media/libdrm/mobile2/src/util/ustl-1.0/mistream.h - platform/frameworks/base - Git at Google

 // This file is part of the ustl library, an STL implementation.
 //
 // Copyright (C) 2005 by Mike Sharov <msharov@users.sourceforge.net>
 // This file is free software, distributed under the MIT License.
 //
 // mistream.h
 //
 #ifndef MISTREAM_H_103AEF1F266C04AA1A817D38705983DA
 #define MISTREAM_H_103AEF1F266C04AA1A817D38705983DA

 #include "memlink.h"
 #include "uexception.h"
 #include "strmsize.h"
 #include "uassert.h"
 #include "utf8.h"
 #include "uios.h"
 #ifdef WANT_STREAM_BOUNDS_CHECKING
     #include <typeinfo>
 #endif

 namespace ustl {

 class ostream;
 class memlink;
 class string;

 /// \class istream mistream.h ustl.h
 /// \ingroup BinaryStreams
 ///
 /// \brief Helper class to read packed binary streams.
 ///
 /// This class contains a set of functions to read integral types from an
 /// unstructured memory block. Unpacking binary file data can be done this
 /// way, for instance. aligning the data is your responsibility, and can
 /// be accomplished by proper ordering of reads and by calling the align()
 /// function. Unaligned access is usually slower by orders of magnitude and,
 /// on some architectures, such as PowerPC, can cause your program to crash.
 /// Therefore, all read functions have asserts to check alignment.
 /// Overreading the end of the stream will also cause a crash (an assert in
 /// debug builds). Oh, and don't be intimidated by the size of the inlines
 /// here. In the assembly code the compiler will usually chop everything down
 /// to five instructions each.
 ///
 /// Alignment rules for your objects:
 ///	- Assume your writes start off 4-byte aligned.
 ///	- After completion, \ref istream::align the stream to at least 4.
 ///	- If data portability between 32bit and 64bit platforms is important
 ///	(it often is not, in config files and the like), ensure you are always
 ///	using fixed-size types and are aligning to a fixed grain. Avoid writing
 ///	8-byte types, and if you do, manually align before doing so.
 ///	- Non-default alignment is allowed if you plan to frequently write this
 ///	object in array form and alignment would be costly. For example, an
 ///	array of uint16_t-sized objects may leave the stream uint16_t aligned
 ///	as long as you know about it and will default-align the stream after
 ///	writing the array (note: \ref vector will already do this for you)
 ///
 /// Example code:
 /// \code
 ///	memblock b;
 ///	b.read_file ("test.file");
 ///	ostream is (b);
 ///	is >> boolVar >> ios::talign<int>();
 ///	is >> intVar >> floatVar;
 ///	is.read (binaryData, binaryDataSize);
 ///	is.align();
 /// \endcode
 ///
 class istream : public cmemlink, public ios_base {
 public:
 			istream (void);
 			istream (const void* p, size_type n);
     explicit		istream (const cmemlink& source);
     explicit		istream (const ostream& source);
     inline iterator	end (void) const			{ return (cmemlink::end()); }
     inline void		link (const void* p, size_type n)	{ cmemlink::link (p, n); }
     inline void		link (const cmemlink& l)		{ cmemlink::link (l.cdata(), l.readable_size()); }
     inline void		link (const void* f, const void* l)	{ cmemlink::link (f, l); }
 			OVERLOAD_POINTER_AND_SIZE_T_V2(link, const void*)
     inline void		relink (const void* p, size_type n)	{ cmemlink::relink (p, n); m_Pos = 0; }
     inline void		relink (const cmemlink& l)		{ relink (l.cdata(), l.readable_size()); }
     virtual void	unlink (void);
     inline virtual size_type	underflow (size_type = 1)	{ return (remaining()); }
     inline uoff_t	pos (void) const	{ return (m_Pos); }
     inline const_iterator ipos (void) const	{ return (begin() + pos()); }
     inline size_type	remaining (void) const	{ return (size() - pos()); }
     inline void		seek (uoff_t newPos);
     inline void		iseek (const_iterator newPos);
     inline void		skip (size_type nBytes);
     inline bool		aligned (size_type grain = c_DefaultAlignment) const;
     void		verify_remaining (const char* op, const char* type, size_t n) const;
     inline size_type	align_size (size_type grain = c_DefaultAlignment) const;
     inline void		align (size_type grain = c_DefaultAlignment);
     void		swap (istream& is);
     void		read (void* buffer, size_type size);
     inline void		read (memlink& buf)	{ read (buf.begin(), buf.writable_size()); }
     void		read_strz (string& str);
     size_type		readsome (void* s, size_type n);
     inline void		read (istream&)			{ }
     void		write (ostream& os) const;
     void		text_write (ostringstream& os) const;
     inline size_t	stream_size (void) const	{ return (remaining()); }
     template <typename T>
     inline void		iread (T& v);
     inline void		ungetc (void)		{ seek (pos() - 1); }
     inline off_t	tellg (void) const	{ return (pos()); }
     inline void		seekg (off_t p, seekdir d = beg);
 private:
     uoff_t		m_Pos;		///< The current read position.
 };

 //----------------------------------------------------------------------

 template <typename T, typename Stream>
 inline size_t required_stream_size (T, const Stream&) { return (1); }
 template <typename T>
 inline size_t required_stream_size (T v, const istream&) { return (stream_size_of(v)); }

 template <typename Stream>
 inline bool stream_at_eof (const Stream& stm)	{ return (stm.eof()); }
 template <>
 inline bool stream_at_eof (const istream&)	{ return (false); }

 /// \class istream_iterator
 /// \ingroup BinaryStreamIterators
 ///
 /// \brief An iterator over an istream to use with uSTL algorithms.
 ///
 template <typename T, typename Stream = istream>
 class istream_iterator {
 public:
     typedef T			value_type;
     typedef ptrdiff_t		difference_type;
     typedef const value_type*	pointer;
     typedef const value_type&	reference;
     typedef size_t		size_type;
 public:
 				istream_iterator (void)		: m_pis (NULL), m_v() {}
     explicit			istream_iterator (Stream& is)	: m_pis (&is), m_v() { Read(); }
  				istream_iterator (const istream_iterator& i)	: m_pis (i.m_pis), m_v (i.m_v) {}
     /// Reads and returns the next value.
     inline const T&		operator* (void)	{ return (m_v); }
     inline istream_iterator&	operator++ (void)	{ Read(); return (*this); }
     inline istream_iterator&	operator-- (void)	{ m_pis->seek (m_pis->pos() - 2 * stream_size_of(m_v)); return (operator++()); }
     inline istream_iterator	operator++ (int)	{ istream_iterator old (*this); operator++(); return (old); }
     inline istream_iterator	operator-- (int)	{ istream_iterator old (*this); operator--(); return (old); }
     inline istream_iterator&	operator+= (size_type n)	{ while (n--) operator++(); return (*this); }
     inline istream_iterator&	operator-= (size_type n)	{ m_pis->seek (m_pis->pos() - (n + 1) * stream_size_of(m_v)); return (operator++()); }
     inline istream_iterator	operator- (size_type n) const			{ istream_iterator result (*this); return (result -= n); }
     inline difference_type	operator- (const istream_iterator& i) const	{ return (distance (i.m_pis->pos(), m_pis->pos()) / stream_size_of(m_v)); }
     inline bool			operator== (const istream_iterator& i) const	{ return ((!m_pis && !i.m_pis) || (m_pis && i.m_pis && m_pis->pos() == i.m_pis->pos())); }
     inline bool			operator< (const istream_iterator& i) const	{ return (!i.m_pis || (m_pis && m_pis->pos() < i.m_pis->pos())); }
 private:
     void Read (void)
     {
 	if (!m_pis)
 	    return;
 	const size_t rs (required_stream_size (m_v, *m_pis));
 	if (m_pis->remaining() < rs && m_pis->underflow (rs) < rs) {
 	    m_pis = NULL;
 	    return;
 	}
 	*m_pis >> m_v;
 	if (stream_at_eof (*m_pis))
 	    m_pis = NULL;
     }
 private:
     Stream*	m_pis;		///< The host stream.
     T		m_v;		///< Last read value; cached to be returnable as a const reference.
 };

 //----------------------------------------------------------------------

 /// Sets the current read position to \p newPos
 inline void istream::seek (uoff_t newPos)
 {
 #ifdef WANT_STREAM_BOUNDS_CHECKING
     if (newPos > size())
 	throw stream_bounds_exception ("seekg", "byte", pos(), newPos - pos(), size());
 #else
     assert (newPos <= size());
 #endif
     m_Pos = newPos;
 }

 /// Sets the current read position to \p newPos
 inline void istream::iseek (const_iterator newPos)
 {
     seek (distance (begin(), newPos));
 }

 /// Sets the current write position to \p p based on \p d.
 inline void istream::seekg (off_t p, seekdir d)
 {
     switch (d) {
 	case beg:	seek (p); break;
 	case cur:	seek (pos() + p); break;
 	case ios_base::end:	seek (size() - p); break;
     }
 }

 /// Skips \p nBytes without reading them.
 inline void istream::skip (size_type nBytes)
 {
     seek (pos() + nBytes);
 }

 /// Returns the number of bytes to skip to be aligned on \p grain.
 inline istream::size_type istream::align_size (size_type grain) const
 {
     return (Align (pos(), grain) - pos());
 }

 /// Returns \c true if the read position is aligned on \p grain
 inline bool istream::aligned (size_type grain) const
 {
     assert (uintptr_t(begin()) % grain == 0 && "Streams should be attached aligned at the maximum element grain to avoid bus errors.");
     return (pos() % grain == 0);
 }

 /// aligns the read position on \p grain
 inline void istream::align (size_type grain)
 {
     seek (Align (pos(), grain));
 }

 /// Reads type T from the stream via a direct pointer cast.
 template <typename T>
 inline void istream::iread (T& v)
 {
     assert (aligned (alignof (T())));
 #ifdef WANT_STREAM_BOUNDS_CHECKING
     verify_remaining ("read", typeid(v).name(), sizeof(T));
 #else
     assert (remaining() >= sizeof(T));
 #endif
     v = *reinterpret_cast<const T*>(ipos());
     m_Pos += sizeof(T);
 }

 #define ISTREAM_OPERATOR(type)	\
 inline istream&	operator>> (istream& is, type& v)	{ is.iread(v); return (is); }

 template <typename T>
 ISTREAM_OPERATOR(T*)
 ISTREAM_OPERATOR(int8_t)
 ISTREAM_OPERATOR(uint8_t)
 ISTREAM_OPERATOR(int16_t)
 ISTREAM_OPERATOR(uint16_t)
 ISTREAM_OPERATOR(int32_t)
 ISTREAM_OPERATOR(uint32_t)
 ISTREAM_OPERATOR(float)
 ISTREAM_OPERATOR(double)
 ISTREAM_OPERATOR(wchar_t)
 #if SIZE_OF_BOOL == SIZE_OF_CHAR
 ISTREAM_OPERATOR(bool)
 #else
 inline istream&	operator>> (istream& is, bool& v)
 { uint8_t v8; is.iread (v8); v = v8; return (is); }
 #endif
 #if HAVE_THREE_CHAR_TYPES
 ISTREAM_OPERATOR(char)
 #endif
 #if HAVE_INT64_T
 ISTREAM_OPERATOR(int64_t)
 ISTREAM_OPERATOR(uint64_t)
 #endif
 #if SIZE_OF_LONG == SIZE_OF_INT
 ISTREAM_OPERATOR(long)
 ISTREAM_OPERATOR(unsigned long)
 #endif
 #if HAVE_LONG_LONG && (!HAVE_INT64_T || SIZE_OF_LONG_LONG > 8)
 ISTREAM_OPERATOR(long long)
 ISTREAM_OPERATOR(unsigned long long)
 #endif

 //----------------------------------------------------------------------

 typedef istream_iterator<utf8subchar_t> istream_iterator_for_utf8;
 typedef utf8in_iterator<istream_iterator_for_utf8> utf8istream_iterator;

 /// Returns a UTF-8 adaptor reading from \p is.
 inline utf8istream_iterator utf8in (istream& is)
 {
     istream_iterator_for_utf8 si (is);
     return (utf8istream_iterator (si));
 }

 //----------------------------------------------------------------------

 } // namespace ustl

 #endif
	// This file is part of the ustl library, an STL implementation.
	//
	// Copyright (C) 2005 by Mike Sharov <msharov@users.sourceforge.net>
	// This file is free software, distributed under the MIT License.
	//
	// mistream.h
	//
	#ifndef MISTREAM_H_103AEF1F266C04AA1A817D38705983DA
	#define MISTREAM_H_103AEF1F266C04AA1A817D38705983DA

	#include "memlink.h"
	#include "uexception.h"
	#include "strmsize.h"
	#include "uassert.h"
	#include "utf8.h"
	#include "uios.h"
	#ifdef WANT_STREAM_BOUNDS_CHECKING
	#include <typeinfo>
	#endif

	namespace ustl {

	class ostream;
	class memlink;
	class string;

	/// \class istream mistream.h ustl.h
	/// \ingroup BinaryStreams
	///
	/// \brief Helper class to read packed binary streams.
	///
	/// This class contains a set of functions to read integral types from an
	/// unstructured memory block. Unpacking binary file data can be done this
	/// way, for instance. aligning the data is your responsibility, and can
	/// be accomplished by proper ordering of reads and by calling the align()
	/// function. Unaligned access is usually slower by orders of magnitude and,
	/// on some architectures, such as PowerPC, can cause your program to crash.
	/// Therefore, all read functions have asserts to check alignment.
	/// Overreading the end of the stream will also cause a crash (an assert in
	/// debug builds). Oh, and don't be intimidated by the size of the inlines
	/// here. In the assembly code the compiler will usually chop everything down
	/// to five instructions each.
	///
	/// Alignment rules for your objects:
	/// - Assume your writes start off 4-byte aligned.
	/// - After completion, \ref istream::align the stream to at least 4.
	/// - If data portability between 32bit and 64bit platforms is important
	/// (it often is not, in config files and the like), ensure you are always
	/// using fixed-size types and are aligning to a fixed grain. Avoid writing
	/// 8-byte types, and if you do, manually align before doing so.
	/// - Non-default alignment is allowed if you plan to frequently write this
	/// object in array form and alignment would be costly. For example, an
	/// array of uint16_t-sized objects may leave the stream uint16_t aligned
	/// as long as you know about it and will default-align the stream after
	/// writing the array (note: \ref vector will already do this for you)
	///
	/// Example code:
	/// \code
	/// memblock b;
	/// b.read_file ("test.file");
	/// ostream is (b);
	/// is >> boolVar >> ios::talign<int>();
	/// is >> intVar >> floatVar;
	/// is.read (binaryData, binaryDataSize);
	/// is.align();
	/// \endcode
	///
	class istream : public cmemlink, public ios_base {
	public:
	istream (void);
	istream (const void* p, size_type n);
	explicit istream (const cmemlink& source);
	explicit istream (const ostream& source);
	inline iterator end (void) const { return (cmemlink::end()); }
	inline void link (const void* p, size_type n) { cmemlink::link (p, n); }
	inline void link (const cmemlink& l) { cmemlink::link (l.cdata(), l.readable_size()); }
	inline void link (const void* f, const void* l) { cmemlink::link (f, l); }
	OVERLOAD_POINTER_AND_SIZE_T_V2(link, const void*)
	inline void relink (const void* p, size_type n) { cmemlink::relink (p, n); m_Pos = 0; }
	inline void relink (const cmemlink& l) { relink (l.cdata(), l.readable_size()); }
	virtual void unlink (void);
	inline virtual size_type underflow (size_type = 1) { return (remaining()); }
	inline uoff_t pos (void) const { return (m_Pos); }
	inline const_iterator ipos (void) const { return (begin() + pos()); }
	inline size_type remaining (void) const { return (size() - pos()); }
	inline void seek (uoff_t newPos);
	inline void iseek (const_iterator newPos);
	inline void skip (size_type nBytes);
	inline bool aligned (size_type grain = c_DefaultAlignment) const;
	void verify_remaining (const char* op, const char* type, size_t n) const;
	inline size_type align_size (size_type grain = c_DefaultAlignment) const;
	inline void align (size_type grain = c_DefaultAlignment);
	void swap (istream& is);
	void read (void* buffer, size_type size);
	inline void read (memlink& buf) { read (buf.begin(), buf.writable_size()); }
	void read_strz (string& str);
	size_type readsome (void* s, size_type n);
	inline void read (istream&) { }
	void write (ostream& os) const;
	void text_write (ostringstream& os) const;
	inline size_t stream_size (void) const { return (remaining()); }
	template <typename T>
	inline void iread (T& v);
	inline void ungetc (void) { seek (pos() - 1); }
	inline off_t tellg (void) const { return (pos()); }
	inline void seekg (off_t p, seekdir d = beg);
	private:
	uoff_t m_Pos; ///< The current read position.
	};

	//----------------------------------------------------------------------

	template <typename T, typename Stream>
	inline size_t required_stream_size (T, const Stream&) { return (1); }
	template <typename T>
	inline size_t required_stream_size (T v, const istream&) { return (stream_size_of(v)); }

	template <typename Stream>
	inline bool stream_at_eof (const Stream& stm) { return (stm.eof()); }
	template <>
	inline bool stream_at_eof (const istream&) { return (false); }

	/// \class istream_iterator
	/// \ingroup BinaryStreamIterators
	///
	/// \brief An iterator over an istream to use with uSTL algorithms.
	///
	template <typename T, typename Stream = istream>
	class istream_iterator {
	public:
	typedef T value_type;
	typedef ptrdiff_t difference_type;
	typedef const value_type* pointer;
	typedef const value_type& reference;
	typedef size_t size_type;
	public:
	istream_iterator (void) : m_pis (NULL), m_v() {}
	explicit istream_iterator (Stream& is) : m_pis (&is), m_v() { Read(); }
	istream_iterator (const istream_iterator& i) : m_pis (i.m_pis), m_v (i.m_v) {}
	/// Reads and returns the next value.
	inline const T& operator* (void) { return (m_v); }
	inline istream_iterator& operator++ (void) { Read(); return (*this); }
	inline istream_iterator& operator-- (void) { m_pis->seek (m_pis->pos() - 2 * stream_size_of(m_v)); return (operator++()); }
	inline istream_iterator operator++ (int) { istream_iterator old (*this); operator++(); return (old); }
	inline istream_iterator operator-- (int) { istream_iterator old (*this); operator--(); return (old); }
	inline istream_iterator& operator+= (size_type n) { while (n--) operator++(); return (*this); }
	inline istream_iterator& operator-= (size_type n) { m_pis->seek (m_pis->pos() - (n + 1) * stream_size_of(m_v)); return (operator++()); }
	inline istream_iterator operator- (size_type n) const { istream_iterator result (*this); return (result -= n); }
	inline difference_type operator- (const istream_iterator& i) const { return (distance (i.m_pis->pos(), m_pis->pos()) / stream_size_of(m_v)); }
	inline bool operator== (const istream_iterator& i) const { return ((!m_pis && !i.m_pis) \|\| (m_pis && i.m_pis && m_pis->pos() == i.m_pis->pos())); }
	inline bool operator< (const istream_iterator& i) const { return (!i.m_pis \|\| (m_pis && m_pis->pos() < i.m_pis->pos())); }
	private:
	void Read (void)
	{
	if (!m_pis)
	return;
	const size_t rs (required_stream_size (m_v, *m_pis));
	if (m_pis->remaining() < rs && m_pis->underflow (rs) < rs) {
	m_pis = NULL;
	return;
	}
	*m_pis >> m_v;
	if (stream_at_eof (*m_pis))
	m_pis = NULL;
	}
	private:
	Stream* m_pis; ///< The host stream.
	T m_v; ///< Last read value; cached to be returnable as a const reference.
	};

	//----------------------------------------------------------------------

	/// Sets the current read position to \p newPos
	inline void istream::seek (uoff_t newPos)
	{
	#ifdef WANT_STREAM_BOUNDS_CHECKING
	if (newPos > size())
	throw stream_bounds_exception ("seekg", "byte", pos(), newPos - pos(), size());
	#else
	assert (newPos <= size());
	#endif
	m_Pos = newPos;
	}

	/// Sets the current read position to \p newPos
	inline void istream::iseek (const_iterator newPos)
	{
	seek (distance (begin(), newPos));
	}

	/// Sets the current write position to \p p based on \p d.
	inline void istream::seekg (off_t p, seekdir d)
	{
	switch (d) {
	case beg: seek (p); break;
	case cur: seek (pos() + p); break;
	case ios_base::end: seek (size() - p); break;
	}
	}

	/// Skips \p nBytes without reading them.
	inline void istream::skip (size_type nBytes)
	{
	seek (pos() + nBytes);
	}

	/// Returns the number of bytes to skip to be aligned on \p grain.
	inline istream::size_type istream::align_size (size_type grain) const
	{
	return (Align (pos(), grain) - pos());
	}

	/// Returns \c true if the read position is aligned on \p grain
	inline bool istream::aligned (size_type grain) const
	{
	assert (uintptr_t(begin()) % grain == 0 && "Streams should be attached aligned at the maximum element grain to avoid bus errors.");
	return (pos() % grain == 0);
	}

	/// aligns the read position on \p grain
	inline void istream::align (size_type grain)
	{
	seek (Align (pos(), grain));
	}

	/// Reads type T from the stream via a direct pointer cast.
	template <typename T>
	inline void istream::iread (T& v)
	{
	assert (aligned (alignof (T())));
	#ifdef WANT_STREAM_BOUNDS_CHECKING
	verify_remaining ("read", typeid(v).name(), sizeof(T));
	#else
	assert (remaining() >= sizeof(T));
	#endif
	v = reinterpret_cast<const T>(ipos());
	m_Pos += sizeof(T);
	}

	#define ISTREAM_OPERATOR(type) \
	inline istream& operator>> (istream& is, type& v) { is.iread(v); return (is); }

	template <typename T>
	ISTREAM_OPERATOR(T*)
	ISTREAM_OPERATOR(int8_t)
	ISTREAM_OPERATOR(uint8_t)
	ISTREAM_OPERATOR(int16_t)
	ISTREAM_OPERATOR(uint16_t)
	ISTREAM_OPERATOR(int32_t)
	ISTREAM_OPERATOR(uint32_t)
	ISTREAM_OPERATOR(float)
	ISTREAM_OPERATOR(double)
	ISTREAM_OPERATOR(wchar_t)
	#if SIZE_OF_BOOL == SIZE_OF_CHAR
	ISTREAM_OPERATOR(bool)
	#else
	inline istream& operator>> (istream& is, bool& v)
	{ uint8_t v8; is.iread (v8); v = v8; return (is); }
	#endif
	#if HAVE_THREE_CHAR_TYPES
	ISTREAM_OPERATOR(char)
	#endif
	#if HAVE_INT64_T
	ISTREAM_OPERATOR(int64_t)
	ISTREAM_OPERATOR(uint64_t)
	#endif
	#if SIZE_OF_LONG == SIZE_OF_INT
	ISTREAM_OPERATOR(long)
	ISTREAM_OPERATOR(unsigned long)
	#endif
	#if HAVE_LONG_LONG && (!HAVE_INT64_T \|\| SIZE_OF_LONG_LONG > 8)
	ISTREAM_OPERATOR(long long)
	ISTREAM_OPERATOR(unsigned long long)
	#endif

	//----------------------------------------------------------------------

	typedef istream_iterator<utf8subchar_t> istream_iterator_for_utf8;
	typedef utf8in_iterator<istream_iterator_for_utf8> utf8istream_iterator;

	/// Returns a UTF-8 adaptor reading from \p is.
	inline utf8istream_iterator utf8in (istream& is)
	{
	istream_iterator_for_utf8 si (is);
	return (utf8istream_iterator (si));
	}

	//----------------------------------------------------------------------

	} // namespace ustl

	#endif