#ifndef SQL_STRING_INCLUDED #define SQL_STRING_INCLUDED /* Copyright (c) 2000, 2013, Oracle and/or its affiliates. Copyright (c) 2008, 2020, MariaDB Corporation. This program 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; version 2 of the License. This program 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 this program; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1335 USA */ /* This file is originally from the mysql distribution. Coded by monty */ #ifdef USE_PRAGMA_INTERFACE #pragma interface /* gcc class implementation */ #endif #include "m_ctype.h" /* my_charset_bin */ #include /* alloc_root, my_free, my_realloc */ #include "m_string.h" /* TRASH */ #include "sql_list.h" class String; typedef struct st_io_cache IO_CACHE; typedef struct st_mem_root MEM_ROOT; #include "pack.h" int sortcmp(const String *a,const String *b, CHARSET_INFO *cs); String *copy_if_not_alloced(String *a,String *b,uint32 arg_length); inline uint32 copy_and_convert(char *to, size_t to_length, CHARSET_INFO *to_cs, const char *from, size_t from_length, CHARSET_INFO *from_cs, uint *errors) { return my_convert(to, (uint)to_length, to_cs, from, (uint)from_length, from_cs, errors); } class String_copy_status: protected MY_STRCOPY_STATUS { public: const char *source_end_pos() const { return m_source_end_pos; } const char *well_formed_error_pos() const { return m_well_formed_error_pos; } }; class Well_formed_prefix_status: public String_copy_status { public: Well_formed_prefix_status(CHARSET_INFO *cs, const char *str, const char *end, size_t nchars) { cs->cset->well_formed_char_length(cs, str, end, nchars, this); } }; class Well_formed_prefix: public Well_formed_prefix_status { const char *m_str; // The beginning of the string public: Well_formed_prefix(CHARSET_INFO *cs, const char *str, const char *end, size_t nchars) :Well_formed_prefix_status(cs, str, end, nchars), m_str(str) { } Well_formed_prefix(CHARSET_INFO *cs, const char *str, size_t length, size_t nchars) :Well_formed_prefix_status(cs, str, str + length, nchars), m_str(str) { } Well_formed_prefix(CHARSET_INFO *cs, const char *str, size_t length) :Well_formed_prefix_status(cs, str, str + length, length), m_str(str) { } Well_formed_prefix(CHARSET_INFO *cs, LEX_CSTRING str, size_t nchars) :Well_formed_prefix_status(cs, str.str, str.str + str.length, nchars), m_str(str.str) { } size_t length() const { return m_source_end_pos - m_str; } }; class String_copier: public String_copy_status, protected MY_STRCONV_STATUS { public: const char *cannot_convert_error_pos() const { return m_cannot_convert_error_pos; } const char *most_important_error_pos() const { return well_formed_error_pos() ? well_formed_error_pos() : cannot_convert_error_pos(); } /* Convert a string between character sets. "dstcs" and "srccs" cannot be &my_charset_bin. */ size_t convert_fix(CHARSET_INFO *dstcs, char *dst, size_t dst_length, CHARSET_INFO *srccs, const char *src, size_t src_length, size_t nchars) { return my_convert_fix(dstcs, dst, dst_length, srccs, src, src_length, nchars, this, this); } /* Copy a string. Fix bad bytes/characters to '?'. */ uint well_formed_copy(CHARSET_INFO *to_cs, char *to, size_t to_length, CHARSET_INFO *from_cs, const char *from, size_t from_length, size_t nchars); // Same as above, but without the "nchars" limit. uint well_formed_copy(CHARSET_INFO *to_cs, char *to, size_t to_length, CHARSET_INFO *from_cs, const char *from, size_t from_length) { return well_formed_copy(to_cs, to, to_length, from_cs, from, from_length, from_length /* No limit on "nchars"*/); } }; size_t my_copy_with_hex_escaping(CHARSET_INFO *cs, char *dst, size_t dstlen, const char *src, size_t srclen); uint convert_to_printable(char *to, size_t to_len, const char *from, size_t from_len, CHARSET_INFO *from_cs, size_t nbytes= 0); size_t convert_to_printable_required_length(uint len); class Charset { CHARSET_INFO *m_charset; public: Charset() :m_charset(&my_charset_bin) { } Charset(CHARSET_INFO *cs) :m_charset(cs) { } CHARSET_INFO *charset() const { return m_charset; } uint mbminlen() const { return m_charset->mbminlen; } uint mbmaxlen() const { return m_charset->mbmaxlen; } size_t numchars(const char *str, const char *end) const { return m_charset->cset->numchars(m_charset, str, end); } size_t lengthsp(const char *str, size_t length) const { return m_charset->cset->lengthsp(m_charset, str, length); } size_t charpos(const char *str, const char *end, size_t pos) const { return m_charset->cset->charpos(m_charset, str, end, pos); } void set_charset(CHARSET_INFO *charset_arg) { m_charset= charset_arg; } void set_charset(const Charset &other) { m_charset= other.m_charset; } void swap(Charset &other) { swap_variables(CHARSET_INFO*, m_charset, other.m_charset); } bool same_encoding(const Charset &other) const { return !strcmp(m_charset->csname, other.m_charset->csname); } /* Collation name without the character set name. For example, in case of "latin1_swedish_ci", this method returns "_swedish_ci". */ LEX_CSTRING collation_specific_name() const; bool encoding_allows_reinterpret_as(CHARSET_INFO *cs) const; bool eq_collation_specific_names(CHARSET_INFO *cs) const; }; /* A storage for String. Should be eventually derived from LEX_STRING. */ class Static_binary_string : public Sql_alloc { protected: char *Ptr; uint32 str_length; public: Static_binary_string() :Ptr(NULL), str_length(0) { } Static_binary_string(char *str, size_t length_arg) :Ptr(str), str_length((uint32) length_arg) { DBUG_ASSERT(length_arg < UINT_MAX32); } inline uint32 length() const { return str_length;} inline char& operator [] (size_t i) const { return Ptr[i]; } inline void length(size_t len) { str_length=(uint32)len ; } inline bool is_empty() const { return (str_length == 0); } inline const char *ptr() const { return Ptr; } inline const char *end() const { return Ptr + str_length; } LEX_STRING lex_string() const { LEX_STRING str = { (char*) ptr(), length() }; return str; } LEX_CSTRING lex_cstring() const { LEX_CSTRING skr = { ptr(), length() }; return skr; } bool has_8bit_bytes() const { for (const char *c= ptr(), *c_end= end(); c < c_end; c++) { if (!my_isascii(*c)) return true; } return false; } bool bin_eq(const Static_binary_string *other) const { return length() == other->length() && !memcmp(ptr(), other->ptr(), length()); } void set(char *str, size_t len) { Ptr= str; str_length= (uint32) len; } void swap(Static_binary_string &s) { swap_variables(char *, Ptr, s.Ptr); swap_variables(uint32, str_length, s.str_length); } /* PMG 2004.11.12 This is a method that works the same as perl's "chop". It simply drops the last character of a string. This is useful in the case of the federated storage handler where I'm building a unknown number, list of values and fields to be used in a sql insert statement to be run on the remote server, and have a comma after each. When the list is complete, I "chop" off the trailing comma ex. String stringobj; stringobj.append("VALUES ('foo', 'fi', 'fo',"); stringobj.chop(); stringobj.append(")"); In this case, the value of string was: VALUES ('foo', 'fi', 'fo', VALUES ('foo', 'fi', 'fo' VALUES ('foo', 'fi', 'fo') */ inline void chop() { str_length--; Ptr[str_length]= '\0'; DBUG_ASSERT(strlen(Ptr) == str_length); } // Returns offset to substring or -1 int strstr(const Static_binary_string &search, uint32 offset=0); // Returns offset to substring or -1 int strrstr(const Static_binary_string &search, uint32 offset=0); /* The following append operations do NOT check alloced memory q_*** methods writes values of parameters itself qs_*** methods writes string representation of value */ void q_append(const char c) { Ptr[str_length++] = c; } void q_append2b(const uint32 n) { int2store(Ptr + str_length, n); str_length += 2; } void q_append(const uint32 n) { int4store(Ptr + str_length, n); str_length += 4; } void q_append(double d) { float8store(Ptr + str_length, d); str_length += 8; } void q_append(double *d) { float8store(Ptr + str_length, *d); str_length += 8; } void q_append(const char *data, size_t data_len) { if (data_len) memcpy(Ptr + str_length, data, data_len); DBUG_ASSERT(str_length <= UINT_MAX32 - data_len); str_length += (uint)data_len; } void q_append(const LEX_CSTRING *ls) { DBUG_ASSERT(ls->length < UINT_MAX32 && ((ls->length == 0 && !ls->str) || ls->length == strlen(ls->str))); q_append(ls->str, (uint32) ls->length); } void write_at_position(int position, uint32 value) { int4store(Ptr + position,value); } void qs_append(const char *str) { qs_append(str, (uint32)strlen(str)); } void qs_append(const LEX_CSTRING *ls) { DBUG_ASSERT(ls->length < UINT_MAX32 && ((ls->length == 0 && !ls->str) || ls->length == strlen(ls->str))); qs_append(ls->str, (uint32)ls->length); } void qs_append(const char *str, size_t len); void qs_append_hex(const char *str, uint32 len); void qs_append(double d); void qs_append(double *d); inline void qs_append(const char c) { Ptr[str_length]= c; str_length++; } void qs_append(int i); void qs_append(uint i) { qs_append((ulonglong)i); } void qs_append(ulong i) { qs_append((ulonglong)i); } void qs_append(ulonglong i); void qs_append(longlong i, int radix) { char *buff= Ptr + str_length; char *end= ll2str(i, buff, radix, 0); str_length+= uint32(end-buff); } }; class Binary_string: public Static_binary_string { uint32 Alloced_length, extra_alloc; bool alloced, thread_specific; void init_private_data() { Alloced_length= extra_alloc= 0; alloced= thread_specific= false; } public: Binary_string() { init_private_data(); } explicit Binary_string(size_t length_arg) { init_private_data(); (void) real_alloc(length_arg); } explicit Binary_string(const char *str) :Binary_string(str, strlen(str)) { } /* NOTE: If one intend to use the c_ptr() method, the following two contructors need the size of memory for STR to be at least LEN+1 (to make room for zero termination). */ Binary_string(const char *str, size_t len) :Static_binary_string((char *) str, len) { init_private_data(); } Binary_string(char *str, size_t len) :Static_binary_string(str, len) { Alloced_length= (uint32) len; extra_alloc= 0; alloced= thread_specific= 0; } explicit Binary_string(const Binary_string &str) :Static_binary_string(str) { Alloced_length= str.Alloced_length; extra_alloc= 0; alloced= thread_specific= 0; } ~Binary_string() { free(); } /* Mark variable thread specific it it's not allocated already */ inline void set_thread_specific() { if (!alloced) thread_specific= 1; } bool is_alloced() const { return alloced; } inline uint32 alloced_length() const { return Alloced_length;} inline uint32 extra_allocation() const { return extra_alloc;} inline void extra_allocation(size_t len) { extra_alloc= (uint32)len; } inline void mark_as_const() { Alloced_length= 0;} inline bool uses_buffer_owned_by(const Binary_string *s) const { return (s->alloced && Ptr >= s->Ptr && Ptr < s->Ptr + s->str_length); } /* Swap two string objects. Efficient way to exchange data without memcpy. */ void swap(Binary_string &s) { Static_binary_string::swap(s); swap_variables(uint32, Alloced_length, s.Alloced_length); swap_variables(bool, alloced, s.alloced); } /** Points the internal buffer to the supplied one. The old buffer is freed. @param str Pointer to the new buffer. @param arg_length Length of the new buffer in characters, excluding any null character. @note The new buffer will not be null terminated. */ void set_alloced(char *str, size_t length_arg, size_t alloced_length_arg) { free(); Static_binary_string::set(str, length_arg); DBUG_ASSERT(alloced_length_arg < UINT_MAX32); Alloced_length= (uint32) alloced_length_arg; } inline void set(char *str, size_t arg_length) { set_alloced(str, arg_length, arg_length); } inline void set(const char *str, size_t arg_length) { free(); Static_binary_string::set((char *) str, arg_length); } void set(Binary_string &str, size_t offset, size_t arg_length) { DBUG_ASSERT(&str != this); free(); Static_binary_string::set((char*) str.ptr() + offset, arg_length); if (str.Alloced_length) Alloced_length= (uint32) (str.Alloced_length - offset); } /* Take over handling of buffer from some other object */ void reset(char *ptr_arg, size_t length_arg, size_t alloced_length_arg) { set_alloced(ptr_arg, length_arg, alloced_length_arg); alloced= ptr_arg != 0; } /* Forget about the buffer, let some other object handle it */ char *release() { char *old= Ptr; Static_binary_string::set(NULL, 0); init_private_data(); return old; } inline void set_quick(char *str, size_t arg_length) { if (!alloced) { Static_binary_string::set(str, arg_length); Alloced_length= (uint32) arg_length; } } inline Binary_string& operator=(const Binary_string &s) { if (&s != this) { /* It is forbidden to do assignments like some_string = substring_of_that_string */ DBUG_ASSERT(!s.uses_buffer_owned_by(this)); set_alloced((char *) s.Ptr, s.str_length, s.Alloced_length); } return *this; } bool set_hex(ulonglong num); bool set_hex(const char *str, uint32 len); bool set_fcvt(double num, uint decimals); bool copy(); // Alloc string if not alloced bool copy(const Binary_string &s); // Allocate new string bool copy(const char *s, size_t arg_length); // Allocate new string bool copy_or_move(const char *s,size_t arg_length); bool append_ulonglong(ulonglong val); bool append_longlong(longlong val); bool append(const char *s, size_t size) { if (!size) return false; if (realloc_with_extra_if_needed(str_length + size)) return true; q_append(s, size); return false; } bool append(const Binary_string &s) { return append(s.ptr(), s.length()); } bool append(IO_CACHE* file, uint32 arg_length); inline bool append_char(char chr) { if (str_length < Alloced_length) { Ptr[str_length++]= chr; } else { if (unlikely(realloc_with_extra(str_length + 1))) return true; Ptr[str_length++]= chr; } return false; } bool append_hex(const char *src, uint32 srclen) { for (const char *src_end= src + srclen ; src != src_end ; src++) { if (unlikely(append_char(_dig_vec_lower[((uchar) *src) >> 4])) || unlikely(append_char(_dig_vec_lower[((uchar) *src) & 0x0F]))) return true; } return false; } bool append_with_step(const char *s, uint32 arg_length, uint32 step_alloc) { uint32 new_length= arg_length + str_length; if (new_length > Alloced_length && unlikely(realloc(new_length + step_alloc))) return true; q_append(s, arg_length); return false; } inline char *c_ptr() { DBUG_ASSERT(!alloced || !Ptr || !Alloced_length || (Alloced_length >= (str_length + 1))); if (!Ptr || Ptr[str_length]) // Should be safe (void) realloc(str_length); return Ptr; } inline char *c_ptr_quick() { if (Ptr && str_length < Alloced_length) Ptr[str_length]=0; return Ptr; } inline char *c_ptr_safe() { if (Ptr && str_length < Alloced_length) Ptr[str_length]=0; else (void) realloc(str_length); return Ptr; } inline void free() { if (alloced) { alloced=0; my_free(Ptr); } Alloced_length= extra_alloc= 0; Static_binary_string::set(NULL, 0); // Safety } inline bool alloc(size_t arg_length) { if (arg_length < Alloced_length) return 0; return real_alloc(arg_length); } bool real_alloc(size_t arg_length); // Empties old string bool realloc_raw(size_t arg_length); bool realloc(size_t arg_length) { if (realloc_raw(arg_length)) return TRUE; Ptr[arg_length]= 0; // This make other funcs shorter return FALSE; } bool realloc_with_extra(size_t arg_length) { if (extra_alloc < 4096) extra_alloc= extra_alloc*2+128; if (realloc_raw(arg_length + extra_alloc)) return TRUE; Ptr[arg_length]=0; // This make other funcs shorter return FALSE; } bool realloc_with_extra_if_needed(size_t arg_length) { if (arg_length < Alloced_length) { Ptr[arg_length]=0; // behave as if realloc was called. return 0; } return realloc_with_extra(arg_length); } // Shrink the buffer, but only if it is allocated on the heap. inline void shrink(size_t arg_length) { if (!is_alloced()) return; if (ALIGN_SIZE(arg_length+1) < Alloced_length) { char *new_ptr; if (unlikely(!(new_ptr=(char*) my_realloc(Ptr, arg_length,MYF((thread_specific ? MY_THREAD_SPECIFIC : 0)))))) { Alloced_length= 0; real_alloc(arg_length); } else { Ptr= new_ptr; Alloced_length= (uint32) arg_length; } } } void move(Binary_string &s) { set_alloced(s.Ptr, s.str_length, s.Alloced_length); extra_alloc= s.extra_alloc; alloced= s.alloced; thread_specific= s.thread_specific; s.alloced= 0; } bool fill(uint32 max_length,char fill); /* Replace substring with string If wrong parameter or not enough memory, do nothing */ bool replace(uint32 offset,uint32 arg_length, const char *to, uint32 length); bool replace(uint32 offset,uint32 arg_length, const Static_binary_string &to) { return replace(offset,arg_length,to.ptr(),to.length()); } int reserve(size_t space_needed) { DBUG_ASSERT((ulonglong) str_length + space_needed < UINT_MAX32); return realloc(str_length + space_needed); } int reserve(size_t space_needed, size_t grow_by); inline char *prep_append(uint32 arg_length, uint32 step_alloc) { uint32 new_length= arg_length + str_length; if (new_length > Alloced_length) { if (unlikely(realloc(new_length + step_alloc))) return 0; } uint32 old_length= str_length; str_length+= arg_length; return Ptr + old_length; // Area to use } void q_net_store_length(ulonglong length) { DBUG_ASSERT(Alloced_length >= (str_length + net_length_size(length))); char *pos= (char *) net_store_length((uchar *)(Ptr + str_length), length); str_length= uint32(pos - Ptr); } void q_net_store_data(const uchar *from, size_t length) { DBUG_ASSERT(length < UINT_MAX32); DBUG_ASSERT(Alloced_length >= (str_length + length + net_length_size(length))); q_net_store_length(length); q_append((const char *)from, (uint32) length); } }; class String: public Charset, public Binary_string { public: String() { } String(size_t length_arg) :Binary_string(length_arg) { } String(const char *str, CHARSET_INFO *cs) :Charset(cs), Binary_string(str) { } /* NOTE: If one intend to use the c_ptr() method, the following two contructors need the size of memory for STR to be at least LEN+1 (to make room for zero termination). */ String(const char *str, size_t len, CHARSET_INFO *cs) :Charset(cs), Binary_string((char *) str, len) { } String(char *str, size_t len, CHARSET_INFO *cs) :Charset(cs), Binary_string(str, len) { } String(const String &str) :Charset(str), Binary_string(str) { } void set(String &str,size_t offset,size_t arg_length) { Binary_string::set(str, offset, arg_length); set_charset(str); } inline void set(char *str,size_t arg_length, CHARSET_INFO *cs) { Binary_string::set(str, arg_length); set_charset(cs); } inline void set(const char *str,size_t arg_length, CHARSET_INFO *cs) { Binary_string::set(str, arg_length); set_charset(cs); } bool set_ascii(const char *str, size_t arg_length); inline void set_quick(char *str,size_t arg_length, CHARSET_INFO *cs) { Binary_string::set_quick(str, arg_length); set_charset(cs); } bool set_int(longlong num, bool unsigned_flag, CHARSET_INFO *cs); bool set(int num, CHARSET_INFO *cs) { return set_int(num, false, cs); } bool set(uint num, CHARSET_INFO *cs) { return set_int(num, true, cs); } bool set(long num, CHARSET_INFO *cs) { return set_int(num, false, cs); } bool set(ulong num, CHARSET_INFO *cs) { return set_int(num, true, cs); } bool set(longlong num, CHARSET_INFO *cs) { return set_int(num, false, cs); } bool set(ulonglong num, CHARSET_INFO *cs) { return set_int((longlong)num, true, cs); } bool set_real(double num,uint decimals, CHARSET_INFO *cs); bool set_fcvt(double num, uint decimals) { set_charset(&my_charset_latin1); return Binary_string::set_fcvt(num, decimals); } bool set_hex(ulonglong num) { set_charset(&my_charset_latin1); return Binary_string::set_hex(num); } bool set_hex(const char *str, uint32 len) { set_charset(&my_charset_latin1); return Binary_string::set_hex(str, len); } /* Take over handling of buffer from some other object */ void reset(char *ptr_arg, size_t length_arg, size_t alloced_length_arg, CHARSET_INFO *cs) { Binary_string::reset(ptr_arg, length_arg, alloced_length_arg); set_charset(cs); } inline String& operator = (const String &s) { if (&s != this) { set_charset(s); Binary_string::operator=(s); } return *this; } bool copy() { return Binary_string::copy(); } bool copy(const String &s) { set_charset(s); return Binary_string::copy(s); } bool copy(const char *s, size_t arg_length, CHARSET_INFO *cs) { set_charset(cs); return Binary_string::copy(s, arg_length); } bool copy_or_move(const char *s, size_t arg_length, CHARSET_INFO *cs) { set_charset(cs); return Binary_string::copy_or_move(s, arg_length); } static bool needs_conversion(size_t arg_length, CHARSET_INFO *cs_from, CHARSET_INFO *cs_to, uint32 *offset); static bool needs_conversion_on_storage(size_t arg_length, CHARSET_INFO *cs_from, CHARSET_INFO *cs_to); bool copy_aligned(const char *s, size_t arg_length, size_t offset, CHARSET_INFO *cs); bool set_or_copy_aligned(const char *s, size_t arg_length, CHARSET_INFO *cs); bool copy(const char*s, size_t arg_length, CHARSET_INFO *csfrom, CHARSET_INFO *csto, uint *errors); bool copy(const String *str, CHARSET_INFO *tocs, uint *errors) { return copy(str->ptr(), str->length(), str->charset(), tocs, errors); } bool copy(CHARSET_INFO *tocs, CHARSET_INFO *fromcs, const char *src, size_t src_length, size_t nchars, String_copier *copier) { if (unlikely(alloc(tocs->mbmaxlen * src_length))) return true; str_length= copier->well_formed_copy(tocs, Ptr, alloced_length(), fromcs, src, (uint)src_length, (uint)nchars); set_charset(tocs); return false; } // Append without character set conversion bool append(const String &s) { return Binary_string::append(s); } inline bool append(char chr) { return Binary_string::append_char(chr); } bool append_hex(const char *src, uint32 srclen) { return Binary_string::append_hex(src, srclen); } bool append_hex(const uchar *src, uint32 srclen) { return Binary_string::append_hex((const char*)src, srclen); } bool append(IO_CACHE* file, uint32 arg_length) { return Binary_string::append(file, arg_length); } inline bool append(const char *s, uint32 arg_length, uint32 step_alloc) { return append_with_step(s, arg_length, step_alloc); } // Append with optional character set conversion from ASCII (e.g. to UCS2) bool append(const char *s) { return append(s, strlen(s)); } bool append(const LEX_STRING *ls) { DBUG_ASSERT(ls->length < UINT_MAX32 && ((ls->length == 0 && !ls->str) || ls->length == strlen(ls->str))); return append(ls->str, (uint32) ls->length); } bool append(const LEX_CSTRING *ls) { DBUG_ASSERT(ls->length < UINT_MAX32 && ((ls->length == 0 && !ls->str) || ls->length == strlen(ls->str))); return append(ls->str, (uint32) ls->length); } bool append(const LEX_CSTRING &ls) { return append(&ls); } bool append(const char *s, size_t size); bool append_with_prefill(const char *s, uint32 arg_length, uint32 full_length, char fill_char); bool append_parenthesized(long nr, int radix= 10); // Append with optional character set conversion from cs to charset() bool append(const char *s, size_t arg_length, CHARSET_INFO *cs); bool append(const LEX_CSTRING &s, CHARSET_INFO *cs) { return append(s.str, s.length, cs); } void strip_sp(); friend int sortcmp(const String *a,const String *b, CHARSET_INFO *cs); friend int stringcmp(const String *a,const String *b); friend String *copy_if_not_alloced(String *a,String *b,uint32 arg_length); friend class Field; uint32 numchars() const { return (uint32) Charset::numchars(ptr(), end()); } int charpos(longlong i, uint32 offset=0) { if (i <= 0) return (int) i; return (int) Charset::charpos(ptr() + offset, end(), (size_t) i); } size_t lengthsp() const { return Charset::lengthsp(Ptr, str_length); } void print(String *to) const; void print_with_conversion(String *to, CHARSET_INFO *cs) const; void print(String *to, CHARSET_INFO *cs) const { if (my_charset_same(charset(), cs)) print(to); else print_with_conversion(to, cs); } bool append_for_single_quote(const char *st, size_t len); bool append_for_single_quote(const String *s) { return append_for_single_quote(s->ptr(), s->length()); } bool append_for_single_quote(const char *st) { size_t len= strlen(st); DBUG_ASSERT(len < UINT_MAX32); return append_for_single_quote(st, (uint32) len); } void swap(String &s) { Charset::swap(s); Binary_string::swap(s); } uint well_formed_length() const { return (uint) Well_formed_prefix(charset(), ptr(), length()).length(); } bool is_ascii() const { if (length() == 0) return TRUE; if (charset()->mbminlen > 1) return FALSE; return !has_8bit_bytes(); } bool eq(const String *other, CHARSET_INFO *cs) const { return !sortcmp(this, other, cs); } private: bool append_semi_hex(const char *s, uint len, CHARSET_INFO *cs); }; // The following class is a backport from MySQL 5.6: /** String class wrapper with a preallocated buffer of size buff_sz This class allows to replace sequences of: char buff[12345]; String str(buff, sizeof(buff)); str.length(0); with a simple equivalent declaration: StringBuffer<12345> str; */ template class StringBuffer : public String { char buff[buff_sz]; public: StringBuffer() : String(buff, buff_sz, &my_charset_bin) { length(0); } explicit StringBuffer(CHARSET_INFO *cs) : String(buff, buff_sz, cs) { length(0); } }; class String_space: public String { public: String_space(uint n) { if (fill(n, ' ')) set("", 0, &my_charset_bin); } }; static inline bool check_if_only_end_space(CHARSET_INFO *cs, const char *str, const char *end) { return str+ cs->cset->scan(cs, str, end, MY_SEQ_SPACES) == end; } int append_query_string(CHARSET_INFO *csinfo, String *to, const char *str, size_t len, bool no_backslash); #endif /* SQL_STRING_INCLUDED */