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diff --git a/trunk/libxmount_input/libxmount_input_aewf/libxmount_input_aewf.c b/trunk/libxmount_input/libxmount_input_aewf/libxmount_input_aewf.c
index 5c105d3..f0a5189 100644
--- a/trunk/libxmount_input/libxmount_input_aewf/libxmount_input_aewf.c
+++ b/trunk/libxmount_input/libxmount_input_aewf/libxmount_input_aewf.c
@@ -1,1938 +1,1938 @@
/*******************************************************************************
* xmount Copyright (c) 2008-2015 by Gillen Daniel <gillen.dan@pinguin.lu> *
* *
* This module has been written by Guy Voncken. It contains the functions for *
* accessing EWF images created by Guymager and others. *
* *
* This program is free software: you can redistribute it and/or modify it *
* under the terms of the GNU General Public License as published by the Free *
* Software Foundation, either version 3 of the License, or (at your option) *
* any later version. *
* *
* This program 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 General Public License for *
* more details. *
* *
* You should have received a copy of the GNU General Public License along with *
* this program. If not, see <http://www.gnu.org/licenses/>. *
*******************************************************************************/
// Aewf has been written in order to reduce xmount's memory footprint when
// operating on large EWF images. Before Aewf, xmount exclusively relied on
// libewf for accessing EWF images, resulting in enormous memory consumption.
//
// Aewf uses 2 main structures for handling image access: pAewf->pSegmentArr
// contains everything about the image files (segments) and pAewf->pTableArr
// handles the EWF chunk offset tables.
//
// At the same time, those structures serve as caches for the two most vital
// ressouces, namely the number of segment files opened in parallel and the
// memory consumed by the chunk offset tables.
//
// The max. values for both are configurable, see pAewf->MaxOpenSegments and
// pAewf->MaxTableCache.
// Please don't touch source code formatting!
#ifdef LINTING
// #define _LARGEFILE_SOURCE
// #define _FILE_OFFSET_BITS 64
#define AEWF_STANDALONE
#endif
#include <string.h>
#include <stdio.h>
#include <stdlib.h>
#include <locale.h>
#include <limits.h>
#include <time.h> //lint !e537 !e451 Include file messages
#include <zlib.h>
#include <unistd.h> //lint !e537
#include <wchar.h> //lint !e537 !e451
#include <stdarg.h> //lint !e537 !e451
#include <limits.h> //lint !e537 !e451
#include <errno.h>
#include <pthread.h>
#include "../libxmount_input.h"
#include "libxmount_input_aewf.h"
#ifdef AEWF_STANDALONE
#define CREATE_REVERSE_FILE
// #define REVERSE_FILE_USES_SEPARATE_HANDLE
#define LOG_STDOUT TRUE
#endif
//#ifdef AEWF_STANDALONE
// #define _GNU_SOURCE
//#endif
#define AEWF_OPTION_TABLECACHE "aewfmaxmem"
#define AEWF_OPTION_MAXOPENSEGMENTS "aewfmaxfiles"
#define AEWF_OPTION_STATS "aewfstats"
#define AEWF_OPTION_STATSREFRESH "aewfrefresh"
#define AEWF_OPTION_LOG "aewflog"
#define AEWF_OPTION_THREADS "aewfthreads"
static int AewfClose (void *pHandle);
static const char* AewfGetErrorMessage (int ErrNum);
const uint64_t AEWF_DEFAULT_TABLECACHE = 10; // MiB
const uint64_t AEWF_DEFAULT_MAXOPENSEGMENTS = 10;
const uint64_t AEWF_DEFAULT_STATSREFRESH = 10;
const uint64_t AEWF_DEFAULT_THREADS = 4; // There normally is no sense in using higher values, as - according to out statistics - we never get called for reading
// more than 128k of data (there's only 1 exception: the very 1st read request from xmount itself). With the default EWF
// chunk size of 32K, 4 threads are enough for running the whole decompression in parallel.
// ----------------------------
// Logging and error handling
// ----------------------------
#define LOG_HEADER_LEN 80
int LogvEntry (const char *pLogPath, uint8_t LogStdout, const char *pFileName, const char *pFunctionName, int LineNr, const char *pFormat, va_list pArguments)
{
time_t NowT;
struct tm *pNowTM;
FILE *pFile;
int wr;
char *pFullLogFileName = NULL;
const char *pBase;
char LogLineHeader[1024];
pid_t OwnPID;
va_list pArguments0;
if (!LogStdout && (pLogPath==NULL))
return AEWF_OK;
time (&NowT);
pNowTM = localtime (&NowT);
OwnPID = getpid(); // pthread_self()
wr = (int) strftime (&LogLineHeader[0] , sizeof(LogLineHeader) , "%a %d.%b.%Y %H:%M:%S ", pNowTM); //lint !e713
wr += snprintf (&LogLineHeader[wr], sizeof(LogLineHeader)-wr, "%5d ", OwnPID); //lint !e737
if (pFileName && pFunctionName)
{
pBase = strrchr(pFileName, '/');
if (pBase)
pFileName = pBase+1;
wr += snprintf (&LogLineHeader[wr], sizeof(LogLineHeader)-wr, "%s %s %d ", pFileName, pFunctionName, LineNr); //lint !e737
}
// while (wr < LOG_HEADER_LEN)
// LogLineHeader[wr++] = ' ';
if (pLogPath)
{
wr = asprintf (&pFullLogFileName, "%s/log_%d", pLogPath, OwnPID);
if ((wr <= 0) || (pFullLogFileName == NULL))
{
if (LogStdout)
printf ("\nLog file error: Can't build filename");
return AEWF_MEMALLOC_FAILED;
}
else
{
pFile = fopen64 (pFullLogFileName, "a");
if (pFile == NULL)
{
if (LogStdout)
printf ("\nLog file error: Can't be opened");
return AEWF_CANNOT_OPEN_LOGFILE;
}
else
{
fprintf (pFile, "%-*s", LOG_HEADER_LEN, &LogLineHeader[0]);
va_copy (pArguments0, pArguments);
vfprintf (pFile, pFormat, pArguments0);
fprintf (pFile, "\n");
fclose (pFile);
}
free (pFullLogFileName);
}
}
if (LogStdout)
{
printf ("%s", &LogLineHeader[0]);
va_copy (pArguments0, pArguments);
vprintf (pFormat, pArguments0);
printf ("\n");
}
return AEWF_OK;
}
int LogEntry (const char *pLogPath, uint8_t LogStdout, const char *pFileName, const char *pFunctionName, int LineNr, const char *pFormat, ...)
{
va_list VaList;
int rc;
if (!LogStdout && (pLogPath==NULL))
return AEWF_OK;
va_start (VaList, pFormat); //lint !e530 Symbol 'VaList' not initialized
rc = LogvEntry (pLogPath, LogStdout, pFileName, pFunctionName, LineNr, pFormat, VaList);
va_end(VaList);
return rc;
}
// CHK requires existance of pAewf handle
#ifdef AEWF_STANDALONE
#define LOG_ERRORS_ON_STDOUT TRUE
#else
#define LOG_ERRORS_ON_STDOUT pAewf->LogStdout
#endif
#define CHK(ChkVal) \
{ \
int ChkValRc; \
if ((ChkValRc=(ChkVal)) != AEWF_OK) \
{ \
const char *pErr = AewfGetErrorMessage (ChkValRc); \
LogEntry (pAewf->pLogPath, LOG_ERRORS_ON_STDOUT, __FILE__, __FUNCTION__, __LINE__, "Error %d (%s) occured", ChkValRc, pErr); \
return ChkValRc; \
} \
}
#define LOG(...) \
LogEntry (pAewf->pLogPath, pAewf->LogStdout, __FILE__, __FUNCTION__, __LINE__, __VA_ARGS__);
// AewfCheckError is called before exiting AewfRead. It should not
// be called elsewehere or else the statistics would become wrong.
static void AewfCheckError (t_pAewf pAewf, int Ret, int *pErrno)
{
*pErrno = 0;
if (Ret != AEWF_OK)
{
pAewf->Errors++;
pAewf->LastError = Ret;
if ((Ret >= AEWF_ERROR_ENOMEM_START) && (Ret <= AEWF_ERROR_ENOMEM_END)) *pErrno = ENOMEM;
else if ((Ret >= AEWF_ERROR_EINVAL_START) && (Ret <= AEWF_ERROR_EINVAL_END)) *pErrno = EINVAL;
else *pErrno = EIO; // all other errors
}
}
// ------------------------------------
// Internal functions
// ------------------------------------
static int OpenFile (FILE **ppFile, const char *pFilename)
{
*ppFile = fopen (pFilename, "r");
if (*ppFile == NULL)
return AEWF_FILE_OPEN_FAILED;
return AEWF_OK;
}
static int CloseFile (FILE **ppFile)
{
if (fclose (*ppFile))
return AEWF_FILE_CLOSE_FAILED;
*ppFile = NULL;
return AEWF_OK;
}
#define NO_SEEK ULLONG_MAX
static int ReadFilePos (t_pAewf pAewf, FILE *pFile, void *pMem, unsigned int Size, uint64_t Pos)
{
if (Size == 0)
return AEWF_OK;
if (Pos != NO_SEEK)
{
if (fseeko64 (pFile, Pos, SEEK_SET))
return AEWF_FILE_SEEK_FAILED;
}
if (fread (pMem, Size, 1UL, pFile) != 1)
return AEWF_FILE_READ_FAILED;
return AEWF_OK;
}
static int ReadFileAllocPos (t_pAewf pAewf, FILE *pFile, void **ppMem, unsigned int Size, uint64_t Pos)
{
*ppMem = (void*) malloc (Size);
if (*ppMem == NULL)
return AEWF_MEMALLOC_FAILED;
CHK (ReadFilePos (pAewf, pFile, *ppMem, Size, Pos))
return AEWF_OK;
}
static int ReadFileAlloc (t_pAewf pAewf, FILE *pFile, void **ppMem, unsigned int Size)
{
CHK (ReadFileAllocPos (pAewf, pFile, ppMem, Size, NO_SEEK))
return AEWF_OK;
}
static int QsortCompareSegments (const void *pA, const void *pB)
{
const t_pSegment pSegmentA = ((const t_pSegment)pA); //lint !e1773 Attempt to cast way const
const t_pSegment pSegmentB = ((const t_pSegment)pB); //lint !e1773 Attempt to cast way const
return (int)pSegmentA->Number - (int)pSegmentB->Number;
}
static int CreateInfoData (t_pAewf pAewf, t_pAewfSectionVolume pVolume,
char *pHeader , unsigned HeaderLen,
char *pHeader2, unsigned Header2Len,
t_pAewfSectionHash pMD5)
{
char *pInfo1 = NULL;
char *pInfo2 = NULL;
char *pInfo3 = NULL;
char *pInfo4 = NULL;
char *pInfo5 = NULL;
char *pInfo6 = NULL;
char *pHdr = NULL;
unsigned HdrLen= 0;
char *pText = NULL;
char *pCurrent;
char *pDesc = NULL;
char *pData = NULL;
char *pEnd;
uLongf DstLen0;
int zrc;
const int MaxTextSize = 65536;
unsigned UncompressedLen;
int rc = AEWF_OK;
#define RET_ERR(ErrCode) \
{ \
rc = ErrCode; \
goto CleanUp; \
}
#define ASPRINTF(...) \
{ \
if (asprintf(__VA_ARGS__) < 0) \
RET_ERR (AEWF_ASPRINTF_FAILED) \
}
ASPRINTF(&pInfo1, "Image size %" PRIu64 " (%0.2f GiB)\n"
"Bytes per sector %u\n"
"Sector count %" PRIu64 "\n"
"Sectors per chunk %u\n"
"Chunk count %u\n"
"Error block size %u\n"
"Compression level %u\n"
"Media type %02X\n"
"Cylinders/Heads/Sectors %u/%u/%u\n"
"Media flags %02X\n"
"Palm volume start sector %u\n"
"Smart logs start sector %u\n",
pAewf->ImageSize, pAewf->ImageSize / (1024.0 * 1024.0* 1024.0),
pVolume->BytesPerSector,
pVolume->SectorCount,
pVolume->SectorsPerChunk,
pVolume->ChunkCount,
pVolume->ErrorBlockSize,
pVolume->CompressionLevel,
pVolume->MediaType,
pVolume->CHS_Cylinders, pVolume->CHS_Heads, pVolume->CHS_Sectors,
pVolume->MediaFlags,
pVolume->PalmVolumeStartSector,
pVolume->SmartLogsStartSector);
ASPRINTF (&pInfo2, "AcquirySystemGUID %02X %02X %02X %02X %02X %02X %02X %02X %02X %02X %02X %02X %02X %02X %02X %02X\n",
pVolume->AcquirySystemGUID[ 0], pVolume->AcquirySystemGUID[ 1], pVolume->AcquirySystemGUID[ 2], pVolume->AcquirySystemGUID[ 3],
pVolume->AcquirySystemGUID[ 4], pVolume->AcquirySystemGUID[ 4], pVolume->AcquirySystemGUID[ 6], pVolume->AcquirySystemGUID[ 7],
pVolume->AcquirySystemGUID[ 8], pVolume->AcquirySystemGUID[ 9], pVolume->AcquirySystemGUID[10], pVolume->AcquirySystemGUID[11],
pVolume->AcquirySystemGUID[12], pVolume->AcquirySystemGUID[13], pVolume->AcquirySystemGUID[14], pVolume->AcquirySystemGUID[15]);
if (pHeader2) { pHdr = pHeader2; HdrLen = Header2Len; }
else if (pHeader ) { pHdr = pHeader; HdrLen = HeaderLen; }
if (pHdr)
{
pText = (char *) malloc (MaxTextSize);
if (pText == NULL)
RET_ERR (AEWF_MEMALLOC_FAILED)
DstLen0 = MaxTextSize;
zrc = uncompress ((unsigned char *)pText, &DstLen0, (const Bytef*)pHdr, HdrLen);
UncompressedLen = DstLen0;
if (zrc != Z_OK)
RET_ERR (AEWF_UNCOMPRESS_HEADER_FAILED)
if (pHeader2) // We must convert from silly Windows 2 byte wchar_t to
{ // correct Unix 4 byte wchar_t, before we can convert to UTF8
wchar_t *pTemp = (wchar_t*) malloc ((UncompressedLen/2)*sizeof(wchar_t));
wchar_t *pStart = pTemp;
if (pTemp == NULL)
RET_ERR (AEWF_MEMALLOC_FAILED)
for (unsigned i=0; i<(UncompressedLen/2); i++)
pTemp[i] = (wchar_t) (((unsigned char*)pText)[2*i ]) |
(((wchar_t) (((unsigned char*)pText)[2*i+1])) << 8);
if (*pStart == 0xFEFF) // Jump over BOM if it exists, or else
pStart++; // conversion to UTF8 might fail.
(void) wcstombs(pText, pStart, UncompressedLen/2);
free (pTemp);
}
// Extract descriptor and data lines
// ---------------------------------
pCurrent = pText;
while (pCurrent)
{
if (strcasestr(pCurrent, "main") == pCurrent) // The header line is the one that
break; // follows the line beginning with "main"
pCurrent = strstr (pCurrent, "\n");
if (pCurrent)
pCurrent++;
}
if (pCurrent)
{
pDesc = strstr (pCurrent, "\n");
if (pDesc)
{
*pDesc++ = '\0';
pData = strstr (pDesc, "\n");
if (pData)
{
*pData++ = '\0';
pEnd = strstr (pData, "\n");
if (pEnd)
*pEnd = '\0';
}
}
}
// Scan descriptor and data lines
// ------------------------------
char *pCurDesc = pDesc;
char *pCurData = pData;
const char *pField;
char *pTabDesc;
char *pTabData;
char *pValue;
int wr = 0;
time_t Time;
struct tm *pTM;
char TimeBuff[64];
if (pCurDesc && pCurData)
{
pInfo3 = (char *) malloc (strlen (pCurData) + 4096);
if (pInfo3 == NULL)
RET_ERR (AEWF_MEMALLOC_FAILED)
while (*pCurDesc && *pCurData)
{
pTabDesc = strstr (pCurDesc, "\t");
pTabData = strstr (pCurData, "\t");
if (pTabDesc) *pTabDesc = '\0';
if (pTabData) *pTabData = '\0';
if (strcasecmp(pCurDesc, "a" ) == 0) pField = "Description";
else if (strcasecmp(pCurDesc, "c" ) == 0) pField = "Case";
else if (strcasecmp(pCurDesc, "n" ) == 0) pField = "Evidence";
else if (strcasecmp(pCurDesc, "e" ) == 0) pField = "Examiner";
else if (strcasecmp(pCurDesc, "t" ) == 0) pField = "Notes";
else if (strcasecmp(pCurDesc, "md") == 0) pField = "Model";
else if (strcasecmp(pCurDesc, "sn") == 0) pField = "Serial number";
else if (strcasecmp(pCurDesc, "av") == 0) pField = "Imager version";
else if (strcasecmp(pCurDesc, "ov") == 0) pField = "OS version";
else if (strcasecmp(pCurDesc, "m" ) == 0) pField = "Acquired time";
else if (strcasecmp(pCurDesc, "u" ) == 0) pField = "System time";
else if (strcasecmp(pCurDesc, "p" ) == 0) pField = NULL;
else if (strcasecmp(pCurDesc, "dc") == 0) pField = NULL;
else pField = "--";
if (pField)
{
pValue = pCurData;
if (strstr (pField, "time"))
{
size_t w;
Time = atoll (pCurData);
pTM = localtime (&Time);
pValue = &TimeBuff[0];
w = strftime (pValue, sizeof(TimeBuff), "%Y-%m-%d %H:%M:%S (%z)", pTM);
sprintf (&pValue[w], " (epoch %s)", pCurData);
}
wr += sprintf (&pInfo3[wr], "%-17s %s\n", pField, pValue);
}
if (!pTabDesc || !pTabData)
break;
pCurDesc = pTabDesc+1;
pCurData = pTabData+1;
}
}
}
if (pAewf->Segments == 1)
ASPRINTF (&pInfo4, "%"PRIu64" segment file: %s\n",
pAewf->Segments,
pAewf->pSegmentArr[0].pName)
else ASPRINTF (&pInfo4, "%"PRIu64" segment files\n First: %s\n Last: %s\n",
pAewf->Segments,
pAewf->pSegmentArr[0 ].pName,
pAewf->pSegmentArr[pAewf->Segments-1].pName);
ASPRINTF (&pInfo5, "%"PRIu64" tables\n", pAewf->Tables);
if (pMD5)
ASPRINTF (&pInfo6, "MD5 stored in image: %02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x\n",
pMD5->MD5[0], pMD5->MD5[1], pMD5->MD5[2 ], pMD5->MD5[3 ], pMD5->MD5[4 ], pMD5->MD5[5 ], pMD5->MD5[6 ], pMD5->MD5[7 ],
pMD5->MD5[8], pMD5->MD5[9], pMD5->MD5[10], pMD5->MD5[11], pMD5->MD5[12], pMD5->MD5[13], pMD5->MD5[14], pMD5->MD5[15])
else
ASPRINTF (&pInfo6, "MD5 stored in image: none")
if (pInfo3)
ASPRINTF (&pAewf->pInfo, "%s%s\n%s\n%s%s\n%s", pInfo1, pInfo2, pInfo3, pInfo4, pInfo5, pInfo6)
else ASPRINTF (&pAewf->pInfo, "%s%s%s%s\n%s" , pInfo1, pInfo2, pInfo4, pInfo5, pInfo6)
#undef RET_ERR
#undef ASPRINTF
CleanUp:
if (pText ) free (pText );
if (pInfo1) free (pInfo1);
if (pInfo2) free (pInfo2);
if (pInfo3) free (pInfo3);
if (pInfo4) free (pInfo4);
if (pInfo5) free (pInfo5);
if (pInfo6) free (pInfo6);
return rc;
}
static int AewfOpenSegment (t_pAewf pAewf, t_pTable pTable)
{
t_pSegment pOldestSegment;
if (pTable->pSegment->pFile != NULL) // is already opened ?
{
pAewf->SegmentCacheHits++;
return AEWF_OK;
}
pAewf->SegmentCacheMisses++;
// Check if another segment file must be closed first
// --------------------------------------------------
while (pAewf->OpenSegments >= pAewf->MaxOpenSegments)
{
pOldestSegment = NULL;
for (unsigned i=0; i<pAewf->Segments; i++)
{
if (pAewf->pSegmentArr[i].pFile == NULL)
continue;
if (pOldestSegment == NULL)
{
pOldestSegment = &pAewf->pSegmentArr[i];
}
else
{
if (pAewf->pSegmentArr[i].LastUsed < pOldestSegment->LastUsed)
pOldestSegment = &pAewf->pSegmentArr[i];
}
}
if (pOldestSegment == NULL)
break;
LOG ("Closing %s", pOldestSegment->pName);
CHK (CloseFile (&pOldestSegment->pFile))
pAewf->OpenSegments--;
}
// Open the desired segment file
// -----------------------------
LOG ("Opening %s", pTable->pSegment->pName);
CHK (OpenFile(&pTable->pSegment->pFile, pTable->pSegment->pName))
pAewf->OpenSegments++;
return AEWF_OK;
}
static int AewfLoadEwfTable (t_pAewf pAewf, t_pTable pTable)
{
t_pTable pOldestTable = NULL;
if (pTable->pEwfTable != NULL) // is already loaded?
{
pAewf->TableCacheHits++;
return AEWF_OK;
}
pAewf->TableCacheMisses++;
// Check if another pEwfTable must be given up first
// -------------------------------------------------
while ((pAewf->TableCache + pTable->Size) > pAewf->MaxTableCache)
{
pOldestTable = NULL;
for (unsigned i=0; i<pAewf->Tables; i++)
{
if (pAewf->pTableArr[i].pEwfTable == NULL)
continue;
if (pOldestTable == NULL)
{
pOldestTable = &pAewf->pTableArr[i];
}
else
{
if (pAewf->pTableArr[i].LastUsed < pOldestTable->LastUsed)
pOldestTable = &pAewf->pTableArr[i];
}
}
if (pOldestTable == NULL)
break;
pAewf->TableCache -= pOldestTable->Size;
free (pOldestTable->pEwfTable);
pOldestTable->pEwfTable = NULL;
LOG ("Releasing table %" PRIu64 " (%lu bytes)", pOldestTable->Nr, pOldestTable->Size);
}
// Read the desired table into RAM
// -------------------------------
LOG ("Loading table %" PRIu64 " (%lu bytes)", pTable->Nr, pTable->Size);
CHK (AewfOpenSegment (pAewf, pTable));
CHK (ReadFileAllocPos (pAewf, pTable->pSegment->pFile, (void**) &pTable->pEwfTable, pTable->Size, pTable->Offset))
pAewf->TableCache += pTable->Size;
- pAewf->TablesReadFromImage = pTable->Size;
+ pAewf->TablesReadFromImage += pTable->Size;
return AEWF_OK;
}
static int UpdateStats (t_pAewf pAewf, int Force)
{
time_t NowT;
pid_t pid;
FILE *pFile;
char *pFilename = NULL;
char *pCurrentWorkDir = NULL;
if (pAewf->pStatsPath)
{
time (&NowT);
if (((NowT - pAewf->LastStatsUpdate) >= (int)pAewf->StatsRefresh) || Force)
{
pAewf->LastStatsUpdate = NowT;
pid = getpid ();
if (asprintf (&pFilename, "%s/stats_%d", pAewf->pStatsPath, pid) < 0)
return AEWF_MEMALLOC_FAILED;
pFile = fopen (pFilename, "w");
if (pFile == NULL) // May be the file is locked by someone else, let's retry in 1 second
{
pAewf->LastStatsUpdate = NowT - pAewf->StatsRefresh + 1;
return AEWF_OK;
}
fprintf (pFile, "Image segment files %6"PRIu64"\n" , pAewf->Segments);
fprintf (pFile, "Image tables %6"PRIu64"\n" , pAewf->Tables);
fprintf (pFile, "\n");
fprintf (pFile, "Cache hits misses ratio\n");
fprintf (pFile, "--------------------------------------\n");
fprintf (pFile, "Segment %10" PRIu64 " %10" PRIu64 " %5.1f%%\n", pAewf->SegmentCacheHits, pAewf->SegmentCacheMisses, (100.0*pAewf->SegmentCacheHits)/(pAewf->SegmentCacheHits+pAewf->SegmentCacheMisses));
fprintf (pFile, "Table %10" PRIu64 " %10" PRIu64 " %5.1f%%\n", pAewf->TableCacheHits , pAewf->TableCacheMisses , (100.0*pAewf->TableCacheHits) /(pAewf->TableCacheHits +pAewf->TableCacheMisses ));
fprintf (pFile, "Chunk %10" PRIu64 " %10" PRIu64 " %5.1f%%\n", pAewf->ChunkCacheHits , pAewf->ChunkCacheMisses , (100.0*pAewf->ChunkCacheHits) /(pAewf->ChunkCacheHits +pAewf->ChunkCacheMisses ));
fprintf (pFile, "\n");
fprintf (pFile, "Read operations %10" PRIu64 "\n", pAewf->ReadOperations);
fprintf (pFile, "Errors %10" PRIu64 "\n", pAewf->Errors);
fprintf (pFile, "Open segment files %10" PRIu64"\n" , pAewf->OpenSegments);
fprintf (pFile, "Last error %10d (%s)\n" , pAewf->LastError, AewfGetErrorMessage (pAewf->LastError));
fprintf (pFile, "Data read from image %10.1f MiB (compressed)\n", pAewf->DataReadFromImage / (1024.0*1024.0));
fprintf (pFile, "Data read from image %10.1f MiB (raw)\n" , pAewf->DataReadFromImageRaw / (1024.0*1024.0));
fprintf (pFile, "Data requested by caller %10.1f MiB\n" , pAewf->DataRequestedByCaller/ (1024.0*1024.0));
fprintf (pFile, "Tables read from image %10.1f MiB\n" , pAewf->TablesReadFromImage / (1024.0*1024.0));
fprintf (pFile, "RAM used as table cache %10.1f MiB\n" , pAewf->TableCache / (1024.0*1024.0));
fprintf (pFile, "Size of all image tables %10.1f MiB\n" , pAewf->TotalTableSize / (1024.0*1024.0));
fprintf (pFile, "\n");
fprintf (pFile, "Histogram of read request sizes\n");
fprintf (pFile, "-------------------------------\n");
fprintf (pFile, " 0 < Size <= 32K %10" PRIu64"\n", pAewf->ReadSizesArr[READSIZE_32K]);
fprintf (pFile, " 32K < Size <= 64K %10" PRIu64"\n", pAewf->ReadSizesArr[READSIZE_64K]);
fprintf (pFile, " 64K < Size <= 128K %10" PRIu64"\n", pAewf->ReadSizesArr[READSIZE_128K]);
fprintf (pFile, "128K < Size <= 256K %10" PRIu64"\n", pAewf->ReadSizesArr[READSIZE_256K]);
fprintf (pFile, "256K < Size <= 512K %10" PRIu64"\n", pAewf->ReadSizesArr[READSIZE_512K]);
fprintf (pFile, "512K < Size <= 1M %10" PRIu64"\n", pAewf->ReadSizesArr[READSIZE_1M]);
fprintf (pFile, " Size > 1M %10" PRIu64"\n", pAewf->ReadSizesArr[READSIZE_ABOVE_1M]);
pCurrentWorkDir = getcwd (NULL, 0);
if (pCurrentWorkDir == NULL)
return AEWF_MEMALLOC_FAILED;
fprintf (pFile, "\nCurrent working directory: %s\n", pCurrentWorkDir);
free (pCurrentWorkDir);
(void) fclose (pFile);
free (pFilename);
return AEWF_OK;
}
}
return AEWF_OK;
}
// -----------------------------------------------------------------------------
// Legacy functions - Single threaded read function from former xmount version
// -----------------------------------------------------------------------------
// AewfReadChunkLegacy0 reads exactly one chunk. It expects the EWF table be present
// in memory and the required segment be opened.
static int AewfReadChunkLegacy0 (t_pAewf pAewf, t_pTable pTable, uint64_t AbsoluteChunk, unsigned TableChunk)
{
int Compressed;
uint64_t SeekPos;
t_pAewfSectionTable pEwfTable;
unsigned int Offset;
unsigned int ReadLen;
uLongf DstLen0;
int zrc;
uint CalcCRC;
uint *pStoredCRC;
uint64_t ChunkSize;
int Ret = AEWF_OK;
pEwfTable = pTable->pEwfTable;
if (pEwfTable == NULL)
return AEWF_ERROR_EWF_TABLE_NOT_READY;
if (pTable->pSegment->pFile == NULL)
return AEWF_ERROR_EWF_SEGMENT_NOT_READY;
Compressed = pEwfTable->OffsetArray[TableChunk] & AEWF_COMPRESSED;
Offset = pEwfTable->OffsetArray[TableChunk] & ~AEWF_COMPRESSED;
SeekPos = pEwfTable->TableBaseOffset + Offset;
if (TableChunk < (pEwfTable->ChunkCount-1))
ReadLen = (pEwfTable->OffsetArray[TableChunk+1] & ~AEWF_COMPRESSED) - Offset;
else ReadLen = (pTable->SectionSectorsSize - sizeof(t_AewfSection)) - (Offset - (pEwfTable->OffsetArray[0] & ~AEWF_COMPRESSED));
// else ReadLen = pAewf->ChunkBuffSize; // This also works! It looks as if uncompress is able to find out by itself the real size of the input data.
if (ReadLen > pAewf->ChunkBuffSize)
{
LOG ("Chunk too big %u / %u", ReadLen, pAewf->ChunkBuffSize);
return AEWF_CHUNK_TOO_BIG;
}
ChunkSize = pAewf->ChunkSize;
if (AbsoluteChunk == (pAewf->Chunks-1)) // The very last chunk of the image may be smaller than the default
{ // chunk size if the image isn't a multiple of the chunk size.
ChunkSize = pAewf->ImageSize % pAewf->ChunkSize;
if (ChunkSize == 0)
ChunkSize = pAewf->ChunkSize;
}
if (Compressed)
{
CHK (ReadFilePos (pAewf, pTable->pSegment->pFile, pAewf->pChunkBuffCompressed, ReadLen, SeekPos))
DstLen0 = pAewf->ChunkBuffSize;
zrc = uncompress ((unsigned char*)pAewf->pChunkBuffUncompressed, &DstLen0, (const Bytef*)pAewf->pChunkBuffCompressed, ReadLen);
if (zrc != Z_OK)
Ret = AEWF_UNCOMPRESS_FAILED;
if (DstLen0 != ChunkSize)
Ret = AEWF_BAD_UNCOMPRESSED_LENGTH;
}
else
{
CHK (ReadFilePos (pAewf, pTable->pSegment->pFile, pAewf->pChunkBuffUncompressed, ReadLen, SeekPos))
CalcCRC = adler32 (1, (const Bytef *) pAewf->pChunkBuffUncompressed, ChunkSize);
pStoredCRC = (uint *) (pAewf->pChunkBuffUncompressed + ChunkSize); //lint !e826 Suspicious pointer-to-pointer conversion (area too small)
if (CalcCRC != *pStoredCRC)
Ret = AEWF_CHUNK_CRC_ERROR;
}
pAewf->DataReadFromImage += ReadLen;
pAewf->DataReadFromImageRaw += ChunkSize;
if (Ret == AEWF_OK)
{
pAewf->ChunkInBuff = AbsoluteChunk;
pAewf->ChunkBuffUncompressedDataLen = ChunkSize;
}
else
{
pAewf->ChunkInBuff = AEWF_NONE;
pAewf->ChunkBuffUncompressedDataLen = 0;
}
return Ret;
}
static int AewfReadChunkLegacy (t_pAewf pAewf, uint64_t AbsoluteChunk, char **ppBuffer, unsigned int *pLen)
{
t_pTable pTable;
int Found=FALSE;
unsigned TableChunk;
unsigned TableNr;
*ppBuffer = pAewf->pChunkBuffUncompressed;
*pLen = 0;
if (pAewf->ChunkInBuff == AbsoluteChunk)
{
*pLen = pAewf->ChunkBuffUncompressedDataLen;
pAewf->ChunkCacheHits++;
return AEWF_OK;
}
pAewf->ChunkCacheMisses++;
// Find table containing desired chunk
// -----------------------------------
for (TableNr=0; TableNr<pAewf->Tables; TableNr++)
{
pTable = &pAewf->pTableArr[TableNr];
Found = (AbsoluteChunk >= pTable->ChunkFrom) &&
(AbsoluteChunk <= pTable->ChunkTo);
if (Found)
break;
}
if (!Found)
CHK (AEWF_CHUNK_NOT_FOUND)
// Load corresponding table and get chunk
// --------------------------------------
pTable->LastUsed = time(NULL); //lint !e771 pTable' (line 640) conceivably not initialized
pTable->pSegment->LastUsed = pTable->LastUsed; // Update LastUsed here, in order not to remove the required data from cache
CHK (AewfLoadEwfTable (pAewf, pTable))
CHK (AewfOpenSegment (pAewf, pTable));
if ((AbsoluteChunk - pTable->ChunkFrom) > UINT_MAX)
CHK (AEWF_ERROR_IN_CHUNK_NUMBER)
TableChunk = AbsoluteChunk - pTable->ChunkFrom;
// LOG ("table %d / entry %" PRIu64 " (%s)", TableNr, TableChunk, pTable->pSegment->pName)
CHK (AewfReadChunkLegacy0 (pAewf, pTable, AbsoluteChunk, TableChunk))
*pLen = pAewf->ChunkBuffUncompressedDataLen;
return AEWF_OK;
}
static int AewfReadLegacy (t_pAewf pAewf, char *pBuf, uint64_t Seek64, size_t Count, size_t *pRead, int *pErrno)
{
char *pChunkBuffer;
uint64_t Chunk;
uint64_t Remaining;
unsigned int ChunkLen, Ofs, ToCopy;
Ofs = Seek64 % pAewf->ChunkSize;
Chunk = Seek64 / pAewf->ChunkSize;
Remaining = Count;
while (Remaining)
{
CHK (AewfReadChunkLegacy (pAewf, Chunk, &pChunkBuffer, &ChunkLen))
if (ChunkLen == 0)
return AEWF_CHUNK_LENGTH_ZERO;
ToCopy = GETMIN (ChunkLen-Ofs, Remaining);
memcpy (pBuf, pChunkBuffer+Ofs, ToCopy);
Remaining -= ToCopy;
pBuf += ToCopy;
*pRead += ToCopy;
Ofs = 0;
Chunk++;
}
return AEWF_OK;
}
// ------------------------------------------------------------------------------------
// MT functions - Read function with multi-threaded decompression and CRC calculation
// ------------------------------------------------------------------------------------
// AewfThreadUncompress is run whenever compressed data chunk are encountered. It uncompresses
// the data and copies it to the correct destination.
static void* AewfThreadUncompress (void *pArg)
{
t_pAewfThread pThread = (t_pAewfThread) pArg;
uLongf DstLen0;
int zrc;
pThread->ReturnCode = AEWF_OK;
DstLen0 = pThread->pAewf->ChunkBuffSize;
zrc = uncompress ((unsigned char*)pThread->pChunkBuffUncompressed, &DstLen0,
(const Bytef*)pThread->pChunkBuffCompressed ,
pThread->ChunkBuffCompressedDataLen);
if (zrc != Z_OK)
pThread->ReturnCode = AEWF_UNCOMPRESS_FAILED;
else if (DstLen0 != pThread->ChunkBuffUncompressedDataLen)
pThread->ReturnCode = AEWF_BAD_UNCOMPRESSED_LENGTH;
else
memcpy (pThread->pBuf, pThread->pChunkBuffUncompressed+pThread->Ofs, pThread->Len);
return NULL;
}
// AewfThreadCRC is called for uncompressed data chunks. It verifies the CRC and
// copies the data to the correct destination.
static void* AewfThreadCRC (void *pArg)
{
t_pAewfThread pThread = (t_pAewfThread) pArg;
uint *pStoredCRC;
uint CalcCRC;
pThread->ReturnCode = AEWF_OK;
CalcCRC = adler32 (1, (const Bytef *) pThread->pChunkBuffUncompressed, pThread->ChunkBuffUncompressedDataLen);
pStoredCRC = (uint *) (pThread->pChunkBuffUncompressed + pThread->ChunkBuffUncompressedDataLen); //lint !e826 Suspicious pointer-to-pointer conversion (area too small)
if (CalcCRC != *pStoredCRC)
pThread->ReturnCode = AEWF_CHUNK_CRC_ERROR;
memcpy (pThread->pBuf, pThread->pChunkBuffUncompressed+pThread->Ofs, pThread->Len);
return NULL;
}
// AewfThreadCopy is used in case of a cache hit. It simply copies the data from the
// uncompressed buffer to the destination.
static void* AewfThreadCopy (void *pArg)
{
t_pAewfThread pThread = (t_pAewfThread) pArg;
memcpy (pThread->pBuf, pThread->pChunkBuffUncompressed+pThread->Ofs, pThread->Len);
pThread->ReturnCode = AEWF_OK;
return NULL;
}
// AewfReadChunkMT0 reads exactly one chunk. It expects the EWF table be present
// in memory and the required segment be opened.
static int AewfReadChunkMT0 (t_pAewf pAewf, t_pTable pTable, uint64_t AbsoluteChunk, unsigned TableChunk, char *pBuf, unsigned int Ofs, unsigned int Len)
{
int Compressed;
uint64_t SeekPos;
t_pAewfSectionTable pEwfTable;
unsigned int Offset;
unsigned int ReadLen;
int prc;
uint64_t ChunkSize;
int Ret = AEWF_OK;
// LOG ("Called - AbsoluteChunk=%'" PRIu64, AbsoluteChunk);
pEwfTable = pTable->pEwfTable;
if (pEwfTable == NULL)
return AEWF_ERROR_EWF_TABLE_NOT_READY;
if (pTable->pSegment->pFile == NULL)
return AEWF_ERROR_EWF_SEGMENT_NOT_READY;
Compressed = pEwfTable->OffsetArray[TableChunk] & AEWF_COMPRESSED;
Offset = pEwfTable->OffsetArray[TableChunk] & ~AEWF_COMPRESSED;
SeekPos = pEwfTable->TableBaseOffset + Offset;
if (TableChunk < (pEwfTable->ChunkCount-1))
ReadLen = (pEwfTable->OffsetArray[TableChunk+1] & ~AEWF_COMPRESSED) - Offset;
else ReadLen = (pTable->SectionSectorsSize - sizeof(t_AewfSection)) - (Offset - (pEwfTable->OffsetArray[0] & ~AEWF_COMPRESSED));
// else ReadLen = pAewf->ChunkBuffSize; // This also works! It looks as if uncompress is able to find out by itself the real size of the input data.
if (ReadLen > pAewf->ChunkBuffSize)
{
LOG ("Chunk too big %u / %u", ReadLen, pAewf->ChunkBuffSize);
CHK (AEWF_CHUNK_TOO_BIG)
}
ChunkSize = pAewf->ChunkSize;
if (AbsoluteChunk == (pAewf->Chunks-1)) // The very last chunk of the image may be smaller than the default
{ // chunk size if the image isn't a multiple of the chunk size.
ChunkSize = pAewf->ImageSize % pAewf->ChunkSize;
if (ChunkSize == 0)
ChunkSize = pAewf->ChunkSize;
}
for (int i=0; i<pAewf->Threads; i++)
{
t_pAewfThread pThread = &(pAewf->pThreadArr[i]);
if (pThread->State == AEWF_IDLE)
{
pThread->State = AEWF_LAUNCHED;
pThread->ChunkBuffCompressedDataLen = ReadLen;
pThread->ChunkBuffUncompressedDataLen = ChunkSize; // uncompress should return this size (if it's a compressed chunk)
pThread->ChunkInBuff = AbsoluteChunk;
pThread->pBuf = pBuf; // These 3 parameters specify which part
pThread->Ofs = Ofs; // of the resulting chunk data should be
pThread->Len = Len; // copied to which location.
if (Compressed)
{
CHK (ReadFilePos (pAewf, pTable->pSegment->pFile, pThread->pChunkBuffCompressed, ReadLen, SeekPos))
prc = pthread_create (&pThread->ID, NULL, AewfThreadUncompress, pThread);
}
else
{
CHK (ReadFilePos (pAewf, pTable->pSegment->pFile, pThread->pChunkBuffUncompressed, ReadLen, SeekPos))
prc = pthread_create (&pThread->ID, NULL, AewfThreadCRC, pThread);
}
if (prc != 0)
Ret = AEWF_ERROR_PTHREAD;
break;
}
}
pAewf->DataReadFromImage += ReadLen;
pAewf->DataReadFromImageRaw += ChunkSize;
return Ret;
}
static int AewfReadChunkMT (t_pAewf pAewf, uint64_t AbsoluteChunk, char *pBuf, unsigned int Ofs, unsigned int Len)
{
t_pTable pTable;
int Found=FALSE;
unsigned TableChunk;
unsigned TableNr;
int rc;
// LOG ("Called - AbsoluteChunk=%'" PRIu64, AbsoluteChunk);
// Check if chunk already is in cache
// ----------------------------------
for (int i=0; i<pAewf->Threads; i++)
{
t_pAewfThread pThread = &(pAewf->pThreadArr[i]);
if (pThread->ChunkInBuff == AbsoluteChunk)
{
pThread->State = AEWF_LAUNCHED;
pThread->pBuf = pBuf;
pThread->Ofs = Ofs;
pThread->Len = Len;
rc = pthread_create (&pThread->ID, NULL, AewfThreadCopy, pThread);
if (rc != 0)
return AEWF_ERROR_PTHREAD;
pAewf->ChunkCacheHits++;
return AEWF_OK;
}
}
pAewf->ChunkCacheMisses++;
// Find table containing desired chunk
// -----------------------------------
for (TableNr=0; TableNr<pAewf->Tables; TableNr++)
{
pTable = &pAewf->pTableArr[TableNr];
Found = (AbsoluteChunk >= pTable->ChunkFrom) &&
(AbsoluteChunk <= pTable->ChunkTo);
if (Found)
break;
}
if (!Found)
CHK (AEWF_CHUNK_NOT_FOUND)
// Load corresponding table and get chunk
// --------------------------------------
pTable->LastUsed = time(NULL); //lint !e771 pTable' (line 640) conceivably not initialized
pTable->pSegment->LastUsed = pTable->LastUsed; // Update LastUsed here, in order not to remove the required data from cache
CHK (AewfLoadEwfTable (pAewf, pTable))
CHK (AewfOpenSegment (pAewf, pTable));
if ((AbsoluteChunk - pTable->ChunkFrom) > UINT_MAX)
CHK (AEWF_ERROR_IN_CHUNK_NUMBER)
TableChunk = AbsoluteChunk - pTable->ChunkFrom;
// LOG ("table %d / entry %" PRIu64 " (%s)", TableNr, TableChunk, pTable->pSegment->pName)
CHK (AewfReadChunkMT0 (pAewf, pTable, AbsoluteChunk, TableChunk, pBuf, Ofs, Len))
return AEWF_OK;
}
static int AewfReadMT0 (t_pAewf pAewf, char *pBuf, uint64_t Seek64, size_t Count, size_t *pRead, int *pErrno)
{
uint64_t AbsoluteChunk;
uint64_t Remaining;
uint64_t Len, Ofs;
t_pAewfThread pThread;
Ofs = Seek64 % pAewf->ChunkSize;
AbsoluteChunk = Seek64 / pAewf->ChunkSize;
Remaining = Count;
*pRead = 0;
// Launch all read/decompress jobs
// -------------------------------
while (Remaining)
{
Len = GETMIN (pAewf->ChunkSize - Ofs, Remaining);
CHK (AewfReadChunkMT (pAewf, AbsoluteChunk, pBuf, Ofs, Len))
Remaining -= Len;
pBuf += Len;
Ofs = 0;
AbsoluteChunk++;
}
// Wait for threads
// ----------------
for (int i=0; i<pAewf->Threads; i++)
{
pThread = &(pAewf->pThreadArr[i]);
// LOG ("Checking thread %d -> %d", i, pThread->State);
if (pThread->State == AEWF_LAUNCHED)
{
pthread_join (pThread->ID, NULL);
pThread->State = AEWF_IDLE;
CHK (pThread->ReturnCode)
*pRead += pThread->Len;
}
}
return AEWF_OK;
}
static int AewfReadMT (t_pAewf pAewf, char *pBuf, uint64_t Seek64, size_t Count, size_t *pRead, int *pErrno)
{
uint64_t ToRead;
uint64_t MaxPerLoop;
size_t Read;
MaxPerLoop = pAewf->Threads * pAewf->ChunkSize;
while (Count)
{
ToRead = GETMIN (MaxPerLoop, Count);
Read = 0;
CHK (AewfReadMT0 (pAewf, pBuf, Seek64, ToRead, &Read, pErrno))
*pRead += Read;
pBuf += Read;
Seek64 += Read;
Count -= Read;
}
return AEWF_OK;
}
// ---------------
// API functions
// ---------------
static int AewfCreateHandle (void **ppHandle, const char *pFormat, uint8_t Debug)
{
t_pAewf pAewf;
*ppHandle = NULL;
// Create handle and clear it
// --------------------------
pAewf = (t_pAewf) malloc (sizeof(t_Aewf));
if (pAewf == NULL)
return AEWF_MEMALLOC_FAILED;
memset(pAewf,0,sizeof(t_Aewf));
pAewf->ChunkInBuff = AEWF_NONE;
pAewf->pErrorText = NULL;
pAewf->StatsRefresh = 10;
pAewf->SegmentCacheHits = 0;
pAewf->SegmentCacheMisses = 0;
pAewf->TableCacheHits = 0;
pAewf->TableCacheMisses = 0;
pAewf->ChunkCacheHits = 0;
pAewf->ChunkCacheMisses = 0;
pAewf->ReadOperations = 0;
pAewf->DataReadFromImage = 0;
pAewf->DataReadFromImageRaw = 0;
pAewf->DataRequestedByCaller = 0;
pAewf->TablesReadFromImage = 0;
pAewf->ChunksRead = 0;
pAewf->BytesRead = 0;
memset (pAewf->ReadSizesArr, 0, sizeof (pAewf->ReadSizesArr));
pAewf->Errors = 0;
pAewf->LastError = AEWF_OK;
pAewf->MaxTableCache = 0;
pAewf->MaxOpenSegments = 0;
pAewf->pStatsPath = NULL;
pAewf->StatsRefresh = 0;
pAewf->pLogPath = NULL;
pAewf->LogStdout = Debug;
pAewf->pThreadArr = NULL;
pAewf->MaxTableCache = AEWF_DEFAULT_TABLECACHE * 1024*1024;
pAewf->MaxOpenSegments = AEWF_DEFAULT_MAXOPENSEGMENTS;
pAewf->StatsRefresh = AEWF_DEFAULT_STATSREFRESH;
pAewf->Threads = AEWF_DEFAULT_THREADS;
*ppHandle = (void*) pAewf;
return AEWF_OK;
}
int AewfDestroyHandle(void **ppHandle)
{
t_pAewf pAewf = (t_pAewf) *ppHandle;
LOG ("Called");
LOG ("Remark: 'Ret' won't be logged"); // Handle gets destroyed, 'ret' logging not possible
if (pAewf->pLogPath ) free(pAewf->pLogPath );
if (pAewf->pStatsPath) free(pAewf->pStatsPath);
memset (pAewf, 0, sizeof(t_Aewf));
free (pAewf);
*ppHandle = NULL;
return AEWF_OK;
}
int AewfOpen (void *pHandle, const char **ppFilenameArr, uint64_t FilenameArrLen)
{
t_pAewf pAewf = (t_pAewf) pHandle;
t_AewfFileHeader FileHeader;
t_AewfSection Section;
FILE *pFile;
t_pSegment pSegment;
t_pSegment pPrevSegment;
t_pTable pTable;
uint64_t Pos;
t_pAewfSectionTable pEwfTable = NULL;
t_pAewfSectionVolume pVolume = NULL;
t_pAewfSectionHash pMD5 = NULL;
char *pHeader = NULL;
char *pHeader2 = NULL;
int LastSection;
unsigned int SectionSectorsSize;
unsigned HeaderLen = 0;
unsigned Header2Len = 0;
LOG ("Called - Files=%" PRIu64, FilenameArrLen);
// Create pSegmentArr and put the segment files in it
// --------------------------------------------------
int SegmentArrLen = FilenameArrLen * sizeof(t_Segment);
pAewf->pSegmentArr = (t_pSegment) malloc (SegmentArrLen);
pAewf->Segments = FilenameArrLen;
if (pAewf->pSegmentArr == NULL)
return AEWF_MEMALLOC_FAILED;
memset (pAewf->pSegmentArr, 0, SegmentArrLen);
for (unsigned i=0; i<FilenameArrLen; i++)
{
pSegment = &pAewf->pSegmentArr[i];
pSegment->pName = realpath (ppFilenameArr[i], NULL); // realpath allocates a buffer of the necessary length
LOG ("Opening segment %s", ppFilenameArr[i]);
CHK (OpenFile (&pFile, pSegment->pName))
CHK (ReadFilePos (pAewf, pFile, (void*)&FileHeader, sizeof(FileHeader), 0))
pSegment->Number = FileHeader.SegmentNumber;
pSegment->LastUsed = 0;
pSegment->pFile = NULL;
CHK (CloseFile (&pFile))
}
// Put segment array into correct sequence and check if segment numbers are correct
// --------------------------------------------------------------------------------
qsort (pAewf->pSegmentArr, pAewf->Segments, sizeof (t_Segment), &QsortCompareSegments);
pPrevSegment = NULL;
for (unsigned i=0; i<pAewf->Segments; i++)
{
pSegment = &(pAewf->pSegmentArr[i]);
if (pPrevSegment)
{
if (pSegment->Number == pPrevSegment->Number)
{
LOG ("Error: Duplicate segment numbers");
LOG ("Segment files %s and %s have both segment number %u", pPrevSegment->pName, pSegment->pName, pSegment->Number);
return AEWF_DUPLICATE_SEGMENT_NUMBER;
}
}
if (pSegment->Number != (i+1))
{
LOG ("Error: Missing segment number(s)");
LOG ("Previous segment file %s has segment number %u", pPrevSegment->pName, pPrevSegment->Number);
LOG ("Following segment file %s has segment number %u", pSegment->pName , pSegment->Number );
return AEWF_MISSING_SEGMENT_NUMBER;
}
pPrevSegment = pSegment;
}
// Find all tables in the segment files
// ------------------------------------
pAewf->pTableArr = NULL;
pAewf->Tables = 0;
pAewf->Chunks = 0;
pAewf->TotalTableSize = 0;
SectionSectorsSize = 0;
LOG ("Reading tables");
for (unsigned i=0; i<pAewf->Segments; i++)
{
pSegment = &pAewf->pSegmentArr[i];
CHK (OpenFile (&pFile, pSegment->pName))
CHK (ReadFilePos (pAewf, pFile, &FileHeader, sizeof(FileHeader), 0))
Pos = sizeof (FileHeader);
LOG ("Segment %s ", pSegment->pName);
// Search for the important sections
do
{
CHK (ReadFilePos (pAewf, pFile, &Section, sizeof (t_AewfSection), Pos))
if (strcasecmp ((char *)Section.Type, "sectors") == 0)
{
SectionSectorsSize = Section.Size;
}
else if (strcasecmp ((char *)Section.Type, "table") == 0)
{
if (pVolume == NULL)
return AEWF_VOLUME_MUST_PRECEDE_TABLES;
if (SectionSectorsSize == 0)
return AEWF_SECTORS_MUST_PRECEDE_TABLES;
pAewf->Tables++;
pAewf->pTableArr = (t_pTable) realloc (pAewf->pTableArr, pAewf->Tables * sizeof (t_Table));
CHK (ReadFileAlloc (pAewf, pFile, (void**) &pEwfTable, sizeof(t_AewfSectionTable))) // No need to read the actual offset table
pTable = &pAewf->pTableArr[pAewf->Tables-1];
pTable->Nr = pAewf->Tables-1;
pTable->pSegment = pSegment;
pTable->Offset = Pos + sizeof (t_AewfSection);
pTable->Size = Section.Size;
pTable->ChunkCount = pEwfTable->ChunkCount;
pTable->LastUsed = 0;
pTable->pEwfTable = NULL;
pTable->ChunkFrom = pAewf->Chunks;
pTable->SectionSectorsSize = SectionSectorsSize;
pAewf->TotalTableSize += pTable->Size;
pAewf->Chunks += pTable->ChunkCount;
pTable->ChunkTo = pAewf->Chunks-1;
free (pEwfTable);
pEwfTable = NULL;
SectionSectorsSize = 0;
}
else if ((strcasecmp ((char *)Section.Type, "header") == 0) && (pHeader==NULL))
{
HeaderLen = Section.Size - sizeof(t_AewfSection);
CHK (ReadFileAlloc (pAewf, pFile, (void**) &pHeader, HeaderLen))
}
else if ((strcasecmp ((char *)Section.Type, "header2") == 0) && (pHeader2==NULL))
{
Header2Len = Section.Size - sizeof(t_AewfSection);
CHK (ReadFileAlloc (pAewf, pFile, (void**) &pHeader2, Header2Len))
}
else if ( ((strcasecmp ((char *)Section.Type, "volume") == 0) || // Guymager works with the volume section. Others use different names
(strcasecmp ((char *)Section.Type, "disk" ) == 0) || // for it, but it all is the same. See Joachim Metz' EWF documentation
(strcasecmp ((char *)Section.Type, "data" ) == 0))
&& (pVolume==NULL))
{
CHK (ReadFileAlloc (pAewf, pFile, (void**) &pVolume, sizeof(t_AewfSectionVolume)))
pAewf->Sectors = pVolume->SectorCount;
pAewf->SectorSize = pVolume->BytesPerSector;
pAewf->ChunkSize = pVolume->SectorsPerChunk * pVolume->BytesPerSector; //lint !e647 Suspicious truncation
pAewf->ImageSize = pAewf->Sectors * pAewf->SectorSize;
}
if (strcasecmp ((char *)Section.Type, "hash") == 0)
{
CHK (ReadFileAlloc (pAewf, pFile, (void**) &pMD5, sizeof(t_AewfSectionHash)))
}
// LOG ("Section %s", Section.Type)
LastSection = (Pos == Section.OffsetNextSection);
Pos = Section.OffsetNextSection;
} while (!LastSection);
CHK (CloseFile (&pFile))
}
if (pVolume == NULL)
return AEWF_VOLUME_MISSING;
if (pAewf->Chunks != pVolume->ChunkCount)
{
LOG ("Error: Wrong chunk count: %"PRIu64" / %"PRIu64, pAewf->Chunks, pVolume->ChunkCount);
LOG ("Maybe some segment files are missing. Perhaps you specified E01 instead of E?? or the segments continue beyond extension .EZZ.");
return AEWF_WRONG_CHUNK_COUNT;
}
pAewf->ChunkBuffSize = pAewf->ChunkSize + 4096; // reserve some extra space (for CRC and as compressed data might be slightly larger than uncompressed data with some imagers)
pAewf->pChunkBuffCompressed = (char *) malloc (pAewf->ChunkBuffSize);
pAewf->pChunkBuffUncompressed = (char *) malloc (pAewf->ChunkBuffSize);
if ((pAewf->pChunkBuffCompressed == NULL) ||
(pAewf->pChunkBuffUncompressed == NULL))
return AEWF_MEMALLOC_FAILED;
pAewf->TableCache = 0;
pAewf->OpenSegments = 0;
CHK (CreateInfoData (pAewf, pVolume, pHeader, HeaderLen, pHeader2, Header2Len, pMD5))
free (pVolume);
free (pHeader);
free (pHeader2);
// Allocate thread structures
// --------------------------
if (pAewf->Threads > 1)
{
pAewf->pThreadArr = (t_pAewfThread) malloc (pAewf->Threads * sizeof (t_AewfThread));
for (int i=0; i<pAewf->Threads; i++)
{
t_pAewfThread pThread = &pAewf->pThreadArr[i];
memset (pThread, 0, sizeof(t_AewfThread));
pThread->pAewf = pAewf;
pThread->pChunkBuffCompressed = (char *) malloc (pAewf->ChunkBuffSize);
pThread->pChunkBuffUncompressed = (char *) malloc (pAewf->ChunkBuffSize);
pThread->ChunkInBuff = AEWF_NONE;
pThread->State = AEWF_IDLE;
}
}
LOG ("Ret");
return AEWF_OK;
}
static int AewfClose (void *pHandle)
{
t_pAewf pAewf = (t_pAewf) pHandle;
t_pTable pTable;
t_pSegment pSegment;
LOG ("Called");
CHK (UpdateStats (pAewf,TRUE))
for (unsigned i=0; i<pAewf->Tables; i++)
{
pTable = &pAewf->pTableArr[i];
if (pTable->pEwfTable)
free (pTable->pEwfTable);
}
for (unsigned i=0;i<pAewf->Segments;i++)
{
pSegment = &pAewf->pSegmentArr[i];
if (pSegment->pFile)
CHK (CloseFile (&pSegment->pFile));
free (pSegment->pName);
}
free (pAewf->pTableArr);
free (pAewf->pSegmentArr);
free (pAewf->pChunkBuffCompressed);
free (pAewf->pChunkBuffUncompressed);
// Free thread structures
// ----------------------
if (pAewf->pThreadArr)
{
for (int i=0; i<pAewf->Threads; i++)
{
t_pAewfThread pThread = &pAewf->pThreadArr[i];
free (pThread->pChunkBuffCompressed);
free (pThread->pChunkBuffUncompressed);
}
free (pAewf->pThreadArr);
pAewf->pThreadArr = NULL;
}
LOG ("Ret");
return AEWF_OK;
}
static int AewfSize (void *pHandle, uint64_t *pSize)
{
t_pAewf pAewf = (t_pAewf) pHandle;
LOG ("Called");
*pSize = pAewf->ImageSize;
LOG ("Ret - Size=%" PRIu64, *pSize);
return AEWF_OK;
}
static int AewfRead (void *pHandle, char *pBuf, off_t Seek, size_t Count, size_t *pRead, int *pErrno)
{
t_pAewf pAewf = (t_pAewf) pHandle;
uint64_t Seek64;
int Ret = AEWF_OK;
LOG ("Called - Seek=%'" PRIu64 ",Count=%'" PRIu64, Seek, Count);
*pRead = 0;
*pErrno = 0;
if (Seek < 0)
{
Ret = AEWF_NEGATIVE_SEEK;
goto Leave;
}
Seek64 = Seek;
pAewf->ReadOperations++;
pAewf->DataRequestedByCaller+=Count;
if (Count <= 32*1024) pAewf->ReadSizesArr[READSIZE_32K]++;
else if (Count <= 64*1024) pAewf->ReadSizesArr[READSIZE_64K]++;
else if (Count <= 128*1024) pAewf->ReadSizesArr[READSIZE_128K]++;
else if (Count <= 256*1024) pAewf->ReadSizesArr[READSIZE_256K]++;
else if (Count <= 512*1024) pAewf->ReadSizesArr[READSIZE_512K]++;
else if (Count <= 1024*1024) pAewf->ReadSizesArr[READSIZE_1M]++;
else pAewf->ReadSizesArr[READSIZE_ABOVE_1M]++;
if (Seek64 >= pAewf->ImageSize) // If calling function asks
goto Leave; // for data beyond end of
if ((Seek64+Count) > pAewf->ImageSize) // image simply return what
Count = pAewf->ImageSize - Seek64; // is possible.
if (pAewf->Threads == 1)
Ret = AewfReadLegacy (pAewf, pBuf, Seek64, Count, pRead, pErrno);
else Ret = AewfReadMT (pAewf, pBuf, Seek64, Count, pRead, pErrno);
Leave:
AewfCheckError (pAewf, Ret, pErrno);
CHK (UpdateStats (pAewf, (Ret != AEWF_OK)))
LOG ("Ret %d - Read=%" PRIu32, Ret, *pRead);
return Ret;
}
static int AewfOptionsHelp (const char **ppHelp)
{
char *pHelp=NULL;
int wr;
wr = asprintf (&pHelp, " %-12s : Maximum amount of RAM cache, in MiB, for image offset tables. Default: %"PRIu64" MiB\n"
" %-12s : Maximum number of concurrently opened image segment files. Default: %"PRIu64"\n"
" %-12s : Output statistics at regular intervals to this directory (must exist).\n"
" The files created in this directory will be named stats_<pid>.\n"
" %-12s : The update interval, in seconds, for the statistics (%s must be set). Default: %"PRIu64"s.\n"
" %-12s : Path for writing log file (must exist).\n"
" The files created in this directory will be named log_<pid>.\n"
" %-12s : Max. number of threads for parallelized decompression. Default: %"PRIu64"\n"
" A value of 1 switches back to old, single-threaded legacy functions.\n",
AEWF_OPTION_TABLECACHE, AEWF_DEFAULT_TABLECACHE,
AEWF_OPTION_MAXOPENSEGMENTS, AEWF_DEFAULT_MAXOPENSEGMENTS,
AEWF_OPTION_STATS,
AEWF_OPTION_STATSREFRESH, AEWF_OPTION_STATS, AEWF_DEFAULT_STATSREFRESH,
AEWF_OPTION_LOG,
AEWF_OPTION_THREADS, AEWF_DEFAULT_THREADS);
if ((pHelp == NULL) || (wr<=0))
return AEWF_MEMALLOC_FAILED;
*ppHelp = pHelp;
return AEWF_OK;
}
static int AewfOptionsParse (void *pHandle, uint32_t OptionCount, const pts_LibXmountOptions *ppOptions, const char **ppError)
{
pts_LibXmountOptions pOption;
t_pAewf pAewf = (t_pAewf) pHandle;
const char *pError = NULL;
int rc = AEWF_OK;
int Ok;
LOG ("Called - OptionCount=%" PRIu32, OptionCount);
*ppError = NULL;
#define TEST_OPTION_UINT64(Opt,DestField) \
if (strcmp (pOption->p_key, Opt) == 0) \
{ \
pAewf->DestField = StrToUint64 (pOption->p_value, &Ok); \
if (!Ok) \
{ \
pError = "Error in option %s: Invalid value"; \
break; \
} \
LOG ("Option %s set to %" PRIu64, Opt, pAewf->DestField) \
}
for (uint32_t i=0; i<OptionCount; i++)
{
pOption = ppOptions[i];
if (strcmp (pOption->p_key, AEWF_OPTION_LOG) == 0)
{
pAewf->pLogPath = realpath (pOption->p_value, NULL);
if (pAewf->pLogPath == NULL)
{
pError = "The given log path does not exist";
LOG ("Log path %s not found", pOption->p_value);
break;
}
rc = LOG ("Logging for libxmount_input_aewf started")
if (rc != AEWF_OK)
{
pError = "Write test to log file failed";
break;
}
pOption->valid = TRUE;
LOG ("Option %s set to %s (full path %s)", AEWF_OPTION_LOG, pOption->p_value, pAewf->pLogPath);
}
if (strcmp (pOption->p_key, AEWF_OPTION_STATS) == 0)
{
pAewf->pStatsPath = realpath (pOption->p_value, NULL);
if (pAewf->pStatsPath == NULL)
{
pError = "The given stats path does not exist";
LOG ("Stats path %s not found", pOption->p_value);
break;
}
pOption->valid = TRUE;
LOG ("Option %s set to %s (full path %s)", AEWF_OPTION_STATS, pOption->p_value, pAewf->pLogPath);
}
else TEST_OPTION_UINT64 (AEWF_OPTION_MAXOPENSEGMENTS, MaxOpenSegments)
else TEST_OPTION_UINT64 (AEWF_OPTION_TABLECACHE , MaxTableCache)
else TEST_OPTION_UINT64 (AEWF_OPTION_STATSREFRESH , StatsRefresh)
else TEST_OPTION_UINT64 (AEWF_OPTION_THREADS , Threads)
}
#undef TEST_OPTION_UINT64
if (pError)
{
*ppError = strdup (pError);
rc = AEWF_OPTIONS_ERROR;
}
LOG ("Ret - rc=%d, error=%s", rc, *ppError);
return rc;
}
static int AewfGetInfofileContent (void *pHandle, const char **ppInfoBuf)
{
t_pAewf pAewf = (t_pAewf) pHandle;
char *pInfo;
LOG ("Called");
pInfo = strdup (pAewf->pInfo);
if (pInfo == NULL)
return AEWF_MEMALLOC_FAILED;
*ppInfoBuf = pInfo;
LOG ("Ret - %d bytes of info", strlen(pInfo)+1);
return AEWF_OK;
}
static const char* AewfGetErrorMessage (int ErrNum)
{
const char *pMsg;
#define ADD_ERR(AewfErrCode) \
case AewfErrCode: pMsg = #AewfErrCode; \
break;
switch (ErrNum)
{
ADD_ERR (AEWF_OK)
ADD_ERR (AEWF_MEMALLOC_FAILED)
ADD_ERR (AEWF_READ_BEYOND_END_OF_IMAGE)
ADD_ERR (AEWF_OPTIONS_ERROR)
ADD_ERR (AEWF_CANNOT_OPEN_LOGFILE)
ADD_ERR (AEWF_FILE_OPEN_FAILED)
ADD_ERR (AEWF_FILE_CLOSE_FAILED)
ADD_ERR (AEWF_FILE_SEEK_FAILED)
ADD_ERR (AEWF_FILE_READ_FAILED)
ADD_ERR (AEWF_READFILE_BAD_MEM)
// ADD_ERR (AEWF_MISSING_SEGMENT_NUMBER)
// ADD_ERR (AEWF_DUPLICATE_SEGMENT_NUMBER)
case AEWF_MISSING_SEGMENT_NUMBER:
pMsg = "Missing segment number. The list of EWF segment files is incomplete. One or "
"more segment numbers are missing.";
break;
case AEWF_DUPLICATE_SEGMENT_NUMBER:
pMsg = "Duplicate segment number. The list of EWF segment files contains duplicate segment "
"numbers. Maybe you accidentally specified the segment files of more than just one EWF image.";
break;
ADD_ERR (AEWF_WRONG_SEGMENT_FILE_COUNT)
ADD_ERR (AEWF_VOLUME_MUST_PRECEDE_TABLES)
ADD_ERR (AEWF_SECTORS_MUST_PRECEDE_TABLES)
// ADD_ERR (AEWF_WRONG_CHUNK_COUNT)
case AEWF_WRONG_CHUNK_COUNT:
pMsg = "Wrong chunk count. Some segment files seem to be missing. Perhaps you specified .E01 "
"instead of .E?? or the segment files continue beyond extension .EZZ.";
break;
ADD_ERR (AEWF_CHUNK_NOT_FOUND)
ADD_ERR (AEWF_VOLUME_MISSING)
ADD_ERR (AEWF_ERROR_EWF_TABLE_NOT_READY)
ADD_ERR (AEWF_ERROR_EWF_SEGMENT_NOT_READY)
ADD_ERR (AEWF_CHUNK_TOO_BIG)
ADD_ERR (AEWF_UNCOMPRESS_FAILED)
ADD_ERR (AEWF_BAD_UNCOMPRESSED_LENGTH)
ADD_ERR (AEWF_CHUNK_CRC_ERROR)
ADD_ERR (AEWF_ERROR_IN_CHUNK_NUMBER)
ADD_ERR (AEWF_VASPRINTF_FAILED)
ADD_ERR (AEWF_UNCOMPRESS_HEADER_FAILED)
ADD_ERR (AEWF_ASPRINTF_FAILED)
ADD_ERR (AEWF_CHUNK_LENGTH_ZERO)
ADD_ERR (AEWF_NEGATIVE_SEEK)
ADD_ERR (AEWF_ERROR_EIO_END)
ADD_ERR (AEWF_ERROR_PTHREAD)
ADD_ERR (AEWF_WRONG_CHUNK_CALCULATION)
default:
pMsg = "Unknown error";
}
#undef ARR_ERR
return pMsg;
}
static int AewfFreeBuffer (void *pBuf)
{
free (pBuf);
return AEWF_OK;
}
// ------------------------------------
// LibXmount_Input API implementation
// ------------------------------------
uint8_t LibXmount_Input_GetApiVersion ()
{
return LIBXMOUNT_INPUT_API_VERSION;
}
const char* LibXmount_Input_GetSupportedFormats ()
{
return "aewf\0\0"; //lint !e840 Use of nul character in a string literal
}
void LibXmount_Input_GetFunctions (ts_LibXmountInputFunctions *pFunctions)
{
pFunctions->CreateHandle = &AewfCreateHandle;
pFunctions->DestroyHandle = &AewfDestroyHandle;
pFunctions->Open = &AewfOpen;
pFunctions->Close = &AewfClose;
pFunctions->Size = &AewfSize;
pFunctions->Read = &AewfRead;
pFunctions->OptionsHelp = &AewfOptionsHelp;
pFunctions->OptionsParse = &AewfOptionsParse;
pFunctions->GetInfofileContent = &AewfGetInfofileContent;
pFunctions->GetErrorMessage = &AewfGetErrorMessage;
pFunctions->FreeBuffer = &AewfFreeBuffer;
}
// -----------------------------------------------------
// Small main routine for testing
// It converts an EWF file into dd
// -----------------------------------------------------
#ifdef AEWF_STANDALONE
#define PRINT_ERROR_AND_EXIT(...) \
{ \
printf (__VA_ARGS__); \
exit (1); \
}
int ParseOptions (t_pAewf pAewf, char *pOptions)
{
pts_LibXmountOptions pOptionArr;
pts_LibXmountOptions *ppOptionArr;
int OptionCount;
char *pSep;
char *pEqual;
char *pTmp;
const char *pError;
char *pOpt;
int rc;
if (pOptions == NULL)
return AEWF_OK;
if (*pOptions == '\0')
return AEWF_OK;
if (*pOptions == ',')
return AEWF_OPTIONS_ERROR;
if (pOptions[strlen(pOptions)-1] == ',')
return AEWF_OPTIONS_ERROR;
pOpt = strdup (pOptions);
// Count number of comma separated options
OptionCount = 1;
pTmp = pOpt;
while ((pTmp = strchr (pTmp, ',')) != NULL)
{
OptionCount++;
pTmp++;
}
// Create and fill option array
pOptionArr = (pts_LibXmountOptions) malloc (OptionCount * sizeof(ts_LibXmountOptions));
if (pOptionArr == NULL)
PRINT_ERROR_AND_EXIT ("Cannot allocate pOptionArr");
memset (pOptionArr, 0, OptionCount * sizeof(ts_LibXmountOptions));
pTmp = pOpt;
for (int i=0; i<OptionCount; i++)
{
pOptionArr[i].p_key = pTmp;
pSep = strchr (pTmp, ',');
if (pSep)
*pSep ='\0';
pEqual = strchr (pTmp, '=');
if (pEqual)
{
*pEqual = '\0';
pOptionArr[i].p_value = pEqual+1;
}
if (pSep != NULL)
pTmp = pSep+1;
}
// Create pointer array and call AEWF parse function
ppOptionArr = (pts_LibXmountOptions *)malloc (OptionCount*sizeof (pts_LibXmountOptions));
if (ppOptionArr == NULL)
PRINT_ERROR_AND_EXIT ("Cannot allocate ppOptionArr");
for (int i=0; i<OptionCount; i++)
ppOptionArr[i] = &pOptionArr[i];
rc = AewfOptionsParse ((void*) pAewf, OptionCount, ppOptionArr, &pError);
free (ppOptionArr);
free ( pOptionArr);
free ( pOpt);
if (pError)
PRINT_ERROR_AND_EXIT ("Error while setting options: %s", pError);
CHK (rc)
return AEWF_OK;
}
int main(int argc, const char *argv[])
{
t_pAewf pAewf=NULL;
uint64_t TotalSize;
uint64_t Remaining;
uint64_t ToRead;
uint64_t Read;
uint64_t Pos;
unsigned int BuffSize = 13*65536; // A multiple of chunk size for good performance
char Buff[BuffSize];
FILE *pFile;
int Percent;
int PercentOld;
int rc;
int Errno;
char *pOptions = NULL;
const char *pHelp;
const char *pInfoBuff;
#ifdef CREATE_REVERSE_FILE
FILE *pFileRev;
uint64_t PosRev;
#ifdef REVERSE_FILE_USES_SEPARATE_HANDLE
t_pAewf pAewfRev;
#else
#define pAewfRev pAewf
#endif
#endif
setbuf(stdout, NULL);
setbuf(stderr, NULL);
(void) setlocale (LC_ALL, "");
printf ("EWF to DD converter - result file is named dd\n");
printf (" Result file is named dd");
#ifdef CREATE_REVERSE_FILE
printf ("; Also creates a backwards read file named rev");
#ifdef REVERSE_FILE_USES_SEPARATE_HANDLE
printf ("; Uses separate AEWF handle for reverse file");
#else
printf ("; Uses the same AEWF handle for reverse file");
#endif
#endif
printf ("\n");
if (argc < 2)
{
(void) AewfOptionsHelp (&pHelp);
printf ("Usage: %s <EWF segment file 1> <EWF segment file 2> <...> [-comma_separated_options]\n", argv[0]);
printf ("Possible options:\n%s\n", pHelp);
printf ("The output file will be named dd.\n");
CHK (AewfFreeBuffer ((void*) pHelp))
exit (1);
}
if (argv[argc-1][0] == '-')
{
pOptions = strdup (&(argv[argc-1][1]));
argc--;
}
rc = AewfCreateHandle ((void**) &pAewf, "aewf", LOG_STDOUT);
if (rc != AEWF_OK)
PRINT_ERROR_AND_EXIT ("Cannot create handle, rc=%d\n", rc)
if (pOptions)
CHK (ParseOptions(pAewf, pOptions))
rc = AewfOpen (pAewf, &argv[1], argc-1);
if (rc != AEWF_OK)
PRINT_ERROR_AND_EXIT ("Cannot open EWF files, rc=%d\n", rc)
#if defined(CREATE_REVERSE_FILE) && defined(REVERSE_FILE_USES_SEPARATE_HANDLE)
rc = AewfCreateHandle ((void**) &pAewfRev, "aewf", LOG_STDOUT);
if (rc != AEWF_OK)
PRINT_ERROR_AND_EXIT ("Cannot create reverse handle, rc=%d\n", rc)
if (pOptions)
CHK (ParseOptions (pAewfRev, pOptions))
rc = AewfOpen (pAewfRev, &argv[1], argc-1);
if (rc != AEWF_OK)
PRINT_ERROR_AND_EXIT ("Cannot open EWF files, rc=%d\n", rc)
#endif
CHK (AewfGetInfofileContent ((void*) pAewf, &pInfoBuff))
if (pInfoBuff)
printf ("Contents of info buffer:\n%s\n", pInfoBuff);
CHK (AewfFreeBuffer ((void*) pInfoBuff))
CHK (AewfSize (pAewf, &TotalSize))
printf ("Total size: %" PRIu64 " bytes\n", TotalSize);
pFile = fopen ("dd", "w");
if (pFile == NULL)
PRINT_ERROR_AND_EXIT("Cannot open destination file\n");
#ifdef CREATE_REVERSE_FILE
pFileRev = fopen ("rev", "w");
if (pFileRev == NULL)
PRINT_ERROR_AND_EXIT("Cannot open reverse destination file\n");
PosRev = TotalSize;
#endif
Remaining = TotalSize;
Pos = 0;
PercentOld = -1;
Errno = 0;
while (Remaining)
{
// LOG ("Pos %" PRIu64 " -- Remaining %" PRIu64 " ", Pos, Remaining);
ToRead = GETMIN (Remaining, BuffSize);
rc = AewfRead ((void*) pAewf, &Buff[0], Pos, ToRead, &Read, &Errno);
if ((rc != AEWF_OK) || (Errno != 0))
PRINT_ERROR_AND_EXIT("Error %d while calling AewfRead (Errno %d)\n", rc, Errno);
if (Read != ToRead)
PRINT_ERROR_AND_EXIT("Only %" PRIu64 " out of %" PRIu64 " bytes read\n", Read, ToRead);
if (fwrite (Buff, Read, 1, pFile) != 1)
PRINT_ERROR_AND_EXIT("Could not write to destination file\n");
Remaining -= ToRead;
Pos += ToRead;
#ifdef CREATE_REVERSE_FILE
PosRev -= ToRead;
rc = AewfRead ((void*) pAewfRev, &Buff[0], PosRev, ToRead, &Read, &Errno);
if ((rc != AEWF_OK) || (Errno != 0))
PRINT_ERROR_AND_EXIT("Error %d while reverse calling AewfRead (Errno %d)\n", rc, Errno);
if (Read != ToRead)
PRINT_ERROR_AND_EXIT("Only %" PRIu64 " out of %" PRIu64 " bytes read from rev file\n", Read, ToRead);
if (fseeko (pFileRev, PosRev, SEEK_SET))
return AEWF_FILE_SEEK_FAILED;
if (fwrite (Buff, Read, 1, pFileRev) != 1)
PRINT_ERROR_AND_EXIT("Could not write to reverse destination file\n");
#endif
Percent = (100*Pos) / TotalSize;
if (Percent != PercentOld)
{
printf ("\r%d%% done...", Percent);
PercentOld = Percent;
}
}
if (AewfClose (pAewf))
PRINT_ERROR_AND_EXIT("Error while closing AEWF files\n");
if (AewfDestroyHandle ((void**)&pAewf))
PRINT_ERROR_AND_EXIT("Error while destroying AEWF handle\n");
if (fclose (pFile))
PRINT_ERROR_AND_EXIT ("Error while closing destination file\n");
#ifdef CREATE_REVERSE_FILE
#ifdef REVERSE_FILE_USES_SEPARATE_HANDLE
if (AewfClose (pAewfRev))
PRINT_ERROR_AND_EXIT("Error while closing reverse AEWF files\n");
if (AewfDestroyHandle ((void**)&pAewfRev))
PRINT_ERROR_AND_EXIT("Error while destroying reverse AEWF handle\n");
#endif
if (fclose (pFileRev))
PRINT_ERROR_AND_EXIT ("Error while closing reverse destination file\n");
#endif
printf ("\n");
return 0;
}
#endif

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