[1096] | 1 | A Fast Method for Identifying Plain Text Files
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| 2 | ==============================================
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| 3 |
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| 4 |
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| 5 | Introduction
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| 6 | ------------
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| 7 |
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| 8 | Given a file coming from an unknown source, it is sometimes desirable
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| 9 | to find out whether the format of that file is plain text. Although
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| 10 | this may appear like a simple task, a fully accurate detection of the
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| 11 | file type requires heavy-duty semantic analysis on the file contents.
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| 12 | It is, however, possible to obtain satisfactory results by employing
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| 13 | various heuristics.
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| 14 |
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| 15 | Previous versions of PKZip and other zip-compatible compression tools
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| 16 | were using a crude detection scheme: if more than 80% (4/5) of the bytes
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| 17 | found in a certain buffer are within the range [7..127], the file is
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| 18 | labeled as plain text, otherwise it is labeled as binary. A prominent
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| 19 | limitation of this scheme is the restriction to Latin-based alphabets.
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| 20 | Other alphabets, like Greek, Cyrillic or Asian, make extensive use of
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| 21 | the bytes within the range [128..255], and texts using these alphabets
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| 22 | are most often misidentified by this scheme; in other words, the rate
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| 23 | of false negatives is sometimes too high, which means that the recall
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| 24 | is low. Another weakness of this scheme is a reduced precision, due to
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| 25 | the false positives that may occur when binary files containing large
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| 26 | amounts of textual characters are misidentified as plain text.
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| 27 |
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| 28 | In this article we propose a new, simple detection scheme that features
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| 29 | a much increased precision and a near-100% recall. This scheme is
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| 30 | designed to work on ASCII, Unicode and other ASCII-derived alphabets,
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| 31 | and it handles single-byte encodings (ISO-8859, MacRoman, KOI8, etc.)
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| 32 | and variable-sized encodings (ISO-2022, UTF-8, etc.). Wider encodings
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| 33 | (UCS-2/UTF-16 and UCS-4/UTF-32) are not handled, however.
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| 34 |
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| 35 |
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| 36 | The Algorithm
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| 37 | -------------
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| 38 |
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| 39 | The algorithm works by dividing the set of bytecodes [0..255] into three
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| 40 | categories:
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| 41 | - The white list of textual bytecodes:
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| 42 | 9 (TAB), 10 (LF), 13 (CR), 32 (SPACE) to 255.
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| 43 | - The gray list of tolerated bytecodes:
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| 44 | 7 (BEL), 8 (BS), 11 (VT), 12 (FF), 26 (SUB), 27 (ESC).
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| 45 | - The black list of undesired, non-textual bytecodes:
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| 46 | 0 (NUL) to 6, 14 to 31.
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| 47 |
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| 48 | If a file contains at least one byte that belongs to the white list and
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| 49 | no byte that belongs to the black list, then the file is categorized as
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| 50 | plain text; otherwise, it is categorized as binary. (The boundary case,
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| 51 | when the file is empty, automatically falls into the latter category.)
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| 52 |
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| 53 |
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| 54 | Rationale
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| 55 | ---------
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| 56 |
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| 57 | The idea behind this algorithm relies on two observations.
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| 58 |
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| 59 | The first observation is that, although the full range of 7-bit codes
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| 60 | [0..127] is properly specified by the ASCII standard, most control
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| 61 | characters in the range [0..31] are not used in practice. The only
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| 62 | widely-used, almost universally-portable control codes are 9 (TAB),
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| 63 | 10 (LF) and 13 (CR). There are a few more control codes that are
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| 64 | recognized on a reduced range of platforms and text viewers/editors:
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| 65 | 7 (BEL), 8 (BS), 11 (VT), 12 (FF), 26 (SUB) and 27 (ESC); but these
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| 66 | codes are rarely (if ever) used alone, without being accompanied by
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| 67 | some printable text. Even the newer, portable text formats such as
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| 68 | XML avoid using control characters outside the list mentioned here.
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| 69 |
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| 70 | The second observation is that most of the binary files tend to contain
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| 71 | control characters, especially 0 (NUL). Even though the older text
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| 72 | detection schemes observe the presence of non-ASCII codes from the range
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| 73 | [128..255], the precision rarely has to suffer if this upper range is
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| 74 | labeled as textual, because the files that are genuinely binary tend to
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| 75 | contain both control characters and codes from the upper range. On the
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| 76 | other hand, the upper range needs to be labeled as textual, because it
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| 77 | is used by virtually all ASCII extensions. In particular, this range is
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| 78 | used for encoding non-Latin scripts.
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| 79 |
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| 80 | Since there is no counting involved, other than simply observing the
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| 81 | presence or the absence of some byte values, the algorithm produces
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| 82 | consistent results, regardless what alphabet encoding is being used.
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| 83 | (If counting were involved, it could be possible to obtain different
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| 84 | results on a text encoded, say, using ISO-8859-16 versus UTF-8.)
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| 85 |
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| 86 | There is an extra category of plain text files that are "polluted" with
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| 87 | one or more black-listed codes, either by mistake or by peculiar design
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| 88 | considerations. In such cases, a scheme that tolerates a small fraction
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| 89 | of black-listed codes would provide an increased recall (i.e. more true
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| 90 | positives). This, however, incurs a reduced precision overall, since
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| 91 | false positives are more likely to appear in binary files that contain
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| 92 | large chunks of textual data. Furthermore, "polluted" plain text should
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| 93 | be regarded as binary by general-purpose text detection schemes, because
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| 94 | general-purpose text processing algorithms might not be applicable.
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| 95 | Under this premise, it is safe to say that our detection method provides
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| 96 | a near-100% recall.
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| 97 |
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| 98 | Experiments have been run on many files coming from various platforms
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| 99 | and applications. We tried plain text files, system logs, source code,
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| 100 | formatted office documents, compiled object code, etc. The results
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| 101 | confirm the optimistic assumptions about the capabilities of this
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| 102 | algorithm.
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| 103 |
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| 104 |
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| 105 | --
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| 106 | Cosmin Truta
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| 107 | Last updated: 2006-May-28
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