Exemplo n.º 1
0
int FilePath::discardLeadingRelSegments()
{
    int count = 0;
    bool didSeg = true;
    do
    {
        OovString seg = getPathSegment(0);
        if(seg.compare("..") == 0)
        {
            CHECKSIZE(__FILE__, __LINE__, size(), 3);
            pathStdStr().erase(0, 3);
            count++;
        }
        else if(seg.compare(".") == 0)
        {
            CHECKSIZE(__FILE__, __LINE__, size(), 2);
            pathStdStr().erase(0, 2);
        }
        else
        {
            didSeg = false;
        }
    } while(didSeg);
    return count;
}
Exemplo n.º 2
0
void FilePathRemovePathSep(std::string &path, size_t pos)
{
    CHECKSIZE(__FILE__, __LINE__, path.size(), pos);
    if(path[pos] == '/' || path[pos] == '\\' )
    {
        CHECKSIZE(__FILE__, __LINE__, path.size(), pos);
        path.erase(path.begin() + pos);
    }
}
Exemplo n.º 3
0
static int
check_cg_offsets(struct cg *cg) {
	char *base = (char*)cg,
		*end = ((char*)cg) + sblock.fs_bsize;;

#define CHECKSIZE(x) (((x) < 0) || \
		((x) > sblock.fs_bsize) || \
		(base + (x) > end))
	if (CHECKSIZE(cg->cg_btotoff)) {
		pfatal("CG:  block total offset out of range (%d)\n", cg->cg_btotoff);
		return 0;
	}

	if ((unsigned int)sblock.fs_cpg > INT_MAX / sizeof(int32_t)) {
		pfatal("CG:  block total array size overflows\n");
		return 0;
	}

	if (CHECKSIZE(sblock.fs_cpg * sizeof(int32_t))) {
		pfatal("CG:  block total arrays out of bounds\n");
		return 0;
	}

	if (CHECKSIZE(cg->cg_boff)) {
		pfatal("CG:  free block positions out of range (%d)\n", cg->cg_boff);
		return 0;
	}

	if ((unsigned int)sblock.fs_nrpos > INT_MAX / sizeof(int16_t)) {
		pfatal("CG:  free block array size overflows\n");
		return 0;
	}

	if (CHECKSIZE(sblock.fs_nrpos * sizeof(int16_t))) {
		pfatal("CG:  free block array out of bounds\n");
		return 0;
	}

	if (CHECKSIZE(cg->cg_clustersumoff)) {
		pfatal("CG:  cluster sum array offset out of range (%d)\n", cg->cg_clustersumoff);
		return 0;
	}
#undef CHECKSIZE

	if ((unsigned int)sblock.fs_nrpos > INT_MAX / (unsigned int)sblock.fs_cpg) {
		pfatal("CG:  nrpos * cpg overflows\n");
		return 0;
	}

	return 1;
}
Exemplo n.º 4
0
void FilePath::discardTail(size_t pos)
{
    // Keep the end sep so that this is still indicated as a directory.
    if(FilePathIsPathSep(pathStdStr(), pos))
    {
        CHECKSIZE(__FILE__, __LINE__, size(), pos+1);
        pathStdStr().erase(pos+1);
    }
    else
    {
        CHECKSIZE(__FILE__, __LINE__, size(), pos);
        pathStdStr().erase(pos);
    }
}
TiffEntryBE::TiffEntryBE(FileMap* f, uint32 offset) : mDataSwapped(false) {
  type = TIFF_UNDEFINED;  // We set type to undefined to avoid debug assertion errors.
  data = f->getDataWrt(offset);
  tag = (TiffTag)getShort();
  data += 2;
  TiffDataType _type = (TiffDataType)getShort();
  data += 2;
  count = getInt();
  type = _type;         //Now we can set it to the proper type

  if (type > 13)
    ThrowTPE("Error reading TIFF structure. Unknown Type 0x%x encountered.", type);
  uint32 bytesize = count << datashifts[type];
  if (bytesize <= 4) {
    data = f->getDataWrt(offset + 8);
  } else { // offset
    data = f->getDataWrt(offset + 8);
    data_offset = (unsigned int)data[0] << 24 | (unsigned int)data[1] << 16 | (unsigned int)data[2] << 8 | (unsigned int)data[3];
    CHECKSIZE(data_offset + bytesize);
    data = f->getDataWrt(data_offset);
  }
#ifdef _DEBUG
  debug_intVal = 0xC0CAC01A;
  debug_floatVal = sqrtf(-1);

  if (type == TIFF_LONG || type == TIFF_SHORT)
    debug_intVal = getInt();
  if (type == TIFF_FLOAT || type == TIFF_DOUBLE)
    debug_floatVal = getFloat();
#endif
}
Exemplo n.º 6
0
void TiffEntry::fetchData() {
  FileMap *f = file; // CHECKSIZE uses f
  if(file) {
    uint32 bytesize = count << datashifts[type];
    CHECKSIZE(data_offset + bytesize);
    data = file->getDataWrt(data_offset);
  }
}
Exemplo n.º 7
0
void FilePath::discardMatchingHead(OovStringRef const pathPart)
{
    std::string part(pathPart);
    if(pathStdStr().compare(0, part.length(), part) == 0)
    {
        CHECKSIZE(__FILE__, __LINE__, size(), part.length());
        pathStdStr().erase(0, part.length());
    }
}
Exemplo n.º 8
0
void FilePath::appendPathAtPos(OovStringRef const pathPart, size_t pos)
{
    char const *pp = pathPart;
    if(pos != std::string::npos)
    {
        if(FilePathIsPathSep(pp, 0))
            pp++;
        if(FilePathIsPathSep(pathStdStr(), pos))
        {
            CHECKSIZE(__FILE__, __LINE__, size(), pos+1);
            pathStdStr().erase(pos+1);
        }
        else
        {
            CHECKSIZE(__FILE__, __LINE__, size(), pos);
            pathStdStr().erase(pos);
        }
    }
    pathStdStr().append(pp);
}
template <typename T> void f() {
  std::vector<T> v;
  if (v.size())
    ;
  // CHECK-MESSAGES: :[[@LINE-2]]:7: warning: The 'empty' method should be used
  // CHECK-FIXES: {{^  }}if (!v.empty()){{$}}
  // CHECK-FIXES-NEXT: ;
  CHECKSIZE(v);
  // CHECK-MESSAGES: :[[@LINE-1]]:13: warning: The 'empty' method should be used
  // CHECK-MESSAGES: CHECKSIZE(v);
}
Exemplo n.º 10
0
static INLINE IMG_VOID *PVRSRVTimeTraceWriteHeader(IMG_UINT32 *pui32TraceItem, IMG_UINT32 ui32Group,
							IMG_UINT32 ui32Class, IMG_UINT32 ui32Token,
							IMG_UINT32 ui32Size, IMG_UINT32 ui32Type,
							IMG_UINT32 ui32Count)
{
	/* Sanity check arg's */
	CHECKSIZE(ui32Group, PVRSRV_TRACE_GROUP_MASK);
	CHECKSIZE(ui32Class, PVRSRV_TRACE_CLASS_MASK);
	CHECKSIZE(ui32Token, PVRSRV_TRACE_TOKEN_MASK);

	CHECKSIZE(ui32Size, PVRSRV_TRACE_SIZE_MASK);
	CHECKSIZE(ui32Type, PVRSRV_TRACE_TYPE_MASK);
	CHECKSIZE(ui32Count, PVRSRV_TRACE_COUNT_MASK);

	/* Trace header */
	pui32TraceItem[PVRSRV_TRACE_HEADER] = WRITE_HEADER(GROUP, ui32Group);
	pui32TraceItem[PVRSRV_TRACE_HEADER] |= WRITE_HEADER(CLASS, ui32Class);
	pui32TraceItem[PVRSRV_TRACE_HEADER] |= WRITE_HEADER(TOKEN, ui32Token);

	/* Data header */
	pui32TraceItem[PVRSRV_TRACE_DATA_HEADER] = WRITE_HEADER(SIZE, ui32Size);
	pui32TraceItem[PVRSRV_TRACE_DATA_HEADER] |= WRITE_HEADER(TYPE, ui32Type);
	pui32TraceItem[PVRSRV_TRACE_DATA_HEADER] |= WRITE_HEADER(COUNT, ui32Count);

	pui32TraceItem[PVRSRV_TRACE_TIMESTAMP] = OSFuncHighResTimerGetus(g_psTimer);
	pui32TraceItem[PVRSRV_TRACE_HOSTUID] = g_ui32HostUID++;

	return ui32Size?((IMG_VOID *) &pui32TraceItem[PVRSRV_TRACE_DATA_PAYLOAD]):NULL;
}
Exemplo n.º 11
0
void TiffParser::parseData() {
    const unsigned char* data = mInput->getData(0);
    if (mInput->getSize() < 16)
        throw TiffParserException("Not a TIFF file (size too small)");

    if (data[0] != 0x49 || data[1] != 0x49) {
        tiff_endian = big;
        if (data[0] != 0x4D || data[1] != 0x4D)
            throw TiffParserException("Not a TIFF file (ID)");

        if (data[3] != 42 && data[2] != 0x4f) // ORF sometimes has 0x4f, Lovely!
            throw TiffParserException("Not a TIFF file (magic 42)");
    } else {
        tiff_endian = little;
        if (data[2] != 42 && data[2] != 0x52 && data[2] != 0x55) // ORF has 0x52, RW2 0x55 - Brillant!
            throw TiffParserException("Not a TIFF file (magic 42)");
    }

    if (mRootIFD)
        delete mRootIFD;

    if (tiff_endian == host_endian)
        mRootIFD = new TiffIFD();
    else
        mRootIFD = new TiffIFDBE();

    uint32 nextIFD;
    data = mInput->getData(4);
    if (tiff_endian == host_endian) {
        nextIFD = *(int*)data;
    } else {
        nextIFD = (unsigned int)data[0] << 24 | (unsigned int)data[1] << 16 | (unsigned int)data[2] << 8 | (unsigned int)data[3];
    }
    while (nextIFD) {
        CHECKSIZE(nextIFD);

        if (tiff_endian == host_endian)
            mRootIFD->mSubIFD.push_back(new TiffIFD(mInput, nextIFD));
        else
            mRootIFD->mSubIFD.push_back(new TiffIFDBE(mInput, nextIFD));

        nextIFD = mRootIFD->mSubIFD.back()->getNextIFD();
    }
}
Exemplo n.º 12
0
void TiffParserHeaderless::parseData(uint32 firstIfdOffset) {
  if (mInput->getSize() < 12)
    throw TiffParserException("Not a TIFF file (size too small)");

  if (tiff_endian == host_endian)
    mRootIFD = new TiffIFD();
  else
    mRootIFD = new TiffIFDBE();

  uint32 nextIFD = firstIfdOffset;
  do {
    CHECKSIZE(nextIFD);

    if (tiff_endian == host_endian)
      mRootIFD->mSubIFD.push_back(new TiffIFD(mInput, nextIFD));
    else
      mRootIFD->mSubIFD.push_back(new TiffIFDBE(mInput, nextIFD));

    nextIFD = mRootIFD->mSubIFD.back()->getNextIFD();
  } while (nextIFD);
}
Exemplo n.º 13
0
void FilePath::discardHead(size_t pos)
{
    CHECKSIZE(__FILE__, __LINE__, size(), pos+1);
    pathStdStr().erase(0, pos+1);
}
Exemplo n.º 14
0
static void test_tab(INT nMinTabWidth)
{
    HWND hwTab;
    RECT rTab;
    HIMAGELIST himl = ImageList_Create(21, 21, ILC_COLOR, 3, 4);
    SIZE size;
    HDC hdc;
    HFONT hOldFont;
    INT i, dpi, exp;

    hwTab = create_tabcontrol(TCS_FIXEDWIDTH, TCIF_TEXT|TCIF_IMAGE);
    SendMessage(hwTab, TCM_SETMINTABWIDTH, 0, nMinTabWidth);
    /* Get System default MinTabWidth */
    if (nMinTabWidth < 0)
        nMinTabWidth = SendMessage(hwTab, TCM_SETMINTABWIDTH, 0, nMinTabWidth);

    hdc = GetDC(hwTab);
    dpi = GetDeviceCaps(hdc, LOGPIXELSX);
    hOldFont = SelectObject(hdc, (HFONT)SendMessage(hwTab, WM_GETFONT, 0, 0));
    GetTextExtentPoint32A(hdc, "Tab 1", strlen("Tab 1"), &size);
    trace("Tab1 text size: size.cx=%d size.cy=%d\n", size.cx, size.cy);
    SelectObject(hdc, hOldFont);
    ReleaseDC(hwTab, hdc);

    trace ("  TCS_FIXEDWIDTH tabs no icon...\n");
    CHECKSIZE(hwTab, dpi, -1, "default width");
    TABCHECKSETSIZE(hwTab, 50, 20, 50, 20, "set size");
    TABCHECKSETSIZE(hwTab, 0, 1, 0, 1, "min size");

    SendMessage(hwTab, TCM_SETIMAGELIST, 0, (LPARAM)himl);

    trace ("  TCS_FIXEDWIDTH tabs with icon...\n");
    TABCHECKSETSIZE(hwTab, 50, 30, 50, 30, "set size > icon");
    TABCHECKSETSIZE(hwTab, 20, 20, 25, 20, "set size < icon");
    TABCHECKSETSIZE(hwTab, 0, 1, 25, 1, "min size");

    DestroyWindow (hwTab);

    hwTab = create_tabcontrol(TCS_FIXEDWIDTH | TCS_BUTTONS, TCIF_TEXT|TCIF_IMAGE);
    SendMessage(hwTab, TCM_SETMINTABWIDTH, 0, nMinTabWidth);

    hdc = GetDC(hwTab);
    dpi = GetDeviceCaps(hdc, LOGPIXELSX);
    ReleaseDC(hwTab, hdc);
    trace ("  TCS_FIXEDWIDTH buttons no icon...\n");
    CHECKSIZE(hwTab, dpi, -1, "default width");
    TABCHECKSETSIZE(hwTab, 20, 20, 20, 20, "set size 1");
    TABCHECKSETSIZE(hwTab, 10, 50, 10, 50, "set size 2");
    TABCHECKSETSIZE(hwTab, 0, 1, 0, 1, "min size");

    SendMessage(hwTab, TCM_SETIMAGELIST, 0, (LPARAM)himl);

    trace ("  TCS_FIXEDWIDTH buttons with icon...\n");
    TABCHECKSETSIZE(hwTab, 50, 30, 50, 30, "set size > icon");
    TABCHECKSETSIZE(hwTab, 20, 20, 25, 20, "set size < icon");
    TABCHECKSETSIZE(hwTab, 0, 1, 25, 1, "min size");
    SendMessage(hwTab, TCM_SETPADDING, 0, MAKELPARAM(4,4));
    TABCHECKSETSIZE(hwTab, 0, 1, 25, 1, "set padding, min size");

    DestroyWindow (hwTab);

    hwTab = create_tabcontrol(TCS_FIXEDWIDTH | TCS_BOTTOM, TCIF_TEXT|TCIF_IMAGE);
    SendMessage(hwTab, TCM_SETMINTABWIDTH, 0, nMinTabWidth);

    hdc = GetDC(hwTab);
    dpi = GetDeviceCaps(hdc, LOGPIXELSX);
    ReleaseDC(hwTab, hdc);
    trace ("  TCS_FIXEDWIDTH | TCS_BOTTOM tabs...\n");
    CHECKSIZE(hwTab, dpi, -1, "no icon, default width");

    TABCHECKSETSIZE(hwTab, 20, 20, 20, 20, "no icon, set size 1");
    TABCHECKSETSIZE(hwTab, 10, 50, 10, 50, "no icon, set size 2");
    TABCHECKSETSIZE(hwTab, 0, 1, 0, 1, "no icon, min size");

    SendMessage(hwTab, TCM_SETIMAGELIST, 0, (LPARAM)himl);

    TABCHECKSETSIZE(hwTab, 50, 30, 50, 30, "with icon, set size > icon");
    TABCHECKSETSIZE(hwTab, 20, 20, 25, 20, "with icon, set size < icon");
    TABCHECKSETSIZE(hwTab, 0, 1, 25, 1, "with icon, min size");
    SendMessage(hwTab, TCM_SETPADDING, 0, MAKELPARAM(4,4));
    TABCHECKSETSIZE(hwTab, 0, 1, 25, 1, "set padding, min size");

    DestroyWindow (hwTab);

    hwTab = create_tabcontrol(0, TCIF_TEXT|TCIF_IMAGE);
    SendMessage(hwTab, TCM_SETMINTABWIDTH, 0, nMinTabWidth);

    trace ("  non fixed width, with text...\n");
    exp = max(size.cx +TAB_PADDING_X*2, (nMinTabWidth < 0) ? DEFAULT_MIN_TAB_WIDTH : nMinTabWidth);
    SendMessage( hwTab, TCM_GETITEMRECT, 0, (LPARAM)&rTab );
    ok( rTab.right  - rTab.left == exp || broken(rTab.right  - rTab.left == DEFAULT_MIN_TAB_WIDTH),
        "no icon, default width: Expected width [%d] got [%d]\n", exp, rTab.right - rTab.left );

    for (i=0; i<8; i++)
    {
        INT nTabWidth = (nMinTabWidth < 0) ? TabWidthPadded(i, 2) : nMinTabWidth;

        SendMessage(hwTab, TCM_SETIMAGELIST, 0, 0);
        SendMessage(hwTab, TCM_SETPADDING, 0, MAKELPARAM(i,i));

        TABCHECKSETSIZE(hwTab, 50, 20, max(size.cx + i*2, nTabWidth), 20, "no icon, set size");
        TABCHECKSETSIZE(hwTab, 0, 1, max(size.cx + i*2, nTabWidth), 1, "no icon, min size");

        SendMessage(hwTab, TCM_SETIMAGELIST, 0, (LPARAM)himl);
        nTabWidth = (nMinTabWidth < 0) ? TabWidthPadded(i, 3) : nMinTabWidth;

        TABCHECKSETSIZE(hwTab, 50, 30, max(size.cx + 21 + i*3, nTabWidth), 30, "with icon, set size > icon");
        TABCHECKSETSIZE(hwTab, 20, 20, max(size.cx + 21 + i*3, nTabWidth), 20, "with icon, set size < icon");
        TABCHECKSETSIZE(hwTab, 0, 1, max(size.cx + 21 + i*3, nTabWidth), 1, "with icon, min size");
    }
    DestroyWindow (hwTab);

    hwTab = create_tabcontrol(0, TCIF_IMAGE);
    SendMessage(hwTab, TCM_SETMINTABWIDTH, 0, nMinTabWidth);

    trace ("  non fixed width, no text...\n");
    exp = (nMinTabWidth < 0) ? DEFAULT_MIN_TAB_WIDTH : nMinTabWidth;
    SendMessage( hwTab, TCM_GETITEMRECT, 0, (LPARAM)&rTab );
    ok( rTab.right  - rTab.left == exp || broken(rTab.right  - rTab.left == DEFAULT_MIN_TAB_WIDTH),
        "no icon, default width: Expected width [%d] got [%d]\n", exp, rTab.right - rTab.left );

    for (i=0; i<8; i++)
    {
        INT nTabWidth = (nMinTabWidth < 0) ? TabWidthPadded(i, 2) : nMinTabWidth;

        SendMessage(hwTab, TCM_SETIMAGELIST, 0, 0);
        SendMessage(hwTab, TCM_SETPADDING, 0, MAKELPARAM(i,i));

        TABCHECKSETSIZE(hwTab, 50, 20, nTabWidth, 20, "no icon, set size");
        TABCHECKSETSIZE(hwTab, 0, 1, nTabWidth, 1, "no icon, min size");

        SendMessage(hwTab, TCM_SETIMAGELIST, 0, (LPARAM)himl);
        if (i > 1 && nMinTabWidth > 0 && nMinTabWidth < DEFAULT_MIN_TAB_WIDTH)
            nTabWidth += EXTRA_ICON_PADDING *(i-1);

        TABCHECKSETSIZE(hwTab, 50, 30, nTabWidth, 30, "with icon, set size > icon");
        TABCHECKSETSIZE(hwTab, 20, 20, nTabWidth, 20, "with icon, set size < icon");
        TABCHECKSETSIZE(hwTab, 0, 1, nTabWidth, 1, "with icon, min size");
    }

    DestroyWindow (hwTab);

    ImageList_Destroy(himl);
    DeleteObject(hFont);
}
Exemplo n.º 15
0
unsigned char mediasize2pxlenum(int pixel_h, int pixel_v)
{
  CHECKSIZE(pixel_h, pixel_v, 612, 792,  eLetterPaper)    ;
  CHECKSIZE(pixel_h, pixel_v, 612, 1008, eLegalPaper)     ;
  CHECKSIZE(pixel_h, pixel_v, 595, 842,  eA4Paper)        ;
  CHECKSIZE(pixel_h, pixel_v, 522, 756,  eExecPaper)      ;
  CHECKSIZE(pixel_h, pixel_v, 792, 1224, eLedgerPaper)    ; /* Ledge is 11x17 landscape */
  CHECKSIZE(pixel_h, pixel_v, 842, 1191, eA3Paper)        ;
  CHECKSIZE(pixel_h, pixel_v, 297, 684,  eCOM10Envelope)  ;
  CHECKSIZE(pixel_h, pixel_v, 279, 540,  eMonarchEnvelope);
  CHECKSIZE(pixel_h, pixel_v, 459, 649,  eC5Envelope)     ;
  CHECKSIZE(pixel_h, pixel_v, 312, 624,  eDLEnvelope)     ;
  CHECKSIZE(pixel_h, pixel_v, 729, 1032, eJB4Paper)       ;
  CHECKSIZE(pixel_h, pixel_v, 516, 729,  eJB5Paper)       ;
  CHECKSIZE(pixel_h, pixel_v, 499, 709,  eB5Paper)        ;
  CHECKSIZE(pixel_h, pixel_v, 499, 709,  eB5Envelope)     ;
  CHECKSIZE(pixel_h, pixel_v, 282, 420,  eJPostcard)      ;
  CHECKSIZE(pixel_h, pixel_v, 420, 564,  eJDoublePostcard);
  CHECKSIZE(pixel_h, pixel_v, 420, 595,  eA5Paper)        ;
  CHECKSIZE(pixel_h, pixel_v, 297, 420,  eA6Paper)        ;
  CHECKSIZE(pixel_h, pixel_v, 363, 516,  eJB6Paper)       ;
  CHECKSIZE(pixel_h, pixel_v, 774, 1114, eJIS8K)          ;
  CHECKSIZE(pixel_h, pixel_v, 558, 774,  eJIS16K)         ;
  CHECKSIZE(pixel_h, pixel_v, 612, 935,  eJISExec)        ;

  return eDefault;
}
Exemplo n.º 16
0
void DngDecoderSlices::decodeSlice(DngDecoderThread* t) {
  if (compression == 7) {
    while (!t->slices.empty()) {
      LJpegPlain l(mFile, mRaw);
      l.mDNGCompatible = mFixLjpeg;
      DngSliceElement e = t->slices.front();
      l.mUseBigtable = e.mUseBigtable;
      t->slices.pop();
      try {
        l.startDecoder(e.byteOffset, e.byteCount, e.offX, e.offY);
      } catch (RawDecoderException &err) {
        mRaw->setError(err.what());
      } catch (IOException &err) {
        mRaw->setError(err.what());
      }
    }
    /* Lossy DNG */
  } else if (compression == 0x884c) {
    /* Each slice is a JPEG image */
    struct jpeg_decompress_struct dinfo;
    struct jpeg_error_mgr jerr;
    while (!t->slices.empty()) {
      DngSliceElement e = t->slices.front();
      t->slices.pop();
      uchar8 *complete_buffer = NULL;
      JSAMPARRAY buffer = (JSAMPARRAY)malloc(sizeof(JSAMPROW));

      try {
        uint32 size = mFile->getSize();
        jpeg_create_decompress(&dinfo);
        dinfo.err = jpeg_std_error(&jerr);
        jerr.error_exit = my_error_throw;
        CHECKSIZE(e.byteOffset);
        CHECKSIZE(e.byteOffset+e.byteCount);
        JPEG_MEMSRC(&dinfo, (unsigned char*)mFile->getData(e.byteOffset, e.byteCount), e.byteCount);

        if (JPEG_HEADER_OK != jpeg_read_header(&dinfo, TRUE))
          ThrowRDE("DngDecoderSlices: Unable to read JPEG header");

        jpeg_start_decompress(&dinfo);
        if (dinfo.output_components != (int)mRaw->getCpp())
          ThrowRDE("DngDecoderSlices: Component count doesn't match");
        int row_stride = dinfo.output_width * dinfo.output_components;
        int pic_size = dinfo.output_height * row_stride;
        complete_buffer = (uchar8*)_aligned_malloc(pic_size, 16);
        while (dinfo.output_scanline < dinfo.output_height) {
          buffer[0] = (JSAMPROW)(&complete_buffer[dinfo.output_scanline*row_stride]);
          if (0 == jpeg_read_scanlines(&dinfo, buffer, 1))
            ThrowRDE("DngDecoderSlices: JPEG Error while decompressing image.");
        }
        jpeg_finish_decompress(&dinfo);

        // Now the image is decoded, and we copy the image data
        int copy_w = min(mRaw->dim.x-e.offX, dinfo.output_width);
        int copy_h = min(mRaw->dim.y-e.offY, dinfo.output_height);
        for (int y = 0; y < copy_h; y++) {
          uchar8* src = &complete_buffer[row_stride*y];
          ushort16* dst = (ushort16*)mRaw->getData(e.offX, y+e.offY);
          for (int x = 0; x < copy_w; x++) {
            for (int c=0; c < dinfo.output_components; c++)
              *dst++ = (*src++);
          }
        }
      } catch (RawDecoderException &err) {
        mRaw->setError(err.what());
      } catch (IOException &err) {
        mRaw->setError(err.what());
      }
      free(buffer);
      if (complete_buffer)
        _aligned_free(complete_buffer);
      jpeg_destroy_decompress(&dinfo);
    }
  }
  else
    mRaw->setError("DngDecoderSlices: Unknown compression");
}
Exemplo n.º 17
0
void
dotest () 
{
	long tmp;

    // materialize a sequence on the stack:
    seq1_t	s1;
    Sequence<long>	s2(o_ref->vseq);
	Sequence<long>	s3 = s2;

    // SEQ OPS

	CHECKLSIZE(s1,0);
	CHECKLSIZE(s2,0);
	CHECKLSIZE(s3,0);
	CHECKSIZE(o_ref,a_seq,0);
	CHECKSIZE(o_ref,vseq,0);

	s1.append_elt(); // uninit
	s1.append_elt(33);
	CHECKLSIZE(s1,2);
	// remove the uninitialized one and renumber
	s1.delete_elt(0);
	tmp = s1.get_elt(0);
	dassert(tmp==33);
	CHECKLSIZE(s1,1);

	// assignment operator
	s3 = s1;
	CHECKLSIZE(s3,1);
	s3.append_elt(44);
	s3.append_elt();
	CHECKLSIZE(s3,3);


	// repeat test with persistent object
	o_ref.update()->vseq.append_elt(); // uninit
	o_ref.update()->vseq.append_elt(99); 
	CHECKSIZE(o_ref,vseq,2);
	// remove the uninitialized one and renumber
	o_ref.update()->vseq.delete_elt(0);
	tmp = o_ref->vseq.get_elt(0);
	dassert(tmp==99);
	CHECKSIZE(o_ref,vseq,1);
	o_ref.update()->vseq.append_elt(); // uninit
	o_ref.update()->vseq.append_elt(); // uninit
	o_ref.update()->vseq.append_elt(); // uninit
	o_ref.update()->vseq.append_elt(99); 
	o_ref.update()->vseq.append_elt(99); 
	o_ref.update()->vseq.append_elt(99); 
	CHECKSIZE(o_ref,vseq,7);
	{
		int i;
		for(i=0; i<4; i++) {
			// write_elt and operator[]
			o_ref.update()->vseq.write_elt(i) = o_ref->vseq[5];
		}
		for(i=0; i<7; i++) {
			// check
			dassert(o_ref->vseq[i] == 99);
		}
		for(i=0; i<7; i++) {
			// write_elt 
			o_ref.update()->vseq.write_elt(i) = i;
		}
		for(i=0; i<7; i++) {
			// operator[]
			dassert(o_ref->vseq[i] == i);
		}
	}

	// assignment operator
	s3 = o_ref->vseq;
	CHECKLSIZE(s3,7);
	{
		size_t sx = s1.get_size();
		// how many ways can we check this???
		dassert(sx==1);
		CHECKLSIZE(s1,1);

		o_ref.update()->vseq = s1;
		CHECKLSIZE(s1,1);
		CHECKLSIZE(o_ref->vseq,sx);
		dassert(sx==1);
		CHECKLSIZE(o_ref->vseq,1);
	}

#ifndef NOTDEF
	// aseq : TODO: what happens to uninit ref?
	// how do you check it?

    o_ref.update()->a_seq.append_elt();  // uninitialized
    o_ref.update()->a_seq.append_elt();  // uninitialized
    o_ref.update()->a_seq.append_elt(a_ref);
	CHECKSIZE(o_ref,a_seq,3);
    { 
		if(o_ref->a_seq.get_size() == 2) {
			// these 2 are identical :
			a_ref = o_ref->a_seq.get_elt(0);
			a_ref = o_ref->a_seq[0];
			o_ref.update()->a_seq.delete_elt(0); // renumbers member [1] to [0]
			o_ref.update()->a_seq.delete_elt(0); // removes what was member [1]
		}
    }

    { long i;
	// correct but inefficient because of renumbering:
	for (i=0; (unsigned long)i < o_ref->a_seq.get_size(); i++) 
		o_ref.update()->a_seq.delete_elt(0);

	// correct and doesn't renumber elements each time:
	for (i=o_ref->a_seq.get_size()-1; i>=0; i--) 
		o_ref.update()->a_seq.delete_elt(i);
    }
#endif
}
Exemplo n.º 18
0
/**
 * Construct the DMI table.
 *
 * @returns VBox status code.
 * @param   pDevIns             The device instance.
 * @param   pTable              Where to create the DMI table.
 * @param   cbMax               The maximum size of the DMI table.
 * @param   pUuid               Pointer to the UUID to use if the DmiUuid
 *                              configuration string isn't present.
 * @param   pCfg                The handle to our config node.
 * @param   cCpus               Number of VCPUs.
 * @param   pcbDmiTables        Size of DMI data in bytes.
 * @param   pcNumDmiTables      Number of DMI tables.
 */
int FwCommonPlantDMITable(PPDMDEVINS pDevIns, uint8_t *pTable, unsigned cbMax, PCRTUUID pUuid, PCFGMNODE pCfg, uint16_t cCpus, uint16_t *pcbDmiTables, uint16_t *pcNumDmiTables)
{
#define CHECKSIZE(cbWant) \
    { \
        size_t cbNeed = (size_t)(pszStr + cbWant - (char *)pTable) + 5; /* +1 for strtab terminator +4 for end-of-table entry */ \
        if (cbNeed > cbMax) \
        { \
            if (fHideErrors) \
            { \
                LogRel(("One of the DMI strings is too long -- using default DMI data!\n")); \
                continue; \
            } \
            return PDMDevHlpVMSetError(pDevIns, VERR_TOO_MUCH_DATA, RT_SRC_POS, \
                                       N_("One of the DMI strings is too long. Check all bios/Dmi* configuration entries. At least %zu bytes are needed but there is no space for more than %d bytes"), cbNeed, cbMax); \
        } \
    }

#define READCFGSTRDEF(variable, name, default_value) \
    { \
        if (fForceDefault) \
            pszTmp = default_value; \
        else \
        { \
            rc = CFGMR3QueryStringDef(pCfg, name, szBuf, sizeof(szBuf), default_value); \
            if (RT_FAILURE(rc)) \
            { \
                if (fHideErrors) \
                { \
                    LogRel(("Configuration error: Querying \"" name "\" as a string failed -- using default DMI data!\n")); \
                    continue; \
                } \
                return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS, \
                                           N_("Configuration error: Querying \"" name "\" as a string failed")); \
            } \
            else if (!strcmp(szBuf, "<EMPTY>")) \
                pszTmp = ""; \
            else \
                pszTmp = szBuf; \
        } \
        if (!pszTmp[0]) \
            variable = 0; /* empty string */ \
        else \
        { \
            variable = iStrNr++; \
            size_t cStr = strlen(pszTmp) + 1; \
            CHECKSIZE(cStr); \
            memcpy(pszStr, pszTmp, cStr); \
            pszStr += cStr ; \
        } \
    }

#define READCFGSTR(variable, name) \
    READCFGSTRDEF(variable, # name, s_szDef ## name)

#define READCFGINT(variable, name) \
    { \
        if (fForceDefault) \
            variable = s_iDef ## name; \
        else \
        { \
            rc = CFGMR3QueryS32Def(pCfg, # name, & variable, s_iDef ## name); \
            if (RT_FAILURE(rc)) \
            { \
                if (fHideErrors) \
                { \
                    LogRel(("Configuration error: Querying \"" # name "\" as an int failed -- using default DMI data!\n")); \
                    continue; \
                } \
                return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS, \
                                           N_("Configuration error: Querying \"" # name "\" as an int failed")); \
            } \
        } \
    }

#define START_STRUCT(tbl)                                       \
        pszStr                       = (char *)(tbl + 1);       \
        iStrNr                       = 1;

#define TERM_STRUCT \
    { \
        *pszStr++                    = '\0'; /* terminate set of text strings */ \
        if (iStrNr == 1) \
            *pszStr++                = '\0'; /* terminate a structure without strings */ \
    }

    bool fForceDefault = false;
#ifdef VBOX_BIOS_DMI_FALLBACK
    /*
     * There will be two passes. If an error occurs during the first pass, a
     * message will be written to the release log and we fall back to default
     * DMI data and start a second pass.
     */
    bool fHideErrors = true;
#else
    /*
     * There will be one pass, every error is fatal and will prevent the VM
     * from starting.
     */
    bool fHideErrors = false;
#endif

    uint8_t fDmiUseHostInfo;
    int rc = CFGMR3QueryU8Def(pCfg, "DmiUseHostInfo", &fDmiUseHostInfo, 0);
    if (RT_FAILURE (rc))
        return PDMDEV_SET_ERROR(pDevIns, rc,
                                N_("Configuration error: Failed to read \"DmiUseHostInfo\""));

    /* Sync up with host default DMI values */
    if (fDmiUseHostInfo)
        fwCommonUseHostDMIStrings();

    uint8_t fDmiExposeMemoryTable;
    rc = CFGMR3QueryU8Def(pCfg, "DmiExposeMemoryTable", &fDmiExposeMemoryTable, 0);
    if (RT_FAILURE (rc))
        return PDMDEV_SET_ERROR(pDevIns, rc,
                                N_("Configuration error: Failed to read \"DmiExposeMemoryTable\""));
    uint8_t fDmiExposeProcessorInf;
    rc = CFGMR3QueryU8Def(pCfg, "DmiExposeProcInf", &fDmiExposeProcessorInf, 0);
    if (RT_FAILURE (rc))
        return PDMDEV_SET_ERROR(pDevIns, rc,
                                N_("Configuration error: Failed to read \"DmiExposeProcInf\""));

    for  (;; fForceDefault = true, fHideErrors = false)
    {
        int  iStrNr;
        char szBuf[256];
        char *pszStr = (char *)pTable;
        char szDmiSystemUuid[64];
        char *pszDmiSystemUuid;
        const char *pszTmp;

        if (fForceDefault)
            pszDmiSystemUuid = NULL;
        else
        {
            rc = CFGMR3QueryString(pCfg, "DmiSystemUuid", szDmiSystemUuid, sizeof(szDmiSystemUuid));
            if (rc == VERR_CFGM_VALUE_NOT_FOUND)
                pszDmiSystemUuid = NULL;
            else if (RT_FAILURE(rc))
            {
                if (fHideErrors)
                {
                    LogRel(("Configuration error: Querying \"DmiSystemUuid\" as a string failed, using default DMI data\n"));
                    continue;
                }
                return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS,
                                           N_("Configuration error: Querying \"DmiSystemUuid\" as a string failed"));
            }
            else
                pszDmiSystemUuid = szDmiSystemUuid;
        }

        /*********************************
         * DMI BIOS information (Type 0) *
         *********************************/
        PDMIBIOSINF pBIOSInf         = (PDMIBIOSINF)pszStr;
        CHECKSIZE(sizeof(*pBIOSInf));

        pszStr                       = (char *)&pBIOSInf->u8ReleaseMajor;
        pBIOSInf->header.u8Length    = RT_OFFSETOF(DMIBIOSINF, u8ReleaseMajor);

        /* don't set these fields by default for legacy compatibility */
        int iDmiBIOSReleaseMajor, iDmiBIOSReleaseMinor;
        READCFGINT(iDmiBIOSReleaseMajor, DmiBIOSReleaseMajor);
        READCFGINT(iDmiBIOSReleaseMinor, DmiBIOSReleaseMinor);
        if (iDmiBIOSReleaseMajor != 0 || iDmiBIOSReleaseMinor != 0)
        {
            pszStr = (char *)&pBIOSInf->u8FirmwareMajor;
            pBIOSInf->header.u8Length = RT_OFFSETOF(DMIBIOSINF, u8FirmwareMajor);
            pBIOSInf->u8ReleaseMajor  = iDmiBIOSReleaseMajor;
            pBIOSInf->u8ReleaseMinor  = iDmiBIOSReleaseMinor;

            int iDmiBIOSFirmwareMajor, iDmiBIOSFirmwareMinor;
            READCFGINT(iDmiBIOSFirmwareMajor, DmiBIOSFirmwareMajor);
            READCFGINT(iDmiBIOSFirmwareMinor, DmiBIOSFirmwareMinor);
            if (iDmiBIOSFirmwareMajor != 0 || iDmiBIOSFirmwareMinor != 0)
            {
                pszStr = (char *)(pBIOSInf + 1);
                pBIOSInf->header.u8Length = sizeof(DMIBIOSINF);
                pBIOSInf->u8FirmwareMajor = iDmiBIOSFirmwareMajor;
                pBIOSInf->u8FirmwareMinor = iDmiBIOSFirmwareMinor;
            }
        }

        iStrNr                       = 1;
        pBIOSInf->header.u8Type      = 0; /* BIOS Information */
        pBIOSInf->header.u16Handle   = 0x0000;
        READCFGSTR(pBIOSInf->u8Vendor,  DmiBIOSVendor);
        READCFGSTR(pBIOSInf->u8Version, DmiBIOSVersion);
        pBIOSInf->u16Start           = 0xE000;
        READCFGSTR(pBIOSInf->u8Release, DmiBIOSReleaseDate);
        pBIOSInf->u8ROMSize          = 1; /* 128K */
        pBIOSInf->u64Characteristics = RT_BIT(4)   /* ISA is supported */
                                     | RT_BIT(7)   /* PCI is supported */
                                     | RT_BIT(15)  /* Boot from CD is supported */
                                     | RT_BIT(16)  /* Selectable Boot is supported */
                                     | RT_BIT(27)  /* Int 9h, 8042 Keyboard services supported */
                                     | RT_BIT(30)  /* Int 10h, CGA/Mono Video Services supported */
                                     /* any more?? */
                                     ;
        pBIOSInf->u8CharacteristicsByte1 = RT_BIT(0)   /* ACPI is supported */
                                         /* any more?? */
                                         ;
        pBIOSInf->u8CharacteristicsByte2 = 0
                                         /* any more?? */
                                         ;
        TERM_STRUCT;

        /***********************************
         * DMI system information (Type 1) *
         ***********************************/
        PDMISYSTEMINF pSystemInf     = (PDMISYSTEMINF)pszStr;
        CHECKSIZE(sizeof(*pSystemInf));
        START_STRUCT(pSystemInf);
        pSystemInf->header.u8Type    = 1; /* System Information */
        pSystemInf->header.u8Length  = sizeof(*pSystemInf);
        pSystemInf->header.u16Handle = 0x0001;
        READCFGSTR(pSystemInf->u8Manufacturer, DmiSystemVendor);
        READCFGSTR(pSystemInf->u8ProductName,  DmiSystemProduct);
        READCFGSTR(pSystemInf->u8Version,      DmiSystemVersion);
        READCFGSTR(pSystemInf->u8SerialNumber, DmiSystemSerial);

        RTUUID uuid;
        if (pszDmiSystemUuid)
        {
            rc = RTUuidFromStr(&uuid, pszDmiSystemUuid);
            if (RT_FAILURE(rc))
            {
                if (fHideErrors)
                {
                    LogRel(("Configuration error: Invalid UUID for DMI tables specified, using default DMI data\n"));
                    continue;
                }
                return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS,
                                           N_("Configuration error: Invalid UUID for DMI tables specified"));
            }
            uuid.Gen.u32TimeLow = RT_H2BE_U32(uuid.Gen.u32TimeLow);
            uuid.Gen.u16TimeMid = RT_H2BE_U16(uuid.Gen.u16TimeMid);
            uuid.Gen.u16TimeHiAndVersion = RT_H2BE_U16(uuid.Gen.u16TimeHiAndVersion);
            pUuid = &uuid;
        }
        memcpy(pSystemInf->au8Uuid, pUuid, sizeof(RTUUID));

        pSystemInf->u8WakeupType     = 6; /* Power Switch */
        READCFGSTR(pSystemInf->u8SKUNumber, DmiSystemSKU);
        READCFGSTR(pSystemInf->u8Family, DmiSystemFamily);
        TERM_STRUCT;

        /**********************************
         * DMI board information (Type 2) *
         **********************************/
        PDMIBOARDINF pBoardInf       = (PDMIBOARDINF)pszStr;
        CHECKSIZE(sizeof(*pBoardInf));
        START_STRUCT(pBoardInf);
        int iDmiBoardBoardType;
        pBoardInf->header.u8Type     = 2; /* Board Information */
        pBoardInf->header.u8Length   = sizeof(*pBoardInf);
        pBoardInf->header.u16Handle  = 0x0008;
        READCFGSTR(pBoardInf->u8Manufacturer, DmiBoardVendor);
        READCFGSTR(pBoardInf->u8Product,      DmiBoardProduct);
        READCFGSTR(pBoardInf->u8Version,      DmiBoardVersion);
        READCFGSTR(pBoardInf->u8SerialNumber, DmiBoardSerial);
        READCFGSTR(pBoardInf->u8AssetTag,     DmiBoardAssetTag);
        pBoardInf->u8FeatureFlags    = RT_BIT(0) /* hosting board, e.g. motherboard */
                                     ;
        READCFGSTR(pBoardInf->u8LocationInChass, DmiBoardLocInChass);
        pBoardInf->u16ChassisHandle  = 0x0003; /* see type 3 */
        READCFGINT(iDmiBoardBoardType, DmiBoardBoardType);
        pBoardInf->u8BoardType = iDmiBoardBoardType;
        pBoardInf->u8cObjectHandles  = 0;

        TERM_STRUCT;

        /********************************************
         * DMI System Enclosure or Chassis (Type 3) *
         ********************************************/
        PDMICHASSIS pChassis         = (PDMICHASSIS)pszStr;
        CHECKSIZE(sizeof(*pChassis));
        pszStr                       = (char*)&pChassis->u32OEMdefined;
        iStrNr                       = 1;
#ifdef VBOX_WITH_DMI_CHASSIS
        pChassis->header.u8Type      = 3; /* System Enclosure or Chassis */
#else
        pChassis->header.u8Type      = 0x7e; /* inactive */
#endif
        pChassis->header.u8Length    = RT_OFFSETOF(DMICHASSIS, u32OEMdefined);
        pChassis->header.u16Handle   = 0x0003;
        READCFGSTR(pChassis->u8Manufacturer, DmiChassisVendor);
        int iDmiChassisType;
        READCFGINT(iDmiChassisType, DmiChassisType);
        pChassis->u8Type             = iDmiChassisType;
        READCFGSTR(pChassis->u8Version, DmiChassisVersion);
        READCFGSTR(pChassis->u8SerialNumber, DmiChassisSerial);
        READCFGSTR(pChassis->u8AssetTag, DmiChassisAssetTag);
        pChassis->u8BootupState      = 0x03; /* safe */
        pChassis->u8PowerSupplyState = 0x03; /* safe */
        pChassis->u8ThermalState     = 0x03; /* safe */
        pChassis->u8SecurityStatus   = 0x03; /* none XXX */
# if 0
        /* v2.3+, currently not supported */
        pChassis->u32OEMdefined      = 0;
        pChassis->u8Height           = 0; /* unspecified */
        pChassis->u8NumPowerChords   = 0; /* unspecified */
        pChassis->u8ContElems        = 0; /* no contained elements */
        pChassis->u8ContElemRecLen   = 0; /* no contained elements */
# endif
        TERM_STRUCT;

        /**************************************
         * DMI Processor Information (Type 4) *
         **************************************/

        /*
         * This is just a dummy processor. Should we expose the real guest CPU features
         * here? Accessing this information at this point is difficult.
         */
        char szSocket[32];
        PDMIPROCESSORINF pProcessorInf = (PDMIPROCESSORINF)pszStr;
        CHECKSIZE(sizeof(*pProcessorInf));
        START_STRUCT(pProcessorInf);
        if (fDmiExposeProcessorInf)
            pProcessorInf->header.u8Type   = 4; /* Processor Information */
        else
            pProcessorInf->header.u8Type   = 126; /* inactive structure */
        pProcessorInf->header.u8Length     = sizeof(*pProcessorInf);
        pProcessorInf->header.u16Handle    = 0x0007;
        RTStrPrintf(szSocket, sizeof(szSocket), "Socket #%u", 0);
        pProcessorInf->u8SocketDesignation = iStrNr++;
        {
            size_t cStr = strlen(szSocket) + 1;
            CHECKSIZE(cStr);
            memcpy(pszStr, szSocket, cStr);
            pszStr += cStr;
        }
        pProcessorInf->u8ProcessorType     = 0x03; /* Central Processor */
        pProcessorInf->u8ProcessorFamily   = 0xB1; /* Pentium III with Intel SpeedStep(TM) */
        READCFGSTR(pProcessorInf->u8ProcessorManufacturer, DmiProcManufacturer);

        pProcessorInf->u64ProcessorID      = UINT64_C(0x0FEBFBFF00010676);
                                             /* Ext Family ID  = 0
                                              * Ext Model ID   = 2
                                              * Processor Type = 0
                                              * Family ID      = 6
                                              * Model          = 7
                                              * Stepping       = 6
                                              * Features: FPU, VME, DE, PSE, TSC, MSR, PAE, MCE, CX8,
                                              *           APIC, SEP, MTRR, PGE, MCA, CMOV, PAT, PSE-36,
                                              *           CFLSH, DS, ACPI, MMX, FXSR, SSE, SSE2, SS */
        READCFGSTR(pProcessorInf->u8ProcessorVersion, DmiProcVersion);
        pProcessorInf->u8Voltage           = 0x02;   /* 3.3V */
        pProcessorInf->u16ExternalClock    = 0x00;   /* unknown */
        pProcessorInf->u16MaxSpeed         = 3000;   /* 3GHz */
        pProcessorInf->u16CurrentSpeed     = 3000;   /* 3GHz */
        pProcessorInf->u8Status            = RT_BIT(6)  /* CPU socket populated */
                                           | RT_BIT(0)  /* CPU enabled */
                                           ;
        pProcessorInf->u8ProcessorUpgrade  = 0x04;   /* ZIF Socket */
        pProcessorInf->u16L1CacheHandle    = 0xFFFF; /* not specified */
        pProcessorInf->u16L2CacheHandle    = 0xFFFF; /* not specified */
        pProcessorInf->u16L3CacheHandle    = 0xFFFF; /* not specified */
        pProcessorInf->u8SerialNumber      = 0;      /* not specified */
        pProcessorInf->u8AssetTag          = 0;      /* not specified */
        pProcessorInf->u8PartNumber        = 0;      /* not specified */
        pProcessorInf->u8CoreCount         = cCpus;  /*  */
        pProcessorInf->u8CoreEnabled       = cCpus;
        pProcessorInf->u8ThreadCount       = 1;
        pProcessorInf->u16ProcessorCharacteristics 
                                           = RT_BIT(2); /* 64-bit capable */
        pProcessorInf->u16ProcessorFamily2 = 0;
        TERM_STRUCT;

        /***************************************
         * DMI Physical Memory Array (Type 16) *
         ***************************************/
        uint64_t u64RamSize;
        rc = CFGMR3QueryU64(pCfg, "RamSize", &u64RamSize);
        if (RT_FAILURE (rc))
            return PDMDEV_SET_ERROR(pDevIns, rc,
                                    N_("Configuration error: Failed to read \"RamSize\""));

        PDMIRAMARRAY pMemArray = (PDMIRAMARRAY)pszStr;
        CHECKSIZE(sizeof(*pMemArray));
        START_STRUCT(pMemArray);
        if (fDmiExposeMemoryTable)
            pMemArray->header.u8Type     = 16;     /* Physical Memory Array */
        else
            pMemArray->header.u8Type     = 126;    /* inactive structure */
        pMemArray->header.u8Length       = sizeof(*pMemArray);
        pMemArray->header.u16Handle      = 0x0005;
        pMemArray->u8Location            = 0x03;   /* Motherboard */
        pMemArray->u8Use                 = 0x03;   /* System memory */
        pMemArray->u8MemErrorCorrection  = 0x01;   /* Other */
        pMemArray->u32MaxCapacity        = (uint32_t)(u64RamSize / _1K); /* RAM size in K */
        pMemArray->u16MemErrorHandle     = 0xfffe; /* No error info structure */
        pMemArray->u16NumberOfMemDevices = 1;
        TERM_STRUCT;

        /***************************************
         * DMI Memory Device (Type 17)         *
         ***************************************/
        PDMIMEMORYDEV pMemDev = (PDMIMEMORYDEV)pszStr;
        CHECKSIZE(sizeof(*pMemDev));
        START_STRUCT(pMemDev);
        if (fDmiExposeMemoryTable)
            pMemDev->header.u8Type       = 17;     /* Memory Device */
        else
            pMemDev->header.u8Type       = 126;    /* inactive structure */
        pMemDev->header.u8Length         = sizeof(*pMemDev);
        pMemDev->header.u16Handle        = 0x0006;
        pMemDev->u16PhysMemArrayHandle   = 0x0005; /* handle of array we belong to */
        pMemDev->u16MemErrHandle         = 0xfffe; /* system doesn't provide this information */
        pMemDev->u16TotalWidth           = 0xffff; /* Unknown */
        pMemDev->u16DataWidth            = 0xffff; /* Unknown */
        int16_t u16RamSizeM = (uint16_t)(u64RamSize / _1M);
        if (u16RamSizeM == 0)
            u16RamSizeM = 0x400; /* 1G */
        pMemDev->u16Size                 = u16RamSizeM; /* RAM size */
        pMemDev->u8FormFactor            = 0x09; /* DIMM */
        pMemDev->u8DeviceSet             = 0x00; /* Not part of a device set */
        READCFGSTRDEF(pMemDev->u8DeviceLocator, " ", "DIMM 0");
        READCFGSTRDEF(pMemDev->u8BankLocator, " ", "Bank 0");
        pMemDev->u8MemoryType            = 0x03; /* DRAM */
        pMemDev->u16TypeDetail           = 0;    /* Nothing special */
        pMemDev->u16Speed                = 1600; /* Unknown, shall be speed in MHz */
        READCFGSTR(pMemDev->u8Manufacturer, DmiSystemVendor);
        READCFGSTRDEF(pMemDev->u8SerialNumber, " ", "00000000");
        READCFGSTRDEF(pMemDev->u8AssetTag, " ", "00000000");
        READCFGSTRDEF(pMemDev->u8PartNumber, " ", "00000000");
        pMemDev->u8Attributes            = 0; /* Unknown */
        TERM_STRUCT;

        /*****************************
         * DMI OEM strings (Type 11) *
         *****************************/
        PDMIOEMSTRINGS pOEMStrings    = (PDMIOEMSTRINGS)pszStr;
        CHECKSIZE(sizeof(*pOEMStrings));
        START_STRUCT(pOEMStrings);
#ifdef VBOX_WITH_DMI_OEMSTRINGS
        pOEMStrings->header.u8Type    = 0xb; /* OEM Strings */
#else
        pOEMStrings->header.u8Type    = 126; /* inactive structure */
#endif
        pOEMStrings->header.u8Length  = sizeof(*pOEMStrings);
        pOEMStrings->header.u16Handle = 0x0002;
        pOEMStrings->u8Count          = 2;

        char szTmp[64];
        RTStrPrintf(szTmp, sizeof(szTmp), "vboxVer_%u.%u.%u",
                    RTBldCfgVersionMajor(), RTBldCfgVersionMinor(), RTBldCfgVersionBuild());
        READCFGSTRDEF(pOEMStrings->u8VBoxVersion, "DmiOEMVBoxVer", szTmp);
        RTStrPrintf(szTmp, sizeof(szTmp), "vboxRev_%u", RTBldCfgRevision());
        READCFGSTRDEF(pOEMStrings->u8VBoxRevision, "DmiOEMVBoxRev", szTmp);
        TERM_STRUCT;

        /*************************************
         * DMI OEM specific table (Type 128) *
         ************************************/
        PDMIOEMSPECIFIC pOEMSpecific = (PDMIOEMSPECIFIC)pszStr;
        CHECKSIZE(sizeof(*pOEMSpecific));
        START_STRUCT(pOEMSpecific);
        pOEMSpecific->header.u8Type    = 0x80; /* OEM specific */
        pOEMSpecific->header.u8Length  = sizeof(*pOEMSpecific);
        pOEMSpecific->header.u16Handle = 0x0008; /* Just next free handle */
        pOEMSpecific->u32CpuFreqKHz    = RT_H2LE_U32((uint32_t)((uint64_t)TMCpuTicksPerSecond(PDMDevHlpGetVM(pDevIns)) / 1000));
        TERM_STRUCT;

        /* End-of-table marker - includes padding to account for fixed table size. */
        PDMIHDR pEndOfTable          = (PDMIHDR)pszStr;
        pszStr                       = (char *)(pEndOfTable + 1);
        pEndOfTable->u8Type          = 0x7f;

        pEndOfTable->u8Length        = sizeof(*pEndOfTable);
        pEndOfTable->u16Handle       = 0xFEFF;
        *pcbDmiTables = ((uintptr_t)pszStr - (uintptr_t)pTable) + 2;

        /* We currently plant 10 DMI tables. Update this if tables number changed. */
        *pcNumDmiTables = 10;

        /* If more fields are added here, fix the size check in READCFGSTR */

        /* Success! */
        break;
    }

#undef READCFGSTR
#undef READCFGINT
#undef CHECKSIZE
    return VINF_SUCCESS;
}
Exemplo n.º 19
0
static void test_misc(void)
{
    const INT nTabs = 5;
    HWND hTab;
    RECT rTab;
    INT nTabsRetrieved;
    INT rowCount;
    INT dpi;
    HDC hdc;

    ok(parent_wnd != NULL, "no parent window!\n");
    flush_sequences(sequences, NUM_MSG_SEQUENCES);

    hTab = createFilledTabControl(parent_wnd, TCS_FIXEDWIDTH, TCIF_TEXT|TCIF_IMAGE, nTabs);
    ok(hTab != NULL, "Failed to create tab control\n");

    if(!winetest_interactive)
        ok_sequence(sequences, TAB_SEQ_INDEX, add_tab_to_parent,
                    "Tab sequence, after adding tab control to parent", TRUE);
    else
        ok_sequence(sequences, TAB_SEQ_INDEX, add_tab_to_parent_interactive,
                    "Tab sequence, after adding tab control to parent", TRUE);

    if(!winetest_interactive)
        ok_sequence(sequences, PARENT_SEQ_INDEX, add_tab_control_parent_seq,
                    "Parent after sequence, adding tab control to parent", TRUE);
    else
        ok_sequence(sequences, PARENT_SEQ_INDEX, add_tab_control_parent_seq_interactive,
                    "Parent after sequence, adding tab control to parent", TRUE);

    flush_sequences(sequences, NUM_MSG_SEQUENCES);
    ok(SendMessage(hTab, TCM_SETMINTABWIDTH, 0, -1) > 0,"TCM_SETMINTABWIDTH returned < 0\n");
    ok_sequence(sequences, PARENT_SEQ_INDEX, empty_sequence, "Set minTabWidth test parent sequence", FALSE);

    /* Testing GetItemCount */
    flush_sequences(sequences, NUM_MSG_SEQUENCES);
    nTabsRetrieved = SendMessage(hTab, TCM_GETITEMCOUNT, 0, 0);
    expect(nTabs, nTabsRetrieved);
    ok_sequence(sequences, TAB_SEQ_INDEX, get_item_count_seq, "Get itemCount test sequence", FALSE);
    ok_sequence(sequences, PARENT_SEQ_INDEX, empty_sequence, "Getset itemCount test parent sequence", FALSE);

    /* Testing GetRowCount */
    flush_sequences(sequences, NUM_MSG_SEQUENCES);
    rowCount = SendMessage(hTab, TCM_GETROWCOUNT, 0, 0);
    expect(1, rowCount);
    ok_sequence(sequences, TAB_SEQ_INDEX, get_row_count_seq, "Get rowCount test sequence", FALSE);
    ok_sequence(sequences, PARENT_SEQ_INDEX, empty_sequence, "Get rowCount test parent sequence", FALSE);

    /* Testing GetItemRect */
    flush_sequences(sequences, NUM_MSG_SEQUENCES);
    ok(SendMessage(hTab, TCM_GETITEMRECT, 0, (LPARAM) &rTab), "GetItemRect failed.\n");

    hdc = GetDC(hTab);
    dpi = GetDeviceCaps(hdc, LOGPIXELSX);
    ReleaseDC(hTab, hdc);
    CHECKSIZE(hTab, dpi, -1 , "Default Width");
    ok_sequence(sequences, TAB_SEQ_INDEX, get_item_rect_seq, "Get itemRect test sequence", FALSE);
    ok_sequence(sequences, PARENT_SEQ_INDEX, empty_sequence, "Get itemRect test parent sequence", FALSE);

    DestroyWindow(hTab);
}
Exemplo n.º 20
0
/**
 * Construct the DMI table.
 *
 * @returns VBox status code.
 * @param   pDevIns             The device instance.
 * @param   pTable              Where to create the DMI table.
 * @param   cbMax               The maximum size of the DMI table.
 * @param   pUuid               Pointer to the UUID to use if the DmiUuid
 *                              configuration string isn't present.
 * @param   pCfg                The handle to our config node.
 */
int FwCommonPlantDMITable(PPDMDEVINS pDevIns, uint8_t *pTable, unsigned cbMax, PCRTUUID pUuid, PCFGMNODE pCfg)
{
#define CHECKSIZE(cbWant) \
    { \
        size_t cbNeed = (size_t)(pszStr + cbWant - (char *)pTable) + 5; /* +1 for strtab terminator +4 for end-of-table entry */ \
        if (cbNeed > cbMax) \
        { \
            if (fHideErrors) \
            { \
                LogRel(("One of the DMI strings is too long -- using default DMI data!\n")); \
                continue; \
            } \
            return PDMDevHlpVMSetError(pDevIns, VERR_TOO_MUCH_DATA, RT_SRC_POS, \
                                       N_("One of the DMI strings is too long. Check all bios/Dmi* configuration entries. At least %zu bytes are needed but there is no space for more than %d bytes"), cbNeed, cbMax); \
        } \
    }

#define READCFGSTRDEF(variable, name, default_value) \
    { \
        if (fForceDefault) \
            pszTmp = default_value; \
        else \
        { \
            rc = CFGMR3QueryStringDef(pCfg, name, szBuf, sizeof(szBuf), default_value); \
            if (RT_FAILURE(rc)) \
            { \
                if (fHideErrors) \
                { \
                    LogRel(("Configuration error: Querying \"" name "\" as a string failed -- using default DMI data!\n")); \
                    continue; \
                } \
                return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS, \
                                           N_("Configuration error: Querying \"" name "\" as a string failed")); \
            } \
            else if (!strcmp(szBuf, "<EMPTY>")) \
                pszTmp = ""; \
            else \
                pszTmp = szBuf; \
        } \
        if (!pszTmp[0]) \
            variable = 0; /* empty string */ \
        else \
        { \
            variable = iStrNr++; \
            size_t cStr = strlen(pszTmp) + 1; \
            CHECKSIZE(cStr); \
            memcpy(pszStr, pszTmp, cStr); \
            pszStr += cStr ; \
        } \
    }

#define READCFGSTR(variable, name) \
    READCFGSTRDEF(variable, # name, s_szDef ## name)

#define READCFGINT(variable, name) \
    { \
        if (fForceDefault) \
            variable = s_iDef ## name; \
        else \
        { \
            rc = CFGMR3QueryS32Def(pCfg, # name, & variable, s_iDef ## name); \
            if (RT_FAILURE(rc)) \
            { \
                if (fHideErrors) \
                { \
                    LogRel(("Configuration error: Querying \"" # name "\" as an int failed -- using default DMI data!\n")); \
                    continue; \
                } \
                return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS, \
                                           N_("Configuration error: Querying \"" # name "\" as an int failed")); \
            } \
        } \
    }

#define START_STRUCT(tbl)                                       \
        pszStr                       = (char *)(tbl + 1);       \
        iStrNr                       = 1;

#define TERM_STRUCT \
    { \
        *pszStr++                    = '\0'; /* terminate set of text strings */ \
        if (iStrNr == 1) \
            *pszStr++                = '\0'; /* terminate a structure without strings */ \
    }

    bool fForceDefault = false;
#ifdef VBOX_BIOS_DMI_FALLBACK
    /*
     * There will be two passes. If an error occurs during the first pass, a
     * message will be written to the release log and we fall back to default
     * DMI data and start a second pass.
     */
    bool fHideErrors = true;
#else
    /*
     * There will be one pass, every error is fatal and will prevent the VM
     * from starting.
     */
    bool fHideErrors = false;
#endif

    uint8_t fDmiUseHostInfo;
    int rc = CFGMR3QueryU8Def(pCfg, "DmiUseHostInfo", &fDmiUseHostInfo, 0);
    if (RT_FAILURE (rc))
        return PDMDEV_SET_ERROR(pDevIns, rc,
                                N_("Configuration error: Failed to read \"DmiUseHostInfo\""));

    /* Sync up with host default DMI values */
    if (fDmiUseHostInfo)
        fwCommonUseHostDMIStrings();

    uint8_t fDmiExposeMemoryTable;
    rc = CFGMR3QueryU8Def(pCfg, "DmiExposeMemoryTable", &fDmiExposeMemoryTable, 0);
    if (RT_FAILURE (rc))
        return PDMDEV_SET_ERROR(pDevIns, rc,
                                N_("Configuration error: Failed to read \"DmiExposeMemoryTable\""));

    for  (;; fForceDefault = true, fHideErrors = false)
    {
        int  iStrNr;
        char szBuf[256];
        char *pszStr = (char *)pTable;
        char szDmiSystemUuid[64];
        char *pszDmiSystemUuid;
        const char *pszTmp;

        if (fForceDefault)
            pszDmiSystemUuid = NULL;
        else
        {
            rc = CFGMR3QueryString(pCfg, "DmiSystemUuid", szDmiSystemUuid, sizeof(szDmiSystemUuid));
            if (rc == VERR_CFGM_VALUE_NOT_FOUND)
                pszDmiSystemUuid = NULL;
            else if (RT_FAILURE(rc))
            {
                if (fHideErrors)
                {
                    LogRel(("Configuration error: Querying \"DmiSystemUuid\" as a string failed, using default DMI data\n"));
                    continue;
                }
                return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS,
                                           N_("Configuration error: Querying \"DmiSystemUuid\" as a string failed"));
            }
            else
                pszDmiSystemUuid = szDmiSystemUuid;
        }

        /*********************************
         * DMI BIOS information (Type 0) *
         *********************************/
        PDMIBIOSINF pBIOSInf         = (PDMIBIOSINF)pszStr;
        CHECKSIZE(sizeof(*pBIOSInf));

        pszStr                       = (char *)&pBIOSInf->u8ReleaseMajor;
        pBIOSInf->header.u8Length    = RT_OFFSETOF(DMIBIOSINF, u8ReleaseMajor);

        /* don't set these fields by default for legacy compatibility */
        int iDmiBIOSReleaseMajor, iDmiBIOSReleaseMinor;
        READCFGINT(iDmiBIOSReleaseMajor, DmiBIOSReleaseMajor);
        READCFGINT(iDmiBIOSReleaseMinor, DmiBIOSReleaseMinor);
        if (iDmiBIOSReleaseMajor != 0 || iDmiBIOSReleaseMinor != 0)
        {
            pszStr = (char *)&pBIOSInf->u8FirmwareMajor;
            pBIOSInf->header.u8Length = RT_OFFSETOF(DMIBIOSINF, u8FirmwareMajor);
            pBIOSInf->u8ReleaseMajor  = iDmiBIOSReleaseMajor;
            pBIOSInf->u8ReleaseMinor  = iDmiBIOSReleaseMinor;

            int iDmiBIOSFirmwareMajor, iDmiBIOSFirmwareMinor;
            READCFGINT(iDmiBIOSFirmwareMajor, DmiBIOSFirmwareMajor);
            READCFGINT(iDmiBIOSFirmwareMinor, DmiBIOSFirmwareMinor);
            if (iDmiBIOSFirmwareMajor != 0 || iDmiBIOSFirmwareMinor != 0)
            {
                pszStr = (char *)(pBIOSInf + 1);
                pBIOSInf->header.u8Length = sizeof(DMIBIOSINF);
                pBIOSInf->u8FirmwareMajor = iDmiBIOSFirmwareMajor;
                pBIOSInf->u8FirmwareMinor = iDmiBIOSFirmwareMinor;
            }
        }

        iStrNr                       = 1;
        pBIOSInf->header.u8Type      = 0; /* BIOS Information */
        pBIOSInf->header.u16Handle   = 0x0000;
        READCFGSTR(pBIOSInf->u8Vendor,  DmiBIOSVendor);
        READCFGSTR(pBIOSInf->u8Version, DmiBIOSVersion);
        pBIOSInf->u16Start           = 0xE000;
        READCFGSTR(pBIOSInf->u8Release, DmiBIOSReleaseDate);
        pBIOSInf->u8ROMSize          = 1; /* 128K */
        pBIOSInf->u64Characteristics = RT_BIT(4)   /* ISA is supported */
                                     | RT_BIT(7)   /* PCI is supported */
                                     | RT_BIT(15)  /* Boot from CD is supported */
                                     | RT_BIT(16)  /* Selectable Boot is supported */
                                     | RT_BIT(27)  /* Int 9h, 8042 Keyboard services supported */
                                     | RT_BIT(30)  /* Int 10h, CGA/Mono Video Services supported */
                                     /* any more?? */
                                     ;
        pBIOSInf->u8CharacteristicsByte1 = RT_BIT(0)   /* ACPI is supported */
                                         /* any more?? */
                                         ;
        pBIOSInf->u8CharacteristicsByte2 = 0
                                         /* any more?? */
                                         ;
        TERM_STRUCT;

        /***********************************
         * DMI system information (Type 1) *
         ***********************************/
        PDMISYSTEMINF pSystemInf     = (PDMISYSTEMINF)pszStr;
        CHECKSIZE(sizeof(*pSystemInf));
        pszStr                       = (char *)(pSystemInf + 1);
        iStrNr                       = 1;
        pSystemInf->header.u8Type    = 1; /* System Information */
        pSystemInf->header.u8Length  = sizeof(*pSystemInf);
        pSystemInf->header.u16Handle = 0x0001;
        READCFGSTR(pSystemInf->u8Manufacturer, DmiSystemVendor);
        READCFGSTR(pSystemInf->u8ProductName,  DmiSystemProduct);
        READCFGSTR(pSystemInf->u8Version,      DmiSystemVersion);
        READCFGSTR(pSystemInf->u8SerialNumber, DmiSystemSerial);

        RTUUID uuid;
        if (pszDmiSystemUuid)
        {
            rc = RTUuidFromStr(&uuid, pszDmiSystemUuid);
            if (RT_FAILURE(rc))
            {
                if (fHideErrors)
                {
                    LogRel(("Configuration error: Invalid UUID for DMI tables specified, using default DMI data\n"));
                    continue;
                }
                return PDMDevHlpVMSetError(pDevIns, rc, RT_SRC_POS,
                                           N_("Configuration error: Invalid UUID for DMI tables specified"));
            }
            uuid.Gen.u32TimeLow = RT_H2BE_U32(uuid.Gen.u32TimeLow);
            uuid.Gen.u16TimeMid = RT_H2BE_U16(uuid.Gen.u16TimeMid);
            uuid.Gen.u16TimeHiAndVersion = RT_H2BE_U16(uuid.Gen.u16TimeHiAndVersion);
            pUuid = &uuid;
        }
        memcpy(pSystemInf->au8Uuid, pUuid, sizeof(RTUUID));

        pSystemInf->u8WakeupType     = 6; /* Power Switch */
        READCFGSTR(pSystemInf->u8SKUNumber, DmiSystemSKU);
        READCFGSTR(pSystemInf->u8Family, DmiSystemFamily);
        TERM_STRUCT;

        /********************************************
         * DMI System Enclosure or Chassis (Type 3) *
         ********************************************/
        PDMICHASSIS pChassis         = (PDMICHASSIS)pszStr;
        CHECKSIZE(sizeof(*pChassis));
        pszStr                       = (char*)&pChassis->u32OEMdefined;
        iStrNr                       = 1;
#ifdef VBOX_WITH_DMI_CHASSIS
        pChassis->header.u8Type      = 3; /* System Enclosure or Chassis */
#else
        pChassis->header.u8Type      = 0x7e; /* inactive */
#endif
        pChassis->header.u8Length    = RT_OFFSETOF(DMICHASSIS, u32OEMdefined);
        pChassis->header.u16Handle   = 0x0003;
        READCFGSTR(pChassis->u8Manufacturer, DmiChassisVendor);
        pChassis->u8Type             = 0x01; /* ''other'', no chassis lock present */
        READCFGSTR(pChassis->u8Version, DmiChassisVersion);
        READCFGSTR(pChassis->u8SerialNumber, DmiChassisSerial);
        READCFGSTR(pChassis->u8AssetTag, DmiChassisAssetTag);
        pChassis->u8BootupState      = 0x03; /* safe */
        pChassis->u8PowerSupplyState = 0x03; /* safe */
        pChassis->u8ThermalState     = 0x03; /* safe */
        pChassis->u8SecurityStatus   = 0x03; /* none XXX */
# if 0
        /* v2.3+, currently not supported */
        pChassis->u32OEMdefined      = 0;
        pChassis->u8Height           = 0; /* unspecified */
        pChassis->u8NumPowerChords   = 0; /* unspecified */
        pChassis->u8ContElems        = 0; /* no contained elements */
        pChassis->u8ContElemRecLen   = 0; /* no contained elements */
# endif
        TERM_STRUCT;

        if (fDmiExposeMemoryTable)
        {
            /***************************************
             * DMI Physical Memory Array (Type 16) *
             ***************************************/
            uint64_t u64RamSize;
            rc = CFGMR3QueryU64(pCfg, "RamSize", &u64RamSize);
            if (RT_FAILURE (rc))
                return PDMDEV_SET_ERROR(pDevIns, rc,
                                        N_("Configuration error: Failed to read \"RamSize\""));

            PDMIRAMARRAY pMemArray = (PDMIRAMARRAY)pszStr;
            CHECKSIZE(sizeof(*pMemArray));

            START_STRUCT(pMemArray);
            pMemArray->header.u8Type    = 16; /* Physical Memory Array */
            pMemArray->header.u8Length  = sizeof(*pMemArray);
            pMemArray->header.u16Handle = 0x0005;
            pMemArray->u8Location = 0x03; /* Motherboard */
            pMemArray->u8Use = 0x03; /* System memory */
            pMemArray->u8MemErrorCorrection = 0x01; /* Other */
            uint32_t u32RamSizeK = (uint32_t)(u64RamSize / _1K);
            pMemArray->u32MaxCapacity = u32RamSizeK; /* RAM size in K */
            pMemArray->u16MemErrorHandle = 0xfffe; /* No error info structure */
            pMemArray->u16NumberOfMemDevices = 1;
            TERM_STRUCT;

            /***************************************
             * DMI Memory Device (Type 17)         *
             ***************************************/
            PDMIMEMORYDEV pMemDev = (PDMIMEMORYDEV)pszStr;
            CHECKSIZE(sizeof(*pMemDev));

            START_STRUCT(pMemDev);
            pMemDev->header.u8Type    = 17; /* Memory Device */
            pMemDev->header.u8Length  = sizeof(*pMemDev);
            pMemDev->header.u16Handle = 0x0006;
            pMemDev->u16PhysMemArrayHandle = 0x0005; /* handle of array we belong to */
            pMemDev->u16MemErrHandle = 0xfffe; /* system doesn't provide this information */
            pMemDev->u16TotalWidth = 0xffff; /* Unknown */
            pMemDev->u16DataWidth = 0xffff;  /* Unknown */
            int16_t u16RamSizeM = (uint16_t)(u64RamSize / _1M);
            if (u16RamSizeM == 0)
                u16RamSizeM = 0x400; /* 1G */
            pMemDev->u16Size = u16RamSizeM; /* RAM size */
            pMemDev->u8FormFactor = 0x09; /* DIMM */
            pMemDev->u8DeviceSet = 0x00; /* Not part of a device set */
            READCFGSTRDEF(pMemDev->u8DeviceLocator, " ", "DIMM 0");
            READCFGSTRDEF(pMemDev->u8BankLocator, " ", "Bank 0");
            pMemDev->u8MemoryType = 0x03; /* DRAM */
            pMemDev->u16TypeDetail = 0; /* Nothing special */
            pMemDev->u16Speed = 1600; /* Unknown, shall be speed in MHz */
            READCFGSTR(pMemDev->u8Manufacturer, DmiSystemVendor);
            READCFGSTRDEF(pMemDev->u8SerialNumber, " ", "00000000");
            READCFGSTRDEF(pMemDev->u8AssetTag, " ", "00000000");
            READCFGSTRDEF(pMemDev->u8PartNumber, " ", "00000000");
            pMemDev->u8Attributes = 0; /* Unknown */
            TERM_STRUCT;
        }

        /*****************************
         * DMI OEM strings (Type 11) *
         *****************************/
        PDMIOEMSTRINGS pOEMStrings    = (PDMIOEMSTRINGS)pszStr;
        CHECKSIZE(sizeof(*pOEMStrings));
        pszStr                        = (char *)(pOEMStrings + 1);
        iStrNr                        = 1;
#ifdef VBOX_WITH_DMI_OEMSTRINGS
        pOEMStrings->header.u8Type    = 0xb; /* OEM Strings */
#else
        pOEMStrings->header.u8Type    = 0x7e; /* inactive */
#endif
        pOEMStrings->header.u8Length  = sizeof(*pOEMStrings);
        pOEMStrings->header.u16Handle = 0x0002;
        pOEMStrings->u8Count          = 2;

        char szTmp[64];
        RTStrPrintf(szTmp, sizeof(szTmp), "vboxVer_%u.%u.%u",
                    RTBldCfgVersionMajor(), RTBldCfgVersionMinor(), RTBldCfgVersionBuild());
        READCFGSTRDEF(pOEMStrings->u8VBoxVersion, "DmiOEMVBoxVer", szTmp);
        RTStrPrintf(szTmp, sizeof(szTmp), "vboxRev_%u", RTBldCfgRevision());
        READCFGSTRDEF(pOEMStrings->u8VBoxRevision, "DmiOEMVBoxRev", szTmp);
        TERM_STRUCT;

        /* End-of-table marker - includes padding to account for fixed table size. */
        PDMIHDR pEndOfTable          = (PDMIHDR)pszStr;
        pEndOfTable->u8Type          = 0x7f;
        pEndOfTable->u8Length        = cbMax - ((char *)pszStr - (char *)pTable) - 2;
        pEndOfTable->u16Handle       = 0xFEFF;

        /* If more fields are added here, fix the size check in READCFGSTR */

        /* Success! */
        break;
    }

#undef READCFGSTR
#undef READCFGINT
#undef CHECKSIZE
    return VINF_SUCCESS;
}