2017-02-16 09:43:50 +00:00
///////////////////////////////////////////////////////////////////////////////
//
// Copyright (c) 2015 Microsoft Corporation. All rights reserved.
//
// This code is licensed under the MIT License (MIT).
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
//
///////////////////////////////////////////////////////////////////////////////
// Adapted from https://github.com/Microsoft/GSL/blob/3819df6e378ffccf0e29465afe99c3b324c2aa70/include/gsl/span
// and https://github.com/Microsoft/GSL/blob/3819df6e378ffccf0e29465afe99c3b324c2aa70/include/gsl/gsl_util
# ifndef mozilla_Span_h
# define mozilla_Span_h
# include "mozilla/Array.h"
# include "mozilla/Assertions.h"
# include "mozilla/Casting.h"
# include "mozilla/IntegerTypeTraits.h"
# include "mozilla/Move.h"
# include "mozilla/TypeTraits.h"
# include "mozilla/UniquePtr.h"
# include <algorithm>
# include <array>
# include <cstring>
# include <iterator>
// Classifications for reasons why constexpr was removed in C++14 to C++11
// conversion. Once we upgrade compilers, we can try defining each of these
// to constexpr to restore a category of constexprs at a time.
# define MOZ_SPAN_ASSERTION_CONSTEXPR
# define MOZ_SPAN_GCC_CONSTEXPR
# define MOZ_SPAN_EXPLICITLY_DEFAULTED_CONSTEXPR
# define MOZ_SPAN_CONSTEXPR_NOT_JUST_RETURN
# define MOZ_SPAN_NON_CONST_CONSTEXPR
# ifdef _MSC_VER
# pragma warning(push)
// turn off some warnings that are noisy about our MOZ_RELEASE_ASSERT statements
# pragma warning(disable : 4127) // conditional expression is constant
// blanket turn off warnings from CppCoreCheck for now
// so people aren't annoyed by them when running the tool.
// more targeted suppressions will be added in a future update to the GSL
# pragma warning(disable : 26481 26482 26483 26485 26490 26491 26492 26493 26495)
# if _MSC_VER < 1910
# pragma push_macro("constexpr")
# define constexpr /*constexpr*/
# endif // _MSC_VER < 1910
# endif // _MSC_VER
namespace mozilla {
// Stuff from gsl_util
// narrow_cast(): a searchable way to do narrowing casts of values
template < class T , class U >
inline constexpr T
narrow_cast ( U & & u )
{
return static_cast < T > ( mozilla : : Forward < U > ( u ) ) ;
}
// end gsl_util
// [views.constants], constants
// This was -1 in gsl::span, but using size_t for sizes instead of ptrdiff_t
// and reserving a magic value that realistically doesn't occur in
// compile-time-constant Span sizes makes things a lot less messy in terms of
// comparison between signed and unsigned.
constexpr const size_t dynamic_extent = mozilla : : MaxValue < size_t > : : value ;
template < class ElementType , size_t Extent = dynamic_extent >
class Span ;
// implementation details
namespace span_details {
2017-04-04 11:04:14 +00:00
inline size_t strlen16 ( const char16_t * aZeroTerminated ) {
size_t len = 0 ;
while ( * ( aZeroTerminated + + ) ) {
len + + ;
}
return len ;
}
2017-02-16 09:43:50 +00:00
// C++14 types that we don't have because we build as C++11.
template < class T >
using remove_cv_t = typename mozilla : : RemoveCV < T > : : Type ;
template < class T >
using remove_const_t = typename mozilla : : RemoveConst < T > : : Type ;
template < bool B , class T , class F >
using conditional_t = typename mozilla : : Conditional < B , T , F > : : Type ;
template < class T >
using add_pointer_t = typename mozilla : : AddPointer < T > : : Type ;
template < bool B , class T = void >
using enable_if_t = typename mozilla : : EnableIf < B , T > : : Type ;
template < class T >
struct is_span_oracle : mozilla : : FalseType
{
} ;
template < class ElementType , size_t Extent >
struct is_span_oracle < mozilla : : Span < ElementType , Extent > > : mozilla : : TrueType
{
} ;
template < class T >
struct is_span : public is_span_oracle < remove_cv_t < T > >
{
} ;
template < class T >
struct is_std_array_oracle : mozilla : : FalseType
{
} ;
template < class ElementType , size_t Extent >
struct is_std_array_oracle < std : : array < ElementType , Extent > > : mozilla : : TrueType
{
} ;
template < class T >
struct is_std_array : public is_std_array_oracle < remove_cv_t < T > >
{
} ;
template < size_t From , size_t To >
struct is_allowed_extent_conversion
: public mozilla : : IntegralConstant < bool ,
From = = To | |
From = = mozilla : : dynamic_extent | |
To = = mozilla : : dynamic_extent >
{
} ;
template < class From , class To >
struct is_allowed_element_type_conversion
: public mozilla : : IntegralConstant < bool , mozilla : : IsConvertible < From ( * ) [ ] , To ( * ) [ ] > : : value >
{
} ;
template < class Span , bool IsConst >
class span_iterator
{
using element_type_ = typename Span : : element_type ;
public :
using iterator_category = std : : random_access_iterator_tag ;
using value_type = remove_const_t < element_type_ > ;
using difference_type = typename Span : : index_type ;
using reference = conditional_t < IsConst , const element_type_ , element_type_ > & ;
using pointer = add_pointer_t < reference > ;
constexpr span_iterator ( ) : span_iterator ( nullptr , 0 ) { }
MOZ_SPAN_ASSERTION_CONSTEXPR span_iterator ( const Span * span ,
typename Span : : index_type index )
: span_ ( span )
, index_ ( index )
{
MOZ_RELEASE_ASSERT ( span = = nullptr | |
( index_ > = 0 & & index < = span_ - > Length ( ) ) ) ;
}
friend class span_iterator < Span , true > ;
constexpr MOZ_IMPLICIT span_iterator ( const span_iterator < Span , false > & other )
: span_iterator ( other . span_ , other . index_ )
{
}
MOZ_SPAN_EXPLICITLY_DEFAULTED_CONSTEXPR span_iterator < Span , IsConst > &
operator = ( const span_iterator < Span , IsConst > & ) = default ;
MOZ_SPAN_GCC_CONSTEXPR reference operator * ( ) const
{
MOZ_RELEASE_ASSERT ( span_ ) ;
return ( * span_ ) [ index_ ] ;
}
MOZ_SPAN_GCC_CONSTEXPR pointer operator - > ( ) const
{
MOZ_RELEASE_ASSERT ( span_ ) ;
return & ( ( * span_ ) [ index_ ] ) ;
}
MOZ_SPAN_NON_CONST_CONSTEXPR span_iterator & operator + + ( )
{
MOZ_RELEASE_ASSERT ( span_ & & index_ > = 0 & & index_ < span_ - > Length ( ) ) ;
+ + index_ ;
return * this ;
}
MOZ_SPAN_NON_CONST_CONSTEXPR span_iterator operator + + ( int )
{
auto ret = * this ;
+ + ( * this ) ;
return ret ;
}
MOZ_SPAN_NON_CONST_CONSTEXPR span_iterator & operator - - ( )
{
MOZ_RELEASE_ASSERT ( span_ & & index_ > 0 & & index_ < = span_ - > Length ( ) ) ;
- - index_ ;
return * this ;
}
MOZ_SPAN_NON_CONST_CONSTEXPR span_iterator operator - - ( int )
{
auto ret = * this ;
- - ( * this ) ;
return ret ;
}
MOZ_SPAN_CONSTEXPR_NOT_JUST_RETURN span_iterator
operator + ( difference_type n ) const
{
auto ret = * this ;
return ret + = n ;
}
MOZ_SPAN_GCC_CONSTEXPR span_iterator & operator + = ( difference_type n )
{
MOZ_RELEASE_ASSERT ( span_ & & ( index_ + n ) > = 0 & &
( index_ + n ) < = span_ - > Length ( ) ) ;
index_ + = n ;
return * this ;
}
MOZ_SPAN_CONSTEXPR_NOT_JUST_RETURN span_iterator
operator - ( difference_type n ) const
{
auto ret = * this ;
return ret - = n ;
}
MOZ_SPAN_NON_CONST_CONSTEXPR span_iterator & operator - = ( difference_type n )
{
return * this + = - n ;
}
MOZ_SPAN_GCC_CONSTEXPR difference_type
operator - ( const span_iterator & rhs ) const
{
MOZ_RELEASE_ASSERT ( span_ = = rhs . span_ ) ;
return index_ - rhs . index_ ;
}
constexpr reference operator [ ] ( difference_type n ) const
{
return * ( * this + n ) ;
}
constexpr friend bool operator = = ( const span_iterator & lhs ,
const span_iterator & rhs )
{
return lhs . span_ = = rhs . span_ & & lhs . index_ = = rhs . index_ ;
}
constexpr friend bool operator ! = ( const span_iterator & lhs ,
const span_iterator & rhs )
{
return ! ( lhs = = rhs ) ;
}
MOZ_SPAN_GCC_CONSTEXPR friend bool operator < ( const span_iterator & lhs ,
const span_iterator & rhs )
{
MOZ_RELEASE_ASSERT ( lhs . span_ = = rhs . span_ ) ;
return lhs . index_ < rhs . index_ ;
}
2017-04-20 18:58:38 +00:00
MOZ_SPAN_GCC_CONSTEXPR friend bool operator < = ( const span_iterator & lhs ,
const span_iterator & rhs )
2017-02-16 09:43:50 +00:00
{
return ! ( rhs < lhs ) ;
}
2017-04-20 18:58:38 +00:00
MOZ_SPAN_GCC_CONSTEXPR friend bool operator > ( const span_iterator & lhs ,
const span_iterator & rhs )
2017-02-16 09:43:50 +00:00
{
return rhs < lhs ;
}
2017-04-20 18:58:38 +00:00
MOZ_SPAN_GCC_CONSTEXPR friend bool operator > = ( const span_iterator & lhs ,
const span_iterator & rhs )
2017-02-16 09:43:50 +00:00
{
return ! ( rhs > lhs ) ;
}
void swap ( span_iterator & rhs )
{
std : : swap ( index_ , rhs . index_ ) ;
std : : swap ( span_ , rhs . span_ ) ;
}
protected :
const Span * span_ ;
size_t index_ ;
} ;
template < class Span , bool IsConst >
inline constexpr span_iterator < Span , IsConst >
operator + ( typename span_iterator < Span , IsConst > : : difference_type n ,
const span_iterator < Span , IsConst > & rhs )
{
return rhs + n ;
}
template < size_t Ext >
class extent_type
{
public :
using index_type = size_t ;
static_assert ( Ext > = 0 , " A fixed-size Span must be >= 0 in size. " ) ;
constexpr extent_type ( ) { }
template < index_type Other >
MOZ_SPAN_ASSERTION_CONSTEXPR MOZ_IMPLICIT extent_type ( extent_type < Other > ext )
{
static_assert (
Other = = Ext | | Other = = dynamic_extent ,
" Mismatch between fixed-size extent and size of initializing data. " ) ;
MOZ_RELEASE_ASSERT ( ext . size ( ) = = Ext ) ;
}
MOZ_SPAN_ASSERTION_CONSTEXPR MOZ_IMPLICIT extent_type ( index_type length )
{
MOZ_RELEASE_ASSERT ( length = = Ext ) ;
}
constexpr index_type size ( ) const { return Ext ; }
} ;
template < >
class extent_type < dynamic_extent >
{
public :
using index_type = size_t ;
template < index_type Other >
explicit constexpr extent_type ( extent_type < Other > ext )
: size_ ( ext . size ( ) )
{
}
explicit constexpr extent_type ( index_type length )
: size_ ( length )
{
}
constexpr index_type size ( ) const { return size_ ; }
private :
index_type size_ ;
} ;
} // namespace span_details
/**
* Span - slices for C + +
*
* Span implements Rust ' s slice concept for C + + . It ' s called " Span " instead of
* " Slice " to follow the naming used in C + + Core Guidelines .
*
* A Span wraps a pointer and a length that identify a non - owning view to a
* contiguous block of memory of objects of the same type . Various types ,
* including ( pre - decay ) C arrays , XPCOM strings , nsTArray , mozilla : : Array ,
* mozilla : : Range and contiguous standard - library containers , auto - convert
* into Spans when attempting to pass them as arguments to methods that take
* Spans . MakeSpan ( ) functions can be used for explicit conversion in other
* contexts . ( Span itself autoconverts into mozilla : : Range . )
*
* Like Rust ' s slices , Span provides safety against out - of - bounds access by
* performing run - time bound checks . However , unlike Rust ' s slices , Span
* cannot provide safety against use - after - free .
*
* ( Note : Span is like Rust ' s slice only conceptually . Due to the lack of
* ABI guarantees , you should still decompose spans / slices to raw pointer
* and length parts when crossing the FFI . )
*
* In addition to having constructors and MakeSpan ( ) functions that take
* various well - known types , a Span for an arbitrary type can be constructed
* ( via constructor or MakeSpan ( ) ) from a pointer and a length or a pointer
* and another pointer pointing just past the last element .
*
2017-04-04 11:04:14 +00:00
* A Span < const char > or Span < const char16_t > can be obtained for const char *
* or const char16_t pointing to a zero - terminated string using the
* MakeStringSpan ( ) function . Corresponding implicit constructor does not exist
* in order to avoid accidental construction in cases where const char * or
* const char16_t * do not point to a zero - terminated string .
2017-02-16 09:43:50 +00:00
*
* Span has methods that follow the Mozilla naming style and methods that
* don ' t . The methods that follow the Mozilla naming style are meant to be
* used directly from Mozilla code . The methods that don ' t are meant for
* integration with C + + 11 range - based loops and with meta - programming that
* expects the same methods that are found on the standard - library
* containers . For example , to decompose a Span into its parts in Mozilla
* code , use Elements ( ) and Length ( ) ( as with nsTArray ) instead of data ( )
* and size ( ) ( as with std : : vector ) .
*
* The pointer and length wrapped by a Span cannot be changed after a Span has
* been created . When new values are required , simply create a new Span . Span
* has a method called Subspan ( ) that works analogously to the Substring ( )
* method of XPCOM strings taking a start index and an optional length . As a
* Mozilla extension ( relative to Microsoft ' s gsl : : span that mozilla : : Span is
* based on ) , Span has methods From ( start ) , To ( end ) and FromTo ( start , end )
* that correspond to Rust ' s & slice [ start . . ] , & slice [ . . end ] and
* & slice [ start . . end ] , respectively . ( That is , the end index is the index of
* the first element not to be included in the new subspan . )
*
* When indicating a Span that ' s only read from , const goes inside the type
* parameter . Don ' t put const in front of Span . That is :
* size_t ReadsFromOneSpanAndWritesToAnother ( Span < const uint8_t > aReadFrom ,
* Span < uint8_t > aWrittenTo ) ;
*
* Any Span < const T > can be viewed as Span < const uint8_t > using the function
* AsBytes ( ) . Any Span < T > can be viewed as Span < uint8_t > using the function
* AsWritableBytes ( ) .
*/
template < class ElementType , size_t Extent >
class Span
{
public :
// constants and types
using element_type = ElementType ;
using index_type = size_t ;
using pointer = element_type * ;
using reference = element_type & ;
using iterator =
span_details : : span_iterator < Span < ElementType , Extent > , false > ;
using const_iterator =
span_details : : span_iterator < Span < ElementType , Extent > , true > ;
using reverse_iterator = std : : reverse_iterator < iterator > ;
using const_reverse_iterator = std : : reverse_iterator < const_iterator > ;
constexpr static const index_type extent = Extent ;
// [Span.cons], Span constructors, copy, assignment, and destructor
// "Dependent" is needed to make "span_details::enable_if_t<(Dependent || Extent == 0 || Extent == mozilla::MaxValue<size_t>::value)>" SFINAE,
// since "span_details::enable_if_t<(Extent == 0 || Extent == mozilla::MaxValue<size_t>::value)>" is ill-formed when Extent is neither of the extreme values.
/**
* Constructor with no args .
*/
template <
bool Dependent = false ,
class = span_details : : enable_if_t <
( Dependent | | Extent = = 0 | | Extent = = mozilla : : MaxValue < size_t > : : value ) > >
constexpr Span ( )
: storage_ ( nullptr , span_details : : extent_type < 0 > ( ) )
{
}
/**
* Constructor for nullptr .
*/
constexpr MOZ_IMPLICIT Span ( std : : nullptr_t ) : Span ( ) { }
/**
* Constructor for pointer and length .
*/
constexpr Span ( pointer aPtr , index_type aLength )
: storage_ ( aPtr , aLength )
{
}
/**
* Constructor for start pointer and pointer past end .
*/
constexpr Span ( pointer aStartPtr , pointer aEndPtr )
: storage_ ( aStartPtr , std : : distance ( aStartPtr , aEndPtr ) )
{
}
/**
* Constructor for C array .
*/
template < size_t N >
constexpr MOZ_IMPLICIT Span ( element_type ( & aArr ) [ N ] )
: storage_ ( & aArr [ 0 ] , span_details : : extent_type < N > ( ) )
{
}
/**
* Constructor for std : : array .
*/
template < size_t N ,
class ArrayElementType = span_details : : remove_const_t < element_type > >
constexpr MOZ_IMPLICIT Span ( std : : array < ArrayElementType , N > & aArr )
: storage_ ( & aArr [ 0 ] , span_details : : extent_type < N > ( ) )
{
}
/**
* Constructor for const std : : array .
*/
template < size_t N >
constexpr MOZ_IMPLICIT Span (
const std : : array < span_details : : remove_const_t < element_type > , N > & aArr )
: storage_ ( & aArr [ 0 ] , span_details : : extent_type < N > ( ) )
{
}
/**
* Constructor for mozilla : : Array .
*/
template < size_t N ,
class ArrayElementType = span_details : : remove_const_t < element_type > >
constexpr MOZ_IMPLICIT Span ( mozilla : : Array < ArrayElementType , N > & aArr )
: storage_ ( & aArr [ 0 ] , span_details : : extent_type < N > ( ) )
{
}
/**
* Constructor for const mozilla : : Array .
*/
template < size_t N >
constexpr MOZ_IMPLICIT Span (
const mozilla : : Array < span_details : : remove_const_t < element_type > , N > & aArr )
: storage_ ( & aArr [ 0 ] , span_details : : extent_type < N > ( ) )
{
}
/**
* Constructor for mozilla : : UniquePtr holding an array and length .
*/
template < class ArrayElementType = std : : add_pointer < element_type > >
constexpr Span ( const mozilla : : UniquePtr < ArrayElementType > & aPtr ,
index_type aLength )
: storage_ ( aPtr . get ( ) , aLength )
{
}
// NB: the SFINAE here uses .data() as a incomplete/imperfect proxy for the requirement
// on Container to be a contiguous sequence container.
/**
* Constructor for standard - library containers .
*/
template <
class Container ,
class = span_details : : enable_if_t <
! span_details : : is_span < Container > : : value & &
! span_details : : is_std_array < Container > : : value & &
mozilla : : IsConvertible < typename Container : : pointer , pointer > : : value & &
mozilla : : IsConvertible < typename Container : : pointer ,
decltype ( mozilla : : DeclVal < Container > ( ) . data ( ) ) > : : value > >
constexpr MOZ_IMPLICIT Span ( Container & cont )
: Span ( cont . data ( ) , ReleaseAssertedCast < index_type > ( cont . size ( ) ) )
{
}
/**
* Constructor for standard - library containers ( const version ) .
*/
template <
class Container ,
class = span_details : : enable_if_t <
mozilla : : IsConst < element_type > : : value & &
! span_details : : is_span < Container > : : value & &
mozilla : : IsConvertible < typename Container : : pointer , pointer > : : value & &
mozilla : : IsConvertible < typename Container : : pointer ,
decltype ( mozilla : : DeclVal < Container > ( ) . data ( ) ) > : : value > >
constexpr MOZ_IMPLICIT Span ( const Container & cont )
: Span ( cont . data ( ) , ReleaseAssertedCast < index_type > ( cont . size ( ) ) )
{
}
/**
* Constructor from other Span .
*/
constexpr Span ( const Span & other ) = default ;
/**
* Constructor from other Span .
*/
constexpr Span ( Span & & other ) = default ;
/**
* Constructor from other Span with conversion of element type .
*/
template <
class OtherElementType ,
size_t OtherExtent ,
class = span_details : : enable_if_t <
span_details : : is_allowed_extent_conversion < OtherExtent , Extent > : : value & &
span_details : : is_allowed_element_type_conversion < OtherElementType ,
element_type > : : value > >
constexpr MOZ_IMPLICIT Span ( const Span < OtherElementType , OtherExtent > & other )
: storage_ ( other . data ( ) ,
span_details : : extent_type < OtherExtent > ( other . size ( ) ) )
{
}
/**
* Constructor from other Span with conversion of element type .
*/
template <
class OtherElementType ,
size_t OtherExtent ,
class = span_details : : enable_if_t <
span_details : : is_allowed_extent_conversion < OtherExtent , Extent > : : value & &
span_details : : is_allowed_element_type_conversion < OtherElementType ,
element_type > : : value > >
constexpr MOZ_IMPLICIT Span ( Span < OtherElementType , OtherExtent > & & other )
: storage_ ( other . data ( ) ,
span_details : : extent_type < OtherExtent > ( other . size ( ) ) )
{
}
~ Span ( ) = default ;
MOZ_SPAN_EXPLICITLY_DEFAULTED_CONSTEXPR Span & operator = ( const Span & other )
= default ;
MOZ_SPAN_EXPLICITLY_DEFAULTED_CONSTEXPR Span & operator = ( Span & & other )
= default ;
// [Span.sub], Span subviews
/**
* Subspan with first N elements with compile - time N .
*/
template < size_t Count >
MOZ_SPAN_GCC_CONSTEXPR Span < element_type , Count > First ( ) const
{
MOZ_RELEASE_ASSERT ( Count < = size ( ) ) ;
return { data ( ) , Count } ;
}
/**
* Subspan with last N elements with compile - time N .
*/
template < size_t Count >
MOZ_SPAN_GCC_CONSTEXPR Span < element_type , Count > Last ( ) const
{
MOZ_RELEASE_ASSERT ( Count < = size ( ) ) ;
return { data ( ) + ( size ( ) - Count ) , Count } ;
}
/**
* Subspan with compile - time start index and length .
*/
template < size_t Offset , size_t Count = dynamic_extent >
MOZ_SPAN_GCC_CONSTEXPR Span < element_type , Count > Subspan ( ) const
{
MOZ_RELEASE_ASSERT ( Offset < = size ( ) & &
( Count = = dynamic_extent | | ( Offset + Count < = size ( ) ) ) ) ;
return { data ( ) + Offset ,
Count = = dynamic_extent ? size ( ) - Offset : Count } ;
}
/**
* Subspan with first N elements with run - time N .
*/
MOZ_SPAN_GCC_CONSTEXPR Span < element_type , dynamic_extent > First (
index_type aCount ) const
{
MOZ_RELEASE_ASSERT ( aCount < = size ( ) ) ;
return { data ( ) , aCount } ;
}
/**
* Subspan with last N elements with run - time N .
*/
MOZ_SPAN_GCC_CONSTEXPR Span < element_type , dynamic_extent > Last (
index_type aCount ) const
{
MOZ_RELEASE_ASSERT ( aCount < = size ( ) ) ;
return { data ( ) + ( size ( ) - aCount ) , aCount } ;
}
/**
* Subspan with run - time start index and length .
*/
MOZ_SPAN_GCC_CONSTEXPR Span < element_type , dynamic_extent > Subspan (
index_type aStart ,
index_type aLength = dynamic_extent ) const
{
MOZ_RELEASE_ASSERT ( aStart < = size ( ) & &
( aLength = = dynamic_extent | |
( aStart + aLength < = size ( ) ) ) ) ;
return { data ( ) + aStart ,
aLength = = dynamic_extent ? size ( ) - aStart : aLength } ;
}
/**
* Subspan with run - time start index . ( Rust ' s & foo [ start . . ] )
*/
MOZ_SPAN_GCC_CONSTEXPR Span < element_type , dynamic_extent > From (
index_type aStart ) const
{
return Subspan ( aStart ) ;
}
/**
* Subspan with run - time exclusive end index . ( Rust ' s & foo [ . . end ] )
*/
MOZ_SPAN_GCC_CONSTEXPR Span < element_type , dynamic_extent > To (
index_type aEnd ) const
{
return Subspan ( 0 , aEnd ) ;
}
/**
* Subspan with run - time start index and exclusive end index .
* ( Rust ' s & foo [ start . . end ] )
*/
MOZ_SPAN_GCC_CONSTEXPR Span < element_type , dynamic_extent > FromTo (
index_type aStart ,
index_type aEnd ) const
{
MOZ_RELEASE_ASSERT ( aStart < = aEnd ) ;
return Subspan ( aStart , aEnd - aStart ) ;
}
// [Span.obs], Span observers
/**
* Number of elements in the span .
*/
constexpr index_type Length ( ) const { return size ( ) ; }
/**
* Number of elements in the span ( standard - libray duck typing version ) .
*/
constexpr index_type size ( ) const { return storage_ . size ( ) ; }
/**
* Size of the span in bytes .
*/
constexpr index_type LengthBytes ( ) const { return size_bytes ( ) ; }
/**
* Size of the span in bytes ( standard - library naming style version ) .
*/
constexpr index_type size_bytes ( ) const
{
return size ( ) * narrow_cast < index_type > ( sizeof ( element_type ) ) ;
}
/**
* Checks if the the length of the span is zero .
*/
constexpr bool IsEmpty ( ) const { return empty ( ) ; }
/**
* Checks if the the length of the span is zero ( standard - libray duck
* typing version ) .
*/
constexpr bool empty ( ) const { return size ( ) = = 0 ; }
// [Span.elem], Span element access
MOZ_SPAN_GCC_CONSTEXPR reference operator [ ] ( index_type idx ) const
{
MOZ_RELEASE_ASSERT ( idx < storage_ . size ( ) ) ;
return data ( ) [ idx ] ;
}
/**
* Access element of span by index ( standard - library duck typing version ) .
*/
constexpr reference at ( index_type idx ) const { return this - > operator [ ] ( idx ) ; }
constexpr reference operator ( ) ( index_type idx ) const
{
return this - > operator [ ] ( idx ) ;
}
/**
* Pointer to the first element of the span .
*/
constexpr pointer Elements ( ) const { return data ( ) ; }
/**
* Pointer to the first element of the span ( standard - libray duck typing version ) .
*/
constexpr pointer data ( ) const { return storage_ . data ( ) ; }
// [Span.iter], Span iterator support
iterator begin ( ) const { return { this , 0 } ; }
iterator end ( ) const { return { this , Length ( ) } ; }
const_iterator cbegin ( ) const { return { this , 0 } ; }
const_iterator cend ( ) const { return { this , Length ( ) } ; }
reverse_iterator rbegin ( ) const
{
return reverse_iterator { end ( ) } ;
}
reverse_iterator rend ( ) const
{
return reverse_iterator { begin ( ) } ;
}
const_reverse_iterator crbegin ( ) const
{
return const_reverse_iterator { cend ( ) } ;
}
const_reverse_iterator crend ( ) const
{
return const_reverse_iterator { cbegin ( ) } ;
}
private :
// this implementation detail class lets us take advantage of the
// empty base class optimization to pay for only storage of a single
// pointer in the case of fixed-size Spans
template < class ExtentType >
class storage_type : public ExtentType
{
public :
template < class OtherExtentType >
MOZ_SPAN_ASSERTION_CONSTEXPR storage_type ( pointer elements ,
OtherExtentType ext )
: ExtentType ( ext )
, data_ ( elements )
{
MOZ_RELEASE_ASSERT (
( ! elements & & ExtentType : : size ( ) = = 0 ) | |
( elements & & ExtentType : : size ( ) ! = mozilla : : MaxValue < size_t > : : value ) ) ;
}
constexpr pointer data ( ) const { return data_ ; }
private :
pointer data_ ;
} ;
storage_type < span_details : : extent_type < Extent > > storage_ ;
} ;
// [Span.comparison], Span comparison operators
template < class ElementType , size_t FirstExtent , size_t SecondExtent >
inline constexpr bool
operator = = ( const Span < ElementType , FirstExtent > & l ,
const Span < ElementType , SecondExtent > & r )
{
return ( l . size ( ) = = r . size ( ) ) & & std : : equal ( l . begin ( ) , l . end ( ) , r . begin ( ) ) ;
}
template < class ElementType , size_t Extent >
inline constexpr bool
operator ! = ( const Span < ElementType , Extent > & l ,
const Span < ElementType , Extent > & r )
{
return ! ( l = = r ) ;
}
template < class ElementType , size_t Extent >
inline constexpr bool
operator < ( const Span < ElementType , Extent > & l ,
const Span < ElementType , Extent > & r )
{
return std : : lexicographical_compare ( l . begin ( ) , l . end ( ) , r . begin ( ) , r . end ( ) ) ;
}
template < class ElementType , size_t Extent >
inline constexpr bool
operator < = ( const Span < ElementType , Extent > & l ,
const Span < ElementType , Extent > & r )
{
return ! ( l > r ) ;
}
template < class ElementType , size_t Extent >
inline constexpr bool
operator > ( const Span < ElementType , Extent > & l ,
const Span < ElementType , Extent > & r )
{
return r < l ;
}
template < class ElementType , size_t Extent >
inline constexpr bool
operator > = ( const Span < ElementType , Extent > & l ,
const Span < ElementType , Extent > & r )
{
return ! ( l < r ) ;
}
namespace span_details {
// if we only supported compilers with good constexpr support then
// this pair of classes could collapse down to a constexpr function
// we should use a narrow_cast<> to go to size_t, but older compilers may not see it as
// constexpr
// and so will fail compilation of the template
template < class ElementType , size_t Extent >
struct calculate_byte_size
: mozilla : : IntegralConstant < size_t ,
static_cast < size_t > ( sizeof ( ElementType ) *
static_cast < size_t > ( Extent ) ) >
{
} ;
template < class ElementType >
struct calculate_byte_size < ElementType , dynamic_extent >
: mozilla : : IntegralConstant < size_t , dynamic_extent >
{
} ;
}
// [Span.objectrep], views of object representation
/**
* View span as Span < const uint8_t > .
*/
template < class ElementType , size_t Extent >
Span < const uint8_t ,
span_details : : calculate_byte_size < ElementType , Extent > : : value >
AsBytes ( Span < ElementType , Extent > s )
{
return { reinterpret_cast < const uint8_t * > ( s . data ( ) ) , s . size_bytes ( ) } ;
}
/**
* View span as Span < uint8_t > .
*/
template < class ElementType ,
size_t Extent ,
class = span_details : : enable_if_t < ! mozilla : : IsConst < ElementType > : : value > >
Span < uint8_t , span_details : : calculate_byte_size < ElementType , Extent > : : value >
AsWritableBytes ( Span < ElementType , Extent > s )
{
return { reinterpret_cast < uint8_t * > ( s . data ( ) ) , s . size_bytes ( ) } ;
}
//
// MakeSpan() - Utility functions for creating Spans
//
/**
* Create span from pointer and length .
*/
template < class ElementType >
Span < ElementType >
MakeSpan ( ElementType * aPtr , typename Span < ElementType > : : index_type aLength )
{
return Span < ElementType > ( aPtr , aLength ) ;
}
/**
* Create span from start pointer and pointer past end .
*/
template < class ElementType >
Span < ElementType >
MakeSpan ( ElementType * aStartPtr , ElementType * aEndPtr )
{
return Span < ElementType > ( aStartPtr , aEndPtr ) ;
}
/**
* Create span from C array .
*/
template < class ElementType , size_t N >
Span < ElementType > MakeSpan ( ElementType ( & aArr ) [ N ] )
{
return Span < ElementType > ( aArr ) ;
}
/**
* Create span from mozilla : : Array .
*/
template < class ElementType , size_t N >
Span < ElementType >
MakeSpan ( mozilla : : Array < ElementType , N > & aArr )
{
return aArr ;
}
/**
* Create span from const mozilla : : Array .
*/
template < class ElementType , size_t N >
Span < const ElementType >
MakeSpan ( const mozilla : : Array < ElementType , N > & arr )
{
return arr ;
}
/**
* Create span from standard - library container .
*/
template < class Container >
Span < typename Container : : value_type >
MakeSpan ( Container & cont )
{
return Span < typename Container : : value_type > ( cont ) ;
}
/**
* Create span from standard - library container ( const version ) .
*/
template < class Container >
Span < const typename Container : : value_type >
MakeSpan ( const Container & cont )
{
return Span < const typename Container : : value_type > ( cont ) ;
}
/**
* Create span from smart pointer and length .
*/
template < class Ptr >
Span < typename Ptr : : element_type >
MakeSpan ( Ptr & aPtr , size_t aLength )
{
return Span < typename Ptr : : element_type > ( aPtr , aLength ) ;
}
/**
* Create span from C string .
*/
inline Span < const char >
2017-04-04 11:04:14 +00:00
MakeStringSpan ( const char * aZeroTerminated )
{
return Span < const char > ( aZeroTerminated , std : : strlen ( aZeroTerminated ) ) ;
}
/**
* Create span from UTF - 16 C string .
*/
inline Span < const char16_t >
MakeStringSpan ( const char16_t * aZeroTerminated )
2017-02-16 09:43:50 +00:00
{
2017-04-04 11:04:14 +00:00
return Span < const char16_t > ( aZeroTerminated , span_details : : strlen16 ( aZeroTerminated ) ) ;
2017-02-16 09:43:50 +00:00
}
} // namespace mozilla
# ifdef _MSC_VER
# if _MSC_VER < 1910
# undef constexpr
# pragma pop_macro("constexpr")
# endif // _MSC_VER < 1910
# pragma warning(pop)
# endif // _MSC_VER
# undef MOZ_SPAN_ASSERTION_CONSTEXPR
# undef MOZ_SPAN_GCC_CONSTEXPR
# undef MOZ_SPAN_EXPLICITLY_DEFAULTED_CONSTEXPR
# undef MOZ_SPAN_CONSTEXPR_NOT_JUST_RETURN
# undef MOZ_SPAN_NON_CONST_CONSTEXPR
# endif // mozilla_Span_h