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1 [[!meta title="Optimizing XSane's scanned PDFs (also: PDF internals)"]]
2 [[!meta author="rohieb"]]
3 [[!meta license="CC-BY-SA 3.0"]]
4 [[!img defaults size=x200]]
5
6 [[!toc levels=2]]
7
8 Problem
9 -------
10
11 I use [XSane][xsane] to scan documents for my digital archive. I want them to be
12 in PDF format and have a reasonable resolution (better than 200 dpi, so I
13 can try OCRing them afterwards). However, the PDFs created by XSane’s multipage
14 mode are too large, about 250 MB for a 20-page document scanned at
15 200 dpi.
16
17 [xsane]: http://www.xsane.org/ "XSane homepage"
18
19 [[!img xsane-multipage-mode.png caption="XSane’s Multipage mode"]]
20
21
22 First (non-optimal) solution
23 --------------
24
25 At first, I tried to optimize the PDF using [GhostScript][gs]. I
26 [[already wrote|use-ghostscript-to-convert-pdf-files]] about how GhostScript’s
27 `-dPDFSETTINGS` option can be used to minimize PDFs by redering the pictures to
28 a smaller resolution. In fact, there are [multiple rendering modes][gs-ps-pdf]
29 (`screen` for 96 dpi, `ebook` for 150 dpi, `printer` for 300 dpi,
30 and `prepress` for color-preserving 300 dpi), but they are pre-defined, and
31 for my 200 dpi images, `ebook` was not enough (I would lose resolution),
32 while `printer` was too high and would only enlarge the PDF.
33
34 [gs]: http://ghostscript.com "Ghostscript homepage"
35 [gs-ps-pdf]: http://milan.kupcevic.net/ghostscript-ps-pdf/#refs "Ghostscript PDF Reference & Tips"
36
37
38 Interlude: PDF Internals
39 ------------------
40
41 The best thing to do was to find out how the images were embedded in the PDF.
42 Since most PDF files are also partly human-readable, I opened my file with vim.
43 (Also, I was surprised that [vim has syntax highlighting for
44 PDF](vim-syntax-highlighting.png).) Before we continue, I'll give a short
45 introduction to the PDF file format (for the long version, see [Adobe’s PDF
46 reference][pdf-ref]).
47
48 [pdf-ref]: http://partners.adobe.com/public/developer/en/pdf/PDFReference.pdf "Adobe Portable Document Format, Version 1.4"
49
50 ### Building Blocks ###
51 Every PDF file starts with the [magic string][magic] that identifies the version
52 of the standard which the document conforms to, like `%PDF-1.4`. After that, a
53 PDF document is made up of the following objects:
54
55 [magic]: https://en.wikipedia.org/wiki/Magic_number_(programming)#Magic_numbers_in_files "Wikipedia: Magic numbers in files"
56
57 Boolean values
58 : `true` and `false`
59
60 Integers and floating-point numbers
61 : for example, `1337`, `-23.42` and `.1415`
62
63 Strings
64 : * interpreted as literal characters when enclosed in parentheses: `(This
65 is a string.)` These can contain escaped characters, particularly
66 escaped closing braces and control characters: `(This string contains a
67 literal \) and some\n newlines.\n)`.
68 * interpreted as hexadecimal data when enclosed in angled brackets:
69 `<53 61 6D 70 6C 65>` equals `(Sample)`.
70
71 Names
72 : starting with a forward slash, like `/Type`. You can think of them like
73 identifiers in programming languages.
74
75 Arrays
76 : enclosed in square brackets:
77 `[ -1 4 6 (A String) /AName [ (strings in arrays in arrays!) ] ]`
78
79 Dictionaries
80 : key-value stores, which are enclosed in double angled brackets. The key must
81 be a name, the value can be any object. Keys and values are given in turns,
82 beginning with the first key:
83 `<< /FirstKey (First Value) /SecondKey 3.14 /ThirdKey /ANameAsValue >>`
84 Usually, the first key is `/Type` and defines what the dictionary actually
85 describes.
86
87 Stream Objects
88
89 : a collection of bytes. In contrast to strings, stream objects are usually
90 used for large amount of data which may not be read entirely, while strings
91 are always read as a whole. For example, streams can be used to embed images
92 or metadata.
93
94 : Streams consist of a dictionary, followed by the keyword `stream`, the raw
95 content of the stream, and the keyword `endstream`. The dictionary describes
96 the stream’s length and the filters that have been applied to it, which
97 basically define the encoding the data is stored in. For example, data
98 streams can be compressed with various algorithms.
99
100 The Null Object
101 : Represented by the literal string `null`.
102
103 Indirect Objects
104
105 : Every object in a PDF document can also be stored as a indirect object,
106 which means that it is given a label and can be used multiple times in the
107 document. The label consists of two numbers, a positive *object number*
108 (which makes the object unique) and a non-negative *generation number*
109 (which allows to incrementally update objects by appending to the file).
110
111 : Indirect objects are defined by their object number, followed by their
112 generation number, the keyword `obj`, the contents of the object, and the
113 keyword `endobj`. Example: `1 0 obj (I'm an object!) endobj` defines the
114 indirect object with object number 1 and generation number 0, which consists
115 only of the string “I'm an object!”. Likewise, more complex data structures
116 can be labeled with indirect objects.
117
118 : Referencing an indirect object works by giving the object and generation
119 number, followed by an uppercase R: `1 0 R` references the object created
120 above. References can be used everywhere where a (direct) object could be
121 used instead.
122
123 Using these object, a PDF document builds up a tree structure, starting from the
124 root object, which has the object number 1 and is a dictionary with the value
125 `/Catalog` assigned to the key `/Type`. The other values of this dictionary
126 point to the objects describing the outlines and pages of the document, which in
127 turn reference other objects describing single pages, which point to objects
128 describing drawing operations or text blocks, etc.
129
130
131 ### Dissecting the PDFs created by XSane ###
132
133 Now that we know how a PDF document looks like, we can go back to out initial
134 problem and try to find out why my PDF file was so huge. I will walk you through
135 the PDF object by object.
136
137 [[!format pdf <<EOF
138 %PDF-1.4
139
140 1 0 obj
141 << /Type /Catalog
142 /Outlines 2 0 R
143 /Pages 3 0 R
144 >>
145 endobj
146 EOF]]
147
148 This is just the magic string declaring the document as PDF-1.4, and the root
149 object with object number 1, which references objects number 2 for Outlines and
150 number 3 for Pages. We're not interested in outlines, let's look at the pages.
151
152 [[!format pdf <<EOF
153 3 0 obj
154 << /Type /Pages
155 /Kids [
156 6 0 R
157 8 0 R
158 10 0 R
159 12 0 R
160 ]
161 /Count 4
162 >>
163 endobj
164 EOF]]
165
166 OK, apparently this document has four pages, which are referenced by objects
167 number 6, 8, 10 and 12. This makes sense, since I scanned four pages ;-)
168
169 Let's start with object number 6:
170
171 [[!format pdf <<EOF
172 6 0 obj
173 << /Type /Page
174 /Parent 3 0 R
175 /MediaBox [0 0 596 842]
176 /Contents 7 0 R
177 /Resources << /ProcSet 8 0 R >>
178 >>
179 endobj
180 EOF]]
181
182 We see that object number 6 is a page object, and the actual content is in
183 object number 7. More redirection, yay!
184
185 [[!format pdf <<EOF
186 7 0 obj
187 << /Length 2678332 >>
188 stream
189 q
190 1 0 0 1 0 0 cm
191 1.000000 0.000000 -0.000000 1.000000 0 0 cm
192 595.080017 0 0 841.679993 0 0 cm
193 BI
194 /W 1653
195 /H 2338
196 /CS /G
197 /BPC 8
198 /F /FlateDecode
199 ID
200 x$¼[$;¾åù!fú¥¡aæátq.4§ [ ...byte stream shortened... ]
201 EI
202 Q
203 endstream
204 endobj
205 EOF]]
206
207 Aha, here is where the magic happens. Object number 7 is a stream object of
208 2,678,332 bytes (about 2 MB) and contains drawing operations! After skipping
209 around a bit in Adobe’s PDF reference (chapters 3 and 4), here is the annotated
210 version of the stream content:
211
212 [[!format pdf <<EOF
213 q % Save drawing context
214 1 0 0 1 0 0 cm % Set up coordinate space for image
215 1.000000 0.000000 -0.000000 1.000000 0 0 cm
216 595.080017 0 0 841.679993 0 0 cm
217 BI % Begin Image
218 /W 1653 % Image width is 1653 pixel
219 /H 2338 % Image height is 2338 pixel
220 /CS /G % Color space is Gray
221 /BPC 8 % 8 bits per pixel
222 /F /FlateDecode % Filters: data is Deflate-compressed
223 ID % Image Data follows:
224 x$¼[$;¾åù!fú¥¡aæátq.4§ [ ...byte stream shortened... ]
225 EI % End Image
226 Q % Restore drawing context
227 EOF]]
228
229 So now we know why the PDF was so huge: the line `/F /FlateDecode` tells us that
230 the image data is stored losslessly with [Deflate][] compression (this is
231 basically what PNG uses). However, scanned images, as well as photographed
232 pictures, have the tendency to become very big when stored losslessly, due to te
233 fact that image sensors always add noise from the universe and lossless
234 compression also has to take account of this noise. In contrast, lossy
235 compression like JPEG, which uses [discrete cosine transform][dct], only has to
236 approximate the image (and therefore the noise from the sensor) to a certain
237 degree, therefore reducing the space needed to save the image. And the PDF
238 standard also allows image data to be DCT-compressed, by adding `/DCTDecode` to
239 the filters.
240
241 [Deflate]: https://en.wikipedia.org/wiki/DEFLATE "Wikipedia: DEFLATE algorithm"
242 [dct]: http://en.wikipedia.org/wiki/Discrete_cosine_transform "Wikipedia: Discrete cosine transform"
243
244
245 Second solution: use a (better) compression algorithm
246 ------------------
247
248 Now that I knew where the problem was, I could try to create PDFs with DCT
249 compression. I still had the original, uncompressed [PNM][] files that fell out
250 of XSane’ multipage mode (just look in the multipage project folder), so I
251 started to play around a bit with [ImageMagick’s][im] `convert` tool, which can
252 also convert images to PDF.
253
254 [im]: http://www.imagemagick.org "ImageMagic homepage"
255 [PNM]: https://en.wikipedia.org/wiki/Netpbm_format "Wikipedia: Netpbm format"
256
257 ### Converting PNM to PDF ###
258 First, I tried converting the umcompressed PNM to PDF:
259
260 $ convert image*.pnm document.pdf
261
262 `convert` generally takes parameters of the form `inputfile outputfile`, but it
263 also allows us to specify more than one input file (which is somehow
264 undocumented in the [man page][man-convert]). In that case it tries to create
265 multi-page documents, if possible. With PDF as output format, this results in
266 one input file per page.
267
268 [man-convert]: http://manpages.debian.net/cgi-bin/man.cgi?query=convert "man convert(1)"
269
270 The embedded image objects looked somewhat like the following:
271
272 [[!format pdf <<EOF
273 8 0 obj
274 <<
275 /Type /XObject
276 /Subtype /Image
277 /Name /Im0
278 /Filter [ /RunLengthDecode ]
279 /Width 1653
280 /Height 2338
281 /ColorSpace 10 0 R
282 /BitsPerComponent 8
283 /Length 9 0 R
284 >>
285 stream
286 % [ raw byte data ]
287 endstream
288 EOF]]
289
290 The filter `/RunLengthDecode` indicates that the stream data is compressed with
291 [Run-length encoding][RLE], another simple lossless compression. Not what I
292 wanted. (Apart from that, `convert` embeds images as XObjects, but there is not
293 much difference to the inline images described above.)
294
295 [RLE]: https://en.wikipedia.org/wiki/Run-length_encoding "Wikipedia: Run-length encoding"
296
297 ### Converting PNM to JPG, then to PDF ###
298
299 Next, I converted the PNMs to JPG, then to PDF.
300
301 $ convert image*.pnm image.jpg
302 $ convert image*jpg document.pdf
303
304 (The first command creates the output files `image-1.jpg`, `image-2.jpg`, etc.,
305 since JPG does not support multiple pages in one file.)
306
307 When looking at the PDF, we see that we now have DCT-compressed images inside
308 the PDF:
309
310 [[!format pdf <<EOF
311 8 0 obj
312 <<
313 /Type /XObject
314 /Subtype /Image
315 /Name /Im0
316 /Filter [ /DCTDecode ]
317 /Width 1653
318 /Height 2338
319 /ColorSpace 10 0 R
320 /BitsPerComponent 8
321 /Length 9 0 R
322 >>
323 stream
324 % [ raw byte data ]
325 endstream
326 EOF]]
327
328 ### Converting PNM to JPG, then to PDF, and fix page size ###
329
330 However, the pages in `document.pdf` are 82.47×58.31&nbsp;cm, which results in
331 about 72&nbsp;dpi in respect to the size of the original images. But `convert`
332 also allows us to specify the pixel density, so we'll set that to 200&nbsp;dpi
333 in X and Y direction, which was the resolution at which the images were scanned:
334
335 $ convert image*jpg -density 200x200 document.pdf
336
337 *Update:* You can also use the [`-page` parameter][page] to set the page size
338 directly. It takes a multitude of predefined paper formats (see link) and will
339 do the pixel density calculation for you, as well as adding any neccessary
340 offset if the image ratio is not quite exact:
341
342 $ convert image*jpg -page A4 document.pdf
343
344 With that approach, I could reduce the size of my PDF from 250&nbsp;MB with
345 losslessly compressed images to 38&nbsp;MB with DCT compression.
346
347 Too long, didn’t read
348 -----------------
349
350 Here’s the gist for you:
351
352 * Read the article above, it’s very comprehensive :P
353 * Use `convert` on XSane’s multipage images and specify your
354 scanning resolution:
355
356 $ convert image*.pnm image.jpg
357 $ convert image*jpg -density 200x200 document.pdf
358
359
360 Further reading
361 -------------
362
363 There is probably software out there which does those thing for you, with a
364 shiny user interface, but I could not find one quickly. What I did find though,
365 was [this detailed article][scan-to-pdfa], which describes how to get
366 high-resolution scans wihh OCR information in PDF/A and DjVu format, using
367 `scantailor` and `unpaper`.
368
369 Also, Didier Stevens helped me understand stream objects in in his
370 [illustrated blogpost][pdf-stream-objects]. He seems to write about PDF more
371 often, and it was fun to poke around in his blog. There is also a nice script,
372 [`pdf-parser`][pdf-tools], which helps you visualize the structure of a PDF
373 document.
374
375 [scan-to-pdfa]: http://blog.konradvoelkel.de/2013/03/scan-to-pdfa/ "Konrad Voelkel: Linux, OCR and PDF: Scan to PDF/A"
376 [pdf-stream-objects]: http://blog.didierstevens.com/2008/05/19/pdf-stream-objects/ "Didier Stevens: PDF Stream Objects"
377 [pdf-tools]: http://blog.didierstevens.com/programs/pdf-tools/ "Didier Stevens: PDF Tools"
378 [page]: http://www.imagemagick.org/script/command-line-options.php#page "ImageMagick: Command-line Options"
379
380 [[!tag PDF note_to_self howto ImageMagic convert file_formats reference longpost]]
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