/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * This file incorporates work covered by the following license notice: * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ #include #include #include #include #include #include #include #include "sane.hxx" #include #include #include #include #include #include #if (OSL_DEBUG_LEVEL > 0) || defined DBG_UTIL #include #define dump_state( a, b, c, d ) fprintf( stderr, a, b, c, d ); #else #define dump_state( a, b, c, d ) ; #endif static void dbg_msg( const char* pString, ... ) { #if (OSL_DEBUG_LEVEL > 0) || defined DBG_UTIL va_list ap; va_start( ap, pString ); vfprintf( stderr, pString, ap ); va_end( ap ); #else (void)pString; #endif } #define FAIL_SHUTDOWN_STATE( x, y, z ) \ if( x != SANE_STATUS_GOOD ) \ { \ dump_state( "%s returned error %d (%s)\n", \ y, x, p_strstatus( x ) ); \ DeInit(); \ return z; \ } #define FAIL_STATE( x, y, z ) \ if( x != SANE_STATUS_GOOD ) \ { \ dump_state( "%s returned error %d (%s)\n", \ y, x, p_strstatus( x ) ); \ return z; \ } #define DUMP_STATE( x, y ) \ if( x != SANE_STATUS_GOOD ) \ { \ dump_state( "%s returned error %d (%s)\n", \ y, x, p_strstatus( x ) ); \ } int Sane::nRefCount = 0; oslModule Sane::pSaneLib = nullptr; SANE_Int Sane::nVersion = 0; SANE_Device** Sane::ppDevices = nullptr; int Sane::nDevices = 0; SANE_Status (*Sane::p_init)( SANE_Int*, SANE_Auth_Callback ) = nullptr; void (*Sane::p_exit)() = nullptr; SANE_Status (*Sane::p_get_devices)( const SANE_Device***, SANE_Bool ) = nullptr; SANE_Status (*Sane::p_open)( SANE_String_Const, SANE_Handle ) = nullptr; void (*Sane::p_close)( SANE_Handle ) = nullptr; const SANE_Option_Descriptor* (*Sane::p_get_option_descriptor)( SANE_Handle, SANE_Int ) = nullptr; SANE_Status (*Sane::p_control_option)( SANE_Handle, SANE_Int, SANE_Action, void*, SANE_Int* ) = nullptr; SANE_Status (*Sane::p_get_parameters)( SANE_Handle, SANE_Parameters* ) = nullptr; SANE_Status (*Sane::p_start)( SANE_Handle ) = nullptr; SANE_Status (*Sane::p_read)( SANE_Handle, SANE_Byte*, SANE_Int, SANE_Int* ) = nullptr; void (*Sane::p_cancel)( SANE_Handle ) = nullptr; SANE_Status (*Sane::p_set_io_mode)( SANE_Handle, SANE_Bool ) = nullptr; SANE_Status (*Sane::p_get_select_fd)( SANE_Handle, SANE_Int* ) = nullptr; SANE_String_Const (*Sane::p_strstatus)( SANE_Status ) = nullptr; static bool bSaneSymbolLoadFailed = false; inline oslGenericFunction Sane::LoadSymbol( const char* pSymbolname ) { oslGenericFunction pFunction = osl_getAsciiFunctionSymbol( pSaneLib, pSymbolname ); if( ! pFunction ) { fprintf( stderr, "Could not load symbol %s\n", pSymbolname ); bSaneSymbolLoadFailed = true; } return pFunction; } SANE_Status Sane::ControlOption( int nOption, SANE_Action nAction, void* pData ) { SANE_Int nInfo = 0; SANE_Status nStatus = p_control_option( maHandle, static_cast(nOption), nAction, pData, &nInfo ); DUMP_STATE( nStatus, "sane_control_option" ); #if OSL_DEBUG_LEVEL > 0 if( nStatus != SANE_STATUS_GOOD ) { const char* pAction = "Unknown"; switch( nAction ) { case SANE_ACTION_GET_VALUE: pAction = "SANE_ACTION_GET_VALUE";break; case SANE_ACTION_SET_VALUE: pAction = "SANE_ACTION_SET_VALUE";break; case SANE_ACTION_SET_AUTO: pAction = "SANE_ACTION_SET_AUTO";break; } dbg_msg( "Option: \"%s\" action: %s\n", OUStringToOString(GetOptionName(nOption), osl_getThreadTextEncoding()).getStr(), pAction ); } #endif if( nInfo & SANE_INFO_RELOAD_OPTIONS ) ReloadOptions(); return nStatus; } Sane::Sane() : mnOptions( 0 ), mnDevice( -1 ), maHandle( nullptr ) { if( ! nRefCount || ! pSaneLib ) Init(); nRefCount++; }; Sane::~Sane() { if( IsOpen() ) Close(); nRefCount--; if( ! nRefCount && pSaneLib ) DeInit(); } void Sane::Init() { OUString sSaneLibName( "libsane" SAL_DLLEXTENSION ); pSaneLib = osl_loadModule( sSaneLibName.pData, SAL_LOADMODULE_LAZY ); if( ! pSaneLib ) { sSaneLibName = "libsane" SAL_DLLEXTENSION ".1"; pSaneLib = osl_loadModule( sSaneLibName.pData, SAL_LOADMODULE_LAZY ); } // try reasonable places that might not be in the library search path if( ! pSaneLib ) { OUString sSaneLibSystemPath( "/usr/local/lib/libsane" SAL_DLLEXTENSION ); osl_getFileURLFromSystemPath( sSaneLibSystemPath.pData, &sSaneLibName.pData ); pSaneLib = osl_loadModule( sSaneLibName.pData, SAL_LOADMODULE_LAZY ); } if( pSaneLib ) { bSaneSymbolLoadFailed = false; p_init = reinterpret_cast( LoadSymbol( "sane_init" )); p_exit = reinterpret_cast( LoadSymbol( "sane_exit" )); p_get_devices = reinterpret_cast( LoadSymbol( "sane_get_devices" )); p_open = reinterpret_cast( LoadSymbol( "sane_open" )); p_close = reinterpret_cast( LoadSymbol( "sane_close" )); p_get_option_descriptor = reinterpret_cast( LoadSymbol( "sane_get_option_descriptor" )); p_control_option = reinterpret_cast( LoadSymbol( "sane_control_option" )); p_get_parameters = reinterpret_cast( LoadSymbol( "sane_get_parameters" )); p_start = reinterpret_cast( LoadSymbol( "sane_start" )); p_read = reinterpret_cast( LoadSymbol( "sane_read" )); p_cancel = reinterpret_cast( LoadSymbol( "sane_cancel" )); p_set_io_mode = reinterpret_cast( LoadSymbol( "sane_set_io_mode" )); p_get_select_fd = reinterpret_cast( LoadSymbol( "sane_get_select_fd" )); p_strstatus = reinterpret_cast( LoadSymbol( "sane_strstatus" )); if( bSaneSymbolLoadFailed ) DeInit(); else { SANE_Status nStatus = p_init( &nVersion, nullptr ); FAIL_SHUTDOWN_STATE( nStatus, "sane_init", ); nStatus = p_get_devices( const_cast(&ppDevices), SANE_FALSE ); FAIL_SHUTDOWN_STATE( nStatus, "sane_get_devices", ); for( nDevices = 0 ; ppDevices[ nDevices ]; nDevices++ ) ; } } #if (OSL_DEBUG_LEVEL > 0) || defined DBG_UTIL else fprintf( stderr, "libsane%s could not be opened: %s\n", SAL_DLLEXTENSION, dlerror() ); #endif } void Sane::DeInit() { if( pSaneLib ) { p_exit(); osl_unloadModule( pSaneLib ); pSaneLib = nullptr; } } void Sane::ReloadDevices() { if( IsOpen() ) Close(); DeInit(); Init(); } void Sane::ReloadOptions() { if( ! IsOpen() ) return; const SANE_Option_Descriptor* pZero = p_get_option_descriptor( maHandle, 0 ); SANE_Word pOptions[2]; SANE_Status nStatus = p_control_option( maHandle, 0, SANE_ACTION_GET_VALUE, static_cast(pOptions), nullptr ); if( nStatus != SANE_STATUS_GOOD ) fprintf( stderr, "Error: sane driver returned %s while reading number of options !\n", p_strstatus( nStatus ) ); mnOptions = pOptions[ 0 ]; if( o3tl::make_unsigned(pZero->size) > sizeof( SANE_Word ) ) fprintf( stderr, "driver returned number of options with larger size than SANE_Word!!!\n" ); mppOptions.reset(new const SANE_Option_Descriptor*[ mnOptions ]); mppOptions[ 0 ] = pZero; for( int i = 1; i < mnOptions; i++ ) mppOptions[ i ] = p_get_option_descriptor( maHandle, i ); CheckConsistency( nullptr, true ); maReloadOptionsLink.Call( *this ); } bool Sane::Open( const char* name ) { SANE_Status nStatus = p_open( reinterpret_cast(name), &maHandle ); FAIL_STATE( nStatus, "sane_open", false ); ReloadOptions(); if( mnDevice == -1 ) { OString aDevice( name ); for( int i = 0; i < nDevices; i++ ) { if( aDevice == ppDevices[i]->name ) { mnDevice = i; break; } } } return true; } bool Sane::Open( int n ) { if( n >= 0 && n < nDevices ) { mnDevice = n; return Open( ppDevices[n]->name ); } return false; } void Sane::Close() { if( maHandle ) { p_close( maHandle ); mppOptions.reset(); maHandle = nullptr; mnDevice = -1; } } int Sane::GetOptionByName( const char* rName ) { int i; OString aOption( rName ); for( i = 0; i < mnOptions; i++ ) { if( mppOptions[i]->name && aOption == mppOptions[i]->name ) return i; } return -1; } bool Sane::GetOptionValue( int n, bool& rRet ) { if( ! maHandle || mppOptions[n]->type != SANE_TYPE_BOOL ) return false; SANE_Word nRet; SANE_Status nStatus = ControlOption( n, SANE_ACTION_GET_VALUE, &nRet ); if( nStatus != SANE_STATUS_GOOD ) return false; rRet = nRet; return true; } bool Sane::GetOptionValue( int n, OString& rRet ) { bool bSuccess = false; if( ! maHandle || mppOptions[n]->type != SANE_TYPE_STRING ) return false; std::unique_ptr pRet(new char[mppOptions[n]->size+1]); SANE_Status nStatus = ControlOption( n, SANE_ACTION_GET_VALUE, pRet.get() ); if( nStatus == SANE_STATUS_GOOD ) { bSuccess = true; rRet = pRet.get(); } return bSuccess; } bool Sane::GetOptionValue( int n, double& rRet, int nElement ) { bool bSuccess = false; if( ! maHandle || ( mppOptions[n]->type != SANE_TYPE_INT && mppOptions[n]->type != SANE_TYPE_FIXED ) ) return false; std::unique_ptr pRet(new SANE_Word[mppOptions[n]->size/sizeof(SANE_Word)]); SANE_Status nStatus = ControlOption( n, SANE_ACTION_GET_VALUE, pRet.get() ); if( nStatus == SANE_STATUS_GOOD ) { bSuccess = true; if( mppOptions[n]->type == SANE_TYPE_INT ) rRet = static_cast(pRet[ nElement ]); else rRet = SANE_UNFIX( pRet[nElement] ); } return bSuccess; } bool Sane::GetOptionValue( int n, double* pSet ) { if( ! maHandle || ! ( mppOptions[n]->type == SANE_TYPE_FIXED || mppOptions[n]->type == SANE_TYPE_INT ) ) return false; std::unique_ptr pFixedSet(new SANE_Word[mppOptions[n]->size/sizeof(SANE_Word)]); SANE_Status nStatus = ControlOption( n, SANE_ACTION_GET_VALUE, pFixedSet.get() ); if( nStatus != SANE_STATUS_GOOD ) return false; for( size_t i = 0; i size/sizeof(SANE_Word); i++ ) { if( mppOptions[n]->type == SANE_TYPE_FIXED ) pSet[i] = SANE_UNFIX( pFixedSet[i] ); else pSet[i] = static_cast(pFixedSet[i]); } return true; } void Sane::SetOptionValue( int n, bool bSet ) { if( ! maHandle || mppOptions[n]->type != SANE_TYPE_BOOL ) return; SANE_Word nRet = bSet ? SANE_TRUE : SANE_FALSE; ControlOption( n, SANE_ACTION_SET_VALUE, &nRet ); } void Sane::SetOptionValue( int n, const OUString& rSet ) { if( ! maHandle || mppOptions[n]->type != SANE_TYPE_STRING ) return; OString aSet(OUStringToOString(rSet, osl_getThreadTextEncoding())); ControlOption( n, SANE_ACTION_SET_VALUE, const_cast(aSet.getStr()) ); } void Sane::SetOptionValue( int n, double fSet, int nElement ) { if( ! maHandle || ( mppOptions[n]->type != SANE_TYPE_INT && mppOptions[n]->type != SANE_TYPE_FIXED ) ) return; if( mppOptions[n]->size/sizeof(SANE_Word) > 1 ) { std::unique_ptr pSet(new SANE_Word[mppOptions[n]->size/sizeof(SANE_Word)]); SANE_Status nStatus = ControlOption( n, SANE_ACTION_GET_VALUE, pSet.get() ); if( nStatus == SANE_STATUS_GOOD ) { pSet[nElement] = mppOptions[n]->type == SANE_TYPE_INT ? static_cast(fSet) : SANE_FIX( fSet ); ControlOption( n, SANE_ACTION_SET_VALUE, pSet.get() ); } } else { SANE_Word nSetTo = mppOptions[n]->type == SANE_TYPE_INT ? static_cast(fSet) : SANE_FIX( fSet ); ControlOption( n, SANE_ACTION_SET_VALUE, &nSetTo ); } } void Sane::SetOptionValue( int n, double const * pSet ) { if( ! maHandle || ( mppOptions[n]->type != SANE_TYPE_INT && mppOptions[n]->type != SANE_TYPE_FIXED ) ) return; std::unique_ptr pFixedSet(new SANE_Word[mppOptions[n]->size/sizeof(SANE_Word)]); for( size_t i = 0; i < mppOptions[n]->size/sizeof(SANE_Word); i++ ) { if( mppOptions[n]->type == SANE_TYPE_FIXED ) pFixedSet[i] = SANE_FIX( pSet[i] ); else pFixedSet[i] = static_cast(pSet[i]); } ControlOption( n, SANE_ACTION_SET_VALUE, pFixedSet.get() ); } namespace { enum FrameStyleType { FrameStyle_BW, FrameStyle_Gray, FrameStyle_RGB, FrameStyle_Separated }; } #define BYTE_BUFFER_SIZE 32768 static sal_uInt8 ReadValue( FILE* fp, int depth ) { if( depth == 16 ) { sal_uInt16 nWord; // data always come in native byte order ! // 16 bits is not really supported by backends as of now // e.g. UMAX Astra 1200S delivers 16 bit but in BIGENDIAN // against SANE documentation (xscanimage gets the same result // as we do size_t items_read = fread( &nWord, 1, 2, fp ); if (items_read != 2) { SAL_WARN( "extensions.scanner", "short read, abandoning" ); return 0; } return static_cast( nWord / 256 ); } sal_uInt8 nByte; size_t items_read = fread( &nByte, 1, 1, fp ); if (items_read != 1) { SAL_WARN( "extensions.scanner", "short read, abandoning" ); return 0; } return nByte; } bool Sane::CheckConsistency( const char* pMes, bool bInit ) { static const SANE_Option_Descriptor** pDescArray = nullptr; static const SANE_Option_Descriptor* pZero = nullptr; if( bInit ) { pDescArray = mppOptions.get(); if( mppOptions ) pZero = mppOptions[0]; return true; } bool bConsistent = true; if( pDescArray != mppOptions.get() ) bConsistent = false; if( pZero != mppOptions[0] ) bConsistent = false; if( ! bConsistent ) dbg_msg( "Sane is not consistent. (%s)\n", pMes ); return bConsistent; } bool Sane::Start( BitmapTransporter& rBitmap ) { int nStream = 0, nLine = 0, i = 0; SANE_Parameters aParams; FrameStyleType eType = FrameStyle_Gray; bool bSuccess = true; bool bWidthSet = false; if( ! maHandle ) return false; int nWidthMM = 0; int nHeightMM = 0; double fTLx, fTLy, fResl = 0.0; int nOption; nOption = GetOptionByName( "tl-x" ); if( nOption != -1 && GetOptionValue( nOption, fTLx ) && GetOptionUnit( nOption ) == SANE_UNIT_MM ) { double fBRx; nOption = GetOptionByName( "br-x" ); if( nOption != -1 && GetOptionValue( nOption, fBRx ) && GetOptionUnit( nOption ) == SANE_UNIT_MM ) { nWidthMM = static_cast(fabs(fBRx - fTLx)); } } nOption = GetOptionByName( "tl-y" ); if( nOption != -1 && GetOptionValue( nOption, fTLy ) && GetOptionUnit( nOption ) == SANE_UNIT_MM ) { double fBRy; nOption = GetOptionByName( "br-y" ); if( nOption != -1 && GetOptionValue( nOption, fBRy ) && GetOptionUnit( nOption ) == SANE_UNIT_MM ) { nHeightMM = static_cast(fabs(fBRy - fTLy)); } } if( ( nOption = GetOptionByName( "resolution" ) ) != -1 ) (void)GetOptionValue( nOption, fResl ); std::unique_ptr pBuffer; SANE_Status nStatus = SANE_STATUS_GOOD; rBitmap.lock(); SvMemoryStream& aConverter = rBitmap.getStream(); aConverter.Seek( 0 ); aConverter.SetEndian( SvStreamEndian::LITTLE ); // write bitmap stream header aConverter.WriteChar( 'B' ).WriteChar( 'M' ); aConverter.WriteUInt32( 0 ); aConverter.WriteUInt32( 0 ); aConverter.WriteUInt32( 60 ); // write BITMAPINFOHEADER aConverter.WriteUInt32( 40 ); aConverter.WriteUInt32( 0 ); // fill in width later aConverter.WriteUInt32( 0 ); // fill in height later aConverter.WriteUInt16( 1 ); // create header for 24 bits // correct later if necessary aConverter.WriteUInt16( 24 ); aConverter.WriteUInt32( 0 ); aConverter.WriteUInt32( 0 ); aConverter.WriteUInt32( 0 ); aConverter.WriteUInt32( 0 ); aConverter.WriteUInt32( 0 ); aConverter.WriteUInt32( 0 ); for( nStream=0; nStream < 3 && bSuccess ; nStream++ ) { nStatus = p_start( maHandle ); DUMP_STATE( nStatus, "sane_start" ); CheckConsistency( "sane_start" ); if( nStatus == SANE_STATUS_GOOD ) { nStatus = p_get_parameters( maHandle, &aParams ); DUMP_STATE( nStatus, "sane_get_parameters" ); CheckConsistency( "sane_get_parameters" ); if (nStatus != SANE_STATUS_GOOD || aParams.bytes_per_line == 0) { bSuccess = false; break; } #if (OSL_DEBUG_LEVEL > 0) || defined DBG_UTIL const char* const ppFormats[] = { "SANE_FRAME_GRAY", "SANE_FRAME_RGB", "SANE_FRAME_RED", "SANE_FRAME_GREEN", "SANE_FRAME_BLUE", "Unknown !!!" }; fprintf( stderr, "Parameters for frame %d:\n", nStream ); if( static_cast< typename std::make_unsigned< typename std::underlying_type::type>::type>( aParams.format) > 4 ) { aParams.format = SANE_Frame(5); } fprintf( stderr, "format: %s\n", ppFormats[ static_cast(aParams.format) ] ); fprintf( stderr, "last_frame: %s\n", aParams.last_frame ? "TRUE" : "FALSE" ); fprintf( stderr, "depth: %d\n", static_cast(aParams.depth) ); fprintf( stderr, "pixels_per_line: %d\n", static_cast(aParams.pixels_per_line) ); fprintf( stderr, "bytes_per_line: %d\n", static_cast(aParams.bytes_per_line) ); #endif if( ! pBuffer ) { pBuffer.reset(new sal_uInt8[ BYTE_BUFFER_SIZE < 4*aParams.bytes_per_line ? 4*aParams.bytes_per_line : BYTE_BUFFER_SIZE ]); } if( aParams.last_frame ) nStream=3; switch( aParams.format ) { case SANE_FRAME_GRAY: eType = FrameStyle_Gray; if( aParams.depth == 1 ) eType = FrameStyle_BW; break; case SANE_FRAME_RGB: eType = FrameStyle_RGB; break; case SANE_FRAME_RED: case SANE_FRAME_GREEN: case SANE_FRAME_BLUE: eType = FrameStyle_Separated; break; default: fprintf( stderr, "Warning: unknown frame style !!!\n" ); } bool bSynchronousRead = true; // should be fail safe, but ... ?? nStatus = p_set_io_mode( maHandle, SANE_FALSE ); CheckConsistency( "sane_set_io_mode" ); if( nStatus != SANE_STATUS_GOOD ) { bSynchronousRead = false; nStatus = p_set_io_mode(maHandle, SANE_TRUE); CheckConsistency( "sane_set_io_mode" ); if (nStatus != SANE_STATUS_GOOD) { SAL_WARN("extensions.scanner", "SANE driver status is: " << nStatus); } } SANE_Int nLen=0; SANE_Int fd = 0; if( ! bSynchronousRead ) { nStatus = p_get_select_fd( maHandle, &fd ); DUMP_STATE( nStatus, "sane_get_select_fd" ); CheckConsistency( "sane_get_select_fd" ); if( nStatus != SANE_STATUS_GOOD ) bSynchronousRead = true; } utl::TempFile aFrame; aFrame.EnableKillingFile(); FILE* pFrame = fopen(OUStringToOString(aFrame.GetFileName(), osl_getThreadTextEncoding()).getStr(), "w+b"); if( ! pFrame ) { bSuccess = false; break; } do { if( ! bSynchronousRead ) { fd_set fdset; struct timeval tv; FD_ZERO( &fdset ); FD_SET( static_cast(fd), &fdset ); tv.tv_sec = 5; tv.tv_usec = 0; if( select( fd+1, &fdset, nullptr, nullptr, &tv ) == 0 ) fprintf( stderr, "Timeout on sane_read descriptor\n" ); } nLen = 0; nStatus = p_read( maHandle, pBuffer.get(), BYTE_BUFFER_SIZE, &nLen ); CheckConsistency( "sane_read" ); if( nLen && ( nStatus == SANE_STATUS_GOOD || nStatus == SANE_STATUS_EOF ) ) { bSuccess = (static_cast(nLen) == fwrite( pBuffer.get(), 1, nLen, pFrame )); if (!bSuccess) break; } else DUMP_STATE( nStatus, "sane_read" ); } while( nStatus == SANE_STATUS_GOOD ); if (nStatus != SANE_STATUS_EOF || !bSuccess) { fclose( pFrame ); bSuccess = false; break; } int nFrameLength = ftell( pFrame ); fseek( pFrame, 0, SEEK_SET ); sal_uInt32 nWidth = static_cast(aParams.pixels_per_line); sal_uInt32 nHeight = static_cast(nFrameLength / aParams.bytes_per_line); if( ! bWidthSet ) { if( ! fResl ) fResl = 300; // if all else fails that's a good guess if( ! nWidthMM ) nWidthMM = static_cast((static_cast(nWidth) / fResl) * 25.4); if( ! nHeightMM ) nHeightMM = static_cast((static_cast(nHeight) / fResl) * 25.4); SAL_INFO("extensions.scanner", "set dimensions to(" << nWidth << ", " << nHeight << ") Pixel, (" << nWidthMM << ", " << nHeightMM << ") mm, resolution is " << fResl); aConverter.Seek( 18 ); aConverter.WriteUInt32( nWidth ); aConverter.WriteUInt32( nHeight ); aConverter.Seek( 38 ); aConverter.WriteUInt32( 1000*nWidth/nWidthMM ); aConverter.WriteUInt32( 1000*nHeight/nHeightMM ); bWidthSet = true; } aConverter.Seek(60); if( eType == FrameStyle_BW ) { aConverter.Seek( 10 ); aConverter.WriteUInt32( 64 ); aConverter.Seek( 28 ); aConverter.WriteUInt16( 1 ); aConverter.Seek( 54 ); // write color table aConverter.WriteUInt16( 0xffff ); aConverter.WriteUChar( 0xff ); aConverter.WriteUChar( 0 ); aConverter.WriteUInt32( 0 ); aConverter.Seek( 64 ); } else if( eType == FrameStyle_Gray ) { aConverter.Seek( 10 ); aConverter.WriteUInt32( 1084 ); aConverter.Seek( 28 ); aConverter.WriteUInt16( 8 ); aConverter.Seek( 54 ); // write color table for( nLine = 0; nLine < 256; nLine++ ) { aConverter.WriteUChar( nLine ); aConverter.WriteUChar( nLine ); aConverter.WriteUChar( nLine ); aConverter.WriteUChar( 0 ); } aConverter.Seek( 1084 ); } for (nLine = nHeight-1; nLine >= 0; --nLine) { if (fseek(pFrame, nLine * aParams.bytes_per_line, SEEK_SET) == -1) { bSuccess = false; break; } if( eType == FrameStyle_BW || ( eType == FrameStyle_Gray && aParams.depth == 8 ) ) { SANE_Int items_read = fread( pBuffer.get(), 1, aParams.bytes_per_line, pFrame ); if (items_read != aParams.bytes_per_line) { SAL_WARN( "extensions.scanner", "short read, padding with zeros" ); memset(pBuffer.get() + items_read, 0, aParams.bytes_per_line - items_read); } aConverter.WriteBytes(pBuffer.get(), aParams.bytes_per_line); } else if( eType == FrameStyle_Gray ) { for( i = 0; i < (aParams.pixels_per_line); i++ ) { sal_uInt8 nGray = ReadValue( pFrame, aParams.depth ); aConverter.WriteUChar( nGray ); } } else if( eType == FrameStyle_RGB ) { for( i = 0; i < (aParams.pixels_per_line); i++ ) { sal_uInt8 nRed, nGreen, nBlue; nRed = ReadValue( pFrame, aParams.depth ); nGreen = ReadValue( pFrame, aParams.depth ); nBlue = ReadValue( pFrame, aParams.depth ); aConverter.WriteUChar( nBlue ); aConverter.WriteUChar( nGreen ); aConverter.WriteUChar( nRed ); } } else if( eType == FrameStyle_Separated ) { for( i = 0; i < (aParams.pixels_per_line); i++ ) { sal_uInt8 nValue = ReadValue( pFrame, aParams.depth ); switch( aParams.format ) { case SANE_FRAME_RED: aConverter.SeekRel( 2 ); aConverter.WriteUChar( nValue ); break; case SANE_FRAME_GREEN: aConverter.SeekRel( 1 ); aConverter.WriteUChar( nValue ); aConverter.SeekRel( 1 ); break; case SANE_FRAME_BLUE: aConverter.WriteUChar( nValue ); aConverter.SeekRel( 2 ); break; case SANE_FRAME_GRAY: case SANE_FRAME_RGB: break; } } } int nGap = aConverter.Tell() & 3; if (nGap) aConverter.SeekRel( 4-nGap ); } fclose( pFrame ); // deletes tmpfile if( eType != FrameStyle_Separated ) break; } else bSuccess = false; } // get stream length int nPos = aConverter.TellEnd(); aConverter.Seek( 2 ); aConverter.WriteUInt32( nPos+1 ); aConverter.Seek( 0 ); rBitmap.unlock(); if( bSuccess ) { // only cancel a successful operation // sane disrupts memory else p_cancel( maHandle ); CheckConsistency( "sane_cancel" ); } pBuffer.reset(); ReloadOptions(); dbg_msg( "Sane::Start returns with %s\n", bSuccess ? "TRUE" : "FALSE" ); return bSuccess; } int Sane::GetRange( int n, std::unique_ptr& rpDouble ) { if( mppOptions[n]->constraint_type != SANE_CONSTRAINT_RANGE && mppOptions[n]->constraint_type != SANE_CONSTRAINT_WORD_LIST ) { return -1; } rpDouble = nullptr; int nItems, i; bool bIsFixed = mppOptions[n]->type == SANE_TYPE_FIXED; dbg_msg( "Sane::GetRange of option %s ", mppOptions[n]->name ); if(mppOptions[n]->constraint_type == SANE_CONSTRAINT_RANGE ) { double fMin, fMax, fQuant; if( bIsFixed ) { fMin = SANE_UNFIX( mppOptions[n]->constraint.range->min ); fMax = SANE_UNFIX( mppOptions[n]->constraint.range->max ); fQuant = SANE_UNFIX( mppOptions[n]->constraint.range->quant ); } else { fMin = static_cast(mppOptions[n]->constraint.range->min); fMax = static_cast(mppOptions[n]->constraint.range->max); fQuant = static_cast(mppOptions[n]->constraint.range->quant); } if( fQuant != 0.0 ) { dbg_msg( "quantum range [ %lg ; %lg ; %lg ]\n", fMin, fQuant, fMax ); nItems = static_cast((fMax - fMin)/fQuant)+1; rpDouble.reset(new double[ nItems ]); double fValue = fMin; for( i = 0; i < nItems; i++, fValue += fQuant ) rpDouble[i] = fValue; rpDouble[ nItems-1 ] = fMax; return nItems; } else { dbg_msg( "normal range [ %lg %lg ]\n", fMin, fMax ); rpDouble.reset(new double[2]); rpDouble[0] = fMin; rpDouble[1] = fMax; return 0; } } else { nItems = mppOptions[n]->constraint.word_list[0]; rpDouble.reset(new double[nItems]); for( i=0; iconstraint.word_list[i+1] ) : static_cast(mppOptions[n]->constraint.word_list[i+1]); } dbg_msg( "wordlist [ %lg ... %lg ]\n", rpDouble[ 0 ], rpDouble[ nItems-1 ] ); return nItems; } } static const char *ppUnits[] = { "", "[Pixel]", "[Bit]", "[mm]", "[DPI]", "[%]", "[usec]" }; OUString Sane::GetOptionUnitName( int n ) { OUString aText; SANE_Unit nUnit = mppOptions[n]->unit; size_t nUnitAsSize = static_cast(nUnit); if (nUnitAsSize >= SAL_N_ELEMENTS( ppUnits )) aText = "[unknown units]"; else aText = OUString( ppUnits[ nUnit ], strlen(ppUnits[ nUnit ]), osl_getThreadTextEncoding() ); return aText; } bool Sane::ActivateButtonOption( int n ) { SANE_Status nStatus = ControlOption( n, SANE_ACTION_SET_VALUE, nullptr ); return nStatus == SANE_STATUS_GOOD; } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */