/*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*/ /****************************************************************************************\ A part of the file implements TIFF reader on base of libtiff library (see otherlibs/_graphics/readme.txt for copyright notice) \****************************************************************************************/ #include "precomp.hpp" #include "grfmt_tiff.hpp" namespace cv { static const char fmtSignTiffII[] = "II\x2a\x00"; static const char fmtSignTiffMM[] = "MM\x00\x2a"; #ifdef HAVE_TIFF #include "tiff.h" #include "tiffio.h" static int grfmt_tiff_err_handler_init = 0; static void GrFmtSilentTIFFErrorHandler( const char*, const char*, va_list ) {} TiffDecoder::TiffDecoder() { m_tif = 0; if( !grfmt_tiff_err_handler_init ) { grfmt_tiff_err_handler_init = 1; TIFFSetErrorHandler( GrFmtSilentTIFFErrorHandler ); TIFFSetWarningHandler( GrFmtSilentTIFFErrorHandler ); } } void TiffDecoder::close() { if( m_tif ) { TIFF* tif = (TIFF*)m_tif; TIFFClose( tif ); m_tif = 0; } } TiffDecoder::~TiffDecoder() { close(); } size_t TiffDecoder::signatureLength() const { return 4; } bool TiffDecoder::checkSignature( const string& signature ) const { return signature.size() >= 4 && (memcmp(signature.c_str(), fmtSignTiffII, 4) == 0 || memcmp(signature.c_str(), fmtSignTiffMM, 4) == 0); } ImageDecoder TiffDecoder::newDecoder() const { return new TiffDecoder; } bool TiffDecoder::readHeader() { bool result = false; close(); TIFF* tif = TIFFOpen( m_filename.c_str(), "rb" ); if( tif ) { int width = 0, height = 0, photometric = 0; m_tif = tif; if( TIFFGetField( tif, TIFFTAG_IMAGEWIDTH, &width ) && TIFFGetField( tif, TIFFTAG_IMAGELENGTH, &height ) && TIFFGetField( tif, TIFFTAG_PHOTOMETRIC, &photometric )) { int bpp=8, ncn = photometric > 1 ? 3 : 1; TIFFGetField( tif, TIFFTAG_BITSPERSAMPLE, &bpp ); TIFFGetField( tif, TIFFTAG_SAMPLESPERPIXEL, &ncn ); m_width = width; m_height = height; if( bpp > 8 && ((photometric != 2 && photometric != 1) || (ncn != 1 && ncn != 3 && ncn != 4))) bpp = 8; switch(bpp) { case 8: m_type = CV_MAKETYPE(CV_8U, photometric > 1 ? 3 : 1); break; case 16: m_type = CV_MAKETYPE(CV_16U, photometric > 1 ? 3 : 1); break; case 32: m_type = CV_MAKETYPE(CV_32F, photometric > 1 ? 3 : 1); break; case 64: m_type = CV_MAKETYPE(CV_64F, photometric > 1 ? 3 : 1); break; default: result = false; } result = true; } } if( !result ) close(); return result; } bool TiffDecoder::readData( Mat& img ) { bool result = false; bool color = img.channels() > 1; uchar* data = img.data; int step = (int)img.step; if( img.depth() != CV_8U && img.depth() != CV_16U && img.depth() != CV_32F && img.depth() != CV_64F ) return false; if( m_tif && m_width && m_height ) { TIFF* tif = (TIFF*)m_tif; int tile_width0 = m_width, tile_height0 = 0; int x, y, i; int is_tiled = TIFFIsTiled(tif); int photometric; TIFFGetField( tif, TIFFTAG_PHOTOMETRIC, &photometric ); int bpp = 8, ncn = photometric > 1 ? 3 : 1; TIFFGetField( tif, TIFFTAG_BITSPERSAMPLE, &bpp ); TIFFGetField( tif, TIFFTAG_SAMPLESPERPIXEL, &ncn ); const int bitsPerByte = 8; int dst_bpp = img.elemSize1() * bitsPerByte; if(dst_bpp == 8) { char errmsg[1024]; if(!TIFFRGBAImageOK( tif, errmsg )) { close(); return false; } } if( (!is_tiled && TIFFGetField( tif, TIFFTAG_ROWSPERSTRIP, &tile_height0 )) || (is_tiled && TIFFGetField( tif, TIFFTAG_TILEWIDTH, &tile_width0 ) && TIFFGetField( tif, TIFFTAG_TILELENGTH, &tile_height0 ))) { if( tile_width0 <= 0 ) tile_width0 = m_width; if( tile_height0 <= 0 ) tile_height0 = m_height; AutoBuffer _buffer(tile_height0*tile_width0*8); uchar* buffer = _buffer; ushort* buffer16 = (ushort*)buffer; float* buffer32 = (float*)buffer; double* buffer64 = (double*)buffer; int tileidx = 0; for( y = 0; y < m_height; y += tile_height0, data += step*tile_height0 ) { int tile_height = tile_height0; if( y + tile_height > m_height ) tile_height = m_height - y; for( x = 0; x < m_width; x += tile_width0, tileidx++ ) { int tile_width = tile_width0, ok; if( x + tile_width > m_width ) tile_width = m_width - x; switch(dst_bpp) { case 8: { if( !is_tiled ) ok = TIFFReadRGBAStrip( tif, y, (uint32*)buffer ); else ok = TIFFReadRGBATile( tif, x, y, (uint32*)buffer ); if( !ok ) { close(); return false; } for( i = 0; i < tile_height; i++ ) if( color ) icvCvt_BGRA2BGR_8u_C4C3R( buffer + i*tile_width*4, 0, data + x*3 + step*(tile_height - i - 1), 0, cvSize(tile_width,1), 2 ); else icvCvt_BGRA2Gray_8u_C4C1R( buffer + i*tile_width*4, 0, data + x + step*(tile_height - i - 1), 0, cvSize(tile_width,1), 2 ); break; } case 16: { if( !is_tiled ) ok = (int)TIFFReadEncodedStrip( tif, tileidx, (uint32*)buffer, (tsize_t)-1 ) >= 0; else ok = (int)TIFFReadEncodedTile( tif, tileidx, (uint32*)buffer, (tsize_t)-1 ) >= 0; if( !ok ) { close(); return false; } for( i = 0; i < tile_height; i++ ) { if( color ) { if( ncn == 1 ) { icvCvt_Gray2BGR_16u_C1C3R(buffer16 + i*tile_width*ncn, 0, (ushort*)(data + step*i) + x*3, 0, cvSize(tile_width,1) ); } else if( ncn == 3 ) { icvCvt_RGB2BGR_16u_C3R(buffer16 + i*tile_width*ncn, 0, (ushort*)(data + step*i) + x*3, 0, cvSize(tile_width,1) ); } else { icvCvt_BGRA2BGR_16u_C4C3R(buffer16 + i*tile_width*ncn, 0, (ushort*)(data + step*i) + x*3, 0, cvSize(tile_width,1), 2 ); } } else { if( ncn == 1 ) { memcpy((ushort*)(data + step*i)+x, buffer16 + i*tile_width*ncn, tile_width*sizeof(buffer16[0])); } else { icvCvt_BGRA2Gray_16u_CnC1R(buffer16 + i*tile_width*ncn, 0, (ushort*)(data + step*i) + x, 0, cvSize(tile_width,1), ncn, 2 ); } } } break; } case 32: case 64: { if( !is_tiled ) ok = (int)TIFFReadEncodedStrip( tif, tileidx, buffer, (tsize_t)-1 ) >= 0; else ok = (int)TIFFReadEncodedTile( tif, tileidx, buffer, (tsize_t)-1 ) >= 0; if( !ok || ncn != 1 ) { close(); return false; } for( i = 0; i < tile_height; i++ ) { if(dst_bpp == 32) { memcpy((float*)(data + step*i)+x, buffer32 + i*tile_width*ncn, tile_width*sizeof(buffer32[0])); } else { memcpy((double*)(data + step*i)+x, buffer64 + i*tile_width*ncn, tile_width*sizeof(buffer64[0])); } } break; } default: { close(); return false; } } } } result = true; } } close(); return result; } #endif ////////////////////////////////////////////////////////////////////////////////////////// TiffEncoder::TiffEncoder() { m_description = "TIFF Files (*.tiff;*.tif)"; #ifdef HAVE_TIFF m_buf_supported = false; #else m_buf_supported = true; #endif } TiffEncoder::~TiffEncoder() { } ImageEncoder TiffEncoder::newEncoder() const { return new TiffEncoder; } bool TiffEncoder::isFormatSupported( int depth ) const { return depth == CV_8U || depth == CV_16U; } void TiffEncoder::writeTag( WLByteStream& strm, TiffTag tag, TiffFieldType fieldType, int count, int value ) { strm.putWord( tag ); strm.putWord( fieldType ); strm.putDWord( count ); strm.putDWord( value ); } #ifdef HAVE_TIFF bool TiffEncoder::writeLibTiff( const Mat& img, const vector& /*params*/) { int channels = img.channels(); int width = img.cols, height = img.rows; int depth = img.depth(); int bitsPerChannel = -1; switch (depth) { case CV_8U: { bitsPerChannel = 8; break; } case CV_16U: { bitsPerChannel = 16; break; } default: { return false; } } const int bitsPerByte = 8; size_t fileStep = (width * channels * bitsPerChannel) / bitsPerByte; int rowsPerStrip = (1 << 13)/fileStep; if( rowsPerStrip < 1 ) rowsPerStrip = 1; if( rowsPerStrip > height ) rowsPerStrip = height; // do NOT put "wb" as the mode, because the b means "big endian" mode, not "binary" mode. // http://www.remotesensing.org/libtiff/man/TIFFOpen.3tiff.html TIFF* pTiffHandle = TIFFOpen(m_filename.c_str(), "w"); if (!pTiffHandle) { return false; } // defaults for now, maybe base them on params in the future int compression = COMPRESSION_LZW; int predictor = PREDICTOR_HORIZONTAL; int colorspace = channels > 1 ? PHOTOMETRIC_RGB : PHOTOMETRIC_MINISBLACK; if ( !TIFFSetField(pTiffHandle, TIFFTAG_IMAGEWIDTH, width) || !TIFFSetField(pTiffHandle, TIFFTAG_IMAGELENGTH, height) || !TIFFSetField(pTiffHandle, TIFFTAG_BITSPERSAMPLE, bitsPerChannel) || !TIFFSetField(pTiffHandle, TIFFTAG_COMPRESSION, compression) || !TIFFSetField(pTiffHandle, TIFFTAG_PHOTOMETRIC, colorspace) || !TIFFSetField(pTiffHandle, TIFFTAG_SAMPLESPERPIXEL, channels) || !TIFFSetField(pTiffHandle, TIFFTAG_PLANARCONFIG, PLANARCONFIG_CONTIG) || !TIFFSetField(pTiffHandle, TIFFTAG_ROWSPERSTRIP, rowsPerStrip) || !TIFFSetField(pTiffHandle, TIFFTAG_PREDICTOR, predictor) ) { TIFFClose(pTiffHandle); return false; } // row buffer, because TIFFWriteScanline modifies the original data! size_t scanlineSize = TIFFScanlineSize(pTiffHandle); AutoBuffer _buffer(scanlineSize+32); uchar* buffer = _buffer; if (!buffer) { TIFFClose(pTiffHandle); return false; } for (int y = 0; y < height; ++y) { switch(channels) { case 1: { memcpy(buffer, img.data + img.step * y, scanlineSize); break; } case 3: { if (depth == CV_8U) icvCvt_BGR2RGB_8u_C3R( img.data + img.step*y, 0, buffer, 0, cvSize(width,1) ); else icvCvt_BGR2RGB_16u_C3R( (const ushort*)(img.data + img.step*y), 0, (ushort*)buffer, 0, cvSize(width,1) ); break; } case 4: { if (depth == CV_8U) icvCvt_BGRA2RGBA_8u_C4R( img.data + img.step*y, 0, buffer, 0, cvSize(width,1) ); else icvCvt_BGRA2RGBA_16u_C4R( (const ushort*)(img.data + img.step*y), 0, (ushort*)buffer, 0, cvSize(width,1) ); } default: { TIFFClose(pTiffHandle); return false; } } int writeResult = TIFFWriteScanline(pTiffHandle, buffer, y, 0); if (writeResult != 1) { TIFFClose(pTiffHandle); return false; } } TIFFClose(pTiffHandle); return true; } #endif #ifdef HAVE_TIFF bool TiffEncoder::write( const Mat& img, const vector& params) #else bool TiffEncoder::write( const Mat& img, const vector& /*params*/) #endif { int channels = img.channels(); int width = img.cols, height = img.rows; int depth = img.depth(); if (depth != CV_8U && depth != CV_16U) return false; int bytesPerChannel = depth == CV_8U ? 1 : 2; int fileStep = width * channels * bytesPerChannel; WLByteStream strm; if( m_buf ) { if( !strm.open(*m_buf) ) return false; } else { #ifdef HAVE_TIFF return writeLibTiff(img, params); #else if( !strm.open(m_filename) ) return false; #endif } int rowsPerStrip = (1 << 13)/fileStep; if( rowsPerStrip < 1 ) rowsPerStrip = 1; if( rowsPerStrip > height ) rowsPerStrip = height; int i, stripCount = (height + rowsPerStrip - 1) / rowsPerStrip; if( m_buf ) m_buf->reserve( alignSize(stripCount*8 + fileStep*height + 256, 256) ); /*#if defined _DEBUG || !defined WIN32 int uncompressedRowSize = rowsPerStrip * fileStep; #endif*/ int directoryOffset = 0; AutoBuffer stripOffsets(stripCount); AutoBuffer stripCounts(stripCount); AutoBuffer _buffer(fileStep+32); uchar* buffer = _buffer; int stripOffsetsOffset = 0; int stripCountsOffset = 0; int bitsPerSample = 8 * bytesPerChannel; int y = 0; strm.putBytes( fmtSignTiffII, 4 ); strm.putDWord( directoryOffset ); // write an image data first (the most reasonable way // for compressed images) for( i = 0; i < stripCount; i++ ) { int limit = y + rowsPerStrip; if( limit > height ) limit = height; stripOffsets[i] = strm.getPos(); for( ; y < limit; y++ ) { if( channels == 3 ) { if (depth == CV_8U) icvCvt_BGR2RGB_8u_C3R( img.data + img.step*y, 0, buffer, 0, cvSize(width,1) ); else icvCvt_BGR2RGB_16u_C3R( (const ushort*)(img.data + img.step*y), 0, (ushort*)buffer, 0, cvSize(width,1) ); } else { if( channels == 4 ) { if (depth == CV_8U) icvCvt_BGRA2RGBA_8u_C4R( img.data + img.step*y, 0, buffer, 0, cvSize(width,1) ); else icvCvt_BGRA2RGBA_16u_C4R( (const ushort*)(img.data + img.step*y), 0, (ushort*)buffer, 0, cvSize(width,1) ); } } strm.putBytes( channels > 1 ? buffer : img.data + img.step*y, fileStep ); } stripCounts[i] = (short)(strm.getPos() - stripOffsets[i]); /*assert( stripCounts[i] == uncompressedRowSize || stripCounts[i] < uncompressedRowSize && i == stripCount - 1);*/ } if( stripCount > 2 ) { stripOffsetsOffset = strm.getPos(); for( i = 0; i < stripCount; i++ ) strm.putDWord( stripOffsets[i] ); stripCountsOffset = strm.getPos(); for( i = 0; i < stripCount; i++ ) strm.putWord( stripCounts[i] ); } else if(stripCount == 2) { stripOffsetsOffset = strm.getPos(); for (i = 0; i < stripCount; i++) { strm.putDWord (stripOffsets [i]); } stripCountsOffset = stripCounts [0] + (stripCounts [1] << 16); } else { stripOffsetsOffset = stripOffsets[0]; stripCountsOffset = stripCounts[0]; } if( channels > 1 ) { int bitsPerSamplePos = strm.getPos(); strm.putWord(bitsPerSample); strm.putWord(bitsPerSample); strm.putWord(bitsPerSample); if( channels == 4 ) strm.putWord(bitsPerSample); bitsPerSample = bitsPerSamplePos; } directoryOffset = strm.getPos(); // write header strm.putWord( 9 ); /* warning: specification 5.0 of Tiff want to have tags in ascending order. This is a non-fatal error, but this cause warning with some tools. So, keep this in ascending order */ writeTag( strm, TIFF_TAG_WIDTH, TIFF_TYPE_LONG, 1, width ); writeTag( strm, TIFF_TAG_HEIGHT, TIFF_TYPE_LONG, 1, height ); writeTag( strm, TIFF_TAG_BITS_PER_SAMPLE, TIFF_TYPE_SHORT, channels, bitsPerSample ); writeTag( strm, TIFF_TAG_COMPRESSION, TIFF_TYPE_LONG, 1, TIFF_UNCOMP ); writeTag( strm, TIFF_TAG_PHOTOMETRIC, TIFF_TYPE_SHORT, 1, channels > 1 ? 2 : 1 ); writeTag( strm, TIFF_TAG_STRIP_OFFSETS, TIFF_TYPE_LONG, stripCount, stripOffsetsOffset ); writeTag( strm, TIFF_TAG_SAMPLES_PER_PIXEL, TIFF_TYPE_SHORT, 1, channels ); writeTag( strm, TIFF_TAG_ROWS_PER_STRIP, TIFF_TYPE_LONG, 1, rowsPerStrip ); writeTag( strm, TIFF_TAG_STRIP_COUNTS, stripCount > 1 ? TIFF_TYPE_SHORT : TIFF_TYPE_LONG, stripCount, stripCountsOffset ); strm.putDWord(0); strm.close(); if( m_buf ) { (*m_buf)[4] = (uchar)directoryOffset; (*m_buf)[5] = (uchar)(directoryOffset >> 8); (*m_buf)[6] = (uchar)(directoryOffset >> 16); (*m_buf)[7] = (uchar)(directoryOffset >> 24); } else { // write directory offset FILE* f = fopen( m_filename.c_str(), "r+b" ); buffer[0] = (uchar)directoryOffset; buffer[1] = (uchar)(directoryOffset >> 8); buffer[2] = (uchar)(directoryOffset >> 16); buffer[3] = (uchar)(directoryOffset >> 24); fseek( f, 4, SEEK_SET ); fwrite( buffer, 1, 4, f ); fclose(f); } return true; } }