Sweden-Number/dlls/dbghelp/minidump.c

845 lines
30 KiB
C

/*
* File minidump.c - management of dumps (read & write)
*
* Copyright (C) 2004-2005, Eric Pouech
*
* 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 <time.h>
#define NONAMELESSUNION
#define NONAMELESSSTRUCT
#include "ntstatus.h"
#define WIN32_NO_STATUS
#include "dbghelp_private.h"
#include "winternl.h"
#include "psapi.h"
#include "wine/debug.h"
WINE_DEFAULT_DEBUG_CHANNEL(dbghelp);
struct dump_memory
{
ULONG base;
ULONG size;
ULONG rva;
};
struct dump_module
{
unsigned is_elf;
ULONG base;
ULONG size;
DWORD timestamp;
DWORD checksum;
WCHAR name[MAX_PATH];
};
struct dump_context
{
/* process & thread information */
HANDLE hProcess;
DWORD pid;
void* pcs_buffer;
SYSTEM_PROCESS_INFORMATION* spi;
/* module information */
struct dump_module* module;
unsigned num_module;
/* exception information */
/* output information */
MINIDUMP_TYPE type;
HANDLE hFile;
RVA rva;
struct dump_memory* mem;
unsigned num_mem;
/* callback information */
MINIDUMP_CALLBACK_INFORMATION* cb;
};
/******************************************************************
* fetch_process_info
*
* reads system wide process information, and make spi point to the record
* for process of id 'pid'
*/
static BOOL fetch_process_info(struct dump_context* dc)
{
ULONG buf_size = 0x1000;
NTSTATUS nts;
dc->pcs_buffer = NULL;
if (!(dc->pcs_buffer = HeapAlloc(GetProcessHeap(), 0, buf_size))) return FALSE;
for (;;)
{
nts = NtQuerySystemInformation(SystemProcessInformation,
dc->pcs_buffer, buf_size, NULL);
if (nts != STATUS_INFO_LENGTH_MISMATCH) break;
dc->pcs_buffer = HeapReAlloc(GetProcessHeap(), 0, dc->pcs_buffer,
buf_size *= 2);
if (!dc->pcs_buffer) return FALSE;
}
if (nts == STATUS_SUCCESS)
{
dc->spi = dc->pcs_buffer;
for (;;)
{
if (dc->spi->dwProcessID == dc->pid) return TRUE;
if (!dc->spi->dwOffset) break;
dc->spi = (SYSTEM_PROCESS_INFORMATION*)
((char*)dc->spi + dc->spi->dwOffset);
}
}
HeapFree(GetProcessHeap(), 0, dc->pcs_buffer);
dc->pcs_buffer = NULL;
dc->spi = NULL;
return FALSE;
}
static void fetch_thread_stack(struct dump_context* dc, const void* teb_addr,
const CONTEXT* ctx, MINIDUMP_MEMORY_DESCRIPTOR* mmd)
{
NT_TIB tib;
if (ReadProcessMemory(dc->hProcess, teb_addr, &tib, sizeof(tib), NULL))
{
#ifdef __i386__
/* limiting the stack dumping to the size actually used */
if (ctx->Esp)
mmd->StartOfMemoryRange = (ctx->Esp - 4);
else
mmd->StartOfMemoryRange = (ULONG_PTR)tib.StackLimit;
#elif defined(__powerpc__)
if (ctx->Iar)
mmd->StartOfMemoryRange = ctx->Iar - 4;
else
mmd->StartOfMemoryRange = (ULONG_PTR)tib.StackLimit;
#elif defined(__x86_64__)
if (ctx->Rsp)
mmd->StartOfMemoryRange = (ctx->Rsp - 8);
else
mmd->StartOfMemoryRange = (ULONG_PTR)tib.StackLimit;
#else
#error unsupported CPU
#endif
mmd->Memory.DataSize = (ULONG_PTR)tib.StackBase - mmd->StartOfMemoryRange;
}
}
/******************************************************************
* fetch_thread_info
*
* fetches some information about thread of id 'tid'
*/
static BOOL fetch_thread_info(struct dump_context* dc, int thd_idx,
const MINIDUMP_EXCEPTION_INFORMATION* except,
MINIDUMP_THREAD* mdThd, CONTEXT* ctx)
{
DWORD tid = dc->spi->ti[thd_idx].dwThreadID;
HANDLE hThread;
THREAD_BASIC_INFORMATION tbi;
memset(ctx, 0, sizeof(*ctx));
mdThd->ThreadId = dc->spi->ti[thd_idx].dwThreadID;
mdThd->SuspendCount = 0;
mdThd->Teb = 0;
mdThd->Stack.StartOfMemoryRange = 0;
mdThd->Stack.Memory.DataSize = 0;
mdThd->Stack.Memory.Rva = 0;
mdThd->ThreadContext.DataSize = 0;
mdThd->ThreadContext.Rva = 0;
mdThd->PriorityClass = dc->spi->ti[thd_idx].dwBasePriority; /* FIXME */
mdThd->Priority = dc->spi->ti[thd_idx].dwCurrentPriority;
if ((hThread = OpenThread(THREAD_ALL_ACCESS, FALSE, tid)) == NULL)
{
FIXME("Couldn't open thread %u (%u)\n",
dc->spi->ti[thd_idx].dwThreadID, GetLastError());
return FALSE;
}
if (NtQueryInformationThread(hThread, ThreadBasicInformation,
&tbi, sizeof(tbi), NULL) == STATUS_SUCCESS)
{
mdThd->Teb = (ULONG_PTR)tbi.TebBaseAddress;
if (tbi.ExitStatus == STILL_ACTIVE)
{
if (tid != GetCurrentThreadId() &&
(mdThd->SuspendCount = SuspendThread(hThread)) != (DWORD)-1)
{
mdThd->SuspendCount--;
ctx->ContextFlags = CONTEXT_FULL;
if (!GetThreadContext(hThread, ctx))
memset(ctx, 0, sizeof(*ctx));
fetch_thread_stack(dc, tbi.TebBaseAddress, ctx, &mdThd->Stack);
ResumeThread(hThread);
}
else if (tid == GetCurrentThreadId() && except)
{
CONTEXT lctx, *pctx;
if (except->ClientPointers)
{
EXCEPTION_POINTERS ep;
ReadProcessMemory(dc->hProcess, except->ExceptionPointers,
&ep, sizeof(ep), NULL);
ReadProcessMemory(dc->hProcess, ep.ContextRecord,
&ctx, sizeof(ctx), NULL);
pctx = &lctx;
}
else pctx = except->ExceptionPointers->ContextRecord;
fetch_thread_stack(dc, tbi.TebBaseAddress, pctx, &mdThd->Stack);
}
}
}
CloseHandle(hThread);
return TRUE;
}
/******************************************************************
* add_module
*
* Add a module to a dump context
*/
static BOOL add_module(struct dump_context* dc, const WCHAR* name,
DWORD base, DWORD size, DWORD timestamp, DWORD checksum,
BOOL is_elf)
{
if (!dc->module)
dc->module = HeapAlloc(GetProcessHeap(), 0,
++dc->num_module * sizeof(*dc->module));
else
dc->module = HeapReAlloc(GetProcessHeap(), 0, dc->module,
++dc->num_module * sizeof(*dc->module));
if (!dc->module) return FALSE;
if (is_elf ||
!GetModuleFileNameExW(dc->hProcess, (HMODULE)base,
dc->module[dc->num_module - 1].name,
sizeof(dc->module[dc->num_module - 1].name) / sizeof(WCHAR)))
lstrcpynW(dc->module[dc->num_module - 1].name, name,
sizeof(dc->module[dc->num_module - 1].name) / sizeof(WCHAR));
dc->module[dc->num_module - 1].base = base;
dc->module[dc->num_module - 1].size = size;
dc->module[dc->num_module - 1].timestamp = timestamp;
dc->module[dc->num_module - 1].checksum = checksum;
dc->module[dc->num_module - 1].is_elf = is_elf;
return TRUE;
}
/******************************************************************
* fetch_pe_module_info_cb
*
* Callback for accumulating in dump_context a PE modules set
*/
static BOOL WINAPI fetch_pe_module_info_cb(PCWSTR name, DWORD64 base, ULONG size,
PVOID user)
{
struct dump_context* dc = (struct dump_context*)user;
IMAGE_NT_HEADERS nth;
if (!validate_addr64(base)) return FALSE;
if (pe_load_nt_header(dc->hProcess, base, &nth))
add_module((struct dump_context*)user, name, base, size,
nth.FileHeader.TimeDateStamp, nth.OptionalHeader.CheckSum,
FALSE);
return TRUE;
}
/******************************************************************
* fetch_elf_module_info_cb
*
* Callback for accumulating in dump_context an ELF modules set
*/
static BOOL fetch_elf_module_info_cb(const WCHAR* name, unsigned long base,
void* user)
{
struct dump_context* dc = (struct dump_context*)user;
DWORD rbase, size, checksum;
/* FIXME: there's no relevant timestamp on ELF modules */
/* NB: if we have a non-null base from the live-target use it (whenever
* the ELF module is relocatable or not). If we have a null base (ELF
* module isn't relocatable) then grab its base address from ELF file
*/
if (!elf_fetch_file_info(name, &rbase, &size, &checksum))
size = checksum = 0;
add_module(dc, name, base ? base : rbase, size, 0 /* FIXME */, checksum, TRUE);
return TRUE;
}
static void fetch_module_info(struct dump_context* dc)
{
EnumerateLoadedModulesW64(dc->hProcess, fetch_pe_module_info_cb, dc);
/* Since we include ELF modules in a separate stream from the regular PE ones,
* we can always include those ELF modules (they don't eat lots of space)
* And it's always a good idea to have a trace of the loaded ELF modules for
* a given application in a post mortem debugging condition.
*/
elf_enum_modules(dc->hProcess, fetch_elf_module_info_cb, dc);
}
/******************************************************************
* add_memory_block
*
* Add a memory block to be dumped in a minidump
* If rva is non 0, it's the rva in the minidump where has to be stored
* also the rva of the memory block when written (this allows to reference
* a memory block from outside the list of memory blocks).
*/
static void add_memory_block(struct dump_context* dc, ULONG64 base, ULONG size, ULONG rva)
{
if (dc->mem)
dc->mem = HeapReAlloc(GetProcessHeap(), 0, dc->mem,
++dc->num_mem * sizeof(*dc->mem));
else
dc->mem = HeapAlloc(GetProcessHeap(), 0, ++dc->num_mem * sizeof(*dc->mem));
if (dc->mem)
{
dc->mem[dc->num_mem - 1].base = base;
dc->mem[dc->num_mem - 1].size = size;
dc->mem[dc->num_mem - 1].rva = rva;
}
else dc->num_mem = 0;
}
/******************************************************************
* writeat
*
* Writes a chunk of data at a given position in the minidump
*/
static void writeat(struct dump_context* dc, RVA rva, const void* data, unsigned size)
{
DWORD written;
SetFilePointer(dc->hFile, rva, NULL, FILE_BEGIN);
WriteFile(dc->hFile, data, size, &written, NULL);
}
/******************************************************************
* append
*
* writes a new chunk of data to the minidump, increasing the current
* rva in dc
*/
static void append(struct dump_context* dc, void* data, unsigned size)
{
writeat(dc, dc->rva, data, size);
dc->rva += size;
}
/******************************************************************
* dump_exception_info
*
* Write in File the exception information from pcs
*/
static void dump_exception_info(struct dump_context* dc,
const MINIDUMP_EXCEPTION_INFORMATION* except,
DWORD *size)
{
MINIDUMP_EXCEPTION_STREAM mdExcpt;
EXCEPTION_RECORD rec, *prec;
CONTEXT ctx, *pctx;
int i;
mdExcpt.ThreadId = except->ThreadId;
mdExcpt.__alignment = 0;
if (except->ClientPointers)
{
EXCEPTION_POINTERS ep;
ReadProcessMemory(dc->hProcess,
except->ExceptionPointers, &ep, sizeof(ep), NULL);
ReadProcessMemory(dc->hProcess,
ep.ExceptionRecord, &rec, sizeof(rec), NULL);
ReadProcessMemory(dc->hProcess,
ep.ContextRecord, &ctx, sizeof(ctx), NULL);
prec = &rec;
pctx = &ctx;
}
else
{
prec = except->ExceptionPointers->ExceptionRecord;
pctx = except->ExceptionPointers->ContextRecord;
}
mdExcpt.ExceptionRecord.ExceptionCode = prec->ExceptionCode;
mdExcpt.ExceptionRecord.ExceptionFlags = prec->ExceptionFlags;
mdExcpt.ExceptionRecord.ExceptionRecord = (DWORD_PTR)prec->ExceptionRecord;
mdExcpt.ExceptionRecord.ExceptionAddress = (DWORD_PTR)prec->ExceptionAddress;
mdExcpt.ExceptionRecord.NumberParameters = prec->NumberParameters;
mdExcpt.ExceptionRecord.__unusedAlignment = 0;
for (i = 0; i < mdExcpt.ExceptionRecord.NumberParameters; i++)
mdExcpt.ExceptionRecord.ExceptionInformation[i] = prec->ExceptionInformation[i];
mdExcpt.ThreadContext.DataSize = sizeof(*pctx);
mdExcpt.ThreadContext.Rva = dc->rva + sizeof(mdExcpt);
append(dc, &mdExcpt, sizeof(mdExcpt));
*size = sizeof(mdExcpt);
append(dc, pctx, sizeof(*pctx));
}
/******************************************************************
* dump_modules
*
* Write in File the modules from pcs
*/
static void dump_modules(struct dump_context* dc, BOOL dump_elf, DWORD *size)
{
MINIDUMP_MODULE mdModule;
MINIDUMP_MODULE_LIST mdModuleList;
char tmp[1024];
MINIDUMP_STRING* ms = (MINIDUMP_STRING*)tmp;
ULONG i, nmod;
RVA rva_base;
DWORD flags_out;
for (i = nmod = 0; i < dc->num_module; i++)
{
if ((dc->module[i].is_elf && dump_elf) ||
(!dc->module[i].is_elf && !dump_elf))
nmod++;
}
mdModuleList.NumberOfModules = 0;
/* reserve space for mdModuleList
* FIXME: since we don't support 0 length arrays, we cannot use the
* size of mdModuleList
* FIXME: if we don't ask for all modules in cb, we'll get a hole in the file
*/
rva_base = dc->rva;
dc->rva += *size = sizeof(mdModuleList.NumberOfModules) + sizeof(mdModule) * nmod;
for (i = 0; i < dc->num_module; i++)
{
if ((dc->module[i].is_elf && !dump_elf) ||
(!dc->module[i].is_elf && dump_elf))
continue;
flags_out = ModuleWriteModule | ModuleWriteMiscRecord | ModuleWriteCvRecord;
if (dc->type & MiniDumpWithDataSegs)
flags_out |= ModuleWriteDataSeg;
if (dc->type & MiniDumpWithProcessThreadData)
flags_out |= ModuleWriteTlsData;
if (dc->type & MiniDumpWithCodeSegs)
flags_out |= ModuleWriteCodeSegs;
ms->Length = (lstrlenW(dc->module[i].name) + 1) * sizeof(WCHAR);
if (sizeof(ULONG) + ms->Length > sizeof(tmp))
FIXME("Buffer overflow!!!\n");
lstrcpyW(ms->Buffer, dc->module[i].name);
if (dc->cb)
{
MINIDUMP_CALLBACK_INPUT cbin;
MINIDUMP_CALLBACK_OUTPUT cbout;
cbin.ProcessId = dc->pid;
cbin.ProcessHandle = dc->hProcess;
cbin.CallbackType = ModuleCallback;
cbin.u.Module.FullPath = ms->Buffer;
cbin.u.Module.BaseOfImage = dc->module[i].base;
cbin.u.Module.SizeOfImage = dc->module[i].size;
cbin.u.Module.CheckSum = dc->module[i].checksum;
cbin.u.Module.TimeDateStamp = dc->module[i].timestamp;
memset(&cbin.u.Module.VersionInfo, 0, sizeof(cbin.u.Module.VersionInfo));
cbin.u.Module.CvRecord = NULL;
cbin.u.Module.SizeOfCvRecord = 0;
cbin.u.Module.MiscRecord = NULL;
cbin.u.Module.SizeOfMiscRecord = 0;
cbout.u.ModuleWriteFlags = flags_out;
if (!dc->cb->CallbackRoutine(dc->cb->CallbackParam, &cbin, &cbout))
continue;
flags_out &= cbout.u.ModuleWriteFlags;
}
if (flags_out & ModuleWriteModule)
{
mdModule.BaseOfImage = dc->module[i].base;
mdModule.SizeOfImage = dc->module[i].size;
mdModule.CheckSum = dc->module[i].checksum;
mdModule.TimeDateStamp = dc->module[i].timestamp;
mdModule.ModuleNameRva = dc->rva;
ms->Length -= sizeof(WCHAR);
append(dc, ms, sizeof(ULONG) + ms->Length + sizeof(WCHAR));
memset(&mdModule.VersionInfo, 0, sizeof(mdModule.VersionInfo)); /* FIXME */
mdModule.CvRecord.DataSize = 0; /* FIXME */
mdModule.CvRecord.Rva = 0; /* FIXME */
mdModule.MiscRecord.DataSize = 0; /* FIXME */
mdModule.MiscRecord.Rva = 0; /* FIXME */
mdModule.Reserved0 = 0; /* FIXME */
mdModule.Reserved1 = 0; /* FIXME */
writeat(dc,
rva_base + sizeof(mdModuleList.NumberOfModules) +
mdModuleList.NumberOfModules++ * sizeof(mdModule),
&mdModule, sizeof(mdModule));
}
}
writeat(dc, rva_base, &mdModuleList.NumberOfModules,
sizeof(mdModuleList.NumberOfModules));
}
/******************************************************************
* dump_system_info
*
* Dumps into File the information about the system
*/
static void dump_system_info(struct dump_context* dc, DWORD *size)
{
MINIDUMP_SYSTEM_INFO mdSysInfo;
SYSTEM_INFO sysInfo;
OSVERSIONINFOW osInfo;
DWORD written;
ULONG slen;
GetSystemInfo(&sysInfo);
osInfo.dwOSVersionInfoSize = sizeof(osInfo);
GetVersionExW(&osInfo);
mdSysInfo.ProcessorArchitecture = sysInfo.u.s.wProcessorArchitecture;
mdSysInfo.ProcessorLevel = sysInfo.wProcessorLevel;
mdSysInfo.ProcessorRevision = sysInfo.wProcessorRevision;
mdSysInfo.u.s.NumberOfProcessors = sysInfo.dwNumberOfProcessors;
mdSysInfo.u.s.ProductType = VER_NT_WORKSTATION; /* FIXME */
mdSysInfo.MajorVersion = osInfo.dwMajorVersion;
mdSysInfo.MinorVersion = osInfo.dwMinorVersion;
mdSysInfo.BuildNumber = osInfo.dwBuildNumber;
mdSysInfo.PlatformId = osInfo.dwPlatformId;
mdSysInfo.CSDVersionRva = dc->rva + sizeof(mdSysInfo);
mdSysInfo.u1.Reserved1 = 0;
memset(&mdSysInfo.Cpu, 0, sizeof(mdSysInfo.Cpu));
append(dc, &mdSysInfo, sizeof(mdSysInfo));
*size = sizeof(mdSysInfo);
slen = lstrlenW(osInfo.szCSDVersion) * sizeof(WCHAR);
WriteFile(dc->hFile, &slen, sizeof(slen), &written, NULL);
WriteFile(dc->hFile, osInfo.szCSDVersion, slen, &written, NULL);
dc->rva += sizeof(ULONG) + slen;
}
/******************************************************************
* dump_threads
*
* Dumps into File the information about running threads
*/
static void dump_threads(struct dump_context* dc,
const MINIDUMP_EXCEPTION_INFORMATION* except,
DWORD *size)
{
MINIDUMP_THREAD mdThd;
MINIDUMP_THREAD_LIST mdThdList;
unsigned i;
RVA rva_base;
DWORD flags_out;
CONTEXT ctx;
mdThdList.NumberOfThreads = 0;
rva_base = dc->rva;
dc->rva += sizeof(mdThdList.NumberOfThreads) +
dc->spi->dwThreadCount * sizeof(mdThd);
for (i = 0; i < dc->spi->dwThreadCount; i++)
{
fetch_thread_info(dc, i, except, &mdThd, &ctx);
flags_out = ThreadWriteThread | ThreadWriteStack | ThreadWriteContext |
ThreadWriteInstructionWindow;
if (dc->type & MiniDumpWithProcessThreadData)
flags_out |= ThreadWriteThreadData;
if (dc->type & MiniDumpWithThreadInfo)
flags_out |= ThreadWriteThreadInfo;
if (dc->cb)
{
MINIDUMP_CALLBACK_INPUT cbin;
MINIDUMP_CALLBACK_OUTPUT cbout;
cbin.ProcessId = dc->pid;
cbin.ProcessHandle = dc->hProcess;
cbin.CallbackType = ThreadCallback;
cbin.u.Thread.ThreadId = dc->spi->ti[i].dwThreadID;
cbin.u.Thread.ThreadHandle = 0; /* FIXME */
memcpy(&cbin.u.Thread.Context, &ctx, sizeof(CONTEXT));
cbin.u.Thread.SizeOfContext = sizeof(CONTEXT);
cbin.u.Thread.StackBase = mdThd.Stack.StartOfMemoryRange;
cbin.u.Thread.StackEnd = mdThd.Stack.StartOfMemoryRange +
mdThd.Stack.Memory.DataSize;
cbout.u.ThreadWriteFlags = flags_out;
if (!dc->cb->CallbackRoutine(dc->cb->CallbackParam, &cbin, &cbout))
continue;
flags_out &= cbout.u.ThreadWriteFlags;
}
if (flags_out & ThreadWriteThread)
{
if (ctx.ContextFlags && (flags_out & ThreadWriteContext))
{
mdThd.ThreadContext.Rva = dc->rva;
mdThd.ThreadContext.DataSize = sizeof(CONTEXT);
append(dc, &ctx, sizeof(CONTEXT));
}
if (mdThd.Stack.Memory.DataSize && (flags_out & ThreadWriteStack))
{
add_memory_block(dc, mdThd.Stack.StartOfMemoryRange,
mdThd.Stack.Memory.DataSize,
rva_base + sizeof(mdThdList.NumberOfThreads) +
mdThdList.NumberOfThreads * sizeof(mdThd) +
FIELD_OFFSET(MINIDUMP_THREAD, Stack.Memory.Rva));
}
writeat(dc,
rva_base + sizeof(mdThdList.NumberOfThreads) +
mdThdList.NumberOfThreads * sizeof(mdThd),
&mdThd, sizeof(mdThd));
mdThdList.NumberOfThreads++;
}
if (ctx.ContextFlags && (flags_out & ThreadWriteInstructionWindow))
{
/* FIXME: - Native dbghelp also dumps 0x80 bytes around EIP
* - also crop values across module boundaries,
* - and don't make it i386 dependent
*/
/* add_memory_block(dc, ctx.Eip - 0x80, ctx.Eip + 0x80, 0); */
}
}
writeat(dc, rva_base,
&mdThdList.NumberOfThreads, sizeof(mdThdList.NumberOfThreads));
*size = dc->rva - rva_base;
}
/******************************************************************
* dump_memory_info
*
* dumps information about the memory of the process (stack of the threads)
*/
static void dump_memory_info(struct dump_context* dc, DWORD* size)
{
MINIDUMP_MEMORY_LIST mdMemList;
MINIDUMP_MEMORY_DESCRIPTOR mdMem;
DWORD written;
unsigned i, pos, len;
RVA rva_base;
char tmp[1024];
mdMemList.NumberOfMemoryRanges = dc->num_mem;
append(dc, &mdMemList.NumberOfMemoryRanges,
sizeof(mdMemList.NumberOfMemoryRanges));
rva_base = dc->rva;
dc->rva += mdMemList.NumberOfMemoryRanges * sizeof(mdMem);
*size = sizeof(mdMemList.NumberOfMemoryRanges) +
mdMemList.NumberOfMemoryRanges * sizeof(mdMem);
for (i = 0; i < dc->num_mem; i++)
{
mdMem.StartOfMemoryRange = dc->mem[i].base;
mdMem.Memory.Rva = dc->rva;
mdMem.Memory.DataSize = dc->mem[i].size;
SetFilePointer(dc->hFile, dc->rva, NULL, FILE_BEGIN);
for (pos = 0; pos < dc->mem[i].size; pos += sizeof(tmp))
{
len = min(dc->mem[i].size - pos, sizeof(tmp));
if (ReadProcessMemory(dc->hProcess,
(void*)(dc->mem[i].base + pos),
tmp, len, NULL))
WriteFile(dc->hFile, tmp, len, &written, NULL);
}
dc->rva += mdMem.Memory.DataSize;
writeat(dc, rva_base + i * sizeof(mdMem), &mdMem, sizeof(mdMem));
if (dc->mem[i].rva)
{
writeat(dc, dc->mem[i].rva, &mdMem.Memory.Rva, sizeof(mdMem.Memory.Rva));
}
}
}
static void dump_misc_info(struct dump_context* dc, DWORD* size)
{
MINIDUMP_MISC_INFO mmi;
mmi.SizeOfInfo = sizeof(mmi);
mmi.Flags1 = MINIDUMP_MISC1_PROCESS_ID;
mmi.ProcessId = dc->pid;
/* FIXME: create/user/kernel time */
append(dc, &mmi, sizeof(mmi));
*size = sizeof(mmi);
}
/******************************************************************
* MiniDumpWriteDump (DEBUGHLP.@)
*
*/
BOOL WINAPI MiniDumpWriteDump(HANDLE hProcess, DWORD pid, HANDLE hFile,
MINIDUMP_TYPE DumpType,
PMINIDUMP_EXCEPTION_INFORMATION ExceptionParam,
PMINIDUMP_USER_STREAM_INFORMATION UserStreamParam,
PMINIDUMP_CALLBACK_INFORMATION CallbackParam)
{
MINIDUMP_HEADER mdHead;
MINIDUMP_DIRECTORY mdDir;
DWORD i, nStreams, idx_stream;
struct dump_context dc;
dc.hProcess = hProcess;
dc.hFile = hFile;
dc.pid = pid;
dc.module = NULL;
dc.num_module = 0;
dc.cb = CallbackParam;
dc.type = DumpType;
dc.mem = NULL;
dc.num_mem = 0;
dc.rva = 0;
if (!fetch_process_info(&dc)) return FALSE;
fetch_module_info(&dc);
/* 1) init */
nStreams = 6 + (ExceptionParam ? 1 : 0) +
(UserStreamParam ? UserStreamParam->UserStreamCount : 0);
if (DumpType & MiniDumpWithDataSegs)
FIXME("NIY MiniDumpWithDataSegs\n");
if (DumpType & MiniDumpWithFullMemory)
FIXME("NIY MiniDumpWithFullMemory\n");
if (DumpType & MiniDumpWithHandleData)
FIXME("NIY MiniDumpWithHandleData\n");
if (DumpType & MiniDumpFilterMemory)
FIXME("NIY MiniDumpFilterMemory\n");
if (DumpType & MiniDumpScanMemory)
FIXME("NIY MiniDumpScanMemory\n");
/* 2) write header */
mdHead.Signature = MINIDUMP_SIGNATURE;
mdHead.Version = MINIDUMP_VERSION;
mdHead.NumberOfStreams = nStreams;
mdHead.StreamDirectoryRva = sizeof(mdHead);
mdHead.u.TimeDateStamp = time(NULL);
mdHead.Flags = DumpType;
mdHead.CheckSum = 0;
append(&dc, &mdHead, sizeof(mdHead));
/* 3) write stream directories */
dc.rva += nStreams * sizeof(mdDir);
idx_stream = 0;
/* 3.1) write data stream directories */
/* must be first in minidump */
mdDir.StreamType = SystemInfoStream;
mdDir.Location.Rva = dc.rva;
dump_system_info(&dc, &mdDir.Location.DataSize);
writeat(&dc, mdHead.StreamDirectoryRva + idx_stream++ * sizeof(mdDir),
&mdDir, sizeof(mdDir));
mdDir.StreamType = ThreadListStream;
mdDir.Location.Rva = dc.rva;
dump_threads(&dc, ExceptionParam, &mdDir.Location.DataSize);
writeat(&dc, mdHead.StreamDirectoryRva + idx_stream++ * sizeof(mdDir),
&mdDir, sizeof(mdDir));
mdDir.StreamType = ModuleListStream;
mdDir.Location.Rva = dc.rva;
dump_modules(&dc, FALSE, &mdDir.Location.DataSize);
writeat(&dc, mdHead.StreamDirectoryRva + idx_stream++ * sizeof(mdDir),
&mdDir, sizeof(mdDir));
mdDir.StreamType = 0xfff0; /* FIXME: this is part of MS reserved streams */
mdDir.Location.Rva = dc.rva;
dump_modules(&dc, TRUE, &mdDir.Location.DataSize);
writeat(&dc, mdHead.StreamDirectoryRva + idx_stream++ * sizeof(mdDir),
&mdDir, sizeof(mdDir));
mdDir.StreamType = MemoryListStream;
mdDir.Location.Rva = dc.rva;
dump_memory_info(&dc, &mdDir.Location.DataSize);
writeat(&dc, mdHead.StreamDirectoryRva + idx_stream++ * sizeof(mdDir),
&mdDir, sizeof(mdDir));
mdDir.StreamType = MiscInfoStream;
mdDir.Location.Rva = dc.rva;
dump_misc_info(&dc, &mdDir.Location.DataSize);
writeat(&dc, mdHead.StreamDirectoryRva + idx_stream++ * sizeof(mdDir),
&mdDir, sizeof(mdDir));
/* 3.2) write exception information (if any) */
if (ExceptionParam)
{
mdDir.StreamType = ExceptionStream;
mdDir.Location.Rva = dc.rva;
dump_exception_info(&dc, ExceptionParam, &mdDir.Location.DataSize);
writeat(&dc, mdHead.StreamDirectoryRva + idx_stream++ * sizeof(mdDir),
&mdDir, sizeof(mdDir));
}
/* 3.3) write user defined streams (if any) */
if (UserStreamParam)
{
for (i = 0; i < UserStreamParam->UserStreamCount; i++)
{
mdDir.StreamType = UserStreamParam->UserStreamArray[i].Type;
mdDir.Location.DataSize = UserStreamParam->UserStreamArray[i].BufferSize;
mdDir.Location.Rva = dc.rva;
writeat(&dc, mdHead.StreamDirectoryRva + idx_stream++ * sizeof(mdDir),
&mdDir, sizeof(mdDir));
append(&dc, UserStreamParam->UserStreamArray[i].Buffer,
UserStreamParam->UserStreamArray[i].BufferSize);
}
}
HeapFree(GetProcessHeap(), 0, dc.pcs_buffer);
HeapFree(GetProcessHeap(), 0, dc.mem);
HeapFree(GetProcessHeap(), 0, dc.module);
return TRUE;
}
/******************************************************************
* MiniDumpReadDumpStream (DEBUGHLP.@)
*
*
*/
BOOL WINAPI MiniDumpReadDumpStream(PVOID base, ULONG str_idx,
PMINIDUMP_DIRECTORY* pdir,
PVOID* stream, ULONG* size)
{
MINIDUMP_HEADER* mdHead = (MINIDUMP_HEADER*)base;
if (mdHead->Signature == MINIDUMP_SIGNATURE)
{
MINIDUMP_DIRECTORY* dir;
int i;
dir = (MINIDUMP_DIRECTORY*)((char*)base + mdHead->StreamDirectoryRva);
for (i = 0; i < mdHead->NumberOfStreams; i++, dir++)
{
if (dir->StreamType == str_idx)
{
*pdir = dir;
*stream = (char*)base + dir->Location.Rva;
*size = dir->Location.DataSize;
return TRUE;
}
}
}
SetLastError(ERROR_INVALID_PARAMETER);
return FALSE;
}