Parents (Total: 6)

The searched file hash is included in 6 parent files which include package known and seen by metalookup. A sample is included below:

Key	Value
MD5	ED3464C2C072FF5AC06755E8B57DF448
PackageArch	noarch
PackageDescription	It often happens that you have text data in Unicode, but you need to represent it in ASCII. For example when integrating with legacy code that doesn't support Unicode, or for ease of entry of non-Roman names on a US keyboard, or when constructing ASCII machine identifiers from human-readable Unicode strings that should still be somewhat intelligible (a popular example of this is when making an URL slug from an article title). In most of these examples you could represent Unicode characters as "???" or "\\15BA\\15A0\\1610", to mention two extreme cases. But that's nearly useless to someone who actually wants to read what the text says. What Unidecode provides is a middle road: function unidecode() takes Unicode data and tries to represent it in ASCII characters (i.e., the universally displayable characters between 0x00 and 0x7F), where the compromises taken when mapping between two character sets are chosen to be near what a human with a US keyboard would choose. The quality of resulting ASCII representation varies. For languages of western origin it should be between perfect and good. On the other hand transliteration (i.e., conveying, in Roman letters, the pronunciation expressed by the text in some other writing system) of languages like Chinese, Japanese or Korean is a very complex issue and this library does not even attempt to address it. It draws the line at context-free character-by-character mapping. So a good rule of thumb is that the further the script you are transliterating is from Latin alphabet, the worse the transliteration will be. Note that this module generally produces better results than simply stripping accents from characters (which can be done in Python with built-in functions). It is based on hand-tuned character mappings that for example also contain ASCII approximations for symbols and non-Latin alphabets. This is a Python port of Text::Unidecode Perl module by Sean M. Burke <sburke@cpan.org>.
PackageMaintainer	https://bugs.opensuse.org
PackageName	python3-Unidecode
PackageRelease	lp151.1.1
PackageVersion	1.0.23
SHA-1	2030B89E993615BB6D5FF204408DC4D8E818C8A2
SHA-256	413776C9B395431BA4A78BD891508BECB0103A4FA3C93F675F4CB442A728FE20

Key	Value
MD5	E775BB6AF9F74DFB849AEDC3B0CB3BFB
PackageArch	noarch
PackageDescription	It often happens that you have text data in Unicode, but you need to represent it in ASCII. For example when integrating with legacy code that doesn't support Unicode, or for ease of entry of non-Roman names on a US keyboard, or when constructing ASCII machine identifiers from human-readable Unicode strings that should still be somewhat intelligible (a popular example of this is when making an URL slug from an article title). In most of these examples you could represent Unicode characters as "???" or "\\15BA\\15A0\\1610", to mention two extreme cases. But that's nearly useless to someone who actually wants to read what the text says. What Unidecode provides is a middle road: function unidecode() takes Unicode data and tries to represent it in ASCII characters (i.e., the universally displayable characters between 0x00 and 0x7F), where the compromises taken when mapping between two character sets are chosen to be near what a human with a US keyboard would choose. The quality of resulting ASCII representation varies. For languages of western origin it should be between perfect and good. On the other hand transliteration (i.e., conveying, in Roman letters, the pronunciation expressed by the text in some other writing system) of languages like Chinese, Japanese or Korean is a very complex issue and this library does not even attempt to address it. It draws the line at context-free character-by-character mapping. So a good rule of thumb is that the further the script you are transliterating is from Latin alphabet, the worse the transliteration will be. Note that this module generally produces better results than simply stripping accents from characters (which can be done in Python with built-in functions). It is based on hand-tuned character mappings that for example also contain ASCII approximations for symbols and non-Latin alphabets. This is a Python port of Text::Unidecode Perl module by Sean M. Burke <sburke@cpan.org>.
PackageMaintainer	https://bugs.opensuse.org
PackageName	python3-Unidecode
PackageRelease	lp152.1.1
PackageVersion	1.1.1
SHA-1	F3D918BA71369FB56BED5439148CF1C984C1A291
SHA-256	DC437014CA98F7D85E5B6941C27F5FAD5B4A3B759EC67EE652ED76166692938E

Key	Value
MD5	D5DB910AB56A3CD607DCA28BDB3302C5
PackageArch	noarch
PackageDescription	It often happens that you have text data in Unicode, but you need to represent it in ASCII. For example when integrating with legacy code that doesn't support Unicode, or for ease of entry of non-Roman names on a US keyboard, or when constructing ASCII machine identifiers from human-readable Unicode strings that should still be somewhat intelligible (a popular example of this is when making an URL slug from an article title). In most of these examples you could represent Unicode characters as "???" or "\\15BA\\15A0\\1610", to mention two extreme cases. But that's nearly useless to someone who actually wants to read what the text says. What Unidecode provides is a middle road: function unidecode() takes Unicode data and tries to represent it in ASCII characters (i.e., the universally displayable characters between 0x00 and 0x7F), where the compromises taken when mapping between two character sets are chosen to be near what a human with a US keyboard would choose. The quality of resulting ASCII representation varies. For languages of western origin it should be between perfect and good. On the other hand transliteration (i.e., conveying, in Roman letters, the pronunciation expressed by the text in some other writing system) of languages like Chinese, Japanese or Korean is a very complex issue and this library does not even attempt to address it. It draws the line at context-free character-by-character mapping. So a good rule of thumb is that the further the script you are transliterating is from Latin alphabet, the worse the transliteration will be. Note that this module generally produces better results than simply stripping accents from characters (which can be done in Python with built-in functions). It is based on hand-tuned character mappings that for example also contain ASCII approximations for symbols and non-Latin alphabets. This is a Python port of Text::Unidecode Perl module by Sean M. Burke <sburke@cpan.org>.
PackageName	python3-Unidecode
PackageRelease	lp150.2.1
PackageVersion	1.1.1
SHA-1	9F44256F748E766693559AEDEEB29559C57BBAE8
SHA-256	2FEF6F55F0048501E157310C130B3A479B0B8E2D38A6D242701C8D625AC7B00A

Key	Value
MD5	A0CB50F51DC86BE1AC16AAA47FC0DD39
PackageArch	noarch
PackageDescription	It often happens that you have text data in Unicode, but you need to represent it in ASCII. For example when integrating with legacy code that doesn't support Unicode, or for ease of entry of non-Roman names on a US keyboard, or when constructing ASCII machine identifiers from human-readable Unicode strings that should still be somewhat intelligible (a popular example of this is when making an URL slug from an article title). In most of these examples you could represent Unicode characters as "???" or "\\15BA\\15A0\\1610", to mention two extreme cases. But that's nearly useless to someone who actually wants to read what the text says. What Unidecode provides is a middle road: function unidecode() takes Unicode data and tries to represent it in ASCII characters (i.e., the universally displayable characters between 0x00 and 0x7F), where the compromises taken when mapping between two character sets are chosen to be near what a human with a US keyboard would choose. The quality of resulting ASCII representation varies. For languages of western origin it should be between perfect and good. On the other hand transliteration (i.e., conveying, in Roman letters, the pronunciation expressed by the text in some other writing system) of languages like Chinese, Japanese or Korean is a very complex issue and this library does not even attempt to address it. It draws the line at context-free character-by-character mapping. So a good rule of thumb is that the further the script you are transliterating is from Latin alphabet, the worse the transliteration will be. Note that this module generally produces better results than simply stripping accents from characters (which can be done in Python with built-in functions). It is based on hand-tuned character mappings that for example also contain ASCII approximations for symbols and non-Latin alphabets. This is a Python port of Text::Unidecode Perl module by Sean M. Burke <sburke@cpan.org>.
PackageMaintainer	https://bugs.opensuse.org
PackageName	python3-Unidecode
PackageRelease	bp155.2.14
PackageVersion	1.1.1
SHA-1	C02A91C9B8E0B7C63C89F38C838AB3CD6E6FEF18
SHA-256	3E5E2D9105292875DD018303D889F361602B27DAF056ACFFF765A12B207255E8

Key	Value
MD5	66107BFD0ADD2BFBB1D5BC89142B1219
PackageArch	noarch
PackageDescription	It often happens that you have text data in Unicode, but you need to represent it in ASCII. For example when integrating with legacy code that doesn't support Unicode, or for ease of entry of non-Roman names on a US keyboard, or when constructing ASCII machine identifiers from human-readable Unicode strings that should still be somewhat intelligible (a popular example of this is when making an URL slug from an article title). In most of these examples you could represent Unicode characters as "???" or "\\15BA\\15A0\\1610", to mention two extreme cases. But that's nearly useless to someone who actually wants to read what the text says. What Unidecode provides is a middle road: function unidecode() takes Unicode data and tries to represent it in ASCII characters (i.e., the universally displayable characters between 0x00 and 0x7F), where the compromises taken when mapping between two character sets are chosen to be near what a human with a US keyboard would choose. The quality of resulting ASCII representation varies. For languages of western origin it should be between perfect and good. On the other hand transliteration (i.e., conveying, in Roman letters, the pronunciation expressed by the text in some other writing system) of languages like Chinese, Japanese or Korean is a very complex issue and this library does not even attempt to address it. It draws the line at context-free character-by-character mapping. So a good rule of thumb is that the further the script you are transliterating is from Latin alphabet, the worse the transliteration will be. Note that this module generally produces better results than simply stripping accents from characters (which can be done in Python with built-in functions). It is based on hand-tuned character mappings that for example also contain ASCII approximations for symbols and non-Latin alphabets. This is a Python port of Text::Unidecode Perl module by Sean M. Burke <sburke@cpan.org>.
PackageMaintainer	https://bugs.opensuse.org
PackageName	python3-Unidecode
PackageRelease	bp154.1.68
PackageVersion	1.1.1
SHA-1	060FC5EB5F092C399740382F2358B1955DF7241D
SHA-256	4F816BB93C7CA3B95D760DD8435A8E21351F44FFD1454BF6B96163D4737614AB

Key	Value
MD5	D6998B9B4BFC03E466A35394F730C27C
PackageArch	noarch
PackageDescription	It often happens that you have text data in Unicode, but you need to represent it in ASCII. For example when integrating with legacy code that doesn't support Unicode, or for ease of entry of non-Roman names on a US keyboard, or when constructing ASCII machine identifiers from human-readable Unicode strings that should still be somewhat intelligible (a popular example of this is when making an URL slug from an article title). In most of these examples you could represent Unicode characters as "???" or "\\15BA\\15A0\\1610", to mention two extreme cases. But that's nearly useless to someone who actually wants to read what the text says. What Unidecode provides is a middle road: function unidecode() takes Unicode data and tries to represent it in ASCII characters (i.e., the universally displayable characters between 0x00 and 0x7F), where the compromises taken when mapping between two character sets are chosen to be near what a human with a US keyboard would choose. The quality of resulting ASCII representation varies. For languages of western origin it should be between perfect and good. On the other hand transliteration (i.e., conveying, in Roman letters, the pronunciation expressed by the text in some other writing system) of languages like Chinese, Japanese or Korean is a very complex issue and this library does not even attempt to address it. It draws the line at context-free character-by-character mapping. So a good rule of thumb is that the further the script you are transliterating is from Latin alphabet, the worse the transliteration will be. Note that this module generally produces better results than simply stripping accents from characters (which can be done in Python with built-in functions). It is based on hand-tuned character mappings that for example also contain ASCII approximations for symbols and non-Latin alphabets. This is a Python port of Text::Unidecode Perl module by Sean M. Burke <sburke@cpan.org>.
PackageMaintainer	https://bugs.opensuse.org
PackageName	python3-Unidecode
PackageRelease	bp153.1.17
PackageVersion	1.1.1
SHA-1	D4E1A829442F52A1F2F60F7035CABE85DB138BA9
SHA-256	3F9AB5AEDA825608C7629F8DDCEE1AAF829EE49448B170A6CF1E09AC6D62813A