mirror of https://github.com/postgres/postgres
206 lines
6.9 KiB
C
206 lines
6.9 KiB
C
/*
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* contrib/hstore/hstore.h
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*/
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#ifndef __HSTORE_H__
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#define __HSTORE_H__
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#include "fmgr.h"
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#include "utils/array.h"
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/*
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* HEntry: there is one of these for each key _and_ value in an hstore
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*
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* the position offset points to the _end_ so that we can get the length
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* by subtraction from the previous entry. the ISFIRST flag lets us tell
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* whether there is a previous entry.
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*/
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typedef struct
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{
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uint32 entry;
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} HEntry;
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#define HENTRY_ISFIRST 0x80000000
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#define HENTRY_ISNULL 0x40000000
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#define HENTRY_POSMASK 0x3FFFFFFF
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/* note possible multiple evaluations, also access to prior array element */
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#define HSE_ISFIRST(he_) (((he_).entry & HENTRY_ISFIRST) != 0)
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#define HSE_ISNULL(he_) (((he_).entry & HENTRY_ISNULL) != 0)
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#define HSE_ENDPOS(he_) ((he_).entry & HENTRY_POSMASK)
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#define HSE_OFF(he_) (HSE_ISFIRST(he_) ? 0 : HSE_ENDPOS((&(he_))[-1]))
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#define HSE_LEN(he_) (HSE_ISFIRST(he_) \
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? HSE_ENDPOS(he_) \
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: HSE_ENDPOS(he_) - HSE_ENDPOS((&(he_))[-1]))
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/*
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* determined by the size of "endpos" (ie HENTRY_POSMASK), though this is a
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* bit academic since currently varlenas (and hence both the input and the
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* whole hstore) have the same limit
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*/
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#define HSTORE_MAX_KEY_LEN 0x3FFFFFFF
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#define HSTORE_MAX_VALUE_LEN 0x3FFFFFFF
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typedef struct
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{
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int32 vl_len_; /* varlena header (do not touch directly!) */
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uint32 size_; /* flags and number of items in hstore */
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/* array of HEntry follows */
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} HStore;
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/*
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* It's not possible to get more than 2^28 items into an hstore, so we reserve
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* the top few bits of the size field. See hstore_compat.c for one reason
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* why. Some bits are left for future use here. MaxAllocSize makes the
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* practical count limit slightly more than 2^28 / 3, or INT_MAX / 24, the
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* limit for an hstore full of 4-byte keys and null values. Therefore, we
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* don't explicitly check the format-imposed limit.
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*/
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#define HS_FLAG_NEWVERSION 0x80000000
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#define HS_COUNT(hsp_) ((hsp_)->size_ & 0x0FFFFFFF)
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#define HS_SETCOUNT(hsp_,c_) ((hsp_)->size_ = (c_) | HS_FLAG_NEWVERSION)
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/*
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* "x" comes from an existing HS_COUNT() (as discussed, <= INT_MAX/24) or a
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* Pairs array length (due to MaxAllocSize, <= INT_MAX/40). "lenstr" is no
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* more than INT_MAX, that extreme case arising in hstore_from_arrays().
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* Therefore, this calculation is limited to about INT_MAX / 5 + INT_MAX.
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*/
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#define HSHRDSIZE (sizeof(HStore))
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#define CALCDATASIZE(x, lenstr) ( (x) * 2 * sizeof(HEntry) + HSHRDSIZE + (lenstr) )
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/* note multiple evaluations of x */
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#define ARRPTR(x) ( (HEntry*) ( (HStore*)(x) + 1 ) )
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#define STRPTR(x) ( (char*)(ARRPTR(x) + HS_COUNT((HStore*)(x)) * 2) )
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/* note multiple/non evaluations */
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#define HS_KEY(arr_,str_,i_) ((str_) + HSE_OFF((arr_)[2*(i_)]))
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#define HS_VAL(arr_,str_,i_) ((str_) + HSE_OFF((arr_)[2*(i_)+1]))
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#define HS_KEYLEN(arr_,i_) (HSE_LEN((arr_)[2*(i_)]))
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#define HS_VALLEN(arr_,i_) (HSE_LEN((arr_)[2*(i_)+1]))
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#define HS_VALISNULL(arr_,i_) (HSE_ISNULL((arr_)[2*(i_)+1]))
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/*
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* currently, these following macros are the _only_ places that rely
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* on internal knowledge of HEntry. Everything else should be using
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* the above macros. Exception: the in-place upgrade in hstore_compat.c
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* messes with entries directly.
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*/
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/*
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* copy one key/value pair (which must be contiguous starting at
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* sptr_) into an under-construction hstore; dent_ is an HEntry*,
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* dbuf_ is the destination's string buffer, dptr_ is the current
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* position in the destination. lots of modification and multiple
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* evaluation here.
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*/
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#define HS_COPYITEM(dent_,dbuf_,dptr_,sptr_,klen_,vlen_,vnull_) \
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do { \
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memcpy((dptr_), (sptr_), (klen_)+(vlen_)); \
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(dptr_) += (klen_)+(vlen_); \
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(dent_)++->entry = ((dptr_) - (dbuf_) - (vlen_)) & HENTRY_POSMASK; \
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(dent_)++->entry = ((((dptr_) - (dbuf_)) & HENTRY_POSMASK) \
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| ((vnull_) ? HENTRY_ISNULL : 0)); \
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} while(0)
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/*
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* add one key/item pair, from a Pairs structure, into an
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* under-construction hstore
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*/
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#define HS_ADDITEM(dent_,dbuf_,dptr_,pair_) \
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do { \
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memcpy((dptr_), (pair_).key, (pair_).keylen); \
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(dptr_) += (pair_).keylen; \
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(dent_)++->entry = ((dptr_) - (dbuf_)) & HENTRY_POSMASK; \
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if ((pair_).isnull) \
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(dent_)++->entry = ((((dptr_) - (dbuf_)) & HENTRY_POSMASK) \
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| HENTRY_ISNULL); \
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else \
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{ \
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memcpy((dptr_), (pair_).val, (pair_).vallen); \
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(dptr_) += (pair_).vallen; \
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(dent_)++->entry = ((dptr_) - (dbuf_)) & HENTRY_POSMASK; \
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} \
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} while (0)
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/* finalize a newly-constructed hstore */
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#define HS_FINALIZE(hsp_,count_,buf_,ptr_) \
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do { \
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int buflen = (ptr_) - (buf_); \
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if ((count_)) \
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ARRPTR(hsp_)[0].entry |= HENTRY_ISFIRST; \
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if ((count_) != HS_COUNT((hsp_))) \
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{ \
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HS_SETCOUNT((hsp_),(count_)); \
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memmove(STRPTR(hsp_), (buf_), buflen); \
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} \
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SET_VARSIZE((hsp_), CALCDATASIZE((count_), buflen)); \
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} while (0)
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/* ensure the varlena size of an existing hstore is correct */
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#define HS_FIXSIZE(hsp_,count_) \
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do { \
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int bl = (count_) ? HSE_ENDPOS(ARRPTR(hsp_)[2*(count_)-1]) : 0; \
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SET_VARSIZE((hsp_), CALCDATASIZE((count_),bl)); \
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} while (0)
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/* DatumGetHStoreP includes support for reading old-format hstore values */
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extern HStore *hstoreUpgrade(Datum orig);
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#define DatumGetHStoreP(d) hstoreUpgrade(d)
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#define PG_GETARG_HS(x) DatumGetHStoreP(PG_GETARG_DATUM(x))
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/*
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* Pairs is a "decompressed" representation of one key/value pair.
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* The two strings are not necessarily null-terminated.
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*/
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typedef struct
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{
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char *key;
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char *val;
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size_t keylen;
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size_t vallen;
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bool isnull; /* value is null? */
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bool needfree; /* need to pfree the value? */
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} Pairs;
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extern int hstoreUniquePairs(Pairs *a, int32 l, int32 *buflen);
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extern HStore *hstorePairs(Pairs *pairs, int32 pcount, int32 buflen);
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extern size_t hstoreCheckKeyLen(size_t len);
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extern size_t hstoreCheckValLen(size_t len);
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extern int hstoreFindKey(HStore *hs, int *lowbound, char *key, int keylen);
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extern Pairs *hstoreArrayToPairs(ArrayType *a, int *npairs);
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#define HStoreContainsStrategyNumber 7
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#define HStoreExistsStrategyNumber 9
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#define HStoreExistsAnyStrategyNumber 10
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#define HStoreExistsAllStrategyNumber 11
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#define HStoreOldContainsStrategyNumber 13 /* backwards compatibility */
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/*
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* defining HSTORE_POLLUTE_NAMESPACE=0 will prevent use of old function names;
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* for now, we default to on for the benefit of people restoring old dumps
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*/
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#ifndef HSTORE_POLLUTE_NAMESPACE
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#define HSTORE_POLLUTE_NAMESPACE 1
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#endif
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#if HSTORE_POLLUTE_NAMESPACE
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#define HSTORE_POLLUTE(newname_,oldname_) \
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PG_FUNCTION_INFO_V1(oldname_); \
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Datum newname_(PG_FUNCTION_ARGS); \
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Datum oldname_(PG_FUNCTION_ARGS) { return newname_(fcinfo); } \
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extern int no_such_variable
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#else
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#define HSTORE_POLLUTE(newname_,oldname_) \
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extern int no_such_variable
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#endif
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#endif /* __HSTORE_H__ */
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