10. Specific Datatype Modules

This class implements the "Bootstring" string transcoder described in ftp://ftp.rfc-editor.org/in-notes/rfc3492.txt.

Creates a Bootstring transcoder instance using the specified parameters.

The base used by the variable-length integers.

The minimum threshold digit value for the variable-length integers. Must be >=0 and <= tmax.

The maximum threshold digit value for the variable-length integers. Must be <= base-1.

The skew term for the bias adapation. Must be >= 1.

The damping factor for the bias adaption. Must be >= 2.

The initial bias for the variable-length integer thresholding. initial_bias % base must be <= base - tmin.

The first code point outside the "basic" set of code points.

The "basic" code point used as the delimiter.

The "basic" code points used as digits. The length of the string should be the same as the base parameter.

Decodes a Bootstring encoded string of "basic" code points back to the original string space.

Encodes a string using Bootstring encoding into a string constisting only of "basic" code points (< initial_n).

A buffer, used for building strings. It's conceptually similar to a string, but you can only add strings to it, and you can only get the value from it once.

There is a reason for those seemingly rather odd limitations, it makes it possible to do some optimizations that really speed things up.

You do not need to use this class unless you add very many strings together, or very large strings.

Returns the size of the buffer.

It is possible to sprintf a String.Buffer object as %s just as if it was a string.

Adds data to the buffer.

Returns the size of the buffer.

Pike 7.8 and earlier did not support adding String.Buffers directly.

It is possible to cast a String.Buffer object to a string and an int.

Empty the buffer, and don't care about the old content.

This function was not available in Pike 7.8 and earlier.

get()

Initializes a new buffer.

If no initial_size is specified, 256 is used. If you know approximately how big the buffer will be, you can optimize the operation of add() (slightly) by passing the size to this function.

Get the data from the buffer.

This will clear the data in the buffer

get_copy(), clear()

Get the data from the buffer. Significantly slower than get, but does not clear the buffer.

get()

Appends the character c at the end of the string.

Appends the output from sprintf at the end of the string. Returns the resulting size of the String.Buffer.

An object of this class is returned by get_iterator() when called with a string.

get_iterator

This is a "compiled" version of the replace function applied on a string, with more than one replace string. The replace strings are given to the create method as a from and to array and are then analyzed. The `() is then called with a string and the replace rules in the Replace object will be applied. The Replace object is used internally by the Pike optimizer and need not be used manually.

This is a "compiled" version of the replace function applied on a string, with just one replace string. The replace strings are given to the create method as a from and tom string and are then analyzed. The `() is then called with a string and the replace rule in the Replace object will be applied. The Replace object is used internally by the Pike optimizer and need not be used manually.

May be called with either zero or two arguments.

An iterator that iterates over substrings of a string, separated by a character or several different characters.

Typically you don't need to explicitly use the SplitIterator. Expressions like the following are automatically optimized into using a SplitIterator.

foreach(str/"\n", string line)
      write("%s\n", line);

The string to split.

The character or characters to split on.

Skip empty elements if set.

Callback function that is called once the buffer is used up and the SplitIterator wants more data.

Translates a string to 1337. The optional argument leetp is the maximum percentage of leetness (100=max leet, 0=no leet).

The translation is performed in three steps, first the necessary elite translations (picture -> pic, cool->kewl etc), then optional translations (ok->k, dude->dood, -ers -> -orz), then calls elite_word on the resulting words.

Translates one word to 1337. The optional argument leetp is the maximum percentage of leetness (100=max leet, 0=no leet). elite_word only do character-based translation, for instance from "k" to "|<", but no language translation (no "cool" to "kewl").

Functions that helps generating HTML. All functions generates HTML that is XHTML compliant as well as backwards compatible with old HTML standards in what extent is possible.

Pads out the rows in a array of rows to equal length. The new elements in the rows will have the value provided in padding, or "&nbsp;".

Creates an HTML select list.

The name of the select list. Will be used in the name attribute of the select element.

May either be an array of strings, where each string is a choice, or an array of pairs. A pair is an array with two strings. The first string is the value of the choice while the second string is the presentation text associated with the value.

The value that should be selected by default, if any.

This function should solve most of the obox needs that arises. It creates a table out of the array of arrays of strings fed into it. The tables will (with default settings) have a thin black outline around the table and between its cells. Much effort has gone into finding a simple HTML reresentation of such obox that is rendered in a similar way in all popular browsers. The current implementation has been tested against IE, Netscape, Mozilla, Opera and Konquest.

Simply an array of arrays with strings. The strings are the values that should appear in the table cells. All rows should have equal number of cells, otherwise the result will not be very eye pleasing.

The color of the surrounding frame. Defaults to "#000000".

The background color of the cells. Defaults to "#ffffff".

The border width. Defaults to "1".

The amount of padding in each cell. Defaults to "3".

If provided, the cell callback will be called for each cell. As in parameters it will get the current x and y coordinates in the table. The upper left cell is 0,0. In addition to the coordinates it will also receive the background color and the contents of the current cell. It is expected to return a td-element.

pad_rows

An object of this class is returned by get_iterator() when called with an array.

get_iterator

An object of this class is returned by get_iterator() when called with a mapping.

get_iterator

A mapping look-alike that overrides (ie shadows) another parent mapping.

The class implements most of the usual mapping operations.

Mapping to be shadowed.

Initial shadow of parent.

Modifications should be done to parent rather than to shadow. If this is set, only entries that are already present in shadow can be modified by later operations.

An object of this class is returned by get_iterator() when called with a multiset.

get_iterator

The type of Int.inf. Do not create more instances of this.

Implements a FIFO bit buffer, i.e. a buffer that operates on bits instead of bytes. It is not designed for performance, but as a way to handle complicated file formats and other standards where you may need to work on unaligned data units of sub byte size, without having to fry your brain while keeping track of all the bits yourself.

sizeof() will return the number of bits in the buffer.

The buffer can be initialized with initial data during creation.

Drains the buffer of all full (8-bits wide) bytes.

Adds full bytes to the buffer.

Get bits from the buffer.

Throws an error in case of data underflow.

The bits are extracted with the most significant bit first.

Put bits number of bits with the value value into the buffer.

value must not be larger than what can be stored with the number of bits given in bits.

The bits are added to the buffer with the most significant bit first.

Put bits number of 0 bits into the buffer.

Put bits number of 1 bits into the buffer.

Reads bytes (or less) bytes from the buffer and returns as string.

This is an circular list implemented by an array. It has a constant time complexity for pop and push. It has a limited max size but it can be increased with the method allocate.

Returns true if the object coll is a CircularList and contains the same values in the same order.

Create and initiate a new CircularListIterator that could be used to iterate over this list.

If an ind value is supplied the iterator will be positioned at that index.

An iterator.

The indices in this list as an array.

Insert an element in the list at the position index, the value at the position index and all above will have their index increased by one.

The index to insert the value at.

The new value.

An error if the index is out of range.

Remove the values at index index from the list.

The index to remove.

The removed value.

An error if the index is out of range.

Search the list for a specific value. Return the index of the first value that is equal to value. If no value was found UNDEFINED is returned instead

The value to find

If a start value is supplied it will start searching at the index start.

Returns the index of the found value or UNDEFINED.

An error if the start is out of range.

The number of elements in this list.

The values in this list as an array.

Addition operator

Append the content of this CircularList and @coll and return the results as a new CircularList.

The lists to append to this list

The result of the append as a new CircularList.

Index operator

The index to get the value for, could be negative to index from the end.

The value at the index index

An error if the index is out of range.

Index assign operator. Set the value at the index index to be value

The index to set

The new value

The new value at the index index

An error if the index is out of range.

Add a value at the front of the list

The value to add.

Add the value even if the list is full, in which case the element at the back of the list will be removed.

An error if the list is full and force is false.

force was not supported in Pike 8.0.1800 and earlier.

This is the same operation as push_front().

push_back(), push_front()

Increase the maxsize of the CircularlList.

Add this number of new elements to the list.

Cast operator.

Casts to this type.

Casts to the following types are supported:

An array with the contents of this list.

Clear the contents of the list.

Creates a new CircularList around the array arg or a new CircularList with the maximum size of arg.

Remove the first occurrence of the value value from the list.

The value to remove from the list.

The index of the removed element or -1 if there was no value to remove.

Create and initiate a new CircularListIterator that could be used to iterate over this list.

An iterator positioned at the first element in the list.

Returns 1 if the list is empty otherwise 0.

Create and initiate a new CircularListIterator that could be used to iterate over this list.

An iterator positioned after the last element in the list.

Returns the maximal size of this list.

The value at the back of the list but do not remove it from the list.

The value at the front of the list but do not remove it from the list.

Remove the value at the back of the list and return it.

The value at the back of the list.

Remove the value at the front of the list and return it.

The value at the front of the list.

Add a new value at the end of the list.

The value to add.

Add the value even if the list is full, in which case the element at the front of the list will be removed.

An error if the list is full and force is false.

force was not supported in Pike 8.0.1800 and earlier.

add(), push_front()

Add a new value at the front of the list.

The value to add.

Add the value even if the list is full, in which case the element at the back of the list will be removed.

An error if the list is full and force is false.

force was not supported in Pike 8.0.1800 and earlier.

This is the same operation as push_front().

add(), push_back()

This class implements a (min-)heap. The value of a child node will always be greater than or equal to the value of its parent node. Thus, the top node of the heap will always hold the smallest value.

Returns the number of elements in the heap.

Takes a value in the heap and sorts it through the heap to maintain its sort criteria (increasing order).

Either the element handle returned by push(), or the pushed value itself.

Returns the element handle for the value (if present in the heap), and 0 (zero) otherwise.

Returns the Element on top of the heap (which is also the one with the smallest value in the heap) without removing it.

Returns the smallest Element on the heap if any, and UNDEFINED otherwise.

peek(), low_pop(), pop()

Removes and returns the Element on top of the heap, which also is the smallest value in the heap.

Returns UNDEFINED if the heap is empty.

pop(), peek(), push(), remove()

Returns the item on top of the heap (which is also the smallest value in the heap) without removing it.

Returns the smallest value on the heap if any, and UNDEFINED otherwise.

low_peek(), pop()

Removes and returns the item on top of the heap, which also is the smallest value in the heap.

Throws an error if the heap is empty.

low_pop(), peek(), push(), remove()

Push an element onto the heap. The heap will automatically sort itself so that the smallest value will be at the top.

Returns an element handle, which can be used with adjust() and remove().

If value is a Heap.Element and already present on the heap this is equivalent to calling adjust().

pop(), remove()

Remove a value from the heap.

Value to remove.

push(), pop()

Returns the number of elements in the heap.

Replaced by lfun::_sizeof.

Removes and returns the item on top of the heap, which also is the smallest value in the heap.

Replaced by pop.

A history is a stack where you can only push entries. When the stack has reached a certain size the oldest entries are removed on every push. Other proposed names for this data type is leaking stack and table (where you push objects onto the table in one end and objects are falling off the table in the other.

Returns the index numbers of the history entries available.

A sizeof operation on this object returns the number of elements currently in the history, e.g. <= the current max size.

Returns the values of the available history entries.

Get a value from the history as if it was an array, e.g. both positive and negative numbers may be used. The positive numbers are however offset with 1, so [1] is the first entry in the history and [-1] is the last.

Overwrite one value in the history. The history position may be identified either by positive or negative offset, like `[].

max_size is the maximum number of entries that can reside in the history at the same time.

Empties the history. All entries in the history are removed, to allow garbage collect to remove them. The entry sequence counter is not reset.

Returns the absolute sequence number of the oldest result still in the history. Returns 0 if there are no results in the history.

Returns the absolute sequence number of the latest result inserted into the history.

Returns the maximum number of values in the history

set_maxsize

Push a new value into the history.

Tells if the History object allows adjacent equal values. 1 means that only uniqe values are allowed adter each other.

set_no_adjacent_duplicates

Set the maximume number of entries that can be stored in the history simultaneous.

get_maxsize

Change how the History object should treat two identical values in a row. If 1 than only unique values are allowed after each other.

query_no_adjacent_duplicates

Linked list of values.

Returns the number of elements in the list.

Describe the list.

sprintf(), lfun::_sprintf()

Returns an array of elements in the list.

Append values to the end of the list.

insert()

Cast the lists. array is the only supported type.

Create a new List, and initialize it with values.

Empties the List.

Get the element at the head of the list.

Throws an error if the list is empty.

is_empty(), tail(), pop()

Insert values at the front of the list.

append()

Check if the list is empty.

Returns 1 if the list is empty, and 0 (zero) if there are elements in the list.

Pop the element at the head of the list from the list.

Throws an error if the list is empty.

is_empty(), head(), tail(), pop_back()

Pop the element at the tail of the list from the list.

Throws an error if the list is empty.

is_empty(), head(), tail(), pop()

Get the element at the tail of the list.

Throws an error if the list is empty.

is_empty(), head(), pop_back()

This class implements a priority queue. Each element in the priority queue is assigned a priority value, and the priority queue always remains sorted in increasing order of the priority values. The top of the priority queue always holds the element with the smallest priority. The priority queue is realized as a (min-)heap.

Adjust the priority value new_pri of an element handle in the priority queue. The priority queue will automatically sort itself so that the element with the smallest priority value will be at the top.

Returns the item on top of the priority queue (which is also the element with the smallest priority value) without removing it.

Removes and returns the item on top of the heap, which also is the smallest value in the heap.

Push an element val into the priority queue and assign a priority value pri to it. The priority queue will automatically sort itself so that the element with the smallest priority will be at the top.

A simple FIFO queue.

It is possible to cast ADT.Queue to an array.

Creates a queue with the initial items args in it.

Empties the queue.

Returns the next element from the queue.

Returns true if the queue is empty, otherwise zero.

Returns the next element from the queue without removing it from the queue.

Adds items to the queue.

The sequence work similar to an array but has the possibilities to insert and remove elements. It also has a more powerful iterator.

Returns true if the object coll is a Sequence and contains the same values in the same order.

Create and initiate a new SequenceIterator that could be used to iterate over this sequence.

If an ind value is supplied the iterator will be positioned at that index.

An iterator.

The indices in this adapter as an array.

Insert an element in the sequence at the position index, the value at the position index and all above will have their index increased by one.

The index to insert the value at.

The new value.

Remove the values at index index from the sequence.

The index to remove.

The removed value.

Search the sequence for a specific value. Return the index of the first value that is equal to value. If no value was found UNDEFINED is returned instead.

The value to find.

If a start value is supplied it will start searching at the index start.

Returns the index of the found value or UNDEFINED.

The number of elements in this adapter.

The values in this adapter as an array.

And operator Perform an and on this sequence and the coll sequence by only returning those values that is present in both sequences as a new Sequence. The remaining values is in the same order as they are in this sequence and the values are compared using `==.

The sequence to and to this sequence.

The result of the and as a new Sequence.

Addition operator

Append the content of @coll to this sequence and return the results as a new Sequence.

The sequences to append to this sequence.

The result of the append as a new Sequence.

Subtraction operator

Removes those values in this sequence that also are present in @coll and return the results as a new Sequence.

The sequence to subtract from this sequence.

The result of the subtraction as a new Sequence.

Index operator.

The index to get the value for, could be negative to index from the end.

The value at the index index.

An error if the index is out of range.

Index assign operator. Set the value at the index index to be value.

The index to set.

The new value.

The new value at the index index.

Xor operator Perform a xor on this sequence and the coll sequence by returning those values that is present in one of the sequences but not in both adapters as a new Sequence. The values are compared using `==.

The sequence to xor with this sequence.

The result of the xor as a new Sequence.

Or operator Perform an or on this sequence and the coll sequence by returning those values that is present in both sequences as a new Sequence. The values are compared using `==.

The sequence to or with this sequence.

The result of the or as a new Sequence.

Add a value at the end of the sequence.

The value to add.

Cast operator.

Casts to this type.

Casts to the following types are supported:

An array with the contents of this sequence.

Clear the contents of the sequence.

Creates a new Sequence around the array arg or a new Sequence with the size of arg.

Remove the first occurrence of the value value from the sequence.

The value to remove from the sequence.

The index of the removed element or -1 if there was no value to remove.

Create and initiate a new SequenceIterator that could be used to iterate over this sequence.

An iterator positioned at the first element in the sequence.

Returns 1 if the sequence is empty otherwise 0.

Create and initiate a new SequenceIterator that could be used to iterate over this sequence.

An iterator positioned after the last element in the sequence.

Returns -1.

ADT.Set implements a datatype for sets. These sets behave much like multisets, except that they are restricted to containing only one instance of each member value.

From a performance viewpoint, it is probably more efficient for a Pike program to use mappings to serve as sets, rather than using an ADT.Set,so ADT.Set is mainly provided for the sake of completeness and code readability.

In analogy with multisets, indices() of an ADT.Set givess an array containing all members of the set.

Number of items in the set.

Printable representation of the set.

In analogy with multisets, values() of an ADT.Set givess an array indicating the number of occurrences in the set for each position in the member array returned by indices(). (Most of the time, this is probably rather useless for sets, since the result is an array which just contain 1's, one for each member of the set. Still, this function is provided for consistency.

Intersection. Returns a set containing those values that were present in both the operand sets.

Difference. The expression 'A - B', where A and B are sets, returns all elements in A that are not also present in B.

True subset. A < B returns true if each item in A is also present in B, and B contains at least one item not present in A.

Equality. A == B returns true if all items in A are present in B, and all items in B are present in A. Otherwise, it returns false.

True superset. A > B returns true if each item in B is also present in A, and A contains at least one item not present in B.

Indexing a set with a value V gives 1 if V is a member of the set, otherwise 0.

Setting an index V to 0 removes V from the set. Setting it to a non-0 value adds V as a member of the set.

Union. Returns a set containing all elements present in either or both of the operand sets.

Add items to the set.

An ADT.Set can be cast to an array or a multiset.

Check whether a value is a member of the set.

Create an ADT.Set, optionally initialized from another ADT.Set or a compatible type. If no initial data is given, the set will start out empty.

Return a filtered version of the set, containing only those members for which the filtering function f returned true.

The filtering function is called with a single mixed-type argument which is the member value to be checked.

Destructively filter the set, i.e. remove every element for which the filtering function f returns 0, and then return the set.

The filtering function is called with a single mixed-type argument which is the member value to be checked.

Returns 1 if the set is empty, otherwise 0.

Map the values of a set: calls the map function f once for each member of the set, returning an array which contains the result of each one of those function calls. Note that since a set isn't ordered, the values in the returned array will be in more or less random order. If you need to know which member value produced which result, you have to make that a part of what the filtering function returns.

The filtering function f is called with a single, mixed-type argument which is the member value to be mapped.

Remove items from the set.

Remove all items from the set.

Subset. A <= B returns true if all items in A are also present in B.