/*M/////////////////////////////////////////////////////////////////////////////////////// // // IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. // // By downloading, copying, installing or using the software you agree to this license. // If you do not agree to this license, do not download, install, // copy or use the software. // // // License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2000-2008, Intel Corporation, all rights reserved. // Copyright (C) 2009, Willow Garage Inc., all rights reserved. // Third party copyrights are property of their respective owners. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // // * Redistribution's of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // * Redistribution's in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // // * The name of the copyright holders may not be used to endorse or promote products // derived from this software without specific prior written permission. // // This software is provided by the copyright holders and contributors "as is" and // any express or implied warranties, including, but not limited to, the implied // warranties of merchantability and fitness for a particular purpose are disclaimed. // In no event shall the Intel Corporation or contributors be liable for any direct, // indirect, incidental, special, exemplary, or consequential damages // (including, but not limited to, procurement of substitute goods or services; // loss of use, data, or profits; or business interruption) however caused // and on any theory of liability, whether in contract, strict liability, // or tort (including negligence or otherwise) arising in any way out of // the use of this software, even if advised of the possibility of such damage. // //M*/ #include "precomp.hpp" #include "grfmt_bmp.hpp" namespace cv { static const char* fmtSignBmp = "BM"; /************************ BMP decoder *****************************/ BmpDecoder::BmpDecoder() { m_signature = fmtSignBmp; m_offset = -1; m_buf_supported = true; } BmpDecoder::~BmpDecoder() { } void BmpDecoder::close() { m_strm.close(); } ImageDecoder BmpDecoder::newDecoder() const { return new BmpDecoder; } bool BmpDecoder::readHeader() { bool result = false; bool iscolor = false; if( !m_buf.empty() ) { if( !m_strm.open( m_buf ) ) return false; } else if( !m_strm.open( m_filename )) return false; try { m_strm.skip( 10 ); m_offset = m_strm.getDWord(); int size = m_strm.getDWord(); if( size >= 36 ) { m_width = m_strm.getDWord(); m_height = m_strm.getDWord(); m_bpp = m_strm.getDWord() >> 16; m_rle_code = (BmpCompression)m_strm.getDWord(); m_strm.skip(12); int clrused = m_strm.getDWord(); m_strm.skip( size - 36 ); if( m_width > 0 && m_height != 0 && (((m_bpp == 1 || m_bpp == 4 || m_bpp == 8 || m_bpp == 24 || m_bpp == 32 ) && m_rle_code == BMP_RGB) || (m_bpp == 16 && (m_rle_code == BMP_RGB || m_rle_code == BMP_BITFIELDS)) || (m_bpp == 4 && m_rle_code == BMP_RLE4) || (m_bpp == 8 && m_rle_code == BMP_RLE8))) { iscolor = true; result = true; if( m_bpp <= 8 ) { memset( m_palette, 0, sizeof(m_palette)); m_strm.getBytes( m_palette, (clrused == 0? 1<> 16; m_rle_code = BMP_RGB; if( m_width > 0 && m_height != 0 && (m_bpp == 1 || m_bpp == 4 || m_bpp == 8 || m_bpp == 24 || m_bpp == 32 )) { if( m_bpp <= 8 ) { uchar buffer[256*3]; int j, clrused = 1 << m_bpp; m_strm.getBytes( buffer, clrused*3 ); for( j = 0; j < clrused; j++ ) { m_palette[j].b = buffer[3*j+0]; m_palette[j].g = buffer[3*j+1]; m_palette[j].r = buffer[3*j+2]; } } result = true; } } } catch(...) { } m_type = iscolor ? CV_8UC3 : CV_8UC1; m_origin = m_height > 0 ? IPL_ORIGIN_BL : IPL_ORIGIN_TL; m_height = std::abs(m_height); if( !result ) { m_offset = -1; m_width = m_height = -1; m_strm.close(); } return result; } bool BmpDecoder::readData( Mat& img ) { uchar* data = img.data; int step = (int)img.step; bool color = img.channels() > 1; uchar gray_palette[256]; bool result = false; int src_pitch = ((m_width*(m_bpp != 15 ? m_bpp : 16) + 7)/8 + 3) & -4; int nch = color ? 3 : 1; int y, width3 = m_width*nch; if( m_offset < 0 || !m_strm.isOpened()) return false; if( m_origin == IPL_ORIGIN_BL ) { data += (m_height - 1)*step; step = -step; } AutoBuffer _src, _bgr; _src.allocate(src_pitch + 32); if( !color ) { if( m_bpp <= 8 ) { CvtPaletteToGray( m_palette, gray_palette, 1 << m_bpp ); } _bgr.allocate(m_width*3 + 32); } uchar *src = _src, *bgr = _bgr; try { m_strm.setPos( m_offset ); switch( m_bpp ) { /************************* 1 BPP ************************/ case 1: for( y = 0; y < m_height; y++, data += step ) { m_strm.getBytes( src, src_pitch ); FillColorRow1( color ? data : bgr, src, m_width, m_palette ); if( !color ) icvCvt_BGR2Gray_8u_C3C1R( bgr, 0, data, 0, cvSize(m_width,1) ); } result = true; break; /************************* 4 BPP ************************/ case 4: if( m_rle_code == BMP_RGB ) { for( y = 0; y < m_height; y++, data += step ) { m_strm.getBytes( src, src_pitch ); if( color ) FillColorRow4( data, src, m_width, m_palette ); else FillGrayRow4( data, src, m_width, gray_palette ); } result = true; } else if( m_rle_code == BMP_RLE4 ) // rle4 compression { uchar* line_end = data + width3; y = 0; for(;;) { int code = m_strm.getWord(); int len = code & 255; code >>= 8; if( len != 0 ) // encoded mode { PaletteEntry clr[2]; uchar gray_clr[2]; int t = 0; clr[0] = m_palette[code >> 4]; clr[1] = m_palette[code & 15]; gray_clr[0] = gray_palette[code >> 4]; gray_clr[1] = gray_palette[code & 15]; uchar* end = data + len*nch; if( end > line_end ) goto decode_rle4_bad; do { if( color ) WRITE_PIX( data, clr[t] ); else *data = gray_clr[t]; t ^= 1; } while( (data += nch) < end ); } else if( code > 2 ) // absolute mode { if( data + code*nch > line_end ) goto decode_rle4_bad; m_strm.getBytes( src, (((code + 1)>>1) + 1) & -2 ); if( color ) data = FillColorRow4( data, src, code, m_palette ); else data = FillGrayRow4( data, src, code, gray_palette ); } else { int x_shift3 = (int)(line_end - data); int y_shift = m_height - y; if( code == 2 ) { x_shift3 = m_strm.getByte()*nch; y_shift = m_strm.getByte(); } len = x_shift3 + ((y_shift * width3) & ((code == 0) - 1)); if( color ) data = FillUniColor( data, line_end, step, width3, y, m_height, x_shift3, m_palette[0] ); else data = FillUniGray( data, line_end, step, width3, y, m_height, x_shift3, gray_palette[0] ); if( y >= m_height ) break; } } result = true; decode_rle4_bad: ; } break; /************************* 8 BPP ************************/ case 8: if( m_rle_code == BMP_RGB ) { for( y = 0; y < m_height; y++, data += step ) { m_strm.getBytes( src, src_pitch ); if( color ) FillColorRow8( data, src, m_width, m_palette ); else FillGrayRow8( data, src, m_width, gray_palette ); } result = true; } else if( m_rle_code == BMP_RLE8 ) // rle8 compression { uchar* line_end = data + width3; int line_end_flag = 0; y = 0; for(;;) { int code = m_strm.getWord(); int len = code & 255; code >>= 8; if( len != 0 ) // encoded mode { int prev_y = y; len *= nch; if( data + len > line_end ) goto decode_rle8_bad; if( color ) data = FillUniColor( data, line_end, step, width3, y, m_height, len, m_palette[code] ); else data = FillUniGray( data, line_end, step, width3, y, m_height, len, gray_palette[code] ); line_end_flag = y - prev_y; } else if( code > 2 ) // absolute mode { int prev_y = y; int code3 = code*nch; if( data + code3 > line_end ) goto decode_rle8_bad; m_strm.getBytes( src, (code + 1) & -2 ); if( color ) data = FillColorRow8( data, src, code, m_palette ); else data = FillGrayRow8( data, src, code, gray_palette ); line_end_flag = y - prev_y; } else { int x_shift3 = (int)(line_end - data); int y_shift = m_height - y; if( code || !line_end_flag || x_shift3 < width3 ) { if( code == 2 ) { x_shift3 = m_strm.getByte()*nch; y_shift = m_strm.getByte(); } x_shift3 += (y_shift * width3) & ((code == 0) - 1); if( y >= m_height ) break; if( color ) data = FillUniColor( data, line_end, step, width3, y, m_height, x_shift3, m_palette[0] ); else data = FillUniGray( data, line_end, step, width3, y, m_height, x_shift3, gray_palette[0] ); if( y >= m_height ) break; } line_end_flag = 0; if( y >= m_height ) break; } } result = true; decode_rle8_bad: ; } break; /************************* 15 BPP ************************/ case 15: for( y = 0; y < m_height; y++, data += step ) { m_strm.getBytes( src, src_pitch ); if( !color ) icvCvt_BGR5552Gray_8u_C2C1R( src, 0, data, 0, cvSize(m_width,1) ); else icvCvt_BGR5552BGR_8u_C2C3R( src, 0, data, 0, cvSize(m_width,1) ); } result = true; break; /************************* 16 BPP ************************/ case 16: for( y = 0; y < m_height; y++, data += step ) { m_strm.getBytes( src, src_pitch ); if( !color ) icvCvt_BGR5652Gray_8u_C2C1R( src, 0, data, 0, cvSize(m_width,1) ); else icvCvt_BGR5652BGR_8u_C2C3R( src, 0, data, 0, cvSize(m_width,1) ); } result = true; break; /************************* 24 BPP ************************/ case 24: for( y = 0; y < m_height; y++, data += step ) { m_strm.getBytes( src, src_pitch ); if(!color) icvCvt_BGR2Gray_8u_C3C1R( src, 0, data, 0, cvSize(m_width,1) ); else memcpy( data, src, m_width*3 ); } result = true; break; /************************* 32 BPP ************************/ case 32: for( y = 0; y < m_height; y++, data += step ) { m_strm.getBytes( src, src_pitch ); if( !color ) icvCvt_BGRA2Gray_8u_C4C1R( src, 0, data, 0, cvSize(m_width,1) ); else icvCvt_BGRA2BGR_8u_C4C3R( src, 0, data, 0, cvSize(m_width,1) ); } result = true; break; default: assert(0); } } catch(...) { } return result; } ////////////////////////////////////////////////////////////////////////////////////////// BmpEncoder::BmpEncoder() { m_description = "Windows bitmap (*.bmp;*.dib)"; m_buf_supported = true; } BmpEncoder::~BmpEncoder() { } ImageEncoder BmpEncoder::newEncoder() const { return new BmpEncoder; } bool BmpEncoder::write( const Mat& img, const vector& ) { int width = img.cols, height = img.rows, channels = img.channels(); int fileStep = (width*channels + 3) & -4; uchar zeropad[] = "\0\0\0\0"; WLByteStream strm; if( m_buf ) { if( !strm.open( *m_buf ) ) return false; } else if( !strm.open( m_filename )) return false; int bitmapHeaderSize = 40; int paletteSize = channels > 1 ? 0 : 1024; int headerSize = 14 /* fileheader */ + bitmapHeaderSize + paletteSize; int fileSize = fileStep*height + headerSize; PaletteEntry palette[256]; if( m_buf ) m_buf->reserve( alignSize(fileSize + 16, 256) ); // write signature 'BM' strm.putBytes( fmtSignBmp, (int)strlen(fmtSignBmp) ); // write file header strm.putDWord( fileSize ); // file size strm.putDWord( 0 ); strm.putDWord( headerSize ); // write bitmap header strm.putDWord( bitmapHeaderSize ); strm.putDWord( width ); strm.putDWord( height ); strm.putWord( 1 ); strm.putWord( channels << 3 ); strm.putDWord( BMP_RGB ); strm.putDWord( 0 ); strm.putDWord( 0 ); strm.putDWord( 0 ); strm.putDWord( 0 ); strm.putDWord( 0 ); if( channels == 1 ) { FillGrayPalette( palette, 8 ); strm.putBytes( palette, sizeof(palette)); } width *= channels; for( int y = height - 1; y >= 0; y-- ) { strm.putBytes( img.data + img.step*y, width ); if( fileStep > width ) strm.putBytes( zeropad, fileStep - width ); } strm.close(); return true; } }