/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright 2009 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
#include <_libelf.h>
#include <dwarf.h>
#include <stdio.h>
#include <unistd.h>
#include <errno.h>
#include <strings.h>
#include <debug.h>
#include <conv.h>
#include <msg.h>
#include <_elfdump.h>
/*
* Data from eh_frame section used by dump_cfi()
*/
typedef struct {
const char *file;
const char *sh_name;
Half e_machine; /* ehdr->e_machine */
uchar_t *e_ident; /* ehdr->e_ident */
uint64_t sh_addr; /* Address of eh_frame section */
int do_swap; /* True if object and system byte */
/* order differs */
int cieRflag; /* R flag from current CIE */
uint64_t ciecalign; /* CIE code align factor */
int64_t ciedalign; /* CIE data align factor */
uint64_t fdeinitloc; /* FDE initial location */
uint64_t gotaddr; /* Address of the GOT */
} dump_cfi_state_t;
/*
* Extract an unsigned integer value from an .eh_frame section, converting it
* from its native byte order to that of the running machine if necessary.
*
* entry:
* data - Base address from which to extract datum
* ndx - Address of variable giving index to start byte in data.
* size - # of bytes in datum. Must be one of: 1, 2, 4, 8
* do_swap - True if the data is in a different byte order than that
* of the host system.
*
* exit:
* *ndx is incremented by the size of the extracted datum.
*
* The requested datum is extracted, byte swapped if necessary,
* and returned.
*/
static dwarf_error_t
dwarf_extract_uint(uchar_t *data, size_t len, uint64_t *ndx, int size,
int do_swap, uint64_t *ret)
{
if (((*ndx + size) > len) ||
((*ndx + size) < *ndx))
return (DW_OVERFLOW);
switch (size) {
case 1:
*ret = (data[(*ndx)++]);
return (DW_SUCCESS);
case 2:
{
Half r;
uchar_t *p = (uchar_t *)&r;
data += *ndx;
if (do_swap)
UL_ASSIGN_BSWAP_HALF(p, data);
else
UL_ASSIGN_HALF(p, data);
(*ndx) += 2;
*ret = r;
return (DW_SUCCESS);
}
case 4:
{
Word r;
uchar_t *p = (uchar_t *)&r;
data += *ndx;
if (do_swap)
UL_ASSIGN_BSWAP_WORD(p, data);
else
UL_ASSIGN_WORD(p, data);
(*ndx) += 4;
*ret = r;
return (DW_SUCCESS);
}
case 8:
{
uint64_t r;
uchar_t *p = (uchar_t *)&r;
data += *ndx;
if (do_swap)
UL_ASSIGN_BSWAP_LWORD(p, data);
else
UL_ASSIGN_LWORD(p, data);
(*ndx) += 8;
*ret = r;
return (DW_SUCCESS);
}
default:
return (DW_BAD_ENCODING);
}
/* NOTREACHED */
}
/*
* Map a DWARF register constant to the machine register name it
* corresponds to, formatting the result into buf.
*
* The assignment of DWARF register numbers is part of the system
* specific ABI for each platform.
*
* entry:
* regno - DWARF register number
* mach - ELF machine code for platform
* buf, bufsize - Buffer to receive the formatted result string
*
* exit:
* The results are formatted into buf, and buf is returned.
* If the generated output would exceed the size of the buffer
* provided, it will be clipped to fit.
*/
static const char *
dwarf_regname(Half mach, int regno, char *buf, size_t bufsize)
{
Conv_inv_buf_t inv_buf;
const char *name;
int good_name;
name = conv_dwarf_regname(mach, regno, 0, &good_name, &inv_buf);
/*
* If there is a good mnemonic machine name for the register,
* format the result as 'r# (mnemonic)'. If there is no good
* name for it, then simply format the dwarf name as 'r#'.
*/
if (good_name)
(void) snprintf(buf, bufsize, MSG_ORIG(MSG_REG_FMT_NAME),
regno, name);
else
(void) snprintf(buf, bufsize, MSG_ORIG(MSG_REG_FMT_BASIC),
regno);
return (buf);
}
/*
* Decode eh_frame Call Frame Instructions, printing each one on a
* separate line.
*
* entry:
* data - Address of base of eh_frame section being processed
* off - Offset of current FDE within eh_frame
* ndx - Index of current position within current FDE
* len - Length of FDE
* state - Object, CIE, and FDE state for current request
* msg - Header message to issue before producing output.
* indent - # of indentation characters issued for each line of output.
*
* exit:
* The Call Frame Instructions have been decoded and printed.
*
* *ndx has been incremented to contain the index of the next
* byte of data to be processed in eh_frame.
*
* note:
* The format of Call Frame Instructions in .eh_frame sections is based
* on the DWARF specification.
*/
static void
dump_cfi(uchar_t *data, uint64_t off, uint64_t *ndx, uint_t len,
dump_cfi_state_t *state, const char *msg, int indent)
{
/*
* We use %*s%s to insert leading whitespace and the op name.
* PREFIX supplies these arguments.
*/
#define PREFIX indent, MSG_ORIG(MSG_STR_EMPTY), opname
/* Hide boilerplate clutter in calls to dwarf_regname() */
#define REGNAME(_rnum, _buf) \
dwarf_regname(state->e_machine, _rnum, _buf, sizeof (_buf))
/* Extract the lower 6 bits from an op code */
#define LOW_OP(_op) (_op & 0x3f)
char rbuf1[32], rbuf2[32];
Conv_inv_buf_t inv_buf;
uchar_t op;
const char *opname;
uint64_t oper1, oper2, cur_pc;
int64_t soper;
const char *loc_str;
int i;
dbg_print(0, msg);
/*
* In a CIE/FDE, the length field does not include it's own
* size. Hence, the value passed in is 4 less than the index
* of the actual final location.
*/
len += 4;
/*
* There is a concept of the 'current location', which is the PC
* to which the current item applies. It starts out set to the
* FDE initial location, and can be set or incremented by
* various OP codes. cur_pc is used to track this.
*
* We want to use 'initloc' in the output the first time the location
* is referenced, and then switch to 'loc' for subsequent references.
* loc_str is used to manage that.
*/
cur_pc = state->fdeinitloc;
loc_str = MSG_ORIG(MSG_STR_INITLOC);
while (*ndx < len) {
/*
* The first byte contains the primary op code in the top
* 2 bits, so there are 4 of them. Primary OP code
* 0 uses the lower 6 bits to specify a sub-opcode, allowing
* for 64 of them. The other 3 primary op codes use the
* lower 6 bits to hold an operand (a register #, or value).
*
* Check the primary OP code. If it's 1-3, handle it
* and move to the next loop iteration. For OP code 0,
* fall through to decode the sub-code.
*/
op = data[off + (*ndx)++];
opname = conv_dwarf_cfa(op, 0, &inv_buf);
switch (op >> 6) {
case 0x1: /* v2: DW_CFA_advance_loc, delta */
oper1 = state->ciecalign * LOW_OP(op);
cur_pc += oper1;
dbg_print(0, MSG_ORIG(MSG_CFA_ADV_LOC), PREFIX,
loc_str, EC_XWORD(oper1), EC_XWORD(cur_pc));
loc_str = MSG_ORIG(MSG_STR_LOC);
continue;
case 0x2: /* v2: DW_CFA_offset, reg, offset */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
oper1 *= state->ciedalign;
dbg_print(0, MSG_ORIG(MSG_CFA_CFAOFF), PREFIX,
REGNAME(LOW_OP(op), rbuf1), EC_XWORD(oper1));
continue;
case 0x3: /* v2: DW_CFA_restore, reg */
dbg_print(0, MSG_ORIG(MSG_CFA_REG), PREFIX,
REGNAME(LOW_OP(op), rbuf1));
continue;
}
/*
* If we're here, the high order 2 bits are 0. The low 6 bits
* specify a sub-opcode defining the operation.
*/
switch (op) {
case 0x00: /* v2: DW_CFA_nop */
/*
* No-ops are used to fill unused space required
* for alignment. It is common for there to be
* multiple adjacent nops. It saves space to report
* them all with a single line of output.
*/
for (i = 1;
(*ndx < len) && (data[off + *ndx] == 0);
i++, (*ndx)++)
;
dbg_print(0, MSG_ORIG(MSG_CFA_SIMPLEREP), PREFIX, i);
break;
case 0x0a: /* v2: DW_CFA_remember_state */
case 0x0b: /* v2: DW_CFA_restore_state */
case 0x2d: /* GNU: DW_CFA_GNU_window_save */
dbg_print(0, MSG_ORIG(MSG_CFA_SIMPLE), PREFIX);
break;
case 0x01: /* v2: DW_CFA_set_loc, address */
switch (dwarf_ehe_extract(&data[off], len, ndx,
&cur_pc, state->cieRflag, state->e_ident, B_FALSE,
state->sh_addr, off + *ndx, state->gotaddr)) {
case DW_OVERFLOW:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
case DW_BAD_ENCODING:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWBADENC),
state->file, state->sh_name,
state->cieRflag);
return;
case DW_SUCCESS:
break;
}
dbg_print(0, MSG_ORIG(MSG_CFA_CFASET), PREFIX,
EC_XWORD(cur_pc));
break;
case 0x02: /* v2: DW_CFA_advance_loc_1, 1-byte delta */
case 0x03: /* v2: DW_CFA_advance_loc_2, 2-byte delta */
case 0x04: /* v2: DW_CFA_advance_loc_4, 4-byte delta */
/*
* Since the codes are contiguous, and the sizes are
* powers of 2, we can compute the word width from
* the code.
*/
i = 1 << (op - 0x02);
switch (dwarf_extract_uint(data + off, len,
ndx, i, state->do_swap, &oper1)) {
case DW_BAD_ENCODING:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWBADENC),
state->file, state->sh_name,
i);
return;
case DW_OVERFLOW:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
case DW_SUCCESS:
break;
}
oper1 *= state->ciecalign;
cur_pc += oper1;
dbg_print(0, MSG_ORIG(MSG_CFA_ADV_LOC), PREFIX,
loc_str, EC_XWORD(oper1), EC_XWORD(cur_pc));
loc_str = MSG_ORIG(MSG_STR_LOC);
break;
case 0x05: /* v2: DW_CFA_offset_extended,reg,off */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
if (sleb_extract(&data[off], ndx, len, &soper) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
soper *= state->ciedalign;
dbg_print(0, MSG_ORIG(MSG_CFA_CFAOFF), PREFIX,
REGNAME(oper1, rbuf1), EC_SXWORD(soper));
break;
case 0x06: /* v2: DW_CFA_restore_extended, reg */
case 0x0d: /* v2: DW_CFA_def_cfa_register, reg */
case 0x08: /* v2: DW_CFA_same_value, reg */
case 0x07: /* v2: DW_CFA_undefined, reg */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
dbg_print(0, MSG_ORIG(MSG_CFA_REG), PREFIX,
REGNAME(oper1, rbuf1));
break;
case 0x09: /* v2: DW_CFA_register, reg, reg */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
if (uleb_extract(&data[off], ndx, len, &oper2) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
dbg_print(0, MSG_ORIG(MSG_CFA_REG_REG), PREFIX,
REGNAME(oper1, rbuf1), REGNAME(oper2, rbuf2));
break;
case 0x0c: /* v2: DW_CFA_def_cfa, reg, offset */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
if (uleb_extract(&data[off], ndx, len, &oper2) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
dbg_print(0, MSG_ORIG(MSG_CFA_REG_OFFLLU), PREFIX,
REGNAME(oper1, rbuf1), EC_XWORD(oper2));
break;
case 0x0e: /* v2: DW_CFA_def_cfa_offset, offset */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
dbg_print(0, MSG_ORIG(MSG_CFA_LLU), PREFIX,
EC_XWORD(oper1));
break;
case 0x0f: /* v3: DW_CFA_def_cfa_expression, blk */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
dbg_print(0, MSG_ORIG(MSG_CFA_EBLK), PREFIX,
EC_XWORD(oper1));
/* We currently do not decode the expression block */
*ndx += oper1;
break;
case 0x10: /* v3: DW_CFA_expression, reg, blk */
case 0x16: /* v3: DW_CFA_val_expression,reg,blk */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
if (uleb_extract(&data[off], ndx, len, &oper2) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
dbg_print(0, MSG_ORIG(MSG_CFA_REG_EBLK), PREFIX,
REGNAME(oper1, rbuf1), EC_XWORD(oper2));
/* We currently do not decode the expression block */
*ndx += oper2;
break;
case 0x11: /* v3: DW_CFA_offset_extended_sf, reg, off */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
if (sleb_extract(&data[off], ndx, len, &soper) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
soper *= state->ciedalign;
dbg_print(0, MSG_ORIG(MSG_CFA_CFAOFF), PREFIX,
REGNAME(oper1, rbuf1), EC_SXWORD(soper));
break;
case 0x12: /* v3: DW_CFA_def_cfa_sf, reg, offset */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
if (sleb_extract(&data[off], ndx, len, &soper) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
soper *= state->ciedalign;
dbg_print(0, MSG_ORIG(MSG_CFA_REG_OFFLLD), PREFIX,
REGNAME(oper1, rbuf1), EC_SXWORD(soper));
break;
case 0x13: /* DW_CFA_def_cfa_offset_sf, offset */
if (sleb_extract(&data[off], ndx, len, &soper) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
soper *= state->ciedalign;
dbg_print(0, MSG_ORIG(MSG_CFA_LLD), PREFIX,
EC_SXWORD(soper));
break;
case 0x14: /* v3: DW_CFA_val_offset, reg, offset */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
if (sleb_extract(&data[off], ndx, len, &soper) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
soper *= state->ciedalign;
dbg_print(0, MSG_ORIG(MSG_CFA_REG_OFFLLD), PREFIX,
REGNAME(oper1, rbuf1), EC_SXWORD(soper));
break;
case 0x15: /* v3: DW_CFA_val_offset_sf, reg, offset */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
if (sleb_extract(&data[off], ndx, len, &soper) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
soper *= state->ciedalign;
dbg_print(0, MSG_ORIG(MSG_CFA_REG_OFFLLD), PREFIX,
REGNAME(oper1, rbuf1), EC_SXWORD(soper));
break;
case 0x1d: /* GNU: DW_CFA_MIPS_advance_loc8, delta */
switch (dwarf_extract_uint(data + off, len,
ndx, 8, state->do_swap, &oper1)) {
case DW_BAD_ENCODING:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWBADENC),
state->file, state->sh_name,
8);
return;
case DW_OVERFLOW:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
case DW_SUCCESS:
break;
}
oper1 *= state->ciecalign;
cur_pc += oper1;
dbg_print(0, MSG_ORIG(MSG_CFA_ADV_LOC), PREFIX,
loc_str, EC_XWORD(oper1), EC_XWORD(cur_pc));
loc_str = MSG_ORIG(MSG_STR_LOC);
break;
case 0x2e: /* GNU: DW_CFA_GNU_args_size, size */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
dbg_print(0, MSG_ORIG(MSG_CFA_LLU), PREFIX,
EC_XWORD(oper1));
break;
case 0x2f: /* GNU:DW_CFA_GNU_negative_offset_extended,reg,off */
if (uleb_extract(&data[off], ndx, len, &oper1) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
if (sleb_extract(&data[off], ndx, len, &soper) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
state->file, state->sh_name);
return;
}
soper = -soper * state->ciedalign;
soper *= state->ciedalign;
dbg_print(0, MSG_ORIG(MSG_CFA_CFAOFF), PREFIX,
REGNAME(oper1, rbuf1), EC_SXWORD(soper));
break;
default:
/*
* Unrecognized OP code: DWARF data is variable length,
* so we don't know how many bytes to skip in order to
* advance to the next item. We cannot decode beyond
* this point, so dump the remainder in hex.
*/
(*ndx)--; /* Back up to unrecognized opcode */
dump_hex_bytes(data + off + *ndx, len - *ndx,
indent, 8, 1);
(*ndx) = len;
break;
}
}
#undef PREFIX
#undef REGNAME
#undef LOW_OP
}
void
dump_eh_frame(const char *file, char *sh_name, uchar_t *data, size_t datasize,
uint64_t sh_addr, Half e_machine, uchar_t *e_ident, uint64_t gotaddr)
{
Conv_dwarf_ehe_buf_t dwarf_ehe_buf;
dump_cfi_state_t cfi_state;
uint64_t off, ndx, length, id;
uint_t cieid, cielength, cieversion, cieretaddr;
int ciePflag = 0, cieZflag = 0, cieLflag = 0;
int cieLflag_present = 0;
uint_t cieaugndx;
char *cieaugstr = NULL;
boolean_t have_cie = B_FALSE;
cfi_state.file = file;
cfi_state.sh_name = sh_name;
cfi_state.e_machine = e_machine;
cfi_state.e_ident = e_ident;
cfi_state.sh_addr = sh_addr;
cfi_state.do_swap = _elf_sys_encoding() != e_ident[EI_DATA];
cfi_state.gotaddr = gotaddr;
off = 0;
while (off < datasize) {
ndx = 0;
/*
* Extract length in native format. A zero length indicates
* that this CIE is a terminator and that processing for this
* unwind information should end. However, skip this entry and
* keep processing, just in case there is any other information
* remaining in this section. Note, ld(1) will terminate the
* processing of the .eh_frame contents for this file after a
* zero length CIE, thus any information that does follow is
* ignored by ld(1), and is therefore questionable.
*/
if (dwarf_extract_uint(data + off, datasize - off,
&ndx, 4, cfi_state.do_swap, &length) == DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
file, sh_name);
return;
}
if (length == 0) {
dbg_print(0, MSG_ORIG(MSG_UNW_ZEROTERM));
off += 4;
continue;
}
if (length > (datasize - off)) {
(void) fprintf(stderr, MSG_INTL(MSG_ERR_BADCIEFDELEN),
file, sh_name, EC_XWORD(length),
EC_XWORD(sh_addr + off));
/*
* If length is wrong, we have no means to find the
* next entry, just give up
*/
return;
}
/*
* extract CIE id in native format
*/
if (dwarf_extract_uint(data + off, datasize - off, &ndx,
4, cfi_state.do_swap, &id) == DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
file, sh_name);
return;
}
/*
* A CIE record has an id of '0', otherwise this is a
* FDE entry and the 'id' is the CIE pointer.
*/
if (id == 0) {
uint64_t persVal, ndx_save = 0;
uint64_t axsize;
have_cie = B_TRUE;
cielength = length;
cieid = id;
ciePflag = cfi_state.cieRflag = cieZflag = 0;
cieLflag = cieLflag_present = 0;
dbg_print(0, MSG_ORIG(MSG_UNW_CIE),
EC_XWORD(sh_addr + off));
dbg_print(0, MSG_ORIG(MSG_UNW_CIELNGTH),
cielength, cieid);
cieversion = data[off + ndx];
ndx += 1;
cieaugstr = (char *)(&data[off + ndx]);
ndx += strlen(cieaugstr) + 1;
dbg_print(0, MSG_ORIG(MSG_UNW_CIEVERS),
cieversion, cieaugstr);
if (uleb_extract(&data[off], &ndx, datasize - off,
&cfi_state.ciecalign) == DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
file, sh_name);
return;
}
if (sleb_extract(&data[off], &ndx, datasize - off,
&cfi_state.ciedalign) == DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
file, sh_name);
return;
}
cieretaddr = data[off + ndx];
ndx += 1;
dbg_print(0, MSG_ORIG(MSG_UNW_CIECALGN),
EC_XWORD(cfi_state.ciecalign),
EC_XWORD(cfi_state.ciedalign), cieretaddr);
if (cieaugstr[0])
dbg_print(0, MSG_ORIG(MSG_UNW_CIEAXVAL));
for (cieaugndx = 0; cieaugstr[cieaugndx]; cieaugndx++) {
switch (cieaugstr[cieaugndx]) {
case 'z':
if (uleb_extract(&data[off], &ndx,
datasize - off, &axsize) ==
DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
file, sh_name);
return;
}
dbg_print(0, MSG_ORIG(MSG_UNW_CIEAXSIZ),
EC_XWORD(axsize));
cieZflag = 1;
/*
* The auxiliary section can contain
* unused padding bytes at the end, so
* save the current index. Along with
* axsize, we will use it to set ndx to
* the proper continuation index after
* the aux data has been processed.
*/
ndx_save = ndx;
break;
case 'P':
ciePflag = data[off + ndx];
ndx += 1;
switch (dwarf_ehe_extract(&data[off],
datasize - off, &ndx, &persVal,
ciePflag, e_ident, B_FALSE, sh_addr,
off + ndx, gotaddr)) {
case DW_OVERFLOW:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
file, sh_name);
return;
case DW_BAD_ENCODING:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWBADENC),
file, sh_name, ciePflag);
return;
case DW_SUCCESS:
break;
}
dbg_print(0,
MSG_ORIG(MSG_UNW_CIEAXPERS));
dbg_print(0,
MSG_ORIG(MSG_UNW_CIEAXPERSENC),
ciePflag, conv_dwarf_ehe(ciePflag,
&dwarf_ehe_buf));
dbg_print(0,
MSG_ORIG(MSG_UNW_CIEAXPERSRTN),
EC_XWORD(persVal));
break;
case 'R':
cfi_state.cieRflag = data[off + ndx];
ndx += 1;
dbg_print(0,
MSG_ORIG(MSG_UNW_CIEAXCENC),
cfi_state.cieRflag,
conv_dwarf_ehe(cfi_state.cieRflag,
&dwarf_ehe_buf));
break;
case 'L':
cieLflag_present = 1;
cieLflag = data[off + ndx];
ndx += 1;
dbg_print(0,
MSG_ORIG(MSG_UNW_CIEAXLSDA),
cieLflag, conv_dwarf_ehe(
cieLflag, &dwarf_ehe_buf));
break;
default:
dbg_print(0,
MSG_ORIG(MSG_UNW_CIEAXUNEC),
cieaugstr[cieaugndx]);
break;
}
}
/*
* If the z flag was present, reposition ndx using the
* length given. This will safely move us past any
* unaccessed padding bytes in the auxiliary section.
*/
if (cieZflag)
ndx = ndx_save + axsize;
/*
* Any remaining data are Call Frame Instructions
*/
if ((cielength + 4) > ndx)
dump_cfi(data, off, &ndx, cielength, &cfi_state,
MSG_ORIG(MSG_UNW_CIECFI), 3);
off += cielength + 4;
} else {
uint_t fdelength = length;
int fdecieptr = id;
uint64_t fdeaddrrange;
if (!have_cie) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWNOCIE), file, sh_name);
return;
}
dbg_print(0, MSG_ORIG(MSG_UNW_FDE),
EC_XWORD(sh_addr + off));
dbg_print(0, MSG_ORIG(MSG_UNW_FDELNGTH),
fdelength, fdecieptr);
switch (dwarf_ehe_extract(&data[off], datasize - off,
&ndx, &cfi_state.fdeinitloc, cfi_state.cieRflag,
e_ident, B_FALSE, sh_addr, off + ndx, gotaddr)) {
case DW_OVERFLOW:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW), file, sh_name);
return;
case DW_BAD_ENCODING:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWBADENC), file, sh_name,
cfi_state.cieRflag);
return;
case DW_SUCCESS:
break;
}
switch (dwarf_ehe_extract(&data[off], datasize - off,
&ndx, &fdeaddrrange,
(cfi_state.cieRflag & ~DW_EH_PE_pcrel), e_ident,
B_FALSE, sh_addr, off + ndx, gotaddr)) {
case DW_OVERFLOW:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW), file, sh_name);
return;
case DW_BAD_ENCODING:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWBADENC), file, sh_name,
(cfi_state.cieRflag & ~DW_EH_PE_pcrel));
return;
case DW_SUCCESS:
break;
}
dbg_print(0, MSG_ORIG(MSG_UNW_FDEINITLOC),
EC_XWORD(cfi_state.fdeinitloc),
EC_XWORD(fdeaddrrange),
EC_XWORD(cfi_state.fdeinitloc + fdeaddrrange - 1));
if ((cieaugstr != NULL) && (cieaugstr[0] != '\0'))
dbg_print(0, MSG_ORIG(MSG_UNW_FDEAXVAL));
if (cieZflag) {
uint64_t val;
uint64_t lndx;
if (uleb_extract(&data[off], &ndx,
datasize - off, &val) == DW_OVERFLOW) {
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
file, sh_name);
return;
}
lndx = ndx;
ndx += val;
dbg_print(0, MSG_ORIG(MSG_UNW_FDEAXSIZE),
EC_XWORD(val));
if (val && cieLflag_present) {
uint64_t lsda;
switch (dwarf_ehe_extract(&data[off],
datasize - off, &lndx, &lsda,
cieLflag, e_ident, B_FALSE, sh_addr,
off + lndx, gotaddr)) {
case DW_OVERFLOW:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWOVRFLW),
file, sh_name);
return;
case DW_BAD_ENCODING:
(void) fprintf(stderr,
MSG_INTL(MSG_ERR_DWBADENC),
file, sh_name, cieLflag);
return;
case DW_SUCCESS:
break;
}
dbg_print(0,
MSG_ORIG(MSG_UNW_FDEAXLSDA),
EC_XWORD(lsda));
}
}
if ((fdelength + 4) > ndx)
dump_cfi(data, off, &ndx, fdelength, &cfi_state,
MSG_ORIG(MSG_UNW_FDECFI), 6);
off += fdelength + 4;
}
}
}