wine/dlls/dbghelp/dwarf.c
Maarten Lankhorst 1dc3ef5188 dbghelp: Add support for zlib compressed debug sections.
Patch created with the assistance of Eric Pouech who helped diagnose
the problem, wrote some parts of this patch and reviewed this patch.
2013-01-30 20:10:44 +01:00

3513 lines
122 KiB
C

/*
* File dwarf.c - read dwarf2 information from the ELF modules
*
* Copyright (C) 2005, Raphael Junqueira
* Copyright (C) 2006-2011, Eric Pouech
* Copyright (C) 2010, Alexandre Julliard
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
*/
#define NONAMELESSUNION
#include "config.h"
#include <sys/types.h>
#include <fcntl.h>
#ifdef HAVE_SYS_STAT_H
# include <sys/stat.h>
#endif
#ifdef HAVE_SYS_MMAN_H
#include <sys/mman.h>
#endif
#include <limits.h>
#include <stdlib.h>
#include <string.h>
#ifdef HAVE_UNISTD_H
# include <unistd.h>
#endif
#include <stdio.h>
#include <assert.h>
#include <stdarg.h>
#ifdef HAVE_ZLIB
#include <zlib.h>
#endif
#include "windef.h"
#include "winternl.h"
#include "winbase.h"
#include "winuser.h"
#include "ole2.h"
#include "oleauto.h"
#include "dbghelp_private.h"
#include "image_private.h"
#include "wine/debug.h"
WINE_DEFAULT_DEBUG_CHANNEL(dbghelp_dwarf);
/* FIXME:
* - Functions:
* o unspecified parameters
* o inlined functions
* o Debug{Start|End}Point
* o CFA
* - Udt
* o proper types loading (nesting)
*/
#if 0
static void dump(const void* ptr, unsigned len)
{
int i, j;
BYTE msg[128];
static const char hexof[] = "0123456789abcdef";
const BYTE* x = ptr;
for (i = 0; i < len; i += 16)
{
sprintf(msg, "%08x: ", i);
memset(msg + 10, ' ', 3 * 16 + 1 + 16);
for (j = 0; j < min(16, len - i); j++)
{
msg[10 + 3 * j + 0] = hexof[x[i + j] >> 4];
msg[10 + 3 * j + 1] = hexof[x[i + j] & 15];
msg[10 + 3 * j + 2] = ' ';
msg[10 + 3 * 16 + 1 + j] = (x[i + j] >= 0x20 && x[i + j] < 0x7f) ?
x[i + j] : '.';
}
msg[10 + 3 * 16] = ' ';
msg[10 + 3 * 16 + 1 + 16] = '\0';
TRACE("%s\n", msg);
}
}
#endif
/**
*
* Main Specs:
* http://www.eagercon.com/dwarf/dwarf3std.htm
* http://www.eagercon.com/dwarf/dwarf-2.0.0.pdf
*
* dwarf2.h: http://www.hakpetzna.com/b/binutils/dwarf2_8h-source.html
*
* example of projects who do dwarf2 parsing:
* http://www.x86-64.org/cgi-bin/cvsweb.cgi/binutils.dead/binutils/readelf.c?rev=1.1.1.2
* http://elis.ugent.be/diota/log/ltrace_elf.c
*/
#include "dwarf.h"
/**
* Parsers
*/
typedef struct dwarf2_abbrev_entry_attr_s
{
unsigned long attribute;
unsigned long form;
struct dwarf2_abbrev_entry_attr_s* next;
} dwarf2_abbrev_entry_attr_t;
typedef struct dwarf2_abbrev_entry_s
{
unsigned long entry_code;
unsigned long tag;
unsigned char have_child;
unsigned num_attr;
dwarf2_abbrev_entry_attr_t* attrs;
} dwarf2_abbrev_entry_t;
struct dwarf2_block
{
unsigned size;
const unsigned char* ptr;
};
struct attribute
{
unsigned long form;
enum {attr_direct, attr_abstract_origin, attr_specification} gotten_from;
union
{
unsigned long uvalue;
ULONGLONG lluvalue;
long svalue;
const char* string;
struct dwarf2_block block;
} u;
};
typedef struct dwarf2_debug_info_s
{
const dwarf2_abbrev_entry_t*abbrev;
struct symt* symt;
const unsigned char** data;
struct vector children;
struct dwarf2_debug_info_s* parent;
} dwarf2_debug_info_t;
typedef struct dwarf2_section_s
{
BOOL compressed;
const unsigned char* address;
unsigned size;
DWORD_PTR rva;
} dwarf2_section_t;
enum dwarf2_sections {section_debug, section_string, section_abbrev, section_line, section_ranges, section_max};
typedef struct dwarf2_traverse_context_s
{
const unsigned char* data;
const unsigned char* end_data;
unsigned char word_size;
} dwarf2_traverse_context_t;
/* symt_cache indexes */
#define sc_void 0
#define sc_int1 1
#define sc_int2 2
#define sc_int4 3
#define sc_num 4
typedef struct dwarf2_parse_context_s
{
const dwarf2_section_t* sections;
unsigned section;
struct pool pool;
struct module* module;
struct symt_compiland* compiland;
const struct elf_thunk_area*thunks;
struct sparse_array abbrev_table;
struct sparse_array debug_info_table;
unsigned long load_offset;
unsigned long ref_offset;
struct symt* symt_cache[sc_num]; /* void, int1, int2, int4 */
char* cpp_name;
} dwarf2_parse_context_t;
/* stored in the dbghelp's module internal structure for later reuse */
struct dwarf2_module_info_s
{
dwarf2_section_t debug_loc;
dwarf2_section_t debug_frame;
dwarf2_section_t eh_frame;
unsigned char word_size;
};
#define loc_dwarf2_location_list (loc_user + 0)
#define loc_dwarf2_block (loc_user + 1)
/* forward declarations */
static struct symt* dwarf2_parse_enumeration_type(dwarf2_parse_context_t* ctx, dwarf2_debug_info_t* entry);
static unsigned char dwarf2_get_byte(const unsigned char* ptr)
{
return *ptr;
}
static unsigned char dwarf2_parse_byte(dwarf2_traverse_context_t* ctx)
{
unsigned char uvalue = dwarf2_get_byte(ctx->data);
ctx->data += 1;
return uvalue;
}
static unsigned short dwarf2_get_u2(const unsigned char* ptr)
{
return *(const UINT16*)ptr;
}
static unsigned short dwarf2_parse_u2(dwarf2_traverse_context_t* ctx)
{
unsigned short uvalue = dwarf2_get_u2(ctx->data);
ctx->data += 2;
return uvalue;
}
static unsigned long dwarf2_get_u4(const unsigned char* ptr)
{
return *(const UINT32*)ptr;
}
static unsigned long dwarf2_parse_u4(dwarf2_traverse_context_t* ctx)
{
unsigned long uvalue = dwarf2_get_u4(ctx->data);
ctx->data += 4;
return uvalue;
}
static DWORD64 dwarf2_get_u8(const unsigned char* ptr)
{
return *(const UINT64*)ptr;
}
static DWORD64 dwarf2_parse_u8(dwarf2_traverse_context_t* ctx)
{
DWORD64 uvalue = dwarf2_get_u8(ctx->data);
ctx->data += 8;
return uvalue;
}
static unsigned long dwarf2_get_leb128_as_unsigned(const unsigned char* ptr, const unsigned char** end)
{
unsigned long ret = 0;
unsigned char byte;
unsigned shift = 0;
do
{
byte = dwarf2_get_byte(ptr++);
ret |= (byte & 0x7f) << shift;
shift += 7;
} while (byte & 0x80);
if (end) *end = ptr;
return ret;
}
static unsigned long dwarf2_leb128_as_unsigned(dwarf2_traverse_context_t* ctx)
{
unsigned long ret;
assert(ctx);
ret = dwarf2_get_leb128_as_unsigned(ctx->data, &ctx->data);
return ret;
}
static long dwarf2_get_leb128_as_signed(const unsigned char* ptr, const unsigned char** end)
{
long ret = 0;
unsigned char byte;
unsigned shift = 0;
const unsigned size = sizeof(int) * 8;
do
{
byte = dwarf2_get_byte(ptr++);
ret |= (byte & 0x7f) << shift;
shift += 7;
} while (byte & 0x80);
if (end) *end = ptr;
/* as spec: sign bit of byte is 2nd high order bit (80x40)
* -> 0x80 is used as flag.
*/
if ((shift < size) && (byte & 0x40))
{
ret |= - (1 << shift);
}
return ret;
}
static long dwarf2_leb128_as_signed(dwarf2_traverse_context_t* ctx)
{
long ret = 0;
assert(ctx);
ret = dwarf2_get_leb128_as_signed(ctx->data, &ctx->data);
return ret;
}
static unsigned dwarf2_leb128_length(const dwarf2_traverse_context_t* ctx)
{
unsigned ret;
for (ret = 0; ctx->data[ret] & 0x80; ret++);
return ret + 1;
}
/******************************************************************
* dwarf2_get_addr
*
* Returns an address.
* We assume that in all cases word size from Dwarf matches the size of
* addresses in platform where the exec is compiled.
*/
static unsigned long dwarf2_get_addr(const unsigned char* ptr, unsigned word_size)
{
unsigned long ret;
switch (word_size)
{
case 4:
ret = dwarf2_get_u4(ptr);
break;
case 8:
ret = dwarf2_get_u8(ptr);
break;
default:
FIXME("Unsupported Word Size %u\n", word_size);
ret = 0;
}
return ret;
}
static unsigned long dwarf2_parse_addr(dwarf2_traverse_context_t* ctx)
{
unsigned long ret = dwarf2_get_addr(ctx->data, ctx->word_size);
ctx->data += ctx->word_size;
return ret;
}
static const char* dwarf2_debug_traverse_ctx(const dwarf2_traverse_context_t* ctx)
{
return wine_dbg_sprintf("ctx(%p)", ctx->data);
}
static const char* dwarf2_debug_ctx(const dwarf2_parse_context_t* ctx)
{
return wine_dbg_sprintf("ctx(%p,%s)",
ctx, debugstr_w(ctx->module->module.ModuleName));
}
static const char* dwarf2_debug_di(const dwarf2_debug_info_t* di)
{
return wine_dbg_sprintf("debug_info(abbrev:%p,symt:%p)",
di->abbrev, di->symt);
}
static dwarf2_abbrev_entry_t*
dwarf2_abbrev_table_find_entry(const struct sparse_array* abbrev_table,
unsigned long entry_code)
{
assert( NULL != abbrev_table );
return sparse_array_find(abbrev_table, entry_code);
}
static void dwarf2_parse_abbrev_set(dwarf2_traverse_context_t* abbrev_ctx,
struct sparse_array* abbrev_table,
struct pool* pool)
{
unsigned long entry_code;
dwarf2_abbrev_entry_t* abbrev_entry;
dwarf2_abbrev_entry_attr_t* new = NULL;
dwarf2_abbrev_entry_attr_t* last = NULL;
unsigned long attribute;
unsigned long form;
assert( NULL != abbrev_ctx );
TRACE("%s, end at %p\n",
dwarf2_debug_traverse_ctx(abbrev_ctx), abbrev_ctx->end_data);
sparse_array_init(abbrev_table, sizeof(dwarf2_abbrev_entry_t), 32);
while (abbrev_ctx->data < abbrev_ctx->end_data)
{
TRACE("now at %s\n", dwarf2_debug_traverse_ctx(abbrev_ctx));
entry_code = dwarf2_leb128_as_unsigned(abbrev_ctx);
TRACE("found entry_code %lu\n", entry_code);
if (!entry_code)
{
TRACE("NULL entry code at %s\n", dwarf2_debug_traverse_ctx(abbrev_ctx));
break;
}
abbrev_entry = sparse_array_add(abbrev_table, entry_code, pool);
assert( NULL != abbrev_entry );
abbrev_entry->entry_code = entry_code;
abbrev_entry->tag = dwarf2_leb128_as_unsigned(abbrev_ctx);
abbrev_entry->have_child = dwarf2_parse_byte(abbrev_ctx);
abbrev_entry->attrs = NULL;
abbrev_entry->num_attr = 0;
TRACE("table:(%p,#%u) entry_code(%lu) tag(0x%lx) have_child(%u) -> %p\n",
abbrev_table, sparse_array_length(abbrev_table),
entry_code, abbrev_entry->tag, abbrev_entry->have_child, abbrev_entry);
last = NULL;
while (1)
{
attribute = dwarf2_leb128_as_unsigned(abbrev_ctx);
form = dwarf2_leb128_as_unsigned(abbrev_ctx);
if (!attribute) break;
new = pool_alloc(pool, sizeof(dwarf2_abbrev_entry_attr_t));
assert(new);
new->attribute = attribute;
new->form = form;
new->next = NULL;
if (abbrev_entry->attrs) last->next = new;
else abbrev_entry->attrs = new;
last = new;
abbrev_entry->num_attr++;
}
}
TRACE("found %u entries\n", sparse_array_length(abbrev_table));
}
static void dwarf2_swallow_attribute(dwarf2_traverse_context_t* ctx,
const dwarf2_abbrev_entry_attr_t* abbrev_attr)
{
unsigned step;
TRACE("(attr:0x%lx,form:0x%lx)\n", abbrev_attr->attribute, abbrev_attr->form);
switch (abbrev_attr->form)
{
case DW_FORM_ref_addr:
case DW_FORM_addr: step = ctx->word_size; break;
case DW_FORM_flag:
case DW_FORM_data1:
case DW_FORM_ref1: step = 1; break;
case DW_FORM_data2:
case DW_FORM_ref2: step = 2; break;
case DW_FORM_data4:
case DW_FORM_ref4:
case DW_FORM_strp: step = 4; break;
case DW_FORM_data8:
case DW_FORM_ref8: step = 8; break;
case DW_FORM_sdata:
case DW_FORM_ref_udata:
case DW_FORM_udata: step = dwarf2_leb128_length(ctx); break;
case DW_FORM_string: step = strlen((const char*)ctx->data) + 1; break;
case DW_FORM_block: step = dwarf2_leb128_as_unsigned(ctx); break;
case DW_FORM_block1: step = dwarf2_parse_byte(ctx); break;
case DW_FORM_block2: step = dwarf2_parse_u2(ctx); break;
case DW_FORM_block4: step = dwarf2_parse_u4(ctx); break;
default:
FIXME("Unhandled attribute form %lx\n", abbrev_attr->form);
return;
}
ctx->data += step;
}
static void dwarf2_fill_attr(const dwarf2_parse_context_t* ctx,
const dwarf2_abbrev_entry_attr_t* abbrev_attr,
const unsigned char* data,
struct attribute* attr)
{
attr->form = abbrev_attr->form;
switch (attr->form)
{
case DW_FORM_ref_addr:
case DW_FORM_addr:
attr->u.uvalue = dwarf2_get_addr(data,
ctx->module->format_info[DFI_DWARF]->u.dwarf2_info->word_size);
TRACE("addr<0x%lx>\n", attr->u.uvalue);
break;
case DW_FORM_flag:
attr->u.uvalue = dwarf2_get_byte(data);
TRACE("flag<0x%lx>\n", attr->u.uvalue);
break;
case DW_FORM_data1:
attr->u.uvalue = dwarf2_get_byte(data);
TRACE("data1<%lu>\n", attr->u.uvalue);
break;
case DW_FORM_data2:
attr->u.uvalue = dwarf2_get_u2(data);
TRACE("data2<%lu>\n", attr->u.uvalue);
break;
case DW_FORM_data4:
attr->u.uvalue = dwarf2_get_u4(data);
TRACE("data4<%lu>\n", attr->u.uvalue);
break;
case DW_FORM_data8:
attr->u.lluvalue = dwarf2_get_u8(data);
TRACE("data8<%s>\n", wine_dbgstr_longlong(attr->u.uvalue));
break;
case DW_FORM_ref1:
attr->u.uvalue = ctx->ref_offset + dwarf2_get_byte(data);
TRACE("ref1<0x%lx>\n", attr->u.uvalue);
break;
case DW_FORM_ref2:
attr->u.uvalue = ctx->ref_offset + dwarf2_get_u2(data);
TRACE("ref2<0x%lx>\n", attr->u.uvalue);
break;
case DW_FORM_ref4:
attr->u.uvalue = ctx->ref_offset + dwarf2_get_u4(data);
TRACE("ref4<0x%lx>\n", attr->u.uvalue);
break;
case DW_FORM_ref8:
FIXME("Unhandled 64 bit support\n");
break;
case DW_FORM_sdata:
attr->u.svalue = dwarf2_get_leb128_as_signed(data, NULL);
break;
case DW_FORM_ref_udata:
attr->u.uvalue = dwarf2_get_leb128_as_unsigned(data, NULL);
break;
case DW_FORM_udata:
attr->u.uvalue = dwarf2_get_leb128_as_unsigned(data, NULL);
break;
case DW_FORM_string:
attr->u.string = (const char *)data;
TRACE("string<%s>\n", attr->u.string);
break;
case DW_FORM_strp:
{
unsigned long offset = dwarf2_get_u4(data);
attr->u.string = (const char*)ctx->sections[section_string].address + offset;
}
TRACE("strp<%s>\n", attr->u.string);
break;
case DW_FORM_block:
attr->u.block.size = dwarf2_get_leb128_as_unsigned(data, &attr->u.block.ptr);
break;
case DW_FORM_block1:
attr->u.block.size = dwarf2_get_byte(data);
attr->u.block.ptr = data + 1;
break;
case DW_FORM_block2:
attr->u.block.size = dwarf2_get_u2(data);
attr->u.block.ptr = data + 2;
break;
case DW_FORM_block4:
attr->u.block.size = dwarf2_get_u4(data);
attr->u.block.ptr = data + 4;
break;
default:
FIXME("Unhandled attribute form %lx\n", abbrev_attr->form);
break;
}
}
static BOOL dwarf2_find_attribute(const dwarf2_parse_context_t* ctx,
const dwarf2_debug_info_t* di,
unsigned at, struct attribute* attr)
{
unsigned i, refidx = 0;
dwarf2_abbrev_entry_attr_t* abbrev_attr;
dwarf2_abbrev_entry_attr_t* ref_abbrev_attr = NULL;
attr->gotten_from = attr_direct;
while (di)
{
ref_abbrev_attr = NULL;
for (i = 0, abbrev_attr = di->abbrev->attrs; abbrev_attr; i++, abbrev_attr = abbrev_attr->next)
{
if (abbrev_attr->attribute == at)
{
dwarf2_fill_attr(ctx, abbrev_attr, di->data[i], attr);
return TRUE;
}
if ((abbrev_attr->attribute == DW_AT_abstract_origin ||
abbrev_attr->attribute == DW_AT_specification) &&
at != DW_AT_sibling)
{
if (ref_abbrev_attr)
FIXME("two references %lx and %lx\n", ref_abbrev_attr->attribute, abbrev_attr->attribute);
ref_abbrev_attr = abbrev_attr;
refidx = i;
attr->gotten_from = (abbrev_attr->attribute == DW_AT_abstract_origin) ?
attr_abstract_origin : attr_specification;
}
}
/* do we have either an abstract origin or a specification debug entry to look into ? */
if (!ref_abbrev_attr) break;
dwarf2_fill_attr(ctx, ref_abbrev_attr, di->data[refidx], attr);
if (!(di = sparse_array_find(&ctx->debug_info_table, attr->u.uvalue)))
FIXME("Should have found the debug info entry\n");
}
return FALSE;
}
static void dwarf2_load_one_entry(dwarf2_parse_context_t*, dwarf2_debug_info_t*);
#define Wine_DW_no_register 0x7FFFFFFF
static unsigned dwarf2_map_register(int regno)
{
if (regno == Wine_DW_no_register)
{
FIXME("What the heck map reg 0x%x\n",regno);
return 0;
}
return dbghelp_current_cpu->map_dwarf_register(regno);
}
static enum location_error
compute_location(dwarf2_traverse_context_t* ctx, struct location* loc,
HANDLE hproc, const struct location* frame)
{
DWORD_PTR tmp, stack[64];
unsigned stk;
unsigned char op;
BOOL piece_found = FALSE;
stack[stk = 0] = 0;
loc->kind = loc_absolute;
loc->reg = Wine_DW_no_register;
while (ctx->data < ctx->end_data)
{
op = dwarf2_parse_byte(ctx);
if (op >= DW_OP_lit0 && op <= DW_OP_lit31)
stack[++stk] = op - DW_OP_lit0;
else if (op >= DW_OP_reg0 && op <= DW_OP_reg31)
{
/* dbghelp APIs don't know how to cope with this anyway
* (for example 'long long' stored in two registers)
* FIXME: We should tell winedbg how to deal with it (sigh)
*/
if (!piece_found)
{
DWORD cvreg = dwarf2_map_register(op - DW_OP_reg0);
if (loc->reg != Wine_DW_no_register)
FIXME("Only supporting one reg (%s/%d -> %s/%d)\n",
dbghelp_current_cpu->fetch_regname(loc->reg), loc->reg,
dbghelp_current_cpu->fetch_regname(cvreg), cvreg);
loc->reg = cvreg;
}
loc->kind = loc_register;
}
else if (op >= DW_OP_breg0 && op <= DW_OP_breg31)
{
/* dbghelp APIs don't know how to cope with this anyway
* (for example 'long long' stored in two registers)
* FIXME: We should tell winedbg how to deal with it (sigh)
*/
if (!piece_found)
{
DWORD cvreg = dwarf2_map_register(op - DW_OP_breg0);
if (loc->reg != Wine_DW_no_register)
FIXME("Only supporting one breg (%s/%d -> %s/%d)\n",
dbghelp_current_cpu->fetch_regname(loc->reg), loc->reg,
dbghelp_current_cpu->fetch_regname(cvreg), cvreg);
loc->reg = cvreg;
}
stack[++stk] = dwarf2_leb128_as_signed(ctx);
loc->kind = loc_regrel;
}
else switch (op)
{
case DW_OP_nop: break;
case DW_OP_addr: stack[++stk] = dwarf2_parse_addr(ctx); break;
case DW_OP_const1u: stack[++stk] = dwarf2_parse_byte(ctx); break;
case DW_OP_const1s: stack[++stk] = dwarf2_parse_byte(ctx); break;
case DW_OP_const2u: stack[++stk] = dwarf2_parse_u2(ctx); break;
case DW_OP_const2s: stack[++stk] = dwarf2_parse_u2(ctx); break;
case DW_OP_const4u: stack[++stk] = dwarf2_parse_u4(ctx); break;
case DW_OP_const4s: stack[++stk] = dwarf2_parse_u4(ctx); break;
case DW_OP_const8u: stack[++stk] = dwarf2_parse_u8(ctx); break;
case DW_OP_const8s: stack[++stk] = dwarf2_parse_u8(ctx); break;
case DW_OP_constu: stack[++stk] = dwarf2_leb128_as_unsigned(ctx); break;
case DW_OP_consts: stack[++stk] = dwarf2_leb128_as_signed(ctx); break;
case DW_OP_dup: stack[stk + 1] = stack[stk]; stk++; break;
case DW_OP_drop: stk--; break;
case DW_OP_over: stack[stk + 1] = stack[stk - 1]; stk++; break;
case DW_OP_pick: stack[stk + 1] = stack[stk - dwarf2_parse_byte(ctx)]; stk++; break;
case DW_OP_swap: tmp = stack[stk]; stack[stk] = stack[stk-1]; stack[stk-1] = tmp; break;
case DW_OP_rot: tmp = stack[stk]; stack[stk] = stack[stk-1]; stack[stk-1] = stack[stk-2]; stack[stk-2] = tmp; break;
case DW_OP_abs: stack[stk] = labs(stack[stk]); break;
case DW_OP_neg: stack[stk] = -stack[stk]; break;
case DW_OP_not: stack[stk] = ~stack[stk]; break;
case DW_OP_and: stack[stk-1] &= stack[stk]; stk--; break;
case DW_OP_or: stack[stk-1] |= stack[stk]; stk--; break;
case DW_OP_minus: stack[stk-1] -= stack[stk]; stk--; break;
case DW_OP_mul: stack[stk-1] *= stack[stk]; stk--; break;
case DW_OP_plus: stack[stk-1] += stack[stk]; stk--; break;
case DW_OP_xor: stack[stk-1] ^= stack[stk]; stk--; break;
case DW_OP_shl: stack[stk-1] <<= stack[stk]; stk--; break;
case DW_OP_shr: stack[stk-1] >>= stack[stk]; stk--; break;
case DW_OP_plus_uconst: stack[stk] += dwarf2_leb128_as_unsigned(ctx); break;
case DW_OP_shra: stack[stk-1] = stack[stk-1] / (1 << stack[stk]); stk--; break;
case DW_OP_div: stack[stk-1] = stack[stk-1] / stack[stk]; stk--; break;
case DW_OP_mod: stack[stk-1] = stack[stk-1] % stack[stk]; stk--; break;
case DW_OP_ge: stack[stk-1] = (stack[stk-1] >= stack[stk]); stk--; break;
case DW_OP_gt: stack[stk-1] = (stack[stk-1] > stack[stk]); stk--; break;
case DW_OP_le: stack[stk-1] = (stack[stk-1] <= stack[stk]); stk--; break;
case DW_OP_lt: stack[stk-1] = (stack[stk-1] < stack[stk]); stk--; break;
case DW_OP_eq: stack[stk-1] = (stack[stk-1] == stack[stk]); stk--; break;
case DW_OP_ne: stack[stk-1] = (stack[stk-1] != stack[stk]); stk--; break;
case DW_OP_skip: tmp = dwarf2_parse_u2(ctx); ctx->data += tmp; break;
case DW_OP_bra: tmp = dwarf2_parse_u2(ctx); if (!stack[stk--]) ctx->data += tmp; break;
case DW_OP_regx:
tmp = dwarf2_leb128_as_unsigned(ctx);
if (!piece_found)
{
if (loc->reg != Wine_DW_no_register)
FIXME("Only supporting one reg\n");
loc->reg = dwarf2_map_register(tmp);
}
loc->kind = loc_register;
break;
case DW_OP_bregx:
tmp = dwarf2_leb128_as_unsigned(ctx);
if (loc->reg != Wine_DW_no_register)
FIXME("Only supporting one regx\n");
loc->reg = dwarf2_map_register(tmp);
stack[++stk] = dwarf2_leb128_as_signed(ctx);
loc->kind = loc_regrel;
break;
case DW_OP_fbreg:
if (loc->reg != Wine_DW_no_register)
FIXME("Only supporting one reg (%s/%d -> -2)\n",
dbghelp_current_cpu->fetch_regname(loc->reg), loc->reg);
if (frame && frame->kind == loc_register)
{
loc->kind = loc_regrel;
loc->reg = frame->reg;
stack[++stk] = dwarf2_leb128_as_signed(ctx);
}
else if (frame && frame->kind == loc_regrel)
{
loc->kind = loc_regrel;
loc->reg = frame->reg;
stack[++stk] = dwarf2_leb128_as_signed(ctx) + frame->offset;
}
else
{
/* FIXME: this could be later optimized by not recomputing
* this very location expression
*/
loc->kind = loc_dwarf2_block;
stack[++stk] = dwarf2_leb128_as_signed(ctx);
}
break;
case DW_OP_piece:
{
unsigned sz = dwarf2_leb128_as_unsigned(ctx);
WARN("Not handling OP_piece (size=%d)\n", sz);
piece_found = TRUE;
}
break;
case DW_OP_deref:
if (!stk)
{
FIXME("Unexpected empty stack\n");
return loc_err_internal;
}
if (loc->reg != Wine_DW_no_register)
{
WARN("Too complex expression for deref\n");
return loc_err_too_complex;
}
if (hproc)
{
DWORD_PTR addr = stack[stk--];
DWORD_PTR deref;
if (!ReadProcessMemory(hproc, (void*)addr, &deref, sizeof(deref), NULL))
{
WARN("Couldn't read memory at %lx\n", addr);
return loc_err_cant_read;
}
stack[++stk] = deref;
}
else
{
loc->kind = loc_dwarf2_block;
}
break;
case DW_OP_deref_size:
if (!stk)
{
FIXME("Unexpected empty stack\n");
return loc_err_internal;
}
if (loc->reg != Wine_DW_no_register)
{
WARN("Too complex expression for deref\n");
return loc_err_too_complex;
}
if (hproc)
{
DWORD_PTR addr = stack[stk--];
BYTE derefsize = dwarf2_parse_byte(ctx);
DWORD64 deref;
if (!ReadProcessMemory(hproc, (void*)addr, &deref, derefsize, NULL))
{
WARN("Couldn't read memory at %lx\n", addr);
return loc_err_cant_read;
}
switch (derefsize)
{
case 1: stack[++stk] = *(unsigned char*)&deref; break;
case 2: stack[++stk] = *(unsigned short*)&deref; break;
case 4: stack[++stk] = *(DWORD*)&deref; break;
case 8: if (ctx->word_size >= derefsize) stack[++stk] = deref; break;
}
}
else
{
dwarf2_parse_byte(ctx);
loc->kind = loc_dwarf2_block;
}
break;
case DW_OP_stack_value:
/* Expected behaviour is that this is the last instruction of this
* expression and just the "top of stack" value should be put to loc->offset. */
break;
default:
if (op < DW_OP_lo_user) /* as DW_OP_hi_user is 0xFF, we don't need to test against it */
FIXME("Unhandled attr op: %x\n", op);
/* FIXME else unhandled extension */
return loc_err_internal;
}
}
loc->offset = stack[stk];
return 0;
}
static BOOL dwarf2_compute_location_attr(dwarf2_parse_context_t* ctx,
const dwarf2_debug_info_t* di,
unsigned long dw,
struct location* loc,
const struct location* frame)
{
struct attribute xloc;
if (!dwarf2_find_attribute(ctx, di, dw, &xloc)) return FALSE;
switch (xloc.form)
{
case DW_FORM_data1: case DW_FORM_data2:
case DW_FORM_udata: case DW_FORM_sdata:
loc->kind = loc_absolute;
loc->reg = 0;
loc->offset = xloc.u.uvalue;
return TRUE;
case DW_FORM_data4: case DW_FORM_data8:
loc->kind = loc_dwarf2_location_list;
loc->reg = Wine_DW_no_register;
loc->offset = xloc.u.uvalue;
return TRUE;
case DW_FORM_block:
case DW_FORM_block1:
case DW_FORM_block2:
case DW_FORM_block4:
break;
default: FIXME("Unsupported yet form %lx\n", xloc.form);
return FALSE;
}
/* assume we have a block form */
if (xloc.u.block.size)
{
dwarf2_traverse_context_t lctx;
enum location_error err;
lctx.data = xloc.u.block.ptr;
lctx.end_data = xloc.u.block.ptr + xloc.u.block.size;
lctx.word_size = ctx->module->format_info[DFI_DWARF]->u.dwarf2_info->word_size;
err = compute_location(&lctx, loc, NULL, frame);
if (err < 0)
{
loc->kind = loc_error;
loc->reg = err;
}
else if (loc->kind == loc_dwarf2_block)
{
unsigned* ptr = pool_alloc(&ctx->module->pool,
sizeof(unsigned) + xloc.u.block.size);
*ptr = xloc.u.block.size;
memcpy(ptr + 1, xloc.u.block.ptr, xloc.u.block.size);
loc->offset = (unsigned long)ptr;
}
}
return TRUE;
}
static struct symt* dwarf2_lookup_type(dwarf2_parse_context_t* ctx,
const dwarf2_debug_info_t* di)
{
struct attribute attr;
dwarf2_debug_info_t* type;
if (!dwarf2_find_attribute(ctx, di, DW_AT_type, &attr))
return NULL;
if (!(type = sparse_array_find(&ctx->debug_info_table, attr.u.uvalue)))
{
FIXME("Unable to find back reference to type %lx\n", attr.u.uvalue);
return NULL;
}
if (!type->symt)
{
/* load the debug info entity */
dwarf2_load_one_entry(ctx, type);
if (!type->symt)
FIXME("Unable to load forward reference for tag %lx\n", type->abbrev->tag);
}
return type->symt;
}
static const char* dwarf2_get_cpp_name(dwarf2_parse_context_t* ctx, dwarf2_debug_info_t* di, const char* name)
{
char* last;
struct attribute diname;
struct attribute spec;
if (di->abbrev->tag == DW_TAG_compile_unit) return name;
if (!ctx->cpp_name)
ctx->cpp_name = pool_alloc(&ctx->pool, MAX_SYM_NAME);
last = ctx->cpp_name + MAX_SYM_NAME - strlen(name) - 1;
strcpy(last, name);
/* if the di is a definition, but has also a (previous) declaration, then scope must
* be gotten from declaration not definition
*/
if (dwarf2_find_attribute(ctx, di, DW_AT_specification, &spec) && spec.gotten_from == attr_direct)
{
di = sparse_array_find(&ctx->debug_info_table, spec.u.uvalue);
if (!di)
{
FIXME("Should have found the debug info entry\n");
return NULL;
}
}
for (di = di->parent; di; di = di->parent)
{
switch (di->abbrev->tag)
{
case DW_TAG_namespace:
case DW_TAG_structure_type:
case DW_TAG_class_type:
case DW_TAG_interface_type:
case DW_TAG_union_type:
if (dwarf2_find_attribute(ctx, di, DW_AT_name, &diname))
{
size_t len = strlen(diname.u.string);
last -= 2 + len;
if (last < ctx->cpp_name) return NULL;
memcpy(last, diname.u.string, len);
last[len] = last[len + 1] = ':';
}
break;
default:
break;
}
}
return last;
}
/******************************************************************
* dwarf2_read_range
*
* read a range for a given debug_info (either using AT_range attribute, in which
* case we don't return all the details, or using AT_low_pc & AT_high_pc attributes)
* in all cases, range is relative to beginning of compilation unit
*/
static BOOL dwarf2_read_range(dwarf2_parse_context_t* ctx, const dwarf2_debug_info_t* di,
unsigned long* plow, unsigned long* phigh)
{
struct attribute range;
if (dwarf2_find_attribute(ctx, di, DW_AT_ranges, &range))
{
dwarf2_traverse_context_t traverse;
unsigned long low, high;
traverse.data = ctx->sections[section_ranges].address + range.u.uvalue;
traverse.end_data = ctx->sections[section_ranges].address +
ctx->sections[section_ranges].size;
traverse.word_size = ctx->module->format_info[DFI_DWARF]->u.dwarf2_info->word_size;
*plow = ULONG_MAX;
*phigh = 0;
while (traverse.data + 2 * traverse.word_size < traverse.end_data)
{
low = dwarf2_parse_addr(&traverse);
high = dwarf2_parse_addr(&traverse);
if (low == 0 && high == 0) break;
if (low == ULONG_MAX) FIXME("unsupported yet (base address selection)\n");
if (low < *plow) *plow = low;
if (high > *phigh) *phigh = high;
}
if (*plow == ULONG_MAX || *phigh == 0) {FIXME("no entry found\n"); return FALSE;}
if (*plow == *phigh) {FIXME("entry found, but low=high\n"); return FALSE;}
return TRUE;
}
else
{
struct attribute low_pc;
struct attribute high_pc;
if (!dwarf2_find_attribute(ctx, di, DW_AT_low_pc, &low_pc) ||
!dwarf2_find_attribute(ctx, di, DW_AT_high_pc, &high_pc))
return FALSE;
*plow = low_pc.u.uvalue;
*phigh = high_pc.u.uvalue;
return TRUE;
}
}
/******************************************************************
* dwarf2_read_one_debug_info
*
* Loads into memory one debug info entry, and recursively its children (if any)
*/
static BOOL dwarf2_read_one_debug_info(dwarf2_parse_context_t* ctx,
dwarf2_traverse_context_t* traverse,
dwarf2_debug_info_t* parent_di,
dwarf2_debug_info_t** pdi)
{
const dwarf2_abbrev_entry_t*abbrev;
unsigned long entry_code;
unsigned long offset;
dwarf2_debug_info_t* di;
dwarf2_debug_info_t* child;
dwarf2_debug_info_t** where;
dwarf2_abbrev_entry_attr_t* attr;
unsigned i;
struct attribute sibling;
offset = traverse->data - ctx->sections[ctx->section].address;
entry_code = dwarf2_leb128_as_unsigned(traverse);
TRACE("found entry_code %lu at 0x%lx\n", entry_code, offset);
if (!entry_code)
{
*pdi = NULL;
return TRUE;
}
abbrev = dwarf2_abbrev_table_find_entry(&ctx->abbrev_table, entry_code);
if (!abbrev)
{
WARN("Cannot find abbrev entry for %lu at 0x%lx\n", entry_code, offset);
return FALSE;
}
di = sparse_array_add(&ctx->debug_info_table, offset, &ctx->pool);
if (!di) return FALSE;
di->abbrev = abbrev;
di->symt = NULL;
di->parent = parent_di;
if (abbrev->num_attr)
{
di->data = pool_alloc(&ctx->pool, abbrev->num_attr * sizeof(const char*));
for (i = 0, attr = abbrev->attrs; attr; i++, attr = attr->next)
{
di->data[i] = traverse->data;
dwarf2_swallow_attribute(traverse, attr);
}
}
else di->data = NULL;
if (abbrev->have_child)
{
vector_init(&di->children, sizeof(dwarf2_debug_info_t*), 16);
while (traverse->data < traverse->end_data)
{
if (!dwarf2_read_one_debug_info(ctx, traverse, di, &child)) return FALSE;
if (!child) break;
where = vector_add(&di->children, &ctx->pool);
if (!where) return FALSE;
*where = child;
}
}
if (dwarf2_find_attribute(ctx, di, DW_AT_sibling, &sibling) &&
traverse->data != ctx->sections[ctx->section].address + sibling.u.uvalue)
{
WARN("setting cursor for %s to next sibling <0x%lx>\n",
dwarf2_debug_traverse_ctx(traverse), sibling.u.uvalue);
traverse->data = ctx->sections[ctx->section].address + sibling.u.uvalue;
}
*pdi = di;
return TRUE;
}
static struct vector* dwarf2_get_di_children(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct attribute spec;
while (di)
{
if (di->abbrev->have_child)
return &di->children;
if (!dwarf2_find_attribute(ctx, di, DW_AT_specification, &spec)) break;
if (!(di = sparse_array_find(&ctx->debug_info_table, spec.u.uvalue)))
FIXME("Should have found the debug info entry\n");
}
return NULL;
}
static struct symt* dwarf2_parse_base_type(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct attribute name;
struct attribute size;
struct attribute encoding;
enum BasicType bt;
int cache_idx = -1;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
if (!dwarf2_find_attribute(ctx, di, DW_AT_name, &name))
name.u.string = NULL;
if (!dwarf2_find_attribute(ctx, di, DW_AT_byte_size, &size)) size.u.uvalue = 0;
if (!dwarf2_find_attribute(ctx, di, DW_AT_encoding, &encoding)) encoding.u.uvalue = DW_ATE_void;
switch (encoding.u.uvalue)
{
case DW_ATE_void: bt = btVoid; break;
case DW_ATE_address: bt = btULong; break;
case DW_ATE_boolean: bt = btBool; break;
case DW_ATE_complex_float: bt = btComplex; break;
case DW_ATE_float: bt = btFloat; break;
case DW_ATE_signed: bt = btInt; break;
case DW_ATE_unsigned: bt = btUInt; break;
case DW_ATE_signed_char: bt = btChar; break;
case DW_ATE_unsigned_char: bt = btChar; break;
default: bt = btNoType; break;
}
di->symt = &symt_new_basic(ctx->module, bt, name.u.string, size.u.uvalue)->symt;
switch (bt)
{
case btVoid:
assert(size.u.uvalue == 0);
cache_idx = sc_void;
break;
case btInt:
switch (size.u.uvalue)
{
case 1: cache_idx = sc_int1; break;
case 2: cache_idx = sc_int2; break;
case 4: cache_idx = sc_int4; break;
}
break;
default: break;
}
if (cache_idx != -1 && !ctx->symt_cache[cache_idx])
ctx->symt_cache[cache_idx] = di->symt;
if (dwarf2_get_di_children(ctx, di)) FIXME("Unsupported children\n");
return di->symt;
}
static struct symt* dwarf2_parse_typedef(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct symt* ref_type;
struct attribute name;
if (di->symt) return di->symt;
TRACE("%s, for %lu\n", dwarf2_debug_ctx(ctx), di->abbrev->entry_code);
if (!dwarf2_find_attribute(ctx, di, DW_AT_name, &name)) name.u.string = NULL;
ref_type = dwarf2_lookup_type(ctx, di);
if (name.u.string)
di->symt = &symt_new_typedef(ctx->module, ref_type, name.u.string)->symt;
if (dwarf2_get_di_children(ctx, di)) FIXME("Unsupported children\n");
return di->symt;
}
static struct symt* dwarf2_parse_pointer_type(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct symt* ref_type;
struct attribute size;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
if (!dwarf2_find_attribute(ctx, di, DW_AT_byte_size, &size)) size.u.uvalue = sizeof(void *);
if (!(ref_type = dwarf2_lookup_type(ctx, di)))
{
ref_type = ctx->symt_cache[sc_void];
assert(ref_type);
}
di->symt = &symt_new_pointer(ctx->module, ref_type, size.u.uvalue)->symt;
if (dwarf2_get_di_children(ctx, di)) FIXME("Unsupported children\n");
return di->symt;
}
static struct symt* dwarf2_parse_array_type(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct symt* ref_type;
struct symt* idx_type = NULL;
struct attribute min, max, cnt;
dwarf2_debug_info_t* child;
unsigned int i;
const struct vector* children;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
ref_type = dwarf2_lookup_type(ctx, di);
if (!(children = dwarf2_get_di_children(ctx, di)))
{
/* fake an array with unknown size */
/* FIXME: int4 even on 64bit machines??? */
idx_type = ctx->symt_cache[sc_int4];
min.u.uvalue = 0;
max.u.uvalue = -1;
}
else for (i = 0; i < vector_length(children); i++)
{
child = *(dwarf2_debug_info_t**)vector_at(children, i);
switch (child->abbrev->tag)
{
case DW_TAG_subrange_type:
idx_type = dwarf2_lookup_type(ctx, child);
if (!dwarf2_find_attribute(ctx, child, DW_AT_lower_bound, &min))
min.u.uvalue = 0;
if (!dwarf2_find_attribute(ctx, child, DW_AT_upper_bound, &max))
max.u.uvalue = 0;
if (dwarf2_find_attribute(ctx, child, DW_AT_count, &cnt))
max.u.uvalue = min.u.uvalue + cnt.u.uvalue;
break;
default:
FIXME("Unhandled Tag type 0x%lx at %s, for %s\n",
child->abbrev->tag, dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
break;
}
}
di->symt = &symt_new_array(ctx->module, min.u.uvalue, max.u.uvalue, ref_type, idx_type)->symt;
return di->symt;
}
static struct symt* dwarf2_parse_const_type(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct symt* ref_type;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
if (!(ref_type = dwarf2_lookup_type(ctx, di)))
{
ref_type = ctx->symt_cache[sc_void];
assert(ref_type);
}
if (dwarf2_get_di_children(ctx, di)) FIXME("Unsupported children\n");
di->symt = ref_type;
return ref_type;
}
static struct symt* dwarf2_parse_volatile_type(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct symt* ref_type;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
if (!(ref_type = dwarf2_lookup_type(ctx, di)))
{
ref_type = ctx->symt_cache[sc_void];
assert(ref_type);
}
if (dwarf2_get_di_children(ctx, di)) FIXME("Unsupported children\n");
di->symt = ref_type;
return ref_type;
}
static struct symt* dwarf2_parse_reference_type(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct symt* ref_type = NULL;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
ref_type = dwarf2_lookup_type(ctx, di);
/* FIXME: for now, we hard-wire C++ references to pointers */
di->symt = &symt_new_pointer(ctx->module, ref_type, sizeof(void *))->symt;
if (dwarf2_get_di_children(ctx, di)) FIXME("Unsupported children\n");
return di->symt;
}
static void dwarf2_parse_udt_member(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di,
struct symt_udt* parent)
{
struct symt* elt_type;
struct attribute name;
struct attribute bit_size;
struct attribute bit_offset;
struct location loc;
assert(parent);
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
if (!dwarf2_find_attribute(ctx, di, DW_AT_name, &name)) name.u.string = NULL;
elt_type = dwarf2_lookup_type(ctx, di);
if (dwarf2_compute_location_attr(ctx, di, DW_AT_data_member_location, &loc, NULL))
{
if (loc.kind != loc_absolute)
{
FIXME("Found register, while not expecting it\n");
loc.offset = 0;
}
else
TRACE("found member_location at %s -> %lu\n",
dwarf2_debug_ctx(ctx), loc.offset);
}
else
loc.offset = 0;
if (!dwarf2_find_attribute(ctx, di, DW_AT_bit_size, &bit_size))
bit_size.u.uvalue = 0;
if (dwarf2_find_attribute(ctx, di, DW_AT_bit_offset, &bit_offset))
{
/* FIXME: we should only do this when implementation is LSB (which is
* the case on i386 processors)
*/
struct attribute nbytes;
if (!dwarf2_find_attribute(ctx, di, DW_AT_byte_size, &nbytes))
{
DWORD64 size;
nbytes.u.uvalue = symt_get_info(ctx->module, elt_type, TI_GET_LENGTH, &size) ?
(unsigned long)size : 0;
}
bit_offset.u.uvalue = nbytes.u.uvalue * 8 - bit_offset.u.uvalue - bit_size.u.uvalue;
}
else bit_offset.u.uvalue = 0;
symt_add_udt_element(ctx->module, parent, name.u.string, elt_type,
(loc.offset << 3) + bit_offset.u.uvalue,
bit_size.u.uvalue);
if (dwarf2_get_di_children(ctx, di)) FIXME("Unsupported children\n");
}
static struct symt* dwarf2_parse_subprogram(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di);
static struct symt* dwarf2_parse_udt_type(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di,
enum UdtKind udt)
{
struct attribute name;
struct attribute size;
struct vector* children;
dwarf2_debug_info_t*child;
unsigned int i;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
/* quirk... FIXME provide real support for anonymous UDTs */
if (!dwarf2_find_attribute(ctx, di, DW_AT_name, &name))
name.u.string = "zz_anon_zz";
if (!dwarf2_find_attribute(ctx, di, DW_AT_byte_size, &size)) size.u.uvalue = 0;
di->symt = &symt_new_udt(ctx->module, dwarf2_get_cpp_name(ctx, di, name.u.string),
size.u.uvalue, udt)->symt;
children = dwarf2_get_di_children(ctx, di);
if (children) for (i = 0; i < vector_length(children); i++)
{
child = *(dwarf2_debug_info_t**)vector_at(children, i);
switch (child->abbrev->tag)
{
case DW_TAG_member:
/* FIXME: should I follow the sibling stuff ?? */
dwarf2_parse_udt_member(ctx, child, (struct symt_udt*)di->symt);
break;
case DW_TAG_enumeration_type:
dwarf2_parse_enumeration_type(ctx, child);
break;
case DW_TAG_subprogram:
dwarf2_parse_subprogram(ctx, child);
break;
case DW_TAG_structure_type:
case DW_TAG_class_type:
case DW_TAG_union_type:
case DW_TAG_typedef:
/* FIXME: we need to handle nested udt definitions */
case DW_TAG_inheritance:
case DW_TAG_template_type_param:
case DW_TAG_template_value_param:
case DW_TAG_variable:
case DW_TAG_imported_declaration:
case DW_TAG_ptr_to_member_type:
/* FIXME: some C++ related stuff */
break;
default:
FIXME("Unhandled Tag type 0x%lx at %s, for %s\n",
child->abbrev->tag, dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
break;
}
}
return di->symt;
}
static void dwarf2_parse_enumerator(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di,
struct symt_enum* parent)
{
struct attribute name;
struct attribute value;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
if (!dwarf2_find_attribute(ctx, di, DW_AT_name, &name)) return;
if (!dwarf2_find_attribute(ctx, di, DW_AT_const_value, &value)) value.u.svalue = 0;
symt_add_enum_element(ctx->module, parent, name.u.string, value.u.svalue);
if (dwarf2_get_di_children(ctx, di)) FIXME("Unsupported children\n");
}
static struct symt* dwarf2_parse_enumeration_type(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct attribute name;
struct attribute size;
struct symt_basic* basetype;
struct vector* children;
dwarf2_debug_info_t*child;
unsigned int i;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
if (!dwarf2_find_attribute(ctx, di, DW_AT_name, &name)) name.u.string = NULL;
if (!dwarf2_find_attribute(ctx, di, DW_AT_byte_size, &size)) size.u.uvalue = 4;
switch (size.u.uvalue) /* FIXME: that's wrong */
{
case 1: basetype = symt_new_basic(ctx->module, btInt, "char", 1); break;
case 2: basetype = symt_new_basic(ctx->module, btInt, "short", 2); break;
default:
case 4: basetype = symt_new_basic(ctx->module, btInt, "int", 4); break;
}
di->symt = &symt_new_enum(ctx->module, name.u.string, &basetype->symt)->symt;
children = dwarf2_get_di_children(ctx, di);
/* FIXME: should we use the sibling stuff ?? */
if (children) for (i = 0; i < vector_length(children); i++)
{
child = *(dwarf2_debug_info_t**)vector_at(children, i);
switch (child->abbrev->tag)
{
case DW_TAG_enumerator:
dwarf2_parse_enumerator(ctx, child, (struct symt_enum*)di->symt);
break;
default:
FIXME("Unhandled Tag type 0x%lx at %s, for %s\n",
di->abbrev->tag, dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
}
}
return di->symt;
}
/* structure used to pass information around when parsing a subprogram */
typedef struct dwarf2_subprogram_s
{
dwarf2_parse_context_t* ctx;
struct symt_function* func;
BOOL non_computed_variable;
struct location frame;
} dwarf2_subprogram_t;
/******************************************************************
* dwarf2_parse_variable
*
* Parses any variable (parameter, local/global variable)
*/
static void dwarf2_parse_variable(dwarf2_subprogram_t* subpgm,
struct symt_block* block,
dwarf2_debug_info_t* di)
{
struct symt* param_type;
struct attribute name, value;
struct location loc;
BOOL is_pmt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(subpgm->ctx), dwarf2_debug_di(di));
is_pmt = !block && di->abbrev->tag == DW_TAG_formal_parameter;
param_type = dwarf2_lookup_type(subpgm->ctx, di);
if (!dwarf2_find_attribute(subpgm->ctx, di, DW_AT_name, &name)) {
/* cannot do much without the name, the functions below won't like it. */
return;
}
if (dwarf2_compute_location_attr(subpgm->ctx, di, DW_AT_location,
&loc, &subpgm->frame))
{
struct attribute ext;
TRACE("found parameter %s (kind=%d, offset=%ld, reg=%d) at %s\n",
name.u.string, loc.kind, loc.offset, loc.reg,
dwarf2_debug_ctx(subpgm->ctx));
switch (loc.kind)
{
case loc_error:
break;
case loc_absolute:
/* it's a global variable */
/* FIXME: we don't handle its scope yet */
if (!dwarf2_find_attribute(subpgm->ctx, di, DW_AT_external, &ext))
ext.u.uvalue = 0;
loc.offset += subpgm->ctx->load_offset;
symt_new_global_variable(subpgm->ctx->module, subpgm->ctx->compiland,
dwarf2_get_cpp_name(subpgm->ctx, di, name.u.string), !ext.u.uvalue,
loc, 0, param_type);
break;
default:
subpgm->non_computed_variable = TRUE;
/* fall through */
case loc_register:
case loc_regrel:
/* either a pmt/variable relative to frame pointer or
* pmt/variable in a register
*/
assert(subpgm->func);
symt_add_func_local(subpgm->ctx->module, subpgm->func,
is_pmt ? DataIsParam : DataIsLocal,
&loc, block, param_type, name.u.string);
break;
}
}
else if (dwarf2_find_attribute(subpgm->ctx, di, DW_AT_const_value, &value))
{
VARIANT v;
if (subpgm->func) WARN("Unsupported constant %s in function\n", name.u.string);
if (is_pmt) FIXME("Unsupported constant (parameter) %s in function\n", name.u.string);
switch (value.form)
{
case DW_FORM_data1:
case DW_FORM_data2:
case DW_FORM_data4:
case DW_FORM_udata:
case DW_FORM_addr:
v.n1.n2.vt = VT_UI4;
v.n1.n2.n3.lVal = value.u.uvalue;
break;
case DW_FORM_data8:
v.n1.n2.vt = VT_UI8;
v.n1.n2.n3.llVal = value.u.lluvalue;
break;
case DW_FORM_sdata:
v.n1.n2.vt = VT_I4;
v.n1.n2.n3.lVal = value.u.svalue;
break;
case DW_FORM_strp:
case DW_FORM_string:
/* FIXME: native doesn't report const strings from here !!
* however, the value of the string is in the code somewhere
*/
v.n1.n2.vt = VT_I1 | VT_BYREF;
v.n1.n2.n3.byref = pool_strdup(&subpgm->ctx->module->pool, value.u.string);
break;
case DW_FORM_block:
case DW_FORM_block1:
case DW_FORM_block2:
case DW_FORM_block4:
v.n1.n2.vt = VT_I4;
switch (value.u.block.size)
{
case 1: v.n1.n2.n3.lVal = *(BYTE*)value.u.block.ptr; break;
case 2: v.n1.n2.n3.lVal = *(USHORT*)value.u.block.ptr; break;
case 4: v.n1.n2.n3.lVal = *(DWORD*)value.u.block.ptr; break;
default:
v.n1.n2.vt = VT_I1 | VT_BYREF;
v.n1.n2.n3.byref = pool_alloc(&subpgm->ctx->module->pool, value.u.block.size);
memcpy(v.n1.n2.n3.byref, value.u.block.ptr, value.u.block.size);
}
break;
default:
FIXME("Unsupported form for const value %s (%lx)\n",
name.u.string, value.form);
v.n1.n2.vt = VT_EMPTY;
}
di->symt = &symt_new_constant(subpgm->ctx->module, subpgm->ctx->compiland,
name.u.string, param_type, &v)->symt;
}
else
{
/* variable has been optimized away... report anyway */
loc.kind = loc_error;
loc.reg = loc_err_no_location;
if (subpgm->func)
{
symt_add_func_local(subpgm->ctx->module, subpgm->func,
is_pmt ? DataIsParam : DataIsLocal,
&loc, block, param_type, name.u.string);
}
else
{
WARN("dropping global variable %s which has been optimized away\n", name.u.string);
}
}
if (is_pmt && subpgm->func && subpgm->func->type)
symt_add_function_signature_parameter(subpgm->ctx->module,
(struct symt_function_signature*)subpgm->func->type,
param_type);
if (dwarf2_get_di_children(subpgm->ctx, di)) FIXME("Unsupported children\n");
}
static void dwarf2_parse_subprogram_label(dwarf2_subprogram_t* subpgm,
const dwarf2_debug_info_t* di)
{
struct attribute name;
struct attribute low_pc;
struct location loc;
TRACE("%s, for %s\n", dwarf2_debug_ctx(subpgm->ctx), dwarf2_debug_di(di));
if (!dwarf2_find_attribute(subpgm->ctx, di, DW_AT_low_pc, &low_pc)) low_pc.u.uvalue = 0;
if (!dwarf2_find_attribute(subpgm->ctx, di, DW_AT_name, &name))
name.u.string = NULL;
loc.kind = loc_absolute;
loc.offset = subpgm->ctx->load_offset + low_pc.u.uvalue;
symt_add_function_point(subpgm->ctx->module, subpgm->func, SymTagLabel,
&loc, name.u.string);
}
static void dwarf2_parse_subprogram_block(dwarf2_subprogram_t* subpgm,
struct symt_block* parent_block,
dwarf2_debug_info_t* di);
static void dwarf2_parse_inlined_subroutine(dwarf2_subprogram_t* subpgm,
struct symt_block* parent_block,
dwarf2_debug_info_t* di)
{
struct symt_block* block;
unsigned long low_pc, high_pc;
struct vector* children;
dwarf2_debug_info_t*child;
unsigned int i;
TRACE("%s, for %s\n", dwarf2_debug_ctx(subpgm->ctx), dwarf2_debug_di(di));
if (!dwarf2_read_range(subpgm->ctx, di, &low_pc, &high_pc))
{
FIXME("cannot read range\n");
return;
}
block = symt_open_func_block(subpgm->ctx->module, subpgm->func, parent_block,
subpgm->ctx->load_offset + low_pc - subpgm->func->address,
high_pc - low_pc);
children = dwarf2_get_di_children(subpgm->ctx, di);
if (children) for (i = 0; i < vector_length(children); i++)
{
child = *(dwarf2_debug_info_t**)vector_at(children, i);
switch (child->abbrev->tag)
{
case DW_TAG_formal_parameter:
case DW_TAG_variable:
dwarf2_parse_variable(subpgm, block, child);
break;
case DW_TAG_lexical_block:
dwarf2_parse_subprogram_block(subpgm, block, child);
break;
case DW_TAG_inlined_subroutine:
dwarf2_parse_inlined_subroutine(subpgm, block, child);
break;
case DW_TAG_label:
dwarf2_parse_subprogram_label(subpgm, child);
break;
case DW_TAG_GNU_call_site:
/* this isn't properly supported by dbghelp interface. skip it for now */
break;
default:
FIXME("Unhandled Tag type 0x%lx at %s, for %s\n",
child->abbrev->tag, dwarf2_debug_ctx(subpgm->ctx),
dwarf2_debug_di(di));
}
}
symt_close_func_block(subpgm->ctx->module, subpgm->func, block, 0);
}
static void dwarf2_parse_subprogram_block(dwarf2_subprogram_t* subpgm,
struct symt_block* parent_block,
dwarf2_debug_info_t* di)
{
struct symt_block* block;
unsigned long low_pc, high_pc;
struct vector* children;
dwarf2_debug_info_t*child;
unsigned int i;
TRACE("%s, for %s\n", dwarf2_debug_ctx(subpgm->ctx), dwarf2_debug_di(di));
if (!dwarf2_read_range(subpgm->ctx, di, &low_pc, &high_pc))
{
FIXME("no range\n");
return;
}
block = symt_open_func_block(subpgm->ctx->module, subpgm->func, parent_block,
subpgm->ctx->load_offset + low_pc - subpgm->func->address,
high_pc - low_pc);
children = dwarf2_get_di_children(subpgm->ctx, di);
if (children) for (i = 0; i < vector_length(children); i++)
{
child = *(dwarf2_debug_info_t**)vector_at(children, i);
switch (child->abbrev->tag)
{
case DW_TAG_inlined_subroutine:
dwarf2_parse_inlined_subroutine(subpgm, block, child);
break;
case DW_TAG_variable:
dwarf2_parse_variable(subpgm, block, child);
break;
case DW_TAG_lexical_block:
dwarf2_parse_subprogram_block(subpgm, block, child);
break;
case DW_TAG_subprogram:
/* FIXME: likely a declaration (to be checked)
* skip it for now
*/
break;
case DW_TAG_formal_parameter:
/* FIXME: likely elements for exception handling (GCC flavor)
* Skip it for now
*/
break;
case DW_TAG_imported_module:
/* C++ stuff to be silenced (for now) */
break;
case DW_TAG_GNU_call_site:
/* this isn't properly supported by dbghelp interface. skip it for now */
break;
case DW_TAG_label:
dwarf2_parse_subprogram_label(subpgm, child);
break;
case DW_TAG_class_type:
case DW_TAG_structure_type:
case DW_TAG_union_type:
case DW_TAG_enumeration_type:
case DW_TAG_typedef:
/* the type referred to will be loaded when we need it, so skip it */
break;
default:
FIXME("Unhandled Tag type 0x%lx at %s, for %s\n",
child->abbrev->tag, dwarf2_debug_ctx(subpgm->ctx), dwarf2_debug_di(di));
}
}
symt_close_func_block(subpgm->ctx->module, subpgm->func, block, 0);
}
static struct symt* dwarf2_parse_subprogram(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct attribute name;
unsigned long low_pc, high_pc;
struct attribute is_decl;
struct attribute inline_flags;
struct symt* ret_type;
struct symt_function_signature* sig_type;
dwarf2_subprogram_t subpgm;
struct vector* children;
dwarf2_debug_info_t* child;
unsigned int i;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
if (!dwarf2_find_attribute(ctx, di, DW_AT_name, &name))
{
WARN("No name for function... dropping function\n");
return NULL;
}
/* if it's an abstract representation of an inline function, there should be
* a concrete object that we'll handle
*/
if (dwarf2_find_attribute(ctx, di, DW_AT_inline, &inline_flags) &&
inline_flags.u.uvalue != DW_INL_not_inlined)
{
TRACE("Function %s declared as inlined (%ld)... skipping\n",
name.u.string ? name.u.string : "(null)", inline_flags.u.uvalue);
return NULL;
}
if (dwarf2_find_attribute(ctx, di, DW_AT_declaration, &is_decl) &&
is_decl.u.uvalue && is_decl.gotten_from == attr_direct)
{
/* it's a real declaration, skip it */
return NULL;
}
if (!dwarf2_read_range(ctx, di, &low_pc, &high_pc))
{
WARN("cannot get range for %s\n", name.u.string);
return NULL;
}
/* As functions (defined as inline assembly) get debug info with dwarf
* (not the case for stabs), we just drop Wine's thunks here...
* Actual thunks will be created in elf_module from the symbol table
*/
if (elf_is_in_thunk_area(ctx->load_offset + low_pc, ctx->thunks) >= 0)
return NULL;
if (!(ret_type = dwarf2_lookup_type(ctx, di)))
{
ret_type = ctx->symt_cache[sc_void];
assert(ret_type);
}
/* FIXME: assuming C source code */
sig_type = symt_new_function_signature(ctx->module, ret_type, CV_CALL_FAR_C);
subpgm.func = symt_new_function(ctx->module, ctx->compiland,
dwarf2_get_cpp_name(ctx, di, name.u.string),
ctx->load_offset + low_pc, high_pc - low_pc,
&sig_type->symt);
di->symt = &subpgm.func->symt;
subpgm.ctx = ctx;
if (!dwarf2_compute_location_attr(ctx, di, DW_AT_frame_base,
&subpgm.frame, NULL))
{
/* on stack !! */
subpgm.frame.kind = loc_regrel;
subpgm.frame.reg = dbghelp_current_cpu->frame_regno;
subpgm.frame.offset = 0;
}
subpgm.non_computed_variable = FALSE;
children = dwarf2_get_di_children(ctx, di);
if (children) for (i = 0; i < vector_length(children); i++)
{
child = *(dwarf2_debug_info_t**)vector_at(children, i);
switch (child->abbrev->tag)
{
case DW_TAG_variable:
case DW_TAG_formal_parameter:
dwarf2_parse_variable(&subpgm, NULL, child);
break;
case DW_TAG_lexical_block:
dwarf2_parse_subprogram_block(&subpgm, NULL, child);
break;
case DW_TAG_inlined_subroutine:
dwarf2_parse_inlined_subroutine(&subpgm, NULL, child);
break;
case DW_TAG_subprogram:
/* FIXME: likely a declaration (to be checked)
* skip it for now
*/
break;
case DW_TAG_label:
dwarf2_parse_subprogram_label(&subpgm, child);
break;
case DW_TAG_class_type:
case DW_TAG_structure_type:
case DW_TAG_union_type:
case DW_TAG_enumeration_type:
case DW_TAG_typedef:
/* the type referred to will be loaded when we need it, so skip it */
break;
case DW_TAG_unspecified_parameters:
case DW_TAG_template_type_param:
case DW_TAG_template_value_param:
case DW_TAG_GNU_call_site:
/* FIXME: no support in dbghelp's internals so far */
break;
default:
FIXME("Unhandled Tag type 0x%lx at %s, for %s\n",
child->abbrev->tag, dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
}
}
if (subpgm.non_computed_variable || subpgm.frame.kind >= loc_user)
{
symt_add_function_point(ctx->module, subpgm.func, SymTagCustom,
&subpgm.frame, NULL);
}
if (subpgm.func) symt_normalize_function(subpgm.ctx->module, subpgm.func);
return di->symt;
}
static struct symt* dwarf2_parse_subroutine_type(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct symt* ret_type;
struct symt_function_signature* sig_type;
struct vector* children;
dwarf2_debug_info_t* child;
unsigned int i;
if (di->symt) return di->symt;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
if (!(ret_type = dwarf2_lookup_type(ctx, di)))
{
ret_type = ctx->symt_cache[sc_void];
assert(ret_type);
}
/* FIXME: assuming C source code */
sig_type = symt_new_function_signature(ctx->module, ret_type, CV_CALL_FAR_C);
children = dwarf2_get_di_children(ctx, di);
if (children) for (i = 0; i < vector_length(children); i++)
{
child = *(dwarf2_debug_info_t**)vector_at(children, i);
switch (child->abbrev->tag)
{
case DW_TAG_formal_parameter:
symt_add_function_signature_parameter(ctx->module, sig_type,
dwarf2_lookup_type(ctx, child));
break;
case DW_TAG_unspecified_parameters:
WARN("Unsupported unspecified parameters\n");
break;
}
}
return di->symt = &sig_type->symt;
}
static void dwarf2_parse_namespace(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
struct vector* children;
dwarf2_debug_info_t* child;
unsigned int i;
if (di->symt) return;
TRACE("%s, for %s\n", dwarf2_debug_ctx(ctx), dwarf2_debug_di(di));
di->symt = ctx->symt_cache[sc_void];
children = dwarf2_get_di_children(ctx, di);
if (children) for (i = 0; i < vector_length(children); i++)
{
child = *(dwarf2_debug_info_t**)vector_at(children, i);
dwarf2_load_one_entry(ctx, child);
}
}
static void dwarf2_load_one_entry(dwarf2_parse_context_t* ctx,
dwarf2_debug_info_t* di)
{
switch (di->abbrev->tag)
{
case DW_TAG_typedef:
dwarf2_parse_typedef(ctx, di);
break;
case DW_TAG_base_type:
dwarf2_parse_base_type(ctx, di);
break;
case DW_TAG_pointer_type:
dwarf2_parse_pointer_type(ctx, di);
break;
case DW_TAG_class_type:
dwarf2_parse_udt_type(ctx, di, UdtClass);
break;
case DW_TAG_structure_type:
dwarf2_parse_udt_type(ctx, di, UdtStruct);
break;
case DW_TAG_union_type:
dwarf2_parse_udt_type(ctx, di, UdtUnion);
break;
case DW_TAG_array_type:
dwarf2_parse_array_type(ctx, di);
break;
case DW_TAG_const_type:
dwarf2_parse_const_type(ctx, di);
break;
case DW_TAG_volatile_type:
dwarf2_parse_volatile_type(ctx, di);
break;
case DW_TAG_reference_type:
dwarf2_parse_reference_type(ctx, di);
break;
case DW_TAG_enumeration_type:
dwarf2_parse_enumeration_type(ctx, di);
break;
case DW_TAG_subprogram:
dwarf2_parse_subprogram(ctx, di);
break;
case DW_TAG_subroutine_type:
dwarf2_parse_subroutine_type(ctx, di);
break;
case DW_TAG_variable:
{
dwarf2_subprogram_t subpgm;
subpgm.ctx = ctx;
subpgm.func = NULL;
subpgm.frame.kind = loc_absolute;
subpgm.frame.offset = 0;
subpgm.frame.reg = Wine_DW_no_register;
dwarf2_parse_variable(&subpgm, NULL, di);
}
break;
case DW_TAG_namespace:
dwarf2_parse_namespace(ctx, di);
break;
/* silence a couple of C++ defines */
case DW_TAG_imported_module:
case DW_TAG_imported_declaration:
case DW_TAG_ptr_to_member_type:
break;
default:
FIXME("Unhandled Tag type 0x%lx at %s, for %lu\n",
di->abbrev->tag, dwarf2_debug_ctx(ctx), di->abbrev->entry_code);
}
}
static void dwarf2_set_line_number(struct module* module, unsigned long address,
const struct vector* v, unsigned file, unsigned line)
{
struct symt_function* func;
struct symt_ht* symt;
unsigned* psrc;
if (!file || !(psrc = vector_at(v, file - 1))) return;
TRACE("%s %lx %s %u\n",
debugstr_w(module->module.ModuleName), address, source_get(module, *psrc), line);
if (!(symt = symt_find_nearest(module, address)) ||
symt->symt.tag != SymTagFunction) return;
func = (struct symt_function*)symt;
symt_add_func_line(module, func, *psrc, line, address - func->address);
}
static BOOL dwarf2_parse_line_numbers(const dwarf2_section_t* sections,
dwarf2_parse_context_t* ctx,
const char* compile_dir,
unsigned long offset)
{
dwarf2_traverse_context_t traverse;
unsigned long length;
unsigned insn_size, default_stmt;
unsigned line_range, opcode_base;
int line_base;
const unsigned char* opcode_len;
struct vector dirs;
struct vector files;
const char** p;
/* section with line numbers stripped */
if (sections[section_line].address == IMAGE_NO_MAP)
return FALSE;
if (offset + 4 > sections[section_line].size)
{
WARN("out of bounds offset\n");
return FALSE;
}
traverse.data = sections[section_line].address + offset;
traverse.end_data = traverse.data + 4;
traverse.word_size = ctx->module->format_info[DFI_DWARF]->u.dwarf2_info->word_size;
length = dwarf2_parse_u4(&traverse);
traverse.end_data = sections[section_line].address + offset + length;
if (offset + 4 + length > sections[section_line].size)
{
WARN("out of bounds header\n");
return FALSE;
}
dwarf2_parse_u2(&traverse); /* version */
dwarf2_parse_u4(&traverse); /* header_len */
insn_size = dwarf2_parse_byte(&traverse);
default_stmt = dwarf2_parse_byte(&traverse);
line_base = (signed char)dwarf2_parse_byte(&traverse);
line_range = dwarf2_parse_byte(&traverse);
opcode_base = dwarf2_parse_byte(&traverse);
opcode_len = traverse.data;
traverse.data += opcode_base - 1;
vector_init(&dirs, sizeof(const char*), 4);
p = vector_add(&dirs, &ctx->pool);
*p = compile_dir ? compile_dir : ".";
while (*traverse.data)
{
const char* rel = (const char*)traverse.data;
unsigned rellen = strlen(rel);
TRACE("Got include %s\n", rel);
traverse.data += rellen + 1;
p = vector_add(&dirs, &ctx->pool);
if (*rel == '/' || !compile_dir)
*p = rel;
else
{
/* include directory relative to compile directory */
unsigned baselen = strlen(compile_dir);
char* tmp = pool_alloc(&ctx->pool, baselen + 1 + rellen + 1);
strcpy(tmp, compile_dir);
if (tmp[baselen - 1] != '/') tmp[baselen++] = '/';
strcpy(&tmp[baselen], rel);
*p = tmp;
}
}
traverse.data++;
vector_init(&files, sizeof(unsigned), 16);
while (*traverse.data)
{
unsigned int dir_index, mod_time;
const char* name;
const char* dir;
unsigned* psrc;
name = (const char*)traverse.data;
traverse.data += strlen(name) + 1;
dir_index = dwarf2_leb128_as_unsigned(&traverse);
mod_time = dwarf2_leb128_as_unsigned(&traverse);
length = dwarf2_leb128_as_unsigned(&traverse);
dir = *(const char**)vector_at(&dirs, dir_index);
TRACE("Got file %s/%s (%u,%lu)\n", dir, name, mod_time, length);
psrc = vector_add(&files, &ctx->pool);
*psrc = source_new(ctx->module, dir, name);
}
traverse.data++;
while (traverse.data < traverse.end_data)
{
unsigned long address = 0;
unsigned file = 1;
unsigned line = 1;
unsigned is_stmt = default_stmt;
BOOL end_sequence = FALSE;
unsigned opcode, extopcode, i;
while (!end_sequence)
{
opcode = dwarf2_parse_byte(&traverse);
TRACE("Got opcode %x\n", opcode);
if (opcode >= opcode_base)
{
unsigned delta = opcode - opcode_base;
address += (delta / line_range) * insn_size;
line += line_base + (delta % line_range);
dwarf2_set_line_number(ctx->module, address, &files, file, line);
}
else
{
switch (opcode)
{
case DW_LNS_copy:
dwarf2_set_line_number(ctx->module, address, &files, file, line);
break;
case DW_LNS_advance_pc:
address += insn_size * dwarf2_leb128_as_unsigned(&traverse);
break;
case DW_LNS_advance_line:
line += dwarf2_leb128_as_signed(&traverse);
break;
case DW_LNS_set_file:
file = dwarf2_leb128_as_unsigned(&traverse);
break;
case DW_LNS_set_column:
dwarf2_leb128_as_unsigned(&traverse);
break;
case DW_LNS_negate_stmt:
is_stmt = !is_stmt;
break;
case DW_LNS_set_basic_block:
break;
case DW_LNS_const_add_pc:
address += ((255 - opcode_base) / line_range) * insn_size;
break;
case DW_LNS_fixed_advance_pc:
address += dwarf2_parse_u2(&traverse);
break;
case DW_LNS_extended_op:
dwarf2_leb128_as_unsigned(&traverse);
extopcode = dwarf2_parse_byte(&traverse);
switch (extopcode)
{
case DW_LNE_end_sequence:
dwarf2_set_line_number(ctx->module, address, &files, file, line);
end_sequence = TRUE;
break;
case DW_LNE_set_address:
address = ctx->load_offset + dwarf2_parse_addr(&traverse);
break;
case DW_LNE_define_file:
FIXME("not handled define file %s\n", traverse.data);
traverse.data += strlen((const char *)traverse.data) + 1;
dwarf2_leb128_as_unsigned(&traverse);
dwarf2_leb128_as_unsigned(&traverse);
dwarf2_leb128_as_unsigned(&traverse);
break;
case DW_LNE_set_discriminator:
{
unsigned descr;
descr = dwarf2_leb128_as_unsigned(&traverse);
WARN("not handled discriminator %x\n", descr);
}
break;
default:
FIXME("Unsupported extended opcode %x\n", extopcode);
break;
}
break;
default:
WARN("Unsupported opcode %x\n", opcode);
for (i = 0; i < opcode_len[opcode]; i++)
dwarf2_leb128_as_unsigned(&traverse);
break;
}
}
}
}
return TRUE;
}
static BOOL dwarf2_parse_compilation_unit(const dwarf2_section_t* sections,
struct module* module,
const struct elf_thunk_area* thunks,
dwarf2_traverse_context_t* mod_ctx,
unsigned long load_offset)
{
dwarf2_parse_context_t ctx;
dwarf2_traverse_context_t abbrev_ctx;
dwarf2_debug_info_t* di;
dwarf2_traverse_context_t cu_ctx;
const unsigned char* comp_unit_start = mod_ctx->data;
unsigned long cu_length;
unsigned short cu_version;
unsigned long cu_abbrev_offset;
BOOL ret = FALSE;
cu_length = dwarf2_parse_u4(mod_ctx);
cu_ctx.data = mod_ctx->data;
cu_ctx.end_data = mod_ctx->data + cu_length;
mod_ctx->data += cu_length;
cu_version = dwarf2_parse_u2(&cu_ctx);
cu_abbrev_offset = dwarf2_parse_u4(&cu_ctx);
cu_ctx.word_size = dwarf2_parse_byte(&cu_ctx);
TRACE("Compilation Unit Header found at 0x%x:\n",
(int)(comp_unit_start - sections[section_debug].address));
TRACE("- length: %lu\n", cu_length);
TRACE("- version: %u\n", cu_version);
TRACE("- abbrev_offset: %lu\n", cu_abbrev_offset);
TRACE("- word_size: %u\n", cu_ctx.word_size);
if (cu_version != 2)
{
WARN("%u DWARF version unsupported. Wine dbghelp only support DWARF 2.\n",
cu_version);
return FALSE;
}
module->format_info[DFI_DWARF]->u.dwarf2_info->word_size = cu_ctx.word_size;
mod_ctx->word_size = cu_ctx.word_size;
pool_init(&ctx.pool, 65536);
ctx.sections = sections;
ctx.section = section_debug;
ctx.module = module;
ctx.thunks = thunks;
ctx.load_offset = load_offset;
ctx.ref_offset = comp_unit_start - sections[section_debug].address;
memset(ctx.symt_cache, 0, sizeof(ctx.symt_cache));
ctx.symt_cache[sc_void] = &symt_new_basic(module, btVoid, "void", 0)->symt;
ctx.cpp_name = NULL;
abbrev_ctx.data = sections[section_abbrev].address + cu_abbrev_offset;
abbrev_ctx.end_data = sections[section_abbrev].address + sections[section_abbrev].size;
abbrev_ctx.word_size = cu_ctx.word_size;
dwarf2_parse_abbrev_set(&abbrev_ctx, &ctx.abbrev_table, &ctx.pool);
sparse_array_init(&ctx.debug_info_table, sizeof(dwarf2_debug_info_t), 128);
dwarf2_read_one_debug_info(&ctx, &cu_ctx, NULL, &di);
if (di->abbrev->tag == DW_TAG_compile_unit)
{
struct attribute name;
struct vector* children;
dwarf2_debug_info_t* child = NULL;
unsigned int i;
struct attribute stmt_list, low_pc;
struct attribute comp_dir;
if (!dwarf2_find_attribute(&ctx, di, DW_AT_name, &name))
name.u.string = NULL;
/* get working directory of current compilation unit */
if (!dwarf2_find_attribute(&ctx, di, DW_AT_comp_dir, &comp_dir))
comp_dir.u.string = NULL;
if (!dwarf2_find_attribute(&ctx, di, DW_AT_low_pc, &low_pc))
low_pc.u.uvalue = 0;
ctx.compiland = symt_new_compiland(module, ctx.load_offset + low_pc.u.uvalue,
source_new(module, comp_dir.u.string, name.u.string));
di->symt = &ctx.compiland->symt;
children = dwarf2_get_di_children(&ctx, di);
if (children) for (i = 0; i < vector_length(children); i++)
{
child = *(dwarf2_debug_info_t**)vector_at(children, i);
dwarf2_load_one_entry(&ctx, child);
}
if (dwarf2_find_attribute(&ctx, di, DW_AT_stmt_list, &stmt_list))
{
if (dwarf2_parse_line_numbers(sections, &ctx, comp_dir.u.string, stmt_list.u.uvalue))
module->module.LineNumbers = TRUE;
}
ret = TRUE;
}
else FIXME("Should have a compilation unit here\n");
pool_destroy(&ctx.pool);
return ret;
}
static BOOL dwarf2_lookup_loclist(const struct module_format* modfmt, const BYTE* start,
unsigned long ip, dwarf2_traverse_context_t* lctx)
{
DWORD_PTR beg, end;
const BYTE* ptr = start;
DWORD len;
while (ptr < modfmt->u.dwarf2_info->debug_loc.address + modfmt->u.dwarf2_info->debug_loc.size)
{
beg = dwarf2_get_addr(ptr, modfmt->u.dwarf2_info->word_size); ptr += modfmt->u.dwarf2_info->word_size;
end = dwarf2_get_addr(ptr, modfmt->u.dwarf2_info->word_size); ptr += modfmt->u.dwarf2_info->word_size;
if (!beg && !end) break;
len = dwarf2_get_u2(ptr); ptr += 2;
if (beg <= ip && ip < end)
{
lctx->data = ptr;
lctx->end_data = ptr + len;
lctx->word_size = modfmt->u.dwarf2_info->word_size;
return TRUE;
}
ptr += len;
}
WARN("Couldn't find ip in location list\n");
return FALSE;
}
static enum location_error loc_compute_frame(struct process* pcs,
const struct module_format* modfmt,
const struct symt_function* func,
DWORD_PTR ip, struct location* frame)
{
struct symt** psym = NULL;
struct location* pframe;
dwarf2_traverse_context_t lctx;
enum location_error err;
unsigned int i;
for (i=0; i<vector_length(&func->vchildren); i++)
{
psym = vector_at(&func->vchildren, i);
if ((*psym)->tag == SymTagCustom)
{
pframe = &((struct symt_hierarchy_point*)*psym)->loc;
/* First, recompute the frame information, if needed */
switch (pframe->kind)
{
case loc_regrel:
case loc_register:
*frame = *pframe;
break;
case loc_dwarf2_location_list:
WARN("Searching loclist for %s\n", func->hash_elt.name);
if (!dwarf2_lookup_loclist(modfmt,
modfmt->u.dwarf2_info->debug_loc.address + pframe->offset,
ip, &lctx))
return loc_err_out_of_scope;
if ((err = compute_location(&lctx, frame, pcs->handle, NULL)) < 0) return err;
if (frame->kind >= loc_user)
{
WARN("Couldn't compute runtime frame location\n");
return loc_err_too_complex;
}
break;
default:
WARN("Unsupported frame kind %d\n", pframe->kind);
return loc_err_internal;
}
return 0;
}
}
WARN("Couldn't find Custom function point, whilst location list offset is searched\n");
return loc_err_internal;
}
enum reg_rule
{
RULE_UNSET, /* not set at all */
RULE_UNDEFINED, /* undefined value */
RULE_SAME, /* same value as previous frame */
RULE_CFA_OFFSET, /* stored at cfa offset */
RULE_OTHER_REG, /* stored in other register */
RULE_EXPRESSION, /* address specified by expression */
RULE_VAL_EXPRESSION /* value specified by expression */
};
/* make it large enough for all CPUs */
#define NB_FRAME_REGS 64
#define MAX_SAVED_STATES 16
struct frame_state
{
ULONG_PTR cfa_offset;
unsigned char cfa_reg;
enum reg_rule cfa_rule;
enum reg_rule rules[NB_FRAME_REGS];
ULONG_PTR regs[NB_FRAME_REGS];
};
struct frame_info
{
ULONG_PTR ip;
ULONG_PTR code_align;
LONG_PTR data_align;
unsigned char retaddr_reg;
unsigned char fde_encoding;
unsigned char lsda_encoding;
unsigned char signal_frame;
unsigned char aug_z_format;
unsigned char state_sp;
struct frame_state state;
struct frame_state state_stack[MAX_SAVED_STATES];
};
static ULONG_PTR dwarf2_parse_augmentation_ptr(dwarf2_traverse_context_t* ctx, unsigned char encoding)
{
ULONG_PTR base;
if (encoding == DW_EH_PE_omit) return 0;
switch (encoding & 0xf0)
{
case DW_EH_PE_abs:
base = 0;
break;
case DW_EH_PE_pcrel:
base = (ULONG_PTR)ctx->data;
break;
default:
FIXME("unsupported encoding %02x\n", encoding);
return 0;
}
switch (encoding & 0x0f)
{
case DW_EH_PE_native:
return base + dwarf2_parse_addr(ctx);
case DW_EH_PE_leb128:
return base + dwarf2_leb128_as_unsigned(ctx);
case DW_EH_PE_data2:
return base + dwarf2_parse_u2(ctx);
case DW_EH_PE_data4:
return base + dwarf2_parse_u4(ctx);
case DW_EH_PE_data8:
return base + dwarf2_parse_u8(ctx);
case DW_EH_PE_signed|DW_EH_PE_leb128:
return base + dwarf2_leb128_as_signed(ctx);
case DW_EH_PE_signed|DW_EH_PE_data2:
return base + (signed short)dwarf2_parse_u2(ctx);
case DW_EH_PE_signed|DW_EH_PE_data4:
return base + (signed int)dwarf2_parse_u4(ctx);
case DW_EH_PE_signed|DW_EH_PE_data8:
return base + (LONG64)dwarf2_parse_u8(ctx);
default:
FIXME("unsupported encoding %02x\n", encoding);
return 0;
}
}
static BOOL parse_cie_details(dwarf2_traverse_context_t* ctx, struct frame_info* info)
{
unsigned char version;
const char* augmentation;
const unsigned char* end;
ULONG_PTR len;
memset(info, 0, sizeof(*info));
info->lsda_encoding = DW_EH_PE_omit;
info->aug_z_format = 0;
/* parse the CIE first */
version = dwarf2_parse_byte(ctx);
if (version != 1)
{
FIXME("unknown CIE version %u at %p\n", version, ctx->data - 1);
return FALSE;
}
augmentation = (const char*)ctx->data;
ctx->data += strlen(augmentation) + 1;
info->code_align = dwarf2_leb128_as_unsigned(ctx);
info->data_align = dwarf2_leb128_as_signed(ctx);
info->retaddr_reg = dwarf2_parse_byte(ctx);
info->state.cfa_rule = RULE_CFA_OFFSET;
end = NULL;
TRACE("\tparsing augmentation %s\n", augmentation);
if (*augmentation) do
{
switch (*augmentation)
{
case 'z':
len = dwarf2_leb128_as_unsigned(ctx);
end = ctx->data + len;
info->aug_z_format = 1;
continue;
case 'L':
info->lsda_encoding = dwarf2_parse_byte(ctx);
continue;
case 'P':
{
unsigned char encoding = dwarf2_parse_byte(ctx);
/* throw away the indirect bit, as we don't care for the result */
encoding &= ~DW_EH_PE_indirect;
dwarf2_parse_augmentation_ptr(ctx, encoding); /* handler */
continue;
}
case 'R':
info->fde_encoding = dwarf2_parse_byte(ctx);
continue;
case 'S':
info->signal_frame = 1;
continue;
}
FIXME("unknown augmentation '%c'\n", *augmentation);
if (!end) return FALSE;
break;
} while (*++augmentation);
if (end) ctx->data = end;
return TRUE;
}
static BOOL dwarf2_get_cie(unsigned long addr, struct module* module, DWORD_PTR delta,
dwarf2_traverse_context_t* fde_ctx, dwarf2_traverse_context_t* cie_ctx,
struct frame_info* info, BOOL in_eh_frame)
{
const unsigned char* ptr_blk;
const unsigned char* cie_ptr;
const unsigned char* last_cie_ptr = (const unsigned char*)~0;
unsigned len, id;
unsigned long start, range;
unsigned cie_id;
const BYTE* start_data = fde_ctx->data;
cie_id = in_eh_frame ? 0 : DW_CIE_ID;
/* skip 0-padding at beginning of section (alignment) */
while (fde_ctx->data + 2 * 4 < fde_ctx->end_data)
{
if (dwarf2_parse_u4(fde_ctx))
{
fde_ctx->data -= 4;
break;
}
}
for (; fde_ctx->data + 2 * 4 < fde_ctx->end_data; fde_ctx->data = ptr_blk)
{
/* find the FDE for address addr (skip CIE) */
len = dwarf2_parse_u4(fde_ctx);
if (len == 0xffffffff) FIXME("Unsupported yet 64-bit CIEs\n");
ptr_blk = fde_ctx->data + len;
id = dwarf2_parse_u4(fde_ctx);
if (id == cie_id)
{
last_cie_ptr = fde_ctx->data - 8;
/* we need some bits out of the CIE in order to parse all contents */
if (!parse_cie_details(fde_ctx, info)) return FALSE;
cie_ctx->data = fde_ctx->data;
cie_ctx->end_data = ptr_blk;
cie_ctx->word_size = fde_ctx->word_size;
continue;
}
cie_ptr = (in_eh_frame) ? fde_ctx->data - id - 4 : start_data + id;
if (cie_ptr != last_cie_ptr)
{
last_cie_ptr = cie_ptr;
cie_ctx->data = cie_ptr;
cie_ctx->word_size = fde_ctx->word_size;
cie_ctx->end_data = cie_ptr + 4;
cie_ctx->end_data = cie_ptr + 4 + dwarf2_parse_u4(cie_ctx);
if (dwarf2_parse_u4(cie_ctx) != cie_id)
{
FIXME("wrong CIE pointer at %x from FDE %x\n",
(unsigned)(cie_ptr - start_data),
(unsigned)(fde_ctx->data - start_data));
return FALSE;
}
if (!parse_cie_details(cie_ctx, info)) return FALSE;
}
start = delta + dwarf2_parse_augmentation_ptr(fde_ctx, info->fde_encoding);
range = dwarf2_parse_augmentation_ptr(fde_ctx, info->fde_encoding & 0x0F);
if (addr >= start && addr < start + range)
{
/* reset the FDE context */
fde_ctx->end_data = ptr_blk;
info->ip = start;
return TRUE;
}
}
return FALSE;
}
static int valid_reg(ULONG_PTR reg)
{
if (reg >= NB_FRAME_REGS) FIXME("unsupported reg %lx\n", reg);
return (reg < NB_FRAME_REGS);
}
static void execute_cfa_instructions(dwarf2_traverse_context_t* ctx,
ULONG_PTR last_ip, struct frame_info *info)
{
while (ctx->data < ctx->end_data && info->ip <= last_ip + info->signal_frame)
{
enum dwarf_call_frame_info op = dwarf2_parse_byte(ctx);
if (op & 0xc0)
{
switch (op & 0xc0)
{
case DW_CFA_advance_loc:
{
ULONG_PTR offset = (op & 0x3f) * info->code_align;
TRACE("%lx: DW_CFA_advance_loc %lu\n", info->ip, offset);
info->ip += offset;
break;
}
case DW_CFA_offset:
{
ULONG_PTR reg = op & 0x3f;
LONG_PTR offset = dwarf2_leb128_as_unsigned(ctx) * info->data_align;
if (!valid_reg(reg)) break;
TRACE("%lx: DW_CFA_offset %s, %ld\n",
info->ip,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)),
offset);
info->state.regs[reg] = offset;
info->state.rules[reg] = RULE_CFA_OFFSET;
break;
}
case DW_CFA_restore:
{
ULONG_PTR reg = op & 0x3f;
if (!valid_reg(reg)) break;
TRACE("%lx: DW_CFA_restore %s\n",
info->ip,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)));
info->state.rules[reg] = RULE_UNSET;
break;
}
}
}
else switch (op)
{
case DW_CFA_nop:
break;
case DW_CFA_set_loc:
{
ULONG_PTR loc = dwarf2_parse_augmentation_ptr(ctx, info->fde_encoding);
TRACE("%lx: DW_CFA_set_loc %lx\n", info->ip, loc);
info->ip = loc;
break;
}
case DW_CFA_advance_loc1:
{
ULONG_PTR offset = dwarf2_parse_byte(ctx) * info->code_align;
TRACE("%lx: DW_CFA_advance_loc1 %lu\n", info->ip, offset);
info->ip += offset;
break;
}
case DW_CFA_advance_loc2:
{
ULONG_PTR offset = dwarf2_parse_u2(ctx) * info->code_align;
TRACE("%lx: DW_CFA_advance_loc2 %lu\n", info->ip, offset);
info->ip += offset;
break;
}
case DW_CFA_advance_loc4:
{
ULONG_PTR offset = dwarf2_parse_u4(ctx) * info->code_align;
TRACE("%lx: DW_CFA_advance_loc4 %lu\n", info->ip, offset);
info->ip += offset;
break;
}
case DW_CFA_offset_extended:
case DW_CFA_offset_extended_sf:
{
ULONG_PTR reg = dwarf2_leb128_as_unsigned(ctx);
LONG_PTR offset = (op == DW_CFA_offset_extended) ? dwarf2_leb128_as_unsigned(ctx) * info->data_align
: dwarf2_leb128_as_signed(ctx) * info->data_align;
if (!valid_reg(reg)) break;
TRACE("%lx: DW_CFA_offset_extended %s, %ld\n",
info->ip,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)),
offset);
info->state.regs[reg] = offset;
info->state.rules[reg] = RULE_CFA_OFFSET;
break;
}
case DW_CFA_restore_extended:
{
ULONG_PTR reg = dwarf2_leb128_as_unsigned(ctx);
if (!valid_reg(reg)) break;
TRACE("%lx: DW_CFA_restore_extended %s\n",
info->ip,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)));
info->state.rules[reg] = RULE_UNSET;
break;
}
case DW_CFA_undefined:
{
ULONG_PTR reg = dwarf2_leb128_as_unsigned(ctx);
if (!valid_reg(reg)) break;
TRACE("%lx: DW_CFA_undefined %s\n",
info->ip,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)));
info->state.rules[reg] = RULE_UNDEFINED;
break;
}
case DW_CFA_same_value:
{
ULONG_PTR reg = dwarf2_leb128_as_unsigned(ctx);
if (!valid_reg(reg)) break;
TRACE("%lx: DW_CFA_same_value %s\n",
info->ip,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)));
info->state.regs[reg] = reg;
info->state.rules[reg] = RULE_SAME;
break;
}
case DW_CFA_register:
{
ULONG_PTR reg = dwarf2_leb128_as_unsigned(ctx);
ULONG_PTR reg2 = dwarf2_leb128_as_unsigned(ctx);
if (!valid_reg(reg) || !valid_reg(reg2)) break;
TRACE("%lx: DW_CFA_register %s == %s\n",
info->ip,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)),
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg2)));
info->state.regs[reg] = reg2;
info->state.rules[reg] = RULE_OTHER_REG;
break;
}
case DW_CFA_remember_state:
TRACE("%lx: DW_CFA_remember_state\n", info->ip);
if (info->state_sp >= MAX_SAVED_STATES)
FIXME("%lx: DW_CFA_remember_state too many nested saves\n", info->ip);
else
info->state_stack[info->state_sp++] = info->state;
break;
case DW_CFA_restore_state:
TRACE("%lx: DW_CFA_restore_state\n", info->ip);
if (!info->state_sp)
FIXME("%lx: DW_CFA_restore_state without corresponding save\n", info->ip);
else
info->state = info->state_stack[--info->state_sp];
break;
case DW_CFA_def_cfa:
case DW_CFA_def_cfa_sf:
{
ULONG_PTR reg = dwarf2_leb128_as_unsigned(ctx);
ULONG_PTR offset = (op == DW_CFA_def_cfa) ? dwarf2_leb128_as_unsigned(ctx)
: dwarf2_leb128_as_signed(ctx) * info->data_align;
if (!valid_reg(reg)) break;
TRACE("%lx: DW_CFA_def_cfa %s, %ld\n",
info->ip,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)),
offset);
info->state.cfa_reg = reg;
info->state.cfa_offset = offset;
info->state.cfa_rule = RULE_CFA_OFFSET;
break;
}
case DW_CFA_def_cfa_register:
{
ULONG_PTR reg = dwarf2_leb128_as_unsigned(ctx);
if (!valid_reg(reg)) break;
TRACE("%lx: DW_CFA_def_cfa_register %s\n",
info->ip,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)));
info->state.cfa_reg = reg;
info->state.cfa_rule = RULE_CFA_OFFSET;
break;
}
case DW_CFA_def_cfa_offset:
case DW_CFA_def_cfa_offset_sf:
{
ULONG_PTR offset = (op == DW_CFA_def_cfa_offset) ? dwarf2_leb128_as_unsigned(ctx)
: dwarf2_leb128_as_signed(ctx) * info->data_align;
TRACE("%lx: DW_CFA_def_cfa_offset %ld\n", info->ip, offset);
info->state.cfa_offset = offset;
info->state.cfa_rule = RULE_CFA_OFFSET;
break;
}
case DW_CFA_def_cfa_expression:
{
ULONG_PTR expr = (ULONG_PTR)ctx->data;
ULONG_PTR len = dwarf2_leb128_as_unsigned(ctx);
TRACE("%lx: DW_CFA_def_cfa_expression %lx-%lx\n", info->ip, expr, expr+len);
info->state.cfa_offset = expr;
info->state.cfa_rule = RULE_VAL_EXPRESSION;
ctx->data += len;
break;
}
case DW_CFA_expression:
case DW_CFA_val_expression:
{
ULONG_PTR reg = dwarf2_leb128_as_unsigned(ctx);
ULONG_PTR expr = (ULONG_PTR)ctx->data;
ULONG_PTR len = dwarf2_leb128_as_unsigned(ctx);
if (!valid_reg(reg)) break;
TRACE("%lx: DW_CFA_%sexpression %s %lx-%lx\n",
info->ip, (op == DW_CFA_expression) ? "" : "val_",
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(reg)),
expr, expr + len);
info->state.regs[reg] = expr;
info->state.rules[reg] = (op == DW_CFA_expression) ? RULE_EXPRESSION : RULE_VAL_EXPRESSION;
ctx->data += len;
break;
}
case DW_CFA_GNU_args_size:
/* FIXME: should check that GCC is the compiler for this CU */
{
ULONG_PTR args = dwarf2_leb128_as_unsigned(ctx);
TRACE("%lx: DW_CFA_GNU_args_size %lu\n", info->ip, args);
/* ignored */
break;
}
default:
FIXME("%lx: unknown CFA opcode %02x\n", info->ip, op);
break;
}
}
}
/* retrieve a context register from its dwarf number */
static ULONG_PTR get_context_reg(CONTEXT *context, ULONG_PTR dw_reg)
{
unsigned regno = dbghelp_current_cpu->map_dwarf_register(dw_reg), sz;
ULONG_PTR* ptr = dbghelp_current_cpu->fetch_context_reg(context, regno, &sz);
if (sz != sizeof(ULONG_PTR))
{
FIXME("reading register %lu/%u of wrong size %u\n", dw_reg, regno, sz);
return 0;
}
return *ptr;
}
/* set a context register from its dwarf number */
static void set_context_reg(struct cpu_stack_walk* csw, CONTEXT *context, ULONG_PTR dw_reg,
ULONG_PTR val, BOOL isdebuggee)
{
unsigned regno = dbghelp_current_cpu->map_dwarf_register(dw_reg), sz;
ULONG_PTR* ptr = dbghelp_current_cpu->fetch_context_reg(context, regno, &sz);
if (isdebuggee)
{
char tmp[16];
if (sz > sizeof(tmp))
{
FIXME("register %lu/%u size is too wide: %u\n", dw_reg, regno, sz);
return;
}
if (!sw_read_mem(csw, val, tmp, sz))
{
WARN("Couldn't read memory at %p\n", (void*)val);
return;
}
memcpy(ptr, tmp, sz);
}
else
{
if (sz != sizeof(ULONG_PTR))
{
FIXME("assigning to register %lu/%u of wrong size %u\n", dw_reg, regno, sz);
return;
}
*ptr = val;
}
}
/* copy a register from one context to another using dwarf number */
static void copy_context_reg(CONTEXT *dstcontext, ULONG_PTR dwregdst, CONTEXT* srccontext, ULONG_PTR dwregsrc)
{
unsigned regdstno = dbghelp_current_cpu->map_dwarf_register(dwregdst), szdst;
unsigned regsrcno = dbghelp_current_cpu->map_dwarf_register(dwregsrc), szsrc;
ULONG_PTR* ptrdst = dbghelp_current_cpu->fetch_context_reg(dstcontext, regdstno, &szdst);
ULONG_PTR* ptrsrc = dbghelp_current_cpu->fetch_context_reg(srccontext, regsrcno, &szsrc);
if (szdst != szsrc)
{
FIXME("Cannot copy register %lu/%u => %lu/%u because of size mismatch (%u => %u)\n",
dwregsrc, regsrcno, dwregdst, regdstno, szsrc, szdst);
return;
}
memcpy(ptrdst, ptrsrc, szdst);
}
static ULONG_PTR eval_expression(const struct module* module, struct cpu_stack_walk* csw,
const unsigned char* zp, CONTEXT *context)
{
dwarf2_traverse_context_t ctx;
ULONG_PTR reg, sz, tmp, stack[64];
int sp = -1;
ULONG_PTR len;
ctx.data = zp;
ctx.end_data = zp + 4;
len = dwarf2_leb128_as_unsigned(&ctx);
ctx.end_data = ctx.data + len;
ctx.word_size = module->format_info[DFI_DWARF]->u.dwarf2_info->word_size;
while (ctx.data < ctx.end_data)
{
unsigned char opcode = dwarf2_parse_byte(&ctx);
if (opcode >= DW_OP_lit0 && opcode <= DW_OP_lit31)
stack[++sp] = opcode - DW_OP_lit0;
else if (opcode >= DW_OP_reg0 && opcode <= DW_OP_reg31)
stack[++sp] = get_context_reg(context, opcode - DW_OP_reg0);
else if (opcode >= DW_OP_breg0 && opcode <= DW_OP_breg31)
stack[++sp] = get_context_reg(context, opcode - DW_OP_breg0) + dwarf2_leb128_as_signed(&ctx);
else switch (opcode)
{
case DW_OP_nop: break;
case DW_OP_addr: stack[++sp] = dwarf2_parse_addr(&ctx); break;
case DW_OP_const1u: stack[++sp] = dwarf2_parse_byte(&ctx); break;
case DW_OP_const1s: stack[++sp] = (signed char)dwarf2_parse_byte(&ctx); break;
case DW_OP_const2u: stack[++sp] = dwarf2_parse_u2(&ctx); break;
case DW_OP_const2s: stack[++sp] = (short)dwarf2_parse_u2(&ctx); break;
case DW_OP_const4u: stack[++sp] = dwarf2_parse_u4(&ctx); break;
case DW_OP_const4s: stack[++sp] = (signed int)dwarf2_parse_u4(&ctx); break;
case DW_OP_const8u: stack[++sp] = dwarf2_parse_u8(&ctx); break;
case DW_OP_const8s: stack[++sp] = (LONG_PTR)dwarf2_parse_u8(&ctx); break;
case DW_OP_constu: stack[++sp] = dwarf2_leb128_as_unsigned(&ctx); break;
case DW_OP_consts: stack[++sp] = dwarf2_leb128_as_signed(&ctx); break;
case DW_OP_deref:
if (!sw_read_mem(csw, stack[sp], &tmp, sizeof(tmp)))
{
ERR("Couldn't read memory at %lx\n", stack[sp]);
tmp = 0;
}
stack[sp] = tmp;
break;
case DW_OP_dup: stack[sp + 1] = stack[sp]; sp++; break;
case DW_OP_drop: sp--; break;
case DW_OP_over: stack[sp + 1] = stack[sp - 1]; sp++; break;
case DW_OP_pick: stack[sp + 1] = stack[sp - dwarf2_parse_byte(&ctx)]; sp++; break;
case DW_OP_swap: tmp = stack[sp]; stack[sp] = stack[sp-1]; stack[sp-1] = tmp; break;
case DW_OP_rot: tmp = stack[sp]; stack[sp] = stack[sp-1]; stack[sp-1] = stack[sp-2]; stack[sp-2] = tmp; break;
case DW_OP_abs: stack[sp] = labs(stack[sp]); break;
case DW_OP_neg: stack[sp] = -stack[sp]; break;
case DW_OP_not: stack[sp] = ~stack[sp]; break;
case DW_OP_and: stack[sp-1] &= stack[sp]; sp--; break;
case DW_OP_or: stack[sp-1] |= stack[sp]; sp--; break;
case DW_OP_minus: stack[sp-1] -= stack[sp]; sp--; break;
case DW_OP_mul: stack[sp-1] *= stack[sp]; sp--; break;
case DW_OP_plus: stack[sp-1] += stack[sp]; sp--; break;
case DW_OP_xor: stack[sp-1] ^= stack[sp]; sp--; break;
case DW_OP_shl: stack[sp-1] <<= stack[sp]; sp--; break;
case DW_OP_shr: stack[sp-1] >>= stack[sp]; sp--; break;
case DW_OP_plus_uconst: stack[sp] += dwarf2_leb128_as_unsigned(&ctx); break;
case DW_OP_shra: stack[sp-1] = (LONG_PTR)stack[sp-1] / (1 << stack[sp]); sp--; break;
case DW_OP_div: stack[sp-1] = (LONG_PTR)stack[sp-1] / (LONG_PTR)stack[sp]; sp--; break;
case DW_OP_mod: stack[sp-1] = (LONG_PTR)stack[sp-1] % (LONG_PTR)stack[sp]; sp--; break;
case DW_OP_ge: stack[sp-1] = ((LONG_PTR)stack[sp-1] >= (LONG_PTR)stack[sp]); sp--; break;
case DW_OP_gt: stack[sp-1] = ((LONG_PTR)stack[sp-1] > (LONG_PTR)stack[sp]); sp--; break;
case DW_OP_le: stack[sp-1] = ((LONG_PTR)stack[sp-1] <= (LONG_PTR)stack[sp]); sp--; break;
case DW_OP_lt: stack[sp-1] = ((LONG_PTR)stack[sp-1] < (LONG_PTR)stack[sp]); sp--; break;
case DW_OP_eq: stack[sp-1] = (stack[sp-1] == stack[sp]); sp--; break;
case DW_OP_ne: stack[sp-1] = (stack[sp-1] != stack[sp]); sp--; break;
case DW_OP_skip: tmp = (short)dwarf2_parse_u2(&ctx); ctx.data += tmp; break;
case DW_OP_bra: tmp = (short)dwarf2_parse_u2(&ctx); if (!stack[sp--]) ctx.data += tmp; break;
case DW_OP_GNU_encoded_addr:
tmp = dwarf2_parse_byte(&ctx);
stack[++sp] = dwarf2_parse_augmentation_ptr(&ctx, tmp);
break;
case DW_OP_regx:
stack[++sp] = get_context_reg(context, dwarf2_leb128_as_unsigned(&ctx));
break;
case DW_OP_bregx:
reg = dwarf2_leb128_as_unsigned(&ctx);
tmp = dwarf2_leb128_as_signed(&ctx);
stack[++sp] = get_context_reg(context, reg) + tmp;
break;
case DW_OP_deref_size:
sz = dwarf2_parse_byte(&ctx);
if (!sw_read_mem(csw, stack[sp], &tmp, sz))
{
ERR("Couldn't read memory at %lx\n", stack[sp]);
tmp = 0;
}
/* do integral promotion */
switch (sz)
{
case 1: stack[sp] = *(unsigned char*)&tmp; break;
case 2: stack[sp] = *(unsigned short*)&tmp; break;
case 4: stack[sp] = *(unsigned int*)&tmp; break;
case 8: stack[sp] = *(ULONG_PTR*)&tmp; break; /* FIXME: won't work on 32bit platform */
default: FIXME("Unknown size for deref 0x%lx\n", sz);
}
break;
default:
FIXME("unhandled opcode %02x\n", opcode);
}
}
return stack[sp];
}
static void apply_frame_state(const struct module* module, struct cpu_stack_walk* csw,
CONTEXT *context, struct frame_state *state, ULONG_PTR* cfa)
{
unsigned int i;
ULONG_PTR value;
CONTEXT new_context = *context;
switch (state->cfa_rule)
{
case RULE_EXPRESSION:
*cfa = eval_expression(module, csw, (const unsigned char*)state->cfa_offset, context);
if (!sw_read_mem(csw, *cfa, cfa, sizeof(*cfa)))
{
WARN("Couldn't read memory at %p\n", (void*)*cfa);
return;
}
break;
case RULE_VAL_EXPRESSION:
*cfa = eval_expression(module, csw, (const unsigned char*)state->cfa_offset, context);
break;
default:
*cfa = get_context_reg(context, state->cfa_reg) + state->cfa_offset;
break;
}
if (!*cfa) return;
for (i = 0; i < NB_FRAME_REGS; i++)
{
switch (state->rules[i])
{
case RULE_UNSET:
case RULE_UNDEFINED:
case RULE_SAME:
break;
case RULE_CFA_OFFSET:
set_context_reg(csw, &new_context, i, *cfa + state->regs[i], TRUE);
break;
case RULE_OTHER_REG:
copy_context_reg(&new_context, i, context, state->regs[i]);
break;
case RULE_EXPRESSION:
value = eval_expression(module, csw, (const unsigned char*)state->regs[i], context);
set_context_reg(csw, &new_context, i, value, TRUE);
break;
case RULE_VAL_EXPRESSION:
value = eval_expression(module, csw, (const unsigned char*)state->regs[i], context);
set_context_reg(csw, &new_context, i, value, FALSE);
break;
}
}
*context = new_context;
}
/***********************************************************************
* dwarf2_virtual_unwind
*
*/
BOOL dwarf2_virtual_unwind(struct cpu_stack_walk* csw, ULONG_PTR ip, CONTEXT* context, ULONG_PTR* cfa)
{
struct module_pair pair;
struct frame_info info;
dwarf2_traverse_context_t cie_ctx, fde_ctx;
struct module_format* modfmt;
const unsigned char* end;
DWORD_PTR delta;
if (!(pair.pcs = process_find_by_handle(csw->hProcess)) ||
!(pair.requested = module_find_by_addr(pair.pcs, ip, DMT_UNKNOWN)) ||
!module_get_debug(&pair))
return FALSE;
modfmt = pair.effective->format_info[DFI_DWARF];
if (!modfmt) return FALSE;
memset(&info, 0, sizeof(info));
fde_ctx.data = modfmt->u.dwarf2_info->eh_frame.address;
fde_ctx.end_data = fde_ctx.data + modfmt->u.dwarf2_info->eh_frame.size;
fde_ctx.word_size = modfmt->u.dwarf2_info->word_size;
/* let offsets relative to the eh_frame sections be correctly computed, as we'll map
* in this process the IMAGE section at a different address as the one expected by
* the image
*/
delta = pair.effective->module.BaseOfImage + modfmt->u.dwarf2_info->eh_frame.rva -
(DWORD_PTR)modfmt->u.dwarf2_info->eh_frame.address;
if (!dwarf2_get_cie(ip, pair.effective, delta, &fde_ctx, &cie_ctx, &info, TRUE))
{
fde_ctx.data = modfmt->u.dwarf2_info->debug_frame.address;
fde_ctx.end_data = fde_ctx.data + modfmt->u.dwarf2_info->debug_frame.size;
fde_ctx.word_size = modfmt->u.dwarf2_info->word_size;
delta = pair.effective->reloc_delta;
if (!dwarf2_get_cie(ip, pair.effective, delta, &fde_ctx, &cie_ctx, &info, FALSE))
{
TRACE("Couldn't find information for %lx\n", ip);
return FALSE;
}
}
TRACE("function %lx/%lx code_align %lu data_align %ld retaddr %s\n",
ip, info.ip, info.code_align, info.data_align,
dbghelp_current_cpu->fetch_regname(dbghelp_current_cpu->map_dwarf_register(info.retaddr_reg)));
/* if at very beginning of function, return and use default unwinder */
if (ip == info.ip) return FALSE;
execute_cfa_instructions(&cie_ctx, ip, &info);
if (info.aug_z_format) /* get length of augmentation data */
{
ULONG_PTR len = dwarf2_leb128_as_unsigned(&fde_ctx);
end = fde_ctx.data + len;
}
else end = NULL;
dwarf2_parse_augmentation_ptr(&fde_ctx, info.lsda_encoding); /* handler_data */
if (end) fde_ctx.data = end;
execute_cfa_instructions(&fde_ctx, ip, &info);
apply_frame_state(pair.effective, csw, context, &info.state, cfa);
return TRUE;
}
static void dwarf2_location_compute(struct process* pcs,
const struct module_format* modfmt,
const struct symt_function* func,
struct location* loc)
{
struct location frame;
DWORD_PTR ip;
int err;
dwarf2_traverse_context_t lctx;
if (!func->container || func->container->tag != SymTagCompiland)
{
WARN("We'd expect function %s's container to exist and be a compiland\n", func->hash_elt.name);
err = loc_err_internal;
}
else
{
/* instruction pointer relative to compiland's start */
ip = pcs->ctx_frame.InstructionOffset - ((struct symt_compiland*)func->container)->address;
if ((err = loc_compute_frame(pcs, modfmt, func, ip, &frame)) == 0)
{
switch (loc->kind)
{
case loc_dwarf2_location_list:
/* Then, if the variable has a location list, find it !! */
if (dwarf2_lookup_loclist(modfmt,
modfmt->u.dwarf2_info->debug_loc.address + loc->offset,
ip, &lctx))
goto do_compute;
err = loc_err_out_of_scope;
break;
case loc_dwarf2_block:
/* or if we have a copy of an existing block, get ready for it */
{
unsigned* ptr = (unsigned*)loc->offset;
lctx.data = (const BYTE*)(ptr + 1);
lctx.end_data = lctx.data + *ptr;
lctx.word_size = modfmt->u.dwarf2_info->word_size;
}
do_compute:
/* now get the variable */
err = compute_location(&lctx, loc, pcs->handle, &frame);
break;
case loc_register:
case loc_regrel:
/* nothing to do */
break;
default:
WARN("Unsupported local kind %d\n", loc->kind);
err = loc_err_internal;
}
}
}
if (err < 0)
{
loc->kind = loc_register;
loc->reg = err;
}
}
#ifdef HAVE_ZLIB
static void *zalloc(void *priv, uInt items, uInt sz)
{
return HeapAlloc(GetProcessHeap(), 0, items * sz);
}
static void zfree(void *priv, void *addr)
{
HeapFree(GetProcessHeap(), 0, addr);
}
static inline BOOL dwarf2_init_zsection(dwarf2_section_t* section,
const char* zsectname,
struct image_section_map* ism)
{
z_stream z;
LARGE_INTEGER li;
int res;
BOOL ret = FALSE;
BYTE *addr, *sect = (BYTE *)image_map_section(ism);
size_t sz = image_get_map_size(ism);
if (sz <= 12 || memcmp(sect, "ZLIB", 4))
{
ERR("invalid compressed section %s\n", zsectname);
goto out;
}
#ifdef WORDS_BIGENDIAN
li.u.HighPart = *(DWORD*)&sect[4];
li.u.LowPart = *(DWORD*)&sect[8];
#else
li.u.HighPart = RtlUlongByteSwap(*(DWORD*)&sect[4]);
li.u.LowPart = RtlUlongByteSwap(*(DWORD*)&sect[8]);
#endif
addr = HeapAlloc(GetProcessHeap(), 0, li.QuadPart);
if (!addr)
goto out;
z.next_in = &sect[12];
z.avail_in = sz - 12;
z.opaque = NULL;
z.zalloc = zalloc;
z.zfree = zfree;
res = inflateInit(&z);
if (res != Z_OK)
{
FIXME("inflateInit failed with %i / %s\n", res, z.msg);
goto out_free;
}
do {
z.next_out = addr + z.total_out;
z.avail_out = li.QuadPart - z.total_out;
res = inflate(&z, Z_FINISH);
} while (z.avail_in && res == Z_STREAM_END);
if (res != Z_STREAM_END)
{
FIXME("Decompression failed with %i / %s\n", res, z.msg);
goto out_end;
}
ret = TRUE;
section->compressed = TRUE;
section->address = addr;
section->rva = image_get_map_rva(ism);
section->size = z.total_out;
out_end:
inflateEnd(&z);
out_free:
if (!ret)
HeapFree(GetProcessHeap(), 0, addr);
out:
image_unmap_section(ism);
return ret;
}
#endif
static inline BOOL dwarf2_init_section(dwarf2_section_t* section, struct image_file_map* fmap,
const char* sectname, const char* zsectname,
struct image_section_map* ism)
{
struct image_section_map local_ism;
if (!ism) ism = &local_ism;
section->compressed = FALSE;
if (image_find_section(fmap, sectname, ism))
{
section->address = (const BYTE*)image_map_section(ism);
section->size = image_get_map_size(ism);
section->rva = image_get_map_rva(ism);
return TRUE;
}
section->address = NULL;
section->size = 0;
section->rva = 0;
if (zsectname && image_find_section(fmap, zsectname, ism))
{
#ifdef HAVE_ZLIB
return dwarf2_init_zsection(section, zsectname, ism);
#else
FIXME("dbghelp not built with zlib, but compressed section found\n" );
#endif
}
return FALSE;
}
static inline void dwarf2_fini_section(dwarf2_section_t* section)
{
if (section->compressed)
HeapFree(GetProcessHeap(), 0, (void*)section->address);
}
static void dwarf2_module_remove(struct process* pcs, struct module_format* modfmt)
{
dwarf2_fini_section(&modfmt->u.dwarf2_info->debug_loc);
dwarf2_fini_section(&modfmt->u.dwarf2_info->debug_frame);
HeapFree(GetProcessHeap(), 0, modfmt);
}
BOOL dwarf2_parse(struct module* module, unsigned long load_offset,
const struct elf_thunk_area* thunks,
struct image_file_map* fmap)
{
dwarf2_section_t eh_frame, section[section_max];
dwarf2_traverse_context_t mod_ctx;
struct image_section_map debug_sect, debug_str_sect, debug_abbrev_sect,
debug_line_sect, debug_ranges_sect, eh_frame_sect;
BOOL ret = TRUE;
struct module_format* dwarf2_modfmt;
dwarf2_init_section(&eh_frame, fmap, ".eh_frame", NULL, &eh_frame_sect);
dwarf2_init_section(&section[section_debug], fmap, ".debug_info", ".zdebug_info", &debug_sect);
dwarf2_init_section(&section[section_abbrev], fmap, ".debug_abbrev", ".zdebug_abbrev", &debug_abbrev_sect);
dwarf2_init_section(&section[section_string], fmap, ".debug_str", ".zdebug_str", &debug_str_sect);
dwarf2_init_section(&section[section_line], fmap, ".debug_line", ".zdebug_line", &debug_line_sect);
dwarf2_init_section(&section[section_ranges], fmap, ".debug_ranges", ".zdebug_ranges", &debug_ranges_sect);
/* to do anything useful we need either .eh_frame or .debug_info */
if ((!eh_frame.address || eh_frame.address == IMAGE_NO_MAP) &&
(!section[section_debug].address || section[section_debug].address == IMAGE_NO_MAP))
{
ret = FALSE;
goto leave;
}
if (fmap->modtype == DMT_ELF && debug_sect.fmap)
{
/* debug info might have a different base address than .so file
* when elf file is prelinked after splitting off debug info
* adjust symbol base addresses accordingly
*/
load_offset += fmap->u.elf.elf_start - debug_sect.fmap->u.elf.elf_start;
}
TRACE("Loading Dwarf2 information for %s\n", debugstr_w(module->module.ModuleName));
mod_ctx.data = section[section_debug].address;
mod_ctx.end_data = mod_ctx.data + section[section_debug].size;
mod_ctx.word_size = 0; /* will be correctly set later on */
dwarf2_modfmt = HeapAlloc(GetProcessHeap(), 0,
sizeof(*dwarf2_modfmt) + sizeof(*dwarf2_modfmt->u.dwarf2_info));
if (!dwarf2_modfmt)
{
ret = FALSE;
goto leave;
}
dwarf2_modfmt->module = module;
dwarf2_modfmt->remove = dwarf2_module_remove;
dwarf2_modfmt->loc_compute = dwarf2_location_compute;
dwarf2_modfmt->u.dwarf2_info = (struct dwarf2_module_info_s*)(dwarf2_modfmt + 1);
dwarf2_modfmt->u.dwarf2_info->word_size = 0; /* will be correctly set later on */
dwarf2_modfmt->module->format_info[DFI_DWARF] = dwarf2_modfmt;
/* As we'll need later some sections' content, we won't unmap these
* sections upon existing this function
*/
dwarf2_init_section(&dwarf2_modfmt->u.dwarf2_info->debug_loc, fmap, ".debug_loc", ".zdebug_loc", NULL);
dwarf2_init_section(&dwarf2_modfmt->u.dwarf2_info->debug_frame, fmap, ".debug_frame", ".zdebug_frame", NULL);
dwarf2_modfmt->u.dwarf2_info->eh_frame = eh_frame;
while (mod_ctx.data < mod_ctx.end_data)
{
dwarf2_parse_compilation_unit(section, dwarf2_modfmt->module, thunks, &mod_ctx, load_offset);
}
dwarf2_modfmt->module->module.SymType = SymDia;
dwarf2_modfmt->module->module.CVSig = 'D' | ('W' << 8) | ('A' << 16) | ('R' << 24);
/* FIXME: we could have a finer grain here */
dwarf2_modfmt->module->module.GlobalSymbols = TRUE;
dwarf2_modfmt->module->module.TypeInfo = TRUE;
dwarf2_modfmt->module->module.SourceIndexed = TRUE;
dwarf2_modfmt->module->module.Publics = TRUE;
/* set the word_size for eh_frame parsing */
dwarf2_modfmt->u.dwarf2_info->word_size = fmap->addr_size / 8;
leave:
dwarf2_fini_section(&section[section_debug]);
dwarf2_fini_section(&section[section_abbrev]);
dwarf2_fini_section(&section[section_string]);
dwarf2_fini_section(&section[section_line]);
dwarf2_fini_section(&section[section_ranges]);
image_unmap_section(&debug_sect);
image_unmap_section(&debug_abbrev_sect);
image_unmap_section(&debug_str_sect);
image_unmap_section(&debug_line_sect);
image_unmap_section(&debug_ranges_sect);
if (!ret) image_unmap_section(&eh_frame_sect);
return ret;
}