/* Copyright (c) 2011, Oracle and/or its affiliates. Copyright (c) 1991, 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 Street, Fifth Floor, Boston, MA 02110-1335 USA */ #ifndef _my_compare_h #define _my_compare_h #include "myisampack.h" #ifdef __cplusplus extern "C" { #endif #include "m_ctype.h" /* CHARSET_INFO */ /* There is a hard limit for the maximum number of keys as there are only 8 bits in the index file header for the number of keys in a table. This means that 0..255 keys can exist for a table. The idea of HA_MAX_POSSIBLE_KEY is to ensure that one can use myisamchk & tools on a MyISAM table for which one has more keys than MyISAM is normally compiled for. If you don't have this, you will get a core dump when running myisamchk compiled for 128 keys on a table with 255 keys. */ #define HA_MAX_POSSIBLE_KEY 255 /* For myisamchk */ /* The following defines can be increased if necessary. But beware the dependency of MI_MAX_POSSIBLE_KEY_BUFF and HA_MAX_KEY_LENGTH. */ #define HA_MAX_KEY_LENGTH 1000 /* Max length in bytes */ #define HA_MAX_KEY_SEG 32 /* Max segments for key */ #define HA_MAX_POSSIBLE_KEY_BUFF (HA_MAX_KEY_LENGTH + 24+ 6+6) #define HA_MAX_KEY_BUFF (HA_MAX_KEY_LENGTH+HA_MAX_KEY_SEG*6+8+8) typedef struct st_HA_KEYSEG /* Key-portion */ { CHARSET_INFO *charset; uint32 start; /* Start of key in record */ uint32 null_pos; /* position to NULL indicator */ uint16 bit_pos; /* Position to bit part */ uint16 flag; uint16 length; /* Keylength */ uint16 language; uint8 type; /* Type of key (for sort) */ uint8 null_bit; /* bitmask to test for NULL */ uint8 bit_start; uint8 bit_length; /* Length of bit part */ } HA_KEYSEG; #define get_key_length(length,key) \ { if (*(const uchar*) (key) != 255) \ length= (uint) *(const uchar*) ((key)++); \ else \ { length= mi_uint2korr((key)+1); (key)+=3; } \ } #define get_key_length_rdonly(length,key) \ { if (*(const uchar*) (key) != 255) \ length= ((uint) *(const uchar*) ((key))); \ else \ { length= mi_uint2korr((key)+1); } \ } #define get_key_pack_length(length,length_pack,key) \ { if (*(const uchar*) (key) != 255) \ { length= (uint) *(const uchar*) ((key)++); length_pack= 1; }\ else \ { length=mi_uint2korr((key)+1); (key)+= 3; length_pack= 3; } \ } #define store_key_length_inc(key,length) \ { if ((length) < 255) \ { *(key)++= (uchar)(length); } \ else \ { *(key)=255; mi_int2store((key)+1,(length)); (key)+=3; } \ } #define size_to_store_key_length(length) ((length) < 255 ? 1 : 3) static inline uchar get_rec_bits(const uchar *ptr, uchar ofs, uint len) { uint16 val= ptr[0]; if (ofs + len > 8) val|= (uint16)((uint16)(ptr[1]) << 8); return (uchar) ((val >> ofs) & ((1 << len) - 1)); } static inline void set_rec_bits(uint16 bits, uchar *ptr, uchar ofs, uint len) { ptr[0]= (uchar) ((ptr[0] & ~(((1 << len) - 1) << ofs)) | (bits << ofs)); if (ofs + len > 8) ptr[1]= (uchar) ((ptr[1] & ~((1 << (len - 8 + ofs)) - 1)) | bits >> (8 - ofs)); } #define clr_rec_bits(bit_ptr, bit_ofs, bit_len) \ set_rec_bits(0, bit_ptr, bit_ofs, bit_len) extern int ha_compare_text(CHARSET_INFO *, const uchar *, size_t, const uchar *, size_t , my_bool); extern int ha_key_cmp(HA_KEYSEG *keyseg, const uchar *a, const uchar *b, uint key_length, uint nextflag, uint *diff_pos); extern HA_KEYSEG *ha_find_null(HA_KEYSEG *keyseg, const uchar *a); /* Inside an in-memory data record, memory pointers to pieces of the record (like BLOBs) are stored in their native byte order and in this amount of bytes. */ #define portable_sizeof_char_ptr 8 #ifdef __cplusplus } #endif /** Return values for pushed index condition or rowid filter check functions. 0=CHECK_NEG - The filter is not satisfied. The engine should discard this index tuple and continue the scan. 1=CHECK_POS - The filter is statisfied. Current index tuple should be returned to the SQL layer. 2=CHECK_OUT_OF_RANGE - the index tuple is outside of the range that we're scanning. (Example: if we're scanning "t.key BETWEEN 10 AND 20" and got a "t.key=21" tuple) Tthe engine should stop scanning and return HA_ERR_END_OF_FILE right away). 3=CHECK_ABORTED_BY_USER - the engine must stop scanning and should return HA_ERR_ABORTED_BY_USER right away -1=CHECK_ERROR - Reserved for internal errors in engines. Should not be returned by ICP or rowid filter check functions. */ typedef enum check_result { CHECK_ERROR=-1, CHECK_NEG=0, CHECK_POS=1, CHECK_OUT_OF_RANGE=2, CHECK_ABORTED_BY_USER=3 } check_result_t; typedef check_result_t (*index_cond_func_t)(void *param); typedef check_result_t (*rowid_filter_func_t)(void *param); typedef int (*rowid_filter_is_active_func_t)(void *param); #endif /* _my_compare_h */