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exiv2/src/actions.cpp

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// ***************************************************************** -*- C++ -*-
/*
* Copyright (C) 2004-2008 Andreas Huggel <ahuggel@gmx.net>
*
* This program is part of the Exiv2 distribution.
*
* 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, write to the Free Software
* Foundation, Inc., 51 Franklin Street, 5th Floor, Boston, MA 02110-1301 USA.
*/
/*
File: actions.cpp
Version: $Rev$
Author(s): Andreas Huggel (ahu) <ahuggel@gmx.net>
History: 08-Dec-03, ahu: created
30-Apr-06, Roger Larsson: Print filename if processing multiple files
*/
// *****************************************************************************
#include "rcsid.hpp"
EXIV2_RCSID("@(#) $Id$")
// *****************************************************************************
// included header files
#ifdef _MSC_VER
# include "exv_msvc.h"
#else
# include "exv_conf.h"
#endif
#ifndef EXV_HAVE_TIMEGM
# include "timegm.h"
#endif
#include "actions.hpp"
#include "exiv2.hpp"
#include "image.hpp"
#include "jpgimage.hpp"
#include "xmpsidecar.hpp"
#include "utils.hpp"
#include "types.hpp"
#include "exif.hpp"
#include "canonmn.hpp"
#include "iptc.hpp"
#include "xmp.hpp"
#include "futils.hpp"
#include "i18n.h" // NLS support.
// + standard includes
#include <string>
#include <iostream>
#include <iomanip>
#include <fstream>
#include <sstream>
#include <cstring>
#include <cstdio>
#include <ctime>
#include <cmath>
#include <cassert>
#include <sys/types.h> // for stat()
#include <sys/stat.h> // for stat()
#ifdef EXV_HAVE_UNISTD_H
# include <unistd.h> // for stat()
#endif
#ifdef _MSC_VER
# include <sys/utime.h>
#else
# include <utime.h>
#endif
// *****************************************************************************
// local declarations
namespace {
//! Helper class to set the timestamp of a file to that of another file
class Timestamp {
public:
//! C'tor
Timestamp() : actime_(0), modtime_(0) {}
//! Read the timestamp of a file
int read(const std::string& path);
//! Read the timestamp from a broken-down time in buffer \em tm.
int read(struct tm* tm);
//! Set the timestamp of a file
int touch(const std::string& path);
private:
time_t actime_;
time_t modtime_;
};
/*!
@brief Convert a string "YYYY:MM:DD HH:MI:SS" to a struct tm type,
returns 0 if successful
*/
int str2Tm(const std::string& timeStr, struct tm* tm);
//! Convert a UTC time to a string "YYYY:MM:DD HH:MI:SS", "" on error
std::string time2Str(time_t time);
//! Convert a tm structure to a string "YYYY:MM:DD HH:MI:SS", "" on error
std::string tm2Str(struct tm* tm);
/*!
@brief Copy metadata from source to target according to Params::copyXyz
@param source Source file path
@param target Target file path. An *.exv file is created if target doesn't
exist.
@param targetType Image type for the target image in case it needs to be
created.
@param preserve Indicates if existing metadata in the target file should
be kept.
@return 0 if successful, else an error code
*/
int metacopy(const std::string& source,
const std::string& target,
int targetType,
bool preserve);
/*!
@brief Rename a file according to a timestamp value.
@param path The original file path. Contains the new path on exit.
@param tm Pointer to a buffer with the broken-down time to rename
the file to.
@return 0 if successful, -1 if the file was skipped, 1 on error.
*/
int renameFile(std::string& path, const struct tm* tm);
/*!
@brief Make a file path from the current file path, destination
directory (if any) and the filename extension passed in.
@param path Path of the existing file
@param ext New filename extension (incl. the dot '.' if required)
@return 0 if successful, 1 if the new file exists and the user
chose not to overwrite it.
*/
std::string newFilePath(const std::string& path, const std::string& ext);
/*!
@brief Check if file \em path exists and whether it should be
overwritten. Ask user if necessary. Return 1 if the file
exists and shouldn't be overwritten, else 0.
*/
int dontOverwrite(const std::string& path);
}
// *****************************************************************************
// class member definitions
namespace Action {
Task::AutoPtr Task::clone() const
{
return AutoPtr(clone_());
}
TaskFactory* TaskFactory::instance_ = 0;
TaskFactory& TaskFactory::instance()
{
if (0 == instance_) {
instance_ = new TaskFactory;
}
return *instance_;
} // TaskFactory::instance
void TaskFactory::cleanup()
{
if (instance_ != 0) {
Registry::iterator e = registry_.end();
for (Registry::iterator i = registry_.begin(); i != e; ++i) {
delete i->second;
}
delete instance_;
instance_ = 0;
}
} //TaskFactory::cleanup
void TaskFactory::registerTask(TaskType type, Task::AutoPtr task)
{
Registry::iterator i = registry_.find(type);
if (i != registry_.end()) {
delete i->second;
}
registry_[type] = task.release();
} // TaskFactory::registerTask
TaskFactory::TaskFactory()
{
// Register a prototype of each known task
registerTask(adjust, Task::AutoPtr(new Adjust));
registerTask(print, Task::AutoPtr(new Print));
registerTask(rename, Task::AutoPtr(new Rename));
registerTask(erase, Task::AutoPtr(new Erase));
registerTask(extract, Task::AutoPtr(new Extract));
registerTask(insert, Task::AutoPtr(new Insert));
registerTask(modify, Task::AutoPtr(new Modify));
registerTask(fixiso, Task::AutoPtr(new FixIso));
} // TaskFactory c'tor
Task::AutoPtr TaskFactory::create(TaskType type)
{
Registry::const_iterator i = registry_.find(type);
if (i != registry_.end() && i->second != 0) {
Task* t = i->second;
return t->clone();
}
return Task::AutoPtr(0);
} // TaskFactory::create
int Print::run(const std::string& path)
try {
path_ = path;
int rc = 0;
switch (Params::instance().printMode_) {
case Params::pmSummary: rc = printSummary(); break;
case Params::pmList: rc = printList(); break;
case Params::pmIptc: rc = printIptc(); break;
case Params::pmXmp: rc = printXmp(); break;
case Params::pmComment: rc = printComment(); break;
}
return rc;
}
catch(const Exiv2::AnyError& e) {
std::cerr << "Exiv2 exception in print action for file "
<< path << ":\n" << e << "\n";
return 1;
} // Print::run
int Print::printSummary()
{
if (!Exiv2::fileExists(path_, true)) {
std::cerr << path_ << ": "
<< _("Failed to open the file\n");
return -1;
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path_);
assert(image.get() != 0);
image->readMetadata();
Exiv2::ExifData& exifData = image->exifData();
align_ = 16;
// Filename
printLabel(_("File name"));
std::cout << path_ << std::endl;
// Filesize
struct stat buf;
if (0 == stat(path_.c_str(), &buf)) {
printLabel(_("File size"));
std::cout << buf.st_size << " " << _("Bytes") << std::endl;
}
// MIME type
printLabel(_("MIME type"));
std::cout << image->mimeType() << "\n";
// Image size
printLabel(_("Image size"));
std::cout << image->pixelWidth() << " x " << image->pixelHeight() << "\n";
if (exifData.empty()) {
std::cerr << path_ << ": "
<< _("No Exif data found in the file\n");
return -3;
}
// Camera make
printTag(exifData, "Exif.Image.Make", _("Camera make"));
// Camera model
printTag(exifData, "Exif.Image.Model", _("Camera model"));
// Image Timestamp
printTag(exifData, "Exif.Photo.DateTimeOriginal", _("Image timestamp"));
// Image number
// Todo: Image number for cameras other than Canon
printTag(exifData, "Exif.Canon.ImageNumber", _("Image number"));
// Exposure time
// From ExposureTime, failing that, try ShutterSpeedValue
bool done = false;
printLabel(_("Exposure time"));
if (!done) {
done = 0 != printTag(exifData, "Exif.Photo.ExposureTime");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Photo.ShutterSpeedValue");
}
std::cout << std::endl;
// Aperture
// Get if from FNumber and, failing that, try ApertureValue
done = false;
printLabel(_("Aperture"));
if (!done) {
done = 0 != printTag(exifData, "Exif.Photo.FNumber");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Photo.ApertureValue");
}
std::cout << std::endl;
// Exposure bias
printTag(exifData, "Exif.Photo.ExposureBiasValue", _("Exposure bias"));
// Flash
printTag(exifData, "Exif.Photo.Flash", _("Flash"));
// Todo: Flash bias, flash energy
// Todo: Implement this for other cameras
done = false;
printLabel(_("Flash bias"));
if (!done) {
done = 0 != printTag(exifData, "Exif.CanonSi.FlashBias");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Panasonic.FlashBias");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Olympus.FlashBias");
}
std::cout << std::endl;
// Actual focal length and 35 mm equivalent
// Todo: Calculate 35 mm equivalent a la jhead
Exiv2::ExifData::const_iterator md;
printLabel(_("Focal length"));
if (1 == printTag(exifData, "Exif.Photo.FocalLength")) {
md = exifData.findKey(
Exiv2::ExifKey("Exif.Photo.FocalLengthIn35mmFilm"));
if (md != exifData.end()) {
std::cout << " ("<< _("35 mm equivalent") << ": " << *md << ")";
}
}
std::cout << std::endl;
// Subject distance
printLabel(_("Subject distance"));
done = false;
if (!done) {
done = 0 != printTag(exifData, "Exif.Photo.SubjectDistance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.CanonSi.SubjectDistance");
}
std::cout << std::endl;
// ISO speed
// from ISOSpeedRatings or the Makernote
printLabel(_("ISO speed"));
done = false;
if (!done) {
done = 0 != printTag(exifData, "Exif.Photo.ISOSpeedRatings");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.CanonSi.ISOSpeed");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Nikon1.ISOSpeed");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Nikon2.ISOSpeed");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Nikon3.ISOSpeed");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsNew.ISOSpeed");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsOld.ISOSpeed");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCs5D.ISOSpeed");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCs7D.ISOSpeed");
}
std::cout << std::endl;
// Exposure mode
// From ExposureProgram or Canon Makernote
printLabel(_("Exposure mode"));
done = false;
if (!done) {
done = 0 != printTag(exifData, "Exif.Photo.ExposureProgram");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.CanonCs.ExposureProgram");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCs7D.ExposureMode");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCs5D.ExposureMode");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsNew.ExposureMode");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsOld.ExposureMode");
}
std::cout << std::endl;
// Metering mode
printTag(exifData, "Exif.Photo.MeteringMode", _("Metering mode"));
// Macro mode
// Todo: Implement this for other cameras
printLabel(_("Macro mode"));
done = false;
if (!done) {
done = 0 != printTag(exifData, "Exif.CanonCs.Macro");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Fujifilm.Macro");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Olympus.Macro");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Panasonic.Macro");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsNew.MacroMode");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsOld.MacroMode");
}
std::cout << std::endl;
// Image quality setting (compression)
// Todo: Implement this for other cameras
printLabel(_("Image quality"));
done = false;
if (!done) {
done = 0 != printTag(exifData, "Exif.CanonCs.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Fujifilm.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Sigma.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Nikon1.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Nikon2.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Nikon3.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Olympus.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Panasonic.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Minolta.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsNew.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsOld.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCs5D.Quality");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCs7D.Quality");
}
std::cout << std::endl;
// Exif Resolution
printLabel(_("Exif Resolution"));
long xdim = 0;
long ydim = 0;
md = exifData.findKey(Exiv2::ExifKey("Exif.Image.ImageWidth"));
if (md == exifData.end()) {
md = exifData.findKey(Exiv2::ExifKey("Exif.Photo.PixelXDimension"));
}
if (md != exifData.end()) {
xdim = md->toLong();
}
md = exifData.findKey(Exiv2::ExifKey("Exif.Image.ImageLength"));
if (md == exifData.end()) {
md = exifData.findKey(Exiv2::ExifKey("Exif.Photo.PixelYDimension"));
}
if (md != exifData.end()) {
ydim = md->toLong();
}
if (xdim != 0 && ydim != 0) {
std::cout << xdim << " x " << ydim;
}
std::cout << std::endl;
// White balance
// Todo: Implement this for other cameras
printLabel(_("White balance"));
done = false;
if (!done) {
done = 0 != printTag(exifData, "Exif.CanonSi.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Fujifilm.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Sigma.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Nikon1.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Nikon2.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Nikon3.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Olympus.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.Panasonic.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCs5D.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCs7D.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsNew.WhiteBalance");
}
if (!done) {
done = 0 != printTag(exifData, "Exif.MinoltaCsOld.WhiteBalance");
}
std::cout << std::endl;
// Thumbnail
printLabel(_("Thumbnail"));
Exiv2::ExifThumbC exifThumb(exifData);
std::string thumbExt = exifThumb.extension();
if (thumbExt.empty()) {
std::cout << _("None");
}
else {
Exiv2::DataBuf buf = exifThumb.copy();
std::cout << exifThumb.mimeType() << ", "
<< buf.size_ << " " << _("Bytes");
}
std::cout << std::endl;
// Copyright
printTag(exifData, "Exif.Image.Copyright", _("Copyright"));
// Exif Comment
printTag(exifData, "Exif.Photo.UserComment", _("Exif comment"));
std::cout << std::endl;
return 0;
} // Print::printSummary
void Print::printLabel(const std::string& label) const
{
std::cout << std::setfill(' ') << std::left;
if (Params::instance().files_.size() > 1) {
std::cout << std::setw(20) << path_ << " ";
}
std::cout << std::setw(align_)
<< label << ": ";
}
int Print::printTag(const Exiv2::ExifData& exifData,
const std::string& key,
const std::string& label) const
{
int rc = 0;
if (!label.empty()) {
printLabel(label);
}
Exiv2::ExifKey ek(key);
Exiv2::ExifData::const_iterator md = exifData.findKey(ek);
if (md != exifData.end()) {
std::cout << *md;
rc = 1;
}
if (!label.empty()) std::cout << std::endl;
return rc;
} // Print::printTag
int Print::printList()
{
if (!Exiv2::fileExists(path_, true)) {
std::cerr << path_
<< ": " << _("Failed to open the file\n");
return -1;
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path_);
assert(image.get() != 0);
image->readMetadata();
Exiv2::ExifData& exifData = image->exifData();
if (exifData.empty()) {
std::cerr << path_
<< ": " << _("No Exif data found in the file\n");
return -3;
}
Exiv2::ExifData::const_iterator md;
bool const manyFiles = Params::instance().files_.size() > 1;
for (md = exifData.begin(); md != exifData.end(); ++md) {
if ( Params::instance().unknown_
&& md->tagName().substr(0, 2) == "0x") {
continue;
}
if (manyFiles) {
std::cout << std::setfill(' ') << std::left << std::setw(20)
<< path_ << " ";
}
bool first = true;
if (Params::instance().printItems_ & Params::prTag) {
if (!first) std::cout << " ";
first = false;
std::cout << "0x" << std::setw(4) << std::setfill('0')
<< std::right << std::hex
<< md->tag();
}
if (Params::instance().printItems_ & Params::prGroup) {
if (!first) std::cout << " ";
first = false;
std::cout << std::setw(12) << std::setfill(' ') << std::left
<< md->groupName();
}
if (Params::instance().printItems_ & Params::prKey) {
if (!first) std::cout << " ";
first = false;
std::cout << std::setfill(' ') << std::left << std::setw(44)
<< md->key();
}
if (Params::instance().printItems_ & Params::prName) {
if (!first) std::cout << " ";
first = false;
std::cout << std::setw(27) << std::setfill(' ') << std::left
<< md->tagName();
}
if (Params::instance().printItems_ & Params::prLabel) {
if (!first) std::cout << " ";
first = false;
std::cout << std::setw(30) << std::setfill(' ') << std::left
<< md->tagLabel();
}
if (Params::instance().printItems_ & Params::prType) {
if (!first) std::cout << " ";
first = false;
std::cout << std::setw(9) << std::setfill(' ') << std::left
<< md->typeName();
}
if (Params::instance().printItems_ & Params::prCount) {
if (!first) std::cout << " ";
first = false;
std::cout << std::dec << std::setw(3)
<< std::setfill(' ') << std::right
<< md->count();
}
if (Params::instance().printItems_ & Params::prSize) {
if (!first) std::cout << " ";
first = false;
std::cout << std::dec << std::setw(3)
<< std::setfill(' ') << std::right
<< md->size();
}
if (Params::instance().printItems_ & Params::prValue) {
if (!first) std::cout << " ";
first = false;
if ( Params::instance().binary_
&& md->typeId() == Exiv2::undefined
&& md->size() > 100) {
std::cout << _("(Binary value suppressed)") << std::endl;
continue;
}
std::cout << std::dec << md->value();
}
if (Params::instance().printItems_ & Params::prTrans) {
if (!first) std::cout << " ";
first = false;
if ( Params::instance().binary_
&& md->typeId() == Exiv2::undefined
&& md->size() > 100) {
std::cout << _("(Binary value suppressed)") << std::endl;
continue;
}
std::cout << std::dec << *md;
}
if (Params::instance().printItems_ & Params::prHex) {
if (!first) std::cout << std::endl;
first = false;
if ( Params::instance().binary_
&& md->typeId() == Exiv2::undefined
&& md->size() > 100) {
std::cout << _("(Binary value suppressed)") << std::endl;
continue;
}
Exiv2::DataBuf buf(md->size());
md->copy(buf.pData_, image->byteOrder());
Exiv2::hexdump(std::cout, buf.pData_, buf.size_);
}
std::cout << std::endl;
}
return 0;
} // Print::printList
int Print::printIptc()
{
if (!Exiv2::fileExists(path_, true)) {
std::cerr << path_
<< ": " << _("Failed to open the file\n");
return -1;
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path_);
assert(image.get() != 0);
image->readMetadata();
Exiv2::IptcData& iptcData = image->iptcData();
if (iptcData.empty()) {
std::cerr << path_
<< ": " << _("No IPTC data found in the file\n");
return -3;
}
Exiv2::IptcData::const_iterator end = iptcData.end();
Exiv2::IptcData::const_iterator md;
bool manyFiles = Params::instance().files_.size() > 1;
for (md = iptcData.begin(); md != end; ++md) {
std::cout << std::setfill(' ') << std::left;
if (manyFiles) {
std::cout << std::setw(20) << path_ << " ";
}
std::cout << std::setw(44)
<< md->key() << " "
<< std::setw(9) << std::setfill(' ') << std::left
<< md->typeName() << " "
<< std::dec << std::setw(3)
<< std::setfill(' ') << std::right
<< md->count() << " "
<< std::dec << md->value()
<< std::endl;
}
return 0;
} // Print::printIptc
int Print::printXmp()
{
if (!Exiv2::fileExists(path_, true)) {
std::cerr << path_
<< ": " << _("Failed to open the file\n");
return -1;
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path_);
assert(image.get() != 0);
image->readMetadata();
Exiv2::XmpData& xmpData = image->xmpData();
if (xmpData.empty()) {
std::cerr << path_
<< ": " << _("No XMP data found in the file\n");
return -3;
}
Exiv2::XmpData::const_iterator end = xmpData.end();
Exiv2::XmpData::const_iterator md;
bool manyFiles = Params::instance().files_.size() > 1;
for (md = xmpData.begin(); md != end; ++md) {
std::cout << std::setfill(' ') << std::left;
if (manyFiles) {
std::cout << std::setw(20) << path_ << " ";
}
std::cout << std::setw(44)
<< md->key() << " "
<< std::setw(9) << std::setfill(' ') << std::left
<< md->typeName() << " "
<< std::dec << std::setw(3)
<< std::setfill(' ') << std::right
<< md->count() << " "
<< std::dec << *md
<< std::endl;
}
return 0;
} // Print::printXmp
int Print::printComment()
{
if (!Exiv2::fileExists(path_, true)) {
std::cerr << path_
<< ": " << _("Failed to open the file\n");
return -1;
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path_);
assert(image.get() != 0);
image->readMetadata();
if (Params::instance().verbose_) {
std::cout << _("JPEG comment") << ": ";
}
std::cout << image->comment() << std::endl;
return 0;
} // Print::printComment
Print::AutoPtr Print::clone() const
{
return AutoPtr(clone_());
}
Print* Print::clone_() const
{
return new Print(*this);
}
int Rename::run(const std::string& path)
{
try {
if (!Exiv2::fileExists(path, true)) {
std::cerr << path
<< ": " << _("Failed to open the file\n");
return -1;
}
Timestamp ts;
if (Params::instance().preserve_) {
ts.read(path);
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path);
assert(image.get() != 0);
image->readMetadata();
Exiv2::ExifData& exifData = image->exifData();
if (exifData.empty()) {
std::cerr << path
<< ": " << _("No Exif data found in the file\n");
return -3;
}
Exiv2::ExifKey key("Exif.Photo.DateTimeOriginal");
Exiv2::ExifData::iterator md = exifData.findKey(key);
if (md == exifData.end()) {
key = Exiv2::ExifKey("Exif.Image.DateTime");
md = exifData.findKey(key);
}
if (md == exifData.end()) {
std::cerr << _("Neither tag") << " `Exif.Photo.DateTimeOriginal' "
<< _("nor") << " `Exif.Image.DateTime' "
<< _("found in the file") << " " << path << "\n";
return 1;
}
std::string v = md->toString();
if (v.length() == 0 || v[0] == ' ') {
std::cerr << _("Image file creation timestamp not set in the file")
<< " " << path << "\n";
return 1;
}
struct tm tm;
if (str2Tm(v, &tm) != 0) {
std::cerr << _("Failed to parse timestamp") << " `" << v
<< "' " << _("in the file") << " " << path << "\n";
return 1;
}
if ( Params::instance().timestamp_
|| Params::instance().timestampOnly_) {
ts.read(&tm);
}
int rc = 0;
std::string newPath = path;
if (Params::instance().timestampOnly_) {
if (Params::instance().verbose_) {
std::cout << _("Updating timestamp to") << " " << v << std::endl;
}
}
else {
rc = renameFile(newPath, &tm);
if (rc == -1) return 0; // skip
}
if ( 0 == rc
&& ( Params::instance().preserve_
|| Params::instance().timestamp_
|| Params::instance().timestampOnly_)) {
ts.touch(newPath);
}
return rc;
}
catch(const Exiv2::AnyError& e)
{
std::cerr << "Exiv2 exception in rename action for file " << path
<< ":\n" << e << "\n";
return 1;
}} // Rename::run
Rename::AutoPtr Rename::clone() const
{
return AutoPtr(clone_());
}
Rename* Rename::clone_() const
{
return new Rename(*this);
}
int Erase::run(const std::string& path)
try {
path_ = path;
if (!Exiv2::fileExists(path_, true)) {
std::cerr << path_
<< ": " << _("Failed to open the file\n");
return -1;
}
Timestamp ts;
if (Params::instance().preserve_) {
ts.read(path);
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path_);
assert(image.get() != 0);
image->readMetadata();
// Thumbnail must be before Exif
int rc = 0;
if (Params::instance().target_ & Params::ctThumb) {
rc = eraseThumbnail(image.get());
}
if (0 == rc && Params::instance().target_ & Params::ctExif) {
rc = eraseExifData(image.get());
}
if (0 == rc && Params::instance().target_ & Params::ctIptc) {
rc = eraseIptcData(image.get());
}
if (0 == rc && Params::instance().target_ & Params::ctComment) {
rc = eraseComment(image.get());
}
if (0 == rc && Params::instance().target_ & Params::ctXmp) {
rc = eraseXmpData(image.get());
}
if (0 == rc) {
image->writeMetadata();
}
if (Params::instance().preserve_) {
ts.touch(path);
}
return rc;
}
catch(const Exiv2::AnyError& e)
{
std::cerr << "Exiv2 exception in erase action for file " << path
<< ":\n" << e << "\n";
return 1;
} // Erase::run
int Erase::eraseThumbnail(Exiv2::Image* image) const
{
Exiv2::ExifThumb exifThumb(image->exifData());
std::string thumbExt = exifThumb.extension();
if (thumbExt.empty()) {
return 0;
}
exifThumb.erase();
if (Params::instance().verbose_) {
std::cout << _("Erasing thumbnail data") << std::endl;
}
return 0;
}
int Erase::eraseExifData(Exiv2::Image* image) const
{
if (Params::instance().verbose_ && image->exifData().count() > 0) {
std::cout << _("Erasing Exif data from the file") << std::endl;
}
image->clearExifData();
return 0;
}
int Erase::eraseIptcData(Exiv2::Image* image) const
{
if (Params::instance().verbose_ && image->iptcData().count() > 0) {
std::cout << _("Erasing IPTC data from the file") << std::endl;
}
image->clearIptcData();
return 0;
}
int Erase::eraseComment(Exiv2::Image* image) const
{
if (Params::instance().verbose_ && image->comment().size() > 0) {
std::cout << _("Erasing JPEG comment from the file") << std::endl;
}
image->clearComment();
return 0;
}
int Erase::eraseXmpData(Exiv2::Image* image) const
{
if (Params::instance().verbose_ && image->xmpData().count() > 0) {
std::cout << _("Erasing XMP data from the file") << std::endl;
}
image->clearXmpPacket();
return 0;
}
Erase::AutoPtr Erase::clone() const
{
return AutoPtr(clone_());
}
Erase* Erase::clone_() const
{
return new Erase(*this);
}
int Extract::run(const std::string& path)
try {
path_ = path;
int rc = 0;
if (Params::instance().target_ & Params::ctThumb) {
rc = writeThumbnail();
}
if (Params::instance().target_ & Params::ctXmpSidecar) {
std::string xmpPath = newFilePath(path_, ".xmp");
if (dontOverwrite(xmpPath)) return 0;
rc = metacopy(path_, xmpPath, Exiv2::ImageType::xmp, false);
}
if ( !(Params::instance().target_ & Params::ctXmpSidecar)
&& !(Params::instance().target_ & Params::ctThumb)) {
std::string exvPath = newFilePath(path_, ".exv");
if (dontOverwrite(exvPath)) return 0;
rc = metacopy(path_, exvPath, Exiv2::ImageType::exv, false);
}
return rc;
}
catch(const Exiv2::AnyError& e)
{
std::cerr << "Exiv2 exception in extract action for file " << path
<< ":\n" << e << "\n";
return 1;
} // Extract::run
int Extract::writeThumbnail() const
{
if (!Exiv2::fileExists(path_, true)) {
std::cerr << path_
<< ": " << _("Failed to open the file\n");
return -1;
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path_);
assert(image.get() != 0);
image->readMetadata();
Exiv2::ExifData& exifData = image->exifData();
if (exifData.empty()) {
std::cerr << path_
<< ": " << _("No Exif data found in the file\n");
return -3;
}
int rc = 0;
Exiv2::ExifThumb exifThumb(exifData);
std::string thumbExt = exifThumb.extension();
if (thumbExt.empty()) {
std::cerr << path_ << ": " << _("Image does not contain an Exif thumbnail\n");
}
else {
std::string thumb = newFilePath(path_, "-thumb");
std::string thumbPath = thumb + thumbExt;
if (dontOverwrite(thumbPath)) return 0;
if (Params::instance().verbose_) {
Exiv2::DataBuf buf = exifThumb.copy();
std::cout << _("Writing thumbnail") << " (" << exifThumb.mimeType() << ", "
<< buf.size_ << " " << _("Bytes") << ") " << _("to file") << " "
<< thumbPath << std::endl;
}
rc = exifThumb.writeFile(thumb);
if (rc == 0) {
std::cerr << path_ << ": " << _("Exif data doesn't contain a thumbnail\n");
}
}
return rc;
} // Extract::writeThumbnail
Extract::AutoPtr Extract::clone() const
{
return AutoPtr(clone_());
}
Extract* Extract::clone_() const
{
return new Extract(*this);
}
int Insert::run(const std::string& path)
try {
if (!Exiv2::fileExists(path, true)) {
std::cerr << path
<< ": " << _("Failed to open the file\n");
return -1;
}
int rc = 0;
Timestamp ts;
if (Params::instance().preserve_) {
ts.read(path);
}
if (Params::instance().target_ & Params::ctThumb) {
rc = insertThumbnail(path);
}
if ( rc == 0
&& ( Params::instance().target_ & Params::ctExif
|| Params::instance().target_ & Params::ctIptc
|| Params::instance().target_ & Params::ctComment
|| Params::instance().target_ & Params::ctXmp)) {
std::string suffix = Params::instance().suffix_;
if (suffix.empty()) suffix = ".exv";
if (Params::instance().target_ & Params::ctXmpSidecar) suffix = ".xmp";
std::string exvPath = newFilePath(path, suffix);
rc = metacopy(exvPath, path, Exiv2::ImageType::none, true);
}
if (0 == rc && Params::instance().target_ & Params::ctXmpSidecar) {
rc = insertXmpPacket(path);
}
if (Params::instance().preserve_) {
ts.touch(path);
}
return rc;
}
catch(const Exiv2::AnyError& e)
{
std::cerr << "Exiv2 exception in insert action for file " << path
<< ":\n" << e << "\n";
return 1;
} // Insert::run
int Insert::insertXmpPacket(const std::string& path) const
{
std::string xmpPath = newFilePath(path, ".xmp");
if (!Exiv2::fileExists(xmpPath, true)) {
std::cerr << xmpPath
<< ": " << _("Failed to open the file\n");
return -1;
}
if (!Exiv2::fileExists(path, true)) {
std::cerr << path
<< ": " << _("Failed to open the file\n");
return -1;
}
Exiv2::DataBuf buf = Exiv2::readFile(xmpPath);
std::string xmpPacket;
xmpPacket.assign(reinterpret_cast<char*>(buf.pData_), buf.size_);
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path);
assert(image.get() != 0);
image->readMetadata();
image->setXmpPacket(xmpPacket);
image->writeMetadata();
return 0;
}
int Insert::insertThumbnail(const std::string& path) const
{
std::string thumbPath = newFilePath(path, "-thumb.jpg");
if (!Exiv2::fileExists(thumbPath, true)) {
std::cerr << thumbPath
<< ": " << _("Failed to open the file\n");
return -1;
}
if (!Exiv2::fileExists(path, true)) {
std::cerr << path
<< ": " << _("Failed to open the file\n");
return -1;
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path);
assert(image.get() != 0);
image->readMetadata();
Exiv2::ExifThumb exifThumb(image->exifData());
exifThumb.setJpegThumbnail(thumbPath);
image->writeMetadata();
return 0;
} // Insert::insertThumbnail
Insert::AutoPtr Insert::clone() const
{
return AutoPtr(clone_());
}
Insert* Insert::clone_() const
{
return new Insert(*this);
}
int Modify::run(const std::string& path)
{
try {
if (!Exiv2::fileExists(path, true)) {
std::cerr << path
<< ": " << _("Failed to open the file\n");
return -1;
}
Timestamp ts;
if (Params::instance().preserve_) {
ts.read(path);
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path);
assert(image.get() != 0);
image->readMetadata();
applyCommands(image.get());
// Save both exif and iptc metadata
image->writeMetadata();
if (Params::instance().preserve_) {
ts.touch(path);
}
return 0;
}
catch(const Exiv2::AnyError& e)
{
std::cerr << "Exiv2 exception in modify action for file " << path
<< ":\n" << e << "\n";
return 1;
}
} // Modify::run
void Modify::applyCommands(Exiv2::Image* pImage)
{
if (!Params::instance().jpegComment_.empty()) {
if (Params::instance().verbose_) {
std::cout << _("Setting JPEG comment") << " '"
<< Params::instance().jpegComment_
<< "'"
<< std::endl;
}
pImage->setComment(Params::instance().jpegComment_);
}
// loop through command table and apply each command
ModifyCmds& modifyCmds = Params::instance().modifyCmds_;
ModifyCmds::const_iterator i = modifyCmds.begin();
ModifyCmds::const_iterator end = modifyCmds.end();
for (; i != end; ++i) {
switch (i->cmdId_) {
case add:
addMetadatum(pImage, *i);
break;
case set:
setMetadatum(pImage, *i);
break;
case del:
delMetadatum(pImage, *i);
break;
case reg:
regNamespace(*i);
break;
case invalidCmdId:
assert(invalidCmdId == i->cmdId_);
break;
}
}
} // Modify::applyCommands
void Modify::addMetadatum(Exiv2::Image* pImage, const ModifyCmd& modifyCmd)
{
if (Params::instance().verbose_) {
std::cout << _("Add") << " " << modifyCmd.key_ << " \""
<< modifyCmd.value_ << "\" ("
<< Exiv2::TypeInfo::typeName(modifyCmd.typeId_)
<< ")" << std::endl;
}
Exiv2::ExifData& exifData = pImage->exifData();
Exiv2::IptcData& iptcData = pImage->iptcData();
Exiv2::XmpData& xmpData = pImage->xmpData();
Exiv2::Value::AutoPtr value = Exiv2::Value::create(modifyCmd.typeId_);
if (0 == value->read(modifyCmd.value_)) {
if (modifyCmd.metadataId_ == exif) {
exifData.add(Exiv2::ExifKey(modifyCmd.key_), value.get());
}
if (modifyCmd.metadataId_ == iptc) {
iptcData.add(Exiv2::IptcKey(modifyCmd.key_), value.get());
}
if (modifyCmd.metadataId_ == xmp) {
xmpData.add(Exiv2::XmpKey(modifyCmd.key_), value.get());
}
}
}
// This function looks rather complex because we try to avoid adding an
// empty metadatum if reading the value fails
void Modify::setMetadatum(Exiv2::Image* pImage, const ModifyCmd& modifyCmd)
{
if (Params::instance().verbose_) {
std::cout << _("Set") << " " << modifyCmd.key_ << " \""
<< modifyCmd.value_ << "\" ("
<< Exiv2::TypeInfo::typeName(modifyCmd.typeId_)
<< ")" << std::endl;
}
Exiv2::ExifData& exifData = pImage->exifData();
Exiv2::IptcData& iptcData = pImage->iptcData();
Exiv2::XmpData& xmpData = pImage->xmpData();
Exiv2::Metadatum* metadatum = 0;
if (modifyCmd.metadataId_ == exif) {
Exiv2::ExifData::iterator pos =
exifData.findKey(Exiv2::ExifKey(modifyCmd.key_));
if (pos != exifData.end()) {
metadatum = &(*pos);
}
}
if (modifyCmd.metadataId_ == iptc) {
Exiv2::IptcData::iterator pos =
iptcData.findKey(Exiv2::IptcKey(modifyCmd.key_));
if (pos != iptcData.end()) {
metadatum = &(*pos);
}
}
if (modifyCmd.metadataId_ == xmp) {
Exiv2::XmpData::iterator pos =
xmpData.findKey(Exiv2::XmpKey(modifyCmd.key_));
if (pos != xmpData.end()) {
metadatum = &(*pos);
}
}
// If a type was explicitly requested, use it; else
// use the current type of the metadatum, if any;
// or the default type
Exiv2::Value::AutoPtr value;
if (metadatum) {
value = metadatum->getValue();
}
if ( value.get() == 0
|| ( modifyCmd.explicitType_
&& modifyCmd.typeId_ != value->typeId())) {
value = Exiv2::Value::create(modifyCmd.typeId_);
}
if (0 == value->read(modifyCmd.value_)) {
if (metadatum) {
metadatum->setValue(value.get());
}
else {
if (modifyCmd.metadataId_ == exif) {
exifData.add(Exiv2::ExifKey(modifyCmd.key_), value.get());
}
if (modifyCmd.metadataId_ == iptc) {
iptcData.add(Exiv2::IptcKey(modifyCmd.key_), value.get());
}
if (modifyCmd.metadataId_ == xmp) {
xmpData.add(Exiv2::XmpKey(modifyCmd.key_), value.get());
}
}
}
else {
std::cerr << _("Warning") << ": " << modifyCmd.key_ << ": "
<< _("Failed to read") << " "
<< Exiv2::TypeInfo::typeName(value->typeId())
<< " " << _("value")
<< " \"" << modifyCmd.value_ << "\"\n";
}
}
void Modify::delMetadatum(Exiv2::Image* pImage, const ModifyCmd& modifyCmd)
{
if (Params::instance().verbose_) {
std::cout << _("Del") << " " << modifyCmd.key_ << std::endl;
}
Exiv2::ExifData& exifData = pImage->exifData();
Exiv2::IptcData& iptcData = pImage->iptcData();
Exiv2::XmpData& xmpData = pImage->xmpData();
if (modifyCmd.metadataId_ == exif) {
Exiv2::ExifData::iterator pos;
Exiv2::ExifKey exifKey = Exiv2::ExifKey(modifyCmd.key_);
while((pos = exifData.findKey(exifKey)) != exifData.end()) {
exifData.erase(pos);
}
}
if (modifyCmd.metadataId_ == iptc) {
Exiv2::IptcData::iterator pos;
Exiv2::IptcKey iptcKey = Exiv2::IptcKey(modifyCmd.key_);
while((pos = iptcData.findKey(iptcKey)) != iptcData.end()) {
iptcData.erase(pos);
}
}
if (modifyCmd.metadataId_ == xmp) {
Exiv2::XmpData::iterator pos;
Exiv2::XmpKey xmpKey = Exiv2::XmpKey(modifyCmd.key_);
while((pos = xmpData.findKey(xmpKey)) != xmpData.end()) {
xmpData.erase(pos);
}
}
}
void Modify::regNamespace(const ModifyCmd& modifyCmd)
{
if (Params::instance().verbose_) {
std::cout << _("Reg ") << modifyCmd.key_ << "=\""
<< modifyCmd.value_ << "\"" << std::endl;
}
// Registration has been done immediately after parsing the command.
}
Modify::AutoPtr Modify::clone() const
{
return AutoPtr(clone_());
}
Modify* Modify::clone_() const
{
return new Modify(*this);
}
int Adjust::run(const std::string& path)
try {
adjustment_ = Params::instance().adjustment_;
yearAdjustment_ = Params::instance().yodAdjust_[Params::yodYear].adjustment_;
monthAdjustment_ = Params::instance().yodAdjust_[Params::yodMonth].adjustment_;
dayAdjustment_ = Params::instance().yodAdjust_[Params::yodDay].adjustment_;
if (!Exiv2::fileExists(path, true)) {
std::cerr << path
<< ": " << _("Failed to open the file\n");
return -1;
}
Timestamp ts;
if (Params::instance().preserve_) {
ts.read(path);
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path);
assert(image.get() != 0);
image->readMetadata();
Exiv2::ExifData& exifData = image->exifData();
if (exifData.empty()) {
std::cerr << path
<< ": " << _("No Exif data found in the file\n");
return -3;
}
int rc = adjustDateTime(exifData, "Exif.Image.DateTime", path);
rc += adjustDateTime(exifData, "Exif.Photo.DateTimeOriginal", path);
rc += adjustDateTime(exifData, "Exif.Photo.DateTimeDigitized", path);
if (rc) return 1;
image->writeMetadata();
if (Params::instance().preserve_) {
ts.touch(path);
}
return rc;
}
catch(const Exiv2::AnyError& e)
{
std::cerr << "Exiv2 exception in adjust action for file " << path
<< ":\n" << e << "\n";
return 1;
} // Adjust::run
Adjust::AutoPtr Adjust::clone() const
{
return AutoPtr(clone_());
}
Adjust* Adjust::clone_() const
{
return new Adjust(*this);
}
int Adjust::adjustDateTime(Exiv2::ExifData& exifData,
const std::string& key,
const std::string& path) const
{
Exiv2::ExifKey ek(key);
Exiv2::ExifData::iterator md = exifData.findKey(ek);
if (md == exifData.end()) {
// Key not found. That's ok, we do nothing.
return 0;
}
std::string timeStr = md->toString();
if (timeStr == "" || timeStr[0] == ' ') {
std::cerr << path << ": " << _("Timestamp of metadatum with key") << " `"
<< ek << "' " << _("not set\n");
return 1;
}
if (Params::instance().verbose_) {
bool comma = false;
std::cout << _("Adjusting") << " `" << ek << "' " << _("by");
if (yearAdjustment_ != 0) {
std::cout << (yearAdjustment_ < 0 ? " " : " +") << yearAdjustment_ << " ";
if (yearAdjustment_ < -1 || yearAdjustment_ > 1) {
std::cout << _("years");
}
else {
std::cout << _("year");
}
comma = true;
}
if (monthAdjustment_ != 0) {
if (comma) std::cout << ",";
std::cout << (monthAdjustment_ < 0 ? " " : " +") << monthAdjustment_ << " ";
if (monthAdjustment_ < -1 || monthAdjustment_ > 1) {
std::cout << _("months");
}
else {
std::cout << _("month");
}
comma = true;
}
if (dayAdjustment_ != 0) {
if (comma) std::cout << ",";
std::cout << (dayAdjustment_ < 0 ? " " : " +") << dayAdjustment_ << " ";
if (dayAdjustment_ < -1 || dayAdjustment_ > 1) {
std::cout << _("days");
}
else {
std::cout << _("day");
}
comma = true;
}
if (adjustment_ != 0) {
if (comma) std::cout << ",";
std::cout << " " << adjustment_ << _("s");
}
}
struct tm tm;
if (str2Tm(timeStr, &tm) != 0) {
if (Params::instance().verbose_) std::cout << std::endl;
std::cerr << path << ": " << _("Failed to parse timestamp") << " `"
<< timeStr << "'\n";
return 1;
}
const long monOverflow = (tm.tm_mon + monthAdjustment_) / 12;
tm.tm_mon = (tm.tm_mon + monthAdjustment_) % 12;
tm.tm_year += yearAdjustment_ + monOverflow;
// Let's not create files with non-4-digit years, we can't read them.
if (tm.tm_year > 9999 - 1900 || tm.tm_year < 1000 - 1900) {
if (Params::instance().verbose_) std::cout << std::endl;
std::cerr << path << ": " << _("Can't adjust timestamp by") << " "
<< yearAdjustment_ + monOverflow
<< " " << _("years") << "\n";
return 1;
}
time_t time = timegm(&tm);
time += adjustment_ + dayAdjustment_ * 86400;
timeStr = time2Str(time);
if (Params::instance().verbose_) {
std::cout << " " << _("to") << " " << timeStr << std::endl;
}
md->setValue(timeStr);
return 0;
} // Adjust::adjustDateTime
int FixIso::run(const std::string& path)
{
try {
if (!Exiv2::fileExists(path, true)) {
std::cerr << path
<< ": " <<_("Failed to open the file\n");
return -1;
}
Timestamp ts;
if (Params::instance().preserve_) {
ts.read(path);
}
Exiv2::Image::AutoPtr image = Exiv2::ImageFactory::open(path);
assert(image.get() != 0);
image->readMetadata();
Exiv2::ExifData& exifData = image->exifData();
if (exifData.empty()) {
std::cerr << path
<< ": " << _("No Exif data found in the file\n");
return -3;
}
// Check if the standard tag exists
Exiv2::ExifKey key("Exif.Photo.ISOSpeedRatings");
Exiv2::ExifData::iterator md = exifData.findKey(key);
if (md != exifData.end()) {
if (Params::instance().verbose_) {
std::cout << _("Standard Exif ISO tag exists; not modified\n");
}
return 0;
}
// Fix Nikon ISO setting
key = Exiv2::ExifKey("Exif.Nikon3.ISOSpeed");
md = exifData.findKey(key);
if (md == exifData.end()) {
key = Exiv2::ExifKey("Exif.Nikon2.ISOSpeed");
md = exifData.findKey(key);
}
if (md == exifData.end()) {
key = Exiv2::ExifKey("Exif.Nikon1.ISOSpeed");
md = exifData.findKey(key);
}
// Canon has a similar bad habit, fix that too
if (md == exifData.end()) {
key = Exiv2::ExifKey("Exif.CanonSi.ISOSpeed");
md = exifData.findKey(key);
}
if (md == exifData.end()) {
key = Exiv2::ExifKey("Exif.CanonCs.ISOSpeed");
md = exifData.findKey(key);
}
// Copy the proprietary tag to the standard place
if (md != exifData.end()) {
std::ostringstream os;
os << *md;
if (Params::instance().verbose_) {
std::cout << _("Setting Exif ISO value to") << " " << os.str() << "\n";
}
exifData["Exif.Photo.ISOSpeedRatings"] = os.str();
}
image->writeMetadata();
if (Params::instance().preserve_) {
ts.touch(path);
}
return 0;
}
catch(const Exiv2::AnyError& e)
{
std::cerr << "Exiv2 exception in fixiso action for file " << path
<< ":\n" << e << "\n";
return 1;
}
} // FixIso::run
FixIso::AutoPtr FixIso::clone() const
{
return AutoPtr(clone_());
}
FixIso* FixIso::clone_() const
{
return new FixIso(*this);
}
} // namespace Action
// *****************************************************************************
// local definitions
namespace {
//! @cond IGNORE
int Timestamp::read(const std::string& path)
{
struct stat buf;
int rc = stat(path.c_str(), &buf);
if (0 == rc) {
actime_ = buf.st_atime;
modtime_ = buf.st_mtime;
}
return rc;
}
int Timestamp::read(struct tm* tm)
{
int rc = 1;
time_t t = mktime(tm);
if (t != (time_t)-1) {
rc = 0;
actime_ = t;
modtime_ = t;
}
return rc;
}
int Timestamp::touch(const std::string& path)
{
if (0 == actime_) return 1;
struct utimbuf buf;
buf.actime = actime_;
buf.modtime = modtime_;
return utime(path.c_str(), &buf);
}
//! @endcond
int str2Tm(const std::string& timeStr, struct tm* tm)
{
if (timeStr.length() == 0 || timeStr[0] == ' ') return 1;
if (timeStr.length() < 19) return 2;
if ( timeStr[4] != ':' || timeStr[7] != ':' || timeStr[10] != ' '
|| timeStr[13] != ':' || timeStr[16] != ':') return 3;
if (0 == tm) return 4;
std::memset(tm, 0x0, sizeof(struct tm));
tm->tm_isdst = -1;
long tmp;
if (!Util::strtol(timeStr.substr(0,4).c_str(), tmp)) return 5;
tm->tm_year = tmp - 1900;
if (!Util::strtol(timeStr.substr(5,2).c_str(), tmp)) return 6;
tm->tm_mon = tmp - 1;
if (!Util::strtol(timeStr.substr(8,2).c_str(), tmp)) return 7;
tm->tm_mday = tmp;
if (!Util::strtol(timeStr.substr(11,2).c_str(), tmp)) return 8;
tm->tm_hour = tmp;
if (!Util::strtol(timeStr.substr(14,2).c_str(), tmp)) return 9;
tm->tm_min = tmp;
if (!Util::strtol(timeStr.substr(17,2).c_str(), tmp)) return 10;
tm->tm_sec = tmp;
return 0;
} // str2Tm
std::string time2Str(time_t time)
{
struct tm* tm = gmtime(&time);
return tm2Str(tm);
} // time2Str
std::string tm2Str(struct tm* tm)
{
if (0 == tm) return "";
std::ostringstream os;
os << std::setfill('0')
<< tm->tm_year + 1900 << ":"
<< std::setw(2) << tm->tm_mon + 1 << ":"
<< std::setw(2) << tm->tm_mday << " "
<< std::setw(2) << tm->tm_hour << ":"
<< std::setw(2) << tm->tm_min << ":"
<< std::setw(2) << tm->tm_sec;
return os.str();
} // tm2Str
int metacopy(const std::string& source,
const std::string& target,
int targetType,
bool preserve)
{
if (!Exiv2::fileExists(source, true)) {
std::cerr << source
<< ": " << _("Failed to open the file\n");
return -1;
}
Exiv2::Image::AutoPtr sourceImage = Exiv2::ImageFactory::open(source);
assert(sourceImage.get() != 0);
sourceImage->readMetadata();
// Apply any modification commands to the source image on-the-fly
Action::Modify::applyCommands(sourceImage.get());
Exiv2::Image::AutoPtr targetImage;
if (Exiv2::fileExists(target)) {
targetImage = Exiv2::ImageFactory::open(target);
assert(targetImage.get() != 0);
if (preserve) targetImage->readMetadata();
}
else {
targetImage = Exiv2::ImageFactory::create(targetType, target);
assert(targetImage.get() != 0);
}
if ( Params::instance().target_ & Params::ctExif
&& !sourceImage->exifData().empty()) {
if (Params::instance().verbose_) {
std::cout << _("Writing Exif data from") << " " << source
<< " " << _("to") << " " << target << std::endl;
}
targetImage->setExifData(sourceImage->exifData());
}
if ( Params::instance().target_ & Params::ctIptc
&& !sourceImage->iptcData().empty()) {
if (Params::instance().verbose_) {
std::cout << _("Writing IPTC data from") << " " << source
<< " " << _("to") << " " << target << std::endl;
}
targetImage->setIptcData(sourceImage->iptcData());
}
if ( Params::instance().target_ & Params::ctXmp
&& !sourceImage->xmpData().empty()) {
if (Params::instance().verbose_) {
std::cout << _("Writing XMP data from") << " " << source
<< " " << _("to") << " " << target << std::endl;
}
// Todo: Should use XMP packet if there are no XMP modification commands
targetImage->setXmpData(sourceImage->xmpData());
}
if ( Params::instance().target_ & Params::ctComment
&& !sourceImage->comment().empty()) {
if (Params::instance().verbose_) {
std::cout << _("Writing JPEG comment from") << " " << source
<< " " << _("to") << " " << target << std::endl;
}
targetImage->setComment(sourceImage->comment());
}
try {
targetImage->writeMetadata();
}
catch (const Exiv2::AnyError& e) {
std::cerr << target <<
": " << _("Could not write metadata to file") << ": " << e << "\n";
}
return 0;
} // metacopy
int renameFile(std::string& newPath, const struct tm* tm)
{
std::string path = newPath;
std::string format = Params::instance().format_;
Util::replace(format, ":basename:", Util::basename(path, true));
Util::replace(format, ":dirname:", Util::basename(Util::dirname(path)));
Util::replace(format, ":parentname:", Util::basename(Util::dirname(Util::dirname(path))));
const size_t max = 1024;
char basename[max];
std::memset(basename, 0x0, max);
if (strftime(basename, max, format.c_str(), tm) == 0) {
std::cerr << _("Filename format yields empty filename for the file") << " "
<< path << "\n";
return 1;
}
newPath = Util::dirname(path) + EXV_SEPERATOR_STR
+ basename + Util::suffix(path);
if ( Util::dirname(newPath) == Util::dirname(path)
&& Util::basename(newPath) == Util::basename(path)) {
if (Params::instance().verbose_) {
std::cout << _("This file already has the correct name") << std::endl;
}
return -1;
}
bool go = true;
int seq = 1;
std::string s;
Params::FileExistsPolicy fileExistsPolicy
= Params::instance().fileExistsPolicy_;
while (go) {
if (Exiv2::fileExists(newPath)) {
switch (fileExistsPolicy) {
case Params::overwritePolicy:
go = false;
break;
case Params::renamePolicy:
newPath = Util::dirname(path)
+ EXV_SEPERATOR_STR + basename
+ "_" + Exiv2::toString(seq++)
+ Util::suffix(path);
break;
case Params::askPolicy:
std::cout << Params::instance().progname()
<< ": " << _("File") << " `" << newPath
<< "' " << _("exists. [O]verwrite, [r]ename or [s]kip?")
<< " ";
std::cin >> s;
switch (s[0]) {
case 'o':
case 'O':
go = false;
break;
case 'r':
case 'R':
fileExistsPolicy = Params::renamePolicy;
newPath = Util::dirname(path)
+ EXV_SEPERATOR_STR + basename
+ "_" + Exiv2::toString(seq++)
+ Util::suffix(path);
break;
default: // skip
return -1;
break;
}
}
}
else {
go = false;
}
}
if (Params::instance().verbose_) {
std::cout << _("Renaming file to") << " " << newPath;
if (Params::instance().timestamp_) {
std::cout << ", " << _("updating timestamp");
}
std::cout << std::endl;
}
// Workaround for MinGW rename which does not overwrite existing files
remove(newPath.c_str());
if (std::rename(path.c_str(), newPath.c_str()) == -1) {
std::cerr << Params::instance().progname()
<< ": " << _("Failed to rename") << " "
<< path << " " << _("to") << " " << newPath << ": "
<< Exiv2::strError() << "\n";
return 1;
}
return 0;
} // renameFile
std::string newFilePath(const std::string& path, const std::string& ext)
{
std::string directory = Params::instance().directory_;
if (directory.empty()) directory = Util::dirname(path);
std::string newPath = directory + EXV_SEPERATOR_STR
+ Util::basename(path, true) + ext;
return newPath;
}
int dontOverwrite(const std::string& path)
{
if (!Params::instance().force_ && Exiv2::fileExists(path)) {
std::cout << Params::instance().progname()
<< ": " << _("Overwrite") << " `" << path << "'? ";
std::string s;
std::cin >> s;
if (s[0] != 'y' && s[0] != 'Y') return 1;
}
return 0;
}
}
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