#ifdef GEN_INTELLISENSE_DIRECTIVES # pragma once # include "hashing.hpp" #endif #pragma region Strings // Constant string with length. struct StrC { sw Len; char const* Ptr; operator char const* () const { return Ptr; } char const& operator[]( sw index ) const { return Ptr[index]; } }; #define cast_to_strc( str ) * rcast( StrC*, (str) - sizeof(sw) ) #define txt( text ) StrC { sizeof( text ) - 1, ( text ) } StrC to_str( char const* str ) { return { str_len( str ), str }; } // Dynamic String // This is directly based off the ZPL string api. // They used a header pattern // I kept it for simplicty of porting but its not necessary to keep it that way. struct String { struct Header { AllocatorInfo Allocator; sw Capacity; sw Length; }; static uw grow_formula( uw value ) { // Using a very aggressive growth formula to reduce time mem_copying with recursive calls to append in this library. return 4 * value + 8; } static String make( AllocatorInfo allocator, char const* str ) { sw length = str ? str_len( str ) : 0; return make_length( allocator, str, length ); } static String make( AllocatorInfo allocator, StrC str ) { return make_length( allocator, str.Ptr, str.Len ); } static String make_reserve( AllocatorInfo allocator, sw capacity ); static String make_length( AllocatorInfo allocator, char const* str, sw length ); static String fmt( AllocatorInfo allocator, char* buf, sw buf_size, char const* fmt, ... ); static String fmt_buf( AllocatorInfo allocator, char const* fmt, ... ); static String join( AllocatorInfo allocator, char const** parts, sw num_parts, char const* glue ) { String result = make( allocator, "" ); for ( sw idx = 0; idx < num_parts; ++idx ) { result.append( parts[ idx ] ); if ( idx < num_parts - 1 ) result.append( glue ); } return result; } static bool are_equal( String lhs, String rhs ) { if ( lhs.length() != rhs.length() ) return false; for ( sw idx = 0; idx < lhs.length(); ++idx ) if ( lhs[ idx ] != rhs[ idx ] ) return false; return true; } static bool are_equal( String lhs, StrC rhs ) { if ( lhs.length() != (rhs.Len) ) return false; for ( sw idx = 0; idx < lhs.length(); ++idx ) if ( lhs[idx] != rhs[idx] ) return false; return true; } bool make_space_for( char const* str, sw add_len ); bool append( char c ) { return append( & c, 1 ); } bool append( char const* str ) { return append( str, str_len( str ) ); } bool append( char const* str, sw length ) { if ( sptr(str) > 0 ) { sw curr_len = this->length(); if ( ! make_space_for( str, length ) ) return false; Header& header = get_header(); mem_copy( Data + curr_len, str, length ); Data[ curr_len + length ] = '\0'; header.Length = curr_len + length; } return str != nullptr; } bool append( StrC str) { return append( str.Ptr, str.Len ); } bool append( const String other ) { return append( other.Data, other.length() ); } bool append_fmt( char const* fmt, ... ); sw avail_space() const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); return header.Capacity - header.Length; } char& back() { return Data[ length() - 1 ]; } sw capacity() const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); return header.Capacity; } void clear() { get_header().Length = 0; } String duplicate( AllocatorInfo allocator ) const { return make_length( allocator, Data, length() ); } void free() { if ( ! Data ) return; Header& header = get_header(); gen::free( header.Allocator, & header ); } Header& get_header() { return *(Header*)(Data - sizeof(Header)); } sw length() const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); return header.Length; } b32 starts_with( StrC substring ) const { if (substring.Len > length()) return false; b32 result = str_compare(Data, substring.Ptr, substring.Len ) == 0; return result; } b32 starts_with( String substring ) const { if (substring.length() > length()) return false; b32 result = str_compare(Data, substring, substring.length() - 1 ) == 0; return result; } void skip_line() { #define current (*scanner) char* scanner = Data; while ( current != '\r' && current != '\n' ) { ++ scanner; } s32 new_length = scanner - Data; if ( current == '\r' ) { new_length += 1; } mem_move( Data, scanner, new_length ); Header* header = & get_header(); header->Length = new_length; #undef current } void strip_space() { char* write_pos = Data; char* read_pos = Data; while ( * read_pos) { if ( ! char_is_space( *read_pos )) { *write_pos = *read_pos; write_pos++; } read_pos++; } write_pos[0] = '\0'; // Null-terminate the modified string // Update the length if needed get_header().Length = write_pos - Data; } void trim( char const* cut_set ) { sw len = 0; char* start_pos = Data; char* end_pos = Data + length() - 1; while ( start_pos <= end_pos && char_first_occurence( cut_set, *start_pos ) ) start_pos++; while ( end_pos > start_pos && char_first_occurence( cut_set, *end_pos ) ) end_pos--; len = scast( sw, ( start_pos > end_pos ) ? 0 : ( ( end_pos - start_pos ) + 1 ) ); if ( Data != start_pos ) mem_move( Data, start_pos, len ); Data[ len ] = '\0'; get_header().Length = len; } void trim_space() { return trim( " \t\r\n\v\f" ); } // Debug function that provides a copy of the string with whitespace characters visualized. String visualize_whitespace() const { Header* header = (Header*)(Data - sizeof(Header)); String result = make_reserve(header->Allocator, length() * 2); // Assume worst case for space requirements. for ( char c : *this ) { switch ( c ) { case ' ': result.append( txt("·") ); break; case '\t': result.append( txt("→") ); break; case '\n': result.append( txt("↵") ); break; case '\r': result.append( txt("⏎") ); break; case '\v': result.append( txt("⇕") ); break; case '\f': result.append( txt("⌂") ); break; default: result.append(c); break; } } return result; } // For-range support char* begin() const { return Data; } char* end() const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); return Data + header.Length; } operator bool() { return Data != nullptr; } operator char* () { return Data; } operator char const* () const { return Data; } operator StrC() const { return { length(), Data }; } // Used with cached strings // Essentially makes the string a string view. String const& operator = ( String const& other ) const { if ( this == & other ) return *this; String& this_ = ccast( String, *this ); this_.Data = other.Data; return this_; } char& operator [] ( sw index ) { return Data[ index ]; } char const& operator [] ( sw index ) const { return Data[ index ]; } char* Data; }; struct String_POD { char* Data; }; static_assert( sizeof( String_POD ) == sizeof( String ), "String is not a POD" ); // Implements basic string interning. Data structure is based off the ZPL Hashtable. using StringTable = HashTable; // Represents strings cached with the string table. // Should never be modified, if changed string is desired, cache_string( str ) another. using StringCached = String const; #pragma endregion Strings