vmap/libs/string/string.h
2020-11-17 12:16:16 +01:00

548 lines
17 KiB
C++

/*
Copyright (C) 2001-2006, William Joseph.
All Rights Reserved.
This file is part of GtkRadiant.
GtkRadiant is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
GtkRadiant is distributed in the hope that it will be useful,
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
along with GtkRadiant; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#if !defined( INCLUDED_STRING_STRING_H )
#define INCLUDED_STRING_STRING_H
#include "globaldefs.h"
/// \file
/// C-style null-terminated-character-array string library.
#include <cstring>
#include <cctype>
#include <algorithm>
#include "memory/allocator.h"
#include "generic/arrayrange.h"
/// \brief Returns true if \p string length is zero.
/// O(1)
inline bool string_empty( const char* string ){
return *string == '\0';
}
/// \brief Returns true if \p string length is not zero.
/// O(1)
inline bool string_not_empty( const char* string ){
return !string_empty( string );
}
/// \brief Returns <0 if \p string is lexicographically less than \p other.
/// Returns >0 if \p string is lexicographically greater than \p other.
/// Returns 0 if \p string is lexicographically equal to \p other.
/// O(n)
inline int string_compare( const char* string, const char* other ){
return std::strcmp( string, other );
}
/// \brief Returns true if \p string is lexicographically equal to \p other.
/// O(n)
inline bool string_equal( const char* string, const char* other ){
return string_compare( string, other ) == 0;
}
/// \brief Returns true if [\p string, \p string + \p n) is lexicographically equal to [\p other, \p other + \p n).
/// O(n)
inline bool string_equal_n( const char* string, const char* other, std::size_t n ){
return std::strncmp( string, other, n ) == 0;
}
/// \brief Returns true if \p string is lexicographically less than \p other.
/// O(n)
inline bool string_less( const char* string, const char* other ){
return string_compare( string, other ) < 0;
}
/// \brief Returns true if \p string is lexicographically greater than \p other.
/// O(n)
inline bool string_greater( const char* string, const char* other ){
return string_compare( string, other ) > 0;
}
/// \brief Returns <0 if \p string is lexicographically less than \p other after converting both to lower-case.
/// Returns >0 if \p string is lexicographically greater than \p other after converting both to lower-case.
/// Returns 0 if \p string is lexicographically equal to \p other after converting both to lower-case.
/// O(n)
inline int string_compare_nocase( const char* string, const char* other ){
#if GDEF_OS_WINDOWS
return _stricmp( string, other );
#else
return strcasecmp( string, other );
#endif
}
/// \brief Returns <0 if [\p string, \p string + \p n) is lexicographically less than [\p other, \p other + \p n).
/// Returns >0 if [\p string, \p string + \p n) is lexicographically greater than [\p other, \p other + \p n).
/// Returns 0 if [\p string, \p string + \p n) is lexicographically equal to [\p other, \p other + \p n).
/// Treats all ascii characters as lower-case during comparisons.
/// O(n)
inline int string_compare_nocase_n( const char* string, const char* other, std::size_t n ){
#if GDEF_OS_WINDOWS
return _strnicmp( string, other, n );
#else
return strncasecmp( string, other, n );
#endif
}
/// \brief Returns true if \p string is lexicographically equal to \p other.
/// Treats all ascii characters as lower-case during comparisons.
/// O(n)
inline bool string_equal_nocase( const char* string, const char* other ){
return string_compare_nocase( string, other ) == 0;
}
/// \brief Returns true if [\p string, \p string + \p n) is lexicographically equal to [\p other, \p other + \p n).
/// Treats all ascii characters as lower-case during comparisons.
/// O(n)
inline bool string_equal_nocase_n( const char* string, const char* other, std::size_t n ){
return string_compare_nocase_n( string, other, n ) == 0;
}
/// \brief Returns true if \p string is lexicographically less than \p other.
/// Treats all ascii characters as lower-case during comparisons.
/// O(n)
inline bool string_less_nocase( const char* string, const char* other ){
return string_compare_nocase( string, other ) < 0;
}
/// \brief Returns true if \p string is lexicographically greater than \p other.
/// Treats all ascii characters as lower-case during comparisons.
/// O(n)
inline bool string_greater_nocase( const char* string, const char* other ){
return string_compare_nocase( string, other ) > 0;
}
/// \brief Returns the number of non-null characters in \p string.
/// O(n)
inline std::size_t string_length( const char* string ){
return std::strlen( string );
}
/// \brief Returns true if the beginning of \p string is equal to \p prefix.
/// O(n)
inline bool string_equal_prefix( const char* string, const char* prefix ){
return string_equal_n( string, prefix, string_length( prefix ) );
}
/// \brief Returns true if the ending of \p string is equal to \p suffix.
/// O(n)
inline bool string_equal_suffix( const char* string, const char* suffix){
const char *s = string + string_length( string ) - string_length( suffix );
return string_equal_n( s , suffix, string_length( suffix ) );
}
/// \brief Copies \p other into \p string and returns \p string.
/// Assumes that the space allocated for \p string is at least string_length(other) + 1.
/// O(n)
inline char* string_copy( char* string, const char* other ){
return std::strcpy( string, other );
}
/// \brief Allocates a string buffer large enough to hold \p length characters, using \p allocator.
/// The returned buffer must be released with \c string_release using a matching \p allocator.
template<typename Allocator>
inline char* string_new( std::size_t length, Allocator& allocator ){
return allocator.allocate( length + 1 );
}
/// \brief Deallocates the \p buffer large enough to hold \p length characters, using \p allocator.
template<typename Allocator>
inline void string_release( char* buffer, std::size_t length, Allocator& allocator ){
allocator.deallocate( buffer, length + 1 );
}
/// \brief Returns a newly-allocated string which is a clone of \p other, using \p allocator.
/// The returned buffer must be released with \c string_release using a matching \p allocator.
template<typename Allocator>
inline char* string_clone( const char* other, Allocator& allocator ){
char* copied = string_new( string_length( other ), allocator );
std::strcpy( copied, other );
return copied;
}
/// \brief Returns a newly-allocated string which is a clone of [\p first, \p last), using \p allocator.
/// The returned buffer must be released with \c string_release using a matching \p allocator.
template<typename Allocator>
inline char* string_clone_range( StringRange range, Allocator& allocator ){
std::size_t length = range.last - range.first;
char* copied = strncpy( string_new( length, allocator ), range.first, length );
copied[length] = '\0';
return copied;
}
/// \brief Allocates a string buffer large enough to hold \p length characters.
/// The returned buffer must be released with \c string_release.
inline char* string_new( std::size_t length ){
DefaultAllocator<char> allocator;
return string_new( length, allocator );
}
/// \brief Allocates a new buffer large enough to hold two concatenated strings and fills it with strings.
inline char* string_new_concat( const char* a, const char* b ){
char* str = string_new( string_length( a ) + string_length( b ) );
strcpy( str, a );
strcat( str, b );
return str;
}
/// \brief Deallocates the \p buffer large enough to hold \p length characters.
inline void string_release( char* string, std::size_t length ){
DefaultAllocator<char> allocator;
string_release( string, length, allocator );
}
/// \brief Returns a newly-allocated string which is a clone of \p other.
/// The returned buffer must be released with \c string_release.
inline char* string_clone( const char* other ){
DefaultAllocator<char> allocator;
return string_clone( other, allocator );
}
/// \brief Returns a newly-allocated string which is a clone of [\p first, \p last).
/// The returned buffer must be released with \c string_release.
inline char* string_clone_range( StringRange range ){
DefaultAllocator<char> allocator;
return string_clone_range( range, allocator );
}
typedef char* char_pointer;
/// \brief Swaps the values of \p string and \p other.
inline void string_swap( char_pointer& string, char_pointer& other ){
std::swap( string, other );
}
typedef const char* char_const_pointer;
/// \brief Swaps the values of \p string and \p other.
inline void string_swap( char_const_pointer& string, char_const_pointer& other ){
std::swap( string, other );
}
/// \brief Converts each character of \p string to lower-case and returns \p string.
/// O(n)
inline char* string_to_lowercase( char* string ){
for ( char* p = string; *p != '\0'; ++p )
{
*p = (char)std::tolower( *p );
}
return string;
}
/// \brief Converts each character of \p string to upper-case and returns \p string.
/// O(n)
inline char* string_to_uppercase( char* string ){
for ( char* p = string; *p != '\0'; ++p )
{
*p = (char)std::toupper( *p );
}
return string;
}
/// \brief A re-entrant string tokeniser similar to strchr.
class StringTokeniser
{
bool istoken( char c ) const {
if ( strchr( m_delimiters, c ) != 0 ) {
return false;
}
return true;
}
const char* advance(){
const char* token = m_pos;
bool intoken = true;
while ( !string_empty( m_pos ) )
{
if ( !istoken( *m_pos ) ) {
*m_pos = '\0';
intoken = false;
}
else if ( !intoken ) {
return token;
}
++m_pos;
}
return token;
}
std::size_t m_length;
char* m_string;
char* m_pos;
const char* m_delimiters;
public:
StringTokeniser( const char* string, const char* delimiters = " \n\r\t\v" ) :
m_length( string_length( string ) ),
m_string( string_copy( string_new( m_length ), string ) ),
m_pos( m_string ),
m_delimiters( delimiters ){
while ( !string_empty( m_pos ) && !istoken( *m_pos ) )
{
++m_pos;
}
}
~StringTokeniser(){
string_release( m_string, m_length );
}
/// \brief Returns the next token or "" if there are no more tokens available.
const char* getToken(){
return advance();
}
};
/// \brief A non-mutable c-style string.
///
/// \param Buffer The string storage implementation. Must be DefaultConstructible, CopyConstructible and Assignable. Must implement:
/// \li Buffer(const char* string) - constructor which copies a c-style \p string.
/// \li Buffer(const char* first, const char*) - constructor which copies a c-style string range [\p first, \p last).
/// \li void swap(Buffer& other) - swaps contents with \p other.
/// \li const char* c_str() - returns the stored non-mutable c-style string.
template<typename Buffer>
class String : public Buffer
{
public:
String()
: Buffer(){
}
String( const char* string )
: Buffer( string ){
}
String( StringRange range )
: Buffer( range ){
}
String& operator=( const String& other ){
String temp( other );
temp.swap( *this );
return *this;
}
String& operator=( const char* string ){
String temp( string );
temp.swap( *this );
return *this;
}
String& operator=( StringRange range ){
String temp( range );
temp.swap( *this );
return *this;
}
void swap( String& other ){
Buffer::swap( other );
}
bool empty() const {
return string_empty( Buffer::c_str() );
}
};
template<typename Buffer>
inline bool operator<( const String<Buffer>& self, const String<Buffer>& other ){
return string_less( self.c_str(), other.c_str() );
}
template<typename Buffer>
inline bool operator>( const String<Buffer>& self, const String<Buffer>& other ){
return string_greater( self.c_str(), other.c_str() );
}
template<typename Buffer>
inline bool operator==( const String<Buffer>& self, const String<Buffer>& other ){
return string_equal( self.c_str(), other.c_str() );
}
template<typename Buffer>
inline bool operator!=( const String<Buffer>& self, const String<Buffer>& other ){
return !string_equal( self.c_str(), other.c_str() );
}
template<typename Buffer>
inline bool operator==( const String<Buffer>& self, const char* other ){
return string_equal( self.c_str(), other );
}
template<typename Buffer>
inline bool operator!=( const String<Buffer>& self, const char* other ){
return !string_equal( self.c_str(), other );
}
namespace std
{
/// \brief Swaps the values of \p self and \p other.
/// Overloads std::swap.
template<typename Buffer>
inline void swap( String<Buffer>& self, String<Buffer>& other ){
self.swap( other );
}
}
/// \brief A non-mutable string buffer which manages memory allocation.
template<typename Allocator>
class CopiedBuffer : private Allocator
{
char* m_string;
char* copy_range( StringRange range ){
return string_clone_range( range, static_cast<Allocator&>( *this ) );
}
char* copy( const char* other ){
return string_clone( other, static_cast<Allocator&>( *this ) );
}
void destroy( char* string ){
string_release( string, string_length( string ), static_cast<Allocator&>( *this ) );
}
protected:
~CopiedBuffer(){
destroy( m_string );
}
public:
CopiedBuffer()
: m_string( copy( "" ) ){
}
explicit CopiedBuffer( const Allocator& allocator )
: Allocator( allocator ), m_string( copy( "" ) ){
}
CopiedBuffer( const CopiedBuffer& other )
: Allocator( other ), m_string( copy( other.m_string ) ){
}
CopiedBuffer( const char* string, const Allocator& allocator = Allocator() )
: Allocator( allocator ), m_string( copy( string ) ){
}
CopiedBuffer( StringRange range, const Allocator& allocator = Allocator() )
: Allocator( allocator ), m_string( copy_range( range ) ){
}
const char* c_str() const {
return m_string;
}
void swap( CopiedBuffer& other ){
string_swap( m_string, other.m_string );
}
};
/// \brief A non-mutable string which uses copy-by-value for assignment.
typedef String< CopiedBuffer< DefaultAllocator<char> > > CopiedString;
/// \brief A non-mutable string buffer which uses reference-counting to avoid unnecessary allocations.
template<typename Allocator>
class SmartBuffer : private Allocator
{
char* m_buffer;
char* copy_range( StringRange range ){
char* buffer = Allocator::allocate( sizeof( std::size_t ) + ( range.last - range.first ) + 1 );
strncpy( buffer + sizeof( std::size_t ), range.first, range.last - range.first );
buffer[sizeof( std::size_t ) + ( range.last - range.first )] = '\0';
*reinterpret_cast<std::size_t*>( buffer ) = 0;
return buffer;
}
char* copy( const char* string ){
char* buffer = Allocator::allocate( sizeof( std::size_t ) + string_length( string ) + 1 );
strcpy( buffer + sizeof( std::size_t ), string );
*reinterpret_cast<std::size_t*>( buffer ) = 0;
return buffer;
}
void destroy( char* buffer ){
Allocator::deallocate( buffer, sizeof( std::size_t ) + string_length( c_str() ) + 1 );
}
void incref( char* buffer ){
++( *reinterpret_cast<std::size_t*>( buffer ) );
}
void decref( char* buffer ){
if ( --( *reinterpret_cast<std::size_t*>( buffer ) ) == 0 ) {
destroy( buffer );
}
}
protected:
~SmartBuffer(){
decref( m_buffer );
}
public:
SmartBuffer()
: m_buffer( copy( "" ) ){
incref( m_buffer );
}
explicit SmartBuffer( const Allocator& allocator )
: Allocator( allocator ), m_buffer( copy( "" ) ){
incref( m_buffer );
}
SmartBuffer( const SmartBuffer& other )
: Allocator( other ), m_buffer( other.m_buffer ){
incref( m_buffer );
}
SmartBuffer( const char* string, const Allocator& allocator = Allocator() )
: Allocator( allocator ), m_buffer( copy( string ) ){
incref( m_buffer );
}
SmartBuffer( StringRange range, const Allocator& allocator = Allocator() )
: Allocator( allocator ), m_buffer( copy_range( range ) ){
incref( m_buffer );
}
const char* c_str() const {
return m_buffer + sizeof( std::size_t );
}
void swap( SmartBuffer& other ){
string_swap( m_buffer, other.m_buffer );
}
};
/// \brief A non-mutable string which uses copy-by-reference for assignment of SmartString.
typedef String< SmartBuffer< DefaultAllocator<char> > > SmartString;
class StringEqualNoCase
{
public:
bool operator()( const CopiedString& key, const CopiedString& other ) const {
return string_equal_nocase( key.c_str(), other.c_str() );
}
};
struct StringLessNoCase
{
bool operator()( const CopiedString& x, const CopiedString& y ) const {
return string_less_nocase( x.c_str(), y.c_str() );
}
};
struct RawStringEqual
{
bool operator()( const char* x, const char* y ) const {
return string_equal( x, y );
}
};
struct RawStringLess
{
bool operator()( const char* x, const char* y ) const {
return string_less( x, y );
}
};
struct RawStringLessNoCase
{
bool operator()( const char* x, const char* y ) const {
return string_less_nocase( x, y );
}
};
#endif