/* Copyright (C) 2002-2006 MySQL AB This library is free software; you can redistribute it and/or modify it under the terms of the GNU Library General Public License as published by the Free Software Foundation; version 2 of the License. This library 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 Library General Public License for more details. You should have received a copy of the GNU Library General Public License along with this library; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA */ #include "mysys_priv.h" #include #include #include #include #include "my_handler_errors.h" /** Swap the contents of two variables. */ #define swap_variables(TYPE, a, b) \ do { \ TYPE dummy; \ dummy= a; \ a= b; \ b= dummy; \ } while (0) #define CMP_NUM(a,b) (((a) < (b)) ? -1 : ((a) == (b)) ? 0 : 1) int ha_compare_text(const CHARSET_INFO * const charset_info, uchar *a, uint a_length, uchar *b, uint b_length, bool part_key, bool skip_end_space) { if (!part_key) return charset_info->coll->strnncollsp(charset_info, a, a_length, b, b_length, (bool)!skip_end_space); return charset_info->coll->strnncoll(charset_info, a, a_length, b, b_length, part_key); } static int compare_bin(uchar *a, uint a_length, uchar *b, uint b_length, bool part_key, bool skip_end_space) { uint length= cmin(a_length,b_length); uchar *end= a+ length; int flag; while (a < end) if ((flag= (int) *a++ - (int) *b++)) return flag; if (part_key && b_length < a_length) return 0; if (skip_end_space && a_length != b_length) { int swap= 1; /* We are using space compression. We have to check if longer key has next character < ' ', in which case it's less than the shorter key that has an implicite space afterwards. This code is identical to the one in strings/ctype-simple.c:my_strnncollsp_simple */ if (a_length < b_length) { /* put shorter key in a */ a_length= b_length; a= b; swap= -1; /* swap sign of result */ } for (end= a + a_length-length; a < end ; a++) { if (*a != ' ') return (*a < ' ') ? -swap : swap; } return 0; } return (int) (a_length-b_length); } /* Compare two keys SYNOPSIS ha_key_cmp() keyseg Array of key segments of key to compare a First key to compare, in format from _mi_pack_key() This is normally key specified by user b Second key to compare. This is always from a row key_length Length of key to compare. This can be shorter than a to just compare sub keys next_flag How keys should be compared If bit SEARCH_FIND is not set the keys includes the row position and this should also be compared diff_pos OUT Number of first keypart where values differ, counting from one. diff_pos[1] OUT (b + diff_pos[1]) points to first value in tuple b that is different from corresponding value in tuple a. EXAMPLES Example1: if the function is called for tuples ('aaa','bbb') and ('eee','fff'), then diff_pos[0] = 1 (as 'aaa' != 'eee') diff_pos[1] = 0 (offset from beggining of tuple b to 'eee' keypart). Example2: if the index function is called for tuples ('aaa','bbb') and ('aaa','fff'), diff_pos[0] = 2 (as 'aaa' != 'eee') diff_pos[1] = 3 (offset from beggining of tuple b to 'fff' keypart, here we assume that first key part is CHAR(3) NOT NULL) NOTES Number-keys can't be splited RETURN VALUES <0 If a < b 0 If a == b >0 If a > b */ #define FCMP(A,B) ((int) (A) - (int) (B)) int ha_key_cmp(register HA_KEYSEG *keyseg, register uchar *a, register uchar *b, uint key_length, uint nextflag, uint *diff_pos) { int flag; int16_t s_1,s_2; int32_t l_1,l_2; uint32_t u_1,u_2; float f_1,f_2; double d_1,d_2; uint next_key_length; uchar *orig_b= b; *diff_pos=0; for ( ; (int) key_length >0 ; key_length=next_key_length, keyseg++) { uchar *end; uint piks=! (keyseg->flag & HA_NO_SORT); (*diff_pos)++; diff_pos[1]= (uint)(b - orig_b); /* Handle NULL part */ if (keyseg->null_bit) { key_length--; if (*a != *b && piks) { flag = (int) *a - (int) *b; return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); } b++; if (!*a++) /* If key was NULL */ { if (nextflag == (SEARCH_FIND | SEARCH_UPDATE)) nextflag=SEARCH_SAME; /* Allow duplicate keys */ else if (nextflag & SEARCH_NULL_ARE_NOT_EQUAL) { /* This is only used from mi_check() to calculate cardinality. It can't be used when searching for a key as this would cause compare of (a,b) and (b,a) to return the same value. */ return -1; } next_key_length=key_length; continue; /* To next key part */ } } end= a+ cmin(keyseg->length,key_length); next_key_length=key_length-keyseg->length; switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_TEXT: /* Ascii; Key is converted */ if (keyseg->flag & HA_SPACE_PACK) { int a_length,b_length,pack_length; get_key_length(a_length,a); get_key_pack_length(b_length,pack_length,b); next_key_length=key_length-b_length-pack_length; if (piks && (flag=ha_compare_text(keyseg->charset,a,a_length,b,b_length, (bool) ((nextflag & SEARCH_PREFIX) && next_key_length <= 0), (bool)!(nextflag & SEARCH_PREFIX)))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a+=a_length; b+=b_length; break; } else { uint length=(uint) (end-a), a_length=length, b_length=length; if (piks && (flag= ha_compare_text(keyseg->charset, a, a_length, b, b_length, (bool) ((nextflag & SEARCH_PREFIX) && next_key_length <= 0), (bool)!(nextflag & SEARCH_PREFIX)))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a=end; b+=length; } break; case HA_KEYTYPE_BINARY: case HA_KEYTYPE_BIT: if (keyseg->flag & HA_SPACE_PACK) { int a_length,b_length,pack_length; get_key_length(a_length,a); get_key_pack_length(b_length,pack_length,b); next_key_length=key_length-b_length-pack_length; if (piks && (flag=compare_bin(a,a_length,b,b_length, (bool) ((nextflag & SEARCH_PREFIX) && next_key_length <= 0),1))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a+=a_length; b+=b_length; break; } else { uint length=keyseg->length; if (piks && (flag=compare_bin(a,length,b,length, (bool) ((nextflag & SEARCH_PREFIX) && next_key_length <= 0),0))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a+=length; b+=length; } break; case HA_KEYTYPE_VARTEXT1: case HA_KEYTYPE_VARTEXT2: { int a_length,b_length,pack_length; get_key_length(a_length,a); get_key_pack_length(b_length,pack_length,b); next_key_length=key_length-b_length-pack_length; if (piks && (flag= ha_compare_text(keyseg->charset,a,a_length,b,b_length, (bool) ((nextflag & SEARCH_PREFIX) && next_key_length <= 0), (bool) ((nextflag & (SEARCH_FIND | SEARCH_UPDATE)) == SEARCH_FIND && ! (keyseg->flag & HA_END_SPACE_ARE_EQUAL))))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a+= a_length; b+= b_length; break; } break; case HA_KEYTYPE_VARBINARY1: case HA_KEYTYPE_VARBINARY2: { int a_length,b_length,pack_length; get_key_length(a_length,a); get_key_pack_length(b_length,pack_length,b); next_key_length=key_length-b_length-pack_length; if (piks && (flag=compare_bin(a,a_length,b,b_length, (bool) ((nextflag & SEARCH_PREFIX) && next_key_length <= 0), 0))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a+=a_length; b+=b_length; break; } break; case HA_KEYTYPE_INT8: { int i_1= (int) *((signed char*) a); int i_2= (int) *((signed char*) b); if (piks && (flag = CMP_NUM(i_1,i_2))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b++; break; } case HA_KEYTYPE_SHORT_INT: s_1= mi_sint2korr(a); s_2= mi_sint2korr(b); if (piks && (flag = CMP_NUM(s_1,s_2))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+= 2; /* sizeof(short int); */ break; case HA_KEYTYPE_USHORT_INT: { uint16_t us_1,us_2; us_1= mi_sint2korr(a); us_2= mi_sint2korr(b); if (piks && (flag = CMP_NUM(us_1,us_2))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+=2; /* sizeof(short int); */ break; } case HA_KEYTYPE_LONG_INT: l_1= mi_sint4korr(a); l_2= mi_sint4korr(b); if (piks && (flag = CMP_NUM(l_1,l_2))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+= 4; /* sizeof(long int); */ break; case HA_KEYTYPE_ULONG_INT: u_1= mi_sint4korr(a); u_2= mi_sint4korr(b); if (piks && (flag = CMP_NUM(u_1,u_2))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+= 4; /* sizeof(long int); */ break; case HA_KEYTYPE_INT24: l_1=mi_sint3korr(a); l_2=mi_sint3korr(b); if (piks && (flag = CMP_NUM(l_1,l_2))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+= 3; break; case HA_KEYTYPE_UINT24: l_1=mi_uint3korr(a); l_2=mi_uint3korr(b); if (piks && (flag = CMP_NUM(l_1,l_2))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+= 3; break; case HA_KEYTYPE_FLOAT: mi_float4get(f_1,a); mi_float4get(f_2,b); /* The following may give a compiler warning about floating point comparison not being safe, but this is ok in this context as we are bascily doing sorting */ if (piks && (flag = CMP_NUM(f_1,f_2))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+= 4; /* sizeof(float); */ break; case HA_KEYTYPE_DOUBLE: mi_float8get(d_1,a); mi_float8get(d_2,b); /* The following may give a compiler warning about floating point comparison not being safe, but this is ok in this context as we are bascily doing sorting */ if (piks && (flag = CMP_NUM(d_1,d_2))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+= 8; /* sizeof(double); */ break; case HA_KEYTYPE_NUM: /* Numeric key */ { int swap_flag= 0; int alength,blength; if (keyseg->flag & HA_REVERSE_SORT) { swap_variables(uchar*, a, b); swap_flag=1; /* Remember swap of a & b */ end= a+ (int) (end-b); } if (keyseg->flag & HA_SPACE_PACK) { alength= *a++; blength= *b++; end=a+alength; next_key_length=key_length-blength-1; } else { alength= (int) (end-a); blength=keyseg->length; /* remove pre space from keys */ for ( ; alength && *a == ' ' ; a++, alength--) ; for ( ; blength && *b == ' ' ; b++, blength--) ; } if (piks) { if (*a == '-') { if (*b != '-') return -1; a++; b++; swap_variables(uchar*, a, b); swap_variables(int, alength, blength); swap_flag=1-swap_flag; alength--; blength--; end=a+alength; } else if (*b == '-') return 1; while (alength && (*a == '+' || *a == '0')) { a++; alength--; } while (blength && (*b == '+' || *b == '0')) { b++; blength--; } if (alength != blength) return (alength < blength) ? -1 : 1; while (a < end) if (*a++ != *b++) return ((int) a[-1] - (int) b[-1]); } else { b+=(end-a); a=end; } if (swap_flag) /* Restore pointers */ swap_variables(uchar*, a, b); break; } case HA_KEYTYPE_LONGLONG: { int64_t ll_a,ll_b; ll_a= mi_sint8korr(a); ll_b= mi_sint8korr(b); if (piks && (flag = CMP_NUM(ll_a,ll_b))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+= 8; break; } case HA_KEYTYPE_ULONGLONG: { uint64_t ll_a,ll_b; ll_a= mi_uint8korr(a); ll_b= mi_uint8korr(b); if (piks && (flag = CMP_NUM(ll_a,ll_b))) return ((keyseg->flag & HA_REVERSE_SORT) ? -flag : flag); a= end; b+= 8; break; } case HA_KEYTYPE_END: /* Ready */ goto end; /* diff_pos is incremented */ } } (*diff_pos)++; end: if (!(nextflag & SEARCH_FIND)) { uint i; if (nextflag & (SEARCH_NO_FIND | SEARCH_LAST)) /* Find record after key */ return (nextflag & (SEARCH_BIGGER | SEARCH_LAST)) ? -1 : 1; flag=0; for (i=keyseg->length ; i-- > 0 ; ) { if (*a++ != *b++) { flag= FCMP(a[-1],b[-1]); break; } } if (nextflag & SEARCH_SAME) return (flag); /* read same */ if (nextflag & SEARCH_BIGGER) return (flag <= 0 ? -1 : 1); /* read next */ return (flag < 0 ? -1 : 1); /* read previous */ } return 0; } /* ha_key_cmp */ /* Find the first NULL value in index-suffix values tuple SYNOPSIS ha_find_null() keyseg Array of keyparts for key suffix a Key suffix value tuple DESCRIPTION Find the first NULL value in index-suffix values tuple. TODO Consider optimizing this function or its use so we don't search for NULL values in completely NOT NULL index suffixes. RETURN First key part that has NULL as value in values tuple, or the last key part (with keyseg->type==HA_TYPE_END) if values tuple doesn't contain NULLs. */ HA_KEYSEG *ha_find_null(HA_KEYSEG *keyseg, uchar *a) { for (; (enum ha_base_keytype) keyseg->type != HA_KEYTYPE_END; keyseg++) { uchar *end; if (keyseg->null_bit) { if (!*a++) return keyseg; } end= a+ keyseg->length; switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_TEXT: case HA_KEYTYPE_BINARY: case HA_KEYTYPE_BIT: if (keyseg->flag & HA_SPACE_PACK) { int a_length; get_key_length(a_length, a); a += a_length; break; } else a= end; break; case HA_KEYTYPE_VARTEXT1: case HA_KEYTYPE_VARTEXT2: case HA_KEYTYPE_VARBINARY1: case HA_KEYTYPE_VARBINARY2: { int a_length; get_key_length(a_length, a); a+= a_length; break; } case HA_KEYTYPE_NUM: if (keyseg->flag & HA_SPACE_PACK) { int alength= *a++; end= a+alength; } a= end; break; case HA_KEYTYPE_INT8: case HA_KEYTYPE_SHORT_INT: case HA_KEYTYPE_USHORT_INT: case HA_KEYTYPE_LONG_INT: case HA_KEYTYPE_ULONG_INT: case HA_KEYTYPE_INT24: case HA_KEYTYPE_UINT24: case HA_KEYTYPE_LONGLONG: case HA_KEYTYPE_ULONGLONG: case HA_KEYTYPE_FLOAT: case HA_KEYTYPE_DOUBLE: a= end; break; case HA_KEYTYPE_END: /* purecov: inspected */ /* keep compiler happy */ assert(0); break; } } return keyseg; } /* Register handler error messages for usage with my_error() NOTES This is safe to call multiple times as my_error_register() will ignore calls to register already registered error numbers. */ void my_handler_error_register(void) { /* If you got compilation error here about compile_time_assert array, check that every HA_ERR_xxx constant has a corresponding error message in handler_error_messages[] list (check mysys/ma_handler_errors.h and include/my_base.h). */ compile_time_assert(HA_ERR_FIRST + array_elements(handler_error_messages) == HA_ERR_LAST + 1); my_error_register(handler_error_messages, HA_ERR_FIRST, HA_ERR_FIRST+ array_elements(handler_error_messages)-1); } void my_handler_error_unregister(void) { my_error_unregister(HA_ERR_FIRST, HA_ERR_FIRST+ array_elements(handler_error_messages)-1); }