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// basisu_containers.h
# pragma once
# include <stdlib.h>
# include <stdio.h>
# include <stdint.h>
# include <assert.h>
# include <algorithm>
# if defined(__linux__) && !defined(ANDROID)
// Only for malloc_usable_size() in basisu_containers_impl.h
# include <malloc.h>
# define HAS_MALLOC_USABLE_SIZE 1
# endif
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// Set to 1 to always check vector operator[], front(), and back() even in release.
# define BASISU_VECTOR_FORCE_CHECKING 0
// If 1, the vector container will not query the CRT to get the size of resized memory blocks.
# define BASISU_VECTOR_DETERMINISTIC 1
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# ifdef _MSC_VER
# define BASISU_FORCE_INLINE __forceinline
# else
# define BASISU_FORCE_INLINE inline
# endif
namespace basisu
{
enum { cInvalidIndex = - 1 } ;
namespace helpers
{
inline bool is_power_of_2 ( uint32_t x ) { return x & & ( ( x & ( x - 1U ) ) = = 0U ) ; }
inline bool is_power_of_2 ( uint64_t x ) { return x & & ( ( x & ( x - 1U ) ) = = 0U ) ; }
template < class T > const T & minimum ( const T & a , const T & b ) { return ( b < a ) ? b : a ; }
template < class T > const T & maximum ( const T & a , const T & b ) { return ( a < b ) ? b : a ; }
inline uint32_t floor_log2i ( uint32_t v )
{
uint32_t l = 0 ;
while ( v > 1U )
{
v > > = 1 ;
l + + ;
}
return l ;
}
inline uint32_t next_pow2 ( uint32_t val )
{
val - - ;
val | = val > > 16 ;
val | = val > > 8 ;
val | = val > > 4 ;
val | = val > > 2 ;
val | = val > > 1 ;
return val + 1 ;
}
inline uint64_t next_pow2 ( uint64_t val )
{
val - - ;
val | = val > > 32 ;
val | = val > > 16 ;
val | = val > > 8 ;
val | = val > > 4 ;
val | = val > > 2 ;
val | = val > > 1 ;
return val + 1 ;
}
} // namespace helpers
template < typename T >
inline T * construct ( T * p )
{
return new ( static_cast < void * > ( p ) ) T ;
}
template < typename T , typename U >
inline T * construct ( T * p , const U & init )
{
return new ( static_cast < void * > ( p ) ) T ( init ) ;
}
template < typename T >
inline void construct_array ( T * p , size_t n )
{
T * q = p + n ;
for ( ; p ! = q ; + + p )
new ( static_cast < void * > ( p ) ) T ;
}
template < typename T , typename U >
inline void construct_array ( T * p , size_t n , const U & init )
{
T * q = p + n ;
for ( ; p ! = q ; + + p )
new ( static_cast < void * > ( p ) ) T ( init ) ;
}
template < typename T >
inline void destruct ( T * p )
{
( void ) p ;
p - > ~ T ( ) ;
}
template < typename T > inline void destruct_array ( T * p , size_t n )
{
T * q = p + n ;
for ( ; p ! = q ; + + p )
p - > ~ T ( ) ;
}
template < typename T > struct int_traits { enum { cMin = INT32_MIN , cMax = INT32_MAX , cSigned = true } ; } ;
template < > struct int_traits < int8_t > { enum { cMin = INT8_MIN , cMax = INT8_MAX , cSigned = true } ; } ;
template < > struct int_traits < int16_t > { enum { cMin = INT16_MIN , cMax = INT16_MAX , cSigned = true } ; } ;
template < > struct int_traits < int32_t > { enum { cMin = INT32_MIN , cMax = INT32_MAX , cSigned = true } ; } ;
template < > struct int_traits < uint8_t > { enum { cMin = 0 , cMax = UINT8_MAX , cSigned = false } ; } ;
template < > struct int_traits < uint16_t > { enum { cMin = 0 , cMax = UINT16_MAX , cSigned = false } ; } ;
template < > struct int_traits < uint32_t > { enum { cMin = 0 , cMax = UINT32_MAX , cSigned = false } ; } ;
template < typename T >
struct scalar_type
{
enum { cFlag = false } ;
static inline void construct ( T * p ) { basisu : : construct ( p ) ; }
static inline void construct ( T * p , const T & init ) { basisu : : construct ( p , init ) ; }
static inline void construct_array ( T * p , size_t n ) { basisu : : construct_array ( p , n ) ; }
static inline void destruct ( T * p ) { basisu : : destruct ( p ) ; }
static inline void destruct_array ( T * p , size_t n ) { basisu : : destruct_array ( p , n ) ; }
} ;
template < typename T > struct scalar_type < T * >
{
enum { cFlag = true } ;
static inline void construct ( T * * p ) { memset ( p , 0 , sizeof ( T * ) ) ; }
static inline void construct ( T * * p , T * init ) { * p = init ; }
static inline void construct_array ( T * * p , size_t n ) { memset ( p , 0 , sizeof ( T * ) * n ) ; }
static inline void destruct ( T * * p ) { p ; }
static inline void destruct_array ( T * * p , size_t n ) { p , n ; }
} ;
# define BASISU_DEFINE_BUILT_IN_TYPE(X) \
template < > struct scalar_type < X > { \
enum { cFlag = true } ; \
static inline void construct ( X * p ) { memset ( p , 0 , sizeof ( X ) ) ; } \
static inline void construct ( X * p , const X & init ) { memcpy ( p , & init , sizeof ( X ) ) ; } \
static inline void construct_array ( X * p , size_t n ) { memset ( p , 0 , sizeof ( X ) * n ) ; } \
static inline void destruct ( X * p ) { p ; } \
static inline void destruct_array ( X * p , size_t n ) { p , n ; } } ;
BASISU_DEFINE_BUILT_IN_TYPE ( bool )
BASISU_DEFINE_BUILT_IN_TYPE ( char )
BASISU_DEFINE_BUILT_IN_TYPE ( unsigned char )
BASISU_DEFINE_BUILT_IN_TYPE ( short )
BASISU_DEFINE_BUILT_IN_TYPE ( unsigned short )
BASISU_DEFINE_BUILT_IN_TYPE ( int )
BASISU_DEFINE_BUILT_IN_TYPE ( unsigned int )
BASISU_DEFINE_BUILT_IN_TYPE ( long )
BASISU_DEFINE_BUILT_IN_TYPE ( unsigned long )
# ifdef __GNUC__
BASISU_DEFINE_BUILT_IN_TYPE ( long long )
BASISU_DEFINE_BUILT_IN_TYPE ( unsigned long long )
# else
BASISU_DEFINE_BUILT_IN_TYPE ( __int64 )
BASISU_DEFINE_BUILT_IN_TYPE ( unsigned __int64 )
# endif
BASISU_DEFINE_BUILT_IN_TYPE ( float )
BASISU_DEFINE_BUILT_IN_TYPE ( double )
BASISU_DEFINE_BUILT_IN_TYPE ( long double )
# undef BASISU_DEFINE_BUILT_IN_TYPE
template < typename T >
struct bitwise_movable { enum { cFlag = false } ; } ;
# define BASISU_DEFINE_BITWISE_MOVABLE(Q) template<> struct bitwise_movable<Q> { enum { cFlag = true }; };
template < typename T >
struct bitwise_copyable { enum { cFlag = false } ; } ;
# define BASISU_DEFINE_BITWISE_COPYABLE(Q) template<> struct bitwise_copyable<Q> { enum { cFlag = true }; };
# define BASISU_IS_POD(T) __is_pod(T)
# define BASISU_IS_SCALAR_TYPE(T) (scalar_type<T>::cFlag)
# if defined(__GNUC__) && __GNUC__<5
# define BASISU_IS_TRIVIALLY_COPYABLE(...) __has_trivial_copy(__VA_ARGS__)
# else
# define BASISU_IS_TRIVIALLY_COPYABLE(...) std::is_trivially_copyable<__VA_ARGS__>::value
# endif
// TODO: clean this up
# define BASISU_IS_BITWISE_COPYABLE(T) (BASISU_IS_SCALAR_TYPE(T) || BASISU_IS_POD(T) || BASISU_IS_TRIVIALLY_COPYABLE(T) || (bitwise_copyable<T>::cFlag))
# define BASISU_IS_BITWISE_COPYABLE_OR_MOVABLE(T) (BASISU_IS_BITWISE_COPYABLE(T) || (bitwise_movable<T>::cFlag))
# define BASISU_HAS_DESTRUCTOR(T) ((!scalar_type<T>::cFlag) && (!__is_pod(T)))
typedef char ( & yes_t ) [ 1 ] ;
typedef char ( & no_t ) [ 2 ] ;
template < class U > yes_t class_test ( int U : : * ) ;
template < class U > no_t class_test ( . . . ) ;
template < class T > struct is_class
{
enum { value = ( sizeof ( class_test < T > ( 0 ) ) = = sizeof ( yes_t ) ) } ;
} ;
template < typename T > struct is_pointer
{
enum { value = false } ;
} ;
template < typename T > struct is_pointer < T * >
{
enum { value = true } ;
} ;
struct empty_type { } ;
BASISU_DEFINE_BITWISE_COPYABLE ( empty_type ) ;
BASISU_DEFINE_BITWISE_MOVABLE ( empty_type ) ;
template < typename T > struct rel_ops
{
friend bool operator ! = ( const T & x , const T & y ) { return ( ! ( x = = y ) ) ; }
friend bool operator > ( const T & x , const T & y ) { return ( y < x ) ; }
friend bool operator < = ( const T & x , const T & y ) { return ( ! ( y < x ) ) ; }
friend bool operator > = ( const T & x , const T & y ) { return ( ! ( x < y ) ) ; }
} ;
struct elemental_vector
{
void * m_p ;
uint32_t m_size ;
uint32_t m_capacity ;
typedef void ( * object_mover ) ( void * pDst , void * pSrc , uint32_t num ) ;
bool increase_capacity ( uint32_t min_new_capacity , bool grow_hint , uint32_t element_size , object_mover pRelocate , bool nofail ) ;
} ;
template < typename T >
class vector : public rel_ops < vector < T > >
{
public :
typedef T * iterator ;
typedef const T * const_iterator ;
typedef T value_type ;
typedef T & reference ;
typedef const T & const_reference ;
typedef T * pointer ;
typedef const T * const_pointer ;
inline vector ( ) :
m_p ( NULL ) ,
m_size ( 0 ) ,
m_capacity ( 0 )
{
}
inline vector ( uint32_t n , const T & init ) :
m_p ( NULL ) ,
m_size ( 0 ) ,
m_capacity ( 0 )
{
increase_capacity ( n , false ) ;
construct_array ( m_p , n , init ) ;
m_size = n ;
}
inline vector ( const vector & other ) :
m_p ( NULL ) ,
m_size ( 0 ) ,
m_capacity ( 0 )
{
increase_capacity ( other . m_size , false ) ;
m_size = other . m_size ;
if ( BASISU_IS_BITWISE_COPYABLE ( T ) )
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{
if ( ( m_p ) & & ( other . m_p ) )
memcpy ( m_p , other . m_p , m_size * sizeof ( T ) ) ;
}
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else
{
T * pDst = m_p ;
const T * pSrc = other . m_p ;
for ( uint32_t i = m_size ; i > 0 ; i - - )
construct ( pDst + + , * pSrc + + ) ;
}
}
inline explicit vector ( size_t size ) :
m_p ( NULL ) ,
m_size ( 0 ) ,
m_capacity ( 0 )
{
resize ( size ) ;
}
inline ~ vector ( )
{
if ( m_p )
{
scalar_type < T > : : destruct_array ( m_p , m_size ) ;
free ( m_p ) ;
}
}
inline vector & operator = ( const vector & other )
{
if ( this = = & other )
return * this ;
if ( m_capacity > = other . m_size )
resize ( 0 ) ;
else
{
clear ( ) ;
increase_capacity ( other . m_size , false ) ;
}
if ( BASISU_IS_BITWISE_COPYABLE ( T ) )
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{
if ( ( m_p ) & & ( other . m_p ) )
memcpy ( m_p , other . m_p , other . m_size * sizeof ( T ) ) ;
}
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else
{
T * pDst = m_p ;
const T * pSrc = other . m_p ;
for ( uint32_t i = other . m_size ; i > 0 ; i - - )
construct ( pDst + + , * pSrc + + ) ;
}
m_size = other . m_size ;
return * this ;
}
BASISU_FORCE_INLINE const T * begin ( ) const { return m_p ; }
BASISU_FORCE_INLINE T * begin ( ) { return m_p ; }
BASISU_FORCE_INLINE const T * end ( ) const { return m_p + m_size ; }
BASISU_FORCE_INLINE T * end ( ) { return m_p + m_size ; }
BASISU_FORCE_INLINE bool empty ( ) const { return ! m_size ; }
BASISU_FORCE_INLINE uint32_t size ( ) const { return m_size ; }
BASISU_FORCE_INLINE uint32_t size_in_bytes ( ) const { return m_size * sizeof ( T ) ; }
BASISU_FORCE_INLINE uint32_t capacity ( ) const { return m_capacity ; }
// operator[] will assert on out of range indices, but in final builds there is (and will never be) any range checking on this method.
//BASISU_FORCE_INLINE const T& operator[] (uint32_t i) const { assert(i < m_size); return m_p[i]; }
//BASISU_FORCE_INLINE T& operator[] (uint32_t i) { assert(i < m_size); return m_p[i]; }
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# if !BASISU_VECTOR_FORCE_CHECKING
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BASISU_FORCE_INLINE const T & operator [ ] ( size_t i ) const { assert ( i < m_size ) ; return m_p [ i ] ; }
BASISU_FORCE_INLINE T & operator [ ] ( size_t i ) { assert ( i < m_size ) ; return m_p [ i ] ; }
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# else
BASISU_FORCE_INLINE const T & operator [ ] ( size_t i ) const
{
if ( i > = m_size )
{
fprintf ( stderr , " operator[] invalid index: %u, max entries %u, type size %u \n " , ( uint32_t ) i , m_size , ( uint32_t ) sizeof ( T ) ) ;
abort ( ) ;
}
return m_p [ i ] ;
}
BASISU_FORCE_INLINE T & operator [ ] ( size_t i )
{
if ( i > = m_size )
{
fprintf ( stderr , " operator[] invalid index: %u, max entries %u, type size %u \n " , ( uint32_t ) i , m_size , ( uint32_t ) sizeof ( T ) ) ;
abort ( ) ;
}
return m_p [ i ] ;
}
# endif
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// at() always includes range checking, even in final builds, unlike operator [].
// The first element is returned if the index is out of range.
BASISU_FORCE_INLINE const T & at ( size_t i ) const { assert ( i < m_size ) ; return ( i > = m_size ) ? m_p [ 0 ] : m_p [ i ] ; }
BASISU_FORCE_INLINE T & at ( size_t i ) { assert ( i < m_size ) ; return ( i > = m_size ) ? m_p [ 0 ] : m_p [ i ] ; }
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# if !BASISU_VECTOR_FORCE_CHECKING
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BASISU_FORCE_INLINE const T & front ( ) const { assert ( m_size ) ; return m_p [ 0 ] ; }
BASISU_FORCE_INLINE T & front ( ) { assert ( m_size ) ; return m_p [ 0 ] ; }
BASISU_FORCE_INLINE const T & back ( ) const { assert ( m_size ) ; return m_p [ m_size - 1 ] ; }
BASISU_FORCE_INLINE T & back ( ) { assert ( m_size ) ; return m_p [ m_size - 1 ] ; }
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# else
BASISU_FORCE_INLINE const T & front ( ) const
{
if ( ! m_size )
{
fprintf ( stderr , " front: vector is empty, type size %u \n " , ( uint32_t ) sizeof ( T ) ) ;
abort ( ) ;
}
return m_p [ 0 ] ;
}
BASISU_FORCE_INLINE T & front ( )
{
if ( ! m_size )
{
fprintf ( stderr , " front: vector is empty, type size %u \n " , ( uint32_t ) sizeof ( T ) ) ;
abort ( ) ;
}
return m_p [ 0 ] ;
}
BASISU_FORCE_INLINE const T & back ( ) const
{
if ( ! m_size )
{
fprintf ( stderr , " back: vector is empty, type size %u \n " , ( uint32_t ) sizeof ( T ) ) ;
abort ( ) ;
}
return m_p [ m_size - 1 ] ;
}
BASISU_FORCE_INLINE T & back ( )
{
if ( ! m_size )
{
fprintf ( stderr , " back: vector is empty, type size %u \n " , ( uint32_t ) sizeof ( T ) ) ;
abort ( ) ;
}
return m_p [ m_size - 1 ] ;
}
# endif
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BASISU_FORCE_INLINE const T * get_ptr ( ) const { return m_p ; }
BASISU_FORCE_INLINE T * get_ptr ( ) { return m_p ; }
BASISU_FORCE_INLINE const T * data ( ) const { return m_p ; }
BASISU_FORCE_INLINE T * data ( ) { return m_p ; }
// clear() sets the container to empty, then frees the allocated block.
inline void clear ( )
{
if ( m_p )
{
scalar_type < T > : : destruct_array ( m_p , m_size ) ;
free ( m_p ) ;
m_p = NULL ;
m_size = 0 ;
m_capacity = 0 ;
}
}
inline void clear_no_destruction ( )
{
if ( m_p )
{
free ( m_p ) ;
m_p = NULL ;
m_size = 0 ;
m_capacity = 0 ;
}
}
inline void reserve ( size_t new_capacity_size_t )
{
if ( new_capacity_size_t > UINT32_MAX )
{
assert ( 0 ) ;
return ;
}
uint32_t new_capacity = ( uint32_t ) new_capacity_size_t ;
if ( new_capacity > m_capacity )
increase_capacity ( new_capacity , false ) ;
else if ( new_capacity < m_capacity )
{
// Must work around the lack of a "decrease_capacity()" method.
// This case is rare enough in practice that it's probably not worth implementing an optimized in-place resize.
vector tmp ;
tmp . increase_capacity ( helpers : : maximum ( m_size , new_capacity ) , false ) ;
tmp = * this ;
swap ( tmp ) ;
}
}
inline bool try_reserve ( size_t new_capacity_size_t )
{
if ( new_capacity_size_t > UINT32_MAX )
{
assert ( 0 ) ;
return false ;
}
uint32_t new_capacity = ( uint32_t ) new_capacity_size_t ;
if ( new_capacity > m_capacity )
{
if ( ! increase_capacity ( new_capacity , false ) )
return false ;
}
else if ( new_capacity < m_capacity )
{
// Must work around the lack of a "decrease_capacity()" method.
// This case is rare enough in practice that it's probably not worth implementing an optimized in-place resize.
vector tmp ;
tmp . increase_capacity ( helpers : : maximum ( m_size , new_capacity ) , false ) ;
tmp = * this ;
swap ( tmp ) ;
}
return true ;
}
// resize(0) sets the container to empty, but does not free the allocated block.
inline void resize ( size_t new_size_size_t , bool grow_hint = false )
{
if ( new_size_size_t > UINT32_MAX )
{
assert ( 0 ) ;
return ;
}
uint32_t new_size = ( uint32_t ) new_size_size_t ;
if ( m_size ! = new_size )
{
if ( new_size < m_size )
scalar_type < T > : : destruct_array ( m_p + new_size , m_size - new_size ) ;
else
{
if ( new_size > m_capacity )
increase_capacity ( new_size , ( new_size = = ( m_size + 1 ) ) | | grow_hint ) ;
scalar_type < T > : : construct_array ( m_p + m_size , new_size - m_size ) ;
}
m_size = new_size ;
}
}
inline bool try_resize ( size_t new_size_size_t , bool grow_hint = false )
{
if ( new_size_size_t > UINT32_MAX )
{
assert ( 0 ) ;
return false ;
}
uint32_t new_size = ( uint32_t ) new_size_size_t ;
if ( m_size ! = new_size )
{
if ( new_size < m_size )
scalar_type < T > : : destruct_array ( m_p + new_size , m_size - new_size ) ;
else
{
if ( new_size > m_capacity )
{
if ( ! increase_capacity ( new_size , ( new_size = = ( m_size + 1 ) ) | | grow_hint , true ) )
return false ;
}
scalar_type < T > : : construct_array ( m_p + m_size , new_size - m_size ) ;
}
m_size = new_size ;
}
return true ;
}
// If size >= capacity/2, reset() sets the container's size to 0 but doesn't free the allocated block (because the container may be similarly loaded in the future).
// Otherwise it blows away the allocated block. See http://www.codercorner.com/blog/?p=494
inline void reset ( )
{
if ( m_size > = ( m_capacity > > 1 ) )
resize ( 0 ) ;
else
clear ( ) ;
}
inline T * enlarge ( uint32_t i )
{
uint32_t cur_size = m_size ;
resize ( cur_size + i , true ) ;
return get_ptr ( ) + cur_size ;
}
inline T * try_enlarge ( uint32_t i )
{
uint32_t cur_size = m_size ;
if ( ! try_resize ( cur_size + i , true ) )
return NULL ;
return get_ptr ( ) + cur_size ;
}
BASISU_FORCE_INLINE void push_back ( const T & obj )
{
assert ( ! m_p | | ( & obj < m_p ) | | ( & obj > = ( m_p + m_size ) ) ) ;
if ( m_size > = m_capacity )
increase_capacity ( m_size + 1 , true ) ;
scalar_type < T > : : construct ( m_p + m_size , obj ) ;
m_size + + ;
}
inline bool try_push_back ( const T & obj )
{
assert ( ! m_p | | ( & obj < m_p ) | | ( & obj > = ( m_p + m_size ) ) ) ;
if ( m_size > = m_capacity )
{
if ( ! increase_capacity ( m_size + 1 , true , true ) )
return false ;
}
scalar_type < T > : : construct ( m_p + m_size , obj ) ;
m_size + + ;
return true ;
}
inline void push_back_value ( T obj )
{
if ( m_size > = m_capacity )
increase_capacity ( m_size + 1 , true ) ;
scalar_type < T > : : construct ( m_p + m_size , obj ) ;
m_size + + ;
}
inline void pop_back ( )
{
assert ( m_size ) ;
if ( m_size )
{
m_size - - ;
scalar_type < T > : : destruct ( & m_p [ m_size ] ) ;
}
}
inline void insert ( uint32_t index , const T * p , uint32_t n )
{
assert ( index < = m_size ) ;
if ( ! n )
return ;
const uint32_t orig_size = m_size ;
resize ( m_size + n , true ) ;
const uint32_t num_to_move = orig_size - index ;
if ( BASISU_IS_BITWISE_COPYABLE ( T ) )
{
// This overwrites the destination object bits, but bitwise copyable means we don't need to worry about destruction.
memmove ( m_p + index + n , m_p + index , sizeof ( T ) * num_to_move ) ;
}
else
{
const T * pSrc = m_p + orig_size - 1 ;
T * pDst = const_cast < T * > ( pSrc ) + n ;
for ( uint32_t i = 0 ; i < num_to_move ; i + + )
{
assert ( ( pDst - m_p ) < ( int ) m_size ) ;
* pDst - - = * pSrc - - ;
}
}
T * pDst = m_p + index ;
if ( BASISU_IS_BITWISE_COPYABLE ( T ) )
{
// This copies in the new bits, overwriting the existing objects, which is OK for copyable types that don't need destruction.
memcpy ( pDst , p , sizeof ( T ) * n ) ;
}
else
{
for ( uint32_t i = 0 ; i < n ; i + + )
{
assert ( ( pDst - m_p ) < ( int ) m_size ) ;
* pDst + + = * p + + ;
}
}
}
inline void insert ( T * p , const T & obj )
{
int64_t ofs = p - begin ( ) ;
if ( ( ofs < 0 ) | | ( ofs > UINT32_MAX ) )
{
assert ( 0 ) ;
return ;
}
insert ( ( uint32_t ) ofs , & obj , 1 ) ;
}
// push_front() isn't going to be very fast - it's only here for usability.
inline void push_front ( const T & obj )
{
insert ( 0 , & obj , 1 ) ;
}
vector & append ( const vector & other )
{
if ( other . m_size )
insert ( m_size , & other [ 0 ] , other . m_size ) ;
return * this ;
}
vector & append ( const T * p , uint32_t n )
{
if ( n )
insert ( m_size , p , n ) ;
return * this ;
}
inline void erase ( uint32_t start , uint32_t n )
{
assert ( ( start + n ) < = m_size ) ;
if ( ( start + n ) > m_size )
return ;
if ( ! n )
return ;
const uint32_t num_to_move = m_size - ( start + n ) ;
T * pDst = m_p + start ;
const T * pSrc = m_p + start + n ;
if ( BASISU_IS_BITWISE_COPYABLE_OR_MOVABLE ( T ) )
{
// This test is overly cautious.
if ( ( ! BASISU_IS_BITWISE_COPYABLE ( T ) ) | | ( BASISU_HAS_DESTRUCTOR ( T ) ) )
{
// Type has been marked explictly as bitwise movable, which means we can move them around but they may need to be destructed.
// First destroy the erased objects.
scalar_type < T > : : destruct_array ( pDst , n ) ;
}
// Copy "down" the objects to preserve, filling in the empty slots.
memmove ( pDst , pSrc , num_to_move * sizeof ( T ) ) ;
}
else
{
// Type is not bitwise copyable or movable.
// Move them down one at a time by using the equals operator, and destroying anything that's left over at the end.
T * pDst_end = pDst + num_to_move ;
while ( pDst ! = pDst_end )
* pDst + + = * pSrc + + ;
scalar_type < T > : : destruct_array ( pDst_end , n ) ;
}
m_size - = n ;
}
inline void erase ( uint32_t index )
{
erase ( index , 1 ) ;
}
inline void erase ( T * p )
{
assert ( ( p > = m_p ) & & ( p < ( m_p + m_size ) ) ) ;
erase ( static_cast < uint32_t > ( p - m_p ) ) ;
}
inline void erase ( T * pFirst , T * pEnd )
{
assert ( pFirst < = pEnd ) ;
assert ( pFirst > = begin ( ) & & pFirst < = end ( ) ) ;
assert ( pEnd > = begin ( ) & & pEnd < = end ( ) ) ;
int64_t ofs = pFirst - begin ( ) ;
if ( ( ofs < 0 ) | | ( ofs > UINT32_MAX ) )
{
assert ( 0 ) ;
return ;
}
int64_t n = pEnd - pFirst ;
if ( ( n < 0 ) | | ( n > UINT32_MAX ) )
{
assert ( 0 ) ;
return ;
}
erase ( ( uint32_t ) ofs , ( uint32_t ) n ) ;
}
void erase_unordered ( uint32_t index )
{
assert ( index < m_size ) ;
if ( ( index + 1 ) < m_size )
( * this ) [ index ] = back ( ) ;
pop_back ( ) ;
}
inline bool operator = = ( const vector & rhs ) const
{
if ( m_size ! = rhs . m_size )
return false ;
else if ( m_size )
{
if ( scalar_type < T > : : cFlag )
return memcmp ( m_p , rhs . m_p , sizeof ( T ) * m_size ) = = 0 ;
else
{
const T * pSrc = m_p ;
const T * pDst = rhs . m_p ;
for ( uint32_t i = m_size ; i ; i - - )
if ( ! ( * pSrc + + = = * pDst + + ) )
return false ;
}
}
return true ;
}
inline bool operator < ( const vector & rhs ) const
{
const uint32_t min_size = helpers : : minimum ( m_size , rhs . m_size ) ;
const T * pSrc = m_p ;
const T * pSrc_end = m_p + min_size ;
const T * pDst = rhs . m_p ;
while ( ( pSrc < pSrc_end ) & & ( * pSrc = = * pDst ) )
{
pSrc + + ;
pDst + + ;
}
if ( pSrc < pSrc_end )
return * pSrc < * pDst ;
return m_size < rhs . m_size ;
}
inline void swap ( vector & other )
{
std : : swap ( m_p , other . m_p ) ;
std : : swap ( m_size , other . m_size ) ;
std : : swap ( m_capacity , other . m_capacity ) ;
}
inline void sort ( )
{
std : : sort ( begin ( ) , end ( ) ) ;
}
inline void unique ( )
{
if ( ! empty ( ) )
{
sort ( ) ;
resize ( std : : unique ( begin ( ) , end ( ) ) - begin ( ) ) ;
}
}
inline void reverse ( )
{
uint32_t j = m_size > > 1 ;
for ( uint32_t i = 0 ; i < j ; i + + )
std : : swap ( m_p [ i ] , m_p [ m_size - 1 - i ] ) ;
}
inline int find ( const T & key ) const
{
const T * p = m_p ;
const T * p_end = m_p + m_size ;
uint32_t index = 0 ;
while ( p ! = p_end )
{
if ( key = = * p )
return index ;
p + + ;
index + + ;
}
return cInvalidIndex ;
}
inline int find_sorted ( const T & key ) const
{
if ( m_size )
{
// Uniform binary search - Knuth Algorithm 6.2.1 U, unrolled twice.
int i = ( ( m_size + 1 ) > > 1 ) - 1 ;
int m = m_size ;
for ( ; ; )
{
assert ( i > = 0 & & i < ( int ) m_size ) ;
const T * pKey_i = m_p + i ;
int cmp = key < * pKey_i ;
# if defined(_DEBUG) || defined(DEBUG)
int cmp2 = * pKey_i < key ;
assert ( ( cmp ! = cmp2 ) | | ( key = = * pKey_i ) ) ;
# endif
if ( ( ! cmp ) & & ( key = = * pKey_i ) ) return i ;
m > > = 1 ;
if ( ! m ) break ;
cmp = - cmp ;
i + = ( ( ( m + 1 ) > > 1 ) ^ cmp ) - cmp ;
if ( i < 0 )
break ;
assert ( i > = 0 & & i < ( int ) m_size ) ;
pKey_i = m_p + i ;
cmp = key < * pKey_i ;
# if defined(_DEBUG) || defined(DEBUG)
cmp2 = * pKey_i < key ;
assert ( ( cmp ! = cmp2 ) | | ( key = = * pKey_i ) ) ;
# endif
if ( ( ! cmp ) & & ( key = = * pKey_i ) ) return i ;
m > > = 1 ;
if ( ! m ) break ;
cmp = - cmp ;
i + = ( ( ( m + 1 ) > > 1 ) ^ cmp ) - cmp ;
if ( i < 0 )
break ;
}
}
return cInvalidIndex ;
}
template < typename Q >
inline int find_sorted ( const T & key , Q less_than ) const
{
if ( m_size )
{
// Uniform binary search - Knuth Algorithm 6.2.1 U, unrolled twice.
int i = ( ( m_size + 1 ) > > 1 ) - 1 ;
int m = m_size ;
for ( ; ; )
{
assert ( i > = 0 & & i < ( int ) m_size ) ;
const T * pKey_i = m_p + i ;
int cmp = less_than ( key , * pKey_i ) ;
if ( ( ! cmp ) & & ( ! less_than ( * pKey_i , key ) ) ) return i ;
m > > = 1 ;
if ( ! m ) break ;
cmp = - cmp ;
i + = ( ( ( m + 1 ) > > 1 ) ^ cmp ) - cmp ;
if ( i < 0 )
break ;
assert ( i > = 0 & & i < ( int ) m_size ) ;
pKey_i = m_p + i ;
cmp = less_than ( key , * pKey_i ) ;
if ( ( ! cmp ) & & ( ! less_than ( * pKey_i , key ) ) ) return i ;
m > > = 1 ;
if ( ! m ) break ;
cmp = - cmp ;
i + = ( ( ( m + 1 ) > > 1 ) ^ cmp ) - cmp ;
if ( i < 0 )
break ;
}
}
return cInvalidIndex ;
}
inline uint32_t count_occurences ( const T & key ) const
{
uint32_t c = 0 ;
const T * p = m_p ;
const T * p_end = m_p + m_size ;
while ( p ! = p_end )
{
if ( key = = * p )
c + + ;
p + + ;
}
return c ;
}
inline void set_all ( const T & o )
{
if ( ( sizeof ( T ) = = 1 ) & & ( scalar_type < T > : : cFlag ) )
memset ( m_p , * reinterpret_cast < const uint8_t * > ( & o ) , m_size ) ;
else
{
T * pDst = m_p ;
T * pDst_end = pDst + m_size ;
while ( pDst ! = pDst_end )
* pDst + + = o ;
}
}
// Caller assumes ownership of the heap block associated with the container. Container is cleared.
inline void * assume_ownership ( )
{
T * p = m_p ;
m_p = NULL ;
m_size = 0 ;
m_capacity = 0 ;
return p ;
}
// Caller is granting ownership of the indicated heap block.
// Block must have size constructed elements, and have enough room for capacity elements.
2022-03-24 19:39:24 +00:00
// The block must have been allocated using malloc().
// Important: This method is used in Basis Universal. If you change how this container allocates memory, you'll need to change any users of this method.
2021-05-07 15:00:41 +00:00
inline bool grant_ownership ( T * p , uint32_t size , uint32_t capacity )
{
// To to prevent the caller from obviously shooting themselves in the foot.
if ( ( ( p + capacity ) > m_p ) & & ( p < ( m_p + m_capacity ) ) )
{
// Can grant ownership of a block inside the container itself!
assert ( 0 ) ;
return false ;
}
if ( size > capacity )
{
assert ( 0 ) ;
return false ;
}
if ( ! p )
{
if ( capacity )
{
assert ( 0 ) ;
return false ;
}
}
else if ( ! capacity )
{
assert ( 0 ) ;
return false ;
}
clear ( ) ;
m_p = p ;
m_size = size ;
m_capacity = capacity ;
return true ;
}
private :
T * m_p ;
uint32_t m_size ;
uint32_t m_capacity ;
template < typename Q > struct is_vector { enum { cFlag = false } ; } ;
template < typename Q > struct is_vector < vector < Q > > { enum { cFlag = true } ; } ;
static void object_mover ( void * pDst_void , void * pSrc_void , uint32_t num )
{
T * pSrc = static_cast < T * > ( pSrc_void ) ;
T * const pSrc_end = pSrc + num ;
T * pDst = static_cast < T * > ( pDst_void ) ;
while ( pSrc ! = pSrc_end )
{
// placement new
new ( static_cast < void * > ( pDst ) ) T ( * pSrc ) ;
pSrc - > ~ T ( ) ;
+ + pSrc ;
+ + pDst ;
}
}
inline bool increase_capacity ( uint32_t min_new_capacity , bool grow_hint , bool nofail = false )
{
return reinterpret_cast < elemental_vector * > ( this ) - > increase_capacity (
min_new_capacity , grow_hint , sizeof ( T ) ,
( BASISU_IS_BITWISE_COPYABLE_OR_MOVABLE ( T ) | | ( is_vector < T > : : cFlag ) ) ? NULL : object_mover , nofail ) ;
}
} ;
template < typename T > struct bitwise_movable < vector < T > > { enum { cFlag = true } ; } ;
// Hash map
template < typename T >
struct hasher
{
inline size_t operator ( ) ( const T & key ) const { return static_cast < size_t > ( key ) ; }
} ;
template < typename T >
struct equal_to
{
inline bool operator ( ) ( const T & a , const T & b ) const { return a = = b ; }
} ;
// Important: The Hasher and Equals objects must be bitwise movable!
template < typename Key , typename Value = empty_type , typename Hasher = hasher < Key > , typename Equals = equal_to < Key > >
class hash_map
{
public :
class iterator ;
class const_iterator ;
private :
friend class iterator ;
friend class const_iterator ;
enum state
{
cStateInvalid = 0 ,
cStateValid = 1
} ;
enum
{
cMinHashSize = 4U
} ;
public :
typedef hash_map < Key , Value , Hasher , Equals > hash_map_type ;
typedef std : : pair < Key , Value > value_type ;
typedef Key key_type ;
typedef Value referent_type ;
typedef Hasher hasher_type ;
typedef Equals equals_type ;
hash_map ( ) :
m_hash_shift ( 32 ) , m_num_valid ( 0 ) , m_grow_threshold ( 0 )
{
}
hash_map ( const hash_map & other ) :
m_values ( other . m_values ) ,
m_hash_shift ( other . m_hash_shift ) ,
m_hasher ( other . m_hasher ) ,
m_equals ( other . m_equals ) ,
m_num_valid ( other . m_num_valid ) ,
m_grow_threshold ( other . m_grow_threshold )
{
}
hash_map & operator = ( const hash_map & other )
{
if ( this = = & other )
return * this ;
clear ( ) ;
m_values = other . m_values ;
m_hash_shift = other . m_hash_shift ;
m_num_valid = other . m_num_valid ;
m_grow_threshold = other . m_grow_threshold ;
m_hasher = other . m_hasher ;
m_equals = other . m_equals ;
return * this ;
}
inline ~ hash_map ( )
{
clear ( ) ;
}
const Equals & get_equals ( ) const { return m_equals ; }
Equals & get_equals ( ) { return m_equals ; }
void set_equals ( const Equals & equals ) { m_equals = equals ; }
const Hasher & get_hasher ( ) const { return m_hasher ; }
Hasher & get_hasher ( ) { return m_hasher ; }
void set_hasher ( const Hasher & hasher ) { m_hasher = hasher ; }
inline void clear ( )
{
if ( ! m_values . empty ( ) )
{
if ( BASISU_HAS_DESTRUCTOR ( Key ) | | BASISU_HAS_DESTRUCTOR ( Value ) )
{
node * p = & get_node ( 0 ) ;
node * p_end = p + m_values . size ( ) ;
uint32_t num_remaining = m_num_valid ;
while ( p ! = p_end )
{
if ( p - > state )
{
destruct_value_type ( p ) ;
num_remaining - - ;
if ( ! num_remaining )
break ;
}
p + + ;
}
}
m_values . clear_no_destruction ( ) ;
m_hash_shift = 32 ;
m_num_valid = 0 ;
m_grow_threshold = 0 ;
}
}
inline void reset ( )
{
if ( ! m_num_valid )
return ;
if ( BASISU_HAS_DESTRUCTOR ( Key ) | | BASISU_HAS_DESTRUCTOR ( Value ) )
{
node * p = & get_node ( 0 ) ;
node * p_end = p + m_values . size ( ) ;
uint32_t num_remaining = m_num_valid ;
while ( p ! = p_end )
{
if ( p - > state )
{
destruct_value_type ( p ) ;
p - > state = cStateInvalid ;
num_remaining - - ;
if ( ! num_remaining )
break ;
}
p + + ;
}
}
else if ( sizeof ( node ) < = 32 )
{
memset ( & m_values [ 0 ] , 0 , m_values . size_in_bytes ( ) ) ;
}
else
{
node * p = & get_node ( 0 ) ;
node * p_end = p + m_values . size ( ) ;
uint32_t num_remaining = m_num_valid ;
while ( p ! = p_end )
{
if ( p - > state )
{
p - > state = cStateInvalid ;
num_remaining - - ;
if ( ! num_remaining )
break ;
}
p + + ;
}
}
m_num_valid = 0 ;
}
inline uint32_t size ( )
{
return m_num_valid ;
}
inline uint32_t get_table_size ( )
{
return m_values . size ( ) ;
}
inline bool empty ( )
{
return ! m_num_valid ;
}
inline void reserve ( uint32_t new_capacity )
{
uint64_t new_hash_size = helpers : : maximum ( 1U , new_capacity ) ;
new_hash_size = new_hash_size * 2ULL ;
if ( ! helpers : : is_power_of_2 ( new_hash_size ) )
new_hash_size = helpers : : next_pow2 ( new_hash_size ) ;
new_hash_size = helpers : : maximum < uint64_t > ( cMinHashSize , new_hash_size ) ;
new_hash_size = helpers : : minimum < uint64_t > ( 0x80000000UL , new_hash_size ) ;
if ( new_hash_size > m_values . size ( ) )
rehash ( ( uint32_t ) new_hash_size ) ;
}
class iterator
{
friend class hash_map < Key , Value , Hasher , Equals > ;
friend class hash_map < Key , Value , Hasher , Equals > : : const_iterator ;
public :
inline iterator ( ) : m_pTable ( NULL ) , m_index ( 0 ) { }
inline iterator ( hash_map_type & table , uint32_t index ) : m_pTable ( & table ) , m_index ( index ) { }
inline iterator ( const iterator & other ) : m_pTable ( other . m_pTable ) , m_index ( other . m_index ) { }
inline iterator & operator = ( const iterator & other )
{
m_pTable = other . m_pTable ;
m_index = other . m_index ;
return * this ;
}
// post-increment
inline iterator operator + + ( int )
{
iterator result ( * this ) ;
+ + * this ;
return result ;
}
// pre-increment
inline iterator & operator + + ( )
{
probe ( ) ;
return * this ;
}
inline value_type & operator * ( ) const { return * get_cur ( ) ; }
inline value_type * operator - > ( ) const { return get_cur ( ) ; }
inline bool operator = = ( const iterator & b ) const { return ( m_pTable = = b . m_pTable ) & & ( m_index = = b . m_index ) ; }
inline bool operator ! = ( const iterator & b ) const { return ! ( * this = = b ) ; }
inline bool operator = = ( const const_iterator & b ) const { return ( m_pTable = = b . m_pTable ) & & ( m_index = = b . m_index ) ; }
inline bool operator ! = ( const const_iterator & b ) const { return ! ( * this = = b ) ; }
private :
hash_map_type * m_pTable ;
uint32_t m_index ;
inline value_type * get_cur ( ) const
{
assert ( m_pTable & & ( m_index < m_pTable - > m_values . size ( ) ) ) ;
assert ( m_pTable - > get_node_state ( m_index ) = = cStateValid ) ;
return & m_pTable - > get_node ( m_index ) ;
}
inline void probe ( )
{
assert ( m_pTable ) ;
m_index = m_pTable - > find_next ( m_index ) ;
}
} ;
class const_iterator
{
friend class hash_map < Key , Value , Hasher , Equals > ;
friend class hash_map < Key , Value , Hasher , Equals > : : iterator ;
public :
inline const_iterator ( ) : m_pTable ( NULL ) , m_index ( 0 ) { }
inline const_iterator ( const hash_map_type & table , uint32_t index ) : m_pTable ( & table ) , m_index ( index ) { }
inline const_iterator ( const iterator & other ) : m_pTable ( other . m_pTable ) , m_index ( other . m_index ) { }
inline const_iterator ( const const_iterator & other ) : m_pTable ( other . m_pTable ) , m_index ( other . m_index ) { }
inline const_iterator & operator = ( const const_iterator & other )
{
m_pTable = other . m_pTable ;
m_index = other . m_index ;
return * this ;
}
inline const_iterator & operator = ( const iterator & other )
{
m_pTable = other . m_pTable ;
m_index = other . m_index ;
return * this ;
}
// post-increment
inline const_iterator operator + + ( int )
{
const_iterator result ( * this ) ;
+ + * this ;
return result ;
}
// pre-increment
inline const_iterator & operator + + ( )
{
probe ( ) ;
return * this ;
}
inline const value_type & operator * ( ) const { return * get_cur ( ) ; }
inline const value_type * operator - > ( ) const { return get_cur ( ) ; }
inline bool operator = = ( const const_iterator & b ) const { return ( m_pTable = = b . m_pTable ) & & ( m_index = = b . m_index ) ; }
inline bool operator ! = ( const const_iterator & b ) const { return ! ( * this = = b ) ; }
inline bool operator = = ( const iterator & b ) const { return ( m_pTable = = b . m_pTable ) & & ( m_index = = b . m_index ) ; }
inline bool operator ! = ( const iterator & b ) const { return ! ( * this = = b ) ; }
private :
const hash_map_type * m_pTable ;
uint32_t m_index ;
inline const value_type * get_cur ( ) const
{
assert ( m_pTable & & ( m_index < m_pTable - > m_values . size ( ) ) ) ;
assert ( m_pTable - > get_node_state ( m_index ) = = cStateValid ) ;
return & m_pTable - > get_node ( m_index ) ;
}
inline void probe ( )
{
assert ( m_pTable ) ;
m_index = m_pTable - > find_next ( m_index ) ;
}
} ;
inline const_iterator begin ( ) const
{
if ( ! m_num_valid )
return end ( ) ;
return const_iterator ( * this , find_next ( UINT32_MAX ) ) ;
}
inline const_iterator end ( ) const
{
return const_iterator ( * this , m_values . size ( ) ) ;
}
inline iterator begin ( )
{
if ( ! m_num_valid )
return end ( ) ;
return iterator ( * this , find_next ( UINT32_MAX ) ) ;
}
inline iterator end ( )
{
return iterator ( * this , m_values . size ( ) ) ;
}
// insert_result.first will always point to inserted key/value (or the already existing key/value).
// insert_resutt.second will be true if a new key/value was inserted, or false if the key already existed (in which case first will point to the already existing value).
typedef std : : pair < iterator , bool > insert_result ;
inline insert_result insert ( const Key & k , const Value & v = Value ( ) )
{
insert_result result ;
if ( ! insert_no_grow ( result , k , v ) )
{
grow ( ) ;
// This must succeed.
if ( ! insert_no_grow ( result , k , v ) )
{
fprintf ( stderr , " insert() failed " ) ;
abort ( ) ;
}
}
return result ;
}
inline insert_result insert ( const value_type & v )
{
return insert ( v . first , v . second ) ;
}
inline const_iterator find ( const Key & k ) const
{
return const_iterator ( * this , find_index ( k ) ) ;
}
inline iterator find ( const Key & k )
{
return iterator ( * this , find_index ( k ) ) ;
}
inline bool erase ( const Key & k )
{
uint32_t i = find_index ( k ) ;
if ( i > = m_values . size ( ) )
return false ;
node * pDst = & get_node ( i ) ;
destruct_value_type ( pDst ) ;
pDst - > state = cStateInvalid ;
m_num_valid - - ;
for ( ; ; )
{
uint32_t r , j = i ;
node * pSrc = pDst ;
do
{
if ( ! i )
{
i = m_values . size ( ) - 1 ;
pSrc = & get_node ( i ) ;
}
else
{
i - - ;
pSrc - - ;
}
if ( ! pSrc - > state )
return true ;
r = hash_key ( pSrc - > first ) ;
} while ( ( i < = r & & r < j ) | | ( r < j & & j < i ) | | ( j < i & & i < = r ) ) ;
move_node ( pDst , pSrc ) ;
pDst = pSrc ;
}
}
inline void swap ( hash_map_type & other )
{
m_values . swap ( other . m_values ) ;
std : : swap ( m_hash_shift , other . m_hash_shift ) ;
std : : swap ( m_num_valid , other . m_num_valid ) ;
std : : swap ( m_grow_threshold , other . m_grow_threshold ) ;
std : : swap ( m_hasher , other . m_hasher ) ;
std : : swap ( m_equals , other . m_equals ) ;
}
private :
struct node : public value_type
{
uint8_t state ;
} ;
static inline void construct_value_type ( value_type * pDst , const Key & k , const Value & v )
{
if ( BASISU_IS_BITWISE_COPYABLE ( Key ) )
memcpy ( & pDst - > first , & k , sizeof ( Key ) ) ;
else
scalar_type < Key > : : construct ( & pDst - > first , k ) ;
if ( BASISU_IS_BITWISE_COPYABLE ( Value ) )
memcpy ( & pDst - > second , & v , sizeof ( Value ) ) ;
else
scalar_type < Value > : : construct ( & pDst - > second , v ) ;
}
static inline void construct_value_type ( value_type * pDst , const value_type * pSrc )
{
if ( ( BASISU_IS_BITWISE_COPYABLE ( Key ) ) & & ( BASISU_IS_BITWISE_COPYABLE ( Value ) ) )
{
memcpy ( pDst , pSrc , sizeof ( value_type ) ) ;
}
else
{
if ( BASISU_IS_BITWISE_COPYABLE ( Key ) )
memcpy ( & pDst - > first , & pSrc - > first , sizeof ( Key ) ) ;
else
scalar_type < Key > : : construct ( & pDst - > first , pSrc - > first ) ;
if ( BASISU_IS_BITWISE_COPYABLE ( Value ) )
memcpy ( & pDst - > second , & pSrc - > second , sizeof ( Value ) ) ;
else
scalar_type < Value > : : construct ( & pDst - > second , pSrc - > second ) ;
}
}
static inline void destruct_value_type ( value_type * p )
{
scalar_type < Key > : : destruct ( & p - > first ) ;
scalar_type < Value > : : destruct ( & p - > second ) ;
}
// Moves *pSrc to *pDst efficiently.
// pDst should NOT be constructed on entry.
static inline void move_node ( node * pDst , node * pSrc , bool update_src_state = true )
{
assert ( ! pDst - > state ) ;
if ( BASISU_IS_BITWISE_COPYABLE_OR_MOVABLE ( Key ) & & BASISU_IS_BITWISE_COPYABLE_OR_MOVABLE ( Value ) )
{
memcpy ( pDst , pSrc , sizeof ( node ) ) ;
}
else
{
if ( BASISU_IS_BITWISE_COPYABLE_OR_MOVABLE ( Key ) )
memcpy ( & pDst - > first , & pSrc - > first , sizeof ( Key ) ) ;
else
{
scalar_type < Key > : : construct ( & pDst - > first , pSrc - > first ) ;
scalar_type < Key > : : destruct ( & pSrc - > first ) ;
}
if ( BASISU_IS_BITWISE_COPYABLE_OR_MOVABLE ( Value ) )
memcpy ( & pDst - > second , & pSrc - > second , sizeof ( Value ) ) ;
else
{
scalar_type < Value > : : construct ( & pDst - > second , pSrc - > second ) ;
scalar_type < Value > : : destruct ( & pSrc - > second ) ;
}
pDst - > state = cStateValid ;
}
if ( update_src_state )
pSrc - > state = cStateInvalid ;
}
struct raw_node
{
inline raw_node ( )
{
node * p = reinterpret_cast < node * > ( this ) ;
p - > state = cStateInvalid ;
}
inline ~ raw_node ( )
{
node * p = reinterpret_cast < node * > ( this ) ;
if ( p - > state )
hash_map_type : : destruct_value_type ( p ) ;
}
inline raw_node ( const raw_node & other )
{
node * pDst = reinterpret_cast < node * > ( this ) ;
const node * pSrc = reinterpret_cast < const node * > ( & other ) ;
if ( pSrc - > state )
{
hash_map_type : : construct_value_type ( pDst , pSrc ) ;
pDst - > state = cStateValid ;
}
else
pDst - > state = cStateInvalid ;
}
inline raw_node & operator = ( const raw_node & rhs )
{
if ( this = = & rhs )
return * this ;
node * pDst = reinterpret_cast < node * > ( this ) ;
const node * pSrc = reinterpret_cast < const node * > ( & rhs ) ;
if ( pSrc - > state )
{
if ( pDst - > state )
{
pDst - > first = pSrc - > first ;
pDst - > second = pSrc - > second ;
}
else
{
hash_map_type : : construct_value_type ( pDst , pSrc ) ;
pDst - > state = cStateValid ;
}
}
else if ( pDst - > state )
{
hash_map_type : : destruct_value_type ( pDst ) ;
pDst - > state = cStateInvalid ;
}
return * this ;
}
uint8_t m_bits [ sizeof ( node ) ] ;
} ;
typedef basisu : : vector < raw_node > node_vector ;
node_vector m_values ;
uint32_t m_hash_shift ;
Hasher m_hasher ;
Equals m_equals ;
uint32_t m_num_valid ;
uint32_t m_grow_threshold ;
inline uint32_t hash_key ( const Key & k ) const
{
assert ( ( 1U < < ( 32U - m_hash_shift ) ) = = m_values . size ( ) ) ;
uint32_t hash = static_cast < uint32_t > ( m_hasher ( k ) ) ;
// Fibonacci hashing
hash = ( 2654435769U * hash ) > > m_hash_shift ;
assert ( hash < m_values . size ( ) ) ;
return hash ;
}
inline const node & get_node ( uint32_t index ) const
{
return * reinterpret_cast < const node * > ( & m_values [ index ] ) ;
}
inline node & get_node ( uint32_t index )
{
return * reinterpret_cast < node * > ( & m_values [ index ] ) ;
}
inline state get_node_state ( uint32_t index ) const
{
return static_cast < state > ( get_node ( index ) . state ) ;
}
inline void set_node_state ( uint32_t index , bool valid )
{
get_node ( index ) . state = valid ;
}
inline void grow ( )
{
uint64_t n = m_values . size ( ) * 3ULL ; // was * 2
if ( ! helpers : : is_power_of_2 ( n ) )
n = helpers : : next_pow2 ( n ) ;
if ( n > 0x80000000UL )
n = 0x80000000UL ;
rehash ( helpers : : maximum < uint32_t > ( cMinHashSize , ( uint32_t ) n ) ) ;
}
inline void rehash ( uint32_t new_hash_size )
{
assert ( new_hash_size > = m_num_valid ) ;
assert ( helpers : : is_power_of_2 ( new_hash_size ) ) ;
if ( ( new_hash_size < m_num_valid ) | | ( new_hash_size = = m_values . size ( ) ) )
return ;
hash_map new_map ;
new_map . m_values . resize ( new_hash_size ) ;
new_map . m_hash_shift = 32U - helpers : : floor_log2i ( new_hash_size ) ;
assert ( new_hash_size = = ( 1U < < ( 32U - new_map . m_hash_shift ) ) ) ;
new_map . m_grow_threshold = UINT_MAX ;
node * pNode = reinterpret_cast < node * > ( m_values . begin ( ) ) ;
node * pNode_end = pNode + m_values . size ( ) ;
while ( pNode ! = pNode_end )
{
if ( pNode - > state )
{
new_map . move_into ( pNode ) ;
if ( new_map . m_num_valid = = m_num_valid )
break ;
}
pNode + + ;
}
new_map . m_grow_threshold = ( new_hash_size + 1U ) > > 1U ;
m_values . clear_no_destruction ( ) ;
m_hash_shift = 32 ;
swap ( new_map ) ;
}
inline uint32_t find_next ( uint32_t index ) const
{
index + + ;
if ( index > = m_values . size ( ) )
return index ;
const node * pNode = & get_node ( index ) ;
for ( ; ; )
{
if ( pNode - > state )
break ;
if ( + + index > = m_values . size ( ) )
break ;
pNode + + ;
}
return index ;
}
inline uint32_t find_index ( const Key & k ) const
{
if ( m_num_valid )
{
uint32_t index = hash_key ( k ) ;
const node * pNode = & get_node ( index ) ;
if ( pNode - > state )
{
if ( m_equals ( pNode - > first , k ) )
return index ;
const uint32_t orig_index = index ;
for ( ; ; )
{
if ( ! index )
{
index = m_values . size ( ) - 1 ;
pNode = & get_node ( index ) ;
}
else
{
index - - ;
pNode - - ;
}
if ( index = = orig_index )
break ;
if ( ! pNode - > state )
break ;
if ( m_equals ( pNode - > first , k ) )
return index ;
}
}
}
return m_values . size ( ) ;
}
inline bool insert_no_grow ( insert_result & result , const Key & k , const Value & v = Value ( ) )
{
if ( ! m_values . size ( ) )
return false ;
uint32_t index = hash_key ( k ) ;
node * pNode = & get_node ( index ) ;
if ( pNode - > state )
{
if ( m_equals ( pNode - > first , k ) )
{
result . first = iterator ( * this , index ) ;
result . second = false ;
return true ;
}
const uint32_t orig_index = index ;
for ( ; ; )
{
if ( ! index )
{
index = m_values . size ( ) - 1 ;
pNode = & get_node ( index ) ;
}
else
{
index - - ;
pNode - - ;
}
if ( orig_index = = index )
return false ;
if ( ! pNode - > state )
break ;
if ( m_equals ( pNode - > first , k ) )
{
result . first = iterator ( * this , index ) ;
result . second = false ;
return true ;
}
}
}
if ( m_num_valid > = m_grow_threshold )
return false ;
construct_value_type ( pNode , k , v ) ;
pNode - > state = cStateValid ;
m_num_valid + + ;
assert ( m_num_valid < = m_values . size ( ) ) ;
result . first = iterator ( * this , index ) ;
result . second = true ;
return true ;
}
inline void move_into ( node * pNode )
{
uint32_t index = hash_key ( pNode - > first ) ;
node * pDst_node = & get_node ( index ) ;
if ( pDst_node - > state )
{
const uint32_t orig_index = index ;
for ( ; ; )
{
if ( ! index )
{
index = m_values . size ( ) - 1 ;
pDst_node = & get_node ( index ) ;
}
else
{
index - - ;
pDst_node - - ;
}
if ( index = = orig_index )
{
assert ( false ) ;
return ;
}
if ( ! pDst_node - > state )
break ;
}
}
move_node ( pDst_node , pNode , false ) ;
m_num_valid + + ;
}
} ;
template < typename Key , typename Value , typename Hasher , typename Equals >
struct bitwise_movable < hash_map < Key , Value , Hasher , Equals > > { enum { cFlag = true } ; } ;
# if BASISU_HASHMAP_TEST
extern void hash_map_test ( ) ;
# endif
} // namespace basisu
namespace std
{
template < typename T >
inline void swap ( basisu : : vector < T > & a , basisu : : vector < T > & b )
{
a . swap ( b ) ;
}
template < typename Key , typename Value , typename Hasher , typename Equals >
inline void swap ( basisu : : hash_map < Key , Value , Hasher , Equals > & a , basisu : : hash_map < Key , Value , Hasher , Equals > & b )
{
a . swap ( b ) ;
}
} // namespace std