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/*
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This file is part of solidity .
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solidity is free software : you can redistribute it and / or modify
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it under the terms of the GNU General Public License as published by
the Free Software Foundation , either version 3 of the License , or
( at your option ) any later version .
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solidity is distributed in the hope that it will be useful ,
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but WITHOUT ANY WARRANTY ; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE . See the
GNU General Public License for more details .
You should have received a copy of the GNU General Public License
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along with solidity . If not , see < http : //www.gnu.org/licenses/>.
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*/
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// SPDX-License-Identifier: GPL-3.0
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/** @file CommonData.h
* @ author Gav Wood < i @ gavwood . com >
* @ date 2014
*
* Shared algorithms and data types .
*/
# pragma once
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# include <iterator>
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# include <libsolutil/Common.h>
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# include <vector>
# include <type_traits>
# include <cstring>
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# include <optional>
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# include <string>
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# include <set>
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# include <functional>
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# include <utility>
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# include <type_traits>
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/// Operators need to stay in the global namespace.
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/// Concatenate the contents of a container onto a vector
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template < class T , class U > std : : vector < T > & operator + = ( std : : vector < T > & _a , U & _b )
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{
for ( auto const & i : _b )
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_a . push_back ( T ( i ) ) ;
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return _a ;
}
/// Concatenate the contents of a container onto a vector, move variant.
template < class T , class U > std : : vector < T > & operator + = ( std : : vector < T > & _a , U & & _b )
{
std : : move ( _b . begin ( ) , _b . end ( ) , std : : back_inserter ( _a ) ) ;
return _a ;
}
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/// Concatenate the contents of a container onto a multiset
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template < class U , class . . . T > std : : multiset < T . . . > & operator + = ( std : : multiset < T . . . > & _a , U & _b )
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{
_a . insert ( _b . begin ( ) , _b . end ( ) ) ;
return _a ;
}
/// Concatenate the contents of a container onto a multiset, move variant.
template < class U , class . . . T > std : : multiset < T . . . > & operator + = ( std : : multiset < T . . . > & _a , U & & _b )
{
for ( auto & & x : _b )
_a . insert ( std : : move ( x ) ) ;
return _a ;
}
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/// Concatenate the contents of a container onto a set
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template < class U , class . . . T > std : : set < T . . . > & operator + = ( std : : set < T . . . > & _a , U & _b )
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{
_a . insert ( _b . begin ( ) , _b . end ( ) ) ;
return _a ;
}
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/// Concatenate the contents of a container onto a set, move variant.
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template < class U , class . . . T > std : : set < T . . . > & operator + = ( std : : set < T . . . > & _a , U & & _b )
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{
for ( auto & & x : _b )
_a . insert ( std : : move ( x ) ) ;
return _a ;
}
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/// Concatenate two vectors of elements.
template < class T >
inline std : : vector < T > operator + ( std : : vector < T > const & _a , std : : vector < T > const & _b )
{
std : : vector < T > ret ( _a ) ;
ret + = _b ;
return ret ;
}
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/// Concatenate two vectors of elements, moving them.
template < class T >
inline std : : vector < T > operator + ( std : : vector < T > & & _a , std : : vector < T > & & _b )
{
std : : vector < T > ret ( std : : move ( _a ) ) ;
if ( & _a = = & _b )
ret + = ret ;
else
ret + = std : : move ( _b ) ;
return ret ;
}
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/// Concatenate something to a sets of elements.
template < class T , class U >
inline std : : set < T > operator + ( std : : set < T > const & _a , U & & _b )
{
std : : set < T > ret ( _a ) ;
ret + = std : : forward < U > ( _b ) ;
return ret ;
}
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/// Concatenate something to a sets of elements, move variant.
template < class T , class U >
inline std : : set < T > operator + ( std : : set < T > & & _a , U & & _b )
{
std : : set < T > ret ( std : : move ( _a ) ) ;
ret + = std : : forward < U > ( _b ) ;
return ret ;
}
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/// Remove the elements of a container from a set.
template < class C , class . . . T >
inline std : : set < T . . . > & operator - = ( std : : set < T . . . > & _a , C const & _b )
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{
for ( auto const & x : _b )
_a . erase ( x ) ;
return _a ;
}
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template < class C , class . . . T >
inline std : : set < T . . . > operator - ( std : : set < T . . . > const & _a , C const & _b )
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{
auto result = _a ;
result - = _b ;
return result ;
}
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/// Remove the elements of a container from a multiset.
template < class C , class . . . T >
inline std : : multiset < T . . . > & operator - = ( std : : multiset < T . . . > & _a , C const & _b )
{
for ( auto const & x : _b )
_a . erase ( x ) ;
return _a ;
}
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namespace solidity : : util
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{
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/// Functional map.
/// Returns a container _oc applying @param _op to each element in @param _c.
/// By default _oc is a vector.
/// If another return type is desired, an empty contained of that type
/// is given as @param _oc.
template < class Container , class Callable , class OutputContainer =
std : : vector < std : : invoke_result_t <
Callable ,
decltype ( * std : : begin ( std : : declval < Container > ( ) ) )
> > >
auto applyMap ( Container const & _c , Callable & & _op , OutputContainer _oc = OutputContainer { } )
{
std : : transform ( std : : begin ( _c ) , std : : end ( _c ) , std : : inserter ( _oc , std : : end ( _oc ) ) , _op ) ;
return _oc ;
}
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/// Filter a vector.
/// Returns a copy of the vector after only taking indices `i` such that `_mask[i]` is true.
template < typename T >
std : : vector < T > filter ( std : : vector < T > const & _vec , std : : vector < bool > const & _mask )
{
assert ( _vec . size ( ) = = _mask . size ( ) ) ;
std : : vector < T > ret ;
for ( size_t i = 0 ; i < _mask . size ( ) ; + + i )
if ( _mask [ i ] )
ret . push_back ( _vec [ i ] ) ;
return ret ;
}
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/// Functional fold.
/// Given a container @param _c, an initial value @param _acc,
/// and a binary operator @param _binaryOp(T, U), accumulate
/// the elements of _c over _acc.
/// Note that <numeric> has a similar function `accumulate` which
/// until C++20 does *not* std::move the partial accumulated.
template < class C , class T , class Callable >
auto fold ( C const & _c , T _acc , Callable & & _binaryOp )
{
for ( auto const & e : _c )
_acc = _binaryOp ( std : : move ( _acc ) , e ) ;
return _acc ;
}
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template < class T , class U >
T convertContainer ( U const & _from )
{
return T { _from . cbegin ( ) , _from . cend ( ) } ;
}
template < class T , class U >
T convertContainer ( U & & _from )
{
return T {
std : : make_move_iterator ( _from . begin ( ) ) ,
std : : make_move_iterator ( _from . end ( ) )
} ;
}
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/// Gets a @a K -> @a V map and returns a map where values from the original map are keys and keys
/// from the original map are values.
///
/// @pre @a originalMap must have unique values.
template < typename K , typename V >
std : : map < V , K > invertMap ( std : : map < K , V > const & originalMap )
{
std : : map < V , K > inverseMap ;
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for ( auto const & originalPair : originalMap )
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{
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assert ( inverseMap . count ( originalPair . second ) = = 0 ) ;
inverseMap . insert ( { originalPair . second , originalPair . first } ) ;
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}
return inverseMap ;
}
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/// Returns a set of keys of a map.
template < typename K , typename V >
std : : set < K > keys ( std : : map < K , V > const & _map )
{
return applyMap ( _map , [ ] ( auto const & _elem ) { return _elem . first ; } , std : : set < K > { } ) ;
}
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/// @returns a pointer to the entry of @a _map at @a _key, if there is one, and nullptr otherwise.
template < typename MapType , typename KeyType >
decltype ( auto ) valueOrNullptr ( MapType & & _map , KeyType const & _key )
{
auto it = _map . find ( _key ) ;
return ( it = = _map . end ( ) ) ? nullptr : & it - > second ;
}
namespace detail
{
struct allow_copy { } ;
}
static constexpr auto allow_copy = detail : : allow_copy { } ;
/// @returns a reference to the entry of @a _map at @a _key, if there is one, and @a _defaultValue otherwise.
/// Makes sure no copy is involved, unless allow_copy is passed as fourth argument.
template <
typename MapType ,
typename KeyType ,
typename ValueType = std : : decay_t < decltype ( std : : declval < MapType > ( ) . find ( std : : declval < KeyType > ( ) ) - > second ) > const & ,
typename AllowCopyType = void *
>
decltype ( auto ) valueOrDefault ( MapType & & _map , KeyType const & _key , ValueType & & _defaultValue = { } , AllowCopyType = nullptr )
{
auto it = _map . find ( _key ) ;
static_assert (
std : : is_same_v < AllowCopyType , detail : : allow_copy > | |
std : : is_reference_v < decltype ( ( it = = _map . end ( ) ) ? _defaultValue : it - > second ) > ,
" valueOrDefault does not allow copies by default. Pass allow_copy as additional argument, if you want to allow copies. "
) ;
return ( it = = _map . end ( ) ) ? _defaultValue : it - > second ;
}
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namespace detail
{
template < typename Callable >
struct MapTuple
{
Callable callable ;
template < typename TupleType >
decltype ( auto ) operator ( ) ( TupleType & & _tuple ) {
using PlainTupleType = std : : remove_cv_t < std : : remove_reference_t < TupleType > > ;
return operator ( ) (
std : : forward < TupleType > ( _tuple ) ,
std : : make_index_sequence < std : : tuple_size_v < PlainTupleType > > { }
) ;
}
private :
template < typename TupleType , size_t . . . I >
decltype ( auto ) operator ( ) ( TupleType & & _tuple , std : : index_sequence < I . . . > )
{
return callable ( std : : get < I > ( std : : forward < TupleType > ( _tuple ) ) . . . ) ;
}
} ;
}
/// Wraps @a _callable, which takes multiple arguments, into a callable that takes a single tuple of arguments.
/// Since structured binding in lambdas is not allowed, i.e. [](auto&& [key, value]) { ... } is invalid, this allows
/// to instead use mapTuple([](auto&& key, auto&& value) { ... }).
template < typename Callable >
decltype ( auto ) mapTuple ( Callable & & _callable )
{
return detail : : MapTuple < Callable > { std : : forward < Callable > ( _callable ) } ;
}
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// String conversion functions, mainly to/from hex/nibble/byte representations.
enum class WhenError
{
DontThrow = 0 ,
Throw = 1 ,
} ;
enum class HexPrefix
{
DontAdd = 0 ,
Add = 1 ,
} ;
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enum class HexCase
{
Lower = 0 ,
Upper = 1 ,
Mixed = 2 ,
} ;
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/// Convert a single byte to a string of hex characters (of length two),
/// optionally with uppercase hex letters.
std : : string toHex ( uint8_t _data , HexCase _case = HexCase : : Lower ) ;
/// Convert a series of bytes to the corresponding string of hex duplets,
/// optionally with "0x" prefix and with uppercase hex letters.
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std : : string toHex ( bytes const & _data , HexPrefix _prefix = HexPrefix : : DontAdd , HexCase _case = HexCase : : Lower ) ;
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/// Converts a (printable) ASCII hex character into the corresponding integer value.
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/// @example fromHex('A') == 10 && fromHex('f') == 15 && fromHex('5') == 5
int fromHex ( char _i , WhenError _throw ) ;
/// Converts a (printable) ASCII hex string into the corresponding byte stream.
/// @example fromHex("41626261") == asBytes("Abba")
/// If _throw = ThrowType::DontThrow, it replaces bad hex characters with 0's, otherwise it will throw an exception.
bytes fromHex ( std : : string const & _s , WhenError _throw = WhenError : : DontThrow ) ;
/// Converts byte array to a string containing the same (binary) data. Unless
/// the byte array happens to contain ASCII data, this won't be printable.
inline std : : string asString ( bytes const & _b )
{
return std : : string ( ( char const * ) _b . data ( ) , ( char const * ) ( _b . data ( ) + _b . size ( ) ) ) ;
}
/// Converts byte array ref to a string containing the same (binary) data. Unless
/// the byte array happens to contain ASCII data, this won't be printable.
inline std : : string asString ( bytesConstRef _b )
{
return std : : string ( ( char const * ) _b . data ( ) , ( char const * ) ( _b . data ( ) + _b . size ( ) ) ) ;
}
/// Converts a string to a byte array containing the string's (byte) data.
inline bytes asBytes ( std : : string const & _b )
{
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return bytes ( ( uint8_t const * ) _b . data ( ) , ( uint8_t const * ) ( _b . data ( ) + _b . size ( ) ) ) ;
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}
// Big-endian to/from host endian conversion functions.
/// Converts a templated integer value to the big-endian byte-stream represented on a templated collection.
/// The size of the collection object will be unchanged. If it is too small, it will not represent the
/// value properly, if too big then the additional elements will be zeroed out.
/// @a Out will typically be either std::string or bytes.
/// @a T will typically by unsigned, u160, u256 or bigint.
template < class T , class Out >
inline void toBigEndian ( T _val , Out & o_out )
{
static_assert ( std : : is_same < bigint , T > : : value | | ! std : : numeric_limits < T > : : is_signed , " only unsigned types or bigint supported " ) ; //bigint does not carry sign bit on shift
for ( auto i = o_out . size ( ) ; i ! = 0 ; _val > > = 8 , i - - )
{
T v = _val & ( T ) 0xff ;
o_out [ i - 1 ] = ( typename Out : : value_type ) ( uint8_t ) v ;
}
}
/// Converts a big-endian byte-stream represented on a templated collection to a templated integer value.
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/// @a In will typically be either std::string or bytes.
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/// @a T will typically by unsigned, u160, u256 or bigint.
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template < class T , class In >
inline T fromBigEndian ( In const & _bytes )
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{
T ret = ( T ) 0 ;
for ( auto i : _bytes )
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ret = ( T ) ( ( ret < < 8 ) | ( uint8_t ) ( typename std : : make_unsigned < typename In : : value_type > : : type ) i ) ;
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return ret ;
}
inline bytes toBigEndian ( u256 _val ) { bytes ret ( 32 ) ; toBigEndian ( _val , ret ) ; return ret ; }
inline bytes toBigEndian ( u160 _val ) { bytes ret ( 20 ) ; toBigEndian ( _val , ret ) ; return ret ; }
/// Convenience function for toBigEndian.
/// @returns a byte array just big enough to represent @a _val.
template < class T >
inline bytes toCompactBigEndian ( T _val , unsigned _min = 0 )
{
static_assert ( std : : is_same < bigint , T > : : value | | ! std : : numeric_limits < T > : : is_signed , " only unsigned types or bigint supported " ) ; //bigint does not carry sign bit on shift
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unsigned i = 0 ;
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for ( T v = _val ; v ; + + i , v > > = 8 ) { }
bytes ret ( std : : max < unsigned > ( _min , i ) , 0 ) ;
toBigEndian ( _val , ret ) ;
return ret ;
}
/// Convenience function for conversion of a u256 to hex
inline std : : string toHex ( u256 val , HexPrefix prefix = HexPrefix : : DontAdd )
{
std : : string str = toHex ( toBigEndian ( val ) ) ;
return ( prefix = = HexPrefix : : Add ) ? " 0x " + str : str ;
}
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inline std : : string toCompactHexWithPrefix ( u256 const & _value )
{
return toHex ( toCompactBigEndian ( _value , 1 ) , HexPrefix : : Add ) ;
}
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/// Returns decimal representation for small numbers and hex for large numbers.
inline std : : string formatNumber ( bigint const & _value )
{
if ( _value < 0 )
return " - " + formatNumber ( - _value ) ;
if ( _value > 0x1000000 )
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return toHex ( toCompactBigEndian ( _value , 1 ) , HexPrefix : : Add ) ;
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else
return _value . str ( ) ;
}
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inline std : : string formatNumber ( u256 const & _value )
{
if ( _value > 0x1000000 )
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return toCompactHexWithPrefix ( _value ) ;
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else
return _value . str ( ) ;
}
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// Algorithms for string and string-like collections.
/// Determine bytes required to encode the given integer value. @returns 0 if @a _i is zero.
template < class T >
inline unsigned bytesRequired ( T _i )
{
static_assert ( std : : is_same < bigint , T > : : value | | ! std : : numeric_limits < T > : : is_signed , " only unsigned types or bigint supported " ) ; //bigint does not carry sign bit on shift
unsigned i = 0 ;
for ( ; _i ! = 0 ; + + i , _i > > = 8 ) { }
return i ;
}
template < class T , class V >
bool contains ( T const & _t , V const & _v )
{
return std : : end ( _t ) ! = std : : find ( std : : begin ( _t ) , std : : end ( _t ) , _v ) ;
}
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template < class T , class Predicate >
bool contains_if ( T const & _t , Predicate const & _p )
{
return std : : end ( _t ) ! = std : : find_if ( std : : begin ( _t ) , std : : end ( _t ) , _p ) ;
}
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/// Function that iterates over a vector, calling a function on each of its
/// elements. If that function returns a vector, the element is replaced by
/// the returned vector. During the iteration, the original vector is only valid
/// on the current element and after that. The actual replacement takes
/// place at the end, but already visited elements might be invalidated.
/// If nothing is replaced, no copy is performed.
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template < typename T , typename F >
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void iterateReplacing ( std : : vector < T > & _vector , F const & _f )
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{
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// Concept: _f must be Callable, must accept param T&, must return optional<vector<T>>
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bool useModified = false ;
std : : vector < T > modifiedVector ;
for ( size_t i = 0 ; i < _vector . size ( ) ; + + i )
{
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if ( std : : optional < std : : vector < T > > r = _f ( _vector [ i ] ) )
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{
if ( ! useModified )
{
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std : : move ( _vector . begin ( ) , _vector . begin ( ) + ptrdiff_t ( i ) , back_inserter ( modifiedVector ) ) ;
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useModified = true ;
}
modifiedVector + = std : : move ( * r ) ;
}
else if ( useModified )
modifiedVector . emplace_back ( std : : move ( _vector [ i ] ) ) ;
}
if ( useModified )
_vector = std : : move ( modifiedVector ) ;
}
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namespace detail
{
template < typename T , typename F , std : : size_t . . . I >
void iterateReplacingWindow ( std : : vector < T > & _vector , F const & _f , std : : index_sequence < I . . . > )
{
// Concept: _f must be Callable, must accept sizeof...(I) parameters of type T&, must return optional<vector<T>>
bool useModified = false ;
std : : vector < T > modifiedVector ;
size_t i = 0 ;
for ( ; i + sizeof . . . ( I ) < = _vector . size ( ) ; + + i )
{
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if ( std : : optional < std : : vector < T > > r = _f ( _vector [ i + I ] . . . ) )
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{
if ( ! useModified )
{
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std : : move ( _vector . begin ( ) , _vector . begin ( ) + ptrdiff_t ( i ) , back_inserter ( modifiedVector ) ) ;
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useModified = true ;
}
modifiedVector + = std : : move ( * r ) ;
i + = sizeof . . . ( I ) - 1 ;
}
else if ( useModified )
modifiedVector . emplace_back ( std : : move ( _vector [ i ] ) ) ;
}
if ( useModified )
{
for ( ; i < _vector . size ( ) ; + + i )
modifiedVector . emplace_back ( std : : move ( _vector [ i ] ) ) ;
_vector = std : : move ( modifiedVector ) ;
}
}
}
/// Function that iterates over the vector @param _vector,
/// calling the function @param _f on sequences of @tparam N of its
/// elements. If @param _f returns a vector, these elements are replaced by
/// the returned vector and the iteration continues with the next @tparam N elements.
/// If the function does not return a vector, the iteration continues with an overlapping
/// sequence of @tparam N elements that starts with the second element of the previous
/// iteration.
/// During the iteration, the original vector is only valid
/// on the current element and after that. The actual replacement takes
/// place at the end, but already visited elements might be invalidated.
/// If nothing is replaced, no copy is performed.
template < std : : size_t N , typename T , typename F >
void iterateReplacingWindow ( std : : vector < T > & _vector , F const & _f )
{
// Concept: _f must be Callable, must accept N parameters of type T&, must return optional<vector<T>>
detail : : iterateReplacingWindow ( _vector , _f , std : : make_index_sequence < N > { } ) ;
}
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/// @returns true iff @a _str passess the hex address checksum test.
/// @param _strict if false, hex strings with only uppercase or only lowercase letters
/// are considered valid.
bool passesAddressChecksum ( std : : string const & _str , bool _strict ) ;
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/// @returns the checksummed version of an address
/// @param hex strings that look like an address
std : : string getChecksummedAddress ( std : : string const & _addr ) ;
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bool isValidHex ( std : : string const & _string ) ;
bool isValidDecimal ( std : : string const & _string ) ;
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/// @returns a quoted string if all characters are printable ASCII chars,
/// or its hex representation otherwise.
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/// _value cannot be longer than 32 bytes.
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std : : string formatAsStringOrNumber ( std : : string const & _value ) ;
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/// @returns a string with the usual backslash-escapes for non-ASCII
/// characters and surrounded by '"'-characters.
std : : string escapeAndQuoteString ( std : : string const & _input ) ;
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template < typename Container , typename Compare >
bool containerEqual ( Container const & _lhs , Container const & _rhs , Compare & & _compare )
{
return std : : equal ( std : : begin ( _lhs ) , std : : end ( _lhs ) , std : : begin ( _rhs ) , std : : end ( _rhs ) , std : : forward < Compare > ( _compare ) ) ;
}
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inline std : : string findAnyOf ( std : : string const & _haystack , std : : vector < std : : string > const & _needles )
{
for ( std : : string const & needle : _needles )
if ( _haystack . find ( needle ) ! = std : : string : : npos )
return needle ;
return " " ;
}
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namespace detail
{
template < typename T >
void variadicEmplaceBack ( std : : vector < T > & ) { }
template < typename T , typename A , typename . . . Args >
void variadicEmplaceBack ( std : : vector < T > & _vector , A & & _a , Args & & . . . _args )
{
_vector . emplace_back ( std : : forward < A > ( _a ) ) ;
variadicEmplaceBack ( _vector , std : : forward < Args > ( _args ) . . . ) ;
}
}
template < typename T , typename . . . Args >
std : : vector < T > make_vector ( Args & & . . . _args )
{
std : : vector < T > result ;
result . reserve ( sizeof . . . ( _args ) ) ;
detail : : variadicEmplaceBack ( result , std : : forward < Args > ( _args ) . . . ) ;
return result ;
}
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}