// // Copyright (c) 2016 KAMADA Ken'ichi. // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions // are met: // 1. Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // 2. Redistributions 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. // // THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 AUTHOR 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. // use std::fmt; use crate::error::Error; use crate::value; use crate::value::Value; use crate::util::atou16; /// A tag of a TIFF/Exif field. /// /// Some well-known tags are provided as associated constants of /// this type. The constant names follow the Exif specification /// but not the Rust naming conventions. /// /// A non-predefined tag can also be specified /// by the context and the number as in `Tag(Context::Tiff, 0x100)`. // // This is not an enum to keep safety and API stability, while // supporting unknown tag numbers. This comment is based on the // behavior of Rust 1.12. // Storing unknown values in a repr(u16) enum is unsafe. The compiler // assumes that there is no undefined discriminant even with a C-like // enum, so the exhaustiveness check of a match expression will break. // Storing unknown values in a special variant such as Unknown(u16) // tends to break backward compatibility. When Tag::VariantFoo is // defined in a new version of the library, the old codes using // Tag::Unknown(Foo's tag number) will break. // // Use of constants is restricted in patterns. As of Rust 1.12, // PartialEq and Eq need to be _automatically derived_ for Tag to // emulate structural equivalency. // #[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)] pub struct Tag(pub Context, pub u16); impl Tag { /// Returns the context of the tag. /// /// # Examples /// ``` /// use exif::{Context, Tag}; /// assert_eq!(Tag::XResolution.context(), Context::Tiff); /// assert_eq!(Tag::DateTimeOriginal.context(), Context::Exif); /// ``` #[inline] pub fn context(self) -> Context { self.0 } /// Returns the tag number. /// /// # Examples /// ``` /// use exif::Tag; /// assert_eq!(Tag::XResolution.number(), 0x11a); /// assert_eq!(Tag::DateTimeOriginal.number(), 0x9003); /// ``` #[inline] pub fn number(self) -> u16 { self.1 } /// Returns the description of the tag. #[inline] pub fn description(&self) -> Option<&str> { get_tag_info(*self).map(|ti| ti.desc) } /// Returns the default value of the tag. `None` is returned if /// it is not defined in the standard or it depends on another tag. #[inline] pub fn default_value(&self) -> Option { get_tag_info(*self).and_then(|ti| (&ti.default).into()) } pub(crate) fn unit(self) -> Option<&'static [UnitPiece]> { get_tag_info(self).and_then(|ti| ti.unit) } } impl fmt::Display for Tag { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match get_tag_info(*self) { Some(ti) => f.pad(ti.name), None => f.pad(&format!("{:?}", self)), } } } /// An enum that indicates how a tag number is interpreted. #[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)] #[non_exhaustive] pub enum Context { /// TIFF attributes defined in the TIFF Rev. 6.0 specification. Tiff, // 0th/1st IFD (toplevel) /// Exif attributes. Exif, // -- Exif IFD /// GPS attributes. Gps, // -- GPS IFD /// Interoperability attributes. Interop, // -- Exif IFD -- Interoperability IFD } #[derive(Debug)] pub enum UnitPiece { Value, Str(&'static str), Tag(Tag), } macro_rules! unit { () => ( None ); ( $str:literal ) => ( unit![V, concat!(" ", $str)] ); ( Tag::$tag:ident ) => ( unit![V, " ", Tag::$tag] ); ( $($tokens:tt)* ) => ( Some(unit_expand!( ; $($tokens)* , )) ); } macro_rules! unit_expand { ( $($built:expr),* ; ) => ( &[$($built),*] ); ( $($built:expr),* ; , ) => ( &[$($built),*] ); ( $($built:expr),* ; V, $($rest:tt)* ) => ( unit_expand!($($built,)* UnitPiece::Value ; $($rest)*) ); ( $($built:expr),* ; $str:literal, $($rest:tt)* ) => ( unit_expand!($($built,)* UnitPiece::Str($str) ; $($rest)*) ); ( $($built:expr),* ; concat!($($strs:literal),*), $($rest:tt)* ) => ( unit_expand!($($built,)* UnitPiece::Str(concat!($($strs),*)) ; $($rest)*) ); ( $($built:expr),* ; Tag::$tag:ident, $($rest:tt)* ) => ( unit_expand!($($built,)* UnitPiece::Tag(Tag::$tag) ; $($rest)*) ); } macro_rules! generate_well_known_tag_constants { ( $( |$ctx:path| $( // Copy the doc attribute to the actual definition. $( #[$attr:meta] )* ($name:ident, $num:expr, $defval:expr, $dispval:ident, $unit:expr, $desc:expr) ),+, )+ ) => ( // This is not relevant for associated constants, because // they cannot be imported even with "uniform paths". // /// It is not recommended to import the constants directly into // /// your namespace; import the module and use with the module name // /// like `tag::DateTime`. The constant names follow the Exif // /// specification but not the Rust naming conventions, and a user // /// of the constants will get the non_upper_case_globals warning // /// if a bare constant is used in a match arm. // // This is discussed in // // . impl Tag { $($( $( #[$attr] )* #[allow(non_upper_case_globals)] pub const $name: Tag = Tag($ctx, $num); )+)+ } mod tag_info { use std::fmt; use crate::value::Value; use crate::value::DefaultValue; use super::{Tag, UnitPiece}; pub struct TagInfo { pub name: &'static str, pub desc: &'static str, pub default: DefaultValue, pub dispval: fn(&mut dyn fmt::Write, &Value) -> fmt::Result, pub unit: Option<&'static [UnitPiece]>, } $($( #[allow(non_upper_case_globals)] pub static $name: TagInfo = TagInfo { name: stringify!($name), desc: $desc, default: $defval, dispval: super::$dispval, unit: $unit, }; )+)+ } fn get_tag_info(tag: Tag) -> Option<&'static tag_info::TagInfo> { match tag { $($( Tag::$name => Some(&tag_info::$name), )+)+ _ => None, } } ) } // Tag constant names do not follow the Rust naming conventions but // the Exif field names: camel cases and all-capital acronyms. generate_well_known_tag_constants!( // Exif-specific IFDs [EXIF23 4.6.3]. |Context::Tiff| /// A pointer to the Exif IFD. This is used for the internal structure /// of Exif data and will not be returned to the user. #[doc(hidden)] (ExifIFDPointer, 0x8769, DefaultValue::None, d_default, unit![], "Exif IFD pointer"), /// A pointer to the GPS IFD. This is used for the internal structure /// of Exif data and will not be returned to the user. #[doc(hidden)] (GPSInfoIFDPointer, 0x8825, DefaultValue::None, d_default, unit![], "GPS Info IFD pointer"), |Context::Exif| /// A pointer to the interoperability IFD. This is used for the internal /// structure of Exif data and will not be returned to the user. #[doc(hidden)] (InteropIFDPointer, 0xa005, DefaultValue::None, d_default, unit![], "Interoperability IFD pointer"), // TIFF primary and thumbnail attributes [EXIF23 4.6.4 Table 4, // 4.6.8 Table 17, and 4.6.8 Table 21]. |Context::Tiff| (ImageWidth, 0x100, DefaultValue::None, d_default, unit!["pixels"], "Image width"), (ImageLength, 0x101, DefaultValue::None, d_default, unit!["pixels"], "Image height"), (BitsPerSample, 0x102, DefaultValue::Short(&[8, 8, 8]), d_default, unit![], "Number of bits per component"), (Compression, 0x103, DefaultValue::None, d_compression, unit![], "Compression scheme"), (PhotometricInterpretation, 0x106, DefaultValue::None, d_photointp, unit![], "Pixel composition"), (ImageDescription, 0x10e, DefaultValue::None, d_default, unit![], "Image title"), /// Manufacturer of the image input equipment. (Make, 0x10f, DefaultValue::None, d_default, unit![], "Manufacturer of image input equipment"), /// Model name or number of the image input equipment. (Model, 0x110, DefaultValue::None, d_default, unit![], "Model of image input equipment"), (StripOffsets, 0x111, DefaultValue::None, d_default, unit![], "Image data location"), (Orientation, 0x112, DefaultValue::Short(&[1]), d_orientation, unit![], "Orientation of image"), (SamplesPerPixel, 0x115, DefaultValue::Short(&[3]), d_default, unit![], "Number of components"), (RowsPerStrip, 0x116, DefaultValue::None, d_default, unit![], "Number of rows per strip"), (StripByteCounts, 0x117, DefaultValue::None, d_default, unit![], "Bytes per compressed strip"), (XResolution, 0x11a, DefaultValue::Rational(&[(72, 1)]), d_decimal, unit![V, " pixels per ", Tag::ResolutionUnit], "Image resolution in width direction"), (YResolution, 0x11b, DefaultValue::Rational(&[(72, 1)]), d_decimal, unit![V, " pixels per ", Tag::ResolutionUnit], "Image resolution in height direction"), (PlanarConfiguration, 0x11c, DefaultValue::Short(&[1]), d_planarcfg, unit![], "Image data arrangement"), /// Unit of XResolution and YResolution fields. (ResolutionUnit, 0x128, DefaultValue::Short(&[2]), d_resunit, unit![], "Unit of X and Y resolution"), (TransferFunction, 0x12d, DefaultValue::None, d_default, unit![], "Transfer function"), /// Name and version of the software used to create the image. (Software, 0x131, DefaultValue::None, d_default, unit![], "Software used"), /// Date and time when the image file was created or last edited. /// For the time when the picture was taken, see DateTimeOriginal field. (DateTime, 0x132, DefaultValue::None, d_datetime, unit![], "File change date and time"), (Artist, 0x13b, DefaultValue::None, d_default, unit![], "Person who created the image"), (WhitePoint, 0x13e, DefaultValue::None, d_decimal, unit![], "White point chromaticity"), (PrimaryChromaticities, 0x13f, DefaultValue::None, d_decimal, unit![], "Chromaticities of primaries"), // Not referenced in Exif. (TileOffsets, 0x144, DefaultValue::None, d_default, unit![], "Tiled image data location"), // Not referenced in Exif. (TileByteCounts, 0x145, DefaultValue::None, d_default, unit![], "Bytes per compressed tile"), (JPEGInterchangeFormat, 0x201, DefaultValue::None, d_default, unit![], "Offset to JPEG SOI"), (JPEGInterchangeFormatLength, 0x202, DefaultValue::None, d_default, unit![], "Bytes of JPEG data"), (YCbCrCoefficients, 0x211, DefaultValue::Unspecified, d_decimal, unit![], "Color space transformation matrix coefficients"), (YCbCrSubSampling, 0x212, DefaultValue::None, d_ycbcrsubsamp, unit![], "Subsampling ratio of Y to C"), (YCbCrPositioning, 0x213, DefaultValue::Short(&[1]), d_ycbcrpos, unit![], "Y and C positioning"), (ReferenceBlackWhite, 0x214, DefaultValue::ContextDependent, d_decimal, unit![], "Pair of black and white reference values"), (Copyright, 0x8298, DefaultValue::None, d_default, unit![], "Copyright holder"), // Exif IFD attributes [EXIF23 4.6.5 Table 7 and 4.6.8 Table 18]. |Context::Exif| (ExposureTime, 0x829a, DefaultValue::None, d_exptime, unit!["s"], "Exposure time"), (FNumber, 0x829d, DefaultValue::None, d_decimal, // F-number is dimensionless, but usually prefixed with "F" in Japan, // "f/" in the U.S., and so on. unit!["f/", V], "F number"), (ExposureProgram, 0x8822, DefaultValue::None, d_expprog, unit![], "Exposure program"), (SpectralSensitivity, 0x8824, DefaultValue::None, d_default, unit![], "Spectral sensitivity"), /// Sensitivity of the device. /// /// The value may be represented by standard output sensitivity (SOS), /// recommended exposure index (REI), or ISO speed. /// What is stored is designated by SensitivityType field. /// /// This field is 16-bit and may be saturated. For 32-bit values, /// see StandardOutputSensitivity, RecommendedExposureIndex, /// ISOSpeed, ISOSpeedLatitudeyyy, and ISOSpeedLatitudezzz fields. (PhotographicSensitivity, 0x8827, DefaultValue::None, d_default, unit![], "Photographic sensitivity"), (OECF, 0x8828, DefaultValue::None, d_default, unit![], "Optoelectric conversion factor"), (SensitivityType, 0x8830, DefaultValue::None, d_sensitivitytype, unit![], "Sensitivity type"), (StandardOutputSensitivity, 0x8831, DefaultValue::None, d_default, unit![], "Standard output sensitivity"), (RecommendedExposureIndex, 0x8832, DefaultValue::None, d_default, unit![], "Recommended exposure index"), (ISOSpeed, 0x8833, DefaultValue::None, d_default, unit![], "ISO speed"), (ISOSpeedLatitudeyyy, 0x8834, DefaultValue::None, d_default, unit![], "ISO speed latitude yyy"), (ISOSpeedLatitudezzz, 0x8835, DefaultValue::None, d_default, unit![], "ISO speed latitude zzz"), // The absence of this field means non-conformance to Exif, so the default // value specified in the standard (e.g., "0231") should not apply. (ExifVersion, 0x9000, DefaultValue::None, d_exifver, unit![], "Exif version"), /// Date and time when the original image was generated (e.g., /// the picture was taken by a camera). (DateTimeOriginal, 0x9003, DefaultValue::None, d_datetime, unit![], "Date and time of original data generation"), /// Date and time when the image was stored as digital data. /// If a picture is taken by a film camera and then digitized later, /// this value will be different from DateTimeOriginal field. (DateTimeDigitized, 0x9004, DefaultValue::None, d_datetime, unit![], "Date and time of digital data generation"), /// Timezone offset for DateTime field. (OffsetTime, 0x9010, DefaultValue::None, d_default, unit![], "Offset data of DateTime"), /// Timezone offset for DateTimeOriginal field. (OffsetTimeOriginal, 0x9011, DefaultValue::None, d_default, unit![], "Offset data of DateTimeOriginal"), /// Timezone offset for DateTimeDigitized field. (OffsetTimeDigitized, 0x9012, DefaultValue::None, d_default, unit![], "Offset data of DateTimeDigitized"), (ComponentsConfiguration, 0x9101, DefaultValue::ContextDependent, d_cpntcfg, unit![], "Meaning of each component"), (CompressedBitsPerPixel, 0x9102, DefaultValue::None, d_decimal, unit![], "Image compression mode"), (ShutterSpeedValue, 0x9201, DefaultValue::None, d_decimal, unit!["EV"], "Shutter speed"), (ApertureValue, 0x9202, DefaultValue::None, d_decimal, unit!["EV"], "Aperture"), (BrightnessValue, 0x9203, DefaultValue::None, d_optdecimal, unit!["EV"], "Brightness"), (ExposureBiasValue, 0x9204, DefaultValue::None, d_decimal, unit!["EV"], "Exposure bias"), (MaxApertureValue, 0x9205, DefaultValue::None, d_decimal, unit!["EV"], "Maximum lens aperture"), (SubjectDistance, 0x9206, DefaultValue::None, d_subjdist, unit!["m"], "Subject distance"), (MeteringMode, 0x9207, DefaultValue::Short(&[0]), d_metering, unit![], "Metering mode"), (LightSource, 0x9208, DefaultValue::Short(&[0]), d_lightsrc, unit![], "Light source"), (Flash, 0x9209, DefaultValue::Unspecified, d_flash, unit![], "Flash"), (FocalLength, 0x920a, DefaultValue::None, d_decimal, unit!["mm"], "Lens focal length"), (SubjectArea, 0x9214, DefaultValue::None, d_subjarea, unit![], "Subject area"), (MakerNote, 0x927c, DefaultValue::None, d_default, unit![], "Manufacturer notes"), (UserComment, 0x9286, DefaultValue::None, d_default, unit![], "User comments"), /// Subseconds for DateTime field. (SubSecTime, 0x9290, DefaultValue::None, d_default, unit![], "DateTime subseconds"), /// Subseconds for DateTimeOriginal field. (SubSecTimeOriginal, 0x9291, DefaultValue::None, d_default, unit![], "DateTimeOriginal subseconds"), /// Subseconds for DateTimeDigitized field. (SubSecTimeDigitized, 0x9292, DefaultValue::None, d_default, unit![], "DateTimeDigitized subseconds"), (Temperature, 0x9400, DefaultValue::None, d_optdecimal, unit!["degC"], "Temperature"), (Humidity, 0x9401, DefaultValue::None, d_optdecimal, unit!["%"], "Humidity"), (Pressure, 0x9402, DefaultValue::None, d_optdecimal, unit!["hPa"], "Pressure"), (WaterDepth, 0x9403, DefaultValue::None, d_optdecimal, unit!["m"], "Water depth"), (Acceleration, 0x9404, DefaultValue::None, d_optdecimal, unit!["mGal"], "Acceleration"), (CameraElevationAngle, 0x9405, DefaultValue::None, d_optdecimal, unit!["deg"], "Camera elevation angle"), (FlashpixVersion, 0xa000, DefaultValue::Undefined(b"0100"), d_exifver, unit![], "Supported Flashpix version"), (ColorSpace, 0xa001, DefaultValue::Unspecified, d_cspace, unit![], "Color space information"), (PixelXDimension, 0xa002, DefaultValue::None, d_default, unit!["pixels"], "Valid image width"), (PixelYDimension, 0xa003, DefaultValue::Unspecified, d_default, unit!["pixels"], "Valid image height"), (RelatedSoundFile, 0xa004, DefaultValue::None, d_default, unit![], "Related audio file"), (FlashEnergy, 0xa20b, DefaultValue::None, d_decimal, unit!["BCPS"], "Flash energy"), (SpatialFrequencyResponse, 0xa20c, DefaultValue::None, d_default, unit![], "Spatial frequency response"), (FocalPlaneXResolution, 0xa20e, DefaultValue::None, d_decimal, unit![V, " pixels per ", Tag::FocalPlaneResolutionUnit], "Focal plane X resolution"), (FocalPlaneYResolution, 0xa20f, DefaultValue::None, d_decimal, unit![V, " pixels per ", Tag::FocalPlaneResolutionUnit], "Focal plane Y resolution"), /// Unit of FocalPlaneXResolution and FocalPlaneYResolution fields. (FocalPlaneResolutionUnit, 0xa210, DefaultValue::Short(&[2]), d_resunit, unit![], "Focal plane resolution unit"), (SubjectLocation, 0xa214, DefaultValue::None, d_subjarea, unit![], "Subject location"), (ExposureIndex, 0xa215, DefaultValue::None, d_decimal, unit![], "Exposure index"), (SensingMethod, 0xa217, DefaultValue::None, d_sensingmethod, unit![], "Sensing method"), (FileSource, 0xa300, DefaultValue::Undefined(&[3]), d_filesrc, unit![], "File source"), (SceneType, 0xa301, DefaultValue::Undefined(&[1]), d_scenetype, unit![], "Scene type"), (CFAPattern, 0xa302, DefaultValue::None, d_default, unit![], "CFA pattern"), (CustomRendered, 0xa401, DefaultValue::Short(&[0]), d_customrendered, unit![], "Custom image processing"), (ExposureMode, 0xa402, DefaultValue::None, d_expmode, unit![], "Exposure mode"), (WhiteBalance, 0xa403, DefaultValue::None, d_whitebalance, unit![], "White balance"), (DigitalZoomRatio, 0xa404, DefaultValue::None, d_dzoomratio, unit![], "Digital zoom ratio"), (FocalLengthIn35mmFilm, 0xa405, DefaultValue::None, d_focallen35, unit!["mm"], "Focal length in 35 mm film"), (SceneCaptureType, 0xa406, DefaultValue::Short(&[0]), d_scenecaptype, unit![], "Scene capture type"), (GainControl, 0xa407, DefaultValue::None, d_gainctrl, unit![], "Gain control"), (Contrast, 0xa408, DefaultValue::Short(&[0]), d_contrast, unit![], "Contrast"), (Saturation, 0xa409, DefaultValue::Short(&[0]), d_saturation, unit![], "Saturation"), (Sharpness, 0xa40a, DefaultValue::Short(&[0]), d_sharpness, unit![], "Sharpness"), (DeviceSettingDescription, 0xa40b, DefaultValue::None, d_default, unit![], "Device settings description"), (SubjectDistanceRange, 0xa40c, DefaultValue::None, d_subjdistrange, unit![], "Subject distance range"), (ImageUniqueID, 0xa420, DefaultValue::None, d_default, unit![], "Unique image ID"), (CameraOwnerName, 0xa430, DefaultValue::None, d_default, unit![], "Camera owner name"), (BodySerialNumber, 0xa431, DefaultValue::None, d_default, unit![], "Body serial number"), (LensSpecification, 0xa432, DefaultValue::None, d_lensspec, unit![], "Lens specification"), (LensMake, 0xa433, DefaultValue::None, d_default, unit![], "Lens make"), (LensModel, 0xa434, DefaultValue::None, d_default, unit![], "Lens model"), (LensSerialNumber, 0xa435, DefaultValue::None, d_default, unit![], "Lens serial number"), (CompositeImage, 0xa460, DefaultValue::Short(&[0]), d_cpstimg, unit![], "Composite image"), (SourceImageNumberOfCompositeImage, 0xa461, DefaultValue::None, d_numcpstimg, unit![], "Source image number of composite image"), (SourceExposureTimesOfCompositeImage, 0xa462, DefaultValue::None, d_default, unit![], "Source exposure times of composite image"), (Gamma, 0xa500, DefaultValue::None, d_decimal, unit![], "Gamma"), // GPS attributes [EXIF23 4.6.6 Table 15 and 4.6.8 Table 19]. |Context::Gps| // Depends on the Exif version. (GPSVersionID, 0x0, DefaultValue::ContextDependent, d_gpsver, unit![], "GPS tag version"), (GPSLatitudeRef, 0x1, DefaultValue::None, d_gpslatlongref, unit![], "North or south latitude"), (GPSLatitude, 0x2, DefaultValue::None, d_gpsdms, unit![Tag::GPSLatitudeRef], "Latitude"), (GPSLongitudeRef, 0x3, DefaultValue::None, d_gpslatlongref, unit![], "East or West Longitude"), (GPSLongitude, 0x4, DefaultValue::None, d_gpsdms, unit![Tag::GPSLongitudeRef], "Longitude"), (GPSAltitudeRef, 0x5, DefaultValue::Byte(&[0]), d_gpsaltref, unit![], "Altitude reference"), (GPSAltitude, 0x6, DefaultValue::None, d_decimal, unit![V, " meters ", Tag::GPSAltitudeRef], "Altitude"), (GPSTimeStamp, 0x7, DefaultValue::None, d_gpstimestamp, unit![], "GPS time (atomic clock)"), (GPSSatellites, 0x8, DefaultValue::None, d_default, unit![], "GPS satellites used for measurement"), (GPSStatus, 0x9, DefaultValue::None, d_gpsstatus, unit![], "GPS receiver status"), (GPSMeasureMode, 0xa, DefaultValue::None, d_gpsmeasuremode, unit![], "GPS measurement mode"), (GPSDOP, 0xb, DefaultValue::None, d_decimal, unit![], "Measurement precision"), (GPSSpeedRef, 0xc, DefaultValue::Ascii(&[b"K"]), d_gpsspeedref, unit![], "Speed unit"), (GPSSpeed, 0xd, DefaultValue::None, d_decimal, unit![Tag::GPSSpeedRef], "Speed of GPS receiver"), (GPSTrackRef, 0xe, DefaultValue::Ascii(&[b"T"]), d_gpsdirref, unit![], "Reference for direction of movement"), (GPSTrack, 0xf, DefaultValue::None, d_decimal, unit![V, " degrees in ", Tag::GPSTrackRef], "Direction of movement"), (GPSImgDirectionRef, 0x10, DefaultValue::Ascii(&[b"T"]), d_gpsdirref, unit![], "Reference for direction of image"), (GPSImgDirection, 0x11, DefaultValue::None, d_decimal, unit![V, " degrees in ", Tag::GPSImgDirectionRef], "Direction of image"), (GPSMapDatum, 0x12, DefaultValue::None, d_default, unit![], "Geodetic survey data used"), (GPSDestLatitudeRef, 0x13, DefaultValue::None, d_gpslatlongref, unit![], "Reference for latitude of destination"), (GPSDestLatitude, 0x14, DefaultValue::None, d_gpsdms, unit![Tag::GPSDestLatitudeRef], "Latitude of destination"), (GPSDestLongitudeRef, 0x15, DefaultValue::None, d_gpslatlongref, unit![], "Reference for longitude of destination"), (GPSDestLongitude, 0x16, DefaultValue::None, d_gpsdms, unit![Tag::GPSDestLongitudeRef], "Longitude of destination"), (GPSDestBearingRef, 0x17, DefaultValue::Ascii(&[b"T"]), d_gpsdirref, unit![], "Reference for bearing of destination"), (GPSDestBearing, 0x18, DefaultValue::None, d_decimal, unit![V, " degrees in ", Tag::GPSDestBearingRef], "Bearing of destination"), (GPSDestDistanceRef, 0x19, DefaultValue::Ascii(&[b"K"]), d_gpsdistref, unit![], "Reference for distance to destination"), (GPSDestDistance, 0x1a, DefaultValue::None, d_decimal, unit![Tag::GPSDestDistanceRef], "Distance to destination"), (GPSProcessingMethod, 0x1b, DefaultValue::None, d_ascii_in_undef, unit![], "Name of GPS processing method"), (GPSAreaInformation, 0x1c, DefaultValue::None, d_default, unit![], "Name of GPS area"), (GPSDateStamp, 0x1d, DefaultValue::None, d_gpsdatestamp, unit![], "GPS date"), (GPSDifferential, 0x1e, DefaultValue::None, d_gpsdifferential, unit![], "GPS differential correction"), (GPSHPositioningError, 0x1f, DefaultValue::None, d_decimal, unit!["m"], "Horizontal positioning error"), // Interoperability attributes [EXIF23 4.6.7 Table 16 and 4.6.8 Table 20] // [DCF20 4.4.5.3, 4.5.4.3, and 4.6.4.3]. |Context::Interop| (InteroperabilityIndex, 0x1, DefaultValue::None, d_default, unit![], "Interoperability identification"), (InteroperabilityVersion, 0x2, DefaultValue::None, d_interopver, unit![], "Interoperability version"), (RelatedImageFileFormat, 0x1000, DefaultValue::None, d_default, unit![], "Related image file format"), (RelatedImageWidth, 0x1001, DefaultValue::None, d_default, unit!["pixels"], "Related image width"), (RelatedImageLength, 0x1002, DefaultValue::None, d_default, unit!["pixels"], "Related image height"), ); // For Value::display_as(). pub fn display_value_as<'a>(value: &'a Value, tag: Tag) -> value::Display<'a> { match get_tag_info(tag) { Some(ti) => value::Display { fmt: ti.dispval, value: value }, None => value::Display { fmt: d_default, value: value }, } } // Compression (TIFF 0x103) fn d_compression(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(1) => "uncompressed", Some(2) => "Modified Huffman", Some(6) => "JPEG", Some(32773) => "PackBits", _ => return d_reserved(w, value, "compression"), }; w.write_str(s) } // PhotometricInterpretation (TIFF 0x106) fn d_photointp(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "white is zero", Some(1) => "black is zero", Some(2) => "RGB", Some(3) => "palette color", Some(4) => "transparency mask", Some(6) => "YCbCr", _ => return d_reserved(w, value, "photometric interpretation"), }; w.write_str(s) } // Orientation (TIFF 0x112) fn d_orientation(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(1) => "row 0 at top and column 0 at left", Some(2) => "row 0 at top and column 0 at right", Some(3) => "row 0 at bottom and column 0 at right", Some(4) => "row 0 at bottom and column 0 at left", Some(5) => "row 0 at left and column 0 at top", Some(6) => "row 0 at right and column 0 at top", Some(7) => "row 0 at right and column 0 at bottom", Some(8) => "row 0 at left and column 0 at bottom", _ => return d_reserved(w, value, "orientation"), }; w.write_str(s) } // PlanarConfiguration (TIFF 0x11c) fn d_planarcfg(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(1) => "chunky", Some(2) => "planar", _ => return d_reserved(w, value, "planar configuration"), }; w.write_str(s) } // ResolutionUnit (TIFF 0x128) // FocalPlaneResolutionUnit (Exif 0xa210) fn d_resunit(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(1) => "no absolute unit", Some(2) => "inch", Some(3) => "cm", _ => return d_reserved(w, value, "resolution unit"), }; w.write_str(s) } // DateTime (TIFF 0x132), DateTimeOriginal (Exif 0x9003), and // DateTimeDigitized (Exif 0x9004) fn d_datetime(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { if let Some(dt) = value.ascii().and_then(|x| x.first()) { match crate::tiff::DateTime::from_ascii(dt) { Ok(dt) => return write!(w, "{}", dt), Err(Error::BlankValue(_)) => return w.write_str("unknown"), _ => {}, } } d_default(w, value) } // YCbCrSubSampling (TIFF 0x212) fn d_ycbcrsubsamp(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { // 0 is used to go to d_default in the match below. let horiz = value.get_uint(0).unwrap_or(0); let vert = value.get_uint(1).unwrap_or(0); let s = match (horiz, vert) { (1, 1) => "full horizontally, full vertically (4:4:4)", (2, 1) => "half horizontally, full vertically (4:2:2)", (2, 2) => "half horizontally, half vertically (4:2:0)", (4, 1) => "quarter horizontally, full vertically (4:1:1)", (4, 2) => "quarter horizontally, half vertically", (4, 4) => "quarter horizontally, quarter vertically", _ => return d_default(w, value), }; w.write_str(s) } // YCbCrPositioning (TIFF 0x213) fn d_ycbcrpos(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(1) => "centered", Some(2) => "co-sited", _ => return d_reserved(w, value, "YCbCr positioning"), }; w.write_str(s) } // ExposureTime (Exif 0x829a) fn d_exptime(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { if let Some(et) = value.rational().and_then(|x| x.first()) { if et.num >= et.denom { return write!(w, "{}", et.to_f64()); } else if et.num != 0 { return write!(w, "1/{}", et.denom as f64 / et.num as f64); } } d_default(w, value) } // ExposureProgram (Exif 0x8822) fn d_expprog(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "not defined", Some(1) => "manual", Some(2) => "normal program", Some(3) => "aperture priority", Some(4) => "shutter priority", Some(5) => "creative program", Some(6) => "action program", Some(7) => "portrait mode", Some(8) => "landscape mode", _ => return d_reserved(w, value, "exposure program"), }; w.write_str(s) } // SensitivityType (Exif 0x8830) fn d_sensitivitytype(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "unknown", Some(1) => "SOS", Some(2) => "REI", Some(3) => "ISO speed", Some(4) => "SOS/REI", Some(5) => "SOS/ISO speed", Some(6) => "REI/ISO speed", Some(7) => "SOS/REI/ISO speed", _ => return d_reserved(w, value, "sensitivity type"), }; w.write_str(s) } // ExifVersion (Exif 0x9000), FlashpixVersion (Exif 0xa000) fn d_exifver(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { if let Some(s) = value.undefined().filter(|s| s.len() == 4) { if let Ok(major) = atou16(&s[0..2]) { if let Ok(minor) = atou16(&s[2..4]) { if minor % 10 == 0 { return write!(w, "{}.{}", major, minor / 10); } else { return write!(w, "{}.{:02}", major, minor); } } } } d_default(w, value) } // ComponentsConfiguration (Exif 0x9101) fn d_cpntcfg(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match value.undefined() { Some(s) => s.iter().try_for_each(|x| match x { 0 => w.write_char('_'), 1 => w.write_char('Y'), 2 => w.write_str("Cb"), 3 => w.write_str("Cr"), 4 => w.write_char('R'), 5 => w.write_char('G'), 6 => w.write_char('B'), _ => w.write_char('?'), }), None => d_default(w, value), } } // SubjectDistance (Exif 0x9206) fn d_subjdist(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { if let Some(dist) = value.rational().and_then(|x| x.first()) { if dist.num == 0 { return w.write_str("unknown"); } else if dist.num == 0xffffffff { return w.write_str("infinity"); } } d_decimal(w, value) } // MeteringMode (Exif 0x9207) fn d_metering(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "unknown", Some(1) => "average", Some(2) => "center-weighted average", Some(3) => "spot", Some(4) => "multi-spot", Some(5) => "pattern", Some(6) => "partial", Some(255) => "other", _ => return d_reserved(w, value, "metering mode"), }; w.write_str(s) } // LightSource (Exif 0x9208) fn d_lightsrc(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "unknown", Some(1) => "daylight", Some(2) => "fluorescent", Some(3) => "tungsten", Some(4) => "flash", Some(9) => "fine weather", Some(10) => "cloudy weather", Some(11) => "shade", Some(12) => "daylight fluorescent (D 5700-7100K)", Some(13) => "day white fluorescent (N 4600-5500K)", Some(14) => "cool white fluorescent (W 3800-4500K)", Some(15) => "white fluorescent (WW 3250-3800K)", Some(16) => "warm white fluorescent (L 2600-3250K)", Some(17) => "standard light A", Some(18) => "standard light B", Some(19) => "standard light C", Some(20) => "D55", Some(21) => "D65", Some(22) => "D75", Some(23) => "D50", Some(24) => "ISO studio tungsten", Some(255) => "other", _ => return d_reserved(w, value, "light source"), }; w.write_str(s) } // Flash (Exif 0x9209) fn d_flash(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { const FIRED: &[&str] = &["not fired", "fired"]; const RETURN: &[&str] = &[ ", no return light detection function", ", return light status 1 (reserved)", ", return light not detected", ", return light detected", ]; const AUTO: &[&str] = &[ ", auto mode 0 (unknown)", ", forced", ", suppressed", ", auto"]; const FUNCTION: &[&str] = &["", ", no function present"]; const RED_EYE: &[&str] = &["", ", red-eye reduction"]; if let Some(v) = value.get_uint(0) { write!(w, "{}{}{}{}{}{}", FIRED[v as usize & 1], RETURN[v as usize >> 1 & 3], AUTO[v as usize >> 3 & 3], FUNCTION[v as usize >> 5 & 1], RED_EYE[v as usize >> 6 & 1], if v >> 7 != 0 { ", unknown MSB bits" } else { "" }) } else { d_default(w, value) } } // SubjectArea (Exif 0x9214), SubjectLocation (Exif 0xa214) // Only (x, y) case is valid for SubjectLocation. fn d_subjarea(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { if let Some(x) = value.get_uint(0) { if let Some(y) = value.get_uint(1) { if let Some(d) = value.get_uint(2) { if let Some(h) = value.get_uint(3) { return write!(w, "rectangle (x={}, y={}, w={}, h={})", x, y, d, h); } return write!(w, "circle (x={}, y={}, d={})", x, y, d); } return write!(w, "point (x={}, y={})", x, y); } } d_default(w, value) } // Rational/SRational with 0xffffffff being unknown. // BrightnessValue (Exif 0x9203), // Temperature (Exif 0x9400), Humidity (Exif 0x9401), // Pressure (Exif 0x9402), WaterDepth (Exif 0x9403), // Acceleration (Exif 0x9404), CameraElevationAngle (Exif 0x9405) fn d_optdecimal(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match *value { Value::Rational(ref v) if v.len() > 0 => if v[0].denom != 0xffffffff { write!(w, "{}", v[0].to_f64()) } else { w.write_str("unknown") }, Value::SRational(ref v) if v.len() > 0 => if v[0].denom != -1 { write!(w, "{}", v[0].to_f64()) } else { w.write_str("unknown") }, _ => d_decimal(w, value), } } // ColorSpace (Exif 0xa001) fn d_cspace(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(1) => "sRGB", Some(0xffff) => "uncalibrated", _ => return d_reserved(w, value, "color space"), }; w.write_str(s) } // SensingMethod (Exif 0xa217) fn d_sensingmethod(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(1) => "not defined", Some(2) => "one-chip color area sensor", Some(3) => "two-chip color area sensor", Some(4) => "three-chip color area sensor", Some(5) => "color sequential area sensor", Some(7) => "trilinear sensor", Some(8) => "color sequential linear sensor", _ => return d_reserved(w, value, "sensing method"), }; w.write_str(s) } // FileSource (Exif 0xa300) fn d_filesrc(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.undefined().and_then(|x| x.first().copied()) { Some(0) => "others", Some(1) => "transparency scanner", Some(2) => "reflective scanner", Some(3) => "digital still camera", _ => return d_reserved(w, value, "file source"), }; w.write_str(s) } // SceneType (Exif 0xa301) fn d_scenetype(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.undefined().and_then(|x| x.first().copied()) { Some(1) => "directly photographed image", _ => return d_reserved(w, value, "scene type"), }; w.write_str(s) } // CustomRendered (Exif 0xa401) fn d_customrendered(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "normal process", Some(1) => "custom process", _ => return d_reserved(w, value, "custom rendered"), }; w.write_str(s) } // ExposureMode (Exif 0xa402) fn d_expmode(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "auto exposure", Some(1) => "manual exposure", Some(2) => "auto bracket", _ => return d_reserved(w, value, "exposure mode"), }; w.write_str(s) } // WhiteBalance (Exif 0xa403) fn d_whitebalance(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "auto white balance", Some(1) => "manual white balance", _ => return d_reserved(w, value, "white balance mode"), }; w.write_str(s) } // DigitalZoomRatio (Exif 0xa404) fn d_dzoomratio(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { if value.rational().and_then(|x| x.first()).map(|x| x.num) == Some(0) { return w.write_str("unused"); } d_decimal(w, value) } // FocalLengthIn35mmFilm (Exif 0xa405) fn d_focallen35(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match value.get_uint(0) { Some(0) => w.write_str("unknown"), _ => d_default(w, value), } } // SceneCaptureType (Exif 0xa406) fn d_scenecaptype(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "standard", Some(1) => "landscape", Some(2) => "portrait", Some(3) => "night scene", _ => return d_reserved(w, value, "scene capture type"), }; w.write_str(s) } // GainControl (Exif 0xa407) fn d_gainctrl(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "none", Some(1) => "low gain up", Some(2) => "high gain up", Some(3) => "low gain down", Some(4) => "high gain down", _ => return d_reserved(w, value, "gain control"), }; w.write_str(s) } // Contrast (Exif 0xa408) fn d_contrast(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "normal", Some(1) => "soft", Some(2) => "hard", _ => return d_reserved(w, value, "contrast processing"), }; w.write_str(s) } // Saturation (Exif 0xa409) fn d_saturation(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "normal", Some(1) => "low saturation", Some(2) => "high saturation", _ => return d_reserved(w, value, "saturation processing"), }; w.write_str(s) } // Sharpness (Exif 0xa40a) fn d_sharpness(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "normal", Some(1) => "soft", Some(2) => "hard", _ => return d_reserved(w, value, "sharpness processing"), }; w.write_str(s) } // SubjectDistanceRange (Exif 0xa40c) fn d_subjdistrange(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "unknown", Some(1) => "macro", Some(2) => "close view", Some(3) => "distant view", _ => return d_reserved(w, value, "subject distance range"), }; w.write_str(s) } // LensSpecification (Exif 0xa432) fn d_lensspec(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match value.rational().and_then(|x| x.get(..4)) { // There are several notations: "F1.4" in Japan, "f/1.4" // in the U.S., and so on. Some(s) => write!(w, "{}-{} mm, f/{}-{}", s[0].to_f64(), s[1].to_f64(), s[2].to_f64(), s[3].to_f64()), _ => d_default(w, value), } } // CompositeImage (Exif 0xa460) fn d_cpstimg(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "unknown", Some(1) => "non-composite", Some(2) => "composite (general)", Some(3) => "composite (at the moment of shooting)", _ => return d_reserved(w, value, "composite image"), }; w.write_str(s) } // SourceImageNumberOfCompositeImage (Exif 0xa461) fn d_numcpstimg(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match (value.get_uint(0), value.get_uint(1)) { (Some(t), Some(u)) => write!(w, "total {}, used {}", t, u), _ => d_default(w, value), } } // GPSVersionID (GPS 0x0) fn d_gpsver(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match value.byte().and_then(|x| x.get(..4)) { Some(s) => write!(w, "{}.{}.{}.{}", s[0], s[1], s[2], s[3]), _ => d_default(w, value), } } // GPSLatitudeRef (GPS 0x1), GPSLongitudeRef (GPS 0x3) // GPSDestLatitudeRef (GPS 0x13), GPSDestLongitudeRef (GPS 0x15) fn d_gpslatlongref(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match value.ascii().and_then(|x| x.first()) { Some([c]) if c.is_ascii_uppercase() => w.write_char(*c as char), _ => d_default(w, value), } } // GPSLatitude (GPS 0x2), GPSLongitude (GPS 0x4), // GPSDestLatitude (GPS 0x14), GPSDestLongitude (GPS 0x16) fn d_gpsdms(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match value.rational().and_then(|x| x.get(..3)) { Some(s) => write!(w, "{} deg {} min {} sec", s[0].to_f64(), s[1].to_f64(), s[2].to_f64()), _ => d_default(w, value), } } // GPSAltitudeRef (GPS 0x5) fn d_gpsaltref(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "above sea level", Some(1) => "below sea level", _ => return d_reserved(w, value, "GPS altitude ref"), }; w.write_str(s) } // GPSTimeStamp (GPS 0x7) fn d_gpstimestamp(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match value.rational().and_then(|x| x.get(..3)) { Some(s) => { let (h, m, s) = (s[0].to_f64(), s[1].to_f64(), s[2].to_f64()); write!(w, "{}{}:{}{}:{}{}", if h < 10.0 { "0" } else { "" }, h, if m < 10.0 { "0" } else { "" }, m, if s < 10.0 { "0" } else { "" }, s) }, _ => d_default(w, value), } } // GPSStatus (GPS 0x9) fn d_gpsstatus(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.ascii().and_then(|x| x.first()) { Some(b"A") => "measurement in progress", Some(b"V") => "measurement interrupted", _ => return d_reserved(w, value, "GPS status"), }; w.write_str(s) } // GPSMeasureMode (GPS 0xa) fn d_gpsmeasuremode(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.ascii().and_then(|x| x.first()) { Some(b"2") => "2-dimensional measurement", Some(b"3") => "3-dimensional measurement", _ => return d_reserved(w, value, "GPS measurement mode"), }; w.write_str(s) } // GPSSpeedRef (GPS 0xc) fn d_gpsspeedref(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.ascii().and_then(|x| x.first()) { Some(b"K") => "km/h", Some(b"M") => "mph", Some(b"N") => "knots", _ => return d_reserved(w, value, "GPS speed ref"), }; w.write_str(s) } // GPSTrackRef (GPS 0xe), GPSImgDirectionRef (GPS 0x10), // GPSDestBearingRef (GPS 0x17) fn d_gpsdirref(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.ascii().and_then(|x| x.first()) { Some(b"T") => "true direction", Some(b"M") => "magnetic direction", _ => return d_reserved(w, value, "GPS direction ref"), }; w.write_str(s) } // GPSDestDistanceRef (GPS 0x19) fn d_gpsdistref(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.ascii().and_then(|x| x.first()) { Some(b"K") => "km", Some(b"M") => "miles", Some(b"N") => "nautical miles", _ => return d_reserved(w, value, "GPS distance ref"), }; w.write_str(s) } // GPSDateStamp (GPS 0x1d) fn d_gpsdatestamp(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { if let Some(data) = value.ascii().and_then(|x| x.first()) { if data.len() >= 10 && data[4] == b':' && data[7] == b':' { if let Ok(year) = atou16(&data[0..4]) { if let Ok(month) = atou16(&data[5..7]) { if let Ok(day) = atou16(&data[8..10]) { return write!(w, "{:04}-{:02}-{:02}", year, month, day); } } } } } d_default(w, value) } // GPSDifferential (GPS 0x1e) fn d_gpsdifferential(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { let s = match value.get_uint(0) { Some(0) => "no differential correction", Some(1) => "differential correction applied", _ => return d_reserved(w, value, "GPS differential correction"), }; w.write_str(s) } // InteroperabilityVersion (Interoperability 0x2) fn d_interopver(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { if let Some(s) = value.undefined().filter(|s| s.len() == 4) { if let Ok(major) = atou16(&s[0..2]) { if let Ok(minor) = atou16(&s[2..4]) { return write!(w, "{}.{:02}", major, minor); } } } d_default(w, value) } fn d_ascii_in_undef(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match *value { Value::Undefined(ref v, _) => d_sub_ascii(w, v), _ => d_default(w, value), } } fn d_decimal(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match *value { Value::Rational(ref v) => d_sub_comma(w, v.iter().map(|x| x.to_f64())), Value::SRational(ref v) => d_sub_comma(w, v.iter().map(|x| x.to_f64())), _ => d_default(w, value), } } #[inline(never)] fn d_reserved(w: &mut dyn fmt::Write, value: &Value, name: &str) -> fmt::Result { write!(w, "[reserved {} ", name)?; d_default(w, value)?; w.write_char(']') } fn d_default(w: &mut dyn fmt::Write, value: &Value) -> fmt::Result { match *value { Value::Byte(ref v) => d_sub_comma(w, v), Value::Ascii(ref v) => d_sub_comma(w, v.iter().map(|x| AsciiDisplay(x))), Value::Short(ref v) => d_sub_comma(w, v), Value::Long(ref v) => d_sub_comma(w, v), Value::Rational(ref v) => d_sub_comma(w, v), Value::SByte(ref v) => d_sub_comma(w, v), Value::Undefined(ref v, _) => d_sub_hex(w, v), Value::SShort(ref v) => d_sub_comma(w, v), Value::SLong(ref v) => d_sub_comma(w, v), Value::SRational(ref v) => d_sub_comma(w, v), Value::Float(ref v) => d_sub_comma(w, v), Value::Double(ref v) => d_sub_comma(w, v), Value::Unknown(t, c, o) => write!(w, "unknown value (type={}, count={}, offset={:#x})", t, c, o), } } fn d_sub_comma(w: &mut dyn fmt::Write, itit: I) -> fmt::Result where I: IntoIterator, T: fmt::Display { let mut first = true; for x in itit { match first { true => write!(w, "{}", x), false => write!(w, ", {}", x), }?; first = false; } Ok(()) } struct AsciiDisplay<'a>(&'a [u8]); impl<'a> fmt::Display for AsciiDisplay<'a> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { d_sub_ascii(f, self.0) } } fn d_sub_hex(w: &mut dyn fmt::Write, bytes: &[u8]) -> fmt::Result { w.write_str("0x")?; for x in bytes { write!(w, "{:02x}", x)?; } Ok(()) } fn d_sub_ascii(w: &mut dyn fmt::Write, bytes: &[u8]) -> fmt::Result { w.write_char('"')?; for &c in bytes { match c { b'\\' | b'"' => { w.write_char('\\')?; w.write_char(c as char)?; }, 0x20..=0x7e => w.write_char(c as char)?, _ => write!(w, "\\x{:02x}", c)?, } } w.write_char('"') } #[cfg(test)] mod tests { use value::Rational; use super::*; // This test checks if Tag constants can be used in patterns. #[test] fn tag_constant_in_pattern() { // Destructuring, which will always work. match Tag(Context::Tiff, 0x132) { Tag(Context::Tiff, 0x132) => {}, _ => panic!("failed to match Tag"), } // Matching against a constant. Test if this compiles. match Tag(Context::Tiff, 0x132) { Tag::DateTime => {}, _ => panic!("failed to match Tag"), } } #[test] fn default_value() { assert_pat!(Tag::DateTime.default_value(), None); match Tag::BitsPerSample.default_value() { Some(Value::Short(v)) => assert_eq!(v, &[8, 8, 8]), _ => panic!(), } match Tag::XResolution.default_value() { Some(Value::Rational(v)) => { assert_eq!(v.len(), 1); assert_eq!(v[0].num, 72); assert_eq!(v[0].denom, 1); }, _ => panic!(), } match Tag::FileSource.default_value() { Some(Value::Undefined(v, _)) => assert_eq!(v, &[3]), _ => panic!(), } match Tag::GPSAltitudeRef.default_value() { Some(Value::Byte(v)) => assert_eq!(v, &[0]), _ => panic!(), } match Tag::GPSSpeedRef.default_value() { Some(Value::Ascii(v)) => assert_eq!(v, &[b"K"]), _ => panic!(), } } #[test] fn tag_fmt_display() { let tag1 = Tag(Context::Tiff, 0x132); assert_eq!(format!("{:15}", tag1), "DateTime "); assert_eq!(format!("{:>15}", tag1), " DateTime"); assert_eq!(format!("{:5.6}", tag1), "DateTi"); let tag2 = Tag(Context::Exif, 0); assert_eq!(format!("{:15}", tag2), "Tag(Exif, 0) "); assert_eq!(format!("{:>15}", tag2), " Tag(Exif, 0)"); assert_eq!(format!("{:5.6}", tag2), "Tag(Ex"); } #[test] fn disp_val_sub() { let mut buf = String::new(); d_sub_comma(&mut buf, &[0u16, 1, 2]).unwrap(); assert_eq!(buf, "0, 1, 2"); let mut buf = String::new(); d_sub_comma(&mut buf, &[Rational::from((3, 5))]).unwrap(); assert_eq!(buf, "3/5"); let mut buf = String::new(); let list = &[Rational::from((1, 2))]; d_sub_comma(&mut buf, list.iter().map(|x| x.to_f64())).unwrap(); assert_eq!(buf, "0.5"); let mut buf = String::new(); d_sub_hex(&mut buf, b"abc\x00\xff").unwrap(); assert_eq!(buf, "0x61626300ff"); let mut buf = String::new(); d_sub_ascii(&mut buf, b"a \"\\b\"\n").unwrap(); assert_eq!(buf, r#""a \"\\b\"\x0a""#); } }