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Elektra
0.9.2
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This plugin is a type checker plugin using the CORBA data types.
A common and successful type system happens to be CORBA. The system is well suited because of the many well-defined mappings it provides to other programming languages.
The type checker plugin supports these types: short, unsigned_short, long, unsigned_long, long_long, unsigned_long_long, float, double, char, wchar, boolean, any, enum, string, wstring and octet.
any will always be successful, regardless of the content.string matches any non-empty key value.octet and char are equivalent to each other.enum will do enum checking as described below.boolean only allows the values 1 and 0. See also Normalization.wchar and wstring the function mbstowcs(3) must be able convert the key value into a wide character string. wstrings can be of any non-zero length, wchar must have exactly length 1.If a key is set to the type enum the plugin will look for the metadata array check/enum/#.
For example:
Only the values listed in this array will be accepted. The array indices don't have to be continuous, using e.g. only #1, #2 and #4 is also allowed. Just make sure check/enum is set to the largest index in the array.
Furthermore check/enum/delimiter may contain a separator character, that separates multiple allowed occurrences. If check/enum/delimiter contain more than a single character validation will fail.
For example:
Then the value middle_small would validate. middle_small_small would be allowed as well, because multi-values are treated like bitfields.
Some types support normalization in addition to the standard type checking. This means that an extended set of allowed values is normalized into a different (in most cases standardized) set before type checking. The normalized values will be passed on from kdbGet to the rest of Elektra and your application. During kdbSet changed values are also normalized before type checking and at the end of kdbSet, if everything was successful, the values are restored to the ones originally provided by the user (no matter if they were changed before kdbSet or already present in kdbGet).
The full normalization/restore procedure can be described by the following cases:
Case 1: The Key existed in kdbGet and is unchanged between kdbGet and kdbSet
This is the easiest and most obvious case. The value is normalized in kdbGet and the original value is restored in kdbSet, so that the underlying storage file remains unchanged (w.r.t. the key in question).
Case 2: The Key didn't exist in kdbGet, i.e. it was added
Here the value is normalized to verify the type and then restored immediately (all inside of kdbSet).
Case 3: The Key existed in kdbGet, but its value was changed between kdbGet and kdbSet
This is essential the same as Case 2. keySetString removes the origvalue metadata used to store the original value, so as far as this plugin is concerned, the key didn't exist in kdbGet.
Note: If normalization is used, often times you will get a normalization error instead of a type checking error.
The values that are accepted as booleans are configured during mounting:
The above line defines that the array of allowed boolean pairs. booleans=#1 defines the last element of the array as #1. For each element # the keys booleans/#/true and booleans/#/false define the true and false value respectively. True values are normalized to 1, false values to 0.
Even though we didn't specify them the values 1 and 0 are still accepted. The normalized values are always okay to use. If no configuration is given, the allowed values default to 1, yes, on, true, enabled and enable as true values and 0, no, off, false, disabled and disable as false values.
The accepted values can also be overridden on a per-key-basis. Simply add the metakey check/boolean/true and check/boolean/false to set the accepted true and false values. Only a single true/false value can be chosen. This is intended for use cases, where normally you prefer to use only e.g. 1, 0 and true, false, but what to override that for a key where e.g. enabled and disabled make more sense contextually (e.g. for something like /log/debug). Because of this intention restoring also works differently, when check/boolean/true and check/boolean/false are used. In this case we will always restore to the chosen override values.
Note: The values 1 and 0 are accepted, even if overrides are used. This means you can set a key with overrides to 0 (or 1) and during kdbSet it will be restored to the false (or true) override value. (This is useful for the high-level API.)
It is an error to specify only one of booleans/#/true and booleans/#/false or check/boolean/true and check/boolean/false. Boolean always come in pairs!
You can also change how values shall be restored in kdbSet:
The config key boolean/restoreas must be a valid index of the booleans array or the special value none. If boolean/restoreas was set to an index, the chosen boolean pair will be used when values are restored in kdbSet. So in the above example the plugin accepts 1, true, 0 and false as boolean values, on kdbGet it turns true into 1 and false into 0 and on kdbSet it turns 1 into true and 0 into false.
If no booleans array was given the allowed values for boolean/restoreas are:
#0 for yes/no#1 for true/false#2 for on/off#3 for enabled/disabled#4 for enable/disableThe special value boolean/restoreas=none completely disables the restore procedure. In other words, kdbSet will always return either 0 or 1 for boolean values. This is useful, if a storage format with built-in support for boolean values is used.
Enums also support normalization. Contrary to boolean normalization, enum normalization is always configured on a per-key-basis.
Simply set the metakey check/enum/normalize to 1 in order to normalize the string values to there indexes. Any other value is ignored.
Take for example a key with the following enum configuration:
The value small will be normalized to 0, medium to 1 and huge to 3. During restore the values 0, 1 and 3 will be restored to small, medium and huge.
If you use normalization, you can pass string values or indices to kdbGet and kdbSet, but you will always get back indices from kdbGet and string values from kdbSet. (Therefore you can seamlessly use elektraGetUnsignedLongLong from high-level API for normalized enums.)
The plugin also supports normalizing enums that use check/enum/delimiter, however be careful which indexes you use in this case. The indexes of all values are simple bitwise or-ed (using |). In the above example small_medium would be normalized to 1 (0 | 1 == 1), the same value as medium. This means during restore the value emitted will be medium.
A version that would work with delimiter and normalization is:
Here small_medium is normalized to 3, which is a unique value. During restore with delimiters the values might not be restored to there original form, but may be restored to an equivalent representation. e.g. small_none may be restored to just small or small_medium may be restored to medium_small This has technical reasons and we do not guarantee any restriction on what representation is produced during restore, other than the normalized value being the same as for the user provided representation.
**_IMPORTANT:_** Do not use normalization together with enums, whose string values start with digits (e.g. check/enum/#0 = 1abc). This breaks normalization! Indices are differentiated from string value by whether they start with a digit.
For enums:
Or with multi-enums:
For booleans:
Records are part of other plugins.
The CORBA type system also has its limits. The types string and enum can be unsatisfactory. While string is too general and makes no limit on how the sequence of characters is structured, the enumeration is too finite. For example, it is not possible to say that a string is not allowed to have a specific symbol in it. Combine this plugin with other type checker plugins to circumvent such limitations.
1.8.17