readTIFF {tiff}R Documentation

Read a bitmap image stored in the TIFF format

Description

Reads an image from a TIFF file/content into a raster array.

Usage

readTIFF(source, native = FALSE, all = FALSE, convert = FALSE,
         info = FALSE, indexed = FALSE, as.is = FALSE)

Arguments

source

Either name of the file to read from or a raw vector representing the TIFF file content.

native

determines the image representation - if FALSE (the default) then the result is an array, if TRUE then the result is a native raster representation (suitable for plotting).

all

TIFF files can contain more than one image, if all = TRUE then all images are returenin a list, otherwsie only the first image is returned.

convert

first convert the image into 8-bit RGBA samples and then to an array, see below for details.

info

if set to TRUE then the resulting image(s) will also contain information from TIFF tags as attributes

indexed

if set to TRUE then indexed images will be returned in the indexed form, i.e., as a matrix of integer indices referencing into a color map which is returned in the "color.map" attribute. This flag cannot be combined with convert or native and has no effect on images that are not indexed.

as.is

attempt to return original values without re-scaling where possible

Details

Most common files decompress into RGB (3 channels), RGBA (4 channels), Grayscale (1 channel) or GA (2 channels). Note that G and GA images cannot be directly used in rasterImage unless native is set to TRUE because rasterImage requires RGB or RGBA format (nativeRaster is always 8-bit RGBA).

TIFF images can have a wide range of internal representations, but only the most common in image processing are directly supported (8-bit, 16-bit integer and 32-bit float samples). Other formats (color maps, sub-8-bit images, etc.) are only supported via convert=TRUE which uses the built-in facilities of the TIFF library to convert the image into RGBA format with 8-bit samples (i.e. total of 32-bit per pixel) and then store the relevant components from there into real arrays. This is the same path as used by native=TRUE and so differs only in the output value. Note that conversion may result in different values than direct acccess as it is intended mainly for viewing and not computation.

Value

If native is FALSE then an array of the dimensions height x width x channels. If there is only one channel the result is a matrix. The values are reals between 0 and 1 (except for 32-bit floating point sample storage which are unscaled reals, and for indexed and as.is=TRUE which are integers). If native is TRUE then an object of the class nativeRaster is returned instead. The latter cannot be easily computed on but is the most efficient way to draw using rasterImage.

If all is TRUE then the result is a list of the above with one or more elements..

Note

Some non-standard formats such as 12-bit TIFFs are partially supported (there is no standard for packing order for TIFFs beoynd 8-bit so we assume big-endian packing similar to the default fill order and only support single channel or indexed).

The as.is=TRUE option is experimental, cannot be used with native or convert and only works for integer storage TIFFs.

See Also

rasterImage, writeTIFF

Examples

# read a sample file (R logo)
img <- readTIFF(system.file("img", "Rlogo.tiff", package="tiff"))

# read it also in native format
img.n <- readTIFF(system.file("img", "Rlogo.tiff", package="tiff"), native=TRUE)

# and also in converted
img.c <- readTIFF(system.file("img", "Rlogo.tiff", package="tiff"), convert=TRUE)

# if your R supports it, we'll plot it
if (exists("rasterImage")) { # can plot only in R 2.11.0 and higher
  plot(1:2, type='n')

  if (names(dev.cur()) == "windows") {
    # windows device doesn't support semi-transparency so we'll need
    # to flatten the image
    transparent <- img[,,4] == 0
    img <- as.raster(img[,,1:3])
    img[transparent] <- NA

    # interpolate must be FALSE on Windows, otherwise R will
    # try to interpolate transparency and fail
    rasterImage(img, 1.2, 1.27, 1.8, 1.73, interpolate=FALSE)

  } else {
    # any reasonable device will be fine using alpha
    rasterImage(img, 1.2, 1.27, 1.8, 1.73)
    rasterImage(img.n, 1.5, 1.5, 1.9, 1.8)
  }
}

[Package tiff version 0.1-5 Index]