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@ -17,9 +17,9 @@ Conventional conversion software (like ImageMagick) would either:
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2. not be small because using wasteful flate encoding of raw pixel data
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3. not be fast because input data gets re-encoded
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Another advantage of not having to re-encode the input in most common
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situations is, that img2pdf is able to handle much larger input than other
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software.
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Another advantage of not having to re-encode the input (in most common
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situations) is, that img2pdf is able to handle much larger input than other
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software, because the raw pixel data never has to be loaded into memory.
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The following table shows how img2pdf handles different input depending on the
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input file format and image color space.
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@ -56,34 +56,35 @@ descriptor.
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If no output file is specified with the `-o`/`--output` option, output will be
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done to stdout. A typical invocation is:
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img2pdf img1.png img2.jpg -o out.pdf
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$ img2pdf img1.png img2.jpg -o out.pdf
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The detailed documentation can be accessed by running:
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img2pdf --help
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$ img2pdf --help
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Bugs
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----
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If you find a JPEG, JPEG2000 or PNG file that, when embedded into the PDF
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cannot be read by the Adobe Acrobat Reader, please contact me.
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- If you find a JPEG, JPEG2000, PNG or CCITT Group 4 encoded TIFF file that,
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when embedded into the PDF cannot be read by the Adobe Acrobat Reader,
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please contact me.
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I have not yet figured out how to determine the colorspace of JPEG2000 files.
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Therefore JPEG2000 files use DeviceRGB by default. For JPEG2000 files with
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other colorspaces, you must explicitly specify it using the `--colorspace`
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option.
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- I have not yet figured out how to determine the colorspace of JPEG2000
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files. Therefore JPEG2000 files use DeviceRGB by default. For JPEG2000
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files with other colorspaces, you must explicitly specify it using the
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`--colorspace` option.
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Input images with alpha channels are not allowed. PDF doesn't support alpha
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channels in images and thus, the alpha channel of the input would have to be
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discarded. But img2pdf will always be lossless and thus, input images must not
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carry transparency information.
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- Input images with alpha channels are not allowed. PDF doesn't support alpha
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channels in images and thus, the alpha channel of the input would have to be
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discarded. But img2pdf will always be lossless and thus, input images must
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not carry transparency information.
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img2pdf uses PIL (or Pillow) to obtain image meta data and to convert the input
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if necessary. To prevent decompression bomb denial of service attacks, Pillow
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limits the maximum number of pixels an input image is allowed to have. If you
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are sure that you know what you are doing, then you can disable this safeguard
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by passing the `--pillow-limit-break` option to img2pdf. This allows one to
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process even very large input images.
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- img2pdf uses PIL (or Pillow) to obtain image meta data and to convert the
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input if necessary. To prevent decompression bomb denial of service attacks,
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Pillow limits the maximum number of pixels an input image is allowed to
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have. If you are sure that you know what you are doing, then you can disable
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this safeguard by passing the `--pillow-limit-break` option to img2pdf. This
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allows one to process even very large input images.
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Installation
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------------
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@ -146,3 +147,72 @@ The package can also be used as a library:
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layout_fun = img2pdf.get_layout_fun(a4inpt)
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with open("name.pdf","wb") as f:
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f.write(img2pdf.convert('test.jpg', layout_fun=layout_fun))
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Comparison to ImageMagick
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-------------------------
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Create a large test image:
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$ convert logo: -resize 8000x original.jpg
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Convert it into PDF using ImageMagick and img2pdf:
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$ time img2pdf original.jpg -o img2pdf.pdf
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$ time convert original.jpg imagemagick.pdf
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Notice how ImageMagick took an order of magnitude longer to do the conversion
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than img2pdf. It also used twice the memory.
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Now extract the image data from both PDF documents and compare it to the
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original:
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$ pdfimages -all img2pdf.pdf tmp
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$ compare -metric AE original.jpg tmp-000.jpg null:
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0
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$ pdfimages -all imagemagick.pdf tmp
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$ compare -metric AE original.jpg tmp-000.jpg null:
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118716
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To get lossless output with ImageMagick we can use Zip compression but that
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unnecessarily increases the size of the output:
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$ convert original.jpg -compress Zip imagemagick.pdf
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$ pdfimages -all imagemagick.pdf tmp
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$ compare -metric AE original.jpg tmp-000.png null:
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0
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$ stat --format="%s %n" original.jpg img2pdf.pdf imagemagick.pdf
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1535837 original.jpg
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1536683 img2pdf.pdf
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9397809 imagemagick.pdf
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Comparison to pdfLaTeX
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----------------------
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pdfLaTeX performs a lossless conversion from included images to PDF by default.
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If the input is a JPEG, then it simply embeds the JPEG into the PDF in the same
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way as img2pdf does it. But for other image formats it uses flate compression
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of the plain pixel data and thus needlessly increases the output file size:
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$ convert logo: -resize 8000x original.png
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$ cat << END > pdflatex.tex
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\documentclass{article}
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\usepackage{graphicx}
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\begin{document}
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\includegraphics{original.png}
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\end{document}
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END
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$ pdflatex pdflatex.tex
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$ stat --format="%s %n" original.png pdflatex.pdf
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4500182 original.png
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9318120 pdflatex.pdf
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Comparison to Tesseract OCR
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---------------------------
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Tesseract OCR comes closest to the functionality img2pdf provides. It is able
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to convert JPEG and PNG input to PDF without needlessly increasing the filesize
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and is at the same time lossless. So if your input is JPEG and PNG images, then
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you should safely be able to use Tesseract instead of img2pdf. For other input,
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Tesseract might not do a lossless conversion. For example it converts CMYK
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input to RGB and removes the alpha channel from images with transparency. For
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multipage TIFF or animated GIF, it will only convert the first frame.
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