DarkflameServer/thirdparty/raknet/Source/BitStream_NoTemplate.cpp

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/// \file
///
/// This file is part of RakNet Copyright 2003 Kevin Jenkins.
///
/// Usage of RakNet is subject to the appropriate license agreement.
/// Creative Commons Licensees are subject to the
/// license found at
/// http://creativecommons.org/licenses/by-nc/2.5/
/// Single application licensees are subject to the license found at
/// http://www.jenkinssoftware.com/SingleApplicationLicense.html
/// Custom license users are subject to the terms therein.
/// GPL license users are subject to the GNU General Public
/// License as published by the Free
/// Software Foundation; either version 2 of the License, or (at your
/// option) any later version.
#if defined(_MSC_VER) && _MSC_VER < 1299 // VC6 doesn't support template specialization
#include "BitStream.h"
#include <stdlib.h>
#include <memory.h>
#include <stdio.h>
#include <string.h>
#include <cmath>
#include <float.h>
#ifdef _XBOX360
#include "Console1Includes.h"
#elif defined(_WIN32)
#include <winsock2.h> // htonl
#elif defined(_CONSOLE_2)
#include "Console2Includes.h"
#else
#include <arpa/inet.h>
#endif
// MSWin uses _copysign, others use copysign...
#ifndef _WIN32
#define _copysign copysign
#endif
using namespace RakNet;
#ifdef _MSC_VER
#pragma warning( push )
#endif
BitStream::BitStream()
{
numberOfBitsUsed = 0;
//numberOfBitsAllocated = 32 * 8;
numberOfBitsAllocated = BITSTREAM_STACK_ALLOCATION_SIZE * 8;
readOffset = 0;
//data = ( unsigned char* ) rakMalloc( 32 );
data = ( unsigned char* ) stackData;
#ifdef _DEBUG
// assert( data );
#endif
//memset(data, 0, 32);
copyData = true;
}
BitStream::BitStream( int initialBytesToAllocate )
{
numberOfBitsUsed = 0;
readOffset = 0;
if (initialBytesToAllocate <= BITSTREAM_STACK_ALLOCATION_SIZE)
{
data = ( unsigned char* ) stackData;
numberOfBitsAllocated = BITSTREAM_STACK_ALLOCATION_SIZE * 8;
}
else
{
data = ( unsigned char* ) malloc( initialBytesToAllocate );
numberOfBitsAllocated = initialBytesToAllocate << 3;
}
#ifdef _DEBUG
assert( data );
#endif
// memset(data, 0, initialBytesToAllocate);
copyData = true;
}
BitStream::BitStream( unsigned char* _data, unsigned int lengthInBytes, bool _copyData )
{
numberOfBitsUsed = lengthInBytes << 3;
readOffset = 0;
copyData = _copyData;
numberOfBitsAllocated = lengthInBytes << 3;
if ( copyData )
{
if ( lengthInBytes > 0 )
{
if (lengthInBytes < BITSTREAM_STACK_ALLOCATION_SIZE)
{
data = ( unsigned char* ) stackData;
numberOfBitsAllocated = BITSTREAM_STACK_ALLOCATION_SIZE << 3;
}
else
{
data = ( unsigned char* ) malloc( lengthInBytes );
}
#ifdef _DEBUG
assert( data );
#endif
memcpy( data, _data, lengthInBytes );
}
else
data = 0;
}
else
data = ( unsigned char* ) _data;
}
// Use this if you pass a pointer copy to the constructor (_copyData==false) and want to overallocate to prevent reallocation
void BitStream::SetNumberOfBitsAllocated( const unsigned int lengthInBits )
{
#ifdef _DEBUG
assert( lengthInBits >= ( unsigned int ) numberOfBitsAllocated );
#endif
numberOfBitsAllocated = lengthInBits;
}
BitStream::~BitStream()
{
if ( copyData && numberOfBitsAllocated > (BITSTREAM_STACK_ALLOCATION_SIZE << 3))
RakFree( data ); // Use realloc and free so we are more efficient than delete and new for resizing
}
void BitStream::Reset( void )
{
// Note: Do NOT reallocate memory because BitStream is used
// in places to serialize/deserialize a buffer. Reallocation
// is a dangerous operation (may result in leaks).
if ( numberOfBitsUsed > 0 )
{
// memset(data, 0, BITS_TO_BYTES(numberOfBitsUsed));
}
// Don't free memory here for speed efficiency
//free(data); // Use realloc and free so we are more efficient than delete and new for resizing
numberOfBitsUsed = 0;
//numberOfBitsAllocated=8;
readOffset = 0;
//data=(unsigned char*)rakMalloc(1);
// if (numberOfBitsAllocated>0)
// memset(data, 0, BITS_TO_BYTES(numberOfBitsAllocated));
}
// Write an array or casted stream
void BitStream::Write( const char* input, const int numberOfBytes )
{
if (numberOfBytes==0)
return;
// Optimization:
if ((numberOfBitsUsed & 7) == 0)
{
AddBitsAndReallocate( BYTES_TO_BITS(numberOfBytes) );
memcpy(data+BITS_TO_BYTES(numberOfBitsUsed), input, numberOfBytes);
numberOfBitsUsed+=BYTES_TO_BITS(numberOfBytes);
}
else
{
WriteBits( ( unsigned char* ) input, numberOfBytes * 8, true );
}
}
void BitStream::Write( BitStream *bitStream)
{
Write(bitStream, bitStream->GetNumberOfBitsUsed());
}
void BitStream::Write( BitStream *bitStream, int numberOfBits )
{
AddBitsAndReallocate( numberOfBits );
int numberOfBitsMod8;
while (numberOfBits-->0 && bitStream->readOffset + 1 <= bitStream->numberOfBitsUsed)
{
numberOfBitsMod8 = numberOfBitsUsed & 7;
if ( numberOfBitsMod8 == 0 )
{
// New byte
if (bitStream->data[ bitStream->readOffset >> 3 ] & ( 0x80 >> ( bitStream->readOffset & 7 ) ) )
{
// Write 1
data[ numberOfBitsUsed >> 3 ] = 0x80;
}
else
{
// Write 0
data[ numberOfBitsUsed >> 3 ] = 0;
}
}
else
{
// Existing byte
if (bitStream->data[ bitStream->readOffset >> 3 ] & ( 0x80 >> ( bitStream->readOffset & 7 ) ) )
data[ numberOfBitsUsed >> 3 ] |= 0x80 >> ( numberOfBitsMod8 ); // Set the bit to 1
// else 0, do nothing
}
bitStream->readOffset++;
numberOfBitsUsed++;
}
}
// Read an array or casted stream
bool BitStream::Read( char* output, const int numberOfBytes )
{
// Optimization:
if ((readOffset & 7) == 0)
{
if ( readOffset + ( numberOfBytes << 3 ) > numberOfBitsUsed )
return false;
// Write the data
memcpy( output, data + ( readOffset >> 3 ), numberOfBytes );
readOffset += numberOfBytes << 3;
return true;
}
else
{
return ReadBits( ( unsigned char* ) output, numberOfBytes * 8 );
}
}
// Sets the read pointer back to the beginning of your data.
void BitStream::ResetReadPointer( void )
{
readOffset = 0;
}
// Sets the write pointer back to the beginning of your data.
void BitStream::ResetWritePointer( void )
{
numberOfBitsUsed = 0;
}
// Write a 0
void BitStream::Write0( void )
{
AddBitsAndReallocate( 1 );
// New bytes need to be zeroed
if ( ( numberOfBitsUsed & 7 ) == 0 )
data[ numberOfBitsUsed >> 3 ] = 0;
numberOfBitsUsed++;
}
// Write a 1
void BitStream::Write1( void )
{
AddBitsAndReallocate( 1 );
int numberOfBitsMod8 = numberOfBitsUsed & 7;
if ( numberOfBitsMod8 == 0 )
data[ numberOfBitsUsed >> 3 ] = 0x80;
else
data[ numberOfBitsUsed >> 3 ] |= 0x80 >> ( numberOfBitsMod8 ); // Set the bit to 1
numberOfBitsUsed++;
}
#ifdef _MSC_VER
#pragma warning( disable : 4800 ) // warning C4100: <variable name> : unreferenced formal parameter
#endif
// Returns true if the next data read is a 1, false if it is a 0
bool BitStream::ReadBit( void )
{
bool result = ( data[ readOffset >> 3 ] & ( 0x80 >> ( readOffset & 7 ) ) );
readOffset++;
return result;
}
// Align the bitstream to the byte boundary and then write the specified number of bits.
// This is faster than WriteBits but wastes the bits to do the alignment and requires you to call
// SetReadToByteAlignment at the corresponding read position
void BitStream::WriteAlignedBytes( void* input, const int numberOfBytesToWrite )
{
#ifdef _DEBUG
if (numberOfBytesToWrite<=0)
{
assert( numberOfBytesToWrite > 0 );
}
#endif
AlignWriteToByteBoundary();
Write((const char*) input, numberOfBytesToWrite);
}
/// Aligns the bitstream, writes inputLength, and writes input. Won't write beyond maxBytesToWrite
void BitStream::WriteAlignedBytesSafe( void *input, const int inputLength, const int maxBytesToWrite )
{
if (input==0 || inputLength==0)
{
WriteCompressed((unsigned int)0);
return;
}
WriteCompressed(inputLength);
WriteAlignedBytes((void*) input, inputLength < maxBytesToWrite ? inputLength : maxBytesToWrite);
}
// Read bits, starting at the next aligned bits. Note that the modulus 8 starting offset of the
// sequence must be the same as was used with WriteBits. This will be a problem with packet coalescence
// unless you byte align the coalesced packets.
bool BitStream::ReadAlignedBytes( void* output, const int numberOfBytesToRead )
{
#ifdef _DEBUG
assert( numberOfBytesToRead > 0 );
#endif
if ( numberOfBytesToRead <= 0 )
return false;
// Byte align
AlignReadToByteBoundary();
if ( readOffset + ( numberOfBytesToRead << 3 ) > numberOfBitsUsed )
return false;
// Write the data
memcpy( output, data + ( readOffset >> 3 ), numberOfBytesToRead );
readOffset += numberOfBytesToRead << 3;
return true;
}
bool BitStream::ReadAlignedBytesSafe( void *input, int &inputLength, const int maxBytesToRead )
{
if (ReadCompressed(inputLength)==false)
return false;
if (inputLength > maxBytesToRead)
inputLength=maxBytesToRead;
if (inputLength==0)
return true;
return ReadAlignedBytes((unsigned char*) input, inputLength);
}
bool BitStream::ReadAlignedBytesSafeAlloc( char **input, int &inputLength, const int maxBytesToRead )
{
rakFree(*input);
*input=0;
if (ReadCompressed(inputLength)==false)
return false;
if (inputLength > maxBytesToRead)
inputLength=maxBytesToRead;
if (inputLength==0)
return true;
*input = (char*) rakMalloc( BITS_TO_BYTES( inputLength ) );
return ReadAlignedBytes((unsigned char*) *input, inputLength);
}
// Align the next write and/or read to a byte boundary. This can be used to 'waste' bits to byte align for efficiency reasons
void BitStream::AlignWriteToByteBoundary( void )
{
if ( numberOfBitsUsed )
numberOfBitsUsed += 8 - ( (( numberOfBitsUsed - 1 ) & 7) + 1 );
}
// Align the next write and/or read to a byte boundary. This can be used to 'waste' bits to byte align for efficiency reasons
void BitStream::AlignReadToByteBoundary( void )
{
if ( readOffset )
readOffset += 8 - ( (( readOffset - 1 ) & 7 ) + 1 );
}
// Write numberToWrite bits from the input source
void BitStream::WriteBits( const unsigned char *input, int numberOfBitsToWrite, const bool rightAlignedBits )
{
if (numberOfBitsToWrite<=0)
return;
AddBitsAndReallocate( numberOfBitsToWrite );
int offset = 0;
unsigned char dataByte;
int numberOfBitsUsedMod8;
numberOfBitsUsedMod8 = numberOfBitsUsed & 7;
// Faster to put the while at the top surprisingly enough
while ( numberOfBitsToWrite > 0 )
//do
{
dataByte = *( input + offset );
if ( numberOfBitsToWrite < 8 && rightAlignedBits ) // rightAlignedBits means in the case of a partial byte, the bits are aligned from the right (bit 0) rather than the left (as in the normal internal representation)
dataByte <<= 8 - numberOfBitsToWrite; // shift left to get the bits on the left, as in our internal representation
// Writing to a new byte each time
if ( numberOfBitsUsedMod8 == 0 )
* ( data + ( numberOfBitsUsed >> 3 ) ) = dataByte;
else
{
// Copy over the new data.
*( data + ( numberOfBitsUsed >> 3 ) ) |= dataByte >> ( numberOfBitsUsedMod8 ); // First half
if ( 8 - ( numberOfBitsUsedMod8 ) < 8 && 8 - ( numberOfBitsUsedMod8 ) < numberOfBitsToWrite ) // If we didn't write it all out in the first half (8 - (numberOfBitsUsed%8) is the number we wrote in the first half)
{
*( data + ( numberOfBitsUsed >> 3 ) + 1 ) = (unsigned char) ( dataByte << ( 8 - ( numberOfBitsUsedMod8 ) ) ); // Second half (overlaps byte boundary)
}
}
if ( numberOfBitsToWrite >= 8 )
numberOfBitsUsed += 8;
else
numberOfBitsUsed += numberOfBitsToWrite;
numberOfBitsToWrite -= 8;
offset++;
}
// } while(numberOfBitsToWrite>0);
}
// Set the stream to some initial data. For internal use
void BitStream::SetData( unsigned char *input )
{
data=input;
copyData=false;
}
// Assume the input source points to a native type, compress and write it
void BitStream::WriteCompressed( const unsigned char* input,
const int size, const bool unsignedData )
{
int currentByte = ( size >> 3 ) - 1; // PCs
unsigned char byteMatch;
if ( unsignedData )
{
byteMatch = 0;
}
else
{
byteMatch = 0xFF;
}
// Write upper bytes with a single 1
// From high byte to low byte, if high byte is a byteMatch then write a 1 bit. Otherwise write a 0 bit and then write the remaining bytes
while ( currentByte > 0 )
{
if ( input[ currentByte ] == byteMatch ) // If high byte is byteMatch (0 of 0xff) then it would have the same value shifted
{
bool b = true;
Write( b );
}
else
{
// Write the remainder of the data after writing 0
bool b = false;
Write( b );
WriteBits( input, ( currentByte + 1 ) << 3, true );
// currentByte--;
return ;
}
currentByte--;
}
// If the upper half of the last byte is a 0 (positive) or 16 (negative) then write a 1 and the remaining 4 bits. Otherwise write a 0 and the 8 bites.
if ( ( unsignedData && ( ( *( input + currentByte ) ) & 0xF0 ) == 0x00 ) ||
( unsignedData == false && ( ( *( input + currentByte ) ) & 0xF0 ) == 0xF0 ) )
{
bool b = true;
Write( b );
WriteBits( input + currentByte, 4, true );
}
else
{
bool b = false;
Write( b );
WriteBits( input + currentByte, 8, true );
}
}
// Read numberOfBitsToRead bits to the output source
// alignBitsToRight should be set to true to convert internal bitstream data to userdata
// It should be false if you used WriteBits with rightAlignedBits false
bool BitStream::ReadBits( unsigned char* output, int numberOfBitsToRead, const bool alignBitsToRight )
{
#ifdef _DEBUG
// assert( numberOfBitsToRead > 0 );
#endif
if (numberOfBitsToRead<=0)
return false;
if ( readOffset + numberOfBitsToRead > numberOfBitsUsed )
return false;
int readOffsetMod8;
int offset = 0;
memset( output, 0, BITS_TO_BYTES( numberOfBitsToRead ) );
readOffsetMod8 = readOffset & 7;
// do
// Faster to put the while at the top surprisingly enough
while ( numberOfBitsToRead > 0 )
{
*( output + offset ) |= *( data + ( readOffset >> 3 ) ) << ( readOffsetMod8 ); // First half
if ( readOffsetMod8 > 0 && numberOfBitsToRead > 8 - ( readOffsetMod8 ) ) // If we have a second half, we didn't read enough bytes in the first half
*( output + offset ) |= *( data + ( readOffset >> 3 ) + 1 ) >> ( 8 - ( readOffsetMod8 ) ); // Second half (overlaps byte boundary)
numberOfBitsToRead -= 8;
if ( numberOfBitsToRead < 0 ) // Reading a partial byte for the last byte, shift right so the data is aligned on the right
{
if ( alignBitsToRight )
* ( output + offset ) >>= -numberOfBitsToRead;
readOffset += 8 + numberOfBitsToRead;
}
else
readOffset += 8;
offset++;
}
//} while(numberOfBitsToRead>0);
return true;
}
// Assume the input source points to a compressed native type. Decompress and read it
bool BitStream::ReadCompressed( unsigned char* output,
const int size, const bool unsignedData )
{
int currentByte = ( size >> 3 ) - 1;
unsigned char byteMatch, halfByteMatch;
if ( unsignedData )
{
byteMatch = 0;
halfByteMatch = 0;
}
else
{
byteMatch = 0xFF;
halfByteMatch = 0xF0;
}
// Upper bytes are specified with a single 1 if they match byteMatch
// From high byte to low byte, if high byte is a byteMatch then write a 1 bit. Otherwise write a 0 bit and then write the remaining bytes
while ( currentByte > 0 )
{
// If we read a 1 then the data is byteMatch.
bool b;
if ( Read( b ) == false )
return false;
if ( b ) // Check that bit
{
output[ currentByte ] = byteMatch;
currentByte--;
}
else
{
// Read the rest of the bytes
if ( ReadBits( output, ( currentByte + 1 ) << 3 ) == false )
return false;
return true;
}
}
// All but the first bytes are byteMatch. If the upper half of the last byte is a 0 (positive) or 16 (negative) then what we read will be a 1 and the remaining 4 bits.
// Otherwise we read a 0 and the 8 bytes
//assert(readOffset+1 <=numberOfBitsUsed); // If this assert is hit the stream wasn't long enough to read from
if ( readOffset + 1 > numberOfBitsUsed )
return false;
bool b;
if ( Read( b ) == false )
return false;
if ( b ) // Check that bit
{
if ( ReadBits( output + currentByte, 4 ) == false )
return false;
output[ currentByte ] |= halfByteMatch; // We have to set the high 4 bits since these are set to 0 by ReadBits
}
else
{
if ( ReadBits( output + currentByte, 8 ) == false )
return false;
}
return true;
}
// Reallocates (if necessary) in preparation of writing numberOfBitsToWrite
void BitStream::AddBitsAndReallocate( const int numberOfBitsToWrite )
{
if (numberOfBitsToWrite <= 0)
return;
int newNumberOfBitsAllocated = numberOfBitsToWrite + numberOfBitsUsed;
if ( numberOfBitsToWrite + numberOfBitsUsed > 0 && ( ( numberOfBitsAllocated - 1 ) >> 3 ) < ( ( newNumberOfBitsAllocated - 1 ) >> 3 ) ) // If we need to allocate 1 or more new bytes
{
#ifdef _DEBUG
// If this assert hits then we need to specify true for the third parameter in the constructor
// It needs to reallocate to hold all the data and can't do it unless we allocated to begin with
assert( copyData == true );
#endif
// Less memory efficient but saves on news and deletes
newNumberOfBitsAllocated = ( numberOfBitsToWrite + numberOfBitsUsed ) * 2;
// int newByteOffset = BITS_TO_BYTES( numberOfBitsAllocated );
// Use realloc and free so we are more efficient than delete and new for resizing
int amountToAllocate = BITS_TO_BYTES( newNumberOfBitsAllocated );
if (data==(unsigned char*)stackData)
{
if (amountToAllocate > BITSTREAM_STACK_ALLOCATION_SIZE)
{
data = ( unsigned char* ) rakMalloc( amountToAllocate );
// need to copy the stack data over to our new memory area too
memcpy ((void *)data, (void *)stackData, BITS_TO_BYTES( numberOfBitsAllocated ));
}
}
else
{
data = ( unsigned char* ) RakRealloc( data, amountToAllocate );
}
#ifdef _DEBUG
assert( data ); // Make sure realloc succeeded
#endif
// memset(data+newByteOffset, 0, ((newNumberOfBitsAllocated-1)>>3) - ((numberOfBitsAllocated-1)>>3)); // Set the new data block to 0
}
if ( newNumberOfBitsAllocated > numberOfBitsAllocated )
numberOfBitsAllocated = newNumberOfBitsAllocated;
}
unsigned int BitStream::GetNumberOfBitsAllocated(void) const
{
return numberOfBitsAllocated;
}
// Should hit if reads didn't match writes
void BitStream::AssertStreamEmpty( void )
{
assert( readOffset == numberOfBitsUsed );
}
void BitStream::PrintBits( void ) const
{
if ( numberOfBitsUsed <= 0 )
{
printf( "No bits\n" );
return ;
}
for ( int counter = 0; counter < BITS_TO_BYTES( numberOfBitsUsed ); counter++ )
{
int stop;
if ( counter == ( numberOfBitsUsed - 1 ) >> 3 )
stop = 8 - ( ( ( numberOfBitsUsed - 1 ) & 7 ) + 1 );
else
stop = 0;
for ( int counter2 = 7; counter2 >= stop; counter2-- )
{
if ( ( data[ counter ] >> counter2 ) & 1 )
putchar( '1' );
else
putchar( '0' );
}
putchar( ' ' );
}
putchar( '\n' );
}
// Exposes the data for you to look at, like PrintBits does.
// Data will point to the stream. Returns the length in bits of the stream.
int BitStream::CopyData( unsigned char** _data ) const
{
#ifdef _DEBUG
assert( numberOfBitsUsed > 0 );
#endif
*_data = (unsigned char*) rakMalloc( BITS_TO_BYTES( numberOfBitsUsed ) );
memcpy( *_data, data, sizeof(unsigned char) * ( BITS_TO_BYTES( numberOfBitsUsed ) ) );
return numberOfBitsUsed;
}
// Ignore data we don't intend to read
void BitStream::IgnoreBits( const int numberOfBits )
{
readOffset += numberOfBits;
}
void BitStream::IgnoreBytes( const int numberOfBytes )
{
IgnoreBits(BYTES_TO_BITS(numberOfBytes));
}
// Move the write pointer to a position on the array. Dangerous if you don't know what you are doing!
void BitStream::SetWriteOffset( const int offset )
{
numberOfBitsUsed = offset;
}
/*
int BitStream::GetWriteOffset( void ) const
{
return numberOfBitsUsed;
}
// Returns the length in bits of the stream
int BitStream::GetNumberOfBitsUsed( void ) const
{
return GetWriteOffset();
}
// Returns the length in bytes of the stream
int BitStream::GetNumberOfBytesUsed( void ) const
{
return BITS_TO_BYTES( numberOfBitsUsed );
}
// Returns the number of bits into the stream that we have read
int BitStream::GetReadOffset( void ) const
{
return readOffset;
}
// Sets the read bit index
void BitStream::SetReadOffset( int newReadOffset )
{
readOffset=newReadOffset;
}
// Returns the number of bits left in the stream that haven't been read
int BitStream::GetNumberOfUnreadBits( void ) const
{
return numberOfBitsUsed - readOffset;
}
// Exposes the internal data
unsigned char* BitStream::GetData( void ) const
{
return data;
}
*/
// If we used the constructor version with copy data off, this makes sure it is set to on and the data pointed to is copied.
void BitStream::AssertCopyData( void )
{
if ( copyData == false )
{
copyData = true;
if ( numberOfBitsAllocated > 0 )
{
unsigned char * newdata = ( unsigned char* ) rakMalloc( BITS_TO_BYTES( numberOfBitsAllocated ) );
#ifdef _DEBUG
assert( data );
#endif
memcpy( newdata, data, BITS_TO_BYTES( numberOfBitsAllocated ) );
data = newdata;
}
else
data = 0;
}
}
void BitStream::ReverseBytes(unsigned char *input, unsigned char *output, int length)
{
for (int i=0; i < length; i++)
output[i]=input[length-i-1];
}
void BitStream::ReverseBytesInPlace(unsigned char *data, int length)
{
unsigned char temp;
int i;
for (i=0; i < length; i++)
{
temp = data[i];
data[i]=data[length-i-1];
data[length-i-1]=temp;
}
}
bool BitStream::DoEndianSwap(void)
{
#ifndef __BITSTREAM_NATIVE_END
return IsNetworkOrder()==false;
#else
return false;
#endif
}
bool BitStream::IsBigEndian(void)
{
return IsNetworkOrder();
}
bool BitStream::IsNetworkOrder(void)
{
static bool isNetworkOrder=(htonl(12345) == 12345);
return isNetworkOrder;
}
void BitStream::WriteNormVector( float x, float y, float z ){
#ifdef _DEBUG
assert(x <= 1.01 && y <= 1.01 && z <= 1.01 && x >= -1.01 && y >= -1.01 && z >= -1.01);
#endif
if (x>1.0)
x=1.0;
if (y>1.0)
y=1.0;
if (z>1.0)
z=1.0;
if (x<-1.0)
x=-1.0;
if (y<-1.0)
y=-1.0;
if (z<-1.0)
z=-1.0;
Write((bool) (x < 0.0));
if (y==0.0)
Write(true);
else
{
Write(false);
WriteCompressed((float)y);
//Write((unsigned short)((y+1.0f)*32767.5f));
}
if (z==0.0)
Write(true);
else
{
Write(false);
WriteCompressed((float)z);
//Write((unsigned short)((z+1.0f)*32767.5f));
}
}
void BitStream::WriteVector( float x, float y, float z )
{
float magnitude = sqrt(x * x + y * y + z * z);
Write((float)magnitude);
if (magnitude > 0.0)
{
WriteCompressed((float)(x/magnitude));
WriteCompressed((float)(y/magnitude));
WriteCompressed((float)(z/magnitude));
}
}
void BitStream::WriteNormQuat( float w, float x, float y, float z){
Write((bool)(w<0.0));
Write((bool)(x<0.0));
Write((bool)(y<0.0));
Write((bool)(z<0.0));
Write((unsigned short)(fabs(x)*65535.0));
Write((unsigned short)(fabs(y)*65535.0));
Write((unsigned short)(fabs(z)*65535.0));
// Leave out w and calculate it on the target
}
void BitStream::WriteOrthMatrix(
double m00, double m01, double m02,
double m10, double m11, double m12,
double m20, double m21, double m22 ){
double qw;
double qx;
double qy;
double qz;
#ifdef _MSC_VER
#pragma warning(disable:4100) // m10, m01 : unreferenced formal parameter
#endif
// Convert matrix to quat
// http://www.euclideanspace.com/maths/geometry/rotations/conversions/matrixToQuaternion/
double sum;
sum = 1 + m00 + m11 + m22;
if (sum < 0.0f) sum=0.0f;
qw = sqrt( sum ) / 2;
sum = 1 + m00 - m11 - m22;
if (sum < 0.0f) sum=0.0f;
qx = sqrt( sum ) / 2;
sum = 1 - m00 + m11 - m22;
if (sum < 0.0f) sum=0.0f;
qy = sqrt( sum ) / 2;
sum = 1 - m00 - m11 + m22;
if (sum < 0.0f) sum=0.0f;
qz = sqrt( sum ) / 2;
if (qw < 0.0) qw=0.0;
if (qx < 0.0) qx=0.0;
if (qy < 0.0) qy=0.0;
if (qz < 0.0) qz=0.0;
qx = _copysign( qx, m21 - m12 );
qy = _copysign( qy, m02 - m20 );
qz = _copysign( qz, m10 - m01 );
WriteNormQuat(qw,qx,qy,qz);
}
bool BitStream::ReadNormVector( float &x, float &y, float &z ){
// unsigned short sy, sz;
bool yZero, zZero;
bool xNeg;
float cy,cz;
Read(xNeg);
Read(yZero);
if (yZero)
y=0.0;
else
{
ReadCompressed(cy);
y=cy;
//Read(sy);
//y=((float)sy / 32767.5f - 1.0f);
}
if (!Read(zZero))
return false;
if (zZero)
z=0.0;
else
{
// if (!Read(sz))
// return false;
// z=((float)sz / 32767.5f - 1.0f);
if (!ReadCompressed(cz))
return false;
z=cz;
}
x = float (sqrtf((float)1.0 - y*y - z*z));
if (xNeg)
x=-x;
return true;
}
bool BitStream::ReadVector( float x, float y, float z ){
float magnitude;
if (!Read(magnitude))
return false;
if (magnitude!=0.0)
{
float cx,cy,cz;
ReadCompressed(cx);
ReadCompressed(cy);
if (!ReadCompressed(cz))
return false;
x=cx;
y=cy;
z=cz;
x*=magnitude;
y*=magnitude;
z*=magnitude;
}
else
{
x=0.0;
y=0.0;
z=0.0;
}
return true;
}
bool BitStream::ReadNormQuat( double &w, double &x, double &y, double &z){
bool cwNeg, cxNeg, cyNeg, czNeg;
unsigned short cx,cy,cz;
Read(cwNeg);
Read(cxNeg);
Read(cyNeg);
Read(czNeg);
Read(cx);
Read(cy);
if (!Read(cz))
return false;
// Calculate w from x,y,z
x=(double)(cx/65535.0);
y=(double)(cy/65535.0);
z=(double)(cz/65535.0);
if (cxNeg) x=-x;
if (cyNeg) y=-y;
if (czNeg) z=-z;
double difference = 1.0 - x*x - y*y - z*z;
if (difference < 0.0f)
difference=0.0f;
w = (double)(sqrt(difference));
if (cwNeg)
w=-w;
return true;
}
bool BitStream::ReadOrthMatrix(
float &m00, float &m01, float &m02,
float &m10, float &m11, float &m12,
float &m20, float &m21, float &m22 )
{
double _m00, _m01, _m02, _m10, _m11, _m12, _m20, _m21, _m22;
bool b=ReadOrthMatrix(
_m00, _m01, _m02,
_m10, _m11, _m12,
_m20, _m21, _m22);
m00=(float)_m00; m01=(float)_m01; m02=(float)_m02;
m10=(float)_m10; m11=(float)_m11; m12=(float)_m12;
m20=(float)_m20; m21=(float)_m21; m22=(float)_m22;
return b;
}
bool BitStream::ReadOrthMatrix(
double &m00, double &m01, double &m02,
double &m10, double &m11, double &m12,
double &m20, double &m21, double &m22 ){
float qw,qx,qy,qz;
if (!ReadNormQuat(qw,qx,qy,qz))
return false;
// Quat to orthogonal rotation matrix
// http://www.euclideanspace.com/maths/geometry/rotations/conversions/quaternionToMatrix/index.htm
double sqw = (double)qw*(double)qw;
double sqx = (double)qx*(double)qx;
double sqy = (double)qy*(double)qy;
double sqz = (double)qz*(double)qz;
m00 = (sqx - sqy - sqz + sqw); // since sqw + sqx + sqy + sqz =1
m11 = (-sqx + sqy - sqz + sqw);
m22 = (-sqx - sqy + sqz + sqw);
double tmp1 = (double)qx*(double)qy;
double tmp2 = (double)qz*(double)qw;
m10 = (2.0 * (tmp1 + tmp2));
m01 = (2.0 * (tmp1 - tmp2));
tmp1 = (double)qx*(double)qz;
tmp2 = (double)qy*(double)qw;
m20 = (2.0 * (tmp1 - tmp2));
m02 = (2.0 * (tmp1 + tmp2));
tmp1 = (double)qy*(double)qz;
tmp2 = (double)qx*(double)qw;
m21 = (2.0 * (tmp1 + tmp2));
m12 = (2.0 * (tmp1 - tmp2));
return true;
}
#ifdef _MSC_VER
#pragma warning( pop )
#endif
#endif