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#develop (short for SharpDevelop) is a free IDE for .NET programming languages.
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SharpDevelop/src/AddIns/BackendBindings/Python/RequiredLibraries/IronPython.Modules.xml

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<?xml version="1.0"?>
<doc>
<assembly>
<name>IronPython.Modules</name>
</assembly>
<members>
<member name="F:IronPython.Runtime.ZipImportModule.zipimporter._search_order">
<summary>
zip_searchorder defines how we search for a module in the Zip
archive: we first search for a package __init__, then for
non-package .pyc, .pyo and .py entries. The .pyc and .pyo entries
are swapped by initzipimport() if we run in optimized mode. Also,
'/' is replaced by SEP there.
</summary>
</member>
<member name="M:IronPython.Runtime.ZipImportModule.zipimporter.GetData(System.String,IronPython.Runtime.PythonTuple)">
<summary>
Given a path to a Zip file and a toc_entry, return the (uncompressed)
data as a new reference.
</summary>
<param name="archive"></param>
<param name="toc_entry"></param>
<returns></returns>
</member>
<member name="M:IronPython.Runtime.ZipImportModule.zipimporter.GetCodeFromData(IronPython.Runtime.CodeContext,System.Boolean,System.Boolean,System.Int32,IronPython.Runtime.PythonTuple)">
<summary>
Return the code object for the module named by 'fullname' from the
Zip archive as a new reference.
</summary>
<param name="context"></param>
<param name="ispackage"></param>
<param name="isbytecode"></param>
<param name="mtime"></param>
<param name="toc_entry"></param>
<returns></returns>
</member>
<member name="M:IronPython.Runtime.ZipImportModule.zipimporter.ReadDirectory(System.String)">
<summary>
Given a path to a Zip archive, build a dict, mapping file names
(local to the archive, using SEP as a separator) to toc entries.
A toc_entry is a tuple:
(__file__, # value to use for __file__, available for all files
compress, # compression kind; 0 for uncompressed
data_size, # size of compressed data on disk
file_size, # size of decompressed data
file_offset, # offset of file header from start of archive
time, # mod time of file (in dos format)
date, # mod data of file (in dos format)
crc, # crc checksum of the data
)
Directories can be recognized by the trailing SEP in the name,
data_size and file_offset are 0.
</summary>
<param name="archive"></param>
<returns></returns>
</member>
<member name="M:IronPython.Runtime.ZipImportModule.zipimporter.MakeFilename(System.String,System.String)">
<summary>
Given a (sub)modulename, write the potential file path in the
archive (without extension) to the path buffer.
</summary>
<param name="prefix"></param>
<param name="name"></param>
<returns></returns>
</member>
<member name="M:IronPython.Runtime.ZipImportModule.zipimporter.GetModuleInfo(IronPython.Runtime.CodeContext,System.String)">
<summary>
Determines the type of module we have (package or module, or not found).
</summary>
<param name="context"></param>
<param name="fullname"></param>
<returns></returns>
</member>
<member name="T:IronPython.Runtime.ZipImportModule.SourceStringContentProvider">
<summary>
Provides a StreamContentProvider for a stream of content backed by a file on disk.
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.Adler32">
<summary>
This class represents adler32 checksum algorithm
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Adler32.GetAdler32Checksum(System.Int64,System.Byte[],System.Int32,System.Int32)">
<summary>
This static method returns adler32 checksum of the buffer data
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.Deflate">
<summary>
Implementation of the Deflate compression algorithm.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.MAX_MEM_LEVEL">
<summary>
Maximum memory level
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.Z_DEFAULT_COMPRESSION">
<summary>
Defalult compression method
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.DEF_MEM_LEVEL">
<summary>
Default memory level
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.NeedMore">
<summary>
block not completed, need more input or more output
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.BlockDone">
<summary>
Block internalFlush performed
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.FinishStarted">
<summary>
Finish started, need only more output at next deflate
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.FinishDone">
<summary>
finish done, accept no more input or output
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.PRESET_DICT">
<summary>
preset dictionary flag in zlib header
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.Z_DEFLATED">
<summary>
The deflate compression method
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.Buf_size">
<summary>
The size of the buffer
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.REP_3_6">
<summary>
repeat previous bit length 3-6 times (2 bits of repeat count)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.REPZ_3_10">
<summary>
repeat a zero length 3-10 times (3 bits of repeat count)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.REPZ_11_138">
<summary>
repeat a zero length 11-138 times (7 bits of repeat count)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.config_table">
<summary>
Deflate class congiration table
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.strm">
<summary>
Pointer back to this zlib stream
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.status">
<summary>
As the name implies
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.pending_buf">
<summary>
Output still pending
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.pending_buf_size">
<summary>
Size of Pending_buf
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.pending_out">
<summary>
Next pending byte to output to the stream
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.pending">
<summary>
Number of bytes in the pending buffer
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.noheader">
<summary>
suppress zlib header and adler32
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.data_type">
<summary>
UNKNOWN, BINARY or ASCII
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.method">
<summary>
STORED (for zip only) or DEFLATED
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.last_flush">
<summary>
Value of internalFlush parameter for previous deflate call
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.w_size">
<summary>
LZ77 Window size (32K by default)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.w_bits">
<summary>
log2(w_size) (8..16)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.w_mask">
<summary>
w_size - 1
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.window">
<summary>
Sliding Window. Input bytes are ReadPos into the second half of the Window,
and move to the first half later to keep a dictionary of at least wSize
bytes. With this organization, matches are limited to a distance of
wSize-MAX_MATCH bytes, but this ensures that IO is always
performed with a length multiple of the block size. Also, it limits
the Window size to 64K, which is quite useful on MSDOS.
To do: use the user input buffer as sliding Window.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.window_size">
<summary>
Actual size of Window: 2*wSize, except when the user input buffer is directly used as sliding Window.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.prev">
<summary>
Link to older string with same hash index. To limit the size of this
array to 64K, this link is maintained only for the last 32K strings.
An index in this array is thus a Window index modulo 32K.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.head">
<summary>
Heads of the hash chains or NIL.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.ins_h">
<summary>
hash index of string to be inserted
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.hash_size">
<summary>
number of elements in hash table
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.hash_bits">
<summary>
log2(hash_size)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.hash_mask">
<summary>
hash_size-1
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.hash_shift">
<summary>
Number of bits by which ins_h must be shifted at each input
step. It must be such that after MIN_MATCH steps, the oldest
byte no longer takes part in the hash key, that is:
hash_shift * MIN_MATCH >= hash_bits
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.block_start">
<summary>
Window position at the beginning of the current output block. Gets negative when the Window is moved backwards.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.match_length">
<summary>
length of best match
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.prev_match">
<summary>
previous match
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.match_available">
<summary>
set if previous match exists
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.strstart">
<summary>
start of string to insert
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.match_start">
<summary>
start of matching string
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.lookahead">
<summary>
number of valid bytes ahead in Window
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.prev_length">
<summary>
Length of the best match at previous step. Matches not greater than this
are discarded. This is used in the lazy match evaluation.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.max_chain_length">
<summary>
To speed up deflation, hash chains are never searched beyond this
length. A higher limit improves compression ratio but degrades the speed.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.max_lazy_match">
<summary>
Attempt to find a better match only when the current match is strictly
smaller than this value. This mechanism is used only for compression
levels >= 4.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate._level">
<summary>
compression level (1..9)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.strategy">
<summary>
favor or force Huffman coding
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.good_match">
<summary>
Use a faster search when the previous match is longer than this
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.nice_match">
<summary>
Stop searching when current match exceeds this
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.dyn_ltree">
<summary>
literal and length tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.dyn_dtree">
<summary>
distance tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.bl_tree">
<summary>
Huffman tree for bit lengths
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.l_desc">
<summary>
Desc for literal tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.d_desc">
<summary>
desc for distance tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.bl_desc">
<summary>
desc for bit length tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.bl_count">
<summary>
number of codes at each bit length for an optimal tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.heap">
<summary>
heap used to build the Huffman trees
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.heap_len">
<summary>
number of elements in the heap
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.heap_max">
<summary>
element of largest frequency
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.depth">
<summary>
Depth of each subtree used as tie breaker for trees of equal frequency
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.l_buf">
<summary>
index for literals or lengths
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.lit_bufsize">
<summary>
Size of match buffer for literals/lengths. There are 4 reasons for
limiting lit_bufsize to 64K:
- frequencies can be kept in 16 bit counters
- if compression is not successful for the first block, all input
data is still in the Window so we can still emit a stored block even
when input comes from standard input. (This can also be done for
all blocks if lit_bufsize is not greater than 32K.)
- if compression is not successful for a file smaller than 64K, we can
even emit a stored file instead of a stored block (saving 5 bytes).
This is applicable only for zip (not gzip or zlib).
- creating new Huffman trees less frequently may not provide fast
adaptation to changes in the input data statistics. (Take for
example a binary file with poorly compressible code followed by
a highly compressible string table.) Smaller buffer sizes give
fast adaptation but have of course the overhead of transmitting
trees more frequently.
- I can't count above 4
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.last_lit">
<summary>
running index in l_buf
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.d_buf">
<summary>
index of pendig_buf
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.opt_len">
<summary>
bit length of current block with optimal trees
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.static_len">
<summary>
bit length of current block with static trees
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.matches">
<summary>
number of string matches in current block
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.last_eob_len">
<summary>
bit length of EOB code for last block
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.bi_buf">
<summary>
Output buffer. bits are inserted starting at the bottom (least
significant bits).
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.bi_valid">
<summary>
Number of valid bits in bi_buf. All bits above the last valid bit
are always zero.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.#ctor">
<summary>
Default constructor
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.lm_init">
<summary>
Initialization
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.tr_init">
<summary>
Initialize the tree data structures for a new zlib stream.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.init_block">
<summary>
Initializes block
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.pqdownheap(System.Int16[],System.Int32)">
<summary>
Restore the heap property by moving down the tree starting at node k,
exchanging a node with the smallest of its two sons if necessary, stopping
when the heap property is re-established (each father smaller than its
two sons).
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.scan_tree(System.Int16[],System.Int32)">
<summary>
Scan a literal or distance tree to determine the frequencies of the codes
in the bit length tree.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.build_bl_tree">
<summary>
Construct the Huffman tree for the bit lengths and return the index in
bl_order of the last bit length code to send.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.send_all_trees(System.Int32,System.Int32,System.Int32)">
<summary>
Send the header for a block using dynamic Huffman trees: the counts, the
lengths of the bit length codes, the literal tree and the distance tree.
IN assertion: lcodes >= 257, dcodes >= 1, blcodes >= 4.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.send_tree(System.Int16[],System.Int32)">
<summary>
Send a literal or distance tree in compressed form, using the codes in
bl_tree.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.put_byte(System.Byte[],System.Int32,System.Int32)">
<summary>
Output a byte on the stream.
IN assertion: there is enough room in Pending_buf.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.put_byte(System.Byte)">
<summary>
Adds a byte to the buffer
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate._tr_align">
<summary>
Send one empty static block to give enough lookahead for inflate.
This takes 10 bits, of which 7 may remain in the bit buffer.
The current inflate code requires 9 bits of lookahead. If the
last two codes for the previous block (real code plus EOB) were coded
on 5 bits or less, inflate may have only 5+3 bits of lookahead to decode
the last real code. In this case we send two empty static blocks instead
of one. (There are no problems if the previous block is stored or fixed.)
To simplify the code, we assume the worst case of last real code encoded
on one bit only.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate._tr_tally(System.Int32,System.Int32)">
<summary>
Save the match info and tally the frequency counts. Return true if
the current block must be flushed.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.compress_block(System.Int16[],System.Int16[])">
<summary>
Send the block data compressed using the given Huffman trees
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.set_data_type">
<summary>
Set the data type to ASCII or BINARY, using a crude approximation:
binary if more than 20% of the bytes are &lt;= 6 or &gt;= 128, ascii otherwise.
IN assertion: the fields freq of dyn_ltree are set and the total of all
frequencies does not exceed 64K (to fit in an int on 16 bit machines).
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.bi_flush">
<summary>
Flush the bit buffer, keeping at most 7 bits in it.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.bi_windup">
<summary>
Flush the bit buffer and align the output on a byte boundary
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.copy_block(System.Int32,System.Int32,System.Boolean)">
<summary>
Copy a stored block, storing first the length and its
one's complement if requested.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.flush_block_only(System.Boolean)">
<summary>
Flushes block
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflate_stored(System.Int32)">
<summary>
Copy without compression as much as possible from the input stream, return
the current block state.
This function does not insert new strings in the dictionary since
uncompressible data is probably not useful. This function is used
only for the level=0 compression option.
NOTE: this function should be optimized to avoid extra copying from
Window to Pending_buf.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate._tr_stored_block(System.Int32,System.Int32,System.Boolean)">
<summary>
Send a stored block
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate._tr_flush_block(System.Int32,System.Int32,System.Boolean)">
<summary>
Determine the best encoding for the current block: dynamic trees, static
trees or store, and output the encoded block to the zip file.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.fill_window">
<summary>
Fill the Window when the lookahead becomes insufficient.
Updates strstart and lookahead.
IN assertion: lookahead less than MIN_LOOKAHEAD
OUT assertions: strstart less than or equal to window_size-MIN_LOOKAHEAD
At least one byte has been ReadPos, or _avail_in == 0; reads are
performed for at least two bytes (required for the zip translate_eol
option -- not supported here).
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflate_fast(System.Int32)">
<summary>
Compress as much as possible from the input stream, return the current
block state.
This function does not perform lazy evaluation of matches and inserts
new strings in the dictionary only for unmatched strings or for short
matches. It is used only for the fast compression options.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflate_slow(System.Int32)">
<summary>
Same as above, but achieves better compression. We use a lazy
evaluation for matches: a match is finally adopted only if there is
no better match at the next Window position.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.longest_match(System.Int32)">
<summary>
Finds the longest matching data part
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflateInit(ComponentAce.Compression.Libs.ZLib.ZStream,System.Int32,System.Int32)">
<summary>
Deflate algorithm initialization
</summary>
<param name="strm">ZStream object</param>
<param name="level">Compression level</param>
<param name="bits">Window bits</param>
<returns>A result code</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflateInit(ComponentAce.Compression.Libs.ZLib.ZStream,System.Int32)">
<summary>
Initializes deflate algorithm
</summary>
<param name="strm">ZStream object</param>
<param name="level">Compression level</param>
<returns>Operation result result code</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflateInit2(ComponentAce.Compression.Libs.ZLib.ZStream,System.Int32,System.Int32,System.Int32,System.Int32,ComponentAce.Compression.Libs.ZLib.CompressionStrategy)">
<summary>
Deflate algorithm initialization
</summary>
<param name="strm">ZStream object</param>
<param name="level">Compression level</param>
<param name="method">Compression method</param>
<param name="windowBits">Window bits</param>
<param name="memLevel">Memory level</param>
<param name="strategy">Compression strategy</param>
<returns>Operation result code</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflateReset(ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Resets the current state of deflate object
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflateEnd">
<summary>
Finish compression with deflate algorithm
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflateParams(ComponentAce.Compression.Libs.ZLib.ZStream,System.Int32,ComponentAce.Compression.Libs.ZLib.CompressionStrategy)">
<summary>
Sets deflate algorithm parameters
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflateSetDictionary(ComponentAce.Compression.Libs.ZLib.ZStream,System.Byte[],System.Int32)">
<summary>
Sets deflate dictionary
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.deflate(ComponentAce.Compression.Libs.ZLib.ZStream,ComponentAce.Compression.Libs.ZLib.FlushStrategy)">
<summary>
Performs data compression with the deflate algorithm
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.#cctor">
<summary>
Static constructor initializes config_table
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.Deflate.level">
<summary>
Compression level
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.Deflate.Pending">
<summary>
Number of bytes in the pending buffer
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.Deflate.Pending_buf">
<summary>
Output still pending
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.Deflate.Pending_out">
<summary>
Next pending byte to output to the stream
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.Deflate.NoHeader">
<summary>
suppress zlib header and adler32
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.Deflate.Config">
<summary>
Deflate algorithm configuration parameters class
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.Config.good_length">
<summary>
reduce lazy search above this match length
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.Config.max_lazy">
<summary>
do not perform lazy search above this match length
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Deflate.Config.nice_length">
<summary>
quit search above this match length
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Deflate.Config.#ctor(System.Int32,System.Int32,System.Int32,System.Int32,System.Int32)">
<summary>
Constructor which initializes class inner fields
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.mode">
<summary>
current inflate_block mode
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.left">
<summary>
if STORED, bytes left to copy
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.table">
<summary>
table lengths (14 bits)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.index">
<summary>
index into blens (or border)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.blens">
<summary>
bit lengths of codes
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.bb">
<summary>
bit length tree depth
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.tb">
<summary>
bit length decoding tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.codes">
<summary>
if CODES, current state
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.last">
<summary>
true if this block is the last block
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.bitk">
<summary>
bits in bit buffer
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.bitb">
<summary>
bit buffer
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.hufts">
<summary>
single malloc for tree space
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.window">
<summary>
sliding Window
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.end">
<summary>
one byte after sliding Window
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.read">
<summary>
Window ReadPos pointer
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.write">
<summary>
Window WritePos pointer
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.needCheck">
<summary>
need check
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfBlocks.check">
<summary>
check on output
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfBlocks.reset(ComponentAce.Compression.Libs.ZLib.ZStream,System.Int64[])">
<summary>
Resets this InfBlocks class instance
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfBlocks.proc(ComponentAce.Compression.Libs.ZLib.ZStream,System.Int32)">
<summary>
Block processing functions
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfBlocks.free(ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Frees inner buffers
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfBlocks.set_dictionary(System.Byte[],System.Int32,System.Int32)">
<summary>
Sets dictionary
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfBlocks.sync_point">
<summary>
Returns true if inflate is currently at the End of a block generated
by Z_SYNC_FLUSH or Z_FULL_FLUSH.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfBlocks.inflate_flush(ComponentAce.Compression.Libs.ZLib.ZStream,System.Int32)">
<summary>
copy as much as possible from the sliding Window to the output area
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.InfBlocks.Window">
<summary>
sliding window
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.InfBlocks.End">
<summary>
one byte after sliding Window
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.InfBlocks.ReadPos">
<summary>
Window ReadPos pointer
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.InfBlocks.WritePos">
<summary>
Window WritePos pointer
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.InfBlocks.BitK">
<summary>
bits in bit buffer
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.InfBlocks.BitB">
<summary>
bit buffer
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.InflateCodesMode">
<summary>
Inflate codes mode
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.InfCodes">
<summary>
This class is used by the InfBlocks class
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.mode">
<summary>
current inflate_codes mode
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.count">
<summary>
length
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.tree">
<summary>
pointer into tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.tree_index">
<summary>
current index of the tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.need">
<summary>
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.lbits">
<summary>
ltree bits decoded per branch
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.dbits">
<summary>
dtree bits decoded per branch
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.ltree">
<summary>
literal/length/eob tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.ltree_index">
<summary>
literal/length/eob tree index
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.dtree">
<summary>
distance tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InfCodes.dtree_index">
<summary>
distance tree index
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfCodes.#ctor(System.Int32,System.Int32,System.Int32[],System.Int32,System.Int32[],System.Int32,ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Constructor which takes literal, distance trees, corresponding bites decoded for branches, corresponding indexes and a ZStream object
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfCodes.#ctor(System.Int32,System.Int32,System.Int32[],System.Int32[],ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Constructor which takes literal, distance trees, corresponding bites decoded for branches and a ZStream object
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfCodes.proc(ComponentAce.Compression.Libs.ZLib.InfBlocks,ComponentAce.Compression.Libs.ZLib.ZStream,System.Int32)">
<summary>
Block processing method
</summary>
<param name="s">An instance of the InfBlocks class</param>
<param name="z">A ZStream object</param>
<param name="r">A result code</param>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfCodes.free(ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Frees allocated resources
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfCodes.inflate_fast(System.Int32,System.Int32,System.Int32[],System.Int32,System.Int32[],System.Int32,ComponentAce.Compression.Libs.ZLib.InfBlocks,ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Fast inflate procedure. Called with number of bytes left to WritePos in Window at least 258
(the maximum string length) and number of input bytes available
at least ten. The ten bytes are six bytes for the longest length/
distance pair plus four bytes for overloading the bit buffer.
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.InflateMode">
<summary>
This enumeration contains modes of inflate processing
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.METHOD">
<summary>
waiting for method byte
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.FLAG">
<summary>
waiting for flag byte
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.DICT4">
<summary>
four dictionary check bytes to go
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.DICT3">
<summary>
three dictionary check bytes to go
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.DICT2">
<summary>
two dictionary check bytes to go
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.DICT1">
<summary>
one dictionary check byte to go
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.DICT0">
<summary>
waiting for inflateSetDictionary
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.BLOCKS">
<summary>
decompressing blocks
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.CHECK4">
<summary>
four check bytes to go
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.CHECK3">
<summary>
three check bytes to go
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.CHECK2">
<summary>
two check bytes to go
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.CHECK1">
<summary>
one check byte to go
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.DONE">
<summary>
finished check, done
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.InflateMode.BAD">
<summary>
got an error--stay here
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Inflate.mode">
<summary>
current inflate mode
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Inflate.method">
<summary>
if FLAGS, method byte
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Inflate.was">
<summary>
computed check value
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Inflate.need">
<summary>
stream check value
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Inflate.marker">
<summary>
if BAD, inflateSync's marker bytes count
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Inflate.nowrap">
<summary>
flag for no wrapper
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Inflate.wbits">
<summary>
log2(Window size) (8..15, defaults to 15)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Inflate.blocks">
<summary>
current inflate_blocks state
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Inflate.inflateReset(ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Resets the Inflate algorithm
</summary>
<param name="z">A ZStream object</param>
<returns>A result code</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Inflate.inflateEnd(ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Finishes the inflate algorithm processing
</summary>
<param name="z">A ZStream object</param>
<returns>Operation result code</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Inflate.inflateInit(ComponentAce.Compression.Libs.ZLib.ZStream,System.Int32)">
<summary>
Initializes the inflate algorithm
</summary>
<param name="z">A ZStream object</param>
<param name="windowBits">Window size</param>
<returns>Operation result code</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Inflate.inflate(ComponentAce.Compression.Libs.ZLib.ZStream,ComponentAce.Compression.Libs.ZLib.FlushStrategy)">
<summary>
Runs inflate algorithm
</summary>
<param name="z">A ZStream object</param>
<param name="flush">Flush strategy</param>
<returns>Operation result code</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Inflate.inflateSetDictionary(ComponentAce.Compression.Libs.ZLib.ZStream,System.Byte[],System.Int32)">
<summary>
Sets dictionary for the inflate operation
</summary>
<param name="z">A ZStream object</param>
<param name="dictionary">An array of byte - dictionary</param>
<param name="dictLength">Dictionary length</param>
<returns>Operation result code</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Inflate.inflateSync(ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Inflate synchronization
</summary>
<param name="z">A ZStream object</param>
<returns>Operation result code</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Inflate.inflateSyncPoint(ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Returns true if inflate is currently at the End of a block generated
by Z_SYNC_FLUSH or Z_FULL_FLUSH. This function is used by one PPP
implementation to provide an additional safety check. PPP uses Z_SYNC_FLUSH
but removes the length bytes of the resulting empty stored block. When
decompressing, PPP checks that at the End of input packet, inflate is
waiting for these length bytes.
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.InfTreeUtil">
<summary>
Contains utility information for the InfTree class
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfTree.huft_build(System.Int32[],System.Int32,System.Int32,System.Int32,System.Int32[],System.Int32[],System.Int32[],System.Int32[],System.Int32[],System.Int32[],System.Int32[])">
<summary>
Given a list of code lengths and a maximum table size, make a set of
tables to decode that set of codes.
</summary>
<returns>Return (int)ZLibResultCode.Z_OK on success, (int)ZLibResultCode.Z_DATA_ERROR if the given code set is incomplete (the tables are still built in this case), (int)ZLibResultCode.Z_DATA_ERROR if the input is invalid (an over-subscribed set of lengths), or (int)ZLibResultCode.Z_DATA_ERROR if not enough memory.
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfTree.inflate_trees_bits(System.Int32[],System.Int32[],System.Int32[],System.Int32[],ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Build trees
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfTree.inflate_trees_dynamic(System.Int32,System.Int32,System.Int32[],System.Int32[],System.Int32[],System.Int32[],System.Int32[],System.Int32[],ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Builds dynamic trees
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.InfTree.inflate_trees_fixed(System.Int32[],System.Int32[],System.Int32[][],System.Int32[][],ComponentAce.Compression.Libs.ZLib.ZStream)">
<summary>
Build fixed trees
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.StaticTree.MAX_BL_BITS">
<summary>
Bit length codes must not exceed MAX_BL_BITS bits
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.Tree">
<summary>
This class represents a tree and is used in the Deflate class
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Tree.dyn_tree">
<summary>
The dynamic tree
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Tree.max_code">
<summary>
Largest code with non zero frequency
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.Tree.stat_desc">
<summary>
the corresponding static tree
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Tree.d_code(System.Int32)">
<summary>
Mapping from a distance to a distance code. dist is the distance - 1 and
must not have side effects. _dist_code[256] and _dist_code[257] are never
used.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Tree.gen_bitlen(ComponentAce.Compression.Libs.ZLib.Deflate)">
<summary>
Compute the optimal bit lengths for a tree and update the total bit length
for the current block.
IN assertion: the fields freq and dad are set, heap[heap_max] and
above are the tree nodes sorted by increasing frequency.
OUT assertions: the field count is set to the optimal bit length, the
array bl_count contains the frequencies for each bit length.
The length opt_len is updated; static_len is also updated if stree is
not null.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Tree.build_tree(ComponentAce.Compression.Libs.ZLib.Deflate)">
<summary>
Construct one Huffman tree and assigns the code bit strings and lengths.
Update the total bit length for the current block.
IN assertion: the field freq is set for all tree elements.
OUT assertions: the fields count and code are set to the optimal bit length
and corresponding code. The length opt_len is updated; static_len is
also updated if stree is not null. The field max_code is set.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Tree.gen_codes(System.Int16[],System.Int32,System.Int16[])">
<summary>
Generate the codes for a given tree and bit counts (which need not be
optimal).
IN assertion: the array bl_count contains the bit length statistics for
the given tree and the field count is set for all tree elements.
OUT assertion: the field code is set for all tree elements of non
zero code length.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.Tree.bi_reverse(System.Int32,System.Int32)">
<summary>
Reverse the first count bits of a code, using straightforward code (a faster
method would use a table)
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.Tree.DynTree">
<summary>
The dynamic tree
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.Tree.MaxCode">
<summary>
Largest code with non zero frequency
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.Tree.StatDesc">
<summary>
the corresponding static tree
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.ZLibCompressionLevel">
<summary>
Some constants for specifying compression levels. Methods which takes a compression level as a parameter expects an integer value from 0 to 9. You can either specify an integer value or use constants for some most widely used compression levels.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibCompressionLevel.Z_NO_COMPRESSION">
<summary>
No compression should be used at all.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibCompressionLevel.Z_BEST_SPEED">
<summary>
Minimal compression, but greatest speed.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibCompressionLevel.Z_BEST_COMPRESSION">
<summary>
Maximum compression, but slowest.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibCompressionLevel.Z_DEFAULT_COMPRESSION">
<summary>
Select default compression level (good compression, good speed).
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.CompressionStrategy">
<summary>
Compression strategies. The strategy parameter is used to tune the compression algorithm. The strategy parameter only affects the compression ratio but not the correctness of the compressed output even if it is not set appropriately.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.CompressionStrategy.Z_FILTERED">
<summary>
This strategy is designed for filtered data. Data which consists of mostly small values, with random distribution should use Z_FILTERED. With this strategy, less string matching is performed.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.CompressionStrategy.Z_HUFFMAN_ONLY">
<summary>
Z_HUFFMAN_ONLY forces Huffman encoding only (no string match)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.CompressionStrategy.Z_DEFAULT_STRATEGY">
<summary>
The default strategy is the most commonly used. With this strategy, string matching and huffman compression are balanced.
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.FlushStrategy">
<summary>
Flush strategies
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_NO_FLUSH">
<summary>
Do not internalFlush data, but just write data as normal to the output buffer. This is the normal way in which data is written to the output buffer.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_PARTIAL_FLUSH">
<summary>
Obsolete. You should use Z_SYNC_FLUSH instead.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_SYNC_FLUSH">
<summary>
All pending output is flushed to the output buffer and the output is aligned on a byte boundary, so that the decompressor can get all input data available so far.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FULL_FLUSH">
<summary>
All output is flushed as with Z_SYNC_FLUSH, and the compression state is reset so that decompression can restart from this point if previous compressed data has been damaged or if random access is desired. Using Z_FULL_FLUSH too often can seriously degrade the compression. ZLib_InflateSync will locate points in the compression string where a full has been performed.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FINISH">
<summary>
Notifies the module that the input has now been exhausted. Pending input is processed, pending output is flushed and calls return with Z_STREAM_END if there was enough output space.
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.ZLibResultCode">
<summary>
Results of operations in ZLib library
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK">
<summary>
No failure was encountered, the operation completed without problem.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_END">
<summary>
No failure was encountered, and the input has been exhausted.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_NEED_DICT">
<summary>
A preset dictionary is required for decompression of the data.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_ERRNO">
<summary>
An internal error occurred
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR">
<summary>
The stream structure was inconsistent
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_DATA_ERROR">
<summary>
Input data has been corrupted (for decompression).
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_MEM_ERROR">
<summary>
Memory allocation failed.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_BUF_ERROR">
<summary>
There was not enough space in the output buffer.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_VERSION_ERROR">
<summary>
The version supplied does not match that supported by the ZLib module.
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.DeflateState">
<summary>
States of deflate operation
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.BlockType">
<summary>
Data block types, i.e. binary or ascii text
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.ZLibUtil">
<summary>
Helper class
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibUtil.MAX_WBITS">
<summary>
Max Window size
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibUtil.PRESET_DICT">
<summary>
preset dictionary flag in zlib header
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibUtil.zLibBufSize">
<summary>
The size of the buffer
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibUtil.Z_DEFLATED">
<summary>
Deflate compression method index
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZLibUtil.DIST_CODE_LEN">
<summary>
see definition of array dist_code below
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.Identity(System.Int64)">
<summary>
This method returns the literal value received
</summary>
<param name="literal">The literal to return</param>
<returns>The received value</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.Identity(System.UInt64)">
<summary>
This method returns the literal value received
</summary>
<param name="literal">The literal to return</param>
<returns>The received value</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.Identity(System.Single)">
<summary>
This method returns the literal value received
</summary>
<param name="literal">The literal to return</param>
<returns>The received value</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.Identity(System.Double)">
<summary>
This method returns the literal value received
</summary>
<param name="literal">The literal to return</param>
<returns>The received value</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.URShift(System.Int32,System.Int32)">
<summary>
Performs an unsigned bitwise right shift with the specified number
</summary>
<param name="number">Number to operate on</param>
<param name="bits">Ammount of bits to shift</param>
<returns>The resulting number from the shift operation</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.URShift(System.Int32,System.Int64)">
<summary>
Performs an unsigned bitwise right shift with the specified number
</summary>
<param name="number">Number to operate on</param>
<param name="bits">Ammount of bits to shift</param>
<returns>The resulting number from the shift operation</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.URShift(System.Int64,System.Int32)">
<summary>
Performs an unsigned bitwise right shift with the specified number
</summary>
<param name="number">Number to operate on</param>
<param name="bits">Ammount of bits to shift</param>
<returns>The resulting number from the shift operation</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.URShift(System.Int64,System.Int64)">
<summary>
Performs an unsigned bitwise right shift with the specified number
</summary>
<param name="number">Number to operate on</param>
<param name="bits">Ammount of bits to shift</param>
<returns>The resulting number from the shift operation</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.ReadInput(System.IO.Stream,System.Byte[],System.Int32,System.Int32)">
<summary>Reads a number of characters from the current source Stream and writes the data to the target array at the specified index.</summary>
<param name="sourceStream">The source Stream to ReadPos from.</param>
<param name="target">Contains the array of characters ReadPos from the source Stream.</param>
<param name="start">The starting index of the target array.</param>
<param name="count">The maximum number of characters to ReadPos from the source Stream.</param>
<returns>The number of characters ReadPos. The number will be less than or equal to count depending on the data available in the source Stream. Returns -1 if the End of the stream is reached.</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.ReadInput(System.IO.TextReader,System.Byte[],System.Int32,System.Int32)">
<summary>Reads a number of characters from the current source TextReader and writes the data to the target array at the specified index.</summary>
<param name="sourceTextReader">The source TextReader to ReadPos from</param>
<param name="target">Contains the array of characteres ReadPos from the source TextReader.</param>
<param name="start">The starting index of the target array.</param>
<param name="count">The maximum number of characters to ReadPos from the source TextReader.</param>
<returns>The number of characters ReadPos. The number will be less than or equal to count depending on the data available in the source TextReader. Returns -1 if the End of the stream is reached.</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.ToByteArray(System.String)">
<summary>
Converts a string to an array of bytes
</summary>
<param name="sourceString">The string to be converted</param>
<returns>The new array of bytes</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.ToCharArray(System.Byte[])">
<summary>
Converts an array of bytes to an array of chars
</summary>
<param name="byteArray">The array of bytes to convert</param>
<returns>The new array of chars</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZLibUtil.CopyLargeArrayToSmall.CopyData">
<summary>
Copies large array which was passed as srcBuf to the Initialize method into the destination array which were passes as destBuff
</summary>
<returns>The number of bytes copied</returns>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.ZStream">
<summary>
ZStream is used to store user data to compress/decompress.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream.MAX_MEM_LEVEL">
<summary>
Maximum memory level
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._next_in">
<summary>
Next input byte array
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._next_in_index">
<summary>
Index of the first byte in the <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in">input array</see>.
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._avail_in">
<summary>
Number of bytes available at _next_in
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._total_in">
<summary>
total nb of input bytes ReadPos so far
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._next_out">
<summary>
Byte array for the next output block
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._next_out_index">
<summary>
Index of the first byte in the _next_out array
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._avail_out">
<summary>
Remaining free space at _next_out
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._total_out">
<summary>
Total number of bytes in output array
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._msg">
<summary>
A string to store operation result message (corresponding to result codes)
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._dstate">
<summary>
A deflate object to perform data compression
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._istate">
<summary>
Inflate object to perform data decompression
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream.data_type">
<summary>
Best guess about the data type: ascii or binary
</summary>
</member>
<member name="F:ComponentAce.Compression.Libs.ZLib.ZStream._adler">
<summary>
A checksum computed with Adler algorithm
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateInit">
<summary>
Initializes the internal stream state for decompression. The fields <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/>, <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/> must be
initialized before by the caller. If <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> is not <c>null</c> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/> is large
enough (the exact value depends on the compression method), <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateInit"/> determines the compression
method from the ZLib header and allocates all data structures accordingly; otherwise the allocation will be deferred
to the first call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>.
</summary>
<returns>
inflateInit returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if success, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_MEM_ERROR"/> if there was not enough memory,
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_VERSION_ERROR"/> if the ZLib library version is incompatible with the version assumed by the caller.
<see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.msg"/> is set to <c>null</c> if there is no error message. <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateInit"/> does not perform any decompression
apart from reading the ZLib header if present: this will be done by <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>. (So <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/>
may be modified, but <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/> are unchanged.)
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateInit(System.Int32)">
<summary>
This is another version of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateInit"/> with an extra parameter. The fields <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/>, <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/> must be
initialized before by the caller. If <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> is not <c>null</c> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/> is large enough
(the exact value depends on the compression method), <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateInit(System.Int32)"/> determines the compression method from
the ZLib header and allocates all data structures accordingly; otherwise the allocation will be deferred to the first
call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>.
</summary>
<param name="windowBits">The <c>windowBits</c> parameter is the base two logarithm of the maximum window size (the size of the history buffer).
It should be in the range <c>8..15</c> for this version of the library. The default value is 15 if <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateInit(System.Int32)"/> is used instead.
If a compressed stream with a larger window size is given as input, <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> will return with the error code
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_DATA_ERROR"/> instead of trying to allocate a larger window.</param>
<returns>
inflateInit returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if success, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_MEM_ERROR"/> if there was not enough memory,
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if a parameter is invalid (such as a negative memLevel). <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.msg"/> is set to null
if there is no error message. <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateInit(System.Int32)"/> does not perform any decompression apart from reading the ZLib header
if present: this will be done by <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>. (So <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/> may be modified,
but <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/> are unchanged.)
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)">
<summary>
<para>This method decompresses as much data as possible, and stops when the input buffer (<see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/>) becomes empty or
the output buffer (<see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/>) becomes full. It may some introduce some output latency (reading input without producing any output)
except when forced to flush. </para>
<para>The detailed semantics are as follows. <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> performs one or both of the following actions: </para>
<para>
<list type="bullet">
<item>Decompress more input starting at <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> and update <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/>
accordingly. If not all input can be processed (because there is not enough room in the output buffer), <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> is updated and
processing will resume at this point for the next call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>. </item>
<item>Provide more output starting at <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> and update <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/>
accordingly. <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> provides as much output as possible, until there is no more input data or no more space in
the output buffer (see below about the <paramref name="flush"/> parameter).</item>
</list>
</para>
</summary>
<param name="flush"><see cref="T:ComponentAce.Compression.Libs.ZLib.FlushStrategy">Flush strategy</see> to use.</param>
<remarks>
<para>Before the call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>, the application should ensure that at least one of the actions is possible, by providing
more input and/or consuming more output, and updating the next_* and avail_* values accordingly. The application can consume the uncompressed
output when it wants, for example when the output buffer is full (<c>avail_out == 0</c>), or after each call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>.
If <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> and with zero <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/>, it must be called again
after making room in the <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out">output buffer</see> because there might be more output pending. </para>
<para>If the parameter <paramref name="flush"/> is set to <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_SYNC_FLUSH"/>, <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> flushes
as much output as possible to the output buffer. The flushing behavior of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> is not specified for values of
the <paramref name="flush"/> parameter other than <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_SYNC_FLUSH"/> and <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FINISH"/>,
but the current implementation actually flushes as much output as possible anyway. </para>
<para><see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> should normally be called until it returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_END"/> or an error.
However if all decompression is to be performed in a single step (a single call of inflate), the parameter <paramref name="flush"/>
should be set to <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FINISH"/>. In this case all pending input is processed and all pending output is flushed;
<see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/> must be large enough to hold all the uncompressed data. (The size of the uncompressed data may have been
saved by the compressor for this purpose.) The next operation on this stream must be <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateEnd"/> to deallocate the decompression
state. The use of <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FINISH"/> is never required, but can be used to inform <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> that a faster
routine may be used for the single <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> call. </para>
<para>If a preset dictionary is needed at this point (see <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateSetDictionary(System.Byte[],System.Int32)"/>), <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> sets strm-adler
to the adler32 checksum of the dictionary chosen by the compressor and returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_NEED_DICT"/>; otherwise it
sets strm-&gt;adler to the adler32 checksum of all output produced so far (that is, <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.total_out"/> bytes) and returns
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/>, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_END"/> or an error code as described below. At the end of the stream,
<see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>) checks that its computed adler32 checksum is equal to that saved by the compressor and returns
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_END"/> only if the checksum is correct.</para>
</remarks>
<returns>
<see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if some progress has been made (more input processed or more output produced),
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_END"/> if the end of the compressed data has been reached and all uncompressed output has been produced,
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_NEED_DICT"/> if a preset dictionary is needed at this point, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_DATA_ERROR"/> if
the input data was corrupted (input stream not conforming to the ZLib format or incorrect adler32 checksum),
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if the stream structure was inconsistent (for example if <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> or
<see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> was <c>null</c>), <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_MEM_ERROR"/> if there was not enough memory,
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_BUF_ERROR"/> if no progress is possible or if there was not enough room in the output buffer
when <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FINISH"/> is used. In the <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_DATA_ERROR"/> case, the application
may then call <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateSync"/> to look for a good compression block.
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateEnd">
<summary>
All dynamically allocated data structures for this stream are freed. This function discards any unprocessed input and does not flush any
pending output.
</summary>
<returns>
inflateEnd returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if success, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/>
if the stream state was inconsistent. In the error case, msg may be set but then points to a static string (which must not be deallocated).
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateSync">
<summary>
Skips invalid compressed data until a full flush point (see the description of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)">deflate with Z_FULL_FLUSH</see>) can be found,
or until all available input is skipped. No output is provided.
</summary>
<returns>
<see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateSync"/> returns <seec ref="ZLibResultCode.Z_OK"/> if a full flush point has been found, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_BUF_ERROR"/>
if no more input was provided, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_DATA_ERROR"/> if no flush point has been found, or
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if the stream structure was inconsistent. In the success case, the application may save the current
current value of <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.total_in"/> which indicates where valid compressed data was found. In the error case, the application may repeatedly
call <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateSync"/>, providing more input each time, until success or end of the input data.
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateSetDictionary(System.Byte[],System.Int32)">
<summary>
Initializes the decompression dictionary from the given uncompressed byte sequence. This function must be called immediately after a call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> if this call returned <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_NEED_DICT"/>. The dictionary chosen by the compressor can be determined from the Adler32 value returned by this call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>. The compressor and decompresser must use exactly the same dictionary.
</summary>
<param name="dictionary">A byte array - a dictionary.</param>
<param name="dictLength">The length of the dictionary.</param>
<returns>
inflateSetDictionary returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if success, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if a parameter is invalid (such as <c>null</c> dictionary) or the stream state is inconsistent, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_DATA_ERROR"/> if the given dictionary doesn't match the expected one (incorrect Adler32 value). inflateSetDictionary does not perform any decompression: this will be done by subsequent calls of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>.
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateInit(System.Int32)">
<summary>
Initializes the internal stream state for compression.
</summary>
<param name="level">An integer value from 0 to 9 indicating the desired compression level.</param>
<returns>
deflateInit returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if success, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_MEM_ERROR"/> if there was not enough memory,
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if level is not a valid compression level. <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.msg"/> is set to <c>null</c> if there is
no error message. <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateInit(System.Int32)"/> does not perform any compression: this will be done by <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>.
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateInit(System.Int32,System.Int32)">
<summary>
Initializes the internal stream state for compression.
</summary>
<param name="level">An integer value from 0 to 9 indicating the desired compression level.</param>
<param name="bits"> The windowBits parameter is the base two logarithm of the window size (the size of the history buffer). It should be in the
range 8..15 for this version of the library. Larger values of this parameter result in better compression at the expense of memory usage.
The default value is 15 if deflateInit is used instead.</param>
<returns>
deflateInit returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if success, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_MEM_ERROR"/> if there was not enough memory,
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if level is not a valid compression level. <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.msg"/> is set to <c>null</c> if there
is no error message. <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateInit(System.Int32,System.Int32)"/> does not perform any compression: this will be done by <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>.
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)">
<summary>
<para>Deflate compresses as much data as possible, and stops when the <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in">input buffer</see> becomes empty or the
<see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out">output buffer</see> becomes full. It may introduce some output latency (reading input without producing any output)
except when forced to flush.</para>
<para>The detailed semantics are as follows. deflate performs one or both of the following actions:
<list type="bullet">
<item>Compress more input starting at <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> and update <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/> accordingly.
If not all input can be processed (because there is not enough room in the output buffer), <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/>
are updated and processing will resume at this point for the next call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>. </item>
<item>Provide more output starting at <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> and update <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> and <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/> accordingly.
This action is forced if the parameter flush is non zero. Forcing flush frequently degrades the compression ratio, so this parameter should
be set only when necessary (in interactive applications). Some output may be provided even if flush is not set.</item>
</list>
</para>
</summary>
<param name="flush">The <see cref="T:ComponentAce.Compression.Libs.ZLib.FlushStrategy">flush strategy</see> to use.</param>
<remarks>
<para>
Before the call of <seec ref="deflate"/>, the application should ensure that at least one of the actions is possible, by providing
more input and/or consuming more output, and updating <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/> or <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/> accordingly ; <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/>
should never be zero before the call. The application can consume the compressed output when it wants, for example when the output buffer is full
(<c>avail_out == 0</c>), or after each call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>. If <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/>
and with zero <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/>, it must be called again after making room in the output buffer because there might be more output pending.
</para>
<para>
If the parameter <paramref name="flush"/> is set to <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_SYNC_FLUSH"/>, all pending output is flushed to the
<see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out">output buffer</see> and the output is aligned on a byte boundary, so that the decompressor can get all input
data available so far. (In particular <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/> is zero after the call if enough output space has been provided before the call.)
Flushing may degrade compression for some compression algorithms and so it should be used only when necessary.
</para>
<para>
If flush is set to <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FULL_FLUSH"/>, all output is flushed as with <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_SYNC_FLUSH"/>,
and the compression state is reset so that decompression can restart from this point if previous compressed data has been damaged or if
random access is desired. Using <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FULL_FLUSH"/> too often can seriously degrade the compression.
</para>
</remarks>
<returns>
<para>
If deflate returns with <c><see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/> == 0</c>, this function must be called again with the same value of the flush
parameter and more output space (updated <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/>), until the flush is complete (<see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> returns with
non-zero <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/>).
</para>
<para>
If the parameter <paramref name="flush"/> is set to <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FINISH"/>, pending input is processed, pending
output is flushed and deflate returns with <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_END"/> if there was enough output space ;
if deflate returns with <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/>, this function must be called again with <see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FINISH"/>
and more output space (updated <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/>) but no more input data, until it returns with <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_END"/>
or an error. After deflate has returned <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_END"/>, the only possible operation on the stream is
<see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateEnd"/>. </para>
<para>
<see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FINISH"/> can be used immediately after <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateInit(System.Int32)"/> if all the compression is to be
done in a single step. In this case, avail_out must be at least 0.1% larger than avail_in plus 12 bytes. If deflate does not return
Z_STREAM_END, then it must be called again as described above.
</para>
<para>
<see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> sets strm-&gt; adler to the adler32 checksum of all input read so far (that is, <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.total_in"/> bytes).
</para>
<para>
<see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> may update data_type if it can make a good guess about the input data type (<see cref="T:ComponentAce.Compression.Libs.ZLib.BlockType">Z_ASCII or Z_BINARY</see>).
In doubt, the data is considered binary. This field is only for information purposes and does not affect the compression algorithm in any manner.
</para>
<para>
<see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if some progress has been made (more input processed or more output produced),
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_END"/> if all input has been consumed and all output has been produced (only when flush is set to
<see cref="F:ComponentAce.Compression.Libs.ZLib.FlushStrategy.Z_FINISH"/>), <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if the stream state was inconsistent (for example if
<see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> or <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> was <c>null</c>), <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_BUF_ERROR"/> if no progress is possible
(for example <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in"/> or <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/> was zero).
</para>
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateEnd">
<summary>
All dynamically allocated data structures for this stream are freed. This function discards any unprocessed input and does not flush any pending
output.
</summary>
<returns>
deflateEnd returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if success, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if the stream state was inconsistent,
<see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_DATA_ERROR"/> if the stream was freed prematurely (some input or output was discarded). In the error case,
<see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.msg"/> may be set but then points to a static string (which must not be deallocated).
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateParams(System.Int32,ComponentAce.Compression.Libs.ZLib.CompressionStrategy)">
<summary>
Dynamically update the compression level and compression strategy. The interpretation of level is as in <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateInit(System.Int32)"/>.
This can be used to switch between compression and straight copy of the input data, or to switch to a different kind of input data
requiring a different strategy. If the compression level is changed, the input available so far is compressed with the old level
(and may be flushed); the new level will take effect only at the next call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>
</summary>
<param name="level">An integer value indicating the desired compression level.</param>
<param name="strategy">A <see cref="T:ComponentAce.Compression.Libs.ZLib.FlushStrategy">flush strategy</see> to use.</param>
<remarks>
Before the call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateParams(System.Int32,ComponentAce.Compression.Libs.ZLib.CompressionStrategy)"/>, the stream state must be set as for a call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>, since the
currently available input may have to be compressed and flushed. In particular, <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/> must be non-zero.
</remarks>
<returns>
deflateParams returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if success, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if the source stream
state was inconsistent or if a parameter was invalid, <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_BUF_ERROR"/> if <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out"/> was zero.
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateSetDictionary(System.Byte[],System.Int32)">
<summary>
Initializes the compression dictionary from the given byte sequence without producing any compressed output. This function must be called
immediately after <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateInit(System.Int32)"/>, before any call of <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>. The compressor and decompressor must use
exactly the same dictionary (see <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.inflateSetDictionary(System.Byte[],System.Int32)"/>).
</summary>
<param name="dictionary">A byte array - a dictionary.</param>
<param name="dictLength">The length of the dictionary byte array</param>
<remarks>
<para>
The dictionary should consist of strings (byte sequences) that are likely to be encountered later in the data to be compressed,
with the most commonly used strings preferably put towards the end of the dictionary. Using a dictionary is most useful when the data
to be compressed is short and can be predicted with good accuracy; the data can then be compressed better than with the default empty dictionary.
</para>
<para>Depending on the size of the compression data structures selected by <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateInit(System.Int32)"/>, a part of the dictionary may
in effect be discarded, for example if the dictionary is larger than the window size in <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>. Thus the strings most likely
to be useful should be put at the end of the dictionary, not at the front.</para>
<para>Upon return of this function, adler is set to the Adler32 value of the dictionary; the decompresser may later use this value to determine
which dictionary has been used by the compressor. (The Adler32 value applies to the whole dictionary even if only a subset of the dictionary
is actually used by the compressor.)</para>
</remarks>
<returns>
deflateSetDictionary returns <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_OK"/> if success, or <see cref="F:ComponentAce.Compression.Libs.ZLib.ZLibResultCode.Z_STREAM_ERROR"/> if a parameter
is invalid (such as <c>null</c> dictionary) or the stream state is inconsistent (for example if <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> has already been
called for this stream or if the compression method is bsort). <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflateSetDictionary(System.Byte[],System.Int32)"/> does not perform any compression:
this will be done by <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/>.
</returns>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.flush_pending">
<summary>
Flush as much pending output as possible. All <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> output goes through this function so some applications may wish to
modify it to avoid allocating a large <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> buffer and copying into it.
</summary>
<seealso cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.read_buf(System.Byte[],System.Int32,System.Int32)"/>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.read_buf(System.Byte[],System.Int32,System.Int32)">
<summary>
Read a new buffer from the current input stream, update the adler32 and total number of bytes read. All <see cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.deflate(ComponentAce.Compression.Libs.ZLib.FlushStrategy)"/> input goes
through this function so some applications may wish to modify it to avoid allocating a large <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in"/> buffer and copying from it.
</summary>
<seealso cref="M:ComponentAce.Compression.Libs.ZLib.ZStream.flush_pending"/>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStream.free">
<summary>
Frees all inner <see cref="T:ComponentAce.Compression.Libs.ZLib.ZStream"/> buffers.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.adler">
<summary>
Adler-32 value for uncompressed data processed so far.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.Data_type">
<summary>
Best guess about the data type: ascii or binary
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in">
<summary>
Gets/Sets the next input byte array.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in_index">
<summary>
Index of the first byte in the <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in">input array</see>.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_in">
<summary>
Gets/Sets the number of bytes available in the <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in">input buffer</see>.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.total_in">
<summary>
Gets/Sets the total number of bytes in the <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_in">input buffer</see>.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out">
<summary>
Gets/Sets the buffer for the next output data.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out_index">
<summary>
Gets/Sets the index of the first byte in the <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> byte array to write to.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.avail_out">
<summary>
Gets/Sets the remaining free space in the <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out"/> buffer.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.total_out">
<summary>
Gets/Sets the total number of bytes in the <see cref="P:ComponentAce.Compression.Libs.ZLib.ZStream.next_out">output array</see>.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.msg">
<summary>
Gets sets the last error message occurred during class operations.
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.dstate">
<summary>
A deflate object to perform data compression
</summary>
</member>
<member name="P:ComponentAce.Compression.Libs.ZLib.ZStream.istate">
<summary>
Inflate object to perform data decompression
</summary>
</member>
<member name="T:ComponentAce.Compression.Libs.ZLib.ZStreamException">
<summary>
Exceptions that occur in ZStream
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStreamException.#ctor">
<summary>
Default constructor.
</summary>
</member>
<member name="M:ComponentAce.Compression.Libs.ZLib.ZStreamException.#ctor(System.String)">
<summary>
Constructor which takes one parameter - an error message
</summary>
</member>
<member name="M:IronPython.Modules.PythonCodecs.charmap_build(System.String)">
<summary>
Creates an optimized encoding mapping that can be consumed by an optimized version of charmap_encode.
</summary>
</member>
<member name="M:IronPython.Modules.PythonCodecs.charmap_decode(System.String,System.String,System.String)">
<summary>
Decodes the input string using the provided string mapping.
</summary>
</member>
<member name="M:IronPython.Modules.PythonCodecs.charmap_encode(System.String,System.String,IronPython.Modules.PythonCodecs.EncodingMap)">
<summary>
Encodes the input string with the specified optimized encoding map.
</summary>
</member>
<member name="T:IronPython.Modules.PythonCodecs.EncodingMap">
<summary>
Optimied encoding mapping that can be consumed by charmap_encode.
</summary>
</member>
<member name="T:IronPython.Modules.ModuleOps">
<summary>
Provides helper functions which need to be called from generated code to implement various
portions of modules.
</summary>
</member>
<member name="M:IronPython.Modules.PythonIOModule.GetBytes(System.Object,System.String)">
<summary>
Convert string or bytes into bytes
</summary>
</member>
<member name="M:IronPython.Modules.PythonIOModule.GetBytes(System.Object)">
<summary>
Convert most bytearray-like objects into IList of byte
</summary>
</member>
<member name="T:IronPython.Modules.PythonIOModule.BytesIO">
<summary>
BytesIO([initializer]) -> object
Create a buffered I/O implementation using an in-memory bytes
buffer, ready for reading and writing.
</summary>
</member>
<member name="M:IronPython.Modules.PythonIOModule.BytesIO.close(IronPython.Runtime.CodeContext)">
<summary>
close() -> None. Disable all I/O operations.
</summary>
</member>
<member name="M:IronPython.Modules.PythonIOModule.BytesIO.getvalue">
<summary>
getvalue() -> bytes.
Retrieve the entire contents of the BytesIO object.
</summary>
</member>
<member name="P:IronPython.Modules.PythonIOModule.BytesIO.closed">
<summary>
True if the file is closed.
</summary>
</member>
<member name="M:IronPython.Modules.PythonIOModule.TextIOWrapper.ReadChunk(IronPython.Runtime.CodeContext)">
<summary>
Read and decode the next chunk from the buffered reader. Returns true if EOF was
not reached. Places decoded string in _decodedChars.
</summary>
</member>
<member name="M:IronPython.Modules.PythonIOModule.FileIO.StandardizeMode(System.String)">
<summary>
Remove all 'b's from mode string to simplify parsing
</summary>
</member>
<member name="M:IronPython.Modules.PythonCollections.deque.WalkDeque(IronPython.Modules.PythonCollections.deque.DequeWalker)">
<summary>
Walks the queue calling back to the specified delegate for
each populated index in the queue.
</summary>
</member>
<member name="M:IronPython.Modules.PythonCopyReg.EnsureCallable(IronPython.Runtime.CodeContext,System.Object,System.String)">
<summary>
Throw TypeError with a specified message if object isn't callable.
</summary>
</member>
<member name="M:IronPython.Modules.PythonCopyReg.GetCode(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Convert object to ushort, throwing ValueError on overflow.
</summary>
</member>
<member name="T:IronPython.Modules.PythonPickle.FileInput">
<summary>
Interface for "file-like objects" that implement the protocol needed by load() and friends.
This enables the creation of thin wrappers that make fast .NET types and slow Python types look the same.
</summary>
</member>
<member name="T:IronPython.Modules.PythonPickle.FileOutput">
<summary>
Interface for "file-like objects" that implement the protocol needed by dump() and friends.
This enables the creation of thin wrappers that make fast .NET types and slow Python types look the same.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.SaveObject(IronPython.Modules.PythonPickle.PicklerObject,IronPython.Runtime.CodeContext,System.Object)">
<summary>
Call the appropriate reduce method for obj and pickle the object using
the resulting data. Use the first available of
copy_reg.dispatch_table[type(obj)], obj.__reduce_ex__, and obj.__reduce__.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.SaveReduce(IronPython.Runtime.CodeContext,System.Object,System.Object,System.Object,System.Object,System.Object,System.Object,System.Object)">
<summary>
Pickle the result of a reduce function.
Only context, obj, func, and reduceCallable are required; all other arguments may be null.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteFloatAsString(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Write value in pickle decimalnl_short format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteFloat64(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Write value in pickle float8 format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteUInt8(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Write value in pickle uint1 format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteUInt16(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Write value in pickle uint2 format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteInt32(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Write value in pickle int4 format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteIntAsString(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Write value in pickle decimalnl_short format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteIntAsString(IronPython.Runtime.CodeContext,System.Int32)">
<summary>
Write value in pickle decimalnl_short format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteLongAsString(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Write value in pickle decimalnl_long format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteUnicodeStringRaw(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Write value in pickle unicodestringnl format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteUnicodeStringUtf8(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Write value in pickle unicodestring4 format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.WriteStringPair(IronPython.Runtime.CodeContext,System.Object,System.Object)">
<summary>
Write value in pickle stringnl_noescape_pair format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.IsUInt8(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Return true if value is appropriate for formatting in pickle uint1 format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.IsUInt16(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Return true if value is appropriate for formatting in pickle uint2 format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.IsInt32(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Return true if value is appropriate for formatting in pickle int4 format.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.BatchAppends(IronPython.Runtime.CodeContext,System.Collections.IEnumerator)">
<summary>
Emit a series of opcodes that will set append all items indexed by iter
to the object at the top of the stack. Use APPENDS if possible, but
append no more than BatchSize items at a time.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.BatchSetItems(IronPython.Runtime.CodeContext,IronPython.Runtime.PythonDictionary)">
<summary>
Emit a series of opcodes that will set all (key, value) pairs indexed by
iter in the object at the top of the stack. Use SETITEMS if possible,
but append no more than BatchSize items at a time.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.BatchSetItems(IronPython.Runtime.CodeContext,System.Collections.IEnumerator)">
<summary>
Emit a series of opcodes that will set all (key, value) pairs indexed by
iter in the object at the top of the stack. Use SETITEMS if possible,
but append no more than BatchSize items at a time.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.PicklerObject.FindModuleForGlobal(IronPython.Runtime.CodeContext,System.Object,System.Object)">
<summary>
Find the module for obj and ensure that obj is reachable in that module by the given name.
Throw PicklingError if any of the following are true:
- The module couldn't be determined.
- The module couldn't be loaded.
- The given name doesn't exist in the module.
- The given name is a different object than obj.
Otherwise, return the name of the module.
To determine which module obj lives in, obj.__module__ is used if available. The
module named by obj.__module__ is loaded if needed. If obj has no __module__
attribute, then each loaded module is searched. If a loaded module has an
attribute with the given name, and that attribute is the same object as obj,
then that module is used.
</summary>
</member>
<member name="M:IronPython.Modules.PythonPickle.UnpicklerObject.SetItems(IronPython.Runtime.PythonDictionary,System.Int32)">
<summary>
Interpret everything from markIndex to the top of the stack as a sequence
of key, value, key, value, etc. Set dict[key] = value for each. Pop
everything from markIndex up when done.
</summary>
</member>
<member name="M:IronPython.Modules.PythonDateTime.date.CheckType(System.Object,System.Boolean)">
<summary>
Used to check the type to see if we can do a comparison. Returns true if we can
or false if we should return NotImplemented. May throw if the type's really wrong.
</summary>
</member>
<member name="M:IronPython.Modules.PythonDateTime.time.CompareTo(System.Object)">
<summary>
Helper function for doing the comparisons. time has no __cmp__ method
</summary>
</member>
<member name="T:IronPython.Modules.PythonIterTools.IterBase">
<summary>
Base class used for iterator wrappers.
</summary>
</member>
<member name="M:IronPython.Modules.PythonCsvModule.GetDialects(IronPython.Runtime.CodeContext)">
<summary>
Returns the dialects from the code context.
</summary>
<param name="context"></param>
<returns></returns>
</member>
<member name="M:IronPython.Modules.PythonLocale.LocaleInfo.CreateConventionsDict">
<summary>
Popupates the given directory w/ the locale information from the given
CultureInfo.
</summary>
</member>
<member name="M:IronPython.Modules.PythonMath.erf(System.Double)">
<summary>
Error function on real values
</summary>
</member>
<member name="M:IronPython.Modules.PythonMath.erfc(System.Double)">
<summary>
Complementary error function on real values: erfc(x) = 1 - erf(x)
</summary>
</member>
<member name="M:IronPython.Modules.PythonMath.gamma(System.Double)">
<summary>
Gamma function on real values
</summary>
</member>
<member name="M:IronPython.Modules.PythonMath.lgamma(System.Double)">
<summary>
Natural log of absolute value of Gamma function
</summary>
</member>
<member name="M:IronPython.Modules.PythonNT.access(IronPython.Runtime.CodeContext,System.String,System.Int32)">
<summary>
Checks for the specific permissions, provided by the mode parameter, are available for the provided path. Permissions can be:
F_OK: Check to see if the file exists
R_OK | W_OK | X_OK: Check for the specific permissions. Only W_OK is respected.
</summary>
</member>
<member name="F:IronPython.Modules.PythonNT.environ">
<summary>
single instance of environment dictionary is shared between multiple runtimes because the environment
is shared by multiple runtimes.
</summary>
</member>
<member name="M:IronPython.Modules.PythonNT.lstat(System.String)">
<summary>
lstat(path) -> stat result
Like stat(path), but do not follow symbolic links.
</summary>
</member>
<member name="M:IronPython.Modules.PythonNT.spawnl(IronPython.Runtime.CodeContext,System.Int32,System.String,System.Object[])">
<summary>
spawns a new process.
If mode is nt.P_WAIT then then the call blocks until the process exits and the return value
is the exit code.
Otherwise the call returns a handle to the process. The caller must then call nt.waitpid(pid, options)
to free the handle and get the exit code of the process. Failure to call nt.waitpid will result
in a handle leak.
</summary>
</member>
<member name="M:IronPython.Modules.PythonNT.spawnle(IronPython.Runtime.CodeContext,System.Int32,System.String,System.Object[])">
<summary>
spawns a new process.
If mode is nt.P_WAIT then then the call blocks until the process exits and the return value
is the exit code.
Otherwise the call returns a handle to the process. The caller must then call nt.waitpid(pid, options)
to free the handle and get the exit code of the process. Failure to call nt.waitpid will result
in a handle leak.
</summary>
</member>
<member name="M:IronPython.Modules.PythonNT.spawnv(IronPython.Runtime.CodeContext,System.Int32,System.String,System.Object)">
<summary>
spawns a new process.
If mode is nt.P_WAIT then then the call blocks until the process exits and the return value
is the exit code.
Otherwise the call returns a handle to the process. The caller must then call nt.waitpid(pid, options)
to free the handle and get the exit code of the process. Failure to call nt.waitpid will result
in a handle leak.
</summary>
</member>
<member name="M:IronPython.Modules.PythonNT.spawnve(IronPython.Runtime.CodeContext,System.Int32,System.String,System.Object,System.Object)">
<summary>
spawns a new process.
If mode is nt.P_WAIT then then the call blocks until the process exits and the return value
is the exit code.
Otherwise the call returns a handle to the process. The caller must then call nt.waitpid(pid, options)
to free the handle and get the exit code of the process. Failure to call nt.waitpid will result
in a handle leak.
</summary>
</member>
<member name="M:IronPython.Modules.PythonNT.SetEnvironment(System.Collections.Specialized.StringDictionary,System.Object)">
<summary>
Copy elements from a Python mapping of dict environment variables to a StringDictionary.
</summary>
</member>
<member name="M:IronPython.Modules.PythonNT.ArgumentsToString(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Convert a sequence of args to a string suitable for using to spawn a process.
</summary>
</member>
<member name="T:IronPython.Modules.PythonRegex">
<summary>
Python regular expression module.
</summary>
</member>
<member name="M:IronPython.Modules.PythonRegex.PreParseRegex(IronPython.Runtime.CodeContext,System.String)">
<summary>
Preparses a regular expression text returning a ParsedRegex class
that can be used for further regular expressions.
</summary>
</member>
<member name="T:IronPython.Modules.PythonRegex.RE_Pattern">
<summary>
Compiled reg-ex pattern
</summary>
</member>
<member name="M:IronPython.Modules.PythonSelect.ProcessSocketSequence(IronPython.Runtime.CodeContext,System.Object,IronPython.Runtime.List@,System.Collections.Generic.Dictionary{System.Net.Sockets.Socket,System.Object}@)">
<summary>
Process a sequence of objects that are compatible with ObjectToSocket(). Return two
things as out params: an in-order List of sockets that correspond to the original
objects in the passed-in sequence, and a mapping of these socket objects to their
original objects.
The socketToOriginal mapping is generated because the CPython select module supports
passing to select either file descriptor numbers or an object with a fileno() method.
We try to be faithful to what was originally requested when we return.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSelect.ObjectToSocket(IronPython.Runtime.CodeContext,System.Object)">
<summary>
Return the System.Net.Sockets.Socket object that corresponds to the passed-in
object. obj can be a System.Net.Sockets.Socket, a PythonSocket.SocketObj, a
long integer (representing a socket handle), or a Python object with a fileno()
method (whose result is used to look up an existing PythonSocket.SocketObj,
which is in turn converted to a Socket.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.SignInsensitiveToInt32(System.Object)">
<summary>
Convert an object to a 32-bit integer. This adds two features to Converter.ToInt32:
1. Sign is ignored. For example, 0xffff0000 converts to 4294901760, where Convert.ToInt32
would throw because 0xffff0000 is less than zero.
2. Overflow exceptions are thrown. Converter.ToInt32 throws TypeError if x is
an integer, but is bigger than 32 bits. Instead, we throw OverflowException.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.SignInsensitiveToInt16(System.Object)">
<summary>
Convert an object to a 16-bit integer. This adds two features to Converter.ToInt16:
1. Sign is ignored. For example, 0xff00 converts to 65280, where Convert.ToInt16
would throw because signed 0xff00 is -256.
2. Overflow exceptions are thrown. Converter.ToInt16 throws TypeError if x is
an integer, but is bigger than 16 bits. Instead, we throw OverflowException.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.MakeException(IronPython.Runtime.CodeContext,System.Exception)">
<summary>
Return a standard socket exception (socket.error) whose message and error code come from a SocketException
This will eventually be enhanced to generate the correct error type (error, herror, gaierror) based on the error code.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.IPv6BytesToColonHex(System.Byte[])">
<summary>
Convert an IPv6 address byte array to a string in standard colon-hex notation.
The .NET IPAddress.ToString() method uses dotted-quad for the last 32 bits,
which differs from the normal Python implementation (but is allowed by the IETF);
this method returns the standard (no dotted-quad) colon-hex form.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.ConvertSpecialAddresses(System.String)">
<summary>
Handle conversion of "" to INADDR_ANY and "&lt;broadcast&gt;" to INADDR_BROADCAST.
Otherwise returns host unchanged.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.HostToAddress(IronPython.Runtime.CodeContext,System.String,System.Net.Sockets.AddressFamily)">
<summary>
Return the IP address associated with host, with optional address family checking.
host may be either a name or an IP address (in string form).
If family is non-null, a gaierror will be thrown if the host's address family is
not the same as the specified family. gaierror is also raised if the hostname cannot be
converted to an IP address (e.g. through a name lookup failure).
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.HostToAddresses(IronPython.Runtime.CodeContext,System.String,System.Net.Sockets.AddressFamily)">
<summary>
Return the IP address associated with host, with optional address family checking.
host may be either a name or an IP address (in string form).
If family is non-null, a gaierror will be thrown if the host's address family is
not the same as the specified family. gaierror is also raised if the hostname cannot be
converted to an IP address (e.g. through a name lookup failure).
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.RemoveLocalDomain(System.String)">
<summary>
Return fqdn, but with its domain removed if it's on the same domain as the local machine.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.TupleToEndPoint(IronPython.Runtime.CodeContext,IronPython.Runtime.PythonTuple,System.Net.Sockets.AddressFamily,System.String@)">
<summary>
Convert a (host, port) tuple [IPv4] (host, port, flowinfo, scopeid) tuple [IPv6]
to its corresponding IPEndPoint.
Throws gaierror if host is not a valid address.
Throws ArgumentTypeException if any of the following are true:
- address does not have exactly two elements
- address[0] is not a string
- address[1] is not an int
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.EndPointToTuple(System.Net.IPEndPoint)">
<summary>
Convert an IPEndPoint to its corresponding (host, port) [IPv4] or (host, port, flowinfo, scopeid) [IPv6] tuple.
Throws SocketException if the address family is other than IPv4 or IPv6.
</summary>
</member>
<member name="F:IronPython.Modules.PythonSocket.socket._handleToSocket">
<summary>
handleToSocket allows us to translate from Python's idea of a socket resource (file
descriptor numbers) to .NET's idea of a socket resource (System.Net.Socket objects).
In particular, this allows the select module to convert file numbers (as returned by
fileno()) and convert them to Socket objects so that it can do something useful with them.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.socket.HandleToSocket(System.Int64)">
<summary>
Return the internal System.Net.Sockets.Socket socket object associated with the given
handle (as returned by GetHandle()), or null if no corresponding socket exists. This is
primarily intended to be used by other modules (such as select) that implement
networking primitives. User code should not normally need to call this function.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.socket.#ctor(IronPython.Runtime.CodeContext,System.Net.Sockets.Socket)">
<summary>
Create a Python socket object from an existing .NET socket object
(like one returned from Socket.Accept())
</summary>
</member>
<member name="M:IronPython.Modules.PythonSocket.socket.Initialize(IronPython.Runtime.CodeContext,System.Net.Sockets.Socket)">
<summary>
Perform initialization common to all constructors
</summary>
</member>
<member name="T:IronPython.Modules.LocalOrArg">
<summary>
Wrapper class for emitting locals/variables during marshalling code gen.
</summary>
</member>
<member name="T:IronPython.Modules.MemoryHolder">
<summary>
A wrapper around allocated memory to ensure it gets released and isn't accessed
when it could be finalized.
</summary>
</member>
<member name="M:IronPython.Modules.MemoryHolder.#ctor(System.Int32)">
<summary>
Creates a new MemoryHolder and allocates a buffer of the specified size.
</summary>
</member>
<member name="M:IronPython.Modules.MemoryHolder.#ctor(System.IntPtr,System.Int32)">
<summary>
Creates a new MemoryHolder at the specified address which is not tracked
by us and we will never free.
</summary>
</member>
<member name="M:IronPython.Modules.MemoryHolder.#ctor(System.IntPtr,System.Int32,IronPython.Modules.MemoryHolder)">
<summary>
Creates a new MemoryHolder at the specified address which will keep alive the
parent memory holder.
</summary>
</member>
<member name="M:IronPython.Modules.MemoryHolder.AddObject(System.Object,System.Object)">
<summary>
Used to track the lifetime of objects when one memory region depends upon
another memory region. For example if you have an array of objects that
each have an element which has it's own lifetime the array needs to keep
the individual elements alive.
The keys used here match CPython's keys as tested by CPython's test_ctypes.
Typically they are a string which is the array index, "ffffffff" when
from_buffer is used, or when it's a simple type there's just a string
instead of the full dictionary - we store that under the key "str".
</summary>
</member>
<member name="M:IronPython.Modules.MemoryHolder.CopyFrom(System.IntPtr,System.IntPtr)">
<summary>
Copies the data in data into this MemoryHolder.
</summary>
</member>
<member name="M:IronPython.Modules.MemoryHolder.CopyTo(IronPython.Modules.MemoryHolder,System.Int32,System.Int32)">
<summary>
Copies memory from one location to another keeping the associated memory holders alive during the
operation.
</summary>
</member>
<member name="P:IronPython.Modules.MemoryHolder.UnsafeAddress">
<summary>
Gets the address of the held memory. The caller should ensure the MemoryHolder
is always alive as long as the address will continue to be accessed.
</summary>
</member>
<member name="P:IronPython.Modules.MemoryHolder.Objects">
<summary>
Gets a list of objects which need to be kept alive for this MemoryHolder to be
remain valid.
</summary>
</member>
<member name="T:IronPython.Modules.NativeFunctions">
<summary>
Native functions used for exposing ctypes functionality.
</summary>
</member>
<member name="M:IronPython.Modules.NativeFunctions.Calloc(System.IntPtr)">
<summary>
Allocates memory that's zero-filled
</summary>
</member>
<member name="M:IronPython.Modules.NativeFunctions.MemSet(System.IntPtr,System.Byte,System.IntPtr)">
<summary>
Helper function for implementing memset. Could be more efficient if we
could P/Invoke or call some otherwise native code to do this.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes">
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
<summary>
Provides support for interop with native code from Python code.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.Cast(System.IntPtr,System.IntPtr,System.IntPtr)">
<summary>
Implementation of our cast function. data is marshalled as a void*
so it ends up as an address. obj and type are marshalled as an object
so we need to unmarshal them.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.POINTER(IronPython.Runtime.CodeContext,IronPython.Runtime.Types.PythonType)">
<summary>
Returns a new type which represents a pointer given the existing type.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.PyObj_FromPtr(System.IntPtr)">
<summary>
Converts an address acquired from PyObj_FromPtr or that has been
marshaled as type 'O' back into an object.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.PyObj_ToPtr(System.Object)">
<summary>
Converts an object into an opaque address which can be handed out to
managed code.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.Py_DECREF(System.Object)">
<summary>
Decreases the ref count on an object which has been increased with
Py_INCREF.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.Py_INCREF(System.Object)">
<summary>
Increases the ref count on an object ensuring that it will not be collected.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.addressof(IronPython.Modules.CTypes.CData)">
<summary>
returns address of C instance internal buffer.
It is the callers responsibility to ensure that the provided instance will
stay alive if memory in the resulting address is to be used later.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.alignment(IronPython.Runtime.Types.PythonType)">
<summary>
Gets the required alignment of the given type.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.alignment(System.Object)">
<summary>
Gets the required alignment of an object.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.pointer(IronPython.Runtime.CodeContext,IronPython.Modules.CTypes.CData)">
<summary>
Returns a pointer instance for the given CData
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.GetMarshalTypeFromSize(System.Int32)">
<summary>
Given a specific size returns a .NET type of the equivalent size that
we can use when marshalling these values across calls.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.GetFieldInfo(IronPython.Modules.CTypes.INativeType,System.Object,System.String@,IronPython.Modules.CTypes.INativeType@,System.Nullable{System.Int32}@)">
<summary>
Shared helper between struct and union for getting field info and validating it.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.CheckBits(IronPython.Modules.CTypes.INativeType,IronPython.Runtime.PythonTuple)">
<summary>
Verifies that the provided bit field settings are valid for this type.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.GetFieldsList(System.Object)">
<summary>
Shared helper to get the _fields_ list for struct/union and validate it.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.StringAt(System.IntPtr,System.Int32)">
<summary>
Helper function for translating from memset to NT's FillMemory API.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.WStringAt(System.IntPtr,System.Int32)">
<summary>
Helper function for translating from memset to NT's FillMemory API.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.EmitCDataCreation(IronPython.Modules.CTypes.INativeType,System.Reflection.Emit.ILGenerator,System.Collections.Generic.List{System.Object},System.Int32)">
<summary>
Emits the marshalling code to create a CData object for reverse marshalling.
</summary>
</member>
<member name="P:IronPython.Modules.CTypes._cast_addr">
<summary>
Gets a function which casts the specified memory. Because this is used only
w/ Python API we use a delegate as the return type instead of an actual address.
</summary>
</member>
<member name="P:IronPython.Modules.CTypes.DynamicModule">
<summary>
Gets the ModuleBuilder used to generate our unsafe call stubs into.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes.SimpleTypeKind">
<summary>
The enum used for tracking the various ctypes primitive types.
</summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.Char">
<summary> 'c' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.SignedByte">
<summary> 'b' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.UnsignedByte">
<summary> 'B' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.SignedShort">
<summary> 'h' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.UnsignedShort">
<summary> 'H' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.SignedInt">
<summary> 'i' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.UnsignedInt">
<summary> 'I' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.SignedLong">
<summary> 'l' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.UnsignedLong">
<summary> 'L' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.Single">
<summary> 'f' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.Double">
<summary> 'd', 'g' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.SignedLongLong">
<summary> 'q' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.UnsignedLongLong">
<summary> 'Q' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.Object">
<summary> 'O' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.Pointer">
<summary> 'P' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.CharPointer">
<summary> 'z' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.WCharPointer">
<summary> 'Z' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.WChar">
<summary> 'u' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.Boolean">
<summary> '?' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.VariantBool">
<summary> 'v' </summary>
</member>
<member name="F:IronPython.Modules.CTypes.SimpleTypeKind.BStr">
<summary> 'X' </summary>
</member>
<member name="T:IronPython.Modules.CTypes.CData">
<summary>
Base class for all ctypes interop types.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes.ArrayType">
<summary>
The meta class for ctypes array instances.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes.INativeType">
<summary>
Common functionality that all of the meta classes provide which is part of
our implementation. This is used to implement the serialization/deserialization
of values into/out of memory, emit the marshalling logic for call stubs, and
provide common information (size/alignment) for the types.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.INativeType.GetValue(IronPython.Modules.MemoryHolder,System.Object,System.Int32,System.Boolean)">
<summary>
Deserialized the value of this type from the given address at the given
offset. Any new objects which are created will keep the provided
MemoryHolder alive.
raw determines if the cdata is returned or if the primitive value is
returned. This is only applicable for subtypes of simple cdata types.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.INativeType.SetValue(IronPython.Modules.MemoryHolder,System.Int32,System.Object)">
<summary>
Serializes the provided value into the specified address at the given
offset.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.INativeType.GetNativeType">
<summary>
Gets the .NET type which is used when calling or returning the value
from native code.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.INativeType.GetPythonType">
<summary>
Gets the .NET type which the native type is converted into when going to Python
code. This is usually int, BigInt, double, object, or a CData type.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.INativeType.EmitMarshalling(System.Reflection.Emit.ILGenerator,IronPython.Modules.LocalOrArg,System.Collections.Generic.List{System.Object},System.Int32)">
<summary>
Emits marshalling of an object from Python to native code. This produces the
native type from the Python type.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.INativeType.EmitReverseMarshalling(System.Reflection.Emit.ILGenerator,IronPython.Modules.LocalOrArg,System.Collections.Generic.List{System.Object},System.Int32)">
<summary>
Emits marshalling from native code to Python code This produces the python type
from the native type. This is used for return values and parameters
to Python callable objects that are passed back out to native code.
</summary>
</member>
<member name="P:IronPython.Modules.CTypes.INativeType.Size">
<summary>
Gets the native size of the type
</summary>
</member>
<member name="P:IronPython.Modules.CTypes.INativeType.Alignment">
<summary>
Gets the required alignment for the type
</summary>
</member>
<member name="P:IronPython.Modules.CTypes.INativeType.TypeFormat">
<summary>
Returns a string which describes the type. Used for _buffer_info implementation which
only exists for testing purposes.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.ArrayType.from_param(System.Object)">
<summary>
Converts an object into a function call parameter.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes._CFuncPtr.#ctor(IronPython.Runtime.PythonTuple)">
<summary>
Creates a new CFuncPtr object from a tuple. The 1st element of the
tuple is the ordinal or function name. The second is an object with
a _handle property. The _handle property is the handle of the module
from which the function will be loaded.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes._CFuncPtr.#ctor(System.Int32,System.String)">
<summary>
Creates a new CFuncPtr which calls a COM method.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes._CFuncPtr.#ctor(System.Int32)">
<summary>
Creates a new CFuncPtr with the specfied address.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes._CFuncPtr.#ctor(System.Numerics.BigInteger)">
<summary>
Creates a new CFuncPtr with the specfied address.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes._CFuncPtr.Meta.AddKeepAlives(IronPython.Modules.CTypes._CFuncPtr.Meta.ArgumentMarshaller[],System.Collections.Generic.List{System.Linq.Expressions.Expression})">
<summary>
we need to keep alive any methods which have arguments for the duration of the
call. Otherwise they could be collected on the finalizer thread before we come back.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes._CFuncPtr.Meta.CreateInteropInvoker(System.Runtime.InteropServices.CallingConvention,IronPython.Modules.CTypes._CFuncPtr.Meta.ArgumentMarshaller[],IronPython.Modules.CTypes.INativeType,System.Boolean,System.Collections.Generic.List{System.Object})">
<summary>
Creates a method for calling with the specified signature. The returned method has a signature
of the form:
(IntPtr funcAddress, arg0, arg1, ..., object[] constantPool)
where IntPtr is the address of the function to be called. The arguments types are based upon
the types that the ArgumentMarshaller requires.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes._CFuncPtr.Meta.ArgumentMarshaller">
<summary>
Base class for marshalling arguments from the user provided value to the
call stub. This class provides the logic for creating the call stub and
calling it.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes._CFuncPtr.Meta.ArgumentMarshaller.EmitCallStubArgument(System.Reflection.Emit.ILGenerator,System.Int32,System.Collections.Generic.List{System.Object},System.Int32)">
<summary>
Emits the IL to get the argument for the call stub generated into
a dynamic method.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes._CFuncPtr.Meta.ArgumentMarshaller.GetKeepAlive">
<summary>
Gets an expression which keeps alive the argument for the duration of the call.
Returns null if a keep alive is not necessary.
</summary>
</member>
<member name="P:IronPython.Modules.CTypes._CFuncPtr.Meta.ArgumentMarshaller.ArgumentExpression">
<summary>
Gets the expression used to provide the argument. This is the expression
from an incoming DynamicMetaObject.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes._CFuncPtr.Meta.PrimitiveMarshaller">
<summary>
Provides marshalling of primitive values when the function type
has no type information or when the user has provided us with
an explicit cdata instance.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes._CFuncPtr.Meta.CDataMarshaller">
<summary>
Provides marshalling for when the function type provide argument information.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes._CFuncPtr.Meta.NativeArgumentMarshaller">
<summary>
Provides marshalling for when the user provides a native argument object
(usually gotten by byref or pointer) and the function type has no type information.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes.CFuncPtrType">
<summary>
The meta class for ctypes function pointer instances.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.CFuncPtrType.from_param(System.Object)">
<summary>
Converts an object into a function call parameter.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes.Field">
<summary>
Fields are created when a Structure is defined and provide
introspection of the structure.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.Field.ExtractBits(System.Object)">
<summary>
Called for fields which have been limited to a range of bits. Given the
value for the full type this extracts the individual bits.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.Field.SetBitsValue(IronPython.Modules.MemoryHolder,System.Int32,System.Object)">
<summary>
Called for fields which have been limited to a range of bits. Sets the
specified value into the bits for the field.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes.PointerType">
<summary>
The meta class for ctypes pointers.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.PointerType.from_param(IronPython.Modules.CTypes.Pointer)">
<summary>
Converts an object into a function call parameter.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.PointerType.from_address(System.Object)">
<summary>
Access an instance at the specified address
</summary>
</member>
<member name="T:IronPython.Modules.CTypes.SimpleType">
<summary>
The meta class for ctypes simple data types. These include primitives like ints,
floats, etc... char/wchar pointers, and untyped pointers.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.SimpleType.from_param(System.Object)">
<summary>
Converts an object into a function call parameter.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.SimpleType.ReadChar(IronPython.Modules.MemoryHolder,System.Int32)">
<summary>
Helper function for reading char/wchar's. This is used for reading from
arrays and pointers to avoid creating lots of 1-char strings.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes.StructType">
<summary>
Meta class for structures. Validates _fields_ on creation, provides factory
methods for creating instances from addresses and translating to parameters.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.StructType.from_param(System.Object)">
<summary>
Converts an object into a function call parameter.
Structures just return themselves.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.StructType.EnsureSizeAndAlignment">
<summary>
If our size/alignment hasn't been initialized then grabs the size/alignment
from all of our base classes. If later new _fields_ are added we'll be
initialized and these values will be replaced.
</summary>
</member>
<member name="T:IronPython.Modules.CTypes._Structure">
<summary>
Base class for data structures. Subclasses can define _fields_ which
specifies the in memory layout of the values. Instances can then
be created with the initial values provided as the array. The values
can then be accessed from the instance by field name. The value can also
be passed to a foreign C API and the type can be used in other structures.
class MyStructure(Structure):
_fields_ = [('a', c_int), ('b', c_int)]
MyStructure(1, 2).a
MyStructure()
class MyOtherStructure(Structure):
_fields_ = [('c', MyStructure), ('b', c_int)]
MyOtherStructure((1, 2), 3)
MyOtherStructure(MyStructure(1, 2), 3)
</summary>
</member>
<member name="T:IronPython.Modules.CTypes.UnionType">
<summary>
The meta class for ctypes unions.
</summary>
</member>
<member name="M:IronPython.Modules.CTypes.UnionType.from_param(System.Object)">
<summary>
Converts an object into a function call parameter.
</summary>
</member>
<member name="T:IronPython.Modules.PythonStruct.FormatType">
<summary>
Enum which specifies the format type for a compiled struct
</summary>
</member>
<member name="T:IronPython.Modules.PythonStruct.Format">
<summary>
Struct used to store the format and the number of times it should be repeated.
</summary>
</member>
<member name="M:IronPython.Modules.PythonThread.interrupt_main(IronPython.Runtime.CodeContext)">
<summary>
Stops execution of Python or other .NET code on the main thread. If the thread is
blocked in native code the thread will be interrupted after it returns back to Python
or other .NET code.
</summary>
</member>
<member name="T:IronPython.Modules.PythonThread._local.ThreadLocalDictionaryStorage">
<summary>
Provides a dictionary storage implementation whose storage is local to
the thread.
</summary>
</member>
<member name="T:IronPython.Modules.PythonTime.FoundDateComponents">
<summary>
Represents the date components that we found while parsing the date. Used for zeroing out values
which have different defaults from CPython. Currently we only know that we need to do this for
the year.
</summary>
</member>
<member name="T:IronPython.Modules.xxsubtype">
<summary>
Samples on how to subtype built-in types from C#
</summary>
</member>
<member name="P:IronPython.Modules.xxsubtype.spamlist.state">
<summary>
an int variable for demonstration purposes
</summary>
</member>
<member name="P:IronPython.Modules.xxsubtype.spamdict.state">
<summary>
an int variable for demonstration purposes
</summary>
</member>
<member name="T:IronPython.Modules.FunctionTools.partial">
<summary>
Returns a new callable object with the provided initial set of arguments
bound to it. Calling the new function then appends to the additional
user provided arguments.
</summary>
</member>
<member name="M:IronPython.Modules.FunctionTools.partial.#ctor(IronPython.Runtime.CodeContext,System.Object,System.Object[])">
<summary>
Creates a new partial object with the provided positional arguments.
</summary>
</member>
<member name="M:IronPython.Modules.FunctionTools.partial.#ctor(IronPython.Runtime.CodeContext,System.Object,System.Collections.Generic.IDictionary{System.Object,System.Object},System.Object[])">
<summary>
Creates a new partial object with the provided positional and keyword arguments.
</summary>
</member>
<member name="M:IronPython.Modules.FunctionTools.partial.Call(IronPython.Runtime.CodeContext,System.Object[])">
<summary>
Calls func with the previously provided arguments and more positional arguments.
</summary>
</member>
<member name="M:IronPython.Modules.FunctionTools.partial.Call(IronPython.Runtime.CodeContext,System.Collections.Generic.IDictionary{System.Object,System.Object},System.Object[])">
<summary>
Calls func with the previously provided arguments and more positional arguments and keyword arguments.
</summary>
</member>
<member name="M:IronPython.Modules.FunctionTools.partial.SetMemberAfter(IronPython.Runtime.CodeContext,System.String,System.Object)">
<summary>
Operator method to set arbitrary members on the partial object.
</summary>
</member>
<member name="M:IronPython.Modules.FunctionTools.partial.GetBoundMember(IronPython.Runtime.CodeContext,System.String)">
<summary>
Operator method to get additional arbitrary members defined on the partial object.
</summary>
</member>
<member name="M:IronPython.Modules.FunctionTools.partial.DeleteMember(IronPython.Runtime.CodeContext,System.String)">
<summary>
Operator method to delete arbitrary members defined in the partial object.
</summary>
</member>
<member name="P:IronPython.Modules.FunctionTools.partial.func">
<summary>
Gets the function which will be called
</summary>
</member>
<member name="P:IronPython.Modules.FunctionTools.partial.args">
<summary>
Gets the initially provided positional arguments.
</summary>
</member>
<member name="P:IronPython.Modules.FunctionTools.partial.keywords">
<summary>
Gets the initially provided keyword arguments or None.
</summary>
</member>
<member name="P:IronPython.Modules.FunctionTools.partial.__dict__">
<summary>
Gets or sets the dictionary used for storing extra attributes on the partial object.
</summary>
</member>
<member name="M:IronPython.Modules.PythonSsl.ReadInt(System.Byte[],System.Int32@)">
<summary>
BER encoding of an integer value is the number of bytes
required to represent the integer followed by the bytes
</summary>
</member>
<member name="M:IronPython.Modules.PythonSubprocess.DuplicateHandle(IronPython.Runtime.CodeContext,System.Numerics.BigInteger,IronPython.Modules.PythonSubprocessHandle,System.Numerics.BigInteger,System.Int32,System.Boolean,System.Object)">
<summary>
Duplicates a subprocess handle which was created for piping.
This is only called when we're duplicating the handle to make it inheritable to the child process. In CPython
the parent handle is always reliably garbage collected. Because we know this handle is not going to be
used we close the handle being duplicated.
</summary>
</member>
<member name="M:IronPython.Modules.PythonWeakRef.ref.__hash__(IronPython.Runtime.CodeContext)">
<summary>
Special hash function because IStructuralEquatable.GetHashCode is not allowed to throw.
</summary>
</member>
<member name="M:IronPython.Modules.PythonWeakRef.ref.RefEquals(System.Object,System.Object,System.Collections.IEqualityComparer)">
<summary>
Special equals because none of the special cases in Ops.Equals
are applicable here, and the reference equality check breaks some tests.
</summary>
</member>
<member name="M:IronPython.Modules.PythonWeakRef.weakproxy.GetObject">
<summary>
gets the object or throws a reference exception
</summary>
</member>
<member name="M:IronPython.Modules.PythonWeakRef.weakproxy.__eq__(System.Object)">
<summary>
Special equality function because IStructuralEquatable.Equals is not allowed to throw.
</summary>
</member>
<member name="M:IronPython.Modules.PythonWeakRef.weakcallableproxy.GetObject">
<summary>
gets the object or throws a reference exception
</summary>
</member>
<member name="M:IronPython.Modules.PythonWeakRef.weakcallableproxy.__eq__(System.Object)">
<summary>
Special equality function because IStructuralEquatable.Equals is not allowed to throw.
</summary>
</member>
<member name="M:IronPython.Modules.PythonWinReg.HKEYType.GetKey">
<summary>
Returns the underlying .NET RegistryKey
</summary>
<returns></returns>
</member>
</members>
</doc>