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/**
* @file llimagebmp.cpp
*
* $LicenseInfo:firstyear=2001&license=viewerlgpl$
* Second Life Viewer Source Code
* Copyright (C) 2010, Linden Research, Inc.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation;
* version 2.1 of the License only.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
* Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA
* $/LicenseInfo$
*/
#include "linden_common.h"
#include "llimagebmp.h"
#include "llerror.h"
#include "llendianswizzle.h"
/**
* @struct LLBMPHeader
*
* This struct helps deal with bmp files.
*/
struct LLBMPHeader
{
S32 mSize;
S32 mWidth;
S32 mHeight;
S16 mPlanes;
S16 mBitsPerPixel;
S16 mCompression;
S16 mAlignmentPadding; // pads out to next word boundary
S32 mImageSize;
S32 mHorzPelsPerMeter;
S32 mVertPelsPerMeter;
S32 mNumColors;
S32 mNumColorsImportant;
};
/**
* @struct Win95BmpHeaderExtension
*/
struct Win95BmpHeaderExtension
{
U32 mReadMask;
U32 mGreenMask;
U32 mBlueMask;
U32 mAlphaMask;
U32 mColorSpaceType;
U16 mRed[3]; // Red CIE endpoint
U16 mGreen[3]; // Green CIE endpoint
U16 mBlue[3]; // Blue CIE endpoint
U32 mGamma[3]; // Gamma scale for r g and b
};
/**
* LLImageBMP
*/
LLImageBMP::LLImageBMP()
:
LLImageFormatted(IMG_CODEC_BMP),
mColorPaletteColors( 0 ),
mColorPalette( NULL ),
mBitmapOffset( 0 ),
mBitsPerPixel( 0 ),
mOriginAtTop( false )
{
mBitfieldMask[0] = 0;
mBitfieldMask[1] = 0;
mBitfieldMask[2] = 0;
mBitfieldMask[3] = 0;
}
LLImageBMP::~LLImageBMP()
{
delete[] mColorPalette;
}
bool LLImageBMP::updateData()
{
resetLastError();
LLImageDataLock lock(this);
// Check to make sure that this instance has been initialized with data
U8* mdata = getData();
if (!mdata || (0 == getDataSize()))
{
setLastError("Uninitialized instance of LLImageBMP");
return false;
}
// Read the bitmap headers in order to get all the useful info
// about this image
////////////////////////////////////////////////////////////////////
// Part 1: "File Header"
// 14 bytes consisting of
// 2 bytes: either BM or BA
// 4 bytes: file size in bytes
// 4 bytes: reserved (always 0)
// 4 bytes: bitmap offset (starting position of image data in bytes)
const S32 FILE_HEADER_SIZE = 14;
if ((mdata[0] != 'B') || (mdata[1] != 'M'))
{
if ((mdata[0] != 'B') || (mdata[1] != 'A'))
{
setLastError("OS/2 bitmap array BMP files are not supported");
return false;
}
else
{
setLastError("Does not appear to be a bitmap file");
return false;
}
}
mBitmapOffset = mdata[13];
mBitmapOffset <<= 8; mBitmapOffset += mdata[12];
mBitmapOffset <<= 8; mBitmapOffset += mdata[11];
mBitmapOffset <<= 8; mBitmapOffset += mdata[10];
////////////////////////////////////////////////////////////////////
// Part 2: "Bitmap Header"
const S32 BITMAP_HEADER_SIZE = 40;
LLBMPHeader header;
llassert( sizeof( header ) == BITMAP_HEADER_SIZE );
memcpy( /* Flawfinder: ignore */
(void*)&header,
mdata + FILE_HEADER_SIZE,
BITMAP_HEADER_SIZE);
// convert BMP header from little endian (no-op on little endian builds)
llendianswizzleone(header.mSize);
llendianswizzleone(header.mWidth);
llendianswizzleone(header.mHeight);
llendianswizzleone(header.mPlanes);
llendianswizzleone(header.mBitsPerPixel);
llendianswizzleone(header.mCompression);
llendianswizzleone(header.mAlignmentPadding);
llendianswizzleone(header.mImageSize);
llendianswizzleone(header.mHorzPelsPerMeter);
llendianswizzleone(header.mVertPelsPerMeter);
llendianswizzleone(header.mNumColors);
llendianswizzleone(header.mNumColorsImportant);
bool windows_nt_version = false;
bool windows_95_version = false;
if( 12 == header.mSize )
{
setLastError("Windows 2.x and OS/2 1.x BMP files are not supported");
return false;
}
else
if( 40 == header.mSize )
{
if( 3 == header.mCompression )
{
// Windows NT
windows_nt_version = true;
}
else
{
// Windows 3.x
}
}
else
if( 12 <= header.mSize && header.mSize <= 64 )
{
setLastError("OS/2 2.x BMP files are not supported");
return false;
}
else
if( 108 == header.mSize )
{
// BITMAPV4HEADER
windows_95_version = true;
}
else
if( 108 < header.mSize )
{
// BITMAPV5HEADER or greater
// Should work as long at Microsoft maintained backwards compatibility (which they did in V4 and V5)
windows_95_version = true;
}
S32 width = header.mWidth;
S32 height = header.mHeight;
if (height < 0)
{
mOriginAtTop = true;
height = -height;
}
else
{
mOriginAtTop = false;
}
mBitsPerPixel = header.mBitsPerPixel;
S32 components;
switch( mBitsPerPixel )
{
case 8:
components = 1;
break;
case 24:
case 32:
components = 3;
break;
case 1:
case 4:
case 16: // Started work on 16, but doesn't work yet
// These are legal, but we don't support them yet.
setLastError("Unsupported bit depth");
return false;
default:
setLastError("Unrecognized bit depth");
return false;
}
setSize(width, height, components);
switch( header.mCompression )
{
case 0:
// Uncompressed
break;
case 1:
setLastError("8 bit RLE compression not supported.");
return false;
case 2:
setLastError("4 bit RLE compression not supported.");
return false;
case 3:
// Windows NT or Windows 95
break;
default:
setLastError("Unsupported compression format.");
return false;
}
////////////////////////////////////////////////////////////////////
// Part 3: Bitfield Masks and other color data
S32 extension_size = 0;
if( windows_nt_version )
{
if( (16 != header.mBitsPerPixel) && (32 != header.mBitsPerPixel) )
{
setLastError("Bitfield encoding requires 16 or 32 bits per pixel.");
return false;
}
if( 0 != header.mNumColors )
{
setLastError("Bitfield encoding is not compatible with a color table.");
return false;
}
extension_size = 4 * 3;
memcpy( mBitfieldMask, mdata + FILE_HEADER_SIZE + BITMAP_HEADER_SIZE, extension_size); /* Flawfinder: ignore */
}
else
if( windows_95_version )
{
Win95BmpHeaderExtension win_95_extension;
extension_size = sizeof( win_95_extension );
llassert( sizeof( win_95_extension ) + BITMAP_HEADER_SIZE == 108 );
memcpy( &win_95_extension, mdata + FILE_HEADER_SIZE + BITMAP_HEADER_SIZE, sizeof( win_95_extension ) ); /* Flawfinder: ignore */
if( 3 == header.mCompression )
{
memcpy( mBitfieldMask, mdata + FILE_HEADER_SIZE + BITMAP_HEADER_SIZE, 4 * 4); /* Flawfinder: ignore */
}
// Color correction ignored for now
}
////////////////////////////////////////////////////////////////////
// Part 4: Color Palette (optional)
// Note: There's no color palette if there are 16 or more bits per pixel
S32 color_palette_size = 0;
mColorPaletteColors = 0;
if( header.mBitsPerPixel < 16 )
{
if( 0 == header.mNumColors )
{
mColorPaletteColors = (1 << header.mBitsPerPixel);
}
else
{
mColorPaletteColors = header.mNumColors;
}
}
color_palette_size = mColorPaletteColors * 4;
if( 0 != mColorPaletteColors )
{
mColorPalette = new(std::nothrow) U8[color_palette_size];
if (!mColorPalette)
{
LL_ERRS() << "Out of memory in LLImageBMP::updateData()" << LL_ENDL;
return false;
}
memcpy( mColorPalette, mdata + FILE_HEADER_SIZE + BITMAP_HEADER_SIZE + extension_size, color_palette_size ); /* Flawfinder: ignore */
}
return true;
}
bool LLImageBMP::decode(LLImageRaw* raw_image, F32 decode_time)
{
llassert_always(raw_image);
resetLastError();
LLImageDataLock lockIn(this);
LLImageDataLock lockOut(raw_image);
// Check to make sure that this instance has been initialized with data
const U8* mdata = getData();
if (!mdata || (0 == getDataSize()))
{
setLastError("llimagebmp trying to decode an image with no data!");
return false;
}
if (!raw_image->resize(getWidth(), getHeight(), 3))
{
setLastError("llimagebmp failed to resize image!");
return false;
}
const U8* src = mdata + mBitmapOffset;
U8* dst = raw_image->getData();
bool success = false;
switch( mBitsPerPixel )
{
case 8:
if( mColorPaletteColors >= 256 )
{
success = decodeColorTable8( dst, src );
}
break;
case 16:
success = decodeColorMask16( dst, src );
break;
case 24:
success = decodeTruecolor24( dst, src );
break;
case 32:
success = decodeColorMask32( dst, src );
break;
}
if( success && mOriginAtTop )
{
raw_image->verticalFlip();
}
return success;
}
U32 LLImageBMP::countTrailingZeros( U32 m )
{
U32 shift_count = 0;
while( !(m & 1) )
{
shift_count++;
m >>= 1;
}
return shift_count;
}
bool LLImageBMP::decodeColorMask16( U8* dst, const U8* src )
{
llassert( 16 == mBitsPerPixel );
if( !mBitfieldMask[0] && !mBitfieldMask[1] && !mBitfieldMask[2] )
{
// Use default values
mBitfieldMask[0] = 0x00007C00;
mBitfieldMask[1] = 0x000003E0;
mBitfieldMask[2] = 0x0000001F;
}
S32 src_row_span = getWidth() * 2;
S32 alignment_bytes = (3 * src_row_span) % 4; // round up to nearest multiple of 4
U32 r_shift = countTrailingZeros( mBitfieldMask[2] );
U32 g_shift = countTrailingZeros( mBitfieldMask[1] );
U32 b_shift = countTrailingZeros( mBitfieldMask[0] );
for( S32 row = 0; row < getHeight(); row++ )
{
for( S32 col = 0; col < getWidth(); col++ )
{
U32 value = *((U16*)src);
dst[0] = U8((value & mBitfieldMask[2]) >> r_shift); // Red
dst[1] = U8((value & mBitfieldMask[1]) >> g_shift); // Green
dst[2] = U8((value & mBitfieldMask[0]) >> b_shift); // Blue
src += 2;
dst += 3;
}
src += alignment_bytes;
}
return true;
}
bool LLImageBMP::decodeColorMask32( U8* dst, const U8* src )
{
// Note: alpha is not supported
llassert( 32 == mBitsPerPixel );
if( !mBitfieldMask[0] && !mBitfieldMask[1] && !mBitfieldMask[2] )
{
// Use default values
mBitfieldMask[0] = 0x00FF0000;
mBitfieldMask[1] = 0x0000FF00;
mBitfieldMask[2] = 0x000000FF;
}
if (getWidth() * getHeight() * 4 > getDataSize() - mBitmapOffset)
{ //here we have situation when data size in src less than actually needed
return false;
}
S32 src_row_span = getWidth() * 4;
S32 alignment_bytes = (3 * src_row_span) % 4; // round up to nearest multiple of 4
U32 r_shift = countTrailingZeros( mBitfieldMask[0] );
U32 g_shift = countTrailingZeros( mBitfieldMask[1] );
U32 b_shift = countTrailingZeros( mBitfieldMask[2] );
for( S32 row = 0; row < getHeight(); row++ )
{
for( S32 col = 0; col < getWidth(); col++ )
{
U32 value = *((U32*)src);
dst[0] = U8((value & mBitfieldMask[0]) >> r_shift); // Red
dst[1] = U8((value & mBitfieldMask[1]) >> g_shift); // Green
dst[2] = U8((value & mBitfieldMask[2]) >> b_shift); // Blue
src += 4;
dst += 3;
}
src += alignment_bytes;
}
return true;
}
bool LLImageBMP::decodeColorTable8( U8* dst, const U8* src )
{
llassert( (8 == mBitsPerPixel) && (mColorPaletteColors >= 256) );
S32 src_row_span = getWidth() * 1;
S32 alignment_bytes = (3 * src_row_span) % 4; // round up to nearest multiple of 4
if ((getWidth() * getHeight()) + getHeight() * alignment_bytes > getDataSize() - mBitmapOffset)
{ //here we have situation when data size in src less than actually needed
return false;
}
for( S32 row = 0; row < getHeight(); row++ )
{
for( S32 col = 0; col < getWidth(); col++ )
{
S32 index = 4 * src[0];
dst[0] = mColorPalette[index + 2]; // Red
dst[1] = mColorPalette[index + 1]; // Green
dst[2] = mColorPalette[index + 0]; // Blue
src++;
dst += 3;
}
src += alignment_bytes;
}
return true;
}
bool LLImageBMP::decodeTruecolor24( U8* dst, const U8* src )
{
llassert( 24 == mBitsPerPixel );
llassert( 3 == getComponents() );
S32 src_row_span = getWidth() * 3;
S32 alignment_bytes = (3 * src_row_span) % 4; // round up to nearest multiple of 4
if ((getWidth() * getHeight() * 3) + getHeight() * alignment_bytes > getDataSize() - mBitmapOffset)
{ //here we have situation when data size in src less than actually needed
return false;
}
for( S32 row = 0; row < getHeight(); row++ )
{
for( S32 col = 0; col < getWidth(); col++ )
{
dst[0] = src[2]; // Red
dst[1] = src[1]; // Green
dst[2] = src[0]; // Blue
src += 3;
dst += 3;
}
src += alignment_bytes;
}
return true;
}
bool LLImageBMP::encode(const LLImageRaw* raw_image, F32 encode_time)
{
llassert_always(raw_image);
resetLastError();
LLImageDataSharedLock lockIn(raw_image);
LLImageDataLock lockOut(this);
S32 src_components = raw_image->getComponents();
S32 dst_components = ( src_components < 3 ) ? 1 : 3;
if( (2 == src_components) || (4 == src_components) )
{
LL_INFOS() << "Dropping alpha information during BMP encoding" << LL_ENDL;
}
setSize(raw_image->getWidth(), raw_image->getHeight(), dst_components);
U8 magic[14];
LLBMPHeader header;
int header_bytes = 14+sizeof(header);
llassert(header_bytes == 54);
if (getComponents() == 1)
{
header_bytes += 1024; // Need colour LUT.
}
int line_bytes = getComponents() * getWidth();
int alignment_bytes = (3 * line_bytes) % 4;
line_bytes += alignment_bytes;
int file_bytes = line_bytes*getHeight() + header_bytes;
// Allocate the new buffer for the data.
if(!allocateData(file_bytes)) //memory allocation failed
{
return false ;
}
magic[0] = 'B'; magic[1] = 'M';
magic[2] = (U8) file_bytes;
magic[3] = (U8)(file_bytes>>8);
magic[4] = (U8)(file_bytes>>16);
magic[5] = (U8)(file_bytes>>24);
magic[6] = magic[7] = magic[8] = magic[9] = 0;
magic[10] = (U8) header_bytes;
magic[11] = (U8)(header_bytes>>8);
magic[12] = (U8)(header_bytes>>16);
magic[13] = (U8)(header_bytes>>24);
header.mSize = 40;
header.mWidth = getWidth();
header.mHeight = getHeight();
header.mPlanes = 1;
header.mBitsPerPixel = (getComponents()==1)?8:24;
header.mCompression = 0;
header.mAlignmentPadding = 0;
header.mImageSize = 0;
#if LL_DARWIN
header.mHorzPelsPerMeter = header.mVertPelsPerMeter = 2834; // 72dpi
#else
header.mHorzPelsPerMeter = header.mVertPelsPerMeter = 0;
#endif
header.mNumColors = header.mNumColorsImportant = 0;
// convert BMP header to little endian (no-op on little endian builds)
llendianswizzleone(header.mSize);
llendianswizzleone(header.mWidth);
llendianswizzleone(header.mHeight);
llendianswizzleone(header.mPlanes);
llendianswizzleone(header.mBitsPerPixel);
llendianswizzleone(header.mCompression);
llendianswizzleone(header.mAlignmentPadding);
llendianswizzleone(header.mImageSize);
llendianswizzleone(header.mHorzPelsPerMeter);
llendianswizzleone(header.mVertPelsPerMeter);
llendianswizzleone(header.mNumColors);
llendianswizzleone(header.mNumColorsImportant);
U8* mdata = getData();
// Output magic, then header, then the palette table, then the data.
U32 cur_pos = 0;
memcpy(mdata, magic, 14);
cur_pos += 14;
memcpy(mdata+cur_pos, &header, 40); /* Flawfinder: ignore */
cur_pos += 40;
if (getComponents() == 1)
{
S32 n;
for (n=0; n < 256; n++)
{
mdata[cur_pos++] = (U8)n;
mdata[cur_pos++] = (U8)n;
mdata[cur_pos++] = (U8)n;
mdata[cur_pos++] = 0;
}
}
// Need to iterate through, because we need to flip the RGB.
const U8* src = raw_image->getData();
U8* dst = mdata + cur_pos;
for( S32 row = 0; row < getHeight(); row++ )
{
for( S32 col = 0; col < getWidth(); col++ )
{
switch( src_components )
{
case 1:
*dst++ = *src++;
break;
case 2:
{
U32 lum = src[0];
U32 alpha = src[1];
*dst++ = (U8)(lum * alpha / 255);
src += 2;
break;
}
case 3:
case 4:
dst[0] = src[2];
dst[1] = src[1];
dst[2] = src[0];
src += src_components;
dst += 3;
break;
}
}
for( S32 i = 0; i < alignment_bytes; i++ )
{
*dst++ = 0;
}
}
return true;
}
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