/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2017 jean-pierre.charras * Copyright (C) 2011-2023 KiCad Developers, see AUTHORS.txt for contributors. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #include #include #include // for KiROUND #include // for make_unique, unique_ptr #include #include #include // for wxBitmap #include BITMAP_BASE::BITMAP_BASE( const VECTOR2I& pos ) { m_scale = 1.0; // 1.0 = original bitmap size m_bitmap = nullptr; m_image = nullptr; m_originalImage = nullptr; m_ppi = 300; // the bitmap definition. the default is 300PPI m_pixelSizeIu = 254000.0 / m_ppi; // a pixel size value OK for bitmaps using 300 PPI // for Eeschema which uses currently 254000PPI m_isMirrored = false; m_rotation = ANGLE_0; } BITMAP_BASE::BITMAP_BASE( const BITMAP_BASE& aSchBitmap ) { m_scale = aSchBitmap.m_scale; m_ppi = aSchBitmap.m_ppi; m_pixelSizeIu = aSchBitmap.m_pixelSizeIu; m_isMirrored = aSchBitmap.m_isMirrored; m_rotation = aSchBitmap.m_rotation; m_image = nullptr; m_bitmap = nullptr; m_originalImage = nullptr; if( aSchBitmap.m_image ) { m_image = new wxImage( *aSchBitmap.m_image ); m_bitmap = new wxBitmap( *m_image ); m_originalImage = new wxImage( *aSchBitmap.m_originalImage ); m_imageId = aSchBitmap.m_imageId; } } void BITMAP_BASE::SetImage( wxImage* aImage ) { delete m_image; m_image = aImage; delete m_originalImage; m_originalImage = new wxImage( *aImage ); rebuildBitmap(); } void BITMAP_BASE::rebuildBitmap( bool aResetID ) { if( m_bitmap ) delete m_bitmap; m_bitmap = new wxBitmap( *m_image ); if( aResetID ) m_imageId = KIID(); } void BITMAP_BASE::ImportData( BITMAP_BASE* aItem ) { *m_image = *aItem->m_image; *m_bitmap = *aItem->m_bitmap; *m_originalImage = *aItem->m_originalImage; m_imageId = aItem->m_imageId; m_scale = aItem->m_scale; m_ppi = aItem->m_ppi; m_pixelSizeIu = aItem->m_pixelSizeIu; m_isMirrored = aItem->m_isMirrored; m_rotation = aItem->m_rotation; } bool BITMAP_BASE::ReadImageFile( wxInputStream& aInStream ) { std::unique_ptr new_image = std::make_unique(); if( !new_image->LoadFile( aInStream ) ) return false; delete m_image; m_image = new_image.release(); delete m_originalImage; m_originalImage = new wxImage( *m_image ); rebuildBitmap(); return true; } bool BITMAP_BASE::ReadImageFile( const wxString& aFullFilename ) { wxImage* new_image = new wxImage(); if( !new_image->LoadFile( aFullFilename ) ) { delete new_image; return false; } delete m_image; m_image = new_image; delete m_originalImage; m_originalImage = new wxImage( *m_image ); rebuildBitmap(); // Todo: eventually we need to support dpi / scaling in both dimensions int dpiX = m_originalImage->GetOptionInt( wxIMAGE_OPTION_RESOLUTIONX ); if( dpiX > 1 ) { if( m_originalImage->GetOptionInt( wxIMAGE_OPTION_RESOLUTIONUNIT ) == wxIMAGE_RESOLUTION_CM ) m_ppi = KiROUND( dpiX * 2.54 ); else m_ppi = dpiX; } return true; } bool BITMAP_BASE::SaveData( FILE* aFile ) const { if( m_image ) { wxMemoryOutputStream stream; m_image->SaveFile( stream, wxBITMAP_TYPE_PNG ); // Write binary data in hexadecimal form (ASCII) wxStreamBuffer* buffer = stream.GetOutputStreamBuffer(); char* begin = (char*) buffer->GetBufferStart(); for( int ii = 0; begin < buffer->GetBufferEnd(); begin++, ii++ ) { if( ii >= 32 ) { ii = 0; if( fprintf( aFile, "\n" ) == EOF ) return false; } if( fprintf( aFile, "%2.2X ", *begin & 0xFF ) == EOF ) return false; } } return true; } void BITMAP_BASE::SaveData( wxArrayString& aPngStrings ) const { if( m_image ) { wxMemoryOutputStream stream; m_image->SaveFile( stream, wxBITMAP_TYPE_PNG ); // Write binary data in hexadecimal form (ASCII) wxStreamBuffer* buffer = stream.GetOutputStreamBuffer(); char* begin = (char*) buffer->GetBufferStart(); wxString line; for( int ii = 0; begin < buffer->GetBufferEnd(); begin++, ii++ ) { if( ii >= 32 ) { ii = 0; aPngStrings.Add( line ); line.Empty(); } line << wxString::Format( wxT( "%2.2X " ), *begin & 0xFF ); } // Add last line: if( !line.IsEmpty() ) aPngStrings.Add( line ); } } bool BITMAP_BASE::LoadData( LINE_READER& aLine, wxString& aErrorMsg ) { wxMemoryOutputStream stream; char* line; while( true ) { if( !aLine.ReadLine() ) { aErrorMsg = wxT("Unexpected end of data"); return false; } line = aLine.Line(); if( strncasecmp( line, "EndData", 4 ) == 0 ) { // all the PNG date is read. // We expect here m_image and m_bitmap are void m_image = new wxImage(); wxMemoryInputStream istream( stream ); m_image->LoadFile( istream, wxBITMAP_TYPE_PNG ); m_bitmap = new wxBitmap( *m_image ); m_originalImage = new wxImage( *m_image ); break; } // Read PNG data, stored in hexadecimal, // each byte = 2 hexadecimal digits and a space between 2 bytes // and put it in memory stream buffer int len = strlen( line ); for( ; len > 0; len -= 3, line += 3 ) { int value = 0; if( sscanf( line, "%X", &value ) == 1 ) stream.PutC( (char) value ); else break; } } return true; } const BOX2I BITMAP_BASE::GetBoundingBox() const { BOX2I bbox; VECTOR2I size = GetSize(); bbox.Inflate( size.x / 2, size.y / 2 ); return bbox; } void BITMAP_BASE::DrawBitmap( wxDC* aDC, const VECTOR2I& aPos ) { if( m_bitmap == nullptr ) return; VECTOR2I pos = aPos; VECTOR2I size = GetSize(); // This fixes a bug in OSX that should be fixed in the 3.0.3 version or later. if( ( size.x == 0 ) || ( size.y == 0 ) ) return; // To draw the bitmap, pos is the upper left corner position pos.x -= size.x / 2; pos.y -= size.y / 2; double scale; int logicalOriginX, logicalOriginY; aDC->GetUserScale( &scale, &scale ); aDC->GetLogicalOrigin( &logicalOriginX, &logicalOriginY ); // We already have issues to draw a bitmap on the wxDC, depending on wxWidgets version. // Now we have an issue on wxWidgets 3.1.6 to fix the clip area // and the bitmap position when using TransformMatrix // So for version == 3.1.6 do not use it // Be carefull before changing the code. bool useTransform = aDC->CanUseTransformMatrix(); #if wxCHECK_VERSION( 3, 1, 6 ) && !wxCHECK_VERSION( 3, 1, 7 ) useTransform = false; #endif wxAffineMatrix2D init_matrix = aDC->GetTransformMatrix(); // Note: clipping bitmap area was made to fix a minor issue in old versions of // Kicad/wxWidgets (5.1 / wx 3.0) // However SetClippingRegion creates a lot of issues (different ways to fix the // position and size of the area, depending on wxWidget version)because it changes with // each versions of wxWigets, so it is now disabled // However the code is still here, just in case // #define USE_CLIP_AREA wxPoint clipAreaPos; if( useTransform ) { wxAffineMatrix2D matrix = aDC->GetTransformMatrix(); matrix.Translate( pos.x, pos.y ); matrix.Scale( GetScalingFactor(), GetScalingFactor() ); aDC->SetTransformMatrix( matrix ); // Needed on wx <= 3.1.5, and this is strange... // Nevertheless, this code has problem (the bitmap is not seen) // with wx version > 3.1.5 clipAreaPos.x = pos.x; clipAreaPos.y = pos.y; pos.x = pos.y = 0; } else { aDC->SetUserScale( scale * GetScalingFactor(), scale * GetScalingFactor() ); aDC->SetLogicalOrigin( logicalOriginX / GetScalingFactor(), logicalOriginY / GetScalingFactor() ); pos.x = KiROUND( pos.x / GetScalingFactor() ); pos.y = KiROUND( pos.y / GetScalingFactor() ); size.x = KiROUND( size.x / GetScalingFactor() ); size.y = KiROUND( size.y / GetScalingFactor() ); clipAreaPos.x = pos.x; clipAreaPos.y = pos.y; } #ifdef USE_CLIP_AREA aDC->DestroyClippingRegion(); aDC->SetClippingRegion( clipAreaPos, wxSize( size.x, size.y ) ); #endif if( GetGRForceBlackPenState() ) { wxBitmap result( m_bitmap->ConvertToImage().ConvertToGreyscale() ); aDC->DrawBitmap( result, pos.x, pos.y, true ); } else { aDC->DrawBitmap( *m_bitmap, pos.x, pos.y, true ); } if( useTransform ) aDC->SetTransformMatrix( init_matrix ); else { aDC->SetUserScale( scale, scale ); aDC->SetLogicalOrigin( logicalOriginX, logicalOriginY ); } #ifdef USE_CLIP_AREA aDC->DestroyClippingRegion(); #endif } VECTOR2I BITMAP_BASE::GetSize() const { VECTOR2I size; if( m_bitmap ) { size.x = m_bitmap->GetWidth(); size.y = m_bitmap->GetHeight(); size.x = KiROUND( size.x * GetScalingFactor() ); size.y = KiROUND( size.y * GetScalingFactor() ); } return size; } void BITMAP_BASE::Mirror( bool aVertically ) { if( m_image ) { *m_image = m_image->Mirror( not aVertically ); m_isMirrored = !m_isMirrored; rebuildBitmap( false ); } } void BITMAP_BASE::Rotate( bool aRotateCCW ) { if( m_image ) { *m_image = m_image->Rotate90( aRotateCCW ); m_rotation += ( aRotateCCW ? -ANGLE_90 : ANGLE_90 ); rebuildBitmap( false ); } } void BITMAP_BASE::ConvertToGreyscale() { if( m_image ) { *m_image = m_image->ConvertToGreyscale(); *m_originalImage = m_originalImage->ConvertToGreyscale(); rebuildBitmap(); } } void BITMAP_BASE::PlotImage( PLOTTER* aPlotter, const VECTOR2I& aPos, const COLOR4D& aDefaultColor, int aDefaultPensize ) const { if( m_image == nullptr ) return; // These 2 lines are useful only for plotters that cannot plot a bitmap // and plot a rectangle instead of. aPlotter->SetColor( aDefaultColor ); aPlotter->SetCurrentLineWidth( aDefaultPensize ); aPlotter->PlotImage( *m_image, aPos, GetScalingFactor() ); }