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tdegraphics/kviewshell/plugins/djvu/libdjvu/ByteStream.h

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//C- -*- C++ -*-
//C- -------------------------------------------------------------------
//C- DjVuLibre-3.5
//C- Copyright (c) 2002 Leon Bottou and Yann Le Cun.
//C- Copyright (c) 2001 AT&T
//C-
//C- This software is subject to, and may be distributed under, the
//C- GNU General Public License, Version 2. The license should have
//C- accompanied the software or you may obtain a copy of the license
//C- from the Free Software Foundation at http://www.fsf.org .
//C-
//C- This program is distributed in the hope that it will be useful,
//C- but WITHOUT ANY WARRANTY; without even the implied warranty of
//C- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
//C- GNU General Public License for more details.
//C-
//C- DjVuLibre-3.5 is derived from the DjVu(r) Reference Library
//C- distributed by Lizardtech Software. On July 19th 2002, Lizardtech
//C- Software authorized us to replace the original DjVu(r) Reference
//C- Library notice by the following text (see doc/lizard2002.djvu):
//C-
//C- ------------------------------------------------------------------
//C- | DjVu (r) Reference Library (v. 3.5)
//C- | Copyright (c) 1999-2001 LizardTech, Inc. All Rights Reserved.
//C- | The DjVu Reference Library is protected by U.S. Pat. No.
//C- | 6,058,214 and patents pending.
//C- |
//C- | This software is subject to, and may be distributed under, the
//C- | GNU General Public License, Version 2. The license should have
//C- | accompanied the software or you may obtain a copy of the license
//C- | from the Free Software Foundation at http://www.fsf.org .
//C- |
//C- | The computer code originally released by LizardTech under this
//C- | license and unmodified by other parties is deemed "the LIZARDTECH
//C- | ORIGINAL CODE." Subject to any third party intellectual property
//C- | claims, LizardTech grants recipient a worldwide, royalty-free,
//C- | non-exclusive license to make, use, sell, or otherwise dispose of
//C- | the LIZARDTECH ORIGINAL CODE or of programs derived from the
//C- | LIZARDTECH ORIGINAL CODE in compliance with the terms of the GNU
//C- | General Public License. This grant only confers the right to
//C- | infringe patent claims underlying the LIZARDTECH ORIGINAL CODE to
//C- | the extent such infringement is reasonably necessary to enable
//C- | recipient to make, have made, practice, sell, or otherwise dispose
//C- | of the LIZARDTECH ORIGINAL CODE (or portions thereof) and not to
//C- | any greater extent that may be necessary to utilize further
//C- | modifications or combinations.
//C- |
//C- | The LIZARDTECH ORIGINAL CODE is provided "AS IS" WITHOUT WARRANTY
//C- | OF ANY KIND, EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED
//C- | TO ANY WARRANTY OF NON-INFRINGEMENT, OR ANY IMPLIED WARRANTY OF
//C- | MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
//C- +------------------------------------------------------------------
//
// $Id: ByteStream.h,v 1.11 2003/11/07 22:08:20 leonb Exp $
// $Name: release_3_5_15 $
#ifndef _BYTESTREAM_H
#define _BYTESTREAM_H
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#if NEED_GNUG_PRAGMAS
# pragma interface
#endif
/** @name ByteStream.h
Files #"ByteStream.h"# and #"ByteStream.cpp"# define input/output classes
similar in spirit to the well known C++ #iostream# classes. Class
\Ref{ByteStream} is an abstract base class for all byte streams. It
defines a virtual interface and also provides useful functions. These
files provide two subclasses. Class \Ref{ByteStream::Stdio} provides a
simple interface to the Ansi C buffered input/output functions. Class
\Ref{ByteStream::Memory} provides stream-like access to a dynamical array
maintained in memory. Class \Ref{ByteStream::Static} provides read-only
stream-like access to a user allocated data buffer.
{\bf Notes} --- These classes were partly written because we did not want to
depend on the standard C++ library. The main reason however is related to
the browser interface. We want to have a tight control over the
implementation of subclasses because we want to use a byte stream to
represent data passed by a web browser to a plugin. This operation
involves multi-threading issues that many implementations of the standard
C++ library would squarely ignore.
@memo
Input/output classes
@author
L\'eon Bottou <leonb@research.att.com> -- initial implementation\\
Andrei Erofeev <eaf@geocities.com> --
// From: Leon Bottou, 1/31/2002
// This file has very little to do with my initial implementation.
// It has been practically rewritten by Lizardtech for i18n changes.
// Our original implementation consisted of multiple classes.
// <http://prdownloads.sourceforge.net/djvu/DjVu2_2b-src.tgz>.
@version
#$Id: ByteStream.h,v 1.11 2003/11/07 22:08:20 leonb Exp $# */
//@{
#include "Arrays.h"
#include <stdio.h>
#ifdef HAVE_NAMESPACES
namespace DJVU {
# ifdef NOT_DEFINED // Just to fool emacs c++ mode
}
#endif
#endif
class GURL;
class GUTF8String;
class GNativeString;
/** Abstract class for a stream of bytes. Class #ByteStream# represent an
object from which (resp. to which) bytes can be read (resp. written) as
with a regular file. Virtual functions #read# and #write# must implement
these two basic operations. In addition, function #tell# returns an
offset identifying the current position, and function #seek# may be used
to change the current position.
{\bf Note}. Both the copy constructor and the copy operator are declared
as private members. It is therefore not possible to make multiple copies
of instances of this class, as implied by the class semantic.
*/
class ByteStream : public GPEnabled
{
public:
class Stdio;
class Static;
class Memory;
class Wrapper;
enum codepage_type {RAW,AUTO,NATIVE,UTF8} cp;
/** @name Virtual Functions.
These functions are usually implemented by each subclass of #ByteStream#.
*/
//@{
public:
/** Virtual destructor. */
virtual ~ByteStream();
/** Reads data from a ByteStream. This function {\em must} be implemented
by each subclass of #ByteStream#. At most #size# bytes are read from
the ByteStream and stored in the memory area pointed to by #buffer#.
Function #read# returns immediately if #size# is zero. The actual number
of bytes read is returned. Function #read# returns a number of bytes
smaller than #size# if the end-of-file mark is reached before filling
the buffer. Subsequent invocations will always return value #0#.
Function #read# may also return a value greater than zero but smaller
than #size# for internal reasons. Programs must be ready to handle these
cases or use function \Ref{readall}. Exception \Ref{GException} is
thrown with a plain text error message whenever an error occurs. */
virtual size_t read(void *buffer, size_t size);
/** Writes data to a ByteStream. This function {\em must} be implemented by
each subclass of #ByteStream#. At most #size# bytes from buffer
#buffer# are written to the ByteStream. Function #write# returns
immediately if #size# is zero. The actual number of bytes written is
returned. Function #write# may also return a value greater than zero but
smaller than #size# for internal reasons. Programs must be ready to
handle these cases or use function \Ref{writall}. Exception
\Ref{GException} is thrown with a plain text error message whenever an
error occurs. */
virtual size_t write(const void *buffer, size_t size);
/** Returns the offset of the current position in the ByteStream. This
function {\em must} be implemented by each subclass of #ByteStream#. */
virtual long tell(void) const = 0;
/** Sets the current position for reading or writing the ByteStream. Class
#ByteStream# provides a default implementation able to seek forward by
calling function #read# until reaching the desired position. Subclasses
implementing better seek capabilities must override this default
implementation. The new current position is computed by applying
displacement #offset# to the position represented by argument
#whence#. The following values are recognized for argument #whence#:
\begin{description}
\item[#SEEK_SET#] Argument #offset# indicates the position relative to
the beginning of the ByteStream.
\item[#SEEK_CUR#] Argument #offset# is a signed displacement relative to
the current position.
\item[#SEEK_END#] Argument #offset# is a displacement relative to the end
of the file. It is then advisable to provide a negative value for #offset#.
\end{description}
Results are undefined whenever the new position is greater than the
total size of the ByteStream.
{\bf Error reporting}:
If #seek()# succeeds, #0# is returned. Otherwise it either returns
#-1# (if #nothrow# is set to #FALSE#) or throws the \Ref{GException}
exception. */
virtual int seek(long offset, int whence = SEEK_SET, bool nothrow=false);
/** Flushes all buffers in the ByteStream. Calling this function
guarantees that pending data have been actually written (i.e. passed to
the operating system). Class #ByteStream# provides a default
implementation which does nothing. */
virtual void flush(void);
//@}
/** @name Utility Functions.
Class #ByteStream# implements these functions using the virtual
interface functions only. All subclasses of #ByteStream# inherit these
functions. */
//@{
public:
/** Reads data and blocks until everything has been read. This function is
essentially similar to function #read#. Unlike function #read# however,
function #readall# will never return a value smaller than #size# unless
an end-of-file mark is reached. This is implemented by repeatedly
calling function #read# until everything is read or until we reach an
end-of-file mark. Note that #read# and #readall# are equivalent when
#size# is one. */
size_t readall(void *buffer, size_t size);
/** Writes data and blocks until everything has been written. This function
is essentially similar to function #write#. Unlike function #write#
however, function #writall# will only return after all #size# bytes have
been written. This is implemented by repeatedly calling function
#write# until everything is written. Note that #write# and #writall#
are equivalent when #size# is one. */
size_t writall(const void *buffer, size_t size);
/** Copy data from another ByteStream. A maximum of #size# bytes are read
from the ByteStream #bsfrom# and are written to the ByteStream #*this#
at the current position. Less than #size# bytes may be written if an
end-of-file mark is reached on #bsfrom#. This function returns the
total number of bytes copied. Setting argument #size# to zero (the
default value) has a special meaning: the copying process will continue
until reaching the end-of-file mark on ByteStream #bsfrom#, regardless
of the number of bytes transferred. */
size_t copy(ByteStream &bsfrom, size_t size=0);
/** Create a new #ByteStream# that copies the data from this #ByteStream#
starting from the current position, upto #size# bytes. Setting the
#size# to zero means copy to the end-of-file mark. */
GP<ByteStream> duplicate(const size_t size=0) const;
/// Allows printf() type operations to a bytestream.
size_t format(const char *fmt, ... );
/// Allows scanf() type operations on a bytestream.
int scanf(const char *fmt, ... );
/** Writes the string as is, to the specified stream. */
size_t writestring(const GUTF8String &s);
/** Writes the string as is, to the specified stream. */
size_t writestring(const GNativeString &s);
/** Formats the message string, looks up the external representation
and writes it to the specified stream. */
void formatmessage( const char *fmt, ... );
/** Looks up the message and writes it to the specified stream. */
void writemessage( const char *message );
/** Writes a one-byte integer to a ByteStream. */
void write8 (unsigned int card8);
/** Writes a two-bytes integer to a ByteStream.
The integer most significant byte is written first,
regardless of the processor endianness. */
void write16(unsigned int card16);
/** Writes a three-bytes integer to a ByteStream.
The integer most significant byte is written first,
regardless of the processor endianness. */
void write24(unsigned int card24);
/** Writes a four-bytes integer to a ByteStream.
The integer most significant bytes are written first,
regardless of the processor endianness. */
void write32(unsigned int card32);
/** Reads a one-byte integer from a ByteStream. */
unsigned int read8 ();
/** Reads a two-bytes integer from a ByteStream.
The integer most significant byte is read first,
regardless of the processor endianness. */
unsigned int read16();
/** Reads a three-bytes integer from a ByteStream.
The integer most significant byte is read first,
regardless of the processor endianness. */
unsigned int read24();
/** Reads a four-bytes integer from a ByteStream.
The integer most significant bytes are read first,
regardless of the processor endianness. */
unsigned int read32();
/** Returns the total number of bytes contained in the buffer, file, etc.
Valid offsets for function #seek# range from 0 to the value returned
by this function. */
virtual int size(void) const;
/// Use at your own risk, only guarenteed to work for ByteStream::Memorys.
TArray<char> get_data(void);
/** Reads data from a random position. This function reads at most #sz#
bytes at position #pos# into #buffer# and returns the actual number of
bytes read. The current position is unchanged. */
virtual size_t readat(void *buffer, size_t sz, int pos);
/// Returns false, unless a subclass of ByteStream::Static
virtual bool is_static(void) const { return false; }
//@}
protected:
ByteStream(void) : cp(AUTO) {};
private:
// Cancel C++ default stuff
ByteStream(const ByteStream &);
ByteStream & operator=(const ByteStream &);
public:
/** Constructs an empty Memory ByteStream. The buffer itself is organized
as an array of 4096 byte blocks. The buffer is initially empty. You
must first use function #write# to store data into the buffer, use
function #seek# to rewind the current position, and function #read# to
read the data back. */
static GP<ByteStream> create(void);
/** Constructs a Memory ByteStream by copying initial data. The
Memory buffer is initialized with #size# bytes copied from the
memory area pointed to by #buffer#. */
static GP<ByteStream> create(void const * const buffer, const size_t size);
/** Constructs a ByteStream for accessing the file named #url#.
Arguments #url# and #mode# are similar to the arguments of the well
known stdio function #fopen#. In addition a url of #-# will be
interpreted as the standard output or the standard input according to
#mode#. This constructor will open a stdio file and construct a
ByteStream object accessing this file. Destroying the ByteStream object
will flush and close the associated stdio file. Exception
\Ref{GException} is thrown with a plain text error message if the stdio
file cannot be opened. */
static GP<ByteStream> create(
const GURL &url, char const * const mode);
/** Same as the above, but uses stdin or stdout */
static GP<ByteStream> create( char const * const mode);
/** Constructs a ByteStream for accessing the stdio file #f#.
Argument #mode# indicates the type of the stdio file, as in the
well known stdio function #fopen#. Destroying the ByteStream
object will not close the stdio file #f# unless closeme is true. */
static GP<ByteStream> create(
const int fd, char const * const mode, const bool closeme);
/** Constructs a ByteStream for accessing the stdio file #f#.
Argument #mode# indicates the type of the stdio file, as in the
well known stdio function #fopen#. Destroying the ByteStream
object will not close the stdio file #f# unless closeme is true. */
static GP<ByteStream> create(
FILE * const f, char const * const mode, const bool closeme);
/** Creates a ByteStream object for allocating the memory area of
length #sz# starting at address #buffer#. This call impliments
a read-only ByteStream interface for a memory area specified by
the user at construction time. Calls to function #read# directly
access this memory area. The user must therefore make sure that its
content remain valid long enough. */
static GP<ByteStream> create_static(
void const * const buffer, const size_t size);
/** Easy access to preallocated stdin/stdout/stderr bytestreams */
static GP<ByteStream> get_stdin(char const * const mode=0);
static GP<ByteStream> get_stdout(char const * const mode=0);
static GP<ByteStream> get_stderr(char const * const mode=0);
/** This is the conventional name for EOF exceptions */
static const char *EndOfFile;
/** Returns the contents of the file as a GNativeString */
GNativeString getAsNative(void);
/** Returns the contents of the file as a GUTF8String */
GUTF8String getAsUTF8(void);
};
inline size_t
ByteStream::readat(void *buffer, size_t sz, int pos)
{
size_t retval;
long tpos=tell();
seek(pos, SEEK_SET, true);
retval=readall(buffer,sz);
seek(tpos, SEEK_SET, true);
return retval;
}
inline int
ByteStream::size(void) const
{
ByteStream *bs=const_cast<ByteStream *>(this);
int bsize=(-1);
long pos=tell();
if(bs->seek(0,SEEK_END,true))
{
bsize=(int)tell();
(void)(bs->seek(pos,SEEK_SET,false));
}
return bsize;
}
/** ByteStream::Wrapper implements wrapping bytestream. This is useful
for derived classes that take a GP<ByteStream> as a creation argument,
and the backwards compatible bytestreams. */
class ByteStream::Wrapper : public ByteStream
{
protected:
GP<ByteStream> gbs;
ByteStream *bs;
Wrapper(void) : bs(0) {}
Wrapper(const GP<ByteStream> &xbs) : gbs(xbs), bs(xbs) {}
public:
~Wrapper();
ByteStream * operator & () const {return bs;}
ByteStream * operator & () {return bs;}
virtual size_t read(void *buffer, size_t size)
{ return bs->read(buffer,size); }
virtual size_t write(const void *buffer, size_t size)
{ return bs->write(buffer,size); }
virtual long tell(void) const
{ return bs->tell(); }
virtual int seek(long offset, int whence = SEEK_SET, bool nothrow=false)
{ return bs->seek(offset,whence,nothrow); }
virtual void flush(void)
{ bs->flush(); }
};
//@}
// ------------ THE END
#ifdef HAVE_NAMESPACES
}
# ifndef NOT_USING_DJVU_NAMESPACE
using namespace DJVU;
# endif
#endif
#endif