encoding_cmp);
}
/* Return TRUE if VALUE is a valid logical immediate, i.e. bitmask, that can
be accepted by logical (immediate) instructions
e.g. ORR , , #.
ESIZE is the number of bytes in the decoded immediate value.
If ENCODING is not NULL, on the return of TRUE, the standard encoding for
VALUE will be returned in *ENCODING. */
bfd_boolean
aarch64_logical_immediate_p (uint64_t value, int esize, aarch64_insn *encoding)
{
simd_imm_encoding imm_enc;
const simd_imm_encoding *imm_encoding;
static bfd_boolean initialized = FALSE;
uint64_t upper;
int i;
DEBUG_TRACE ("enter with 0x%" PRIx64 "(%" PRIi64 "), esize: %d", value,
value, esize);
if (!initialized)
{
build_immediate_table ();
initialized = TRUE;
}
/* Allow all zeros or all ones in top bits, so that
constant expressions like ~1 are permitted. */
upper = (uint64_t) -1 << (esize * 4) << (esize * 4);
if ((value & ~upper) != value && (value | upper) != value)
return FALSE;
/* Replicate to a full 64-bit value. */
value &= ~upper;
for (i = esize * 8; i < 64; i *= 2)
value |= (value << i);
imm_enc.imm = value;
imm_encoding = (const simd_imm_encoding *)
bsearch(&imm_enc, simd_immediates, TOTAL_IMM_NB,
sizeof(simd_immediates[0]), simd_imm_encoding_cmp);
if (imm_encoding == NULL)
{
DEBUG_TRACE ("exit with FALSE");
return FALSE;
}
if (encoding != NULL)
*encoding = imm_encoding->encoding;
DEBUG_TRACE ("exit with TRUE");
return TRUE;
}
/* If 64-bit immediate IMM is in the format of
"aaaaaaaabbbbbbbbccccccccddddddddeeeeeeeeffffffffgggggggghhhhhhhh",
where a, b, c, d, e, f, g and h are independently 0 or 1, return an integer
of value "abcdefgh". Otherwise return -1. */
int
aarch64_shrink_expanded_imm8 (uint64_t imm)
{
int i, ret;
uint32_t byte;
ret = 0;
for (i = 0; i < 8; i++)
{
byte = (imm >> (8 * i)) & 0xff;
if (byte == 0xff)
ret |= 1 << i;
else if (byte != 0x00)
return -1;
}
return ret;
}
/* Utility inline functions for operand_general_constraint_met_p. */
static inline void
set_error (aarch64_operand_error *mismatch_detail,
enum aarch64_operand_error_kind kind, int idx,
const char* error)
{
if (mismatch_detail == NULL)
return;
mismatch_detail->kind = kind;
mismatch_detail->index = idx;
mismatch_detail->error = error;
}
static inline void
set_syntax_error (aarch64_operand_error *mismatch_detail, int idx,
const char* error)
{
if (mismatch_detail == NULL)
return;
set_error (mismatch_detail, AARCH64_OPDE_SYNTAX_ERROR, idx, error);
}
static inline void
set_out_of_range_error (aarch64_operand_error *mismatch_detail,
int idx, int lower_bound, int upper_bound,
const char* error)
{
if (mismatch_detail == NULL)
return;
set_error (mismatch_detail, AARCH64_OPDE_OUT_OF_RANGE, idx, error);
mismatch_detail->data[0] = lower_bound;
mismatch_detail->data[1] = upper_bound;
}
static inline void
set_imm_out_of_range_error (aarch64_operand_error *mismatch_detail,
int idx, int lower_bound, int upper_bound)
{
if (mismatch_detail == NULL)
return;
set_out_of_range_error (mismatch_detail, idx, lower_bound, upper_bound,
_("immediate value"));
}
static inline void
set_offset_out_of_range_error (aarch64_operand_error *mismatch_detail,
int idx, int lower_bound, int upper_bound)
{
if (mismatch_detail == NULL)
return;
set_out_of_range_error (mismatch_detail, idx, lower_bound, upper_bound,
_("immediate offset"));
}
static inline void
set_regno_out_of_range_error (aarch64_operand_error *mismatch_detail,
int idx, int lower_bound, int upper_bound)
{
if (mismatch_detail == NULL)
return;
set_out_of_range_error (mismatch_detail, idx, lower_bound, upper_bound,
_("register number"));
}
static inline void
set_elem_idx_out_of_range_error (aarch64_operand_error *mismatch_detail,
int idx, int lower_bound, int upper_bound)
{
if (mismatch_detail == NULL)
return;
set_out_of_range_error (mismatch_detail, idx, lower_bound, upper_bound,
_("register element index"));
}
static inline void
set_sft_amount_out_of_range_error (aarch64_operand_error *mismatch_detail,
int idx, int lower_bound, int upper_bound)
{
if (mismatch_detail == NULL)
return;
set_out_of_range_error (mismatch_detail, idx, lower_bound, upper_bound,
_("shift amount"));
}
/* Report that the MUL modifier in operand IDX should be in the range
[LOWER_BOUND, UPPER_BOUND]. */
static inline void
set_multiplier_out_of_range_error (aarch64_operand_error *mismatch_detail,
int idx, int lower_bound, int upper_bound)
{
if (mismatch_detail == NULL)
return;
set_out_of_range_error (mismatch_detail, idx, lower_bound, upper_bound,
_("multiplier"));
}
static inline void
set_unaligned_error (aarch64_operand_error *mismatch_detail, int idx,
int alignment)
{
if (mismatch_detail == NULL)
return;
set_error (mismatch_detail, AARCH64_OPDE_UNALIGNED, idx, NULL);
mismatch_detail->data[0] = alignment;
}
static inline void
set_reg_list_error (aarch64_operand_error *mismatch_detail, int idx,
int expected_num)
{
if (mismatch_detail == NULL)
return;
set_error (mismatch_detail, AARCH64_OPDE_REG_LIST, idx, NULL);
mismatch_detail->data[0] = expected_num;
}
static inline void
set_other_error (aarch64_operand_error *mismatch_detail, int idx,
const char* error)
{
if (mismatch_detail == NULL)
return;
set_error (mismatch_detail, AARCH64_OPDE_OTHER_ERROR, idx, error);
}
/* General constraint checking based on operand code.
Return 1 if OPNDS[IDX] meets the general constraint of operand code TYPE
as the IDXth operand of opcode OPCODE. Otherwise return 0.
This function has to be called after the qualifiers for all operands
have been resolved.
Mismatching error message is returned in *MISMATCH_DETAIL upon request,
i.e. when MISMATCH_DETAIL is non-NULL. This avoids the generation
of error message during the disassembling where error message is not
wanted. We avoid the dynamic construction of strings of error messages
here (i.e. in libopcodes), as it is costly and complicated; instead, we
use a combination of error code, static string and some integer data to
represent an error. */
static int
operand_general_constraint_met_p (const aarch64_opnd_info *opnds, int idx,
enum aarch64_opnd type,
const aarch64_opcode *opcode,
aarch64_operand_error *mismatch_detail)
{
unsigned num, modifiers, shift;
unsigned char size;
int64_t imm, min_value, max_value;
uint64_t uvalue, mask;
const aarch64_opnd_info *opnd = opnds + idx;
aarch64_opnd_qualifier_t qualifier = opnd->qualifier;
assert (opcode->operands[idx] == opnd->type && opnd->type == type);
switch (aarch64_operands[type].op_class)
{
case AARCH64_OPND_CLASS_INT_REG:
/* Check pair reg constraints for cas* instructions. */
if (type == AARCH64_OPND_PAIRREG)
{
assert (idx == 1 || idx == 3);
if (opnds[idx - 1].reg.regno % 2 != 0)
{
set_syntax_error (mismatch_detail, idx - 1,
_("reg pair must start from even reg"));
return 0;
}
if (opnds[idx].reg.regno != opnds[idx - 1].reg.regno + 1)
{
set_syntax_error (mismatch_detail, idx,
_("reg pair must be contiguous"));
return 0;
}
break;
}
/* may be optional in some IC and TLBI instructions. */
if (type == AARCH64_OPND_Rt_SYS)
{
assert (idx == 1 && (aarch64_get_operand_class (opnds[0].type)
== AARCH64_OPND_CLASS_SYSTEM));
if (opnds[1].present
&& !aarch64_sys_ins_reg_has_xt (opnds[0].sysins_op))
{
set_other_error (mismatch_detail, idx, _("extraneous register"));
return 0;
}
if (!opnds[1].present
&& aarch64_sys_ins_reg_has_xt (opnds[0].sysins_op))
{
set_other_error (mismatch_detail, idx, _("missing register"));
return 0;
}
}
switch (qualifier)
{
case AARCH64_OPND_QLF_WSP:
case AARCH64_OPND_QLF_SP:
if (!aarch64_stack_pointer_p (opnd))
{
set_other_error (mismatch_detail, idx,
_("stack pointer register expected"));
return 0;
}
break;
default:
break;
}
break;
case AARCH64_OPND_CLASS_SVE_REG:
switch (type)
{
case AARCH64_OPND_SVE_Zm3_INDEX:
case AARCH64_OPND_SVE_Zm3_22_INDEX:
case AARCH64_OPND_SVE_Zm3_11_INDEX:
case AARCH64_OPND_SVE_Zm4_11_INDEX:
case AARCH64_OPND_SVE_Zm4_INDEX:
size = get_operand_fields_width (get_operand_from_code (type));
shift = get_operand_specific_data (&aarch64_operands[type]);
mask = (1 << shift) - 1;
if (opnd->reg.regno > mask)
{
assert (mask == 7 || mask == 15);
set_other_error (mismatch_detail, idx,
mask == 15
? _("z0-z15 expected")
: _("z0-z7 expected"));
return 0;
}
mask = (1u << (size - shift)) - 1;
if (!value_in_range_p (opnd->reglane.index, 0, mask))
{
set_elem_idx_out_of_range_error (mismatch_detail, idx, 0, mask);
return 0;
}
break;
case AARCH64_OPND_SVE_Zn_INDEX:
size = aarch64_get_qualifier_esize (opnd->qualifier);
if (!value_in_range_p (opnd->reglane.index, 0, 64 / size - 1))
{
set_elem_idx_out_of_range_error (mismatch_detail, idx,
0, 64 / size - 1);
return 0;
}
break;
case AARCH64_OPND_SVE_ZnxN:
case AARCH64_OPND_SVE_ZtxN:
if (opnd->reglist.num_regs != get_opcode_dependent_value (opcode))
{
set_other_error (mismatch_detail, idx,
_("invalid register list"));
return 0;
}
break;
default:
break;
}
break;
case AARCH64_OPND_CLASS_PRED_REG:
if (opnd->reg.regno >= 8
&& get_operand_fields_width (get_operand_from_code (type)) == 3)
{
set_other_error (mismatch_detail, idx, _("p0-p7 expected"));
return 0;
}
break;
case AARCH64_OPND_CLASS_COND:
if (type == AARCH64_OPND_COND1
&& (opnds[idx].cond->value & 0xe) == 0xe)
{
/* Not allow AL or NV. */
set_syntax_error (mismatch_detail, idx, NULL);
}
break;
case AARCH64_OPND_CLASS_ADDRESS:
/* Check writeback. */
switch (opcode->iclass)
{
case ldst_pos:
case ldst_unscaled:
case ldstnapair_offs:
case ldstpair_off:
case ldst_unpriv:
if (opnd->addr.writeback == 1)
{
set_syntax_error (mismatch_detail, idx,
_("unexpected address writeback"));
return 0;
}
break;
case ldst_imm10:
if (opnd->addr.writeback == 1 && opnd->addr.preind != 1)
{
set_syntax_error (mismatch_detail, idx,
_("unexpected address writeback"));
return 0;
}
break;
case ldst_imm9:
case ldstpair_indexed:
case asisdlsep:
case asisdlsop:
if (opnd->addr.writeback == 0)
{
set_syntax_error (mismatch_detail, idx,
_("address writeback expected"));
return 0;
}
break;
default:
assert (opnd->addr.writeback == 0);
break;
}
switch (type)
{
case AARCH64_OPND_ADDR_SIMM7:
/* Scaled signed 7 bits immediate offset. */
/* Get the size of the data element that is accessed, which may be
different from that of the source register size,
e.g. in strb/ldrb. */
size = aarch64_get_qualifier_esize (opnd->qualifier);
if (!value_in_range_p (opnd->addr.offset.imm, -64 * size, 63 * size))
{
set_offset_out_of_range_error (mismatch_detail, idx,
-64 * size, 63 * size);
return 0;
}
if (!value_aligned_p (opnd->addr.offset.imm, size))
{
set_unaligned_error (mismatch_detail, idx, size);
return 0;
}
break;
case AARCH64_OPND_ADDR_OFFSET:
case AARCH64_OPND_ADDR_SIMM9:
/* Unscaled signed 9 bits immediate offset. */
if (!value_in_range_p (opnd->addr.offset.imm, -256, 255))
{
set_offset_out_of_range_error (mismatch_detail, idx, -256, 255);
return 0;
}
break;
case AARCH64_OPND_ADDR_SIMM9_2:
/* Unscaled signed 9 bits immediate offset, which has to be negative
or unaligned. */
size = aarch64_get_qualifier_esize (qualifier);
if ((value_in_range_p (opnd->addr.offset.imm, 0, 255)
&& !value_aligned_p (opnd->addr.offset.imm, size))
|| value_in_range_p (opnd->addr.offset.imm, -256, -1))
return 1;
set_other_error (mismatch_detail, idx,
_("negative or unaligned offset expected"));
return 0;
case AARCH64_OPND_ADDR_SIMM10:
/* Scaled signed 10 bits immediate offset. */
if (!value_in_range_p (opnd->addr.offset.imm, -4096, 4088))
{
set_offset_out_of_range_error (mismatch_detail, idx, -4096, 4088);
return 0;
}
if (!value_aligned_p (opnd->addr.offset.imm, 8))
{
set_unaligned_error (mismatch_detail, idx, 8);
return 0;
}
break;
case AARCH64_OPND_ADDR_SIMM11:
/* Signed 11 bits immediate offset (multiple of 16). */
if (!value_in_range_p (opnd->addr.offset.imm, -1024, 1008))
{
set_offset_out_of_range_error (mismatch_detail, idx, -1024, 1008);
return 0;
}
if (!value_aligned_p (opnd->addr.offset.imm, 16))
{
set_unaligned_error (mismatch_detail, idx, 16);
return 0;
}
break;
case AARCH64_OPND_ADDR_SIMM13:
/* Signed 13 bits immediate offset (multiple of 16). */
if (!value_in_range_p (opnd->addr.offset.imm, -4096, 4080))
{
set_offset_out_of_range_error (mismatch_detail, idx, -4096, 4080);
return 0;
}
if (!value_aligned_p (opnd->addr.offset.imm, 16))
{
set_unaligned_error (mismatch_detail, idx, 16);
return 0;
}
break;
case AARCH64_OPND_SIMD_ADDR_POST:
/* AdvSIMD load/store multiple structures, post-index. */
assert (idx == 1);
if (opnd->addr.offset.is_reg)
{
if (value_in_range_p (opnd->addr.offset.regno, 0, 30))
return 1;
else
{
set_other_error (mismatch_detail, idx,
_("invalid register offset"));
return 0;
}
}
else
{
const aarch64_opnd_info *prev = &opnds[idx-1];
unsigned num_bytes; /* total number of bytes transferred. */
/* The opcode dependent area stores the number of elements in
each structure to be loaded/stored. */
int is_ld1r = get_opcode_dependent_value (opcode) == 1;
if (opcode->operands[0] == AARCH64_OPND_LVt_AL)
/* Special handling of loading single structure to all lane. */
num_bytes = (is_ld1r ? 1 : prev->reglist.num_regs)
* aarch64_get_qualifier_esize (prev->qualifier);
else
num_bytes = prev->reglist.num_regs
* aarch64_get_qualifier_esize (prev->qualifier)
* aarch64_get_qualifier_nelem (prev->qualifier);
if ((int) num_bytes != opnd->addr.offset.imm)
{
set_other_error (mismatch_detail, idx,
_("invalid post-increment amount"));
return 0;
}
}
break;
case AARCH64_OPND_ADDR_REGOFF:
/* Get the size of the data element that is accessed, which may be
different from that of the source register size,
e.g. in strb/ldrb. */
size = aarch64_get_qualifier_esize (opnd->qualifier);
/* It is either no shift or shift by the binary logarithm of SIZE. */
if (opnd->shifter.amount != 0
&& opnd->shifter.amount != (int)get_logsz (size))
{
set_other_error (mismatch_detail, idx,
_("invalid shift amount"));
return 0;
}
/* Only UXTW, LSL, SXTW and SXTX are the accepted extending
operators. */
switch (opnd->shifter.kind)
{
case AARCH64_MOD_UXTW:
case AARCH64_MOD_LSL:
case AARCH64_MOD_SXTW:
case AARCH64_MOD_SXTX: break;
default:
set_other_error (mismatch_detail, idx,
_("invalid extend/shift operator"));
return 0;
}
break;
case AARCH64_OPND_ADDR_UIMM12:
imm = opnd->addr.offset.imm;
/* Get the size of the data element that is accessed, which may be
different from that of the source register size,
e.g. in strb/ldrb. */
size = aarch64_get_qualifier_esize (qualifier);
if (!value_in_range_p (opnd->addr.offset.imm, 0, 4095 * size))
{
set_offset_out_of_range_error (mismatch_detail, idx,
0, 4095 * size);
return 0;
}
if (!value_aligned_p (opnd->addr.offset.imm, size))
{
set_unaligned_error (mismatch_detail, idx, size);
return 0;
}
break;
case AARCH64_OPND_ADDR_PCREL14:
case AARCH64_OPND_ADDR_PCREL19:
case AARCH64_OPND_ADDR_PCREL21:
case AARCH64_OPND_ADDR_PCREL26:
imm = opnd->imm.value;
if (operand_need_shift_by_two (get_operand_from_code (type)))
{
/* The offset value in a PC-relative branch instruction is alway
4-byte aligned and is encoded without the lowest 2 bits. */
if (!value_aligned_p (imm, 4))
{
set_unaligned_error (mismatch_detail, idx, 4);
return 0;
}
/* Right shift by 2 so that we can carry out the following check
canonically. */
imm >>= 2;
}
size = get_operand_fields_width (get_operand_from_code (type));
if (!value_fit_signed_field_p (imm, size))
{
set_other_error (mismatch_detail, idx,
_("immediate out of range"));
return 0;
}
break;
case AARCH64_OPND_SVE_ADDR_RI_S4xVL:
case AARCH64_OPND_SVE_ADDR_RI_S4x2xVL:
case AARCH64_OPND_SVE_ADDR_RI_S4x3xVL:
case AARCH64_OPND_SVE_ADDR_RI_S4x4xVL:
min_value = -8;
max_value = 7;
sve_imm_offset_vl:
assert (!opnd->addr.offset.is_reg);
assert (opnd->addr.preind);
num = 1 + get_operand_specific_data (&aarch64_operands[type]);
min_value *= num;
max_value *= num;
if ((opnd->addr.offset.imm != 0 && !opnd->shifter.operator_present)
|| (opnd->shifter.operator_present
&& opnd->shifter.kind != AARCH64_MOD_MUL_VL))
{
set_other_error (mismatch_detail, idx,
_("invalid addressing mode"));
return 0;
}
if (!value_in_range_p (opnd->addr.offset.imm, min_value, max_value))
{
set_offset_out_of_range_error (mismatch_detail, idx,
min_value, max_value);
return 0;
}
if (!value_aligned_p (opnd->addr.offset.imm, num))
{
set_unaligned_error (mismatch_detail, idx, num);
return 0;
}
break;
case AARCH64_OPND_SVE_ADDR_RI_S6xVL:
min_value = -32;
max_value = 31;
goto sve_imm_offset_vl;
case AARCH64_OPND_SVE_ADDR_RI_S9xVL:
min_value = -256;
max_value = 255;
goto sve_imm_offset_vl;
case AARCH64_OPND_SVE_ADDR_RI_U6:
case AARCH64_OPND_SVE_ADDR_RI_U6x2:
case AARCH64_OPND_SVE_ADDR_RI_U6x4:
case AARCH64_OPND_SVE_ADDR_RI_U6x8:
min_value = 0;
max_value = 63;
sve_imm_offset:
assert (!opnd->addr.offset.is_reg);
assert (opnd->addr.preind);
num = 1 << get_operand_specific_data (&aarch64_operands[type]);
min_value *= num;
max_value *= num;
if (opnd->shifter.operator_present
|| opnd->shifter.amount_present)
{
set_other_error (mismatch_detail, idx,
_("invalid addressing mode"));
return 0;
}
if (!value_in_range_p (opnd->addr.offset.imm, min_value, max_value))
{
set_offset_out_of_range_error (mismatch_detail, idx,
min_value, max_value);
return 0;
}
if (!value_aligned_p (opnd->addr.offset.imm, num))
{
set_unaligned_error (mismatch_detail, idx, num);
return 0;
}
break;
case AARCH64_OPND_SVE_ADDR_RI_S4x16:
case AARCH64_OPND_SVE_ADDR_RI_S4x32:
min_value = -8;
max_value = 7;
goto sve_imm_offset;
case AARCH64_OPND_SVE_ADDR_ZX:
/* Everything is already ensured by parse_operands or
aarch64_ext_sve_addr_rr_lsl (because this is a very specific
argument type). */
assert (opnd->addr.offset.is_reg);
assert (opnd->addr.preind);
assert ((aarch64_operands[type].flags & OPD_F_NO_ZR) == 0);
assert (opnd->shifter.kind == AARCH64_MOD_LSL);
assert (opnd->shifter.operator_present == 0);
break;
case AARCH64_OPND_SVE_ADDR_R:
case AARCH64_OPND_SVE_ADDR_RR:
case AARCH64_OPND_SVE_ADDR_RR_LSL1:
case AARCH64_OPND_SVE_ADDR_RR_LSL2:
case AARCH64_OPND_SVE_ADDR_RR_LSL3:
case AARCH64_OPND_SVE_ADDR_RX:
case AARCH64_OPND_SVE_ADDR_RX_LSL1:
case AARCH64_OPND_SVE_ADDR_RX_LSL2:
case AARCH64_OPND_SVE_ADDR_RX_LSL3:
case AARCH64_OPND_SVE_ADDR_RZ:
case AARCH64_OPND_SVE_ADDR_RZ_LSL1:
case AARCH64_OPND_SVE_ADDR_RZ_LSL2:
case AARCH64_OPND_SVE_ADDR_RZ_LSL3:
modifiers = 1 << AARCH64_MOD_LSL;
sve_rr_operand:
assert (opnd->addr.offset.is_reg);
assert (opnd->addr.preind);
if ((aarch64_operands[type].flags & OPD_F_NO_ZR) != 0
&& opnd->addr.offset.regno == 31)
{
set_other_error (mismatch_detail, idx,
_("index register xzr is not allowed"));
return 0;
}
if (((1 << opnd->shifter.kind) & modifiers) == 0
|| (opnd->shifter.amount
!= get_operand_specific_data (&aarch64_operands[type])))
{
set_other_error (mismatch_detail, idx,
_("invalid addressing mode"));
return 0;
}
break;
case AARCH64_OPND_SVE_ADDR_RZ_XTW_14:
case AARCH64_OPND_SVE_ADDR_RZ_XTW_22:
case AARCH64_OPND_SVE_ADDR_RZ_XTW1_14:
case AARCH64_OPND_SVE_ADDR_RZ_XTW1_22:
case AARCH64_OPND_SVE_ADDR_RZ_XTW2_14:
case AARCH64_OPND_SVE_ADDR_RZ_XTW2_22:
case AARCH64_OPND_SVE_ADDR_RZ_XTW3_14:
case AARCH64_OPND_SVE_ADDR_RZ_XTW3_22:
modifiers = (1 << AARCH64_MOD_SXTW) | (1 << AARCH64_MOD_UXTW);
goto sve_rr_operand;
case AARCH64_OPND_SVE_ADDR_ZI_U5:
case AARCH64_OPND_SVE_ADDR_ZI_U5x2:
case AARCH64_OPND_SVE_ADDR_ZI_U5x4:
case AARCH64_OPND_SVE_ADDR_ZI_U5x8:
min_value = 0;
max_value = 31;
goto sve_imm_offset;
case AARCH64_OPND_SVE_ADDR_ZZ_LSL:
modifiers = 1 << AARCH64_MOD_LSL;
sve_zz_operand:
assert (opnd->addr.offset.is_reg);
assert (opnd->addr.preind);
if (((1 << opnd->shifter.kind) & modifiers) == 0
|| opnd->shifter.amount < 0
|| opnd->shifter.amount > 3)
{
set_other_error (mismatch_detail, idx,
_("invalid addressing mode"));
return 0;
}
break;
case AARCH64_OPND_SVE_ADDR_ZZ_SXTW:
modifiers = (1 << AARCH64_MOD_SXTW);
goto sve_zz_operand;
case AARCH64_OPND_SVE_ADDR_ZZ_UXTW:
modifiers = 1 << AARCH64_MOD_UXTW;
goto sve_zz_operand;
default:
break;
}
break;
case AARCH64_OPND_CLASS_SIMD_REGLIST:
if (type == AARCH64_OPND_LEt)
{
/* Get the upper bound for the element index. */
num = 16 / aarch64_get_qualifier_esize (qualifier) - 1;
if (!value_in_range_p (opnd->reglist.index, 0, num))
{
set_elem_idx_out_of_range_error (mismatch_detail, idx, 0, num);
return 0;
}
}
/* The opcode dependent area stores the number of elements in
each structure to be loaded/stored. */
num = get_opcode_dependent_value (opcode);
switch (type)
{
case AARCH64_OPND_LVt:
assert (num >= 1 && num <= 4);
/* Unless LD1/ST1, the number of registers should be equal to that
of the structure elements. */
if (num != 1 && opnd->reglist.num_regs != num)
{
set_reg_list_error (mismatch_detail, idx, num);
return 0;
}
break;
case AARCH64_OPND_LVt_AL:
case AARCH64_OPND_LEt:
assert (num >= 1 && num <= 4);
/* The number of registers should be equal to that of the structure
elements. */
if (opnd->reglist.num_regs != num)
{
set_reg_list_error (mismatch_detail, idx, num);
return 0;
}
break;
default:
break;
}
break;
case AARCH64_OPND_CLASS_IMMEDIATE:
/* Constraint check on immediate operand. */
imm = opnd->imm.value;
/* E.g. imm_0_31 constrains value to be 0..31. */
if (qualifier_value_in_range_constraint_p (qualifier)
&& !value_in_range_p (imm, get_lower_bound (qualifier),
get_upper_bound (qualifier)))
{
set_imm_out_of_range_error (mismatch_detail, idx,
get_lower_bound (qualifier),
get_upper_bound (qualifier));
return 0;
}
switch (type)
{
case AARCH64_OPND_AIMM:
if (opnd->shifter.kind != AARCH64_MOD_LSL)
{
set_other_error (mismatch_detail, idx,
_("invalid shift operator"));
return 0;
}
if (opnd->shifter.amount != 0 && opnd->shifter.amount != 12)
{
set_other_error (mismatch_detail, idx,
_("shift amount must be 0 or 12"));
return 0;
}
if (!value_fit_unsigned_field_p (opnd->imm.value, 12))
{
set_other_error (mismatch_detail, idx,
_("immediate out of range"));
return 0;
}
break;
case AARCH64_OPND_HALF:
assert (idx == 1 && opnds[0].type == AARCH64_OPND_Rd);
if (opnd->shifter.kind != AARCH64_MOD_LSL)
{
set_other_error (mismatch_detail, idx,
_("invalid shift operator"));
return 0;
}
size = aarch64_get_qualifier_esize (opnds[0].qualifier);
if (!value_aligned_p (opnd->shifter.amount, 16))
{
set_other_error (mismatch_detail, idx,
_("shift amount must be a multiple of 16"));
return 0;
}
if (!value_in_range_p (opnd->shifter.amount, 0, size * 8 - 16))
{
set_sft_amount_out_of_range_error (mismatch_detail, idx,
0, size * 8 - 16);
return 0;
}
if (opnd->imm.value < 0)
{
set_other_error (mismatch_detail, idx,
_("negative immediate value not allowed"));
return 0;
}
if (!value_fit_unsigned_field_p (opnd->imm.value, 16))
{
set_other_error (mismatch_detail, idx,
_("immediate out of range"));
return 0;
}
break;
case AARCH64_OPND_IMM_MOV:
{
int esize = aarch64_get_qualifier_esize (opnds[0].qualifier);
imm = opnd->imm.value;
assert (idx == 1);
switch (opcode->op)
{
case OP_MOV_IMM_WIDEN:
imm = ~imm;
/* Fall through. */
case OP_MOV_IMM_WIDE:
if (!aarch64_wide_constant_p (imm, esize == 4, NULL))
{
set_other_error (mismatch_detail, idx,
_("immediate out of range"));
return 0;
}
break;
case OP_MOV_IMM_LOG:
if (!aarch64_logical_immediate_p (imm, esize, NULL))
{
set_other_error (mismatch_detail, idx,
_("immediate out of range"));
return 0;
}
break;
default:
assert (0);
return 0;
}
}
break;
case AARCH64_OPND_NZCV:
case AARCH64_OPND_CCMP_IMM:
case AARCH64_OPND_EXCEPTION:
case AARCH64_OPND_UNDEFINED:
case AARCH64_OPND_TME_UIMM16:
case AARCH64_OPND_UIMM4:
case AARCH64_OPND_UIMM4_ADDG:
case AARCH64_OPND_UIMM7:
case AARCH64_OPND_UIMM3_OP1:
case AARCH64_OPND_UIMM3_OP2:
case AARCH64_OPND_SVE_UIMM3:
case AARCH64_OPND_SVE_UIMM7:
case AARCH64_OPND_SVE_UIMM8:
case AARCH64_OPND_SVE_UIMM8_53:
size = get_operand_fields_width (get_operand_from_code (type));
assert (size < 32);
if (!value_fit_unsigned_field_p (opnd->imm.value, size))
{
set_imm_out_of_range_error (mismatch_detail, idx, 0,
(1u << size) - 1);
return 0;
}
break;
case AARCH64_OPND_UIMM10:
/* Scaled unsigned 10 bits immediate offset. */
if (!value_in_range_p (opnd->imm.value, 0, 1008))
{
set_imm_out_of_range_error (mismatch_detail, idx, 0, 1008);
return 0;
}
if (!value_aligned_p (opnd->imm.value, 16))
{
set_unaligned_error (mismatch_detail, idx, 16);
return 0;
}
break;
case AARCH64_OPND_SIMM5:
case AARCH64_OPND_SVE_SIMM5:
case AARCH64_OPND_SVE_SIMM5B:
case AARCH64_OPND_SVE_SIMM6:
case AARCH64_OPND_SVE_SIMM8:
size = get_operand_fields_width (get_operand_from_code (type));
assert (size < 32);
if (!value_fit_signed_field_p (opnd->imm.value, size))
{
set_imm_out_of_range_error (mismatch_detail, idx,
-(1 << (size - 1)),
(1 << (size - 1)) - 1);
return 0;
}
break;
case AARCH64_OPND_WIDTH:
assert (idx > 1 && opnds[idx-1].type == AARCH64_OPND_IMM
&& opnds[0].type == AARCH64_OPND_Rd);
size = get_upper_bound (qualifier);
if (opnd->imm.value + opnds[idx-1].imm.value > size)
/* lsb+width <= reg.size */
{
set_imm_out_of_range_error (mismatch_detail, idx, 1,
size - opnds[idx-1].imm.value);
return 0;
}
break;
case AARCH64_OPND_LIMM:
case AARCH64_OPND_SVE_LIMM:
{
int esize = aarch64_get_qualifier_esize (opnds[0].qualifier);
uint64_t uimm = opnd->imm.value;
if (opcode->op == OP_BIC)
uimm = ~uimm;
if (!aarch64_logical_immediate_p (uimm, esize, NULL))
{
set_other_error (mismatch_detail, idx,
_("immediate out of range"));
return 0;
}
}
break;
case AARCH64_OPND_IMM0:
case AARCH64_OPND_FPIMM0:
if (opnd->imm.value != 0)
{
set_other_error (mismatch_detail, idx,
_("immediate zero expected"));
return 0;
}
break;
case AARCH64_OPND_IMM_ROT1:
case AARCH64_OPND_IMM_ROT2:
case AARCH64_OPND_SVE_IMM_ROT2:
if (opnd->imm.value != 0
&& opnd->imm.value != 90
&& opnd->imm.value != 180
&& opnd->imm.value != 270)
{
set_other_error (mismatch_detail, idx,
_("rotate expected to be 0, 90, 180 or 270"));
return 0;
}
break;
case AARCH64_OPND_IMM_ROT3:
case AARCH64_OPND_SVE_IMM_ROT1:
case AARCH64_OPND_SVE_IMM_ROT3:
if (opnd->imm.value != 90 && opnd->imm.value != 270)
{
set_other_error (mismatch_detail, idx,
_("rotate expected to be 90 or 270"));
return 0;
}
break;
case AARCH64_OPND_SHLL_IMM:
assert (idx == 2);
size = 8 * aarch64_get_qualifier_esize (opnds[idx - 1].qualifier);
if (opnd->imm.value != size)
{
set_other_error (mismatch_detail, idx,
_("invalid shift amount"));
return 0;
}
break;
case AARCH64_OPND_IMM_VLSL:
size = aarch64_get_qualifier_esize (qualifier);
if (!value_in_range_p (opnd->imm.value, 0, size * 8 - 1))
{
set_imm_out_of_range_error (mismatch_detail, idx, 0,
size * 8 - 1);
return 0;
}
break;
case AARCH64_OPND_IMM_VLSR:
size = aarch64_get_qualifier_esize (qualifier);
if (!value_in_range_p (opnd->imm.value, 1, size * 8))
{
set_imm_out_of_range_error (mismatch_detail, idx, 1, size * 8);
return 0;
}
break;
case AARCH64_OPND_SIMD_IMM:
case AARCH64_OPND_SIMD_IMM_SFT:
/* Qualifier check. */
switch (qualifier)
{
case AARCH64_OPND_QLF_LSL:
if (opnd->shifter.kind != AARCH64_MOD_LSL)
{
set_other_error (mismatch_detail, idx,
_("invalid shift operator"));
return 0;
}
break;
case AARCH64_OPND_QLF_MSL:
if (opnd->shifter.kind != AARCH64_MOD_MSL)
{
set_other_error (mismatch_detail, idx,
_("invalid shift operator"));
return 0;
}
break;
case AARCH64_OPND_QLF_NIL:
if (opnd->shifter.kind != AARCH64_MOD_NONE)
{
set_other_error (mismatch_detail, idx,
_("shift is not permitted"));
return 0;
}
break;
default:
assert (0);
return 0;
}
/* Is the immediate valid? */
assert (idx == 1);
if (aarch64_get_qualifier_esize (opnds[0].qualifier) != 8)
{
/* uimm8 or simm8 */
if (!value_in_range_p (opnd->imm.value, -128, 255))
{
set_imm_out_of_range_error (mismatch_detail, idx, -128, 255);
return 0;
}
}
else if (aarch64_shrink_expanded_imm8 (opnd->imm.value) < 0)
{
/* uimm64 is not
'aaaaaaaabbbbbbbbccccccccddddddddeeeeeeee
ffffffffgggggggghhhhhhhh'. */
set_other_error (mismatch_detail, idx,
_("invalid value for immediate"));
return 0;
}
/* Is the shift amount valid? */
switch (opnd->shifter.kind)
{
case AARCH64_MOD_LSL:
size = aarch64_get_qualifier_esize (opnds[0].qualifier);
if (!value_in_range_p (opnd->shifter.amount, 0, (size - 1) * 8))
{
set_sft_amount_out_of_range_error (mismatch_detail, idx, 0,
(size - 1) * 8);
return 0;
}
if (!value_aligned_p (opnd->shifter.amount, 8))
{
set_unaligned_error (mismatch_detail, idx, 8);
return 0;
}
break;
case AARCH64_MOD_MSL:
/* Only 8 and 16 are valid shift amount. */
if (opnd->shifter.amount != 8 && opnd->shifter.amount != 16)
{
set_other_error (mismatch_detail, idx,
_("shift amount must be 0 or 16"));
return 0;
}
break;
default:
if (opnd->shifter.kind != AARCH64_MOD_NONE)
{
set_other_error (mismatch_detail, idx,
_("invalid shift operator"));
return 0;
}
break;
}
break;
case AARCH64_OPND_FPIMM:
case AARCH64_OPND_SIMD_FPIMM:
case AARCH64_OPND_SVE_FPIMM8:
if (opnd->imm.is_fp == 0)
{
set_other_error (mismatch_detail, idx,
_("floating-point immediate expected"));
return 0;
}
/* The value is expected to be an 8-bit floating-point constant with
sign, 3-bit exponent and normalized 4 bits of precision, encoded
in "a:b:c:d:e:f:g:h" or FLD_imm8 (depending on the type of the
instruction). */
if (!value_in_range_p (opnd->imm.value, 0, 255))
{
set_other_error (mismatch_detail, idx,
_("immediate out of range"));
return 0;
}
if (opnd->shifter.kind != AARCH64_MOD_NONE)
{
set_other_error (mismatch_detail, idx,
_("invalid shift operator"));
return 0;
}
break;
case AARCH64_OPND_SVE_AIMM:
min_value = 0;
sve_aimm:
assert (opnd->shifter.kind == AARCH64_MOD_LSL);
size = aarch64_get_qualifier_esize (opnds[0].qualifier);
mask = ~((uint64_t) -1 << (size * 4) << (size * 4));
uvalue = opnd->imm.value;
shift = opnd->shifter.amount;
if (size == 1)
{
if (shift != 0)
{
set_other_error (mismatch_detail, idx,
_("no shift amount allowed for"
" 8-bit constants"));
return 0;
}
}
else
{
if (shift != 0 && shift != 8)
{
set_other_error (mismatch_detail, idx,
_("shift amount must be 0 or 8"));
return 0;
}
if (shift == 0 && (uvalue & 0xff) == 0)
{
shift = 8;
uvalue = (int64_t) uvalue / 256;
}
}
mask >>= shift;
if ((uvalue & mask) != uvalue && (uvalue | ~mask) != uvalue)
{
set_other_error (mismatch_detail, idx,
_("immediate too big for element size"));
return 0;
}
uvalue = (uvalue - min_value) & mask;
if (uvalue > 0xff)
{
set_other_error (mismatch_detail, idx,
_("invalid arithmetic immediate"));
return 0;
}
break;
case AARCH64_OPND_SVE_ASIMM:
min_value = -128;
goto sve_aimm;
case AARCH64_OPND_SVE_I1_HALF_ONE:
assert (opnd->imm.is_fp);
if (opnd->imm.value != 0x3f000000 && opnd->imm.value != 0x3f800000)
{
set_other_error (mismatch_detail, idx,
_("floating-point value must be 0.5 or 1.0"));
return 0;
}
break;
case AARCH64_OPND_SVE_I1_HALF_TWO:
assert (opnd->imm.is_fp);
if (opnd->imm.value != 0x3f000000 && opnd->imm.value != 0x40000000)
{
set_other_error (mismatch_detail, idx,
_("floating-point value must be 0.5 or 2.0"));
return 0;
}
break;
case AARCH64_OPND_SVE_I1_ZERO_ONE:
assert (opnd->imm.is_fp);
if (opnd->imm.value != 0 && opnd->imm.value != 0x3f800000)
{
set_other_error (mismatch_detail, idx,
_("floating-point value must be 0.0 or 1.0"));
return 0;
}
break;
case AARCH64_OPND_SVE_INV_LIMM:
{
int esize = aarch64_get_qualifier_esize (opnds[0].qualifier);
uint64_t uimm = ~opnd->imm.value;
if (!aarch64_logical_immediate_p (uimm, esize, NULL))
{
set_other_error (mismatch_detail, idx,
_("immediate out of range"));
return 0;
}
}
break;
case AARCH64_OPND_SVE_LIMM_MOV:
{
int esize = aarch64_get_qualifier_esize (opnds[0].qualifier);
uint64_t uimm = opnd->imm.value;
if (!aarch64_logical_immediate_p (uimm, esize, NULL))
{
set_other_error (mismatch_detail, idx,
_("immediate out of range"));
return 0;
}
if (!aarch64_sve_dupm_mov_immediate_p (uimm, esize))
{
set_other_error (mismatch_detail, idx,
_("invalid replicated MOV immediate"));
return 0;
}
}
break;
case AARCH64_OPND_SVE_PATTERN_SCALED:
assert (opnd->shifter.kind == AARCH64_MOD_MUL);
if (!value_in_range_p (opnd->shifter.amount, 1, 16))
{
set_multiplier_out_of_range_error (mismatch_detail, idx, 1, 16);
return 0;
}
break;
case AARCH64_OPND_SVE_SHLIMM_PRED:
case AARCH64_OPND_SVE_SHLIMM_UNPRED:
case AARCH64_OPND_SVE_SHLIMM_UNPRED_22:
size = aarch64_get_qualifier_esize (opnds[idx - 1].qualifier);
if (!value_in_range_p (opnd->imm.value, 0, 8 * size - 1))
{
set_imm_out_of_range_error (mismatch_detail, idx,
0, 8 * size - 1);
return 0;
}
break;
case AARCH64_OPND_SVE_SHRIMM_PRED:
case AARCH64_OPND_SVE_SHRIMM_UNPRED:
case AARCH64_OPND_SVE_SHRIMM_UNPRED_22:
num = (type == AARCH64_OPND_SVE_SHRIMM_UNPRED_22) ? 2 : 1;
size = aarch64_get_qualifier_esize (opnds[idx - num].qualifier);
if (!value_in_range_p (opnd->imm.value, 1, 8 * size))
{
set_imm_out_of_range_error (mismatch_detail, idx, 1, 8*size);
return 0;
}
break;
default:
break;
}
break;
case AARCH64_OPND_CLASS_SYSTEM:
switch (type)
{
case AARCH64_OPND_PSTATEFIELD:
assert (idx == 0 && opnds[1].type == AARCH64_OPND_UIMM4);
/* MSR UAO, #uimm4
MSR PAN, #uimm4
MSR SSBS,#uimm4
The immediate must be #0 or #1. */
if ((opnd->pstatefield == 0x03 /* UAO. */
|| opnd->pstatefield == 0x04 /* PAN. */
|| opnd->pstatefield == 0x19 /* SSBS. */
|| opnd->pstatefield == 0x1a) /* DIT. */
&& opnds[1].imm.value > 1)
{
set_imm_out_of_range_error (mismatch_detail, idx, 0, 1);
return 0;
}
/* MSR SPSel, #uimm4
Uses uimm4 as a control value to select the stack pointer: if
bit 0 is set it selects the current exception level's stack
pointer, if bit 0 is clear it selects shared EL0 stack pointer.
Bits 1 to 3 of uimm4 are reserved and should be zero. */
if (opnd->pstatefield == 0x05 /* spsel */ && opnds[1].imm.value > 1)
{
set_imm_out_of_range_error (mismatch_detail, idx, 0, 1);
return 0;
}
break;
default:
break;
}
break;
case AARCH64_OPND_CLASS_SIMD_ELEMENT:
/* Get the upper bound for the element index. */
if (opcode->op == OP_FCMLA_ELEM)
/* FCMLA index range depends on the vector size of other operands
and is halfed because complex numbers take two elements. */
num = aarch64_get_qualifier_nelem (opnds[0].qualifier)
* aarch64_get_qualifier_esize (opnds[0].qualifier) / 2;
else
num = 16;
num = num / aarch64_get_qualifier_esize (qualifier) - 1;
assert (aarch64_get_qualifier_nelem (qualifier) == 1);
/* Index out-of-range. */
if (!value_in_range_p (opnd->reglane.index, 0, num))
{
set_elem_idx_out_of_range_error (mismatch_detail, idx, 0, num);
return 0;
}
/* SMLAL ., ., .[].
Is the vector register (V0-V31) or (V0-V15), whose
number is encoded in "size:M:Rm":
size
00 RESERVED
01 0:Rm
10 M:Rm
11 RESERVED */
if (type == AARCH64_OPND_Em16 && qualifier == AARCH64_OPND_QLF_S_H
&& !value_in_range_p (opnd->reglane.regno, 0, 15))
{
set_regno_out_of_range_error (mismatch_detail, idx, 0, 15);
return 0;
}
break;
case AARCH64_OPND_CLASS_MODIFIED_REG:
assert (idx == 1 || idx == 2);
switch (type)
{
case AARCH64_OPND_Rm_EXT:
if (!aarch64_extend_operator_p (opnd->shifter.kind)
&& opnd->shifter.kind != AARCH64_MOD_LSL)
{
set_other_error (mismatch_detail, idx,
_("extend operator expected"));
return 0;
}
/* It is not optional unless at least one of "Rd" or "Rn" is '11111'
(i.e. SP), in which case it defaults to LSL. The LSL alias is
only valid when "Rd" or "Rn" is '11111', and is preferred in that
case. */
if (!aarch64_stack_pointer_p (opnds + 0)
&& (idx != 2 || !aarch64_stack_pointer_p (opnds + 1)))
{
if (!opnd->shifter.operator_present)
{
set_other_error (mismatch_detail, idx,
_("missing extend operator"));
return 0;
}
else if (opnd->shifter.kind == AARCH64_MOD_LSL)
{
set_other_error (mismatch_detail, idx,
_("'LSL' operator not allowed"));
return 0;
}
}
assert (opnd->shifter.operator_present /* Default to LSL. */
|| opnd->shifter.kind == AARCH64_MOD_LSL);
if (!value_in_range_p (opnd->shifter.amount, 0, 4))
{
set_sft_amount_out_of_range_error (mismatch_detail, idx, 0, 4);
return 0;
}
/* In the 64-bit form, the final register operand is written as Wm
for all but the (possibly omitted) UXTX/LSL and SXTX
operators.
N.B. GAS allows X register to be used with any operator as a
programming convenience. */
if (qualifier == AARCH64_OPND_QLF_X
&& opnd->shifter.kind != AARCH64_MOD_LSL
&& opnd->shifter.kind != AARCH64_MOD_UXTX
&& opnd->shifter.kind != AARCH64_MOD_SXTX)
{
set_other_error (mismatch_detail, idx, _("W register expected"));
return 0;
}
break;
case AARCH64_OPND_Rm_SFT:
/* ROR is not available to the shifted register operand in
arithmetic instructions. */
if (!aarch64_shift_operator_p (opnd->shifter.kind))
{
set_other_error (mismatch_detail, idx,
_("shift operator expected"));
return 0;
}
if (opnd->shifter.kind == AARCH64_MOD_ROR
&& opcode->iclass != log_shift)
{
set_other_error (mismatch_detail, idx,
_("'ROR' operator not allowed"));
return 0;
}
num = qualifier == AARCH64_OPND_QLF_W ? 31 : 63;
if (!value_in_range_p (opnd->shifter.amount, 0, num))
{
set_sft_amount_out_of_range_error (mismatch_detail, idx, 0, num);
return 0;
}
break;
default:
break;
}
break;
default:
break;
}
return 1;
}
/* Main entrypoint for the operand constraint checking.
Return 1 if operands of *INST meet the constraint applied by the operand
codes and operand qualifiers; otherwise return 0 and if MISMATCH_DETAIL is
not NULL, return the detail of the error in *MISMATCH_DETAIL. N.B. when
adding more constraint checking, make sure MISMATCH_DETAIL->KIND is set
with a proper error kind rather than AARCH64_OPDE_NIL (GAS asserts non-NIL
error kind when it is notified that an instruction does not pass the check).
Un-determined operand qualifiers may get established during the process. */
int
aarch64_match_operands_constraint (aarch64_inst *inst,
aarch64_operand_error *mismatch_detail)
{
int i;
DEBUG_TRACE ("enter");
/* Check for cases where a source register needs to be the same as the
destination register. Do this before matching qualifiers since if
an instruction has both invalid tying and invalid qualifiers,
the error about qualifiers would suggest several alternative
instructions that also have invalid tying. */
i = inst->opcode->tied_operand;
if (i > 0 && (inst->operands[0].reg.regno != inst->operands[i].reg.regno))
{
if (mismatch_detail)
{
mismatch_detail->kind = AARCH64_OPDE_UNTIED_OPERAND;
mismatch_detail->index = i;
mismatch_detail->error = NULL;
}
return 0;
}
/* Match operands' qualifier.
*INST has already had qualifier establish for some, if not all, of
its operands; we need to find out whether these established
qualifiers match one of the qualifier sequence in
INST->OPCODE->QUALIFIERS_LIST. If yes, we will assign each operand
with the corresponding qualifier in such a sequence.
Only basic operand constraint checking is done here; the more thorough
constraint checking will carried out by operand_general_constraint_met_p,
which has be to called after this in order to get all of the operands'
qualifiers established. */
if (match_operands_qualifier (inst, TRUE /* update_p */) == 0)
{
DEBUG_TRACE ("FAIL on operand qualifier matching");
if (mismatch_detail)
{
/* Return an error type to indicate that it is the qualifier
matching failure; we don't care about which operand as there
are enough information in the opcode table to reproduce it. */
mismatch_detail->kind = AARCH64_OPDE_INVALID_VARIANT;
mismatch_detail->index = -1;
mismatch_detail->error = NULL;
}
return 0;
}
/* Match operands' constraint. */
for (i = 0; i < AARCH64_MAX_OPND_NUM; ++i)
{
enum aarch64_opnd type = inst->opcode->operands[i];
if (type == AARCH64_OPND_NIL)
break;
if (inst->operands[i].skip)
{
DEBUG_TRACE ("skip the incomplete operand %d", i);
continue;
}
if (operand_general_constraint_met_p (inst->operands, i, type,
inst->opcode, mismatch_detail) == 0)
{
DEBUG_TRACE ("FAIL on operand %d", i);
return 0;
}
}
DEBUG_TRACE ("PASS");
return 1;
}
/* Replace INST->OPCODE with OPCODE and return the replaced OPCODE.
Also updates the TYPE of each INST->OPERANDS with the corresponding
value of OPCODE->OPERANDS.
Note that some operand qualifiers may need to be manually cleared by
the caller before it further calls the aarch64_opcode_encode; by
doing this, it helps the qualifier matching facilities work
properly. */
const aarch64_opcode*
aarch64_replace_opcode (aarch64_inst *inst, const aarch64_opcode *opcode)
{
int i;
const aarch64_opcode *old = inst->opcode;
inst->opcode = opcode;
/* Update the operand types. */
for (i = 0; i < AARCH64_MAX_OPND_NUM; ++i)
{
inst->operands[i].type = opcode->operands[i];
if (opcode->operands[i] == AARCH64_OPND_NIL)
break;
}
DEBUG_TRACE ("replace %s with %s", old->name, opcode->name);
return old;
}
int
aarch64_operand_index (const enum aarch64_opnd *operands, enum aarch64_opnd operand)
{
int i;
for (i = 0; i < AARCH64_MAX_OPND_NUM; ++i)
if (operands[i] == operand)
return i;
else if (operands[i] == AARCH64_OPND_NIL)
break;
return -1;
}
/* R0...R30, followed by FOR31. */
#define BANK(R, FOR31) \
{ R (0), R (1), R (2), R (3), R (4), R (5), R (6), R (7), \
R (8), R (9), R (10), R (11), R (12), R (13), R (14), R (15), \
R (16), R (17), R (18), R (19), R (20), R (21), R (22), R (23), \
R (24), R (25), R (26), R (27), R (28), R (29), R (30), FOR31 }
/* [0][0] 32-bit integer regs with sp Wn
[0][1] 64-bit integer regs with sp Xn sf=1
[1][0] 32-bit integer regs with #0 Wn
[1][1] 64-bit integer regs with #0 Xn sf=1 */
static const char *int_reg[2][2][32] = {
#define R32(X) "w" #X
#define R64(X) "x" #X
{ BANK (R32, "wsp"), BANK (R64, "sp") },
{ BANK (R32, "wzr"), BANK (R64, "xzr") }
#undef R64
#undef R32
};
/* Names of the SVE vector registers, first with .S suffixes,
then with .D suffixes. */
static const char *sve_reg[2][32] = {
#define ZS(X) "z" #X ".s"
#define ZD(X) "z" #X ".d"
BANK (ZS, ZS (31)), BANK (ZD, ZD (31))
#undef ZD
#undef ZS
};
#undef BANK
/* Return the integer register name.
if SP_REG_P is not 0, R31 is an SP reg, other R31 is the zero reg. */
static inline const char *
get_int_reg_name (int regno, aarch64_opnd_qualifier_t qualifier, int sp_reg_p)
{
const int has_zr = sp_reg_p ? 0 : 1;
const int is_64 = aarch64_get_qualifier_esize (qualifier) == 4 ? 0 : 1;
return int_reg[has_zr][is_64][regno];
}
/* Like get_int_reg_name, but IS_64 is always 1. */
static inline const char *
get_64bit_int_reg_name (int regno, int sp_reg_p)
{
const int has_zr = sp_reg_p ? 0 : 1;
return int_reg[has_zr][1][regno];
}
/* Get the name of the integer offset register in OPND, using the shift type
to decide whether it's a word or doubleword. */
static inline const char *
get_offset_int_reg_name (const aarch64_opnd_info *opnd)
{
switch (opnd->shifter.kind)
{
case AARCH64_MOD_UXTW:
case AARCH64_MOD_SXTW:
return get_int_reg_name (opnd->addr.offset.regno, AARCH64_OPND_QLF_W, 0);
case AARCH64_MOD_LSL:
case AARCH64_MOD_SXTX:
return get_int_reg_name (opnd->addr.offset.regno, AARCH64_OPND_QLF_X, 0);
default:
abort ();
}
}
/* Get the name of the SVE vector offset register in OPND, using the operand
qualifier to decide whether the suffix should be .S or .D. */
static inline const char *
get_addr_sve_reg_name (int regno, aarch64_opnd_qualifier_t qualifier)
{
assert (qualifier == AARCH64_OPND_QLF_S_S
|| qualifier == AARCH64_OPND_QLF_S_D);
return sve_reg[qualifier == AARCH64_OPND_QLF_S_D][regno];
}
/* Types for expanding an encoded 8-bit value to a floating-point value. */
typedef union
{
uint64_t i;
double d;
} double_conv_t;
typedef union
{
uint32_t i;
float f;
} single_conv_t;
typedef union
{
uint32_t i;
float f;
} half_conv_t;
/* IMM8 is an 8-bit floating-point constant with sign, 3-bit exponent and
normalized 4 bits of precision, encoded in "a:b:c:d:e:f:g:h" or FLD_imm8
(depending on the type of the instruction). IMM8 will be expanded to a
single-precision floating-point value (SIZE == 4) or a double-precision
floating-point value (SIZE == 8). A half-precision floating-point value
(SIZE == 2) is expanded to a single-precision floating-point value. The
expanded value is returned. */
static uint64_t
expand_fp_imm (int size, uint32_t imm8)
{
uint64_t imm = 0;
uint32_t imm8_7, imm8_6_0, imm8_6, imm8_6_repl4;
imm8_7 = (imm8 >> 7) & 0x01; /* imm8<7> */
imm8_6_0 = imm8 & 0x7f; /* imm8<6:0> */
imm8_6 = imm8_6_0 >> 6; /* imm8<6> */
imm8_6_repl4 = (imm8_6 << 3) | (imm8_6 << 2)
| (imm8_6 << 1) | imm8_6; /* Replicate(imm8<6>,4) */
if (size == 8)
{
imm = (imm8_7 << (63-32)) /* imm8<7> */
| ((imm8_6 ^ 1) << (62-32)) /* NOT(imm8<6) */
| (imm8_6_repl4 << (58-32)) | (imm8_6 << (57-32))
| (imm8_6 << (56-32)) | (imm8_6 << (55-32)) /* Replicate(imm8<6>,7) */
| (imm8_6_0 << (48-32)); /* imm8<6>:imm8<5:0> */
imm <<= 32;
}
else if (size == 4 || size == 2)
{
imm = (imm8_7 << 31) /* imm8<7> */
| ((imm8_6 ^ 1) << 30) /* NOT(imm8<6>) */
| (imm8_6_repl4 << 26) /* Replicate(imm8<6>,4) */
| (imm8_6_0 << 19); /* imm8<6>:imm8<5:0> */
}
else
{
/* An unsupported size. */
assert (0);
}
return imm;
}
/* Produce the string representation of the register list operand *OPND
in the buffer pointed by BUF of size SIZE. PREFIX is the part of
the register name that comes before the register number, such as "v". */
static void
print_register_list (char *buf, size_t size, const aarch64_opnd_info *opnd,
const char *prefix)
{
const int num_regs = opnd->reglist.num_regs;
const int first_reg = opnd->reglist.first_regno;
const int last_reg = (first_reg + num_regs - 1) & 0x1f;
const char *qlf_name = aarch64_get_qualifier_name (opnd->qualifier);
char tb[8]; /* Temporary buffer. */
assert (opnd->type != AARCH64_OPND_LEt || opnd->reglist.has_index);
assert (num_regs >= 1 && num_regs <= 4);
/* Prepare the index if any. */
if (opnd->reglist.has_index)
/* PR 21096: The %100 is to silence a warning about possible truncation. */
snprintf (tb, 8, "[%" PRIi64 "]", (opnd->reglist.index % 100));
else
tb[0] = '\0';
/* The hyphenated form is preferred for disassembly if there are
more than two registers in the list, and the register numbers
are monotonically increasing in increments of one. */
if (num_regs > 2 && last_reg > first_reg)
snprintf (buf, size, "{%s%d.%s-%s%d.%s}%s", prefix, first_reg, qlf_name,
prefix, last_reg, qlf_name, tb);
else
{
const int reg0 = first_reg;
const int reg1 = (first_reg + 1) & 0x1f;
const int reg2 = (first_reg + 2) & 0x1f;
const int reg3 = (first_reg + 3) & 0x1f;
switch (num_regs)
{
case 1:
snprintf (buf, size, "{%s%d.%s}%s", prefix, reg0, qlf_name, tb);
break;
case 2:
snprintf (buf, size, "{%s%d.%s, %s%d.%s}%s", prefix, reg0, qlf_name,
prefix, reg1, qlf_name, tb);
break;
case 3:
snprintf (buf, size, "{%s%d.%s, %s%d.%s, %s%d.%s}%s",
prefix, reg0, qlf_name, prefix, reg1, qlf_name,
prefix, reg2, qlf_name, tb);
break;
case 4:
snprintf (buf, size, "{%s%d.%s, %s%d.%s, %s%d.%s, %s%d.%s}%s",
prefix, reg0, qlf_name, prefix, reg1, qlf_name,
prefix, reg2, qlf_name, prefix, reg3, qlf_name, tb);
break;
}
}
}
/* Print the register+immediate address in OPND to BUF, which has SIZE
characters. BASE is the name of the base register. */
static void
print_immediate_offset_address (char *buf, size_t size,
const aarch64_opnd_info *opnd,
const char *base)
{
if (opnd->addr.writeback)
{
if (opnd->addr.preind)
{
if (opnd->type == AARCH64_OPND_ADDR_SIMM10 && !opnd->addr.offset.imm)
snprintf (buf, size, "[%s]!", base);
else
snprintf (buf, size, "[%s, #%d]!", base, opnd->addr.offset.imm);
}
else
snprintf (buf, size, "[%s], #%d", base, opnd->addr.offset.imm);
}
else
{
if (opnd->shifter.operator_present)
{
assert (opnd->shifter.kind == AARCH64_MOD_MUL_VL);
snprintf (buf, size, "[%s, #%d, mul vl]",
base, opnd->addr.offset.imm);
}
else if (opnd->addr.offset.imm)
snprintf (buf, size, "[%s, #%d]", base, opnd->addr.offset.imm);
else
snprintf (buf, size, "[%s]", base);
}
}
/* Produce the string representation of the register offset address operand
*OPND in the buffer pointed by BUF of size SIZE. BASE and OFFSET are
the names of the base and offset registers. */
static void
print_register_offset_address (char *buf, size_t size,
const aarch64_opnd_info *opnd,
const char *base, const char *offset)
{
char tb[16]; /* Temporary buffer. */
bfd_boolean print_extend_p = TRUE;
bfd_boolean print_amount_p = TRUE;
const char *shift_name = aarch64_operand_modifiers[opnd->shifter.kind].name;
if (!opnd->shifter.amount && (opnd->qualifier != AARCH64_OPND_QLF_S_B
|| !opnd->shifter.amount_present))
{
/* Not print the shift/extend amount when the amount is zero and
when it is not the special case of 8-bit load/store instruction. */
print_amount_p = FALSE;
/* Likewise, no need to print the shift operator LSL in such a
situation. */
if (opnd->shifter.kind == AARCH64_MOD_LSL)
print_extend_p = FALSE;
}
/* Prepare for the extend/shift. */
if (print_extend_p)
{
if (print_amount_p)
snprintf (tb, sizeof (tb), ", %s #%" PRIi64, shift_name,
/* PR 21096: The %100 is to silence a warning about possible truncation. */
(opnd->shifter.amount % 100));
else
snprintf (tb, sizeof (tb), ", %s", shift_name);
}
else
tb[0] = '\0';
snprintf (buf, size, "[%s, %s%s]", base, offset, tb);
}
/* Generate the string representation of the operand OPNDS[IDX] for OPCODE
in *BUF. The caller should pass in the maximum size of *BUF in SIZE.
PC, PCREL_P and ADDRESS are used to pass in and return information about
the PC-relative address calculation, where the PC value is passed in
PC. If the operand is pc-relative related, *PCREL_P (if PCREL_P non-NULL)
will return 1 and *ADDRESS (if ADDRESS non-NULL) will return the
calculated address; otherwise, *PCREL_P (if PCREL_P non-NULL) returns 0.
The function serves both the disassembler and the assembler diagnostics
issuer, which is the reason why it lives in this file. */
void
aarch64_print_operand (char *buf, size_t size, bfd_vma pc,
const aarch64_opcode *opcode,
const aarch64_opnd_info *opnds, int idx, int *pcrel_p,
bfd_vma *address, char** notes)
{
unsigned int i, num_conds;
const char *name = NULL;
const aarch64_opnd_info *opnd = opnds + idx;
enum aarch64_modifier_kind kind;
uint64_t addr, enum_value;
buf[0] = '\0';
if (pcrel_p)
*pcrel_p = 0;
switch (opnd->type)
{
case AARCH64_OPND_Rd:
case AARCH64_OPND_Rn:
case AARCH64_OPND_Rm:
case AARCH64_OPND_Rt:
case AARCH64_OPND_Rt2:
case AARCH64_OPND_Rs:
case AARCH64_OPND_Ra:
case AARCH64_OPND_Rt_SYS:
case AARCH64_OPND_PAIRREG:
case AARCH64_OPND_SVE_Rm:
/* The optional-ness of in e.g. IC {, } is determined by
the , therefore we use opnd->present to override the
generic optional-ness information. */
if (opnd->type == AARCH64_OPND_Rt_SYS)
{
if (!opnd->present)
break;
}
/* Omit the operand, e.g. RET. */
else if (optional_operand_p (opcode, idx)
&& (opnd->reg.regno
== get_optional_operand_default_value (opcode)))
break;
assert (opnd->qualifier == AARCH64_OPND_QLF_W
|| opnd->qualifier == AARCH64_OPND_QLF_X);
snprintf (buf, size, "%s",
get_int_reg_name (opnd->reg.regno, opnd->qualifier, 0));
break;
case AARCH64_OPND_Rd_SP:
case AARCH64_OPND_Rn_SP:
case AARCH64_OPND_Rt_SP:
case AARCH64_OPND_SVE_Rn_SP:
case AARCH64_OPND_Rm_SP:
assert (opnd->qualifier == AARCH64_OPND_QLF_W
|| opnd->qualifier == AARCH64_OPND_QLF_WSP
|| opnd->qualifier == AARCH64_OPND_QLF_X
|| opnd->qualifier == AARCH64_OPND_QLF_SP);
snprintf (buf, size, "%s",
get_int_reg_name (opnd->reg.regno, opnd->qualifier, 1));
break;
case AARCH64_OPND_Rm_EXT:
kind = opnd->shifter.kind;
assert (idx == 1 || idx == 2);
if ((aarch64_stack_pointer_p (opnds)
|| (idx == 2 && aarch64_stack_pointer_p (opnds + 1)))
&& ((opnd->qualifier == AARCH64_OPND_QLF_W
&& opnds[0].qualifier == AARCH64_OPND_QLF_W
&& kind == AARCH64_MOD_UXTW)
|| (opnd->qualifier == AARCH64_OPND_QLF_X
&& kind == AARCH64_MOD_UXTX)))
{
/* 'LSL' is the preferred form in this case. */
kind = AARCH64_MOD_LSL;
if (opnd->shifter.amount == 0)
{
/* Shifter omitted. */
snprintf (buf, size, "%s",
get_int_reg_name (opnd->reg.regno, opnd->qualifier, 0));
break;
}
}
if (opnd->shifter.amount)
snprintf (buf, size, "%s, %s #%" PRIi64,
get_int_reg_name (opnd->reg.regno, opnd->qualifier, 0),
aarch64_operand_modifiers[kind].name,
opnd->shifter.amount);
else
snprintf (buf, size, "%s, %s",
get_int_reg_name (opnd->reg.regno, opnd->qualifier, 0),
aarch64_operand_modifiers[kind].name);
break;
case AARCH64_OPND_Rm_SFT:
assert (opnd->qualifier == AARCH64_OPND_QLF_W
|| opnd->qualifier == AARCH64_OPND_QLF_X);
if (opnd->shifter.amount == 0 && opnd->shifter.kind == AARCH64_MOD_LSL)
snprintf (buf, size, "%s",
get_int_reg_name (opnd->reg.regno, opnd->qualifier, 0));
else
snprintf (buf, size, "%s, %s #%" PRIi64,
get_int_reg_name (opnd->reg.regno, opnd->qualifier, 0),
aarch64_operand_modifiers[opnd->shifter.kind].name,
opnd->shifter.amount);
break;
case AARCH64_OPND_Fd:
case AARCH64_OPND_Fn:
case AARCH64_OPND_Fm:
case AARCH64_OPND_Fa:
case AARCH64_OPND_Ft:
case AARCH64_OPND_Ft2:
case AARCH64_OPND_Sd:
case AARCH64_OPND_Sn:
case AARCH64_OPND_Sm:
case AARCH64_OPND_SVE_VZn:
case AARCH64_OPND_SVE_Vd:
case AARCH64_OPND_SVE_Vm:
case AARCH64_OPND_SVE_Vn:
snprintf (buf, size, "%s%d", aarch64_get_qualifier_name (opnd->qualifier),
opnd->reg.regno);
break;
case AARCH64_OPND_Va:
case AARCH64_OPND_Vd:
case AARCH64_OPND_Vn:
case AARCH64_OPND_Vm:
snprintf (buf, size, "v%d.%s", opnd->reg.regno,
aarch64_get_qualifier_name (opnd->qualifier));
break;
case AARCH64_OPND_Ed:
case AARCH64_OPND_En:
case AARCH64_OPND_Em:
case AARCH64_OPND_Em16:
case AARCH64_OPND_SM3_IMM2:
snprintf (buf, size, "v%d.%s[%" PRIi64 "]", opnd->reglane.regno,
aarch64_get_qualifier_name (opnd->qualifier),
opnd->reglane.index);
break;
case AARCH64_OPND_VdD1:
case AARCH64_OPND_VnD1:
snprintf (buf, size, "v%d.d[1]", opnd->reg.regno);
break;
case AARCH64_OPND_LVn:
case AARCH64_OPND_LVt:
case AARCH64_OPND_LVt_AL:
case AARCH64_OPND_LEt:
print_register_list (buf, size, opnd, "v");
break;
case AARCH64_OPND_SVE_Pd:
case AARCH64_OPND_SVE_Pg3:
case AARCH64_OPND_SVE_Pg4_5:
case AARCH64_OPND_SVE_Pg4_10:
case AARCH64_OPND_SVE_Pg4_16:
case AARCH64_OPND_SVE_Pm:
case AARCH64_OPND_SVE_Pn:
case AARCH64_OPND_SVE_Pt:
if (opnd->qualifier == AARCH64_OPND_QLF_NIL)
snprintf (buf, size, "p%d", opnd->reg.regno);
else if (opnd->qualifier == AARCH64_OPND_QLF_P_Z
|| opnd->qualifier == AARCH64_OPND_QLF_P_M)
snprintf (buf, size, "p%d/%s", opnd->reg.regno,
aarch64_get_qualifier_name (opnd->qualifier));
else
snprintf (buf, size, "p%d.%s", opnd->reg.regno,
aarch64_get_qualifier_name (opnd->qualifier));
break;
case AARCH64_OPND_SVE_Za_5:
case AARCH64_OPND_SVE_Za_16:
case AARCH64_OPND_SVE_Zd:
case AARCH64_OPND_SVE_Zm_5:
case AARCH64_OPND_SVE_Zm_16:
case AARCH64_OPND_SVE_Zn:
case AARCH64_OPND_SVE_Zt:
if (opnd->qualifier == AARCH64_OPND_QLF_NIL)
snprintf (buf, size, "z%d", opnd->reg.regno);
else
snprintf (buf, size, "z%d.%s", opnd->reg.regno,
aarch64_get_qualifier_name (opnd->qualifier));
break;
case AARCH64_OPND_SVE_ZnxN:
case AARCH64_OPND_SVE_ZtxN:
print_register_list (buf, size, opnd, "z");
break;
case AARCH64_OPND_SVE_Zm3_INDEX:
case AARCH64_OPND_SVE_Zm3_22_INDEX:
case AARCH64_OPND_SVE_Zm3_11_INDEX:
case AARCH64_OPND_SVE_Zm4_11_INDEX:
case AARCH64_OPND_SVE_Zm4_INDEX:
case AARCH64_OPND_SVE_Zn_INDEX:
snprintf (buf, size, "z%d.%s[%" PRIi64 "]", opnd->reglane.regno,
aarch64_get_qualifier_name (opnd->qualifier),
opnd->reglane.index);
break;
case AARCH64_OPND_CRn:
case AARCH64_OPND_CRm:
snprintf (buf, size, "C%" PRIi64, opnd->imm.value);
break;
case AARCH64_OPND_IDX:
case AARCH64_OPND_MASK:
case AARCH64_OPND_IMM:
case AARCH64_OPND_IMM_2:
case AARCH64_OPND_WIDTH:
case AARCH64_OPND_UIMM3_OP1:
case AARCH64_OPND_UIMM3_OP2:
case AARCH64_OPND_BIT_NUM:
case AARCH64_OPND_IMM_VLSL:
case AARCH64_OPND_IMM_VLSR:
case AARCH64_OPND_SHLL_IMM:
case AARCH64_OPND_IMM0:
case AARCH64_OPND_IMMR:
case AARCH64_OPND_IMMS:
case AARCH64_OPND_UNDEFINED:
case AARCH64_OPND_FBITS:
case AARCH64_OPND_TME_UIMM16:
case AARCH64_OPND_SIMM5:
case AARCH64_OPND_SVE_SHLIMM_PRED:
case AARCH64_OPND_SVE_SHLIMM_UNPRED:
case AARCH64_OPND_SVE_SHLIMM_UNPRED_22:
case AARCH64_OPND_SVE_SHRIMM_PRED:
case AARCH64_OPND_SVE_SHRIMM_UNPRED:
case AARCH64_OPND_SVE_SHRIMM_UNPRED_22:
case AARCH64_OPND_SVE_SIMM5:
case AARCH64_OPND_SVE_SIMM5B:
case AARCH64_OPND_SVE_SIMM6:
case AARCH64_OPND_SVE_SIMM8:
case AARCH64_OPND_SVE_UIMM3:
case AARCH64_OPND_SVE_UIMM7:
case AARCH64_OPND_SVE_UIMM8:
case AARCH64_OPND_SVE_UIMM8_53:
case AARCH64_OPND_IMM_ROT1:
case AARCH64_OPND_IMM_ROT2:
case AARCH64_OPND_IMM_ROT3:
case AARCH64_OPND_SVE_IMM_ROT1:
case AARCH64_OPND_SVE_IMM_ROT2:
case AARCH64_OPND_SVE_IMM_ROT3:
snprintf (buf, size, "#%" PRIi64, opnd->imm.value);
break;
case AARCH64_OPND_SVE_I1_HALF_ONE:
case AARCH64_OPND_SVE_I1_HALF_TWO:
case AARCH64_OPND_SVE_I1_ZERO_ONE:
{
single_conv_t c;
c.i = opnd->imm.value;
snprintf (buf, size, "#%.1f", c.f);
break;
}
case AARCH64_OPND_SVE_PATTERN:
if (optional_operand_p (opcode, idx)
&& opnd->imm.value == get_optional_operand_default_value (opcode))
break;
enum_value = opnd->imm.value;
assert (enum_value < ARRAY_SIZE (aarch64_sve_pattern_array));
if (aarch64_sve_pattern_array[enum_value])
snprintf (buf, size, "%s", aarch64_sve_pattern_array[enum_value]);
else
snprintf (buf, size, "#%" PRIi64, opnd->imm.value);
break;
case AARCH64_OPND_SVE_PATTERN_SCALED:
if (optional_operand_p (opcode, idx)
&& !opnd->shifter.operator_present
&& opnd->imm.value == get_optional_operand_default_value (opcode))
break;
enum_value = opnd->imm.value;
assert (enum_value < ARRAY_SIZE (aarch64_sve_pattern_array));
if (aarch64_sve_pattern_array[opnd->imm.value])
snprintf (buf, size, "%s", aarch64_sve_pattern_array[opnd->imm.value]);
else
snprintf (buf, size, "#%" PRIi64, opnd->imm.value);
if (opnd->shifter.operator_present)
{
size_t len = strlen (buf);
snprintf (buf + len, size - len, ", %s #%" PRIi64,
aarch64_operand_modifiers[opnd->shifter.kind].name,
opnd->shifter.amount);
}
break;
case AARCH64_OPND_SVE_PRFOP:
enum_value = opnd->imm.value;
assert (enum_value < ARRAY_SIZE (aarch64_sve_prfop_array));
if (aarch64_sve_prfop_array[enum_value])
snprintf (buf, size, "%s", aarch64_sve_prfop_array[enum_value]);
else
snprintf (buf, size, "#%" PRIi64, opnd->imm.value);
break;
case AARCH64_OPND_IMM_MOV:
switch (aarch64_get_qualifier_esize (opnds[0].qualifier))
{
case 4: /* e.g. MOV Wd, #. */
{
int imm32 = opnd->imm.value;
snprintf (buf, size, "#0x%-20x\t// #%d", imm32, imm32);
}
break;
case 8: /* e.g. MOV Xd, #. */
snprintf (buf, size, "#0x%-20" PRIx64 "\t// #%" PRIi64,
opnd->imm.value, opnd->imm.value);
break;
default: assert (0);
}
break;
case AARCH64_OPND_FPIMM0:
snprintf (buf, size, "#0.0");
break;
case AARCH64_OPND_LIMM:
case AARCH64_OPND_AIMM:
case AARCH64_OPND_HALF:
case AARCH64_OPND_SVE_INV_LIMM:
case AARCH64_OPND_SVE_LIMM:
case AARCH64_OPND_SVE_LIMM_MOV:
if (opnd->shifter.amount)
snprintf (buf, size, "#0x%" PRIx64 ", lsl #%" PRIi64, opnd->imm.value,
opnd->shifter.amount);
else
snprintf (buf, size, "#0x%" PRIx64, opnd->imm.value);
break;
case AARCH64_OPND_SIMD_IMM:
case AARCH64_OPND_SIMD_IMM_SFT:
if ((! opnd->shifter.amount && opnd->shifter.kind == AARCH64_MOD_LSL)
|| opnd->shifter.kind == AARCH64_MOD_NONE)
snprintf (buf, size, "#0x%" PRIx64, opnd->imm.value);
else
snprintf (buf, size, "#0x%" PRIx64 ", %s #%" PRIi64, opnd->imm.value,
aarch64_operand_modifiers[opnd->shifter.kind].name,
opnd->shifter.amount);
break;
case AARCH64_OPND_SVE_AIMM:
case AARCH64_OPND_SVE_ASIMM:
if (opnd->shifter.amount)
snprintf (buf, size, "#%" PRIi64 ", lsl #%" PRIi64, opnd->imm.value,
opnd->shifter.amount);
else
snprintf (buf, size, "#%" PRIi64, opnd->imm.value);
break;
case AARCH64_OPND_FPIMM:
case AARCH64_OPND_SIMD_FPIMM:
case AARCH64_OPND_SVE_FPIMM8:
switch (aarch64_get_qualifier_esize (opnds[0].qualifier))
{
case 2: /* e.g. FMOV , #. */
{
half_conv_t c;
c.i = expand_fp_imm (2, opnd->imm.value);
snprintf (buf, size, "#%.18e", c.f);
}
break;
case 4: /* e.g. FMOV .4S, #. */
{
single_conv_t c;
c.i = expand_fp_imm (4, opnd->imm.value);
snprintf (buf, size, "#%.18e", c.f);
}
break;
case 8: /* e.g. FMOV , #. */
{
double_conv_t c;
c.i = expand_fp_imm (8, opnd->imm.value);
snprintf (buf, size, "#%.18e", c.d);
}
break;
default: assert (0);
}
break;
case AARCH64_OPND_CCMP_IMM:
case AARCH64_OPND_NZCV:
case AARCH64_OPND_EXCEPTION:
case AARCH64_OPND_UIMM4:
case AARCH64_OPND_UIMM4_ADDG:
case AARCH64_OPND_UIMM7:
case AARCH64_OPND_UIMM10:
if (optional_operand_p (opcode, idx) == TRUE
&& (opnd->imm.value ==
(int64_t) get_optional_operand_default_value (opcode)))
/* Omit the operand, e.g. DCPS1. */
break;
snprintf (buf, size, "#0x%x", (unsigned int)opnd->imm.value);
break;
case AARCH64_OPND_COND:
case AARCH64_OPND_COND1:
snprintf (buf, size, "%s", opnd->cond->names[0]);
num_conds = ARRAY_SIZE (opnd->cond->names);
for (i = 1; i < num_conds && opnd->cond->names[i]; ++i)
{
size_t len = strlen (buf);
if (i == 1)
snprintf (buf + len, size - len, " // %s = %s",
opnd->cond->names[0], opnd->cond->names[i]);
else
snprintf (buf + len, size - len, ", %s",
opnd->cond->names[i]);
}
break;
case AARCH64_OPND_ADDR_ADRP:
addr = ((pc + AARCH64_PCREL_OFFSET) & ~(uint64_t)0xfff)
+ opnd->imm.value;
if (pcrel_p)
*pcrel_p = 1;
if (address)
*address = addr;
/* This is not necessary during the disassembling, as print_address_func
in the disassemble_info will take care of the printing. But some
other callers may be still interested in getting the string in *STR,
so here we do snprintf regardless. */
snprintf (buf, size, "#0x%" PRIx64, addr);
break;
case AARCH64_OPND_ADDR_PCREL14:
case AARCH64_OPND_ADDR_PCREL19:
case AARCH64_OPND_ADDR_PCREL21:
case AARCH64_OPND_ADDR_PCREL26:
addr = pc + AARCH64_PCREL_OFFSET + opnd->imm.value;
if (pcrel_p)
*pcrel_p = 1;
if (address)
*address = addr;
/* This is not necessary during the disassembling, as print_address_func
in the disassemble_info will take care of the printing. But some
other callers may be still interested in getting the string in *STR,
so here we do snprintf regardless. */
snprintf (buf, size, "#0x%" PRIx64, addr);
break;
case AARCH64_OPND_ADDR_SIMPLE:
case AARCH64_OPND_SIMD_ADDR_SIMPLE:
case AARCH64_OPND_SIMD_ADDR_POST:
name = get_64bit_int_reg_name (opnd->addr.base_regno, 1);
if (opnd->type == AARCH64_OPND_SIMD_ADDR_POST)
{
if (opnd->addr.offset.is_reg)
snprintf (buf, size, "[%s], x%d", name, opnd->addr.offset.regno);
else
snprintf (buf, size, "[%s], #%d", name, opnd->addr.offset.imm);
}
else
snprintf (buf, size, "[%s]", name);
break;
case AARCH64_OPND_ADDR_REGOFF:
case AARCH64_OPND_SVE_ADDR_R:
case AARCH64_OPND_SVE_ADDR_RR:
case AARCH64_OPND_SVE_ADDR_RR_LSL1:
case AARCH64_OPND_SVE_ADDR_RR_LSL2:
case AARCH64_OPND_SVE_ADDR_RR_LSL3:
case AARCH64_OPND_SVE_ADDR_RX:
case AARCH64_OPND_SVE_ADDR_RX_LSL1:
case AARCH64_OPND_SVE_ADDR_RX_LSL2:
case AARCH64_OPND_SVE_ADDR_RX_LSL3:
print_register_offset_address
(buf, size, opnd, get_64bit_int_reg_name (opnd->addr.base_regno, 1),
get_offset_int_reg_name (opnd));
break;
case AARCH64_OPND_SVE_ADDR_ZX:
print_register_offset_address
(buf, size, opnd,
get_addr_sve_reg_name (opnd->addr.base_regno, opnd->qualifier),
get_64bit_int_reg_name (opnd->addr.offset.regno, 0));
break;
case AARCH64_OPND_SVE_ADDR_RZ:
case AARCH64_OPND_SVE_ADDR_RZ_LSL1:
case AARCH64_OPND_SVE_ADDR_RZ_LSL2:
case AARCH64_OPND_SVE_ADDR_RZ_LSL3:
case AARCH64_OPND_SVE_ADDR_RZ_XTW_14:
case AARCH64_OPND_SVE_ADDR_RZ_XTW_22:
case AARCH64_OPND_SVE_ADDR_RZ_XTW1_14:
case AARCH64_OPND_SVE_ADDR_RZ_XTW1_22:
case AARCH64_OPND_SVE_ADDR_RZ_XTW2_14:
case AARCH64_OPND_SVE_ADDR_RZ_XTW2_22:
case AARCH64_OPND_SVE_ADDR_RZ_XTW3_14:
case AARCH64_OPND_SVE_ADDR_RZ_XTW3_22:
print_register_offset_address
(buf, size, opnd, get_64bit_int_reg_name (opnd->addr.base_regno, 1),
get_addr_sve_reg_name (opnd->addr.offset.regno, opnd->qualifier));
break;
case AARCH64_OPND_ADDR_SIMM7:
case AARCH64_OPND_ADDR_SIMM9:
case AARCH64_OPND_ADDR_SIMM9_2:
case AARCH64_OPND_ADDR_SIMM10:
case AARCH64_OPND_ADDR_SIMM11:
case AARCH64_OPND_ADDR_SIMM13:
case AARCH64_OPND_ADDR_OFFSET:
case AARCH64_OPND_SVE_ADDR_RI_S4x16:
case AARCH64_OPND_SVE_ADDR_RI_S4x32:
case AARCH64_OPND_SVE_ADDR_RI_S4xVL:
case AARCH64_OPND_SVE_ADDR_RI_S4x2xVL:
case AARCH64_OPND_SVE_ADDR_RI_S4x3xVL:
case AARCH64_OPND_SVE_ADDR_RI_S4x4xVL:
case AARCH64_OPND_SVE_ADDR_RI_S6xVL:
case AARCH64_OPND_SVE_ADDR_RI_S9xVL:
case AARCH64_OPND_SVE_ADDR_RI_U6:
case AARCH64_OPND_SVE_ADDR_RI_U6x2:
case AARCH64_OPND_SVE_ADDR_RI_U6x4:
case AARCH64_OPND_SVE_ADDR_RI_U6x8:
print_immediate_offset_address
(buf, size, opnd, get_64bit_int_reg_name (opnd->addr.base_regno, 1));
break;
case AARCH64_OPND_SVE_ADDR_ZI_U5:
case AARCH64_OPND_SVE_ADDR_ZI_U5x2:
case AARCH64_OPND_SVE_ADDR_ZI_U5x4:
case AARCH64_OPND_SVE_ADDR_ZI_U5x8:
print_immediate_offset_address
(buf, size, opnd,
get_addr_sve_reg_name (opnd->addr.base_regno, opnd->qualifier));
break;
case AARCH64_OPND_SVE_ADDR_ZZ_LSL:
case AARCH64_OPND_SVE_ADDR_ZZ_SXTW:
case AARCH64_OPND_SVE_ADDR_ZZ_UXTW:
print_register_offset_address
(buf, size, opnd,
get_addr_sve_reg_name (opnd->addr.base_regno, opnd->qualifier),
get_addr_sve_reg_name (opnd->addr.offset.regno, opnd->qualifier));
break;
case AARCH64_OPND_ADDR_UIMM12:
name = get_64bit_int_reg_name (opnd->addr.base_regno, 1);
if (opnd->addr.offset.imm)
snprintf (buf, size, "[%s, #%d]", name, opnd->addr.offset.imm);
else
snprintf (buf, size, "[%s]", name);
break;
case AARCH64_OPND_SYSREG:
for (i = 0; aarch64_sys_regs[i].name; ++i)
{
bfd_boolean exact_match
= (aarch64_sys_regs[i].flags & opnd->sysreg.flags)
== opnd->sysreg.flags;
/* Try and find an exact match, But if that fails, return the first
partial match that was found. */
if (aarch64_sys_regs[i].value == opnd->sysreg.value
&& ! aarch64_sys_reg_deprecated_p (&aarch64_sys_regs[i])
&& (name == NULL || exact_match))
{
name = aarch64_sys_regs[i].name;
if (exact_match)
{
if (notes)
*notes = NULL;
break;
}
/* If we didn't match exactly, that means the presense of a flag
indicates what we didn't want for this instruction. e.g. If
F_REG_READ is there, that means we were looking for a write
register. See aarch64_ext_sysreg. */
if (aarch64_sys_regs[i].flags & F_REG_WRITE)
*notes = _("reading from a write-only register");
else if (aarch64_sys_regs[i].flags & F_REG_READ)
*notes = _("writing to a read-only register");
}
}
if (name)
snprintf (buf, size, "%s", name);
else
{
/* Implementation defined system register. */
unsigned int value = opnd->sysreg.value;
snprintf (buf, size, "s%u_%u_c%u_c%u_%u", (value >> 14) & 0x3,
(value >> 11) & 0x7, (value >> 7) & 0xf, (value >> 3) & 0xf,
value & 0x7);
}
break;
case AARCH64_OPND_PSTATEFIELD:
for (i = 0; aarch64_pstatefields[i].name; ++i)
if (aarch64_pstatefields[i].value == opnd->pstatefield)
break;
assert (aarch64_pstatefields[i].name);
snprintf (buf, size, "%s", aarch64_pstatefields[i].name);
break;
case AARCH64_OPND_SYSREG_AT:
case AARCH64_OPND_SYSREG_DC:
case AARCH64_OPND_SYSREG_IC:
case AARCH64_OPND_SYSREG_TLBI:
case AARCH64_OPND_SYSREG_SR:
snprintf (buf, size, "%s", opnd->sysins_op->name);
break;
case AARCH64_OPND_BARRIER:
snprintf (buf, size, "%s", opnd->barrier->name);
break;
case AARCH64_OPND_BARRIER_ISB:
/* Operand can be omitted, e.g. in DCPS1. */
if (! optional_operand_p (opcode, idx)
|| (opnd->barrier->value
!= get_optional_operand_default_value (opcode)))
snprintf (buf, size, "#0x%x", opnd->barrier->value);
break;
case AARCH64_OPND_PRFOP:
if (opnd->prfop->name != NULL)
snprintf (buf, size, "%s", opnd->prfop->name);
else
snprintf (buf, size, "#0x%02x", opnd->prfop->value);
break;
case AARCH64_OPND_BARRIER_PSB:
snprintf (buf, size, "csync");
break;
case AARCH64_OPND_BTI_TARGET:
if ((HINT_FLAG (opnd->hint_option->value) & HINT_OPD_F_NOPRINT) == 0)
snprintf (buf, size, "%s", opnd->hint_option->name);
break;
default:
assert (0);
}
}
#define CPENC(op0,op1,crn,crm,op2) \
((((op0) << 19) | ((op1) << 16) | ((crn) << 12) | ((crm) << 8) | ((op2) << 5)) >> 5)
/* for 3.9.3 Instructions for Accessing Special Purpose Registers */
#define CPEN_(op1,crm,op2) CPENC(3,(op1),4,(crm),(op2))
/* for 3.9.10 System Instructions */
#define CPENS(op1,crn,crm,op2) CPENC(1,(op1),(crn),(crm),(op2))
#define C0 0
#define C1 1
#define C2 2
#define C3 3
#define C4 4
#define C5 5
#define C6 6
#define C7 7
#define C8 8
#define C9 9
#define C10 10
#define C11 11
#define C12 12
#define C13 13
#define C14 14
#define C15 15
#define SYSREG(name, encoding, flags, features) \
{ name, encoding, flags, features }
#define SR_CORE(n,e,f) SYSREG (n,e,f,0)
#define SR_FEAT(n,e,f,feat) \
SYSREG ((n), (e), (f) | F_ARCHEXT, AARCH64_FEATURE_##feat)
#define SR_RNG(n,e,f) \
SYSREG ((n), (e), (f) | F_ARCHEXT, AARCH64_FEATURE_RNG | AARCH64_FEATURE_V8_5)
#define SR_V8_1(n,e,f) SR_FEAT (n,e,f,V8_1)
#define SR_V8_2(n,e,f) SR_FEAT (n,e,f,V8_2)
#define SR_V8_3(n,e,f) SR_FEAT (n,e,f,V8_3)
#define SR_V8_4(n,e,f) SR_FEAT (n,e,f,V8_4)
#define SR_V8_4(n,e,f) SR_FEAT (n,e,f,V8_4)
#define SR_PAN(n,e,f) SR_FEAT (n,e,f,PAN)
#define SR_RAS(n,e,f) SR_FEAT (n,e,f,RAS)
#define SR_SSBS(n,e,f) SR_FEAT (n,e,f,SSBS)
#define SR_SVE(n,e,f) SR_FEAT (n,e,f,SVE)
#define SR_ID_PFR2(n,e,f) SR_FEAT (n,e,f,ID_PFR2)
#define SR_PROFILE(n,e,f) SR_FEAT (n,e,f,PROFILE)
#define SR_MEMTAG(n,e,f) SR_FEAT (n,e,f,MEMTAG)
#define SR_SCXTNUM(n,e,f) SR_FEAT (n,e,f,SCXTNUM)
/* TODO there is one more issues need to be resolved
1. handle cpu-implementation-defined system registers.
Note that the F_REG_{READ,WRITE} flags mean read-only and write-only
respectively. If neither of these are set then the register is read-write. */
const aarch64_sys_reg aarch64_sys_regs [] =
{
SR_CORE ("spsr_el1", CPEN_ (0,C0,0), 0), /* = spsr_svc. */
SR_V8_1 ("spsr_el12", CPEN_ (5,C0,0), 0),
SR_CORE ("elr_el1", CPEN_ (0,C0,1), 0),
SR_V8_1 ("elr_el12", CPEN_ (5,C0,1), 0),
SR_CORE ("sp_el0", CPEN_ (0,C1,0), 0),
SR_CORE ("spsel", CPEN_ (0,C2,0), 0),
SR_CORE ("daif", CPEN_ (3,C2,1), 0),
SR_CORE ("currentel", CPEN_ (0,C2,2), F_REG_READ),
SR_PAN ("pan", CPEN_ (0,C2,3), 0),
SR_V8_2 ("uao", CPEN_ (0,C2,4), 0),
SR_CORE ("nzcv", CPEN_ (3,C2,0), 0),
SR_SSBS ("ssbs", CPEN_ (3,C2,6), 0),
SR_CORE ("fpcr", CPEN_ (3,C4,0), 0),
SR_CORE ("fpsr", CPEN_ (3,C4,1), 0),
SR_CORE ("dspsr_el0", CPEN_ (3,C5,0), 0),
SR_CORE ("dlr_el0", CPEN_ (3,C5,1), 0),
SR_CORE ("spsr_el2", CPEN_ (4,C0,0), 0), /* = spsr_hyp. */
SR_CORE ("elr_el2", CPEN_ (4,C0,1), 0),
SR_CORE ("sp_el1", CPEN_ (4,C1,0), 0),
SR_CORE ("spsr_irq", CPEN_ (4,C3,0), 0),
SR_CORE ("spsr_abt", CPEN_ (4,C3,1), 0),
SR_CORE ("spsr_und", CPEN_ (4,C3,2), 0),
SR_CORE ("spsr_fiq", CPEN_ (4,C3,3), 0),
SR_CORE ("spsr_el3", CPEN_ (6,C0,0), 0),
SR_CORE ("elr_el3", CPEN_ (6,C0,1), 0),
SR_CORE ("sp_el2", CPEN_ (6,C1,0), 0),
SR_CORE ("spsr_svc", CPEN_ (0,C0,0), F_DEPRECATED), /* = spsr_el1. */
SR_CORE ("spsr_hyp", CPEN_ (4,C0,0), F_DEPRECATED), /* = spsr_el2. */
SR_CORE ("midr_el1", CPENC (3,0,C0,C0,0), F_REG_READ),
SR_CORE ("ctr_el0", CPENC (3,3,C0,C0,1), F_REG_READ),
SR_CORE ("mpidr_el1", CPENC (3,0,C0,C0,5), F_REG_READ),
SR_CORE ("revidr_el1", CPENC (3,0,C0,C0,6), F_REG_READ),
SR_CORE ("aidr_el1", CPENC (3,1,C0,C0,7), F_REG_READ),
SR_CORE ("dczid_el0", CPENC (3,3,C0,C0,7), F_REG_READ),
SR_CORE ("id_dfr0_el1", CPENC (3,0,C0,C1,2), F_REG_READ),
SR_CORE ("id_pfr0_el1", CPENC (3,0,C0,C1,0), F_REG_READ),
SR_CORE ("id_pfr1_el1", CPENC (3,0,C0,C1,1), F_REG_READ),
SR_ID_PFR2 ("id_pfr2_el1", CPENC (3,0,C0,C3,4), F_REG_READ),
SR_CORE ("id_afr0_el1", CPENC (3,0,C0,C1,3), F_REG_READ),
SR_CORE ("id_mmfr0_el1", CPENC (3,0,C0,C1,4), F_REG_READ),
SR_CORE ("id_mmfr1_el1", CPENC (3,0,C0,C1,5), F_REG_READ),
SR_CORE ("id_mmfr2_el1", CPENC (3,0,C0,C1,6), F_REG_READ),
SR_CORE ("id_mmfr3_el1", CPENC (3,0,C0,C1,7), F_REG_READ),
SR_CORE ("id_mmfr4_el1", CPENC (3,0,C0,C2,6), F_REG_READ),
SR_CORE ("id_isar0_el1", CPENC (3,0,C0,C2,0), F_REG_READ),
SR_CORE ("id_isar1_el1", CPENC (3,0,C0,C2,1), F_REG_READ),
SR_CORE ("id_isar2_el1", CPENC (3,0,C0,C2,2), F_REG_READ),
SR_CORE ("id_isar3_el1", CPENC (3,0,C0,C2,3), F_REG_READ),
SR_CORE ("id_isar4_el1", CPENC (3,0,C0,C2,4), F_REG_READ),
SR_CORE ("id_isar5_el1", CPENC (3,0,C0,C2,5), F_REG_READ),
SR_CORE ("mvfr0_el1", CPENC (3,0,C0,C3,0), F_REG_READ),
SR_CORE ("mvfr1_el1", CPENC (3,0,C0,C3,1), F_REG_READ),
SR_CORE ("mvfr2_el1", CPENC (3,0,C0,C3,2), F_REG_READ),
SR_CORE ("ccsidr_el1", CPENC (3,1,C0,C0,0), F_REG_READ),
SR_CORE ("id_aa64pfr0_el1", CPENC (3,0,C0,C4,0), F_REG_READ),
SR_CORE ("id_aa64pfr1_el1", CPENC (3,0,C0,C4,1), F_REG_READ),
SR_CORE ("id_aa64dfr0_el1", CPENC (3,0,C0,C5,0), F_REG_READ),
SR_CORE ("id_aa64dfr1_el1", CPENC (3,0,C0,C5,1), F_REG_READ),
SR_CORE ("id_aa64isar0_el1", CPENC (3,0,C0,C6,0), F_REG_READ),
SR_CORE ("id_aa64isar1_el1", CPENC (3,0,C0,C6,1), F_REG_READ),
SR_CORE ("id_aa64mmfr0_el1", CPENC (3,0,C0,C7,0), F_REG_READ),
SR_CORE ("id_aa64mmfr1_el1", CPENC (3,0,C0,C7,1), F_REG_READ),
SR_V8_2 ("id_aa64mmfr2_el1", CPENC (3,0,C0,C7,2), F_REG_READ),
SR_CORE ("id_aa64afr0_el1", CPENC (3,0,C0,C5,4), F_REG_READ),
SR_CORE ("id_aa64afr1_el1", CPENC (3,0,C0,C5,5), F_REG_READ),
SR_SVE ("id_aa64zfr0_el1", CPENC (3,0,C0,C4,4), F_REG_READ),
SR_CORE ("clidr_el1", CPENC (3,1,C0,C0,1), F_REG_READ),
SR_CORE ("csselr_el1", CPENC (3,2,C0,C0,0), 0),
SR_CORE ("vpidr_el2", CPENC (3,4,C0,C0,0), 0),
SR_CORE ("vmpidr_el2", CPENC (3,4,C0,C0,5), 0),
SR_CORE ("sctlr_el1", CPENC (3,0,C1,C0,0), 0),
SR_CORE ("sctlr_el2", CPENC (3,4,C1,C0,0), 0),
SR_CORE ("sctlr_el3", CPENC (3,6,C1,C0,0), 0),
SR_V8_1 ("sctlr_el12", CPENC (3,5,C1,C0,0), 0),
SR_CORE ("actlr_el1", CPENC (3,0,C1,C0,1), 0),
SR_CORE ("actlr_el2", CPENC (3,4,C1,C0,1), 0),
SR_CORE ("actlr_el3", CPENC (3,6,C1,C0,1), 0),
SR_CORE ("cpacr_el1", CPENC (3,0,C1,C0,2), 0),
SR_V8_1 ("cpacr_el12", CPENC (3,5,C1,C0,2), 0),
SR_CORE ("cptr_el2", CPENC (3,4,C1,C1,2), 0),
SR_CORE ("cptr_el3", CPENC (3,6,C1,C1,2), 0),
SR_CORE ("scr_el3", CPENC (3,6,C1,C1,0), 0),
SR_CORE ("hcr_el2", CPENC (3,4,C1,C1,0), 0),
SR_CORE ("mdcr_el2", CPENC (3,4,C1,C1,1), 0),
SR_CORE ("mdcr_el3", CPENC (3,6,C1,C3,1), 0),
SR_CORE ("hstr_el2", CPENC (3,4,C1,C1,3), 0),
SR_CORE ("hacr_el2", CPENC (3,4,C1,C1,7), 0),
SR_SVE ("zcr_el1", CPENC (3,0,C1,C2,0), 0),
SR_SVE ("zcr_el12", CPENC (3,5,C1,C2,0), 0),
SR_SVE ("zcr_el2", CPENC (3,4,C1,C2,0), 0),
SR_SVE ("zcr_el3", CPENC (3,6,C1,C2,0), 0),
SR_SVE ("zidr_el1", CPENC (3,0,C0,C0,7), 0),
SR_CORE ("ttbr0_el1", CPENC (3,0,C2,C0,0), 0),
SR_CORE ("ttbr1_el1", CPENC (3,0,C2,C0,1), 0),
SR_CORE ("ttbr0_el2", CPENC (3,4,C2,C0,0), 0),
SR_V8_1 ("ttbr1_el2", CPENC (3,4,C2,C0,1), 0),
SR_CORE ("ttbr0_el3", CPENC (3,6,C2,C0,0), 0),
SR_V8_1 ("ttbr0_el12", CPENC (3,5,C2,C0,0), 0),
SR_V8_1 ("ttbr1_el12", CPENC (3,5,C2,C0,1), 0),
SR_CORE ("vttbr_el2", CPENC (3,4,C2,C1,0), 0),
SR_CORE ("tcr_el1", CPENC (3,0,C2,C0,2), 0),
SR_CORE ("tcr_el2", CPENC (3,4,C2,C0,2), 0),
SR_CORE ("tcr_el3", CPENC (3,6,C2,C0,2), 0),
SR_V8_1 ("tcr_el12", CPENC (3,5,C2,C0,2), 0),
SR_CORE ("vtcr_el2", CPENC (3,4,C2,C1,2), 0),
SR_V8_3 ("apiakeylo_el1", CPENC (3,0,C2,C1,0), 0),
SR_V8_3 ("apiakeyhi_el1", CPENC (3,0,C2,C1,1), 0),
SR_V8_3 ("apibkeylo_el1", CPENC (3,0,C2,C1,2), 0),
SR_V8_3 ("apibkeyhi_el1", CPENC (3,0,C2,C1,3), 0),
SR_V8_3 ("apdakeylo_el1", CPENC (3,0,C2,C2,0), 0),
SR_V8_3 ("apdakeyhi_el1", CPENC (3,0,C2,C2,1), 0),
SR_V8_3 ("apdbkeylo_el1", CPENC (3,0,C2,C2,2), 0),
SR_V8_3 ("apdbkeyhi_el1", CPENC (3,0,C2,C2,3), 0),
SR_V8_3 ("apgakeylo_el1", CPENC (3,0,C2,C3,0), 0),
SR_V8_3 ("apgakeyhi_el1", CPENC (3,0,C2,C3,1), 0),
SR_CORE ("afsr0_el1", CPENC (3,0,C5,C1,0), 0),
SR_CORE ("afsr1_el1", CPENC (3,0,C5,C1,1), 0),
SR_CORE ("afsr0_el2", CPENC (3,4,C5,C1,0), 0),
SR_CORE ("afsr1_el2", CPENC (3,4,C5,C1,1), 0),
SR_CORE ("afsr0_el3", CPENC (3,6,C5,C1,0), 0),
SR_V8_1 ("afsr0_el12", CPENC (3,5,C5,C1,0), 0),
SR_CORE ("afsr1_el3", CPENC (3,6,C5,C1,1), 0),
SR_V8_1 ("afsr1_el12", CPENC (3,5,C5,C1,1), 0),
SR_CORE ("esr_el1", CPENC (3,0,C5,C2,0), 0),
SR_CORE ("esr_el2", CPENC (3,4,C5,C2,0), 0),
SR_CORE ("esr_el3", CPENC (3,6,C5,C2,0), 0),
SR_V8_1 ("esr_el12", CPENC (3,5,C5,C2,0), 0),
SR_RAS ("vsesr_el2", CPENC (3,4,C5,C2,3), 0),
SR_CORE ("fpexc32_el2", CPENC (3,4,C5,C3,0), 0),
SR_RAS ("erridr_el1", CPENC (3,0,C5,C3,0), F_REG_READ),
SR_RAS ("errselr_el1", CPENC (3,0,C5,C3,1), 0),
SR_RAS ("erxfr_el1", CPENC (3,0,C5,C4,0), F_REG_READ),
SR_RAS ("erxctlr_el1", CPENC (3,0,C5,C4,1), 0),
SR_RAS ("erxstatus_el1", CPENC (3,0,C5,C4,2), 0),
SR_RAS ("erxaddr_el1", CPENC (3,0,C5,C4,3), 0),
SR_RAS ("erxmisc0_el1", CPENC (3,0,C5,C5,0), 0),
SR_RAS ("erxmisc1_el1", CPENC (3,0,C5,C5,1), 0),
SR_CORE ("far_el1", CPENC (3,0,C6,C0,0), 0),
SR_CORE ("far_el2", CPENC (3,4,C6,C0,0), 0),
SR_CORE ("far_el3", CPENC (3,6,C6,C0,0), 0),
SR_V8_1 ("far_el12", CPENC (3,5,C6,C0,0), 0),
SR_CORE ("hpfar_el2", CPENC (3,4,C6,C0,4), 0),
SR_CORE ("par_el1", CPENC (3,0,C7,C4,0), 0),
SR_CORE ("mair_el1", CPENC (3,0,C10,C2,0), 0),
SR_CORE ("mair_el2", CPENC (3,4,C10,C2,0), 0),
SR_CORE ("mair_el3", CPENC (3,6,C10,C2,0), 0),
SR_V8_1 ("mair_el12", CPENC (3,5,C10,C2,0), 0),
SR_CORE ("amair_el1", CPENC (3,0,C10,C3,0), 0),
SR_CORE ("amair_el2", CPENC (3,4,C10,C3,0), 0),
SR_CORE ("amair_el3", CPENC (3,6,C10,C3,0), 0),
SR_V8_1 ("amair_el12", CPENC (3,5,C10,C3,0), 0),
SR_CORE ("vbar_el1", CPENC (3,0,C12,C0,0), 0),
SR_CORE ("vbar_el2", CPENC (3,4,C12,C0,0), 0),
SR_CORE ("vbar_el3", CPENC (3,6,C12,C0,0), 0),
SR_V8_1 ("vbar_el12", CPENC (3,5,C12,C0,0), 0),
SR_CORE ("rvbar_el1", CPENC (3,0,C12,C0,1), F_REG_READ),
SR_CORE ("rvbar_el2", CPENC (3,4,C12,C0,1), F_REG_READ),
SR_CORE ("rvbar_el3", CPENC (3,6,C12,C0,1), F_REG_READ),
SR_CORE ("rmr_el1", CPENC (3,0,C12,C0,2), 0),
SR_CORE ("rmr_el2", CPENC (3,4,C12,C0,2), 0),
SR_CORE ("rmr_el3", CPENC (3,6,C12,C0,2), 0),
SR_CORE ("isr_el1", CPENC (3,0,C12,C1,0), F_REG_READ),
SR_RAS ("disr_el1", CPENC (3,0,C12,C1,1), 0),
SR_RAS ("vdisr_el2", CPENC (3,4,C12,C1,1), 0),
SR_CORE ("contextidr_el1", CPENC (3,0,C13,C0,1), 0),
SR_V8_1 ("contextidr_el2", CPENC (3,4,C13,C0,1), 0),
SR_V8_1 ("contextidr_el12", CPENC (3,5,C13,C0,1), 0),
SR_RNG ("rndr", CPENC (3,3,C2,C4,0), F_REG_READ),
SR_RNG ("rndrrs", CPENC (3,3,C2,C4,1), F_REG_READ),
SR_MEMTAG ("tco", CPENC (3,3,C4,C2,7), 0),
SR_MEMTAG ("tfsre0_el1", CPENC (3,0,C5,C6,1), 0),
SR_MEMTAG ("tfsr_el1", CPENC (3,0,C5,C6,0), 0),
SR_MEMTAG ("tfsr_el2", CPENC (3,4,C5,C6,0), 0),
SR_MEMTAG ("tfsr_el3", CPENC (3,6,C5,C6,0), 0),
SR_MEMTAG ("tfsr_el12", CPENC (3,5,C5,C6,0), 0),
SR_MEMTAG ("rgsr_el1", CPENC (3,0,C1,C0,5), 0),
SR_MEMTAG ("gcr_el1", CPENC (3,0,C1,C0,6), 0),
SR_MEMTAG ("gmid_el1", CPENC (3,1,C0,C0,4), F_REG_READ),
SR_CORE ("tpidr_el0", CPENC (3,3,C13,C0,2), 0),
SR_CORE ("tpidrro_el0", CPENC (3,3,C13,C0,3), 0),
SR_CORE ("tpidr_el1", CPENC (3,0,C13,C0,4), 0),
SR_CORE ("tpidr_el2", CPENC (3,4,C13,C0,2), 0),
SR_CORE ("tpidr_el3", CPENC (3,6,C13,C0,2), 0),
SR_SCXTNUM ("scxtnum_el0", CPENC (3,3,C13,C0,7), 0),
SR_SCXTNUM ("scxtnum_el1", CPENC (3,0,C13,C0,7), 0),
SR_SCXTNUM ("scxtnum_el2", CPENC (3,4,C13,C0,7), 0),
SR_SCXTNUM ("scxtnum_el12", CPENC (3,5,C13,C0,7), 0),
SR_SCXTNUM ("scxtnum_el3", CPENC (3,6,C13,C0,7), 0),
SR_CORE ("teecr32_el1", CPENC (2,2,C0, C0,0), 0), /* See section 3.9.7.1. */
SR_CORE ("cntfrq_el0", CPENC (3,3,C14,C0,0), 0),
SR_CORE ("cntpct_el0", CPENC (3,3,C14,C0,1), F_REG_READ),
SR_CORE ("cntvct_el0", CPENC (3,3,C14,C0,2), F_REG_READ),
SR_CORE ("cntvoff_el2", CPENC (3,4,C14,C0,3), 0),
SR_CORE ("cntkctl_el1", CPENC (3,0,C14,C1,0), 0),
SR_V8_1 ("cntkctl_el12", CPENC (3,5,C14,C1,0), 0),
SR_CORE ("cnthctl_el2", CPENC (3,4,C14,C1,0), 0),
SR_CORE ("cntp_tval_el0", CPENC (3,3,C14,C2,0), 0),
SR_V8_1 ("cntp_tval_el02", CPENC (3,5,C14,C2,0), 0),
SR_CORE ("cntp_ctl_el0", CPENC (3,3,C14,C2,1), 0),
SR_V8_1 ("cntp_ctl_el02", CPENC (3,5,C14,C2,1), 0),
SR_CORE ("cntp_cval_el0", CPENC (3,3,C14,C2,2), 0),
SR_V8_1 ("cntp_cval_el02", CPENC (3,5,C14,C2,2), 0),
SR_CORE ("cntv_tval_el0", CPENC (3,3,C14,C3,0), 0),
SR_V8_1 ("cntv_tval_el02", CPENC (3,5,C14,C3,0), 0),
SR_CORE ("cntv_ctl_el0", CPENC (3,3,C14,C3,1), 0),
SR_V8_1 ("cntv_ctl_el02", CPENC (3,5,C14,C3,1), 0),
SR_CORE ("cntv_cval_el0", CPENC (3,3,C14,C3,2), 0),
SR_V8_1 ("cntv_cval_el02", CPENC (3,5,C14,C3,2), 0),
SR_CORE ("cnthp_tval_el2", CPENC (3,4,C14,C2,0), 0),
SR_CORE ("cnthp_ctl_el2", CPENC (3,4,C14,C2,1), 0),
SR_CORE ("cnthp_cval_el2", CPENC (3,4,C14,C2,2), 0),
SR_CORE ("cntps_tval_el1", CPENC (3,7,C14,C2,0), 0),
SR_CORE ("cntps_ctl_el1", CPENC (3,7,C14,C2,1), 0),
SR_CORE ("cntps_cval_el1", CPENC (3,7,C14,C2,2), 0),
SR_V8_1 ("cnthv_tval_el2", CPENC (3,4,C14,C3,0), 0),
SR_V8_1 ("cnthv_ctl_el2", CPENC (3,4,C14,C3,1), 0),
SR_V8_1 ("cnthv_cval_el2", CPENC (3,4,C14,C3,2), 0),
SR_CORE ("dacr32_el2", CPENC (3,4,C3,C0,0), 0),
SR_CORE ("ifsr32_el2", CPENC (3,4,C5,C0,1), 0),
SR_CORE ("teehbr32_el1", CPENC (2,2,C1,C0,0), 0),
SR_CORE ("sder32_el3", CPENC (3,6,C1,C1,1), 0),
SR_CORE ("mdscr_el1", CPENC (2,0,C0,C2,2), 0),
SR_CORE ("mdccsr_el0", CPENC (2,3,C0,C1,0), F_REG_READ),
SR_CORE ("mdccint_el1", CPENC (2,0,C0,C2,0), 0),
SR_CORE ("dbgdtr_el0", CPENC (2,3,C0,C4,0), 0),
SR_CORE ("dbgdtrrx_el0", CPENC (2,3,C0,C5,0), F_REG_READ),
SR_CORE ("dbgdtrtx_el0", CPENC (2,3,C0,C5,0), F_REG_WRITE),
SR_CORE ("osdtrrx_el1", CPENC (2,0,C0,C0,2), 0),
SR_CORE ("osdtrtx_el1", CPENC (2,0,C0,C3,2), 0),
SR_CORE ("oseccr_el1", CPENC (2,0,C0,C6,2), 0),
SR_CORE ("dbgvcr32_el2", CPENC (2,4,C0,C7,0), 0),
SR_CORE ("dbgbvr0_el1", CPENC (2,0,C0,C0,4), 0),
SR_CORE ("dbgbvr1_el1", CPENC (2,0,C0,C1,4), 0),
SR_CORE ("dbgbvr2_el1", CPENC (2,0,C0,C2,4), 0),
SR_CORE ("dbgbvr3_el1", CPENC (2,0,C0,C3,4), 0),
SR_CORE ("dbgbvr4_el1", CPENC (2,0,C0,C4,4), 0),
SR_CORE ("dbgbvr5_el1", CPENC (2,0,C0,C5,4), 0),
SR_CORE ("dbgbvr6_el1", CPENC (2,0,C0,C6,4), 0),
SR_CORE ("dbgbvr7_el1", CPENC (2,0,C0,C7,4), 0),
SR_CORE ("dbgbvr8_el1", CPENC (2,0,C0,C8,4), 0),
SR_CORE ("dbgbvr9_el1", CPENC (2,0,C0,C9,4), 0),
SR_CORE ("dbgbvr10_el1", CPENC (2,0,C0,C10,4), 0),
SR_CORE ("dbgbvr11_el1", CPENC (2,0,C0,C11,4), 0),
SR_CORE ("dbgbvr12_el1", CPENC (2,0,C0,C12,4), 0),
SR_CORE ("dbgbvr13_el1", CPENC (2,0,C0,C13,4), 0),
SR_CORE ("dbgbvr14_el1", CPENC (2,0,C0,C14,4), 0),
SR_CORE ("dbgbvr15_el1", CPENC (2,0,C0,C15,4), 0),
SR_CORE ("dbgbcr0_el1", CPENC (2,0,C0,C0,5), 0),
SR_CORE ("dbgbcr1_el1", CPENC (2,0,C0,C1,5), 0),
SR_CORE ("dbgbcr2_el1", CPENC (2,0,C0,C2,5), 0),
SR_CORE ("dbgbcr3_el1", CPENC (2,0,C0,C3,5), 0),
SR_CORE ("dbgbcr4_el1", CPENC (2,0,C0,C4,5), 0),
SR_CORE ("dbgbcr5_el1", CPENC (2,0,C0,C5,5), 0),
SR_CORE ("dbgbcr6_el1", CPENC (2,0,C0,C6,5), 0),
SR_CORE ("dbgbcr7_el1", CPENC (2,0,C0,C7,5), 0),
SR_CORE ("dbgbcr8_el1", CPENC (2,0,C0,C8,5), 0),
SR_CORE ("dbgbcr9_el1", CPENC (2,0,C0,C9,5), 0),
SR_CORE ("dbgbcr10_el1", CPENC (2,0,C0,C10,5), 0),
SR_CORE ("dbgbcr11_el1", CPENC (2,0,C0,C11,5), 0),
SR_CORE ("dbgbcr12_el1", CPENC (2,0,C0,C12,5), 0),
SR_CORE ("dbgbcr13_el1", CPENC (2,0,C0,C13,5), 0),
SR_CORE ("dbgbcr14_el1", CPENC (2,0,C0,C14,5), 0),
SR_CORE ("dbgbcr15_el1", CPENC (2,0,C0,C15,5), 0),
SR_CORE ("dbgwvr0_el1", CPENC (2,0,C0,C0,6), 0),
SR_CORE ("dbgwvr1_el1", CPENC (2,0,C0,C1,6), 0),
SR_CORE ("dbgwvr2_el1", CPENC (2,0,C0,C2,6), 0),
SR_CORE ("dbgwvr3_el1", CPENC (2,0,C0,C3,6), 0),
SR_CORE ("dbgwvr4_el1", CPENC (2,0,C0,C4,6), 0),
SR_CORE ("dbgwvr5_el1", CPENC (2,0,C0,C5,6), 0),
SR_CORE ("dbgwvr6_el1", CPENC (2,0,C0,C6,6), 0),
SR_CORE ("dbgwvr7_el1", CPENC (2,0,C0,C7,6), 0),
SR_CORE ("dbgwvr8_el1", CPENC (2,0,C0,C8,6), 0),
SR_CORE ("dbgwvr9_el1", CPENC (2,0,C0,C9,6), 0),
SR_CORE ("dbgwvr10_el1", CPENC (2,0,C0,C10,6), 0),
SR_CORE ("dbgwvr11_el1", CPENC (2,0,C0,C11,6), 0),
SR_CORE ("dbgwvr12_el1", CPENC (2,0,C0,C12,6), 0),
SR_CORE ("dbgwvr13_el1", CPENC (2,0,C0,C13,6), 0),
SR_CORE ("dbgwvr14_el1", CPENC (2,0,C0,C14,6), 0),
SR_CORE ("dbgwvr15_el1", CPENC (2,0,C0,C15,6), 0),
SR_CORE ("dbgwcr0_el1", CPENC (2,0,C0,C0,7), 0),
SR_CORE ("dbgwcr1_el1", CPENC (2,0,C0,C1,7), 0),
SR_CORE ("dbgwcr2_el1", CPENC (2,0,C0,C2,7), 0),
SR_CORE ("dbgwcr3_el1", CPENC (2,0,C0,C3,7), 0),
SR_CORE ("dbgwcr4_el1", CPENC (2,0,C0,C4,7), 0),
SR_CORE ("dbgwcr5_el1", CPENC (2,0,C0,C5,7), 0),
SR_CORE ("dbgwcr6_el1", CPENC (2,0,C0,C6,7), 0),
SR_CORE ("dbgwcr7_el1", CPENC (2,0,C0,C7,7), 0),
SR_CORE ("dbgwcr8_el1", CPENC (2,0,C0,C8,7), 0),
SR_CORE ("dbgwcr9_el1", CPENC (2,0,C0,C9,7), 0),
SR_CORE ("dbgwcr10_el1", CPENC (2,0,C0,C10,7), 0),
SR_CORE ("dbgwcr11_el1", CPENC (2,0,C0,C11,7), 0),
SR_CORE ("dbgwcr12_el1", CPENC (2,0,C0,C12,7), 0),
SR_CORE ("dbgwcr13_el1", CPENC (2,0,C0,C13,7), 0),
SR_CORE ("dbgwcr14_el1", CPENC (2,0,C0,C14,7), 0),
SR_CORE ("dbgwcr15_el1", CPENC (2,0,C0,C15,7), 0),
SR_CORE ("mdrar_el1", CPENC (2,0,C1,C0,0), F_REG_READ),
SR_CORE ("oslar_el1", CPENC (2,0,C1,C0,4), F_REG_WRITE),
SR_CORE ("oslsr_el1", CPENC (2,0,C1,C1,4), F_REG_READ),
SR_CORE ("osdlr_el1", CPENC (2,0,C1,C3,4), 0),
SR_CORE ("dbgprcr_el1", CPENC (2,0,C1,C4,4), 0),
SR_CORE ("dbgclaimset_el1", CPENC (2,0,C7,C8,6), 0),
SR_CORE ("dbgclaimclr_el1", CPENC (2,0,C7,C9,6), 0),
SR_CORE ("dbgauthstatus_el1", CPENC (2,0,C7,C14,6), F_REG_READ),
SR_PROFILE ("pmblimitr_el1", CPENC (3,0,C9,C10,0), 0),
SR_PROFILE ("pmbptr_el1", CPENC (3,0,C9,C10,1), 0),
SR_PROFILE ("pmbsr_el1", CPENC (3,0,C9,C10,3), 0),
SR_PROFILE ("pmbidr_el1", CPENC (3,0,C9,C10,7), F_REG_READ),
SR_PROFILE ("pmscr_el1", CPENC (3,0,C9,C9,0), 0),
SR_PROFILE ("pmsicr_el1", CPENC (3,0,C9,C9,2), 0),
SR_PROFILE ("pmsirr_el1", CPENC (3,0,C9,C9,3), 0),
SR_PROFILE ("pmsfcr_el1", CPENC (3,0,C9,C9,4), 0),
SR_PROFILE ("pmsevfr_el1", CPENC (3,0,C9,C9,5), 0),
SR_PROFILE ("pmslatfr_el1", CPENC (3,0,C9,C9,6), 0),
SR_PROFILE ("pmsidr_el1", CPENC (3,0,C9,C9,7), 0),
SR_PROFILE ("pmscr_el2", CPENC (3,4,C9,C9,0), 0),
SR_PROFILE ("pmscr_el12", CPENC (3,5,C9,C9,0), 0),
SR_CORE ("pmcr_el0", CPENC (3,3,C9,C12,0), 0),
SR_CORE ("pmcntenset_el0", CPENC (3,3,C9,C12,1), 0),
SR_CORE ("pmcntenclr_el0", CPENC (3,3,C9,C12,2), 0),
SR_CORE ("pmovsclr_el0", CPENC (3,3,C9,C12,3), 0),
SR_CORE ("pmswinc_el0", CPENC (3,3,C9,C12,4), F_REG_WRITE),
SR_CORE ("pmselr_el0", CPENC (3,3,C9,C12,5), 0),
SR_CORE ("pmceid0_el0", CPENC (3,3,C9,C12,6), F_REG_READ),
SR_CORE ("pmceid1_el0", CPENC (3,3,C9,C12,7), F_REG_READ),
SR_CORE ("pmccntr_el0", CPENC (3,3,C9,C13,0), 0),
SR_CORE ("pmxevtyper_el0", CPENC (3,3,C9,C13,1), 0),
SR_CORE ("pmxevcntr_el0", CPENC (3,3,C9,C13,2), 0),
SR_CORE ("pmuserenr_el0", CPENC (3,3,C9,C14,0), 0),
SR_CORE ("pmintenset_el1", CPENC (3,0,C9,C14,1), 0),
SR_CORE ("pmintenclr_el1", CPENC (3,0,C9,C14,2), 0),
SR_CORE ("pmovsset_el0", CPENC (3,3,C9,C14,3), 0),
SR_CORE ("pmevcntr0_el0", CPENC (3,3,C14,C8,0), 0),
SR_CORE ("pmevcntr1_el0", CPENC (3,3,C14,C8,1), 0),
SR_CORE ("pmevcntr2_el0", CPENC (3,3,C14,C8,2), 0),
SR_CORE ("pmevcntr3_el0", CPENC (3,3,C14,C8,3), 0),
SR_CORE ("pmevcntr4_el0", CPENC (3,3,C14,C8,4), 0),
SR_CORE ("pmevcntr5_el0", CPENC (3,3,C14,C8,5), 0),
SR_CORE ("pmevcntr6_el0", CPENC (3,3,C14,C8,6), 0),
SR_CORE ("pmevcntr7_el0", CPENC (3,3,C14,C8,7), 0),
SR_CORE ("pmevcntr8_el0", CPENC (3,3,C14,C9,0), 0),
SR_CORE ("pmevcntr9_el0", CPENC (3,3,C14,C9,1), 0),
SR_CORE ("pmevcntr10_el0", CPENC (3,3,C14,C9,2), 0),
SR_CORE ("pmevcntr11_el0", CPENC (3,3,C14,C9,3), 0),
SR_CORE ("pmevcntr12_el0", CPENC (3,3,C14,C9,4), 0),
SR_CORE ("pmevcntr13_el0", CPENC (3,3,C14,C9,5), 0),
SR_CORE ("pmevcntr14_el0", CPENC (3,3,C14,C9,6), 0),
SR_CORE ("pmevcntr15_el0", CPENC (3,3,C14,C9,7), 0),
SR_CORE ("pmevcntr16_el0", CPENC (3,3,C14,C10,0), 0),
SR_CORE ("pmevcntr17_el0", CPENC (3,3,C14,C10,1), 0),
SR_CORE ("pmevcntr18_el0", CPENC (3,3,C14,C10,2), 0),
SR_CORE ("pmevcntr19_el0", CPENC (3,3,C14,C10,3), 0),
SR_CORE ("pmevcntr20_el0", CPENC (3,3,C14,C10,4), 0),
SR_CORE ("pmevcntr21_el0", CPENC (3,3,C14,C10,5), 0),
SR_CORE ("pmevcntr22_el0", CPENC (3,3,C14,C10,6), 0),
SR_CORE ("pmevcntr23_el0", CPENC (3,3,C14,C10,7), 0),
SR_CORE ("pmevcntr24_el0", CPENC (3,3,C14,C11,0), 0),
SR_CORE ("pmevcntr25_el0", CPENC (3,3,C14,C11,1), 0),
SR_CORE ("pmevcntr26_el0", CPENC (3,3,C14,C11,2), 0),
SR_CORE ("pmevcntr27_el0", CPENC (3,3,C14,C11,3), 0),
SR_CORE ("pmevcntr28_el0", CPENC (3,3,C14,C11,4), 0),
SR_CORE ("pmevcntr29_el0", CPENC (3,3,C14,C11,5), 0),
SR_CORE ("pmevcntr30_el0", CPENC (3,3,C14,C11,6), 0),
SR_CORE ("pmevtyper0_el0", CPENC (3,3,C14,C12,0), 0),
SR_CORE ("pmevtyper1_el0", CPENC (3,3,C14,C12,1), 0),
SR_CORE ("pmevtyper2_el0", CPENC (3,3,C14,C12,2), 0),
SR_CORE ("pmevtyper3_el0", CPENC (3,3,C14,C12,3), 0),
SR_CORE ("pmevtyper4_el0", CPENC (3,3,C14,C12,4), 0),
SR_CORE ("pmevtyper5_el0", CPENC (3,3,C14,C12,5), 0),
SR_CORE ("pmevtyper6_el0", CPENC (3,3,C14,C12,6), 0),
SR_CORE ("pmevtyper7_el0", CPENC (3,3,C14,C12,7), 0),
SR_CORE ("pmevtyper8_el0", CPENC (3,3,C14,C13,0), 0),
SR_CORE ("pmevtyper9_el0", CPENC (3,3,C14,C13,1), 0),
SR_CORE ("pmevtyper10_el0", CPENC (3,3,C14,C13,2), 0),
SR_CORE ("pmevtyper11_el0", CPENC (3,3,C14,C13,3), 0),
SR_CORE ("pmevtyper12_el0", CPENC (3,3,C14,C13,4), 0),
SR_CORE ("pmevtyper13_el0", CPENC (3,3,C14,C13,5), 0),
SR_CORE ("pmevtyper14_el0", CPENC (3,3,C14,C13,6), 0),
SR_CORE ("pmevtyper15_el0", CPENC (3,3,C14,C13,7), 0),
SR_CORE ("pmevtyper16_el0", CPENC (3,3,C14,C14,0), 0),
SR_CORE ("pmevtyper17_el0", CPENC (3,3,C14,C14,1), 0),
SR_CORE ("pmevtyper18_el0", CPENC (3,3,C14,C14,2), 0),
SR_CORE ("pmevtyper19_el0", CPENC (3,3,C14,C14,3), 0),
SR_CORE ("pmevtyper20_el0", CPENC (3,3,C14,C14,4), 0),
SR_CORE ("pmevtyper21_el0", CPENC (3,3,C14,C14,5), 0),
SR_CORE ("pmevtyper22_el0", CPENC (3,3,C14,C14,6), 0),
SR_CORE ("pmevtyper23_el0", CPENC (3,3,C14,C14,7), 0),
SR_CORE ("pmevtyper24_el0", CPENC (3,3,C14,C15,0), 0),
SR_CORE ("pmevtyper25_el0", CPENC (3,3,C14,C15,1), 0),
SR_CORE ("pmevtyper26_el0", CPENC (3,3,C14,C15,2), 0),
SR_CORE ("pmevtyper27_el0", CPENC (3,3,C14,C15,3), 0),
SR_CORE ("pmevtyper28_el0", CPENC (3,3,C14,C15,4), 0),
SR_CORE ("pmevtyper29_el0", CPENC (3,3,C14,C15,5), 0),
SR_CORE ("pmevtyper30_el0", CPENC (3,3,C14,C15,6), 0),
SR_CORE ("pmccfiltr_el0", CPENC (3,3,C14,C15,7), 0),
SR_V8_4 ("dit", CPEN_ (3,C2,5), 0),
SR_V8_4 ("vstcr_el2", CPENC (3,4,C2,C6,2), 0),
SR_V8_4 ("vsttbr_el2", CPENC (3,4,C2,C6,0), 0),
SR_V8_4 ("cnthvs_tval_el2", CPENC (3,4,C14,C4,0), 0),
SR_V8_4 ("cnthvs_cval_el2", CPENC (3,4,C14,C4,2), 0),
SR_V8_4 ("cnthvs_ctl_el2", CPENC (3,4,C14,C4,1), 0),
SR_V8_4 ("cnthps_tval_el2", CPENC (3,4,C14,C5,0), 0),
SR_V8_4 ("cnthps_cval_el2", CPENC (3,4,C14,C5,2), 0),
SR_V8_4 ("cnthps_ctl_el2", CPENC (3,4,C14,C5,1), 0),
SR_V8_4 ("sder32_el2", CPENC (3,4,C1,C3,1), 0),
SR_V8_4 ("vncr_el2", CPENC (3,4,C2,C2,0), 0),
{ 0, CPENC (0,0,0,0,0), 0, 0 }
};
bfd_boolean
aarch64_sys_reg_deprecated_p (const aarch64_sys_reg *reg)
{
return (reg->flags & F_DEPRECATED) != 0;
}
bfd_boolean
aarch64_sys_reg_supported_p (const aarch64_feature_set features,
const aarch64_sys_reg *reg)
{
if (!(reg->flags & F_ARCHEXT))
return TRUE;
if (!AARCH64_CPU_HAS_ALL_FEATURES (features, reg->features))
return FALSE;
/* ARMv8.4 TLB instructions. */
if ((reg->value == CPENS (0, C8, C1, 0)
|| reg->value == CPENS (0, C8, C1, 1)
|| reg->value == CPENS (0, C8, C1, 2)
|| reg->value == CPENS (0, C8, C1, 3)
|| reg->value == CPENS (0, C8, C1, 5)
|| reg->value == CPENS (0, C8, C1, 7)
|| reg->value == CPENS (4, C8, C4, 0)
|| reg->value == CPENS (4, C8, C4, 4)
|| reg->value == CPENS (4, C8, C1, 1)
|| reg->value == CPENS (4, C8, C1, 5)
|| reg->value == CPENS (4, C8, C1, 6)
|| reg->value == CPENS (6, C8, C1, 1)
|| reg->value == CPENS (6, C8, C1, 5)
|| reg->value == CPENS (4, C8, C1, 0)
|| reg->value == CPENS (4, C8, C1, 4)
|| reg->value == CPENS (6, C8, C1, 0)
|| reg->value == CPENS (0, C8, C6, 1)
|| reg->value == CPENS (0, C8, C6, 3)
|| reg->value == CPENS (0, C8, C6, 5)
|| reg->value == CPENS (0, C8, C6, 7)
|| reg->value == CPENS (0, C8, C2, 1)
|| reg->value == CPENS (0, C8, C2, 3)
|| reg->value == CPENS (0, C8, C2, 5)
|| reg->value == CPENS (0, C8, C2, 7)
|| reg->value == CPENS (0, C8, C5, 1)
|| reg->value == CPENS (0, C8, C5, 3)
|| reg->value == CPENS (0, C8, C5, 5)
|| reg->value == CPENS (0, C8, C5, 7)
|| reg->value == CPENS (4, C8, C0, 2)
|| reg->value == CPENS (4, C8, C0, 6)
|| reg->value == CPENS (4, C8, C4, 2)
|| reg->value == CPENS (4, C8, C4, 6)
|| reg->value == CPENS (4, C8, C4, 3)
|| reg->value == CPENS (4, C8, C4, 7)
|| reg->value == CPENS (4, C8, C6, 1)
|| reg->value == CPENS (4, C8, C6, 5)
|| reg->value == CPENS (4, C8, C2, 1)
|| reg->value == CPENS (4, C8, C2, 5)
|| reg->value == CPENS (4, C8, C5, 1)
|| reg->value == CPENS (4, C8, C5, 5)
|| reg->value == CPENS (6, C8, C6, 1)
|| reg->value == CPENS (6, C8, C6, 5)
|| reg->value == CPENS (6, C8, C2, 1)
|| reg->value == CPENS (6, C8, C2, 5)
|| reg->value == CPENS (6, C8, C5, 1)
|| reg->value == CPENS (6, C8, C5, 5))
&& !AARCH64_CPU_HAS_FEATURE (features, AARCH64_FEATURE_V8_4))
return FALSE;
return TRUE;
}
/* The CPENC below is fairly misleading, the fields
here are not in CPENC form. They are in op2op1 form. The fields are encoded
by ins_pstatefield, which just shifts the value by the width of the fields
in a loop. So if you CPENC them only the first value will be set, the rest
are masked out to 0. As an example. op2 = 3, op1=2. CPENC would produce a
value of 0b110000000001000000 (0x30040) while what you want is
0b011010 (0x1a). */
const aarch64_sys_reg aarch64_pstatefields [] =
{
SR_CORE ("spsel", 0x05, 0),
SR_CORE ("daifset", 0x1e, 0),
SR_CORE ("daifclr", 0x1f, 0),
SR_PAN ("pan", 0x04, 0),
SR_V8_2 ("uao", 0x03, 0),
SR_SSBS ("ssbs", 0x19, 0),
SR_V8_4 ("dit", 0x1a, 0),
SR_MEMTAG ("tco", 0x1c, 0),
{ 0, CPENC (0,0,0,0,0), 0, 0 },
};
bfd_boolean
aarch64_pstatefield_supported_p (const aarch64_feature_set features,
const aarch64_sys_reg *reg)
{
if (!(reg->flags & F_ARCHEXT))
return TRUE;
return AARCH64_CPU_HAS_ALL_FEATURES (features, reg->features);
}
const aarch64_sys_ins_reg aarch64_sys_regs_ic[] =
{
{ "ialluis", CPENS(0,C7,C1,0), 0 },
{ "iallu", CPENS(0,C7,C5,0), 0 },
{ "ivau", CPENS (3, C7, C5, 1), F_HASXT },
{ 0, CPENS(0,0,0,0), 0 }
};
const aarch64_sys_ins_reg aarch64_sys_regs_dc[] =
{
{ "zva", CPENS (3, C7, C4, 1), F_HASXT },
{ "gva", CPENS (3, C7, C4, 3), F_HASXT | F_ARCHEXT },
{ "gzva", CPENS (3, C7, C4, 4), F_HASXT | F_ARCHEXT },
{ "ivac", CPENS (0, C7, C6, 1), F_HASXT },
{ "igvac", CPENS (0, C7, C6, 3), F_HASXT | F_ARCHEXT },
{ "igsw", CPENS (0, C7, C6, 4), F_HASXT | F_ARCHEXT },
{ "isw", CPENS (0, C7, C6, 2), F_HASXT },
{ "igdvac", CPENS (0, C7, C6, 5), F_HASXT | F_ARCHEXT },
{ "igdsw", CPENS (0, C7, C6, 6), F_HASXT | F_ARCHEXT },
{ "cvac", CPENS (3, C7, C10, 1), F_HASXT },
{ "cgvac", CPENS (3, C7, C10, 3), F_HASXT | F_ARCHEXT },
{ "cgdvac", CPENS (3, C7, C10, 5), F_HASXT | F_ARCHEXT },
{ "csw", CPENS (0, C7, C10, 2), F_HASXT },
{ "cgsw", CPENS (0, C7, C10, 4), F_HASXT | F_ARCHEXT },
{ "cgdsw", CPENS (0, C7, C10, 6), F_HASXT | F_ARCHEXT },
{ "cvau", CPENS (3, C7, C11, 1), F_HASXT },
{ "cvap", CPENS (3, C7, C12, 1), F_HASXT | F_ARCHEXT },
{ "cgvap", CPENS (3, C7, C12, 3), F_HASXT | F_ARCHEXT },
{ "cgdvap", CPENS (3, C7, C12, 5), F_HASXT | F_ARCHEXT },
{ "cvadp", CPENS (3, C7, C13, 1), F_HASXT | F_ARCHEXT },
{ "cgvadp", CPENS (3, C7, C13, 3), F_HASXT | F_ARCHEXT },
{ "cgdvadp", CPENS (3, C7, C13, 5), F_HASXT | F_ARCHEXT },
{ "civac", CPENS (3, C7, C14, 1), F_HASXT },
{ "cigvac", CPENS (3, C7, C14, 3), F_HASXT | F_ARCHEXT },
{ "cigdvac", CPENS (3, C7, C14, 5), F_HASXT | F_ARCHEXT },
{ "cisw", CPENS (0, C7, C14, 2), F_HASXT },
{ "cigsw", CPENS (0, C7, C14, 4), F_HASXT | F_ARCHEXT },
{ "cigdsw", CPENS (0, C7, C14, 6), F_HASXT | F_ARCHEXT },
{ 0, CPENS(0,0,0,0), 0 }
};
const aarch64_sys_ins_reg aarch64_sys_regs_at[] =
{
{ "s1e1r", CPENS (0, C7, C8, 0), F_HASXT },
{ "s1e1w", CPENS (0, C7, C8, 1), F_HASXT },
{ "s1e0r", CPENS (0, C7, C8, 2), F_HASXT },
{ "s1e0w", CPENS (0, C7, C8, 3), F_HASXT },
{ "s12e1r", CPENS (4, C7, C8, 4), F_HASXT },
{ "s12e1w", CPENS (4, C7, C8, 5), F_HASXT },
{ "s12e0r", CPENS (4, C7, C8, 6), F_HASXT },
{ "s12e0w", CPENS (4, C7, C8, 7), F_HASXT },
{ "s1e2r", CPENS (4, C7, C8, 0), F_HASXT },
{ "s1e2w", CPENS (4, C7, C8, 1), F_HASXT },
{ "s1e3r", CPENS (6, C7, C8, 0), F_HASXT },
{ "s1e3w", CPENS (6, C7, C8, 1), F_HASXT },
{ "s1e1rp", CPENS (0, C7, C9, 0), F_HASXT | F_ARCHEXT },
{ "s1e1wp", CPENS (0, C7, C9, 1), F_HASXT | F_ARCHEXT },
{ 0, CPENS(0,0,0,0), 0 }
};
const aarch64_sys_ins_reg aarch64_sys_regs_tlbi[] =
{
{ "vmalle1", CPENS(0,C8,C7,0), 0 },
{ "vae1", CPENS (0, C8, C7, 1), F_HASXT },
{ "aside1", CPENS (0, C8, C7, 2), F_HASXT },
{ "vaae1", CPENS (0, C8, C7, 3), F_HASXT },
{ "vmalle1is", CPENS(0,C8,C3,0), 0 },
{ "vae1is", CPENS (0, C8, C3, 1), F_HASXT },
{ "aside1is", CPENS (0, C8, C3, 2), F_HASXT },
{ "vaae1is", CPENS (0, C8, C3, 3), F_HASXT },
{ "ipas2e1is", CPENS (4, C8, C0, 1), F_HASXT },
{ "ipas2le1is",CPENS (4, C8, C0, 5), F_HASXT },
{ "ipas2e1", CPENS (4, C8, C4, 1), F_HASXT },
{ "ipas2le1", CPENS (4, C8, C4, 5), F_HASXT },
{ "vae2", CPENS (4, C8, C7, 1), F_HASXT },
{ "vae2is", CPENS (4, C8, C3, 1), F_HASXT },
{ "vmalls12e1",CPENS(4,C8,C7,6), 0 },
{ "vmalls12e1is",CPENS(4,C8,C3,6), 0 },
{ "vae3", CPENS (6, C8, C7, 1), F_HASXT },
{ "vae3is", CPENS (6, C8, C3, 1), F_HASXT },
{ "alle2", CPENS(4,C8,C7,0), 0 },
{ "alle2is", CPENS(4,C8,C3,0), 0 },
{ "alle1", CPENS(4,C8,C7,4), 0 },
{ "alle1is", CPENS(4,C8,C3,4), 0 },
{ "alle3", CPENS(6,C8,C7,0), 0 },
{ "alle3is", CPENS(6,C8,C3,0), 0 },
{ "vale1is", CPENS (0, C8, C3, 5), F_HASXT },
{ "vale2is", CPENS (4, C8, C3, 5), F_HASXT },
{ "vale3is", CPENS (6, C8, C3, 5), F_HASXT },
{ "vaale1is", CPENS (0, C8, C3, 7), F_HASXT },
{ "vale1", CPENS (0, C8, C7, 5), F_HASXT },
{ "vale2", CPENS (4, C8, C7, 5), F_HASXT },
{ "vale3", CPENS (6, C8, C7, 5), F_HASXT },
{ "vaale1", CPENS (0, C8, C7, 7), F_HASXT },
{ "vmalle1os", CPENS (0, C8, C1, 0), F_ARCHEXT },
{ "vae1os", CPENS (0, C8, C1, 1), F_HASXT | F_ARCHEXT },
{ "aside1os", CPENS (0, C8, C1, 2), F_HASXT | F_ARCHEXT },
{ "vaae1os", CPENS (0, C8, C1, 3), F_HASXT | F_ARCHEXT },
{ "vale1os", CPENS (0, C8, C1, 5), F_HASXT | F_ARCHEXT },
{ "vaale1os", CPENS (0, C8, C1, 7), F_HASXT | F_ARCHEXT },
{ "ipas2e1os", CPENS (4, C8, C4, 0), F_HASXT | F_ARCHEXT },
{ "ipas2le1os", CPENS (4, C8, C4, 4), F_HASXT | F_ARCHEXT },
{ "vae2os", CPENS (4, C8, C1, 1), F_HASXT | F_ARCHEXT },
{ "vale2os", CPENS (4, C8, C1, 5), F_HASXT | F_ARCHEXT },
{ "vmalls12e1os", CPENS (4, C8, C1, 6), F_ARCHEXT },
{ "vae3os", CPENS (6, C8, C1, 1), F_HASXT | F_ARCHEXT },
{ "vale3os", CPENS (6, C8, C1, 5), F_HASXT | F_ARCHEXT },
{ "alle2os", CPENS (4, C8, C1, 0), F_ARCHEXT },
{ "alle1os", CPENS (4, C8, C1, 4), F_ARCHEXT },
{ "alle3os", CPENS (6, C8, C1, 0), F_ARCHEXT },
{ "rvae1", CPENS (0, C8, C6, 1), F_HASXT | F_ARCHEXT },
{ "rvaae1", CPENS (0, C8, C6, 3), F_HASXT | F_ARCHEXT },
{ "rvale1", CPENS (0, C8, C6, 5), F_HASXT | F_ARCHEXT },
{ "rvaale1", CPENS (0, C8, C6, 7), F_HASXT | F_ARCHEXT },
{ "rvae1is", CPENS (0, C8, C2, 1), F_HASXT | F_ARCHEXT },
{ "rvaae1is", CPENS (0, C8, C2, 3), F_HASXT | F_ARCHEXT },
{ "rvale1is", CPENS (0, C8, C2, 5), F_HASXT | F_ARCHEXT },
{ "rvaale1is", CPENS (0, C8, C2, 7), F_HASXT | F_ARCHEXT },
{ "rvae1os", CPENS (0, C8, C5, 1), F_HASXT | F_ARCHEXT },
{ "rvaae1os", CPENS (0, C8, C5, 3), F_HASXT | F_ARCHEXT },
{ "rvale1os", CPENS (0, C8, C5, 5), F_HASXT | F_ARCHEXT },
{ "rvaale1os", CPENS (0, C8, C5, 7), F_HASXT | F_ARCHEXT },
{ "ripas2e1is", CPENS (4, C8, C0, 2), F_HASXT | F_ARCHEXT },
{ "ripas2le1is",CPENS (4, C8, C0, 6), F_HASXT | F_ARCHEXT },
{ "ripas2e1", CPENS (4, C8, C4, 2), F_HASXT | F_ARCHEXT },
{ "ripas2le1", CPENS (4, C8, C4, 6), F_HASXT | F_ARCHEXT },
{ "ripas2e1os", CPENS (4, C8, C4, 3), F_HASXT | F_ARCHEXT },
{ "ripas2le1os",CPENS (4, C8, C4, 7), F_HASXT | F_ARCHEXT },
{ "rvae2", CPENS (4, C8, C6, 1), F_HASXT | F_ARCHEXT },
{ "rvale2", CPENS (4, C8, C6, 5), F_HASXT | F_ARCHEXT },
{ "rvae2is", CPENS (4, C8, C2, 1), F_HASXT | F_ARCHEXT },
{ "rvale2is", CPENS (4, C8, C2, 5), F_HASXT | F_ARCHEXT },
{ "rvae2os", CPENS (4, C8, C5, 1), F_HASXT | F_ARCHEXT },
{ "rvale2os", CPENS (4, C8, C5, 5), F_HASXT | F_ARCHEXT },
{ "rvae3", CPENS (6, C8, C6, 1), F_HASXT | F_ARCHEXT },
{ "rvale3", CPENS (6, C8, C6, 5), F_HASXT | F_ARCHEXT },
{ "rvae3is", CPENS (6, C8, C2, 1), F_HASXT | F_ARCHEXT },
{ "rvale3is", CPENS (6, C8, C2, 5), F_HASXT | F_ARCHEXT },
{ "rvae3os", CPENS (6, C8, C5, 1), F_HASXT | F_ARCHEXT },
{ "rvale3os", CPENS (6, C8, C5, 5), F_HASXT | F_ARCHEXT },
{ 0, CPENS(0,0,0,0), 0 }
};
const aarch64_sys_ins_reg aarch64_sys_regs_sr[] =
{
/* RCTX is somewhat unique in a way that it has different values
(op2) based on the instruction in which it is used (cfp/dvp/cpp).
Thus op2 is masked out and instead encoded directly in the
aarch64_opcode_table entries for the respective instructions. */
{ "rctx", CPENS(3,C7,C3,0), F_HASXT | F_ARCHEXT | F_REG_WRITE}, /* WO */
{ 0, CPENS(0,0,0,0), 0 }
};
bfd_boolean
aarch64_sys_ins_reg_has_xt (const aarch64_sys_ins_reg *sys_ins_reg)
{
return (sys_ins_reg->flags & F_HASXT) != 0;
}
extern bfd_boolean
aarch64_sys_ins_reg_supported_p (const aarch64_feature_set features,
const aarch64_sys_ins_reg *reg)
{
if (!(reg->flags & F_ARCHEXT))
return TRUE;
/* DC CVAP. Values are from aarch64_sys_regs_dc. */
if (reg->value == CPENS (3, C7, C12, 1)
&& !AARCH64_CPU_HAS_FEATURE (features, AARCH64_FEATURE_V8_2))
return FALSE;
/* DC CVADP. Values are from aarch64_sys_regs_dc. */
if (reg->value == CPENS (3, C7, C13, 1)
&& !AARCH64_CPU_HAS_FEATURE (features, AARCH64_FEATURE_CVADP))
return FALSE;
/* DC for ARMv8.5-A Memory Tagging Extension. */
if ((reg->value == CPENS (0, C7, C6, 3)
|| reg->value == CPENS (0, C7, C6, 4)
|| reg->value == CPENS (0, C7, C10, 4)
|| reg->value == CPENS (0, C7, C14, 4)
|| reg->value == CPENS (3, C7, C10, 3)
|| reg->value == CPENS (3, C7, C12, 3)
|| reg->value == CPENS (3, C7, C13, 3)
|| reg->value == CPENS (3, C7, C14, 3)
|| reg->value == CPENS (3, C7, C4, 3)
|| reg->value == CPENS (0, C7, C6, 5)
|| reg->value == CPENS (0, C7, C6, 6)
|| reg->value == CPENS (0, C7, C10, 6)
|| reg->value == CPENS (0, C7, C14, 6)
|| reg->value == CPENS (3, C7, C10, 5)
|| reg->value == CPENS (3, C7, C12, 5)
|| reg->value == CPENS (3, C7, C13, 5)
|| reg->value == CPENS (3, C7, C14, 5)
|| reg->value == CPENS (3, C7, C4, 4))
&& !AARCH64_CPU_HAS_FEATURE (features, AARCH64_FEATURE_MEMTAG))
return FALSE;
/* AT S1E1RP, AT S1E1WP. Values are from aarch64_sys_regs_at. */
if ((reg->value == CPENS (0, C7, C9, 0)
|| reg->value == CPENS (0, C7, C9, 1))
&& !AARCH64_CPU_HAS_FEATURE (features, AARCH64_FEATURE_V8_2))
return FALSE;
/* CFP/DVP/CPP RCTX : Value are from aarch64_sys_regs_sr. */
if (reg->value == CPENS (3, C7, C3, 0)
&& !AARCH64_CPU_HAS_FEATURE (features, AARCH64_FEATURE_PREDRES))
return FALSE;
return TRUE;
}
#undef C0
#undef C1
#undef C2
#undef C3
#undef C4
#undef C5
#undef C6
#undef C7
#undef C8
#undef C9
#undef C10
#undef C11
#undef C12
#undef C13
#undef C14
#undef C15
#define BIT(INSN,BT) (((INSN) >> (BT)) & 1)
#define BITS(INSN,HI,LO) (((INSN) >> (LO)) & ((1 << (((HI) - (LO)) + 1)) - 1))
static enum err_type
verify_ldpsw (const struct aarch64_inst *inst ATTRIBUTE_UNUSED,
const aarch64_insn insn, bfd_vma pc ATTRIBUTE_UNUSED,
bfd_boolean encoding ATTRIBUTE_UNUSED,
aarch64_operand_error *mismatch_detail ATTRIBUTE_UNUSED,
aarch64_instr_sequence *insn_sequence ATTRIBUTE_UNUSED)
{
int t = BITS (insn, 4, 0);
int n = BITS (insn, 9, 5);
int t2 = BITS (insn, 14, 10);
if (BIT (insn, 23))
{
/* Write back enabled. */
if ((t == n || t2 == n) && n != 31)
return ERR_UND;
}
if (BIT (insn, 22))
{
/* Load */
if (t == t2)
return ERR_UND;
}
return ERR_OK;
}
/* Verifier for vector by element 3 operands functions where the
conditions `if sz:L == 11 then UNDEFINED` holds. */
static enum err_type
verify_elem_sd (const struct aarch64_inst *inst, const aarch64_insn insn,
bfd_vma pc ATTRIBUTE_UNUSED, bfd_boolean encoding,
aarch64_operand_error *mismatch_detail ATTRIBUTE_UNUSED,
aarch64_instr_sequence *insn_sequence ATTRIBUTE_UNUSED)
{
const aarch64_insn undef_pattern = 0x3;
aarch64_insn value;
assert (inst->opcode);
assert (inst->opcode->operands[2] == AARCH64_OPND_Em);
value = encoding ? inst->value : insn;
assert (value);
if (undef_pattern == extract_fields (value, 0, 2, FLD_sz, FLD_L))
return ERR_UND;
return ERR_OK;
}
/* Initialize an instruction sequence insn_sequence with the instruction INST.
If INST is NULL the given insn_sequence is cleared and the sequence is left
uninitialized. */
void
init_insn_sequence (const struct aarch64_inst *inst,
aarch64_instr_sequence *insn_sequence)
{
int num_req_entries = 0;
insn_sequence->next_insn = 0;
insn_sequence->num_insns = num_req_entries;
if (insn_sequence->instr)
XDELETE (insn_sequence->instr);
insn_sequence->instr = NULL;
if (inst)
{
insn_sequence->instr = XNEW (aarch64_inst);
memcpy (insn_sequence->instr, inst, sizeof (aarch64_inst));
}
/* Handle all the cases here. May need to think of something smarter than
a giant if/else chain if this grows. At that time, a lookup table may be
best. */
if (inst && inst->opcode->constraints & C_SCAN_MOVPRFX)
num_req_entries = 1;
if (insn_sequence->current_insns)
XDELETEVEC (insn_sequence->current_insns);
insn_sequence->current_insns = NULL;
if (num_req_entries != 0)
{
size_t size = num_req_entries * sizeof (aarch64_inst);
insn_sequence->current_insns
= (aarch64_inst**) XNEWVEC (aarch64_inst, num_req_entries);
memset (insn_sequence->current_insns, 0, size);
}
}
/* This function verifies that the instruction INST adheres to its specified
constraints. If it does then ERR_OK is returned, if not then ERR_VFI is
returned and MISMATCH_DETAIL contains the reason why verification failed.
The function is called both during assembly and disassembly. If assembling
then ENCODING will be TRUE, else FALSE. If dissassembling PC will be set
and will contain the PC of the current instruction w.r.t to the section.
If ENCODING and PC=0 then you are at a start of a section. The constraints
are verified against the given state insn_sequence which is updated as it
transitions through the verification. */
enum err_type
verify_constraints (const struct aarch64_inst *inst,
const aarch64_insn insn ATTRIBUTE_UNUSED,
bfd_vma pc,
bfd_boolean encoding,
aarch64_operand_error *mismatch_detail,
aarch64_instr_sequence *insn_sequence)
{
assert (inst);
assert (inst->opcode);
const struct aarch64_opcode *opcode = inst->opcode;
if (!opcode->constraints && !insn_sequence->instr)
return ERR_OK;
assert (insn_sequence);
enum err_type res = ERR_OK;
/* This instruction puts a constraint on the insn_sequence. */
if (opcode->flags & F_SCAN)
{
if (insn_sequence->instr)
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("instruction opens new dependency "
"sequence without ending previous one");
mismatch_detail->index = -1;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
}
init_insn_sequence (inst, insn_sequence);
return res;
}
/* Verify constraints on an existing sequence. */
if (insn_sequence->instr)
{
const struct aarch64_opcode* inst_opcode = insn_sequence->instr->opcode;
/* If we're decoding and we hit PC=0 with an open sequence then we haven't
closed a previous one that we should have. */
if (!encoding && pc == 0)
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("previous `movprfx' sequence not closed");
mismatch_detail->index = -1;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
/* Reset the sequence. */
init_insn_sequence (NULL, insn_sequence);
return res;
}
/* Validate C_SCAN_MOVPRFX constraints. Move this to a lookup table. */
if (inst_opcode->constraints & C_SCAN_MOVPRFX)
{
/* Check to see if the MOVPRFX SVE instruction is followed by an SVE
instruction for better error messages. */
if (!opcode->avariant
|| !(*opcode->avariant &
(AARCH64_FEATURE_SVE | AARCH64_FEATURE_SVE2)))
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("SVE instruction expected after "
"`movprfx'");
mismatch_detail->index = -1;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
goto done;
}
/* Check to see if the MOVPRFX SVE instruction is followed by an SVE
instruction that is allowed to be used with a MOVPRFX. */
if (!(opcode->constraints & C_SCAN_MOVPRFX))
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("SVE `movprfx' compatible instruction "
"expected");
mismatch_detail->index = -1;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
goto done;
}
/* Next check for usage of the predicate register. */
aarch64_opnd_info blk_dest = insn_sequence->instr->operands[0];
aarch64_opnd_info blk_pred, inst_pred;
memset (&blk_pred, 0, sizeof (aarch64_opnd_info));
memset (&inst_pred, 0, sizeof (aarch64_opnd_info));
bfd_boolean predicated = FALSE;
assert (blk_dest.type == AARCH64_OPND_SVE_Zd);
/* Determine if the movprfx instruction used is predicated or not. */
if (insn_sequence->instr->operands[1].type == AARCH64_OPND_SVE_Pg3)
{
predicated = TRUE;
blk_pred = insn_sequence->instr->operands[1];
}
unsigned char max_elem_size = 0;
unsigned char current_elem_size;
int num_op_used = 0, last_op_usage = 0;
int i, inst_pred_idx = -1;
int num_ops = aarch64_num_of_operands (opcode);
for (i = 0; i < num_ops; i++)
{
aarch64_opnd_info inst_op = inst->operands[i];
switch (inst_op.type)
{
case AARCH64_OPND_SVE_Zd:
case AARCH64_OPND_SVE_Zm_5:
case AARCH64_OPND_SVE_Zm_16:
case AARCH64_OPND_SVE_Zn:
case AARCH64_OPND_SVE_Zt:
case AARCH64_OPND_SVE_Vm:
case AARCH64_OPND_SVE_Vn:
case AARCH64_OPND_Va:
case AARCH64_OPND_Vn:
case AARCH64_OPND_Vm:
case AARCH64_OPND_Sn:
case AARCH64_OPND_Sm:
if (inst_op.reg.regno == blk_dest.reg.regno)
{
num_op_used++;
last_op_usage = i;
}
current_elem_size
= aarch64_get_qualifier_esize (inst_op.qualifier);
if (current_elem_size > max_elem_size)
max_elem_size = current_elem_size;
break;
case AARCH64_OPND_SVE_Pd:
case AARCH64_OPND_SVE_Pg3:
case AARCH64_OPND_SVE_Pg4_5:
case AARCH64_OPND_SVE_Pg4_10:
case AARCH64_OPND_SVE_Pg4_16:
case AARCH64_OPND_SVE_Pm:
case AARCH64_OPND_SVE_Pn:
case AARCH64_OPND_SVE_Pt:
inst_pred = inst_op;
inst_pred_idx = i;
break;
default:
break;
}
}
assert (max_elem_size != 0);
aarch64_opnd_info inst_dest = inst->operands[0];
/* Determine the size that should be used to compare against the
movprfx size. */
current_elem_size
= opcode->constraints & C_MAX_ELEM
? max_elem_size
: aarch64_get_qualifier_esize (inst_dest.qualifier);
/* If movprfx is predicated do some extra checks. */
if (predicated)
{
/* The instruction must be predicated. */
if (inst_pred_idx < 0)
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("predicated instruction expected "
"after `movprfx'");
mismatch_detail->index = -1;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
goto done;
}
/* The instruction must have a merging predicate. */
if (inst_pred.qualifier != AARCH64_OPND_QLF_P_M)
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("merging predicate expected due "
"to preceding `movprfx'");
mismatch_detail->index = inst_pred_idx;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
goto done;
}
/* The same register must be used in instruction. */
if (blk_pred.reg.regno != inst_pred.reg.regno)
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("predicate register differs "
"from that in preceding "
"`movprfx'");
mismatch_detail->index = inst_pred_idx;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
goto done;
}
}
/* Destructive operations by definition must allow one usage of the
same register. */
int allowed_usage
= aarch64_is_destructive_by_operands (opcode) ? 2 : 1;
/* Operand is not used at all. */
if (num_op_used == 0)
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("output register of preceding "
"`movprfx' not used in current "
"instruction");
mismatch_detail->index = 0;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
goto done;
}
/* We now know it's used, now determine exactly where it's used. */
if (blk_dest.reg.regno != inst_dest.reg.regno)
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("output register of preceding "
"`movprfx' expected as output");
mismatch_detail->index = 0;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
goto done;
}
/* Operand used more than allowed for the specific opcode type. */
if (num_op_used > allowed_usage)
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("output register of preceding "
"`movprfx' used as input");
mismatch_detail->index = last_op_usage;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
goto done;
}
/* Now the only thing left is the qualifiers checks. The register
must have the same maximum element size. */
if (inst_dest.qualifier
&& blk_dest.qualifier
&& current_elem_size
!= aarch64_get_qualifier_esize (blk_dest.qualifier))
{
mismatch_detail->kind = AARCH64_OPDE_SYNTAX_ERROR;
mismatch_detail->error = _("register size not compatible with "
"previous `movprfx'");
mismatch_detail->index = 0;
mismatch_detail->non_fatal = TRUE;
res = ERR_VFI;
goto done;
}
}
done:
/* Add the new instruction to the sequence. */
memcpy (insn_sequence->current_insns + insn_sequence->next_insn++,
inst, sizeof (aarch64_inst));
/* Check if sequence is now full. */
if (insn_sequence->next_insn >= insn_sequence->num_insns)
{
/* Sequence is full, but we don't have anything special to do for now,
so clear and reset it. */
init_insn_sequence (NULL, insn_sequence);
}
}
return res;
}
/* Return true if VALUE cannot be moved into an SVE register using DUP
(with any element size, not just ESIZE) and if using DUPM would
therefore be OK. ESIZE is the number of bytes in the immediate. */
bfd_boolean
aarch64_sve_dupm_mov_immediate_p (uint64_t uvalue, int esize)
{
int64_t svalue = uvalue;
uint64_t upper = (uint64_t) -1 << (esize * 4) << (esize * 4);
if ((uvalue & ~upper) != uvalue && (uvalue | upper) != uvalue)
return FALSE;
if (esize <= 4 || (uint32_t) uvalue == (uint32_t) (uvalue >> 32))
{
svalue = (int32_t) uvalue;
if (esize <= 2 || (uint16_t) uvalue == (uint16_t) (uvalue >> 16))
{
svalue = (int16_t) uvalue;
if (esize == 1 || (uint8_t) uvalue == (uint8_t) (uvalue >> 8))
return FALSE;
}
}
if ((svalue & 0xff) == 0)
svalue /= 256;
return svalue < -128 || svalue >= 128;
}
/* Include the opcode description table as well as the operand description
table. */
#define VERIFIER(x) verify_##x
#include "aarch64-tbl.h"