Sweden-Number/programs/winedbg/info.c

987 lines
32 KiB
C

/*
* Wine debugger utility routines
*
* Copyright 1993 Eric Youngdale
* Copyright 1995 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
*/
#include "config.h"
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <stdarg.h>
#include "debugger.h"
#include "wingdi.h"
#include "winuser.h"
#include "tlhelp32.h"
#include "wine/debug.h"
#include "wine/exception.h"
WINE_DEFAULT_DEBUG_CHANNEL(winedbg);
/***********************************************************************
* print_help
*
* Implementation of the 'help' command.
*/
void print_help(void)
{
int i = 0;
static const char * const helptext[] =
{
"The commands accepted by the Wine debugger are a reasonable",
"subset of the commands that gdb accepts.",
"The commands currently are:",
" help quit",
" attach <wpid> detach",
" break [*<addr>] watch | rwatch *<addr>",
" delete break bpnum disable bpnum",
" enable bpnum condition <bpnum> [<expr>]",
" finish cont [N]",
" step [N] next [N]",
" stepi [N] nexti [N]",
" x <addr> print <expr>",
" display <expr> undisplay <disnum>",
" local display <expr> delete display <disnum>",
" enable display <disnum> disable display <disnum>",
" bt [<tid>|all] frame <n>",
" up down",
" list <lines> disassemble [<addr>][,<addr>]",
" show dir dir <path>",
" set <reg> = <expr> set *<addr> = <expr>",
" pass whatis",
" info (see 'help info' for options)",
"The 'x' command accepts repeat counts and formats (including 'i') in the",
"same way that gdb does.\n",
"The following are examples of legal expressions:",
" $eax $eax+0x3 0x1000 ($eip + 256) *$eax *($esp + 3)",
" Also, a nm format symbol table can be read from a file using the",
" symbolfile command.", /* Symbols can also be defined individually with",
" the define command.", */
"",
NULL
};
while (helptext[i]) dbg_printf("%s\n", helptext[i++]);
}
/***********************************************************************
* info_help
*
* Implementation of the 'help info' command.
*/
void info_help(void)
{
int i = 0;
static const char * const infotext[] =
{
"The info commands allow you to get assorted bits of interesting stuff",
"to be displayed. The options are:",
" info break Displays information about breakpoints",
" info class <name> Displays information about window class <name>",
" info display Shows auto-display expressions in use",
" info except <pid> Shows exception handler chain (in a given process)",
" info locals Displays values of all local vars for current frame",
" info maps <pid> Shows virtual mappings (in a given process)",
" info process Shows all running processes",
" info reg Displays values of the general registers at top of stack",
" info all-reg Displays the general and floating point registers",
" info segments <pid> Displays information about all known segments",
" info share Displays all loaded modules",
" info share <addr> Displays internal module state",
" info stack [<len>] Dumps information about top of stack, up to len words",
" info symbol <sym> Displays information about a given symbol",
" info thread Shows all running threads",
" info wnd <handle> Displays internal window state",
"",
NULL
};
while (infotext[i]) dbg_printf("%s\n", infotext[i++]);
}
static const char* get_symtype_str(const IMAGEHLP_MODULE64* mi)
{
switch (mi->SymType)
{
default:
case SymNone: return "--none--";
case SymCoff: return "COFF";
case SymCv: return "CodeView";
case SymPdb: return "PDB";
case SymExport: return "Export";
case SymDeferred: return "Deferred";
case SymSym: return "Sym";
case SymDia:
switch (mi->CVSig)
{
case 'S' | ('T' << 8) | ('A' << 16) | ('B' << 24):
return "Stabs";
case 'D' | ('W' << 8) | ('A' << 16) | ('R' << 24):
return "Dwarf";
default:
return "DIA";
}
}
}
struct info_module
{
IMAGEHLP_MODULE64* mi;
unsigned num_alloc;
unsigned num_used;
};
static void module_print_info(const IMAGEHLP_MODULE64* mi, BOOL is_embedded)
{
dbg_printf("%*.*s-%*.*s\t%-16s%s\n",
ADDRWIDTH, ADDRWIDTH, wine_dbgstr_longlong(mi->BaseOfImage),
ADDRWIDTH, ADDRWIDTH, wine_dbgstr_longlong(mi->BaseOfImage + mi->ImageSize),
is_embedded ? "\\" : get_symtype_str(mi), mi->ModuleName);
}
static int module_compare(const void* p1, const void* p2)
{
LONGLONG val = ((const IMAGEHLP_MODULE64*)p1)->BaseOfImage -
((const IMAGEHLP_MODULE64*)p2)->BaseOfImage;
if (val < 0) return -1;
else if (val > 0) return 1;
else return 0;
}
static inline BOOL module_is_container(const IMAGEHLP_MODULE64* wmod_cntnr,
const IMAGEHLP_MODULE64* wmod_child)
{
return wmod_cntnr->BaseOfImage <= wmod_child->BaseOfImage &&
wmod_cntnr->BaseOfImage + wmod_cntnr->ImageSize >=
wmod_child->BaseOfImage + wmod_child->ImageSize;
}
static BOOL CALLBACK info_mod_cb(PCSTR mod_name, DWORD64 base, PVOID ctx)
{
struct info_module* im = ctx;
if (im->num_used + 1 > im->num_alloc)
{
im->num_alloc += 16;
im->mi = dbg_heap_realloc(im->mi, im->num_alloc * sizeof(*im->mi));
}
im->mi[im->num_used].SizeOfStruct = sizeof(im->mi[im->num_used]);
if (SymGetModuleInfo64(dbg_curr_process->handle, base, &im->mi[im->num_used]))
{
im->num_used++;
}
return TRUE;
}
/***********************************************************************
* info_win32_module
*
* Display information about a given module (DLL or EXE), or about all modules
*/
void info_win32_module(DWORD64 base)
{
struct info_module im;
UINT i, j, num_printed = 0;
DWORD opt;
if (!dbg_curr_process)
{
dbg_printf("Cannot get info on module while no process is loaded\n");
return;
}
im.mi = NULL;
im.num_alloc = im.num_used = 0;
/* this is a wine specific options to return also ELF modules in the
* enumeration
*/
SymSetOptions((opt = SymGetOptions()) | 0x40000000);
SymEnumerateModules64(dbg_curr_process->handle, info_mod_cb, (void*)&im);
SymSetOptions(opt);
qsort(im.mi, im.num_used, sizeof(im.mi[0]), module_compare);
dbg_printf("Module\tAddress\t\t\t%sDebug info\tName (%d modules)\n",
ADDRWIDTH == 16 ? "\t\t" : "", im.num_used);
for (i = 0; i < im.num_used; i++)
{
if (base &&
(base < im.mi[i].BaseOfImage || base >= im.mi[i].BaseOfImage + im.mi[i].ImageSize))
continue;
if (strstr(im.mi[i].ModuleName, "<elf>"))
{
dbg_printf("ELF\t");
module_print_info(&im.mi[i], FALSE);
/* print all modules embedded in this one */
for (j = 0; j < im.num_used; j++)
{
if (!strstr(im.mi[j].ModuleName, "<elf>") && module_is_container(&im.mi[i], &im.mi[j]))
{
dbg_printf(" \\-PE\t");
module_print_info(&im.mi[j], TRUE);
}
}
}
else
{
/* check module is not embedded in another module */
for (j = 0; j < im.num_used; j++)
{
if (strstr(im.mi[j].ModuleName, "<elf>") && module_is_container(&im.mi[j], &im.mi[i]))
break;
}
if (j < im.num_used) continue;
if (strstr(im.mi[i].ModuleName, ".so") || strchr(im.mi[i].ModuleName, '<'))
dbg_printf("ELF\t");
else
dbg_printf("PE\t");
module_print_info(&im.mi[i], FALSE);
}
num_printed++;
}
HeapFree(GetProcessHeap(), 0, im.mi);
if (base && !num_printed)
dbg_printf("'0x%x%08x' is not a valid module address\n", (DWORD)(base >> 32), (DWORD)base);
}
struct class_walker
{
ATOM* table;
int used;
int alloc;
};
static void class_walker(HWND hWnd, struct class_walker* cw)
{
char clsName[128];
int i;
ATOM atom;
HWND child;
if (!GetClassNameA(hWnd, clsName, sizeof(clsName)))
return;
if ((atom = FindAtomA(clsName)) == 0)
return;
for (i = 0; i < cw->used; i++)
{
if (cw->table[i] == atom)
break;
}
if (i == cw->used)
{
if (cw->used >= cw->alloc)
{
cw->alloc += 16;
cw->table = dbg_heap_realloc(cw->table, cw->alloc * sizeof(ATOM));
}
cw->table[cw->used++] = atom;
info_win32_class(hWnd, clsName);
}
do
{
if ((child = GetWindow(hWnd, GW_CHILD)) != 0)
class_walker(child, cw);
} while ((hWnd = GetWindow(hWnd, GW_HWNDNEXT)) != 0);
}
void info_win32_class(HWND hWnd, const char* name)
{
WNDCLASSEXA wca;
HINSTANCE hInst = hWnd ? (HINSTANCE)GetWindowLongPtrW(hWnd, GWLP_HINSTANCE) : 0;
if (!name)
{
struct class_walker cw;
cw.table = NULL;
cw.used = cw.alloc = 0;
class_walker(GetDesktopWindow(), &cw);
HeapFree(GetProcessHeap(), 0, cw.table);
return;
}
if (!GetClassInfoExA(hInst, name, &wca))
{
dbg_printf("Cannot find class '%s'\n", name);
return;
}
dbg_printf("Class '%s':\n", name);
dbg_printf("style=0x%08x wndProc=%p\n"
"inst=%p icon=%p cursor=%p bkgnd=%p\n"
"clsExtra=%d winExtra=%d\n",
wca.style, wca.lpfnWndProc, wca.hInstance,
wca.hIcon, wca.hCursor, wca.hbrBackground,
wca.cbClsExtra, wca.cbWndExtra);
if (hWnd && wca.cbClsExtra)
{
int i;
WORD w;
dbg_printf("Extra bytes:");
for (i = 0; i < wca.cbClsExtra / 2; i++)
{
w = GetClassWord(hWnd, i * 2);
/* FIXME: depends on i386 endian-ity */
dbg_printf(" %02x %02x", HIBYTE(w), LOBYTE(w));
}
dbg_printf("\n");
}
dbg_printf("\n");
/* FIXME:
* + print #windows (or even list of windows...)
* + print extra bytes => this requires a window handle on this very class...
*/
}
static void info_window(HWND hWnd, int indent)
{
char clsName[128];
char wndName[128];
HWND child;
do
{
if (!GetClassNameA(hWnd, clsName, sizeof(clsName)))
strcpy(clsName, "-- Unknown --");
if (!GetWindowTextA(hWnd, wndName, sizeof(wndName)))
strcpy(wndName, "-- Empty --");
dbg_printf("%*s%08lx%*s %-17.17s %08x %0*lx %08x %.14s\n",
indent, "", (DWORD_PTR)hWnd, 12 - indent, "",
clsName, GetWindowLongW(hWnd, GWL_STYLE),
ADDRWIDTH, (ULONG_PTR)GetWindowLongPtrW(hWnd, GWLP_WNDPROC),
GetWindowThreadProcessId(hWnd, NULL), wndName);
if ((child = GetWindow(hWnd, GW_CHILD)) != 0)
info_window(child, indent + 1);
} while ((hWnd = GetWindow(hWnd, GW_HWNDNEXT)) != 0);
}
void info_win32_window(HWND hWnd, BOOL detailed)
{
char clsName[128];
char wndName[128];
RECT clientRect;
RECT windowRect;
WORD w;
if (!IsWindow(hWnd)) hWnd = GetDesktopWindow();
if (!detailed)
{
dbg_printf("%-20.20s %-17.17s %-8.8s %-*.*s %-8.8s %s\n",
"Window handle", "Class Name", "Style",
ADDRWIDTH, ADDRWIDTH, "WndProc", "Thread", "Text");
info_window(hWnd, 0);
return;
}
if (!GetClassNameA(hWnd, clsName, sizeof(clsName)))
strcpy(clsName, "-- Unknown --");
if (!GetWindowTextA(hWnd, wndName, sizeof(wndName)))
strcpy(wndName, "-- Empty --");
if (!GetClientRect(hWnd, &clientRect) ||
!MapWindowPoints(hWnd, 0, (LPPOINT) &clientRect, 2))
SetRectEmpty(&clientRect);
if (!GetWindowRect(hWnd, &windowRect))
SetRectEmpty(&windowRect);
/* FIXME missing fields: hmemTaskQ, hrgnUpdate, dce, flags, pProp, scroll */
dbg_printf("next=%p child=%p parent=%p owner=%p class='%s'\n"
"inst=%p active=%p idmenu=%08lx\n"
"style=0x%08x exstyle=0x%08x wndproc=%p text='%s'\n"
"client=%d,%d-%d,%d window=%d,%d-%d,%d sysmenu=%p\n",
GetWindow(hWnd, GW_HWNDNEXT),
GetWindow(hWnd, GW_CHILD),
GetParent(hWnd),
GetWindow(hWnd, GW_OWNER),
clsName,
(HINSTANCE)GetWindowLongPtrW(hWnd, GWLP_HINSTANCE),
GetLastActivePopup(hWnd),
(ULONG_PTR)GetWindowLongPtrW(hWnd, GWLP_ID),
GetWindowLongW(hWnd, GWL_STYLE),
GetWindowLongW(hWnd, GWL_EXSTYLE),
(void*)GetWindowLongPtrW(hWnd, GWLP_WNDPROC),
wndName,
clientRect.left, clientRect.top, clientRect.right, clientRect.bottom,
windowRect.left, windowRect.top, windowRect.right, windowRect.bottom,
GetSystemMenu(hWnd, FALSE));
if (GetClassLongW(hWnd, GCL_CBWNDEXTRA))
{
UINT i;
dbg_printf("Extra bytes:");
for (i = 0; i < GetClassLongW(hWnd, GCL_CBWNDEXTRA) / 2; i++)
{
w = GetWindowWord(hWnd, i * 2);
/* FIXME: depends on i386 endian-ity */
dbg_printf(" %02x %02x", HIBYTE(w), LOBYTE(w));
}
dbg_printf("\n");
}
dbg_printf("\n");
}
struct dump_proc_entry
{
PROCESSENTRY32 proc;
unsigned children; /* index in dump_proc.entries of first child */
unsigned sibling; /* index in dump_proc.entries of next sibling */
};
struct dump_proc
{
struct dump_proc_entry*entries;
unsigned count;
unsigned alloc;
};
static unsigned get_parent(const struct dump_proc* dp, unsigned idx)
{
unsigned i;
for (i = 0; i < dp->count; i++)
{
if (i != idx && dp->entries[i].proc.th32ProcessID == dp->entries[idx].proc.th32ParentProcessID)
return i;
}
return -1;
}
static void dump_proc_info(const struct dump_proc* dp, unsigned idx, unsigned depth)
{
struct dump_proc_entry* dpe;
for ( ; idx != -1; idx = dp->entries[idx].sibling)
{
assert(idx < dp->count);
dpe = &dp->entries[idx];
dbg_printf("%c%08x %-8d ",
(dpe->proc.th32ProcessID == (dbg_curr_process ?
dbg_curr_process->pid : 0)) ? '>' : ' ',
dpe->proc.th32ProcessID, dpe->proc.cntThreads);
if (depth)
{
unsigned i;
for (i = 3 * (depth - 1); i > 0; i--) dbg_printf(" ");
dbg_printf("\\_ ");
}
dbg_printf("'%s'\n", dpe->proc.szExeFile);
dump_proc_info(dp, dpe->children, depth + 1);
}
}
void info_win32_processes(void)
{
HANDLE snap = CreateToolhelp32Snapshot(TH32CS_SNAPPROCESS, 0);
if (snap != INVALID_HANDLE_VALUE)
{
struct dump_proc dp;
unsigned i, first = -1;
BOOL ok;
dp.count = 0;
dp.alloc = 16;
dp.entries = HeapAlloc(GetProcessHeap(), 0, sizeof(*dp.entries) * dp.alloc);
if (!dp.entries)
{
CloseHandle(snap);
return;
}
dp.entries[dp.count].proc.dwSize = sizeof(dp.entries[dp.count].proc);
ok = Process32First(snap, &dp.entries[dp.count].proc);
/* fetch all process information into dp (skipping this debugger) */
while (ok)
{
if (dp.entries[dp.count].proc.th32ProcessID != GetCurrentProcessId())
dp.entries[dp.count++].children = -1;
if (dp.count >= dp.alloc)
{
dp.entries = HeapReAlloc(GetProcessHeap(), 0, dp.entries, sizeof(*dp.entries) * (dp.alloc *= 2));
if (!dp.entries) return;
}
dp.entries[dp.count].proc.dwSize = sizeof(dp.entries[dp.count].proc);
ok = Process32Next(snap, &dp.entries[dp.count].proc);
}
CloseHandle(snap);
/* chain the siblings wrt. their parent */
for (i = 0; i < dp.count; i++)
{
unsigned parent = get_parent(&dp, i);
unsigned *chain = parent == -1 ? &first : &dp.entries[parent].children;
dp.entries[i].sibling = *chain;
*chain = i;
}
dbg_printf(" %-8.8s %-8.8s %s (all id:s are in hex)\n", "pid", "threads", "executable");
dump_proc_info(&dp, first, 0);
HeapFree(GetProcessHeap(), 0, dp.entries);
}
}
static BOOL get_process_name(DWORD pid, PROCESSENTRY32* entry)
{
BOOL ret = FALSE;
HANDLE snap = CreateToolhelp32Snapshot(TH32CS_SNAPPROCESS, 0);
if (snap != INVALID_HANDLE_VALUE)
{
entry->dwSize = sizeof(*entry);
if (Process32First(snap, entry))
while (!(ret = (entry->th32ProcessID == pid)) &&
Process32Next(snap, entry));
CloseHandle(snap);
}
return ret;
}
void info_win32_threads(void)
{
HANDLE snap = CreateToolhelp32Snapshot(TH32CS_SNAPTHREAD, 0);
if (snap != INVALID_HANDLE_VALUE)
{
THREADENTRY32 entry;
BOOL ok;
DWORD lastProcessId = 0;
entry.dwSize = sizeof(entry);
ok = Thread32First(snap, &entry);
dbg_printf("%-8.8s %-8.8s %s (all id:s are in hex)\n",
"process", "tid", "prio");
while (ok)
{
if (entry.th32OwnerProcessID != GetCurrentProcessId())
{
/* FIXME: this assumes that, in the snapshot, all threads of a same process are
* listed sequentially, which is not specified in the doc (Wine's implementation
* does it)
*/
if (entry.th32OwnerProcessID != lastProcessId)
{
struct dbg_process* p = dbg_get_process(entry.th32OwnerProcessID);
PROCESSENTRY32 pcs_entry;
const char* exename;
if (p)
exename = dbg_W2A(p->imageName, -1);
else if (get_process_name(entry.th32OwnerProcessID, &pcs_entry))
exename = pcs_entry.szExeFile;
else
exename = "";
dbg_printf("%08x%s %s\n",
entry.th32OwnerProcessID, p ? " (D)" : "", exename);
lastProcessId = entry.th32OwnerProcessID;
}
dbg_printf("\t%08x %4d%s\n",
entry.th32ThreadID, entry.tpBasePri,
(entry.th32ThreadID == dbg_curr_tid) ? " <==" : "");
}
ok = Thread32Next(snap, &entry);
}
CloseHandle(snap);
}
}
/***********************************************************************
* info_win32_frame_exceptions
*
* Get info on the exception frames of a given thread.
*/
void info_win32_frame_exceptions(DWORD tid)
{
struct dbg_thread* thread;
void* next_frame;
if (!dbg_curr_process || !dbg_curr_thread)
{
dbg_printf("Cannot get info on exceptions while no process is loaded\n");
return;
}
dbg_printf("Exception frames:\n");
if (tid == dbg_curr_tid) thread = dbg_curr_thread;
else
{
thread = dbg_get_thread(dbg_curr_process, tid);
if (!thread)
{
dbg_printf("Unknown thread id (%04x) in current process\n", tid);
return;
}
if (SuspendThread(thread->handle) == -1)
{
dbg_printf("Can't suspend thread id (%04x)\n", tid);
return;
}
}
if (!dbg_read_memory(thread->teb, &next_frame, sizeof(next_frame)))
{
dbg_printf("Can't read TEB:except_frame\n");
return;
}
while (next_frame != (void*)-1)
{
EXCEPTION_REGISTRATION_RECORD frame;
dbg_printf("%p: ", next_frame);
if (!dbg_read_memory(next_frame, &frame, sizeof(frame)))
{
dbg_printf("Invalid frame address\n");
break;
}
dbg_printf("prev=%p handler=%p\n", frame.Prev, frame.Handler);
next_frame = frame.Prev;
}
if (tid != dbg_curr_tid) ResumeThread(thread->handle);
}
void info_win32_segments(DWORD start, int length)
{
char flags[3];
DWORD i;
LDT_ENTRY le;
if (length == -1) length = (8192 - start);
for (i = start; i < start + length; i++)
{
if (!dbg_curr_process->process_io->get_selector(dbg_curr_thread->handle, (i << 3) | 7, &le))
continue;
if (le.HighWord.Bits.Type & 0x08)
{
flags[0] = (le.HighWord.Bits.Type & 0x2) ? 'r' : '-';
flags[1] = '-';
flags[2] = 'x';
}
else
{
flags[0] = 'r';
flags[1] = (le.HighWord.Bits.Type & 0x2) ? 'w' : '-';
flags[2] = '-';
}
dbg_printf("%04x: sel=%04x base=%08x limit=%08x %d-bit %c%c%c\n",
i, (i << 3) | 7,
(le.HighWord.Bits.BaseHi << 24) +
(le.HighWord.Bits.BaseMid << 16) + le.BaseLow,
((le.HighWord.Bits.LimitHi << 8) + le.LimitLow) <<
(le.HighWord.Bits.Granularity ? 12 : 0),
le.HighWord.Bits.Default_Big ? 32 : 16,
flags[0], flags[1], flags[2]);
}
}
void info_win32_virtual(DWORD pid)
{
MEMORY_BASIC_INFORMATION mbi;
char* addr = 0;
const char* state;
const char* type;
char prot[3+1];
HANDLE hProc;
if (pid == dbg_curr_pid)
{
if (dbg_curr_process == NULL)
{
dbg_printf("Cannot look at mapping of current process, while no process is loaded\n");
return;
}
hProc = dbg_curr_process->handle;
}
else
{
hProc = OpenProcess(PROCESS_QUERY_INFORMATION | PROCESS_VM_READ, FALSE, pid);
if (hProc == NULL)
{
dbg_printf("Cannot open process <%04x>\n", pid);
return;
}
}
dbg_printf("Address End State Type RWX\n");
while (VirtualQueryEx(hProc, addr, &mbi, sizeof(mbi)) >= sizeof(mbi))
{
switch (mbi.State)
{
case MEM_COMMIT: state = "commit "; break;
case MEM_FREE: state = "free "; break;
case MEM_RESERVE: state = "reserve"; break;
default: state = "??? "; break;
}
if (mbi.State != MEM_FREE)
{
switch (mbi.Type)
{
case MEM_IMAGE: type = "image "; break;
case MEM_MAPPED: type = "mapped "; break;
case MEM_PRIVATE: type = "private"; break;
case 0: type = " "; break;
default: type = "??? "; break;
}
memset(prot, ' ' , sizeof(prot) - 1);
prot[sizeof(prot) - 1] = '\0';
if (mbi.AllocationProtect & (PAGE_READONLY|PAGE_READWRITE|PAGE_EXECUTE_READ|PAGE_EXECUTE_READWRITE))
prot[0] = 'R';
if (mbi.AllocationProtect & (PAGE_READWRITE|PAGE_EXECUTE_READWRITE))
prot[1] = 'W';
if (mbi.AllocationProtect & (PAGE_WRITECOPY|PAGE_EXECUTE_WRITECOPY))
prot[1] = 'C';
if (mbi.AllocationProtect & (PAGE_EXECUTE|PAGE_EXECUTE_READ|PAGE_EXECUTE_READWRITE))
prot[2] = 'X';
}
else
{
type = "";
prot[0] = '\0';
}
dbg_printf("%08lx %08lx %s %s %s\n",
(DWORD_PTR)addr, (DWORD_PTR)addr + mbi.RegionSize - 1, state, type, prot);
if (addr + mbi.RegionSize < addr) /* wrap around ? */
break;
addr += mbi.RegionSize;
}
if (pid != dbg_curr_pid) CloseHandle(hProc);
}
void info_wine_dbg_channel(BOOL turn_on, const char* cls, const char* name)
{
struct dbg_lvalue lvalue;
struct __wine_debug_channel channel;
unsigned char mask;
int done = 0;
BOOL bAll;
void* addr;
if (!dbg_curr_process || !dbg_curr_thread)
{
dbg_printf("Cannot set/get debug channels while no process is loaded\n");
return;
}
if (symbol_get_lvalue("debug_options", -1, &lvalue, FALSE) != sglv_found)
{
return;
}
addr = memory_to_linear_addr(&lvalue.addr);
if (!cls) mask = ~0;
else if (!strcmp(cls, "fixme")) mask = (1 << __WINE_DBCL_FIXME);
else if (!strcmp(cls, "err")) mask = (1 << __WINE_DBCL_ERR);
else if (!strcmp(cls, "warn")) mask = (1 << __WINE_DBCL_WARN);
else if (!strcmp(cls, "trace")) mask = (1 << __WINE_DBCL_TRACE);
else
{
dbg_printf("Unknown debug class %s\n", cls);
return;
}
bAll = !strcmp("all", name);
while (addr && dbg_read_memory(addr, &channel, sizeof(channel)))
{
if (!channel.name[0]) break;
if (bAll || !strcmp( channel.name, name ))
{
if (turn_on) channel.flags |= mask;
else channel.flags &= ~mask;
if (dbg_write_memory(addr, &channel, sizeof(channel))) done++;
}
addr = (struct __wine_debug_channel *)addr + 1;
}
if (!done) dbg_printf("Unable to find debug channel %s\n", name);
else WINE_TRACE("Changed %d channel instances\n", done);
}
void info_win32_exception(void)
{
const EXCEPTION_RECORD* rec;
ADDRESS64 addr;
char hexbuf[MAX_OFFSET_TO_STR_LEN];
if (!dbg_curr_thread->in_exception)
{
dbg_printf("Thread isn't in an exception\n");
return;
}
rec = &dbg_curr_thread->excpt_record;
memory_get_current_pc(&addr);
/* print some infos */
dbg_printf("%s: ",
dbg_curr_thread->first_chance ? "First chance exception" : "Unhandled exception");
switch (rec->ExceptionCode)
{
case EXCEPTION_BREAKPOINT:
dbg_printf("breakpoint");
break;
case EXCEPTION_SINGLE_STEP:
dbg_printf("single step");
break;
case EXCEPTION_INT_DIVIDE_BY_ZERO:
dbg_printf("divide by zero");
break;
case EXCEPTION_INT_OVERFLOW:
dbg_printf("overflow");
break;
case EXCEPTION_ARRAY_BOUNDS_EXCEEDED:
dbg_printf("array bounds");
break;
case EXCEPTION_ILLEGAL_INSTRUCTION:
dbg_printf("illegal instruction");
break;
case EXCEPTION_STACK_OVERFLOW:
dbg_printf("stack overflow");
break;
case EXCEPTION_PRIV_INSTRUCTION:
dbg_printf("privileged instruction");
break;
case EXCEPTION_ACCESS_VIOLATION:
if (rec->NumberParameters == 2)
dbg_printf("page fault on %s access to 0x%08lx",
rec->ExceptionInformation[0] == EXCEPTION_WRITE_FAULT ? "write" :
rec->ExceptionInformation[0] == EXCEPTION_EXECUTE_FAULT ? "execute" : "read",
rec->ExceptionInformation[1]);
else
dbg_printf("page fault");
break;
case EXCEPTION_DATATYPE_MISALIGNMENT:
dbg_printf("Alignment");
break;
case DBG_CONTROL_C:
dbg_printf("^C");
break;
case CONTROL_C_EXIT:
dbg_printf("^C");
break;
case STATUS_POSSIBLE_DEADLOCK:
{
ADDRESS64 recaddr;
recaddr.Mode = AddrModeFlat;
recaddr.Offset = rec->ExceptionInformation[0];
dbg_printf("wait failed on critical section ");
print_address(&recaddr, FALSE);
}
break;
case EXCEPTION_WINE_STUB:
{
char dll[32], name[256];
memory_get_string(dbg_curr_process,
(void*)rec->ExceptionInformation[0], TRUE, FALSE,
dll, sizeof(dll));
if (HIWORD(rec->ExceptionInformation[1]))
memory_get_string(dbg_curr_process,
(void*)rec->ExceptionInformation[1], TRUE, FALSE,
name, sizeof(name));
else
sprintf( name, "%ld", rec->ExceptionInformation[1] );
dbg_printf("unimplemented function %s.%s called", dll, name);
}
break;
case EXCEPTION_WINE_ASSERTION:
dbg_printf("assertion failed");
break;
case EXCEPTION_VM86_INTx:
dbg_printf("interrupt %02lx in vm86 mode", rec->ExceptionInformation[0]);
break;
case EXCEPTION_VM86_STI:
dbg_printf("sti in vm86 mode");
break;
case EXCEPTION_VM86_PICRETURN:
dbg_printf("PIC return in vm86 mode");
break;
case EXCEPTION_FLT_DENORMAL_OPERAND:
dbg_printf("denormal float operand");
break;
case EXCEPTION_FLT_DIVIDE_BY_ZERO:
dbg_printf("divide by zero");
break;
case EXCEPTION_FLT_INEXACT_RESULT:
dbg_printf("inexact float result");
break;
case EXCEPTION_FLT_INVALID_OPERATION:
dbg_printf("invalid float operation");
break;
case EXCEPTION_FLT_OVERFLOW:
dbg_printf("floating point overflow");
break;
case EXCEPTION_FLT_UNDERFLOW:
dbg_printf("floating point underflow");
break;
case EXCEPTION_FLT_STACK_CHECK:
dbg_printf("floating point stack check");
break;
case CXX_EXCEPTION:
if(rec->NumberParameters == 3 && rec->ExceptionInformation[0] == CXX_FRAME_MAGIC)
dbg_printf("C++ exception(object = 0x%08lx, type = 0x%08lx)",
rec->ExceptionInformation[1], rec->ExceptionInformation[2]);
else
dbg_printf("C++ exception with strange parameter count %d or magic 0x%08lx",
rec->NumberParameters, rec->ExceptionInformation[0]);
break;
default:
dbg_printf("0x%08x", rec->ExceptionCode);
break;
}
if (rec->ExceptionFlags & EH_STACK_INVALID)
dbg_printf(", invalid program stack");
switch (addr.Mode)
{
case AddrModeFlat:
dbg_printf(" in %d-bit code (%s)",
be_cpu->pointer_size * 8,
memory_offset_to_string(hexbuf, addr.Offset, 0));
break;
case AddrModeReal:
dbg_printf(" in vm86 code (%04x:%04x)", addr.Segment, (unsigned) addr.Offset);
break;
case AddrMode1616:
dbg_printf(" in 16-bit code (%04x:%04x)", addr.Segment, (unsigned) addr.Offset);
break;
case AddrMode1632:
dbg_printf(" in segmented 32-bit code (%04x:%08lx)", addr.Segment, (unsigned long) addr.Offset);
break;
default: dbg_printf(" bad address");
}
dbg_printf(".\n");
}