/* Copyright (C) 2000 MySQL AB & Ramil Kalimullin & MySQL Finland AB & TCX DataKonsult AB 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; either version 2 of the License, or (at your option) any later version. 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "myisamdef.h" #ifdef HAVE_RTREE_KEYS #include "rt_index.h" #include "rt_mbr.h" #define INTERSECT_CMP(amin, amax, bmin, bmax) ((amin > bmax) || (bmin > amax)) #define CONTAIN_CMP(amin, amax, bmin, bmax) ((bmin > amin) || (bmax < amax)) #define WITHIN_CMP(amin, amax, bmin, bmax) ((amin > bmin) || (amax < bmax)) #define DISJOINT_CMP(amin, amax, bmin, bmax) ((amin <= bmax) && (bmin <= amax)) #define EQUAL_CMP(amin, amax, bmin, bmax) ((amin != bmin) || (amax != bmax)) #define FCMP(A, B) ((int)(A) - (int)(B)) #define p_inc(A, B, X) {A += X; B += X;} #define RT_CMP(nextflag) \ if (nextflag & MBR_INTERSECT) \ { \ if (INTERSECT_CMP(amin, amax, bmin, bmax)) \ return 1; \ } \ else if (nextflag & MBR_CONTAIN) \ { \ if (CONTAIN_CMP(amin, amax, bmin, bmax)) \ return 1; \ } \ else if (nextflag & MBR_WITHIN) \ { \ if (WITHIN_CMP(amin, amax, bmin, bmax)) \ return 1; \ } \ else if (nextflag & MBR_EQUAL) \ { \ if (EQUAL_CMP(amin, amax, bmin, bmax)) \ return 1; \ } \ else if (nextflag & MBR_DISJOINT) \ { \ if (DISJOINT_CMP(amin, amax, bmin, bmax)) \ return 1; \ }\ else /* if unknown comparison operator */ \ { \ DBUG_ASSERT(0); \ } #define RT_CMP_KORR(type, korr_func, len, nextflag) \ { \ type amin, amax, bmin, bmax; \ amin = korr_func(a); \ bmin = korr_func(b); \ amax = korr_func(a+len); \ bmax = korr_func(b+len); \ RT_CMP(nextflag); \ } #define RT_CMP_GET(type, get_func, len, nextflag) \ { \ type amin, amax, bmin, bmax; \ get_func(amin, a); \ get_func(bmin, b); \ get_func(amax, a+len); \ get_func(bmax, b+len); \ RT_CMP(nextflag); \ } /* Compares two keys a and b depending on nextflag nextflag can contain these flags: MBR_INTERSECT(a,b) a overlaps b MBR_CONTAIN(a,b) a contains b MBR_DISJOINT(a,b) a disjoint b MBR_WITHIN(a,b) a within b MBR_EQUAL(a,b) All coordinates of MBRs are equal MBR_DATA(a,b) Data reference is the same Returns 0 on success. */ int rtree_key_cmp(HA_KEYSEG *keyseg, uchar *b, uchar *a, uint key_length, uint nextflag) { for (; (int) key_length > 0; keyseg += 2 ) { uint32 keyseg_length; switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_INT8: RT_CMP_KORR(int8, mi_sint1korr, 1, nextflag); break; case HA_KEYTYPE_BINARY: RT_CMP_KORR(uint8, mi_uint1korr, 1, nextflag); break; case HA_KEYTYPE_SHORT_INT: RT_CMP_KORR(int16, mi_sint2korr, 2, nextflag); break; case HA_KEYTYPE_USHORT_INT: RT_CMP_KORR(uint16, mi_uint2korr, 2, nextflag); break; case HA_KEYTYPE_INT24: RT_CMP_KORR(int32, mi_sint3korr, 3, nextflag); break; case HA_KEYTYPE_UINT24: RT_CMP_KORR(uint32, mi_uint3korr, 3, nextflag); break; case HA_KEYTYPE_LONG_INT: RT_CMP_KORR(int32, mi_sint4korr, 4, nextflag); break; case HA_KEYTYPE_ULONG_INT: RT_CMP_KORR(uint32, mi_uint4korr, 4, nextflag); break; #ifdef HAVE_LONG_LONG case HA_KEYTYPE_LONGLONG: RT_CMP_KORR(longlong, mi_sint8korr, 8, nextflag) break; case HA_KEYTYPE_ULONGLONG: RT_CMP_KORR(ulonglong, mi_uint8korr, 8, nextflag) break; #endif case HA_KEYTYPE_FLOAT: /* The following should be safe, even if we compare doubles */ RT_CMP_GET(float, mi_float4get, 4, nextflag); break; case HA_KEYTYPE_DOUBLE: RT_CMP_GET(double, mi_float8get, 8, nextflag); break; case HA_KEYTYPE_END: goto end; default: return 1; } keyseg_length= keyseg->length * 2; key_length-= keyseg_length; a+= keyseg_length; b+= keyseg_length; } end: if (nextflag & MBR_DATA) { uchar *end = a + keyseg->length; do { if (*a++ != *b++) return FCMP(a[-1], b[-1]); } while (a != end); } return 0; } #define RT_VOL_KORR(type, korr_func, len, cast) \ { \ type amin, amax; \ amin = korr_func(a); \ amax = korr_func(a+len); \ res *= (cast(amax) - cast(amin)); \ } #define RT_VOL_GET(type, get_func, len, cast) \ { \ type amin, amax; \ get_func(amin, a); \ get_func(amax, a+len); \ res *= (cast(amax) - cast(amin)); \ } /* Calculates rectangle volume */ double rtree_rect_volume(HA_KEYSEG *keyseg, uchar *a, uint key_length) { double res = 1; for (; (int)key_length > 0; keyseg += 2) { uint32 keyseg_length; switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_INT8: RT_VOL_KORR(int8, mi_sint1korr, 1, (double)); break; case HA_KEYTYPE_BINARY: RT_VOL_KORR(uint8, mi_uint1korr, 1, (double)); break; case HA_KEYTYPE_SHORT_INT: RT_VOL_KORR(int16, mi_sint2korr, 2, (double)); break; case HA_KEYTYPE_USHORT_INT: RT_VOL_KORR(uint16, mi_uint2korr, 2, (double)); break; case HA_KEYTYPE_INT24: RT_VOL_KORR(int32, mi_sint3korr, 3, (double)); break; case HA_KEYTYPE_UINT24: RT_VOL_KORR(uint32, mi_uint3korr, 3, (double)); break; case HA_KEYTYPE_LONG_INT: RT_VOL_KORR(int32, mi_sint4korr, 4, (double)); break; case HA_KEYTYPE_ULONG_INT: RT_VOL_KORR(uint32, mi_uint4korr, 4, (double)); break; #ifdef HAVE_LONG_LONG case HA_KEYTYPE_LONGLONG: RT_VOL_KORR(longlong, mi_sint8korr, 8, (double)); break; case HA_KEYTYPE_ULONGLONG: RT_VOL_KORR(longlong, mi_sint8korr, 8, ulonglong2double); break; #endif case HA_KEYTYPE_FLOAT: RT_VOL_GET(float, mi_float4get, 4, (double)); break; case HA_KEYTYPE_DOUBLE: RT_VOL_GET(double, mi_float8get, 8, (double)); break; case HA_KEYTYPE_END: key_length = 0; break; default: return -1; } keyseg_length= keyseg->length * 2; key_length-= keyseg_length; a+= keyseg_length; } return res; } #define RT_D_MBR_KORR(type, korr_func, len, cast) \ { \ type amin, amax; \ amin = korr_func(a); \ amax = korr_func(a+len); \ *res++ = cast(amin); \ *res++ = cast(amax); \ } #define RT_D_MBR_GET(type, get_func, len, cast) \ { \ type amin, amax; \ get_func(amin, a); \ get_func(amax, a+len); \ *res++ = cast(amin); \ *res++ = cast(amax); \ } /* Creates an MBR as an array of doubles. */ int rtree_d_mbr(HA_KEYSEG *keyseg, uchar *a, uint key_length, double *res) { for (; (int)key_length > 0; keyseg += 2) { uint32 keyseg_length; switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_INT8: RT_D_MBR_KORR(int8, mi_sint1korr, 1, (double)); break; case HA_KEYTYPE_BINARY: RT_D_MBR_KORR(uint8, mi_uint1korr, 1, (double)); break; case HA_KEYTYPE_SHORT_INT: RT_D_MBR_KORR(int16, mi_sint2korr, 2, (double)); break; case HA_KEYTYPE_USHORT_INT: RT_D_MBR_KORR(uint16, mi_uint2korr, 2, (double)); break; case HA_KEYTYPE_INT24: RT_D_MBR_KORR(int32, mi_sint3korr, 3, (double)); break; case HA_KEYTYPE_UINT24: RT_D_MBR_KORR(uint32, mi_uint3korr, 3, (double)); break; case HA_KEYTYPE_LONG_INT: RT_D_MBR_KORR(int32, mi_sint4korr, 4, (double)); break; case HA_KEYTYPE_ULONG_INT: RT_D_MBR_KORR(uint32, mi_uint4korr, 4, (double)); break; #ifdef HAVE_LONG_LONG case HA_KEYTYPE_LONGLONG: RT_D_MBR_KORR(longlong, mi_sint8korr, 8, (double)); break; case HA_KEYTYPE_ULONGLONG: RT_D_MBR_KORR(longlong, mi_sint8korr, 8, ulonglong2double); break; #endif case HA_KEYTYPE_FLOAT: RT_D_MBR_GET(float, mi_float4get, 4, (double)); break; case HA_KEYTYPE_DOUBLE: RT_D_MBR_GET(double, mi_float8get, 8, (double)); break; case HA_KEYTYPE_END: key_length = 0; break; default: return 1; } keyseg_length= keyseg->length * 2; key_length-= keyseg_length; a+= keyseg_length; } return 0; } #define RT_COMB_KORR(type, korr_func, store_func, len) \ { \ type amin, amax, bmin, bmax; \ amin = korr_func(a); \ bmin = korr_func(b); \ amax = korr_func(a+len); \ bmax = korr_func(b+len); \ amin = min(amin, bmin); \ amax = max(amax, bmax); \ store_func(c, amin); \ store_func(c+len, amax); \ } #define RT_COMB_GET(type, get_func, store_func, len) \ { \ type amin, amax, bmin, bmax; \ get_func(amin, a); \ get_func(bmin, b); \ get_func(amax, a+len); \ get_func(bmax, b+len); \ amin = min(amin, bmin); \ amax = max(amax, bmax); \ store_func(c, amin); \ store_func(c+len, amax); \ } /* Creates common minimal bounding rectungle for two input rectagnles a and b Result is written to c */ int rtree_combine_rect(HA_KEYSEG *keyseg, uchar* a, uchar* b, uchar* c, uint key_length) { for ( ; (int) key_length > 0 ; keyseg += 2) { uint32 keyseg_length; switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_INT8: RT_COMB_KORR(int8, mi_sint1korr, mi_int1store, 1); break; case HA_KEYTYPE_BINARY: RT_COMB_KORR(uint8, mi_uint1korr, mi_int1store, 1); break; case HA_KEYTYPE_SHORT_INT: RT_COMB_KORR(int16, mi_sint2korr, mi_int2store, 2); break; case HA_KEYTYPE_USHORT_INT: RT_COMB_KORR(uint16, mi_uint2korr, mi_int2store, 2); break; case HA_KEYTYPE_INT24: RT_COMB_KORR(int32, mi_sint3korr, mi_int3store, 3); break; case HA_KEYTYPE_UINT24: RT_COMB_KORR(uint32, mi_uint3korr, mi_int3store, 3); break; case HA_KEYTYPE_LONG_INT: RT_COMB_KORR(int32, mi_sint4korr, mi_int4store, 4); break; case HA_KEYTYPE_ULONG_INT: RT_COMB_KORR(uint32, mi_uint4korr, mi_int4store, 4); break; #ifdef HAVE_LONG_LONG case HA_KEYTYPE_LONGLONG: RT_COMB_KORR(longlong, mi_sint8korr, mi_int8store, 8); break; case HA_KEYTYPE_ULONGLONG: RT_COMB_KORR(ulonglong, mi_uint8korr, mi_int8store, 8); break; #endif case HA_KEYTYPE_FLOAT: RT_COMB_GET(float, mi_float4get, mi_float4store, 4); break; case HA_KEYTYPE_DOUBLE: RT_COMB_GET(double, mi_float8get, mi_float8store, 8); break; case HA_KEYTYPE_END: return 0; default: return 1; } keyseg_length= keyseg->length * 2; key_length-= keyseg_length; a+= keyseg_length; b+= keyseg_length; c+= keyseg_length; } return 0; } #define RT_OVL_AREA_KORR(type, korr_func, len) \ { \ type amin, amax, bmin, bmax; \ amin = korr_func(a); \ bmin = korr_func(b); \ amax = korr_func(a+len); \ bmax = korr_func(b+len); \ amin = max(amin, bmin); \ amax = min(amax, bmax); \ if (amin >= amax) \ return 0; \ res *= amax - amin; \ } #define RT_OVL_AREA_GET(type, get_func, len) \ { \ type amin, amax, bmin, bmax; \ get_func(amin, a); \ get_func(bmin, b); \ get_func(amax, a+len); \ get_func(bmax, b+len); \ amin = max(amin, bmin); \ amax = min(amax, bmax); \ if (amin >= amax) \ return 0; \ res *= amax - amin; \ } /* Calculates overlapping area of two MBRs a & b */ double rtree_overlapping_area(HA_KEYSEG *keyseg, uchar* a, uchar* b, uint key_length) { double res = 1; for (; (int) key_length > 0 ; keyseg += 2) { uint32 keyseg_length; switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_INT8: RT_OVL_AREA_KORR(int8, mi_sint1korr, 1); break; case HA_KEYTYPE_BINARY: RT_OVL_AREA_KORR(uint8, mi_uint1korr, 1); break; case HA_KEYTYPE_SHORT_INT: RT_OVL_AREA_KORR(int16, mi_sint2korr, 2); break; case HA_KEYTYPE_USHORT_INT: RT_OVL_AREA_KORR(uint16, mi_uint2korr, 2); break; case HA_KEYTYPE_INT24: RT_OVL_AREA_KORR(int32, mi_sint3korr, 3); break; case HA_KEYTYPE_UINT24: RT_OVL_AREA_KORR(uint32, mi_uint3korr, 3); break; case HA_KEYTYPE_LONG_INT: RT_OVL_AREA_KORR(int32, mi_sint4korr, 4); break; case HA_KEYTYPE_ULONG_INT: RT_OVL_AREA_KORR(uint32, mi_uint4korr, 4); break; #ifdef HAVE_LONG_LONG case HA_KEYTYPE_LONGLONG: RT_OVL_AREA_KORR(longlong, mi_sint8korr, 8); break; case HA_KEYTYPE_ULONGLONG: RT_OVL_AREA_KORR(longlong, mi_sint8korr, 8); break; #endif case HA_KEYTYPE_FLOAT: RT_OVL_AREA_GET(float, mi_float4get, 4); break; case HA_KEYTYPE_DOUBLE: RT_OVL_AREA_GET(double, mi_float8get, 8); break; case HA_KEYTYPE_END: return res; default: return -1; } keyseg_length= keyseg->length * 2; key_length-= keyseg_length; a+= keyseg_length; b+= keyseg_length; } return res; } #define RT_AREA_INC_KORR(type, korr_func, len) \ { \ type amin, amax, bmin, bmax; \ amin = korr_func(a); \ bmin = korr_func(b); \ amax = korr_func(a+len); \ bmax = korr_func(b+len); \ a_area *= (((double)amax) - ((double)amin)); \ loc_ab_area *= ((double)max(amax, bmax) - (double)min(amin, bmin)); \ } #define RT_AREA_INC_GET(type, get_func, len)\ {\ type amin, amax, bmin, bmax; \ get_func(amin, a); \ get_func(bmin, b); \ get_func(amax, a+len); \ get_func(bmax, b+len); \ a_area *= (((double)amax) - ((double)amin)); \ loc_ab_area *= ((double)max(amax, bmax) - (double)min(amin, bmin)); \ } /* Calculates MBR_AREA(a+b) - MBR_AREA(a) */ double rtree_area_increase(HA_KEYSEG *keyseg, uchar* a, uchar* b, uint key_length, double *ab_area) { double a_area= 1.0; double loc_ab_area= 1.0; *ab_area= 1.0; for (; (int)key_length > 0; keyseg += 2) { uint32 keyseg_length; if (keyseg->null_bit) /* Handle NULL part */ return -1; switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_INT8: RT_AREA_INC_KORR(int8, mi_sint1korr, 1); break; case HA_KEYTYPE_BINARY: RT_AREA_INC_KORR(uint8, mi_uint1korr, 1); break; case HA_KEYTYPE_SHORT_INT: RT_AREA_INC_KORR(int16, mi_sint2korr, 2); break; case HA_KEYTYPE_USHORT_INT: RT_AREA_INC_KORR(uint16, mi_uint2korr, 2); break; case HA_KEYTYPE_INT24: RT_AREA_INC_KORR(int32, mi_sint3korr, 3); break; case HA_KEYTYPE_UINT24: RT_AREA_INC_KORR(int32, mi_uint3korr, 3); break; case HA_KEYTYPE_LONG_INT: RT_AREA_INC_KORR(int32, mi_sint4korr, 4); break; case HA_KEYTYPE_ULONG_INT: RT_AREA_INC_KORR(uint32, mi_uint4korr, 4); break; #ifdef HAVE_LONG_LONG case HA_KEYTYPE_LONGLONG: RT_AREA_INC_KORR(longlong, mi_sint8korr, 8); break; case HA_KEYTYPE_ULONGLONG: RT_AREA_INC_KORR(longlong, mi_sint8korr, 8); break; #endif case HA_KEYTYPE_FLOAT: RT_AREA_INC_GET(float, mi_float4get, 4); break; case HA_KEYTYPE_DOUBLE: RT_AREA_INC_GET(double, mi_float8get, 8); break; case HA_KEYTYPE_END: goto safe_end; default: return -1; } keyseg_length= keyseg->length * 2; key_length-= keyseg_length; a+= keyseg_length; b+= keyseg_length; } safe_end: *ab_area= loc_ab_area; return loc_ab_area - a_area; } #define RT_PERIM_INC_KORR(type, korr_func, len) \ { \ type amin, amax, bmin, bmax; \ amin = korr_func(a); \ bmin = korr_func(b); \ amax = korr_func(a+len); \ bmax = korr_func(b+len); \ a_perim+= (((double)amax) - ((double)amin)); \ *ab_perim+= ((double)max(amax, bmax) - (double)min(amin, bmin)); \ } #define RT_PERIM_INC_GET(type, get_func, len)\ {\ type amin, amax, bmin, bmax; \ get_func(amin, a); \ get_func(bmin, b); \ get_func(amax, a+len); \ get_func(bmax, b+len); \ a_perim+= (((double)amax) - ((double)amin)); \ *ab_perim+= ((double)max(amax, bmax) - (double)min(amin, bmin)); \ } /* Calculates MBR_PERIMETER(a+b) - MBR_PERIMETER(a) */ double rtree_perimeter_increase(HA_KEYSEG *keyseg, uchar* a, uchar* b, uint key_length, double *ab_perim) { double a_perim = 0.0; *ab_perim= 0.0; for (; (int)key_length > 0; keyseg += 2) { uint32 keyseg_length; if (keyseg->null_bit) /* Handle NULL part */ return -1; switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_INT8: RT_PERIM_INC_KORR(int8, mi_sint1korr, 1); break; case HA_KEYTYPE_BINARY: RT_PERIM_INC_KORR(uint8, mi_uint1korr, 1); break; case HA_KEYTYPE_SHORT_INT: RT_PERIM_INC_KORR(int16, mi_sint2korr, 2); break; case HA_KEYTYPE_USHORT_INT: RT_PERIM_INC_KORR(uint16, mi_uint2korr, 2); break; case HA_KEYTYPE_INT24: RT_PERIM_INC_KORR(int32, mi_sint3korr, 3); break; case HA_KEYTYPE_UINT24: RT_PERIM_INC_KORR(int32, mi_uint3korr, 3); break; case HA_KEYTYPE_LONG_INT: RT_PERIM_INC_KORR(int32, mi_sint4korr, 4); break; case HA_KEYTYPE_ULONG_INT: RT_PERIM_INC_KORR(uint32, mi_uint4korr, 4); break; #ifdef HAVE_LONG_LONG case HA_KEYTYPE_LONGLONG: RT_PERIM_INC_KORR(longlong, mi_sint8korr, 8); break; case HA_KEYTYPE_ULONGLONG: RT_PERIM_INC_KORR(longlong, mi_sint8korr, 8); break; #endif case HA_KEYTYPE_FLOAT: RT_PERIM_INC_GET(float, mi_float4get, 4); break; case HA_KEYTYPE_DOUBLE: RT_PERIM_INC_GET(double, mi_float8get, 8); break; case HA_KEYTYPE_END: return *ab_perim - a_perim; default: return -1; } keyseg_length= keyseg->length * 2; key_length-= keyseg_length; a+= keyseg_length; b+= keyseg_length; } return *ab_perim - a_perim; } #define RT_PAGE_MBR_KORR(type, korr_func, store_func, len) \ { \ type amin, amax, bmin, bmax; \ amin = korr_func(k + inc); \ amax = korr_func(k + inc + len); \ k = rt_PAGE_NEXT_KEY(k, k_len, nod_flag); \ for (; k < last; k = rt_PAGE_NEXT_KEY(k, k_len, nod_flag)) \ { \ bmin = korr_func(k + inc); \ bmax = korr_func(k + inc + len); \ if (amin > bmin) \ amin = bmin; \ if (amax < bmax) \ amax = bmax; \ } \ store_func(c, amin); \ c += len; \ store_func(c, amax); \ c += len; \ inc += 2 * len; \ } #define RT_PAGE_MBR_GET(type, get_func, store_func, len) \ { \ type amin, amax, bmin, bmax; \ get_func(amin, k + inc); \ get_func(amax, k + inc + len); \ k = rt_PAGE_NEXT_KEY(k, k_len, nod_flag); \ for (; k < last; k = rt_PAGE_NEXT_KEY(k, k_len, nod_flag)) \ { \ get_func(bmin, k + inc); \ get_func(bmax, k + inc + len); \ if (amin > bmin) \ amin = bmin; \ if (amax < bmax) \ amax = bmax; \ } \ store_func(c, amin); \ c += len; \ store_func(c, amax); \ c += len; \ inc += 2 * len; \ } /* Calculates key page total MBR = MBR(key1) + MBR(key2) + ... */ int rtree_page_mbr(MI_INFO *info, HA_KEYSEG *keyseg, uchar *page_buf, uchar *c, uint key_length) { uint inc = 0; uint k_len = key_length; uint nod_flag = mi_test_if_nod(page_buf); uchar *k; uchar *last = rt_PAGE_END(page_buf); for (; (int)key_length > 0; keyseg += 2) { key_length -= keyseg->length * 2; /* Handle NULL part */ if (keyseg->null_bit) { return 1; } k = rt_PAGE_FIRST_KEY(page_buf, nod_flag); switch ((enum ha_base_keytype) keyseg->type) { case HA_KEYTYPE_INT8: RT_PAGE_MBR_KORR(int8, mi_sint1korr, mi_int1store, 1); break; case HA_KEYTYPE_BINARY: RT_PAGE_MBR_KORR(uint8, mi_uint1korr, mi_int1store, 1); break; case HA_KEYTYPE_SHORT_INT: RT_PAGE_MBR_KORR(int16, mi_sint2korr, mi_int2store, 2); break; case HA_KEYTYPE_USHORT_INT: RT_PAGE_MBR_KORR(uint16, mi_uint2korr, mi_int2store, 2); break; case HA_KEYTYPE_INT24: RT_PAGE_MBR_KORR(int32, mi_sint3korr, mi_int3store, 3); break; case HA_KEYTYPE_UINT24: RT_PAGE_MBR_KORR(uint32, mi_uint3korr, mi_int3store, 3); break; case HA_KEYTYPE_LONG_INT: RT_PAGE_MBR_KORR(int32, mi_sint4korr, mi_int4store, 4); break; case HA_KEYTYPE_ULONG_INT: RT_PAGE_MBR_KORR(uint32, mi_uint4korr, mi_int4store, 4); break; #ifdef HAVE_LONG_LONG case HA_KEYTYPE_LONGLONG: RT_PAGE_MBR_KORR(longlong, mi_sint8korr, mi_int8store, 8); break; case HA_KEYTYPE_ULONGLONG: RT_PAGE_MBR_KORR(ulonglong, mi_uint8korr, mi_int8store, 8); break; #endif case HA_KEYTYPE_FLOAT: RT_PAGE_MBR_GET(float, mi_float4get, mi_float4store, 4); break; case HA_KEYTYPE_DOUBLE: RT_PAGE_MBR_GET(double, mi_float8get, mi_float8store, 8); break; case HA_KEYTYPE_END: return 0; default: return 1; } } return 0; } #endif /*HAVE_RTREE_KEYS*/