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binutils-gdb/opcodes/nds32-dis.c
Alan Modra fe90ae8a9f NDS32 disassembly of odd sized sections 
* nds32-dis.c (print_insn_nds32): Remove unnecessary casts.
	Initialize parts of buffer not written when handling a possible
	2-byte insn at end of section.  Don't attempt decoding of such
	an insn by the 4-byte machinery.
2020-03-20 12:35:51 +10:30

1331 lines
32 KiB
C
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/* NDS32-specific support for 32-bit ELF.
Copyright (C) 2012-2020 Free Software Foundation, Inc.
Contributed by Andes Technology Corporation.
This file is part of BFD, the Binary File Descriptor library.
This program 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 of the License, or
(at your option) any later version.
This program 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; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston, MA
02110-1301, USA. */
#include "sysdep.h"
#include <stdio.h>
#include "ansidecl.h"
#include "disassemble.h"
#include "bfd.h"
#include "symcat.h"
#include "libiberty.h"
#include "opintl.h"
#include "bfd_stdint.h"
#include "hashtab.h"
#include "nds32-asm.h"
#include "opcode/nds32.h"
/* Get fields macro define. */
#define MASK_OP(insn, mask) ((insn) & (0x3f << 25 | (mask)))
/* For mapping symbol. */
enum map_type
{
MAP_DATA0,
MAP_DATA1,
MAP_DATA2,
MAP_DATA3,
MAP_DATA4,
MAP_CODE,
};
struct nds32_private_data
{
/* Whether any mapping symbols are present in the provided symbol
table. -1 if we do not know yet, otherwise 0 or 1. */
int has_mapping_symbols;
/* Track the last type (although this doesn't seem to be useful). */
enum map_type last_mapping_type;
/* Tracking symbol table information. */
int last_symbol_index;
bfd_vma last_addr;
};
/* Default text to print if an instruction isn't recognized. */
#define UNKNOWN_INSN_MSG _("*unknown*")
#define NDS32_PARSE_INSN16 0x01
#define NDS32_PARSE_INSN32 0x02
extern const field_t *nds32_field_table[NDS32_CORE_COUNT];
extern opcode_t *nds32_opcode_table[NDS32_CORE_COUNT];
extern keyword_t **nds32_keyword_table[NDS32_CORE_COUNT];
extern struct nds32_opcode nds32_opcodes[];
extern const field_t operand_fields[];
extern keyword_t *keywords[];
extern const keyword_t keyword_gpr[];
static uint32_t nds32_mask_opcode (uint32_t);
static void nds32_special_opcode (uint32_t, struct nds32_opcode **);
static int get_mapping_symbol_type (struct disassemble_info *, int,
enum map_type *);
static int is_mapping_symbol (struct disassemble_info *, int,
enum map_type *);
/* Hash function for disassemble. */
static htab_t opcode_htab;
/* Find the value map register name. */
static keyword_t *
nds32_find_reg_keyword (keyword_t *reg, int value)
{
if (!reg)
return NULL;
while (reg->name != NULL && reg->value != value)
{
reg++;
}
if (reg->name == NULL)
return NULL;
return reg;
}
static void
nds32_parse_audio_ext (const field_t *pfd,
disassemble_info *info, uint32_t insn)
{
fprintf_ftype func = info->fprintf_func;
void *stream = info->stream;
keyword_t *psys_reg;
int int_value, new_value;
if (pfd->hw_res == HW_INT || pfd->hw_res == HW_UINT)
{
if (pfd->hw_res == HW_INT)
int_value = (unsigned) N32_IMMS (insn >> pfd->bitpos,
pfd->bitsize) << pfd->shift;
else
int_value = __GF (insn, pfd->bitpos, pfd->bitsize) << pfd->shift;
if (int_value < 10)
func (stream, "#%d", int_value);
else
func (stream, "#0x%x", int_value);
return;
}
int_value =
__GF (insn, pfd->bitpos, pfd->bitsize) << pfd->shift;
new_value = int_value;
psys_reg = (keyword_t*) keywords[pfd->hw_res];
/* p = bit[4].bit[1:0], r = bit[4].bit[3:2]. */
if (strcmp (pfd->name, "im5_i") == 0)
{
new_value = int_value & 0x03;
new_value |= ((int_value & 0x10) >> 2);
}
else if (strcmp (pfd->name, "im5_m") == 0)
{
new_value = ((int_value & 0x1C) >> 2);
}
/* p = 0.bit[1:0], r = 0.bit[3:2]. */
/* q = 1.bit[1:0], s = 1.bit[5:4]. */
else if (strcmp (pfd->name, "im6_iq") == 0)
{
new_value |= 0x04;
}
else if (strcmp (pfd->name, "im6_ms") == 0)
{
new_value |= 0x04;
}
/* Rt CONCAT(c, t21, t0). */
else if (strcmp (pfd->name, "a_rt21") == 0)
{
new_value = (insn & 0x00000020) >> 5;
new_value |= (insn & 0x00000C00) >> 9;
new_value |= (insn & 0x00008000) >> 12;
}
else if (strcmp (pfd->name, "a_rte") == 0)
{
new_value = (insn & 0x00000C00) >> 9;
new_value |= (insn & 0x00008000) >> 12;
}
else if (strcmp (pfd->name, "a_rte1") == 0)
{
new_value = (insn & 0x00000C00) >> 9;
new_value |= (insn & 0x00008000) >> 12;
new_value |= 0x01;
}
else if (strcmp (pfd->name, "a_rte69") == 0)
{
new_value = int_value << 1;
}
else if (strcmp (pfd->name, "a_rte69_1") == 0)
{
new_value = int_value << 1;
new_value |= 0x01;
}
psys_reg = nds32_find_reg_keyword (psys_reg, new_value);
if (!psys_reg)
func (stream, "???");
else
func (stream, "$%s", psys_reg->name);
}
/* Match instruction opcode with keyword table. */
static field_t *
match_field (char *name)
{
field_t *pfd;
int k;
for (k = 0; k < NDS32_CORE_COUNT; k++)
{
pfd = (field_t *) nds32_field_table[k];
while (1)
{
if (pfd->name == NULL)
break;
if (strcmp (name, pfd->name) == 0)
return pfd;
pfd++;
}
}
return NULL;
}
/* Dump instruction. If the opcode is unknown, return FALSE. */
static void
nds32_parse_opcode (struct nds32_opcode *opc, bfd_vma pc ATTRIBUTE_UNUSED,
disassemble_info *info, uint32_t insn,
uint32_t parse_mode)
{
int op = 0;
fprintf_ftype func = info->fprintf_func;
void *stream = info->stream;
const char *pstr_src;
char *pstr_tmp;
char tmp_string[16];
unsigned int push25gpr = 0, lsmwRb, lsmwRe, lsmwEnb4, checkbit, i;
int int_value, ifthe1st = 1;
const field_t *pfd;
keyword_t *psys_reg;
if (opc == NULL)
{
func (stream, UNKNOWN_INSN_MSG);
return;
}
pstr_src = opc->instruction;
if (*pstr_src == 0)
{
func (stream, "%s", opc->opcode);
return;
}
/* NDS32_PARSE_INSN16. */
if (parse_mode & NDS32_PARSE_INSN16)
{
func (stream, "%s ", opc->opcode);
}
/* NDS32_PARSE_INSN32. */
else
{
op = N32_OP6 (insn);
if (op == N32_OP6_LSMW)
func (stream, "%s.", opc->opcode);
else if (strstr (opc->instruction, "tito"))
func (stream, "%s", opc->opcode);
else
func (stream, "%s\t", opc->opcode);
}
while (*pstr_src)
{
switch (*pstr_src)
{
case '%':
case '=':
case '&':
pstr_src++;
/* Compare with operand_fields[].name. */
pstr_tmp = &tmp_string[0];
while (*pstr_src)
{
if ((*pstr_src == ',') || (*pstr_src == ' ')
|| (*pstr_src == '{') || (*pstr_src == '}')
|| (*pstr_src == '[') || (*pstr_src == ']')
|| (*pstr_src == '(') || (*pstr_src == ')')
|| (*pstr_src == '+') || (*pstr_src == '<'))
break;
*pstr_tmp++ = *pstr_src++;
}
*pstr_tmp = 0;
if ((pfd = match_field (&tmp_string[0])) == NULL)
return;
/* For insn-16. */
if (parse_mode & NDS32_PARSE_INSN16)
{
if (pfd->hw_res == HW_GPR)
{
int_value =
__GF (insn, pfd->bitpos, pfd->bitsize) << pfd->shift;
/* push25/pop25. */
if ((opc->value == 0xfc00) || (opc->value == 0xfc80))
{
if (int_value == 0)
int_value = 6;
else
int_value = (6 + (0x01 << int_value));
push25gpr = int_value;
}
else if (strcmp (pfd->name, "rt4") == 0)
{
int_value = nds32_r45map[int_value];
}
func (stream, "$%s", keyword_gpr[int_value].name);
}
else if ((pfd->hw_res == HW_INT) || (pfd->hw_res == HW_UINT))
{
if (pfd->hw_res == HW_INT)
int_value
= (unsigned) N32_IMMS (insn >> pfd->bitpos,
pfd->bitsize) << pfd->shift;
else
int_value =
__GF (insn, pfd->bitpos, pfd->bitsize) << pfd->shift;
/* movpi45. */
if (opc->value == 0xfa00)
{
int_value += 16;
func (stream, "#0x%x", int_value);
}
/* lwi45.fe. */
else if (opc->value == 0xb200)
{
int_value = 0 - (128 - int_value);
func (stream, "#%d", int_value);
}
/* beqz38/bnez38/beqs38/bnes38/j8/beqzs8/bnezs8. */
else if ((opc->value == 0xc000) || (opc->value == 0xc800)
|| (opc->value == 0xd000) || (opc->value == 0xd800)
|| (opc->value == 0xd500) || (opc->value == 0xe800)
|| (opc->value == 0xe900))
{
info->print_address_func (int_value + pc, info);
}
/* push25/pop25. */
else if ((opc->value == 0xfc00) || (opc->value == 0xfc80))
{
func (stream, "#%d ! {$r6", int_value);
if (push25gpr != 6)
func (stream, "~$%s", keyword_gpr[push25gpr].name);
func (stream, ", $fp, $gp, $lp}");
}
else if (pfd->hw_res == HW_INT)
{
if (int_value < 10)
func (stream, "#%d", int_value);
else
func (stream, "#0x%x", int_value);
}
else /* if (pfd->hw_res == HW_UINT). */
{
if (int_value < 10)
func (stream, "#%u", int_value);
else
func (stream, "#0x%x", int_value);
}
}
}
/* for audio-ext. */
else if (op == N32_OP6_AEXT)
{
nds32_parse_audio_ext (pfd, info, insn);
}
/* for insn-32. */
else if (pfd->hw_res < HW_INT)
{
int_value =
__GF (insn, pfd->bitpos, pfd->bitsize) << pfd->shift;
psys_reg = *(nds32_keyword_table[pfd->hw_res >> 8]
+ (pfd->hw_res & 0xff));
psys_reg = nds32_find_reg_keyword (psys_reg, int_value);
/* For HW_SR, dump the index when it can't
map the register name. */
if (!psys_reg && pfd->hw_res == HW_SR)
func (stream, "%d", int_value);
else if (!psys_reg)
func (stream, "???");
else
{
if (pfd->hw_res == HW_GPR || pfd->hw_res == HW_CPR
|| pfd->hw_res == HW_FDR || pfd->hw_res == HW_FSR
|| pfd->hw_res == HW_DXR || pfd->hw_res == HW_SR
|| pfd->hw_res == HW_USR)
func (stream, "$%s", psys_reg->name);
else if (pfd->hw_res == HW_DTITON
|| pfd->hw_res == HW_DTITOFF)
func (stream, ".%s", psys_reg->name);
else
func (stream, "%s", psys_reg->name);
}
}
else if ((pfd->hw_res == HW_INT) || (pfd->hw_res == HW_UINT))
{
if (pfd->hw_res == HW_INT)
int_value = (unsigned) N32_IMMS (insn >> pfd->bitpos,
pfd->bitsize) << pfd->shift;
else
int_value =
__GF (insn, pfd->bitpos, pfd->bitsize) << pfd->shift;
if ((op == N32_OP6_BR1) || (op == N32_OP6_BR2))
{
info->print_address_func (int_value + pc, info);
}
else if ((op == N32_OP6_BR3) && (pfd->bitpos == 0))
{
info->print_address_func (int_value + pc, info);
}
else if (op == N32_OP6_JI)
{
/* FIXME: Handle relocation. */
if (info->flags & INSN_HAS_RELOC)
pc = 0;
info->print_address_func (int_value + pc, info);
}
else if (op == N32_OP6_LSMW)
{
/* lmw.adm/smw.adm. */
func (stream, "#0x%x ! {", int_value);
lsmwEnb4 = int_value;
lsmwRb = ((insn >> 20) & 0x1F);
lsmwRe = ((insn >> 10) & 0x1F);
/* If [Rb, Re] specifies at least one register,
Rb(4,0) <= Re(4,0) and 0 <= Rb(4,0), Re(4,0) < 28.
Disassembling does not consider this currently because of
the convience comparing with bsp320. */
if (lsmwRb != 31 || lsmwRe != 31)
{
func (stream, "$%s", keyword_gpr[lsmwRb].name);
if (lsmwRb != lsmwRe)
func (stream, "~$%s", keyword_gpr[lsmwRe].name);
ifthe1st = 0;
}
if (lsmwEnb4 != 0)
{
/* $fp, $gp, $lp, $sp. */
checkbit = 0x08;
for (i = 0; i < 4; i++)
{
if (lsmwEnb4 & checkbit)
{
if (ifthe1st == 1)
{
ifthe1st = 0;
func (stream, "$%s", keyword_gpr[28 + i].name);
}
else
func (stream, ", $%s", keyword_gpr[28 + i].name);
}
checkbit >>= 1;
}
}
func (stream, "}");
}
else if (pfd->hw_res == HW_INT)
{
if (int_value < 10)
func (stream, "#%d", int_value);
else
func (stream, "#0x%x", int_value);
}
else /* if (pfd->hw_res == HW_UINT). */
{
if (int_value < 10)
func (stream, "#%u", int_value);
else
func (stream, "#0x%x", int_value);
}
}
break;
case '{':
case '}':
pstr_src++;
break;
case ',':
func (stream, ", ");
pstr_src++;
break;
case '+':
func (stream, " + ");
pstr_src++;
break;
case '<':
if (pstr_src[1] == '<')
{
func (stream, " << ");
pstr_src += 2;
}
else
{
func (stream, " <");
pstr_src++;
}
break;
default:
func (stream, "%c", *pstr_src++);
break;
}
}
}
/* Filter instructions with some bits must be fixed. */
static void
nds32_filter_unknown_insn (uint32_t insn, struct nds32_opcode **opc)
{
if (!(*opc))
return;
switch ((*opc)->value)
{
case JREG (JR):
case JREG (JRNEZ):
/* jr jr.xtoff */
if (__GF (insn, 6, 2) != 0 || __GF (insn, 15, 10) != 0)
*opc = NULL;
break;
case MISC (STANDBY):
if (__GF (insn, 7, 18) != 0)
*opc = NULL;
break;
case SIMD (PBSAD):
case SIMD (PBSADA):
if (__GF (insn, 5, 5) != 0)
*opc = NULL;
break;
case BR2 (SOP0):
if (__GF (insn, 20, 5) != 0)
*opc = NULL;
break;
case JREG (JRAL):
if (__GF (insn, 5, 3) != 0 || __GF (insn, 15, 5) != 0)
*opc = NULL;
break;
case ALU1 (NOR):
case ALU1 (SLT):
case ALU1 (SLTS):
case ALU1 (SLLI):
case ALU1 (SRLI):
case ALU1 (SRAI):
case ALU1 (ROTRI):
case ALU1 (SLL):
case ALU1 (SRL):
case ALU1 (SRA):
case ALU1 (ROTR):
case ALU1 (SEB):
case ALU1 (SEH):
case ALU1 (ZEH):
case ALU1 (WSBH):
case ALU1 (SVA):
case ALU1 (SVS):
case ALU1 (CMOVZ):
case ALU1 (CMOVN):
if (__GF (insn, 5, 5) != 0)
*opc = NULL;
break;
case MISC (IRET):
case MISC (ISB):
case MISC (DSB):
if (__GF (insn, 5, 20) != 0)
*opc = NULL;
break;
}
}
static void
print_insn32 (bfd_vma pc, disassemble_info *info, uint32_t insn,
uint32_t parse_mode)
{
/* Get the final correct opcode and parse. */
struct nds32_opcode *opc;
uint32_t opcode = nds32_mask_opcode (insn);
opc = (struct nds32_opcode *) htab_find (opcode_htab, &opcode);
nds32_special_opcode (insn, &opc);
nds32_filter_unknown_insn (insn, &opc);
nds32_parse_opcode (opc, pc, info, insn, parse_mode);
}
static void
print_insn16 (bfd_vma pc, disassemble_info *info,
uint32_t insn, uint32_t parse_mode)
{
struct nds32_opcode *opc;
uint32_t opcode;
/* Get highest 7 bit in default. */
unsigned int mask = 0xfe00;
/* Classify 16-bit instruction to 4 sets by bit 13 and 14. */
switch (__GF (insn, 13, 2))
{
case 0x0:
/* mov55 movi55 */
if (__GF (insn, 11, 2) == 0)
{
mask = 0xfc00;
/* ifret16 = mov55 $sp, $sp*/
if (__GF (insn, 0, 11) == 0x3ff)
mask = 0xffff;
}
else if (__GF (insn, 9, 4) == 0xb)
mask = 0xfe07;
break;
case 0x1:
/* lwi37 swi37 */
if (__GF (insn, 11, 2) == 0x3)
mask = 0xf880;
break;
case 0x2:
mask = 0xf800;
/* Exclude beqz38, bnez38, beqs38, and bnes38. */
if (__GF (insn, 12, 1) == 0x1
&& __GF (insn, 8, 3) == 0x5)
{
if (__GF (insn, 11, 1) == 0x0)
mask = 0xff00;
else
mask = 0xffe0;
}
break;
case 0x3:
switch (__GF (insn, 11, 2))
{
case 0x1:
/* beqzs8 bnezs8 */
if (__GF (insn, 9, 2) == 0x0)
mask = 0xff00;
/* addi10s */
else if (__GF(insn, 10, 1) == 0x1)
mask = 0xfc00;
break;
case 0x2:
/* lwi37.sp swi37.sp */
mask = 0xf880;
break;
case 0x3:
if (__GF (insn, 8, 3) == 0x5)
mask = 0xff00;
else if (__GF (insn, 8, 3) == 0x4)
mask = 0xff80;
else if (__GF (insn, 9 , 2) == 0x3)
mask = 0xfe07;
break;
}
break;
}
opcode = insn & mask;
opc = (struct nds32_opcode *) htab_find (opcode_htab, &opcode);
nds32_special_opcode (insn, &opc);
/* Get the final correct opcode and parse it. */
nds32_parse_opcode (opc, pc, info, insn, parse_mode);
}
static hashval_t
htab_hash_hash (const void *p)
{
return (*(unsigned int *) p) % 49;
}
static int
htab_hash_eq (const void *p, const void *q)
{
uint32_t pinsn = ((struct nds32_opcode *) p)->value;
uint32_t qinsn = *((uint32_t *) q);
return (pinsn == qinsn);
}
/* Get the format of instruction. */
static uint32_t
nds32_mask_opcode (uint32_t insn)
{
uint32_t opcode = N32_OP6 (insn);
switch (opcode)
{
case N32_OP6_LBI:
case N32_OP6_LHI:
case N32_OP6_LWI:
case N32_OP6_LDI:
case N32_OP6_LBI_BI:
case N32_OP6_LHI_BI:
case N32_OP6_LWI_BI:
case N32_OP6_LDI_BI:
case N32_OP6_SBI:
case N32_OP6_SHI:
case N32_OP6_SWI:
case N32_OP6_SDI:
case N32_OP6_SBI_BI:
case N32_OP6_SHI_BI:
case N32_OP6_SWI_BI:
case N32_OP6_SDI_BI:
case N32_OP6_LBSI:
case N32_OP6_LHSI:
case N32_OP6_LWSI:
case N32_OP6_LBSI_BI:
case N32_OP6_LHSI_BI:
case N32_OP6_LWSI_BI:
case N32_OP6_MOVI:
case N32_OP6_SETHI:
case N32_OP6_ADDI:
case N32_OP6_SUBRI:
case N32_OP6_ANDI:
case N32_OP6_XORI:
case N32_OP6_ORI:
case N32_OP6_SLTI:
case N32_OP6_SLTSI:
case N32_OP6_CEXT:
case N32_OP6_BITCI:
return MASK_OP (insn, 0);
case N32_OP6_ALU2:
/* FFBI */
if (__GF (insn, 0, 7) == (N32_ALU2_FFBI | N32_BIT (6)))
return MASK_OP (insn, 0x7f);
else if (__GF (insn, 0, 7) == (N32_ALU2_MFUSR | N32_BIT (6))
|| __GF (insn, 0, 7) == (N32_ALU2_MTUSR | N32_BIT (6)))
/* RDOV CLROV */
return MASK_OP (insn, 0xf81ff);
else if (__GF (insn, 0, 10) == (N32_ALU2_ONEOP | N32_BIT (7)))
{
/* INSB */
if (__GF (insn, 12, 3) == 4)
return MASK_OP (insn, 0x73ff);
return MASK_OP (insn, 0x7fff);
}
return MASK_OP (insn, 0x3ff);
case N32_OP6_ALU1:
case N32_OP6_SIMD:
return MASK_OP (insn, 0x1f);
case N32_OP6_MEM:
return MASK_OP (insn, 0xff);
case N32_OP6_JREG:
return MASK_OP (insn, 0x7f);
case N32_OP6_LSMW:
return MASK_OP (insn, 0x23);
case N32_OP6_SBGP:
case N32_OP6_LBGP:
return MASK_OP (insn, 0x1 << 19);
case N32_OP6_HWGP:
if (__GF (insn, 18, 2) == 0x3)
return MASK_OP (insn, 0x7 << 17);
return MASK_OP (insn, 0x3 << 18);
case N32_OP6_DPREFI:
return MASK_OP (insn, 0x1 << 24);
case N32_OP6_LWC:
case N32_OP6_SWC:
case N32_OP6_LDC:
case N32_OP6_SDC:
return MASK_OP (insn, 0x1 << 12);
case N32_OP6_JI:
return MASK_OP (insn, 0x1 << 24);
case N32_OP6_BR1:
return MASK_OP (insn, 0x1 << 14);
case N32_OP6_BR2:
if (__GF (insn, 16, 4) == 0)
return MASK_OP (insn, 0x1ff << 16);
else
return MASK_OP (insn, 0xf << 16);
case N32_OP6_BR3:
return MASK_OP (insn, 0x1 << 19);
case N32_OP6_MISC:
switch (__GF (insn, 0, 5))
{
case N32_MISC_MTSR:
/* SETGIE and SETEND */
if (__GF (insn, 5, 5) == 0x1 || __GF (insn, 5, 5) == 0x2)
return MASK_OP (insn, 0x1fffff);
return MASK_OP (insn, 0x1f);
case N32_MISC_TLBOP:
if (__GF (insn, 5, 5) == 5 || __GF (insn, 5, 5) == 7)
/* PB FLUA */
return MASK_OP (insn, 0x3ff);
return MASK_OP (insn, 0x1f);
default:
return MASK_OP (insn, 0x1f);
}
case N32_OP6_COP:
if (__GF (insn, 4, 2) == 0)
{
/* FPU */
switch (__GF (insn, 0, 4))
{
case 0x0:
case 0x8:
/* FS1/F2OP FD1/F2OP */
if (__GF (insn, 6, 4) == 0xf)
return MASK_OP (insn, 0x7fff);
/* FS1 FD1 */
return MASK_OP (insn, 0x3ff);
case 0x4:
case 0xc:
/* FS2 */
return MASK_OP (insn, 0x3ff);
case 0x1:
case 0x9:
/* XR */
if (__GF (insn, 6, 4) == 0xc)
return MASK_OP (insn, 0x7fff);
/* MFCP MTCP */
return MASK_OP (insn, 0x3ff);
default:
return MASK_OP (insn, 0xff);
}
}
else if (__GF (insn, 0, 2) == 0)
return MASK_OP (insn, 0xf);
return MASK_OP (insn, 0xcf);
case N32_OP6_AEXT:
/* AUDIO */
switch (__GF (insn, 23, 2))
{
case 0x0:
if (__GF (insn, 5, 4) == 0)
/* AMxxx AMAyyS AMyyS AMAWzS AMWzS */
return MASK_OP (insn, (0x1f << 20) | 0x1ff);
else if (__GF (insn, 5, 4) == 1)
/* ALR ASR ALA ASA AUPI */
return MASK_OP (insn, (0x1f << 20) | (0xf << 5));
else if (__GF (insn, 20, 3) == 0 && __GF (insn, 6, 3) == 1)
/* ALR2 */
return MASK_OP (insn, (0x1f << 20) | (0x7 << 6));
else if (__GF (insn, 20 ,3) == 2 && __GF (insn, 6, 3) == 1)
/* AWEXT ASATS48 */
return MASK_OP (insn, (0x1f << 20) | (0xf << 5));
else if (__GF (insn, 20 ,3) == 3 && __GF (insn, 6, 3) == 1)
/* AMTAR AMTAR2 AMFAR AMFAR2 */
return MASK_OP (insn, (0x1f << 20) | (0x1f << 5));
else if (__GF (insn, 7, 2) == 3)
/* AMxxxSA */
return MASK_OP (insn, (0x1f << 20) | (0x3 << 7));
else if (__GF (insn, 6, 3) == 2)
/* AMxxxL.S */
return MASK_OP (insn, (0x1f << 20) | (0xf << 5));
else
/* AmxxxL.l AmxxxL2.S AMxxxL2.L */
return MASK_OP (insn, (0x1f << 20) | (0x7 << 6));
case 0x1:
if (__GF (insn, 20, 3) == 0)
/* AADDL ASUBL */
return MASK_OP (insn, (0x1f << 20) | (0x1 << 5));
else if (__GF (insn, 20, 3) == 1)
/* AMTARI Ix AMTARI Mx */
return MASK_OP (insn, (0x1f << 20));
else if (__GF (insn, 6, 3) == 2)
/* AMAWzSl.S AMWzSl.S */
return MASK_OP (insn, (0x1f << 20) | (0xf << 5));
else if (__GF (insn, 7, 2) == 3)
/* AMAWzSSA AMWzSSA */
return MASK_OP (insn, (0x1f << 20) | (0x3 << 7));
else
/* AMAWzSL.L AMAWzSL2.S AMAWzSL2.L
AMWzSL.L AMWzSL.L AMWzSL2.S */
return MASK_OP (insn, (0x1f << 20) | (0x7 << 6));
case 0x2:
if (__GF (insn, 6, 3) == 2)
/* AMAyySl.S AMWyySl.S */
return MASK_OP (insn, (0x1f << 20) | (0xf << 5));
else if (__GF (insn, 7, 2) == 3)
/* AMAWyySSA AMWyySSA */
return MASK_OP (insn, (0x1f << 20) | (0x3 << 7));
else
/* AMAWyySL.L AMAWyySL2.S AMAWyySL2.L
AMWyySL.L AMWyySL.L AMWyySL2.S */
return MASK_OP (insn, (0x1f << 20) | (0x7 << 6));
}
return MASK_OP (insn, 0x1f << 20);
default:
return 1u << 31;
}
}
/* Define cctl subtype. */
static char *cctl_subtype [] =
{
/* 0x0 */
"st0", "st0", "st0", "st2", "st2", "st3", "st3", "st4",
"st1", "st1", "st1", "st0", "st0", NULL, NULL, "st5",
/* 0x10 */
"st0", NULL, NULL, "st2", "st2", "st3", "st3", NULL,
"st1", NULL, NULL, "st0", "st0", NULL, NULL, NULL
};
/* Check the subset of opcode. */
static void
nds32_special_opcode (uint32_t insn, struct nds32_opcode **opc)
{
char *string = NULL;
uint32_t op;
if (!(*opc))
return;
/* Check if special case. */
switch ((*opc)->value)
{
case OP6 (LWC):
case OP6 (SWC):
case OP6 (LDC):
case OP6 (SDC):
case FPU_RA_IMMBI (LWC):
case FPU_RA_IMMBI (SWC):
case FPU_RA_IMMBI (LDC):
case FPU_RA_IMMBI (SDC):
/* Check if cp0 => FPU. */
if (__GF (insn, 13, 2) == 0)
{
while (!((*opc)->attr & ATTR (FPU)) && (*opc)->next)
*opc = (*opc)->next;
}
break;
case ALU1 (ADD):
case ALU1 (SUB):
case ALU1 (AND):
case ALU1 (XOR):
case ALU1 (OR):
/* Check if (add/add_slli) (sub/sub_slli) (and/and_slli). */
if (N32_SH5(insn) != 0)
string = "sh";
break;
case ALU1 (SRLI):
/* Check if nop. */
if (__GF (insn, 10, 15) == 0)
string = "nop";
break;
case MISC (CCTL):
string = cctl_subtype [__GF (insn, 5, 5)];
break;
case JREG (JR):
case JREG (JRAL):
case JREG (JR) | JREG_RET:
if (__GF (insn, 8, 2) != 0)
string = "tit";
break;
case N32_OP6_COP:
break;
case 0x9200:
/* nop16 */
if (__GF (insn, 0, 9) == 0)
string = "nop16";
break;
}
if (string)
{
while (strstr ((*opc)->opcode, string) == NULL
&& strstr ((*opc)->instruction, string) == NULL && (*opc)->next)
*opc = (*opc)->next;
return;
}
/* Classify instruction is COP or FPU. */
op = N32_OP6 (insn);
if (op == N32_OP6_COP && __GF (insn, 4, 2) != 0)
{
while (((*opc)->attr & ATTR (FPU)) != 0 && (*opc)->next)
*opc = (*opc)->next;
}
}
int
print_insn_nds32 (bfd_vma pc, disassemble_info *info)
{
int status;
bfd_byte buf[4];
bfd_byte buf_data[16];
uint64_t given;
uint64_t given1;
uint32_t insn;
int n;
int last_symbol_index = -1;
bfd_vma addr;
int is_data = FALSE;
bfd_boolean found = FALSE;
struct nds32_private_data *private_data;
unsigned int size;
enum map_type mapping_type = MAP_CODE;
if (info->private_data == NULL)
{
/* Note: remain lifecycle throughout whole execution. */
static struct nds32_private_data private;
private.has_mapping_symbols = -1; /* unknown yet. */
private.last_symbol_index = -1;
private.last_addr = 0;
info->private_data = &private;
}
private_data = info->private_data;
if (info->symtab_size != 0)
{
int start;
if (pc == 0)
start = 0;
else
{
start = info->symtab_pos;
if (start < private_data->last_symbol_index)
start = private_data->last_symbol_index;
}
if (0 > start)
start = 0;
if (private_data->has_mapping_symbols != 0
&& ((strncmp (".text", info->section->name, 5) == 0)))
{
for (n = start; n < info->symtab_size; n++)
{
addr = bfd_asymbol_value (info->symtab[n]);
if (addr > pc)
break;
if (get_mapping_symbol_type (info, n, &mapping_type))
{
last_symbol_index = n;
found = TRUE;
}
}
if (found)
private_data->has_mapping_symbols = 1;
else if (!found && private_data->has_mapping_symbols == -1)
{
/* Make sure there are no any mapping symbol. */
for (n = 0; n < info->symtab_size; n++)
{
if (is_mapping_symbol (info, n, &mapping_type))
{
private_data->has_mapping_symbols = -1;
break;
}
}
if (private_data->has_mapping_symbols == -1)
private_data->has_mapping_symbols = 0;
}
private_data->last_symbol_index = last_symbol_index;
private_data->last_mapping_type = mapping_type;
is_data = (private_data->last_mapping_type == MAP_DATA0
|| private_data->last_mapping_type == MAP_DATA1
|| private_data->last_mapping_type == MAP_DATA2
|| private_data->last_mapping_type == MAP_DATA3
|| private_data->last_mapping_type == MAP_DATA4);
}
}
/* Wonder data or instruction. */
if (is_data)
{
unsigned int i1;
/* Fix corner case: there is no next mapping symbol,
let mapping type decides size */
size = 16;
if (last_symbol_index + 1 >= info->symtab_size)
{
if (mapping_type == MAP_DATA0)
size = 1;
if (mapping_type == MAP_DATA1)
size = 2;
if (mapping_type == MAP_DATA2)
size = 4;
if (mapping_type == MAP_DATA3)
size = 8;
if (mapping_type == MAP_DATA4)
size = 16;
}
for (n = last_symbol_index + 1; n < info->symtab_size; n++)
{
addr = bfd_asymbol_value (info->symtab[n]);
enum map_type fake_mapping_type;
if (get_mapping_symbol_type (info, n, &fake_mapping_type)
&& (addr > pc
&& ((info->section == NULL)
|| (info->section == info->symtab[n]->section)))
&& (addr - pc < size))
{
size = addr - pc;
break;
}
}
if (size == 3)
size = (pc & 1) ? 1 : 2;
/* Read bytes from BFD. */
info->read_memory_func (pc, buf_data, size, info);
given = 0;
given1 = 0;
/* Start assembling data. */
/* Little endian of data. */
if (info->endian == BFD_ENDIAN_LITTLE)
{
for (i1 = size - 1;; i1--)
{
if (i1 >= 8)
given1 = buf_data[i1] | (given1 << 8);
else
given = buf_data[i1] | (given << 8);
if (i1 == 0)
break;
}
}
else
{
/* Big endian of data. */
for (i1 = 0; i1 < size; i1++)
{
if (i1 <= 7)
given = buf_data[i1] | (given << 8);
else
given1 = buf_data[i1] | (given1 << 8);
}
}
info->bytes_per_line = 4;
if (size == 16)
info->fprintf_func (info->stream, ".qword\t0x%016" PRIx64 "%016" PRIx64,
given, given1);
else if (size == 8)
info->fprintf_func (info->stream, ".dword\t0x%016" PRIx64, given);
else if (size == 4)
info->fprintf_func (info->stream, ".word\t0x%08" PRIx64, given);
else if (size == 2)
{
/* short */
if (mapping_type == MAP_DATA0)
info->fprintf_func (info->stream, ".byte\t0x%02" PRIx64,
given & 0xFF);
else
info->fprintf_func (info->stream, ".short\t0x%04" PRIx64, given);
}
else
{
/* byte */
info->fprintf_func (info->stream, ".byte\t0x%02" PRIx64, given);
}
return size;
}
size = 4;
status = info->read_memory_func (pc, buf, 4, info);
if (status)
{
/* For the last 16-bit instruction. */
size = 2;
status = info->read_memory_func (pc, buf, 2, info);
if (status)
{
(*info->memory_error_func) (status, pc, info);
return -1;
}
buf[2] = 0;
buf[3] = 0;
}
insn = bfd_getb32 (buf);
/* 16-bit instruction. */
if (insn & 0x80000000)
{
print_insn16 (pc, info, (insn >> 16), NDS32_PARSE_INSN16);
return 2;
}
/* 32-bit instructions. */
if (size == 4)
print_insn32 (pc, info, insn, NDS32_PARSE_INSN32);
else
info->fprintf_func (info->stream,
_("insufficient data to decode instruction"));
return 4;
}
/* Ignore disassembling unnecessary name. */
static bfd_boolean
nds32_symbol_is_valid (asymbol *sym,
struct disassemble_info *info ATTRIBUTE_UNUSED)
{
const char *name;
if (sym == NULL)
return FALSE;
name = bfd_asymbol_name (sym);
/* Mapping symbol is invalid. */
if (name[0] == '$')
return FALSE;
return TRUE;
}
static void
nds32_add_opcode_hash_table (unsigned indx)
{
opcode_t *opc;
opc = nds32_opcode_table[indx];
if (opc == NULL)
return;
while (opc->opcode != NULL)
{
opcode_t **slot;
slot = (opcode_t **) htab_find_slot
(opcode_htab, &opc->value, INSERT);
if (*slot == NULL)
{
/* This is the new one. */
*slot = opc;
}
else
{
opcode_t *tmp;
/* Already exists. Append to the list. */
tmp = *slot;
while (tmp->next)
tmp = tmp->next;
tmp->next = opc;
opc->next = NULL;
}
opc++;
}
}
void
disassemble_init_nds32 (struct disassemble_info *info)
{
static unsigned init_done = 0;
unsigned k;
/* Set up symbol checking function. */
info->symbol_is_valid = nds32_symbol_is_valid;
/* Only need to initialize once:
High level will call this function for every object file.
For example, when disassemble all members of a library. */
if (init_done)
return;
/* Setup main core. */
nds32_keyword_table[NDS32_MAIN_CORE] = &keywords[0];
nds32_opcode_table[NDS32_MAIN_CORE] = &nds32_opcodes[0];
nds32_field_table[NDS32_MAIN_CORE] = &operand_fields[0];
/* Build opcode table. */
opcode_htab = htab_create_alloc (1024, htab_hash_hash, htab_hash_eq,
NULL, xcalloc, free);
for (k = 0; k < NDS32_CORE_COUNT; k++)
{
/* Add op-codes. */
nds32_add_opcode_hash_table (k);
}
init_done = 1;
}
static int
is_mapping_symbol (struct disassemble_info *info, int n,
enum map_type *map_type)
{
const char *name = NULL;
/* Get symbol name. */
name = bfd_asymbol_name (info->symtab[n]);
if (name[1] == 'c')
{
*map_type = MAP_CODE;
return TRUE;
}
else if (name[1] == 'd' && name[2] == '0')
{
*map_type = MAP_DATA0;
return TRUE;
}
else if (name[1] == 'd' && name[2] == '1')
{
*map_type = MAP_DATA1;
return TRUE;
}
else if (name[1] == 'd' && name[2] == '2')
{
*map_type = MAP_DATA2;
return TRUE;
}
else if (name[1] == 'd' && name[2] == '3')
{
*map_type = MAP_DATA3;
return TRUE;
}
else if (name[1] == 'd' && name[2] == '4')
{
*map_type = MAP_DATA4;
return TRUE;
}
return FALSE;
}
static int
get_mapping_symbol_type (struct disassemble_info *info, int n,
enum map_type *map_type)
{
/* If the symbol is in a different section, ignore it. */
if (info->section != NULL
&& info->section != info->symtab[n]->section)
return FALSE;
return is_mapping_symbol (info, n, map_type);
}
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