/* * 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 #include #include #include #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 detach", " break [*] watch | rwatch *", " delete break bpnum disable bpnum", " enable bpnum condition []", " finish cont [N]", " step [N] next [N]", " stepi [N] nexti [N]", " x print ", " display undisplay ", " local display delete display ", " enable display disable display ", " bt [|all] frame ", " up down", " list disassemble [][,]", " show dir dir ", " set = set * = ", " pass whatis", " info (see 'help info' for options) thread ", "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 Displays information about window class ", " info display Shows auto-display expressions in use", " info except Shows exception handler chain (in a given process)", " info locals Displays values of all local vars for current frame", " info maps 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 Displays information about all known segments", " info share Displays all loaded modules", " info share Displays internal module state", " info stack [] Dumps information about top of stack, up to len words", " info symbol Displays information about a given symbol", " info thread Shows all running threads", " info wnd 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; char name[64]; }; struct info_modules { struct info_module *modules; unsigned num_alloc; unsigned num_used; }; static void module_print_info(const struct info_module *module, BOOL is_embedded) { dbg_printf("%*.*s-%*.*s\t%-16s%s\n", ADDRWIDTH, ADDRWIDTH, wine_dbgstr_longlong(module->mi.BaseOfImage), ADDRWIDTH, ADDRWIDTH, wine_dbgstr_longlong(module->mi.BaseOfImage + module->mi.ImageSize), is_embedded ? "\\" : get_symtype_str(&module->mi), module->name); } static int module_compare(const void* p1, const void* p2) { struct info_module *left = (struct info_module *)p1; struct info_module *right = (struct info_module *)p2; LONGLONG val = left->mi.BaseOfImage - right->mi.BaseOfImage; if (val < 0) return -1; else if (val > 0) return 1; else return 0; } static inline BOOL module_is_container(const struct info_module *wmod_cntnr, const struct info_module *wmod_child) { return wmod_cntnr->mi.BaseOfImage <= wmod_child->mi.BaseOfImage && wmod_cntnr->mi.BaseOfImage + wmod_cntnr->mi.ImageSize >= wmod_child->mi.BaseOfImage + wmod_child->mi.ImageSize; } static BOOL CALLBACK info_mod_cb(PCSTR mod_name, DWORD64 base, PVOID ctx) { struct info_modules *im = ctx; if (im->num_used + 1 > im->num_alloc) { im->num_alloc += 16; im->modules = dbg_heap_realloc(im->modules, im->num_alloc * sizeof(*im->modules)); } im->modules[im->num_used].mi.SizeOfStruct = sizeof(im->modules[im->num_used].mi); if (SymGetModuleInfo64(dbg_curr_process->handle, base, &im->modules[im->num_used].mi)) { const int dst_len = sizeof(im->modules[im->num_used].name); lstrcpynA(im->modules[im->num_used].name, mod_name, dst_len - 1); im->modules[im->num_used].name[dst_len - 1] = 0; 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_modules im; UINT i, j, num_printed = 0; BOOL opt; if (!dbg_curr_process) { dbg_printf("Cannot get info on module while no process is loaded\n"); return; } im.modules = NULL; im.num_alloc = im.num_used = 0; /* this is a wine specific options to return also ELF modules in the * enumeration */ opt = SymSetExtendedOption(SYMOPT_EX_WINE_NATIVE_MODULES, TRUE); SymEnumerateModules64(dbg_curr_process->handle, info_mod_cb, &im); SymSetExtendedOption(SYMOPT_EX_WINE_NATIVE_MODULES, opt); qsort(im.modules, im.num_used, sizeof(im.modules[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.modules[i].mi.BaseOfImage || base >= im.modules[i].mi.BaseOfImage + im.modules[i].mi.ImageSize)) continue; if (strstr(im.modules[i].name, "")) { dbg_printf("ELF\t"); module_print_info(&im.modules[i], FALSE); /* print all modules embedded in this one */ for (j = 0; j < im.num_used; j++) { if (!strstr(im.modules[j].name, "") && module_is_container(&im.modules[i], &im.modules[j])) { dbg_printf(" \\-PE\t"); module_print_info(&im.modules[j], TRUE); } } } else { /* check module is not embedded in another module */ for (j = 0; j < im.num_used; j++) { if (strstr(im.modules[j].name, "") && module_is_container(&im.modules[j], &im.modules[i])) break; } if (j < im.num_used) continue; if (strstr(im.modules[i].name, ".so") || strchr(im.modules[i].name, '<')) dbg_printf("ELF\t"); else dbg_printf("PE\t"); module_print_info(&im.modules[i], FALSE); } num_printed++; } HeapFree(GetProcessHeap(), 0, im.modules); 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_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 if(rec->NumberParameters == 4 && rec->ExceptionInformation[0] == CXX_FRAME_MAGIC) dbg_printf("C++ exception(object = %p, type = %p, base = %p)", (void*)rec->ExceptionInformation[1], (void*)rec->ExceptionInformation[2], (void*)rec->ExceptionInformation[3]); 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)", dbg_curr_process->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:%08x)", addr.Segment, (unsigned) addr.Offset); break; default: dbg_printf(" bad address"); } dbg_printf(".\n"); }