/* * contrib/btree_gin/btree_gin.c */ #include "postgres.h" #include #include "access/stratnum.h" #include "mb/pg_wchar.h" #include "nodes/miscnodes.h" #include "utils/builtins.h" #include "utils/date.h" #include "utils/float.h" #include "utils/inet.h" #include "utils/numeric.h" #include "utils/timestamp.h" #include "utils/uuid.h" #include "varatt.h" PG_MODULE_MAGIC_EXT( .name = "btree_gin", .version = PG_VERSION ); /* * Our opclasses use the same strategy numbers as btree (1-5) for same-type * comparison operators. For cross-type comparison operators, the * low 4 bits of our strategy numbers are the btree strategy number, * and the upper bits are a code for the right-hand-side data type. */ #define BTGIN_GET_BTREE_STRATEGY(strat) ((strat) & 0x0F) #define BTGIN_GET_RHS_TYPE_CODE(strat) ((strat) >> 4) /* extra data passed from gin_btree_extract_query to gin_btree_compare_prefix */ typedef struct QueryInfo { StrategyNumber strategy; /* operator strategy number */ Datum orig_datum; /* original query (comparison) datum */ Datum entry_datum; /* datum we reported as the entry value */ PGFunction typecmp; /* appropriate btree comparison function */ } QueryInfo; typedef Datum (*btree_gin_convert_function) (Datum input); typedef Datum (*btree_gin_leftmost_function) (void); /*** GIN support functions shared by all datatypes ***/ static Datum gin_btree_extract_value(FunctionCallInfo fcinfo, bool is_varlena) { Datum datum = PG_GETARG_DATUM(0); int32 *nentries = (int32 *) PG_GETARG_POINTER(1); Datum *entries = palloc_object(Datum); /* Ensure that values stored in the index are not toasted */ if (is_varlena) datum = PointerGetDatum(PG_DETOAST_DATUM(datum)); entries[0] = datum; *nentries = 1; PG_RETURN_POINTER(entries); } static Datum gin_btree_extract_query(FunctionCallInfo fcinfo, btree_gin_leftmost_function leftmostvalue, const bool *rhs_is_varlena, const btree_gin_convert_function *cvt_fns, const PGFunction *cmp_fns) { Datum datum = PG_GETARG_DATUM(0); int32 *nentries = (int32 *) PG_GETARG_POINTER(1); StrategyNumber strategy = PG_GETARG_UINT16(2); bool **partialmatch = (bool **) PG_GETARG_POINTER(3); Pointer **extra_data = (Pointer **) PG_GETARG_POINTER(4); Datum *entries = palloc_object(Datum); QueryInfo *data = palloc_object(QueryInfo); bool *ptr_partialmatch = palloc_object(bool); int btree_strat, rhs_code; /* * Extract the btree strategy code and the RHS data type code from the * given strategy number. */ btree_strat = BTGIN_GET_BTREE_STRATEGY(strategy); rhs_code = BTGIN_GET_RHS_TYPE_CODE(strategy); /* * Detoast the comparison datum. This isn't necessary for correctness, * but it can save repeat detoastings within the comparison function. */ if (rhs_is_varlena[rhs_code]) datum = PointerGetDatum(PG_DETOAST_DATUM(datum)); /* Prep single comparison key with possible partial-match flag */ *nentries = 1; *partialmatch = ptr_partialmatch; *ptr_partialmatch = false; /* * For BTGreaterEqualStrategyNumber, BTGreaterStrategyNumber, and * BTEqualStrategyNumber we want to start the index scan at the supplied * query datum, and work forward. For BTLessStrategyNumber and * BTLessEqualStrategyNumber, we need to start at the leftmost key, and * work forward until the supplied query datum (which we'll send along * inside the QueryInfo structure). Use partial match rules except for * BTEqualStrategyNumber without a conversion function. (If there is a * conversion function, comparison to the entry value is not trustworthy.) */ switch (btree_strat) { case BTLessStrategyNumber: case BTLessEqualStrategyNumber: entries[0] = leftmostvalue(); *ptr_partialmatch = true; break; case BTGreaterEqualStrategyNumber: case BTGreaterStrategyNumber: *ptr_partialmatch = true; /* FALLTHROUGH */ case BTEqualStrategyNumber: /* If we have a conversion function, apply it */ if (cvt_fns && cvt_fns[rhs_code]) { entries[0] = (*cvt_fns[rhs_code]) (datum); *ptr_partialmatch = true; } else entries[0] = datum; break; default: elog(ERROR, "unrecognized strategy number: %d", strategy); } /* Fill "extra" data */ data->strategy = strategy; data->orig_datum = datum; data->entry_datum = entries[0]; data->typecmp = cmp_fns[rhs_code]; *extra_data = palloc_object(Pointer); **extra_data = (Pointer) data; PG_RETURN_POINTER(entries); } static Datum gin_btree_compare_prefix(FunctionCallInfo fcinfo) { Datum partial_key PG_USED_FOR_ASSERTS_ONLY = PG_GETARG_DATUM(0); Datum key = PG_GETARG_DATUM(1); QueryInfo *data = (QueryInfo *) PG_GETARG_POINTER(3); int32 res, cmp; /* * partial_key is only an approximation to the real comparison value, * especially if it's a leftmost value. We can get an accurate answer by * doing a possibly-cross-type comparison to the real comparison value. * (Note that partial_key and key are of the indexed datatype while * orig_datum is of the query operator's RHS datatype.) * * But just to be sure that things are what we expect, let's assert that * partial_key is indeed what gin_btree_extract_query reported, so that * we'll notice if anyone ever changes the core code in a way that breaks * our assumptions. */ Assert(partial_key == data->entry_datum); cmp = DatumGetInt32(CallerFInfoFunctionCall2(data->typecmp, fcinfo->flinfo, PG_GET_COLLATION(), data->orig_datum, key)); /* * Convert the comparison result to the correct thing for the search * operator strategy. When dealing with cross-type comparisons, an * imprecise entry datum could lead GIN to start the scan just before the * first possible match, so we must continue the scan if the current index * entry doesn't satisfy the search condition for >= and > cases. But if * that happens in an = search we can stop, because an imprecise entry * datum means that the search value is unrepresentable in the indexed * data type, so that there will be no exact matches. */ switch (BTGIN_GET_BTREE_STRATEGY(data->strategy)) { case BTLessStrategyNumber: /* If original datum > indexed one then return match */ if (cmp > 0) res = 0; else res = 1; /* end scan */ break; case BTLessEqualStrategyNumber: /* If original datum >= indexed one then return match */ if (cmp >= 0) res = 0; else res = 1; /* end scan */ break; case BTEqualStrategyNumber: /* If original datum = indexed one then return match */ /* See above about why we can end scan when cmp < 0 */ if (cmp == 0) res = 0; else res = 1; /* end scan */ break; case BTGreaterEqualStrategyNumber: /* If original datum <= indexed one then return match */ if (cmp <= 0) res = 0; else res = -1; /* keep scanning */ break; case BTGreaterStrategyNumber: /* If original datum < indexed one then return match */ if (cmp < 0) res = 0; else res = -1; /* keep scanning */ break; default: elog(ERROR, "unrecognized strategy number: %d", data->strategy); res = 0; } PG_RETURN_INT32(res); } PG_FUNCTION_INFO_V1(gin_btree_consistent); Datum gin_btree_consistent(PG_FUNCTION_ARGS) { bool *recheck = (bool *) PG_GETARG_POINTER(5); *recheck = false; PG_RETURN_BOOL(true); } /*** GIN_SUPPORT macro defines the datatype specific functions ***/ #define GIN_SUPPORT(type, leftmostvalue, is_varlena, cvtfns, cmpfns) \ PG_FUNCTION_INFO_V1(gin_extract_value_##type); \ Datum \ gin_extract_value_##type(PG_FUNCTION_ARGS) \ { \ return gin_btree_extract_value(fcinfo, is_varlena[0]); \ } \ PG_FUNCTION_INFO_V1(gin_extract_query_##type); \ Datum \ gin_extract_query_##type(PG_FUNCTION_ARGS) \ { \ return gin_btree_extract_query(fcinfo, \ leftmostvalue, is_varlena, \ cvtfns, cmpfns); \ } \ PG_FUNCTION_INFO_V1(gin_compare_prefix_##type); \ Datum \ gin_compare_prefix_##type(PG_FUNCTION_ARGS) \ { \ return gin_btree_compare_prefix(fcinfo); \ } /*** Datatype specifications ***/ /* Function to produce the least possible value of the indexed datatype */ static Datum leftmostvalue_int2(void) { return Int16GetDatum(SHRT_MIN); } /* * For cross-type support, we must provide conversion functions that produce * a Datum of the indexed datatype, since GIN requires the "entry" datums to * be of that type. If an exact conversion is not possible, produce a value * that will lead GIN to find the first index entry that is greater than * or equal to the actual comparison value. (But rounding down is OK, so * sometimes we might find an index entry that's just less than the * comparison value.) * * For integer values, it's sufficient to clamp the input to be in-range. * * Note: for out-of-range input values, we could in theory detect that the * search condition matches all or none of the index, and avoid a useless * index descent in the latter case. Such searches are probably rare though, * so we don't contort this code enough to do that. */ static Datum cvt_int4_int2(Datum input) { int32 val = DatumGetInt32(input); val = Max(val, SHRT_MIN); val = Min(val, SHRT_MAX); return Int16GetDatum((int16) val); } static Datum cvt_int8_int2(Datum input) { int64 val = DatumGetInt64(input); val = Max(val, SHRT_MIN); val = Min(val, SHRT_MAX); return Int16GetDatum((int16) val); } /* * RHS-type-is-varlena flags, conversion and comparison function arrays, * indexed by high bits of the operator strategy number. A NULL in the * conversion function array indicates that no conversion is needed, which * will always be the case for the zero'th entry. Note that the cross-type * comparison functions should be the ones with the indexed datatype second. */ static const bool int2_rhs_is_varlena[] = {false, false, false}; static const btree_gin_convert_function int2_cvt_fns[] = {NULL, cvt_int4_int2, cvt_int8_int2}; static const PGFunction int2_cmp_fns[] = {btint2cmp, btint42cmp, btint82cmp}; GIN_SUPPORT(int2, leftmostvalue_int2, int2_rhs_is_varlena, int2_cvt_fns, int2_cmp_fns) static Datum leftmostvalue_int4(void) { return Int32GetDatum(INT_MIN); } static Datum cvt_int2_int4(Datum input) { int16 val = DatumGetInt16(input); return Int32GetDatum((int32) val); } static Datum cvt_int8_int4(Datum input) { int64 val = DatumGetInt64(input); val = Max(val, INT_MIN); val = Min(val, INT_MAX); return Int32GetDatum((int32) val); } static const bool int4_rhs_is_varlena[] = {false, false, false}; static const btree_gin_convert_function int4_cvt_fns[] = {NULL, cvt_int2_int4, cvt_int8_int4}; static const PGFunction int4_cmp_fns[] = {btint4cmp, btint24cmp, btint84cmp}; GIN_SUPPORT(int4, leftmostvalue_int4, int4_rhs_is_varlena, int4_cvt_fns, int4_cmp_fns) static Datum leftmostvalue_int8(void) { return Int64GetDatum(PG_INT64_MIN); } static Datum cvt_int2_int8(Datum input) { int16 val = DatumGetInt16(input); return Int64GetDatum((int64) val); } static Datum cvt_int4_int8(Datum input) { int32 val = DatumGetInt32(input); return Int64GetDatum((int64) val); } static const bool int8_rhs_is_varlena[] = {false, false, false}; static const btree_gin_convert_function int8_cvt_fns[] = {NULL, cvt_int2_int8, cvt_int4_int8}; static const PGFunction int8_cmp_fns[] = {btint8cmp, btint28cmp, btint48cmp}; GIN_SUPPORT(int8, leftmostvalue_int8, int8_rhs_is_varlena, int8_cvt_fns, int8_cmp_fns) static Datum leftmostvalue_float4(void) { return Float4GetDatum(-get_float4_infinity()); } static Datum cvt_float8_float4(Datum input) { float8 val = DatumGetFloat8(input); float4 result; /* * Assume that ordinary C conversion will produce a usable result. * (Compare dtof(), which raises error conditions that we don't need.) * Note that for inputs that aren't exactly representable as float4, it * doesn't matter whether the conversion rounds up or down. That might * cause us to scan a few index entries that we'll reject as not matching, * but we won't miss any that should match. */ result = (float4) val; return Float4GetDatum(result); } static const bool float4_rhs_is_varlena[] = {false, false}; static const btree_gin_convert_function float4_cvt_fns[] = {NULL, cvt_float8_float4}; static const PGFunction float4_cmp_fns[] = {btfloat4cmp, btfloat84cmp}; GIN_SUPPORT(float4, leftmostvalue_float4, float4_rhs_is_varlena, float4_cvt_fns, float4_cmp_fns) static Datum leftmostvalue_float8(void) { return Float8GetDatum(-get_float8_infinity()); } static Datum cvt_float4_float8(Datum input) { float4 val = DatumGetFloat4(input); return Float8GetDatum((float8) val); } static const bool float8_rhs_is_varlena[] = {false, false}; static const btree_gin_convert_function float8_cvt_fns[] = {NULL, cvt_float4_float8}; static const PGFunction float8_cmp_fns[] = {btfloat8cmp, btfloat48cmp}; GIN_SUPPORT(float8, leftmostvalue_float8, float8_rhs_is_varlena, float8_cvt_fns, float8_cmp_fns) static Datum leftmostvalue_money(void) { return Int64GetDatum(PG_INT64_MIN); } static const bool money_rhs_is_varlena[] = {false}; static const PGFunction money_cmp_fns[] = {cash_cmp}; GIN_SUPPORT(money, leftmostvalue_money, money_rhs_is_varlena, NULL, money_cmp_fns) static Datum leftmostvalue_oid(void) { return ObjectIdGetDatum(0); } static const bool oid_rhs_is_varlena[] = {false}; static const PGFunction oid_cmp_fns[] = {btoidcmp}; GIN_SUPPORT(oid, leftmostvalue_oid, oid_rhs_is_varlena, NULL, oid_cmp_fns) static Datum leftmostvalue_timestamp(void) { return TimestampGetDatum(DT_NOBEGIN); } static Datum cvt_date_timestamp(Datum input) { DateADT val = DatumGetDateADT(input); Timestamp result; ErrorSaveContext escontext = {T_ErrorSaveContext}; result = date2timestamp_safe(val, (Node *) &escontext); /* We can ignore errors, since result is useful as-is */ return TimestampGetDatum(result); } static Datum cvt_timestamptz_timestamp(Datum input) { TimestampTz val = DatumGetTimestampTz(input); ErrorSaveContext escontext = {T_ErrorSaveContext}; Timestamp result; result = timestamptz2timestamp_safe(val, (Node *) &escontext); /* We can ignore errors, since result is useful as-is */ return TimestampGetDatum(result); } static const bool timestamp_rhs_is_varlena[] = {false, false, false}; static const btree_gin_convert_function timestamp_cvt_fns[] = {NULL, cvt_date_timestamp, cvt_timestamptz_timestamp}; static const PGFunction timestamp_cmp_fns[] = {timestamp_cmp, date_cmp_timestamp, timestamptz_cmp_timestamp}; GIN_SUPPORT(timestamp, leftmostvalue_timestamp, timestamp_rhs_is_varlena, timestamp_cvt_fns, timestamp_cmp_fns) static Datum cvt_date_timestamptz(Datum input) { DateADT val = DatumGetDateADT(input); ErrorSaveContext escontext = {T_ErrorSaveContext}; TimestampTz result; result = date2timestamptz_safe(val, (Node *) &escontext); /* We can ignore errors, since result is useful as-is */ return TimestampTzGetDatum(result); } static Datum cvt_timestamp_timestamptz(Datum input) { Timestamp val = DatumGetTimestamp(input); ErrorSaveContext escontext = {T_ErrorSaveContext}; TimestampTz result; result = timestamp2timestamptz_safe(val, (Node *) &escontext); /* We can ignore errors, since result is useful as-is */ return TimestampTzGetDatum(result); } static const bool timestamptz_rhs_is_varlena[] = {false, false, false}; static const btree_gin_convert_function timestamptz_cvt_fns[] = {NULL, cvt_date_timestamptz, cvt_timestamp_timestamptz}; static const PGFunction timestamptz_cmp_fns[] = {timestamp_cmp, date_cmp_timestamptz, timestamp_cmp_timestamptz}; GIN_SUPPORT(timestamptz, leftmostvalue_timestamp, timestamptz_rhs_is_varlena, timestamptz_cvt_fns, timestamptz_cmp_fns) static Datum leftmostvalue_time(void) { return TimeADTGetDatum(0); } static const bool time_rhs_is_varlena[] = {false}; static const PGFunction time_cmp_fns[] = {time_cmp}; GIN_SUPPORT(time, leftmostvalue_time, time_rhs_is_varlena, NULL, time_cmp_fns) static Datum leftmostvalue_timetz(void) { TimeTzADT *v = palloc_object(TimeTzADT); v->time = 0; v->zone = -24 * 3600; /* XXX is that true? */ return TimeTzADTPGetDatum(v); } static const bool timetz_rhs_is_varlena[] = {false}; static const PGFunction timetz_cmp_fns[] = {timetz_cmp}; GIN_SUPPORT(timetz, leftmostvalue_timetz, timetz_rhs_is_varlena, NULL, timetz_cmp_fns) static Datum leftmostvalue_date(void) { return DateADTGetDatum(DATEVAL_NOBEGIN); } static Datum cvt_timestamp_date(Datum input) { Timestamp val = DatumGetTimestamp(input); ErrorSaveContext escontext = {T_ErrorSaveContext}; DateADT result; result = timestamp2date_safe(val, (Node *) &escontext); /* We can ignore errors, since result is useful as-is */ return DateADTGetDatum(result); } static Datum cvt_timestamptz_date(Datum input) { TimestampTz val = DatumGetTimestampTz(input); ErrorSaveContext escontext = {T_ErrorSaveContext}; DateADT result; result = timestamptz2date_safe(val, (Node *) &escontext); /* We can ignore errors, since result is useful as-is */ return DateADTGetDatum(result); } static const bool date_rhs_is_varlena[] = {false, false, false}; static const btree_gin_convert_function date_cvt_fns[] = {NULL, cvt_timestamp_date, cvt_timestamptz_date}; static const PGFunction date_cmp_fns[] = {date_cmp, timestamp_cmp_date, timestamptz_cmp_date}; GIN_SUPPORT(date, leftmostvalue_date, date_rhs_is_varlena, date_cvt_fns, date_cmp_fns) static Datum leftmostvalue_interval(void) { Interval *v = palloc_object(Interval); INTERVAL_NOBEGIN(v); return IntervalPGetDatum(v); } static const bool interval_rhs_is_varlena[] = {false}; static const PGFunction interval_cmp_fns[] = {interval_cmp}; GIN_SUPPORT(interval, leftmostvalue_interval, interval_rhs_is_varlena, NULL, interval_cmp_fns) static Datum leftmostvalue_macaddr(void) { macaddr *v = palloc0_object(macaddr); return MacaddrPGetDatum(v); } static const bool macaddr_rhs_is_varlena[] = {false}; static const PGFunction macaddr_cmp_fns[] = {macaddr_cmp}; GIN_SUPPORT(macaddr, leftmostvalue_macaddr, macaddr_rhs_is_varlena, NULL, macaddr_cmp_fns) static Datum leftmostvalue_macaddr8(void) { macaddr8 *v = palloc0_object(macaddr8); return Macaddr8PGetDatum(v); } static const bool macaddr8_rhs_is_varlena[] = {false}; static const PGFunction macaddr8_cmp_fns[] = {macaddr8_cmp}; GIN_SUPPORT(macaddr8, leftmostvalue_macaddr8, macaddr8_rhs_is_varlena, NULL, macaddr8_cmp_fns) static Datum leftmostvalue_inet(void) { return DirectFunctionCall1(inet_in, CStringGetDatum("0.0.0.0/0")); } static const bool inet_rhs_is_varlena[] = {true}; static const PGFunction inet_cmp_fns[] = {network_cmp}; GIN_SUPPORT(inet, leftmostvalue_inet, inet_rhs_is_varlena, NULL, inet_cmp_fns) static const bool cidr_rhs_is_varlena[] = {true}; static const PGFunction cidr_cmp_fns[] = {network_cmp}; GIN_SUPPORT(cidr, leftmostvalue_inet, cidr_rhs_is_varlena, NULL, cidr_cmp_fns) static Datum leftmostvalue_text(void) { return PointerGetDatum(cstring_to_text_with_len("", 0)); } static Datum cvt_name_text(Datum input) { Name val = DatumGetName(input); return PointerGetDatum(cstring_to_text(NameStr(*val))); } static const bool text_rhs_is_varlena[] = {true, false}; static const btree_gin_convert_function text_cvt_fns[] = {NULL, cvt_name_text}; static const PGFunction text_cmp_fns[] = {bttextcmp, btnametextcmp}; GIN_SUPPORT(text, leftmostvalue_text, text_rhs_is_varlena, text_cvt_fns, text_cmp_fns) static const bool bpchar_rhs_is_varlena[] = {true}; static const PGFunction bpchar_cmp_fns[] = {bpcharcmp}; GIN_SUPPORT(bpchar, leftmostvalue_text, bpchar_rhs_is_varlena, NULL, bpchar_cmp_fns) static Datum leftmostvalue_char(void) { return CharGetDatum(0); } static const bool char_rhs_is_varlena[] = {false}; static const PGFunction char_cmp_fns[] = {btcharcmp}; GIN_SUPPORT(char, leftmostvalue_char, char_rhs_is_varlena, NULL, char_cmp_fns) static const bool bytea_rhs_is_varlena[] = {true}; static const PGFunction bytea_cmp_fns[] = {byteacmp}; GIN_SUPPORT(bytea, leftmostvalue_text, bytea_rhs_is_varlena, NULL, bytea_cmp_fns) static Datum leftmostvalue_bit(void) { return DirectFunctionCall3(bit_in, CStringGetDatum(""), ObjectIdGetDatum(0), Int32GetDatum(-1)); } static const bool bit_rhs_is_varlena[] = {true}; static const PGFunction bit_cmp_fns[] = {bitcmp}; GIN_SUPPORT(bit, leftmostvalue_bit, bit_rhs_is_varlena, NULL, bit_cmp_fns) static Datum leftmostvalue_varbit(void) { return DirectFunctionCall3(varbit_in, CStringGetDatum(""), ObjectIdGetDatum(0), Int32GetDatum(-1)); } static const bool varbit_rhs_is_varlena[] = {true}; static const PGFunction varbit_cmp_fns[] = {bitcmp}; GIN_SUPPORT(varbit, leftmostvalue_varbit, varbit_rhs_is_varlena, NULL, varbit_cmp_fns) /* * Numeric type hasn't a real left-most value, so we use PointerGetDatum(NULL) * (*not* a SQL NULL) to represent that. We can get away with that because * the value returned by our leftmostvalue function will never be stored in * the index nor passed to anything except our compare and prefix-comparison * functions. The same trick could be used for other pass-by-reference types. */ #define NUMERIC_IS_LEFTMOST(x) ((x) == NULL) PG_FUNCTION_INFO_V1(gin_numeric_cmp); Datum gin_numeric_cmp(PG_FUNCTION_ARGS) { Numeric a = (Numeric) PG_GETARG_POINTER(0); Numeric b = (Numeric) PG_GETARG_POINTER(1); int res = 0; if (NUMERIC_IS_LEFTMOST(a)) { res = (NUMERIC_IS_LEFTMOST(b)) ? 0 : -1; } else if (NUMERIC_IS_LEFTMOST(b)) { res = 1; } else { res = DatumGetInt32(DirectFunctionCall2(numeric_cmp, NumericGetDatum(a), NumericGetDatum(b))); } PG_RETURN_INT32(res); } static Datum leftmostvalue_numeric(void) { return PointerGetDatum(NULL); } static const bool numeric_rhs_is_varlena[] = {true}; static const PGFunction numeric_cmp_fns[] = {gin_numeric_cmp}; GIN_SUPPORT(numeric, leftmostvalue_numeric, numeric_rhs_is_varlena, NULL, numeric_cmp_fns) /* * Use a similar trick to that used for numeric for enums, since we don't * actually know the leftmost value of any enum without knowing the concrete * type, so we use a dummy leftmost value of InvalidOid. * * Note that we use CallerFInfoFunctionCall2 here so that enum_cmp * gets a valid fn_extra to work with. Unlike most other type comparison * routines it needs it, so we can't use DirectFunctionCall2. */ #define ENUM_IS_LEFTMOST(x) ((x) == InvalidOid) PG_FUNCTION_INFO_V1(gin_enum_cmp); Datum gin_enum_cmp(PG_FUNCTION_ARGS) { Oid a = PG_GETARG_OID(0); Oid b = PG_GETARG_OID(1); int res = 0; if (ENUM_IS_LEFTMOST(a)) { res = (ENUM_IS_LEFTMOST(b)) ? 0 : -1; } else if (ENUM_IS_LEFTMOST(b)) { res = 1; } else { res = DatumGetInt32(CallerFInfoFunctionCall2(enum_cmp, fcinfo->flinfo, PG_GET_COLLATION(), ObjectIdGetDatum(a), ObjectIdGetDatum(b))); } PG_RETURN_INT32(res); } static Datum leftmostvalue_enum(void) { return ObjectIdGetDatum(InvalidOid); } static const bool enum_rhs_is_varlena[] = {false}; static const PGFunction enum_cmp_fns[] = {gin_enum_cmp}; GIN_SUPPORT(anyenum, leftmostvalue_enum, enum_rhs_is_varlena, NULL, enum_cmp_fns) static Datum leftmostvalue_uuid(void) { /* * palloc0 will create the UUID with all zeroes: * "00000000-0000-0000-0000-000000000000" */ pg_uuid_t *retval = palloc0_object(pg_uuid_t); return UUIDPGetDatum(retval); } static const bool uuid_rhs_is_varlena[] = {false}; static const PGFunction uuid_cmp_fns[] = {uuid_cmp}; GIN_SUPPORT(uuid, leftmostvalue_uuid, uuid_rhs_is_varlena, NULL, uuid_cmp_fns) static Datum leftmostvalue_name(void) { NameData *result = (NameData *) palloc0(NAMEDATALEN); return NameGetDatum(result); } static Datum cvt_text_name(Datum input) { text *val = DatumGetTextPP(input); NameData *result = (NameData *) palloc0(NAMEDATALEN); int len = VARSIZE_ANY_EXHDR(val); /* * Truncate oversize input. We're assuming this will produce a result * considered less than the original. That could be a bad assumption in * some collations, but fortunately an index on "name" is generally going * to use C collation. */ if (len >= NAMEDATALEN) len = pg_mbcliplen(VARDATA_ANY(val), len, NAMEDATALEN - 1); memcpy(NameStr(*result), VARDATA_ANY(val), len); return NameGetDatum(result); } static const bool name_rhs_is_varlena[] = {false, true}; static const btree_gin_convert_function name_cvt_fns[] = {NULL, cvt_text_name}; static const PGFunction name_cmp_fns[] = {btnamecmp, bttextnamecmp}; GIN_SUPPORT(name, leftmostvalue_name, name_rhs_is_varlena, name_cvt_fns, name_cmp_fns) static Datum leftmostvalue_bool(void) { return BoolGetDatum(false); } static const bool bool_rhs_is_varlena[] = {false}; static const PGFunction bool_cmp_fns[] = {btboolcmp}; GIN_SUPPORT(bool, leftmostvalue_bool, bool_rhs_is_varlena, NULL, bool_cmp_fns)