mirror of
https://github.com/nillerusr/source-engine.git
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810 lines
22 KiB
C++
810 lines
22 KiB
C++
//========= Copyright Valve Corporation, All rights reserved. ============//
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//
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// Purpose:
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//
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// $NoKeywords: $
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//
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//=============================================================================//
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// NOTE: bf_read is guaranteed to return zeros if it overflows.
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#ifndef BITBUF_H
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#define BITBUF_H
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#ifdef _WIN32
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#pragma once
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#endif
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#include "mathlib/mathlib.h"
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#include "mathlib/vector.h"
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#include "basetypes.h"
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#include "tier0/dbg.h"
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#include "strtools.h"
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#if _DEBUG
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#define BITBUF_INLINE inline
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#else
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#define BITBUF_INLINE FORCEINLINE
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#endif
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//-----------------------------------------------------------------------------
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// Forward declarations.
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//-----------------------------------------------------------------------------
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class Vector;
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class QAngle;
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//-----------------------------------------------------------------------------
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// You can define a handler function that will be called in case of
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// out-of-range values and overruns here.
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//
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// NOTE: the handler is only called in debug mode.
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//
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// Call SetBitBufErrorHandler to install a handler.
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//-----------------------------------------------------------------------------
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typedef enum
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{
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BITBUFERROR_VALUE_OUT_OF_RANGE=0, // Tried to write a value with too few bits.
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BITBUFERROR_BUFFER_OVERRUN, // Was about to overrun a buffer.
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BITBUFERROR_NUM_ERRORS
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} BitBufErrorType;
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typedef void (*BitBufErrorHandler)( BitBufErrorType errorType, const char *pDebugName );
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#if defined( _DEBUG )
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extern void InternalBitBufErrorHandler( BitBufErrorType errorType, const char *pDebugName );
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#define CallErrorHandler( errorType, pDebugName ) InternalBitBufErrorHandler( errorType, pDebugName );
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#else
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#define CallErrorHandler( errorType, pDebugName )
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#endif
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// Use this to install the error handler. Call with NULL to uninstall your error handler.
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void SetBitBufErrorHandler( BitBufErrorHandler fn );
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//-----------------------------------------------------------------------------
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// Helpers.
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//-----------------------------------------------------------------------------
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inline int BitByte( int bits )
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{
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// return PAD_NUMBER( bits, 8 ) >> 3;
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return (bits + 7) >> 3;
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}
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//-----------------------------------------------------------------------------
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// namespaced helpers
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//-----------------------------------------------------------------------------
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namespace bitbuf
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{
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// ZigZag Transform: Encodes signed integers so that they can be
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// effectively used with varint encoding.
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//
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// varint operates on unsigned integers, encoding smaller numbers into
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// fewer bytes. If you try to use it on a signed integer, it will treat
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// this number as a very large unsigned integer, which means that even
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// small signed numbers like -1 will take the maximum number of bytes
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// (10) to encode. ZigZagEncode() maps signed integers to unsigned
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// in such a way that those with a small absolute value will have smaller
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// encoded values, making them appropriate for encoding using varint.
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//
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// int32 -> uint32
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// -------------------------
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// 0 -> 0
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// -1 -> 1
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// 1 -> 2
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// -2 -> 3
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// ... -> ...
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// 2147483647 -> 4294967294
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// -2147483648 -> 4294967295
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//
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// >> encode >>
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// << decode <<
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inline uint32 ZigZagEncode32(int32 n)
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{
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// Note: the right-shift must be arithmetic
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return(n << 1) ^ (n >> 31);
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}
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inline int32 ZigZagDecode32(uint32 n)
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{
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return(n >> 1) ^ -static_cast<int32>(n & 1);
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}
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inline uint64 ZigZagEncode64(int64 n)
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{
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// Note: the right-shift must be arithmetic
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return(n << 1) ^ (n >> 63);
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}
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inline int64 ZigZagDecode64(uint64 n)
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{
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return(n >> 1) ^ -static_cast<int64>(n & 1);
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}
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const int kMaxVarintBytes = 10;
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const int kMaxVarint32Bytes = 5;
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}
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//-----------------------------------------------------------------------------
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// Used for serialization
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//-----------------------------------------------------------------------------
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class bf_write
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{
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public:
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bf_write();
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// nMaxBits can be used as the number of bits in the buffer.
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// It must be <= nBytes*8. If you leave it at -1, then it's set to nBytes * 8.
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bf_write( void *pData, int nBytes, int nMaxBits = -1 );
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bf_write( const char *pDebugName, void *pData, int nBytes, int nMaxBits = -1 );
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// Start writing to the specified buffer.
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// nMaxBits can be used as the number of bits in the buffer.
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// It must be <= nBytes*8. If you leave it at -1, then it's set to nBytes * 8.
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void StartWriting( void *pData, int nBytes, int iStartBit = 0, int nMaxBits = -1 );
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// Restart buffer writing.
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void Reset();
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// Get the base pointer.
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unsigned char* GetBasePointer() { return (unsigned char*) m_pData; }
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// Enable or disable assertion on overflow. 99% of the time, it's a bug that we need to catch,
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// but there may be the occasional buffer that is allowed to overflow gracefully.
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void SetAssertOnOverflow( bool bAssert );
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// This can be set to assign a name that gets output if the buffer overflows.
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const char* GetDebugName();
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void SetDebugName( const char *pDebugName );
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// Seek to a specific position.
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public:
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void SeekToBit( int bitPos );
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// Bit functions.
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public:
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void WriteOneBit(int nValue);
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void WriteOneBitNoCheck(int nValue);
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void WriteOneBitAt( int iBit, int nValue );
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// Write signed or unsigned. Range is only checked in debug.
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void WriteUBitLong( unsigned int data, int numbits, bool bCheckRange=true ) RESTRICT;
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void WriteSBitLong( int data, int numbits );
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// Tell it whether or not the data is unsigned. If it's signed,
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// cast to unsigned before passing in (it will cast back inside).
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void WriteBitLong(unsigned int data, int numbits, bool bSigned);
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// Write a list of bits in.
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bool WriteBits(const void *pIn, int nBits);
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// writes an unsigned integer with variable bit length
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void WriteUBitVar( unsigned int data );
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// writes a varint encoded integer
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void WriteVarInt32( uint32 data );
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void WriteVarInt64( uint64 data );
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void WriteSignedVarInt32( int32 data );
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void WriteSignedVarInt64( int64 data );
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int ByteSizeVarInt32( uint32 data );
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int ByteSizeVarInt64( uint64 data );
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int ByteSizeSignedVarInt32( int32 data );
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int ByteSizeSignedVarInt64( int64 data );
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// Copy the bits straight out of pIn. This seeks pIn forward by nBits.
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// Returns an error if this buffer or the read buffer overflows.
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bool WriteBitsFromBuffer( class bf_read *pIn, int nBits );
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void WriteBitAngle( float fAngle, int numbits );
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void WriteBitCoord (const float f);
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void WriteBitCoordMP( const float f, bool bIntegral, bool bLowPrecision );
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void WriteBitFloat(float val);
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void WriteBitVec3Coord( const Vector& fa );
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void WriteBitNormal( float f );
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void WriteBitVec3Normal( const Vector& fa );
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void WriteBitAngles( const QAngle& fa );
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// Byte functions.
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public:
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void WriteChar(int val);
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void WriteByte(int val);
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void WriteShort(int val);
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void WriteWord(int val);
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void WriteLong(long val);
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void WriteLongLong(int64 val);
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void WriteFloat(float val);
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bool WriteBytes( const void *pBuf, int nBytes );
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// Returns false if it overflows the buffer.
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bool WriteString(const char *pStr);
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// Status.
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public:
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// How many bytes are filled in?
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int GetNumBytesWritten() const;
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int GetNumBitsWritten() const;
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int GetMaxNumBits();
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int GetNumBitsLeft() RESTRICT;
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int GetNumBytesLeft();
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unsigned char* GetData();
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const unsigned char* GetData() const;
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// Has the buffer overflowed?
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bool CheckForOverflow(int nBits);
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inline bool IsOverflowed() const {return m_bOverflow;}
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void SetOverflowFlag() RESTRICT;
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public:
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// The current buffer.
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unsigned long* RESTRICT m_pData;
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int m_nDataBytes;
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int m_nDataBits;
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// Where we are in the buffer.
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int m_iCurBit;
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private:
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// Errors?
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bool m_bOverflow;
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bool m_bAssertOnOverflow;
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const char *m_pDebugName;
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};
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//-----------------------------------------------------------------------------
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// Inlined methods
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//-----------------------------------------------------------------------------
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// How many bytes are filled in?
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inline int bf_write::GetNumBytesWritten() const
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{
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return BitByte(m_iCurBit);
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}
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inline int bf_write::GetNumBitsWritten() const
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{
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return m_iCurBit;
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}
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inline int bf_write::GetMaxNumBits()
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{
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return m_nDataBits;
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}
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inline int bf_write::GetNumBitsLeft() RESTRICT
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{
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return m_nDataBits - m_iCurBit;
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}
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inline int bf_write::GetNumBytesLeft()
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{
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return GetNumBitsLeft() >> 3;
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}
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inline unsigned char* bf_write::GetData()
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{
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return (unsigned char*) m_pData;
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}
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inline const unsigned char* bf_write::GetData() const
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{
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return (unsigned char*) m_pData;
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}
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BITBUF_INLINE bool bf_write::CheckForOverflow(int nBits)
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{
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if ( m_iCurBit + nBits > m_nDataBits )
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{
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SetOverflowFlag();
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CallErrorHandler( BITBUFERROR_BUFFER_OVERRUN, GetDebugName() );
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}
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return m_bOverflow;
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}
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BITBUF_INLINE void bf_write::SetOverflowFlag() RESTRICT
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{
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#ifdef DBGFLAG_ASSERT
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if ( m_bAssertOnOverflow )
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{
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Assert( false );
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}
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#endif
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m_bOverflow = true;
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}
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BITBUF_INLINE void bf_write::WriteOneBitNoCheck(int nValue)
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{
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#if __i386__
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if(nValue)
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m_pData[m_iCurBit >> 5] |= 1u << (m_iCurBit & 31);
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else
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m_pData[m_iCurBit >> 5] &= ~(1u << (m_iCurBit & 31));
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#else
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extern unsigned long g_LittleBits[32];
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if(nValue)
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m_pData[m_iCurBit >> 5] |= g_LittleBits[m_iCurBit & 31];
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else
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m_pData[m_iCurBit >> 5] &= ~g_LittleBits[m_iCurBit & 31];
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#endif
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++m_iCurBit;
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}
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inline void bf_write::WriteOneBit(int nValue)
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{
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if( m_iCurBit >= m_nDataBits )
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{
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SetOverflowFlag();
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CallErrorHandler( BITBUFERROR_BUFFER_OVERRUN, GetDebugName() );
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return;
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}
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WriteOneBitNoCheck( nValue );
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}
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inline void bf_write::WriteOneBitAt( int iBit, int nValue )
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{
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if( iBit >= m_nDataBits )
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{
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SetOverflowFlag();
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CallErrorHandler( BITBUFERROR_BUFFER_OVERRUN, GetDebugName() );
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return;
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}
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#if __i386__
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if(nValue)
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m_pData[iBit >> 5] |= 1u << (iBit & 31);
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else
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m_pData[iBit >> 5] &= ~(1u << (iBit & 31));
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#else
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extern unsigned long g_LittleBits[32];
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if(nValue)
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m_pData[iBit >> 5] |= g_LittleBits[iBit & 31];
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else
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m_pData[iBit >> 5] &= ~g_LittleBits[iBit & 31];
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#endif
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}
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BITBUF_INLINE void bf_write::WriteUBitLong( unsigned int curData, int numbits, bool bCheckRange ) RESTRICT
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{
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#ifdef _DEBUG
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// Make sure it doesn't overflow.
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if ( bCheckRange && numbits < 32 )
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{
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if ( curData >= (unsigned long)(1 << numbits) )
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{
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CallErrorHandler( BITBUFERROR_VALUE_OUT_OF_RANGE, GetDebugName() );
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}
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}
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Assert( numbits >= 0 && numbits <= 32 );
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#endif
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if ( GetNumBitsLeft() < numbits )
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{
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m_iCurBit = m_nDataBits;
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SetOverflowFlag();
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CallErrorHandler( BITBUFERROR_BUFFER_OVERRUN, GetDebugName() );
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return;
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}
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int iCurBitMasked = m_iCurBit & 31;
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int iDWord = m_iCurBit >> 5;
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m_iCurBit += numbits;
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// Mask in a dword.
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Assert( (iDWord*4 + sizeof(long)) <= (unsigned int)m_nDataBytes );
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unsigned long * RESTRICT pOut = &m_pData[iDWord];
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// Rotate data into dword alignment
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curData = (curData << iCurBitMasked) | (curData >> (32 - iCurBitMasked));
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// Calculate bitmasks for first and second word
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unsigned int temp = 1 << (numbits-1);
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unsigned int mask1 = (temp*2-1) << iCurBitMasked;
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unsigned int mask2 = (temp-1) >> (31 - iCurBitMasked);
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// Only look beyond current word if necessary (avoid access violation)
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int i = mask2 & 1;
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unsigned long dword1 = LoadLittleDWord( pOut, 0 );
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unsigned long dword2 = LoadLittleDWord( pOut, i );
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// Drop bits into place
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dword1 ^= ( mask1 & ( curData ^ dword1 ) );
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dword2 ^= ( mask2 & ( curData ^ dword2 ) );
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// Note reversed order of writes so that dword1 wins if mask2 == 0 && i == 0
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StoreLittleDWord( pOut, i, dword2 );
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StoreLittleDWord( pOut, 0, dword1 );
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}
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// writes an unsigned integer with variable bit length
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BITBUF_INLINE void bf_write::WriteUBitVar( unsigned int data )
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{
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/* Reference:
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if ( data < 0x10u )
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WriteUBitLong( 0, 2 ), WriteUBitLong( data, 4 );
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else if ( data < 0x100u )
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WriteUBitLong( 1, 2 ), WriteUBitLong( data, 8 );
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else if ( data < 0x1000u )
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WriteUBitLong( 2, 2 ), WriteUBitLong( data, 12 );
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else
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WriteUBitLong( 3, 2 ), WriteUBitLong( data, 32 );
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*/
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// a < b ? -1 : 0 translates into a CMP, SBB instruction pair
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// with no flow control. should also be branchless on consoles.
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int n = (data < 0x10u ? -1 : 0) + (data < 0x100u ? -1 : 0) + (data < 0x1000u ? -1 : 0);
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WriteUBitLong( data*4 + n + 3, 6 + n*4 + 12 );
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if ( data >= 0x1000u )
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{
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WriteUBitLong( data >> 16, 16 );
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}
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}
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// write raw IEEE float bits in little endian form
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BITBUF_INLINE void bf_write::WriteBitFloat(float val)
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{
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int32 intVal;
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Assert(sizeof(long) == sizeof(float));
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Assert(sizeof(float) == 4);
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Q_memcpy( &intVal, &val, sizeof(intVal));
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WriteUBitLong( intVal, 32 );
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}
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//-----------------------------------------------------------------------------
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// This is useful if you just want a buffer to write into on the stack.
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//-----------------------------------------------------------------------------
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template<int SIZE>
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class old_bf_write_static : public bf_write
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{
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public:
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inline old_bf_write_static() : bf_write(m_StaticData, SIZE) {}
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char m_StaticData[SIZE];
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};
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//-----------------------------------------------------------------------------
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// Used for unserialization
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//-----------------------------------------------------------------------------
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class bf_read
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{
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public:
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bf_read();
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// nMaxBits can be used as the number of bits in the buffer.
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// It must be <= nBytes*8. If you leave it at -1, then it's set to nBytes * 8.
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bf_read( const void *pData, int nBytes, int nBits = -1 );
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bf_read( const char *pDebugName, const void *pData, int nBytes, int nBits = -1 );
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// Start reading from the specified buffer.
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// pData's start address must be dword-aligned.
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// nMaxBits can be used as the number of bits in the buffer.
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// It must be <= nBytes*8. If you leave it at -1, then it's set to nBytes * 8.
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void StartReading( const void *pData, int nBytes, int iStartBit = 0, int nBits = -1 );
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// Restart buffer reading.
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void Reset();
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// Enable or disable assertion on overflow. 99% of the time, it's a bug that we need to catch,
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// but there may be the occasional buffer that is allowed to overflow gracefully.
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void SetAssertOnOverflow( bool bAssert );
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// This can be set to assign a name that gets output if the buffer overflows.
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const char* GetDebugName() const { return m_pDebugName; }
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void SetDebugName( const char *pName );
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void ExciseBits( int startbit, int bitstoremove );
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// Bit functions.
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public:
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// Returns 0 or 1.
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int ReadOneBit();
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protected:
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unsigned int CheckReadUBitLong(int numbits); // For debugging.
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int ReadOneBitNoCheck(); // Faster version, doesn't check bounds and is inlined.
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bool CheckForOverflow(int nBits);
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public:
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// Get the base pointer.
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const unsigned char* GetBasePointer() { return m_pData; }
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BITBUF_INLINE int TotalBytesAvailable( void ) const
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{
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return m_nDataBytes;
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}
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// Read a list of bits in.
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void ReadBits(void *pOut, int nBits);
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// Read a list of bits in, but don't overrun the destination buffer.
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// Returns the number of bits read into the buffer. The remaining
|
|
// bits are skipped over.
|
|
int ReadBitsClamped_ptr(void *pOut, size_t outSizeBytes, size_t nBits);
|
|
// Helper 'safe' template function that infers the size of the destination
|
|
// array. This version of the function should be preferred.
|
|
// Usage: char databuffer[100];
|
|
// ReadBitsClamped( dataBuffer, msg->m_nLength );
|
|
template <typename T, size_t N>
|
|
int ReadBitsClamped( T (&pOut)[N], size_t nBits )
|
|
{
|
|
return ReadBitsClamped_ptr( pOut, N * sizeof(T), nBits );
|
|
}
|
|
|
|
float ReadBitAngle( int numbits );
|
|
|
|
unsigned int ReadUBitLong( int numbits ) RESTRICT;
|
|
unsigned int ReadUBitLongNoInline( int numbits ) RESTRICT;
|
|
unsigned int PeekUBitLong( int numbits );
|
|
int ReadSBitLong( int numbits );
|
|
|
|
// reads an unsigned integer with variable bit length
|
|
unsigned int ReadUBitVar();
|
|
unsigned int ReadUBitVarInternal( int encodingType );
|
|
|
|
// reads a varint encoded integer
|
|
uint32 ReadVarInt32();
|
|
uint64 ReadVarInt64();
|
|
int32 ReadSignedVarInt32();
|
|
int64 ReadSignedVarInt64();
|
|
|
|
// You can read signed or unsigned data with this, just cast to
|
|
// a signed int if necessary.
|
|
unsigned int ReadBitLong(int numbits, bool bSigned);
|
|
|
|
float ReadBitCoord();
|
|
float ReadBitCoordMP( bool bIntegral, bool bLowPrecision );
|
|
float ReadBitFloat();
|
|
float ReadBitNormal();
|
|
void ReadBitVec3Coord( Vector& fa );
|
|
void ReadBitVec3Normal( Vector& fa );
|
|
void ReadBitAngles( QAngle& fa );
|
|
|
|
// Faster for comparisons but do not fully decode float values
|
|
unsigned int ReadBitCoordBits();
|
|
unsigned int ReadBitCoordMPBits( bool bIntegral, bool bLowPrecision );
|
|
|
|
// Byte functions (these still read data in bit-by-bit).
|
|
public:
|
|
|
|
BITBUF_INLINE int ReadChar() { return (char)ReadUBitLong(8); }
|
|
BITBUF_INLINE int ReadByte() { return ReadUBitLong(8); }
|
|
BITBUF_INLINE int ReadShort() { return (short)ReadUBitLong(16); }
|
|
BITBUF_INLINE int ReadWord() { return ReadUBitLong(16); }
|
|
BITBUF_INLINE long ReadLong() { return ReadUBitLong(32); }
|
|
int64 ReadLongLong();
|
|
float ReadFloat();
|
|
bool ReadBytes(void *pOut, int nBytes);
|
|
|
|
// Returns false if bufLen isn't large enough to hold the
|
|
// string in the buffer.
|
|
//
|
|
// Always reads to the end of the string (so you can read the
|
|
// next piece of data waiting).
|
|
//
|
|
// If bLine is true, it stops when it reaches a '\n' or a null-terminator.
|
|
//
|
|
// pStr is always null-terminated (unless bufLen is 0).
|
|
//
|
|
// pOutNumChars is set to the number of characters left in pStr when the routine is
|
|
// complete (this will never exceed bufLen-1).
|
|
//
|
|
bool ReadString( char *pStr, int bufLen, bool bLine=false, int *pOutNumChars=NULL );
|
|
|
|
// Reads a string and allocates memory for it. If the string in the buffer
|
|
// is > 2048 bytes, then pOverflow is set to true (if it's not NULL).
|
|
char* ReadAndAllocateString( bool *pOverflow = 0 );
|
|
|
|
// Returns nonzero if any bits differ
|
|
int CompareBits( bf_read * RESTRICT other, int bits ) RESTRICT;
|
|
int CompareBitsAt( int offset, bf_read * RESTRICT other, int otherOffset, int bits ) RESTRICT;
|
|
|
|
// Status.
|
|
public:
|
|
int GetNumBytesLeft();
|
|
int GetNumBytesRead();
|
|
int GetNumBitsLeft() RESTRICT;
|
|
int GetNumBitsRead() const;
|
|
|
|
// Has the buffer overflowed?
|
|
inline bool IsOverflowed() const {return m_bOverflow;}
|
|
|
|
inline bool Seek(int iBit); // Seek to a specific bit.
|
|
inline bool SeekRelative(int iBitDelta); // Seek to an offset from the current position.
|
|
|
|
// Called when the buffer is overflowed.
|
|
void SetOverflowFlag() RESTRICT;
|
|
|
|
|
|
public:
|
|
|
|
// The current buffer.
|
|
const unsigned char* RESTRICT m_pData;
|
|
int m_nDataBytes;
|
|
int m_nDataBits;
|
|
|
|
// Where we are in the buffer.
|
|
int m_iCurBit;
|
|
|
|
|
|
private:
|
|
// Errors?
|
|
bool m_bOverflow;
|
|
|
|
// For debugging..
|
|
bool m_bAssertOnOverflow;
|
|
|
|
const char *m_pDebugName;
|
|
};
|
|
|
|
//-----------------------------------------------------------------------------
|
|
// Inlines.
|
|
//-----------------------------------------------------------------------------
|
|
|
|
inline int bf_read::GetNumBytesRead()
|
|
{
|
|
return BitByte(m_iCurBit);
|
|
}
|
|
|
|
inline int bf_read::GetNumBitsLeft() RESTRICT
|
|
{
|
|
return m_nDataBits - m_iCurBit;
|
|
}
|
|
|
|
inline int bf_read::GetNumBytesLeft()
|
|
{
|
|
return GetNumBitsLeft() >> 3;
|
|
}
|
|
|
|
inline int bf_read::GetNumBitsRead() const
|
|
{
|
|
return m_iCurBit;
|
|
}
|
|
|
|
inline bool bf_read::Seek(int iBit)
|
|
{
|
|
if(iBit < 0 || iBit > m_nDataBits)
|
|
{
|
|
SetOverflowFlag();
|
|
m_iCurBit = m_nDataBits;
|
|
return false;
|
|
}
|
|
else
|
|
{
|
|
m_iCurBit = iBit;
|
|
return true;
|
|
}
|
|
}
|
|
|
|
// Seek to an offset from the current position.
|
|
inline bool bf_read::SeekRelative(int iBitDelta)
|
|
{
|
|
return Seek(m_iCurBit+iBitDelta);
|
|
}
|
|
|
|
inline bool bf_read::CheckForOverflow(int nBits)
|
|
{
|
|
if( m_iCurBit + nBits > m_nDataBits )
|
|
{
|
|
SetOverflowFlag();
|
|
CallErrorHandler( BITBUFERROR_BUFFER_OVERRUN, GetDebugName() );
|
|
}
|
|
|
|
return m_bOverflow;
|
|
}
|
|
|
|
inline int bf_read::ReadOneBitNoCheck()
|
|
{
|
|
#if VALVE_LITTLE_ENDIAN
|
|
unsigned int value = ((unsigned long * RESTRICT)m_pData)[m_iCurBit >> 5] >> (m_iCurBit & 31);
|
|
#else
|
|
unsigned char value = m_pData[m_iCurBit >> 3] >> (m_iCurBit & 7);
|
|
#endif
|
|
++m_iCurBit;
|
|
return value & 1;
|
|
}
|
|
|
|
inline int bf_read::ReadOneBit()
|
|
{
|
|
if( GetNumBitsLeft() <= 0 )
|
|
{
|
|
SetOverflowFlag();
|
|
CallErrorHandler( BITBUFERROR_BUFFER_OVERRUN, GetDebugName() );
|
|
return 0;
|
|
}
|
|
return ReadOneBitNoCheck();
|
|
}
|
|
|
|
inline float bf_read::ReadBitFloat()
|
|
{
|
|
union { uint32 u; float f; } c = { ReadUBitLong(32) };
|
|
return c.f;
|
|
}
|
|
|
|
BITBUF_INLINE unsigned int bf_read::ReadUBitVar()
|
|
{
|
|
// six bits: low 2 bits for encoding + first 4 bits of value
|
|
unsigned int sixbits = ReadUBitLong(6);
|
|
unsigned int encoding = sixbits & 3;
|
|
if ( encoding )
|
|
{
|
|
// this function will seek back four bits and read the full value
|
|
return ReadUBitVarInternal( encoding );
|
|
}
|
|
return sixbits >> 2;
|
|
}
|
|
|
|
BITBUF_INLINE unsigned int bf_read::ReadUBitLong( int numbits ) RESTRICT
|
|
{
|
|
Assert( numbits > 0 && numbits <= 32 );
|
|
|
|
if ( GetNumBitsLeft() < numbits )
|
|
{
|
|
m_iCurBit = m_nDataBits;
|
|
SetOverflowFlag();
|
|
CallErrorHandler( BITBUFERROR_BUFFER_OVERRUN, GetDebugName() );
|
|
return 0;
|
|
}
|
|
|
|
unsigned int iStartBit = m_iCurBit & 31u;
|
|
int iLastBit = m_iCurBit + numbits - 1;
|
|
unsigned int iWordOffset1 = m_iCurBit >> 5;
|
|
unsigned int iWordOffset2 = iLastBit >> 5;
|
|
m_iCurBit += numbits;
|
|
|
|
#if __i386__
|
|
unsigned int bitmask = (2 << (numbits-1)) - 1;
|
|
#else
|
|
extern unsigned long g_ExtraMasks[33];
|
|
unsigned int bitmask = g_ExtraMasks[numbits];
|
|
#endif
|
|
|
|
unsigned int dw1 = LoadLittleDWord( (unsigned long* RESTRICT)m_pData, iWordOffset1 ) >> iStartBit;
|
|
unsigned int dw2 = LoadLittleDWord( (unsigned long* RESTRICT)m_pData, iWordOffset2 ) << (32 - iStartBit);
|
|
|
|
return (dw1 | dw2) & bitmask;
|
|
}
|
|
|
|
BITBUF_INLINE int bf_read::CompareBits( bf_read * RESTRICT other, int numbits ) RESTRICT
|
|
{
|
|
return (ReadUBitLong(numbits) != other->ReadUBitLong(numbits));
|
|
}
|
|
|
|
|
|
#endif
|
|
|
|
|
|
|