/*------------------------------------------------------------------------- * * datum.c * POSTGRES Datum (abstract data type) manipulation routines. * * Portions Copyright (c) 1996-2021, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * src/backend/utils/adt/datum.c * *------------------------------------------------------------------------- */ /* * In the implementation of these routines we assume the following: * * A) if a type is "byVal" then all the information is stored in the * Datum itself (i.e. no pointers involved!). In this case the * length of the type is always greater than zero and not more than * "sizeof(Datum)" * * B) if a type is not "byVal" and it has a fixed length (typlen > 0), * then the "Datum" always contains a pointer to a stream of bytes. * The number of significant bytes are always equal to the typlen. * * C) if a type is not "byVal" and has typlen == -1, * then the "Datum" always points to a "struct varlena". * This varlena structure has information about the actual length of this * particular instance of the type and about its value. * * D) if a type is not "byVal" and has typlen == -2, * then the "Datum" always points to a null-terminated C string. * * Note that we do not treat "toasted" datums specially; therefore what * will be copied or compared is the compressed data or toast reference. * An exception is made for datumCopy() of an expanded object, however, * because most callers expect to get a simple contiguous (and pfree'able) * result from datumCopy(). See also datumTransfer(). */ #include "postgres.h" #include "access/detoast.h" #include "common/hashfn.h" #include "fmgr.h" #include "utils/builtins.h" #include "utils/datum.h" #include "utils/expandeddatum.h" /*------------------------------------------------------------------------- * datumGetSize * * Find the "real" size of a datum, given the datum value, * whether it is a "by value", and the declared type length. * (For TOAST pointer datums, this is the size of the pointer datum.) * * This is essentially an out-of-line version of the att_addlength_datum() * macro in access/tupmacs.h. We do a tad more error checking though. *------------------------------------------------------------------------- */ Size datumGetSize(Datum value, bool typByVal, int typLen) { Size size; if (typByVal) { /* Pass-by-value types are always fixed-length */ Assert(typLen > 0 && typLen <= sizeof(Datum)); size = (Size) typLen; } else { if (typLen > 0) { /* Fixed-length pass-by-ref type */ size = (Size) typLen; } else if (typLen == -1) { /* It is a varlena datatype */ struct varlena *s = (struct varlena *) DatumGetPointer(value); if (!PointerIsValid(s)) ereport(ERROR, (errcode(ERRCODE_DATA_EXCEPTION), errmsg("invalid Datum pointer"))); size = (Size) VARSIZE_ANY(s); } else if (typLen == -2) { /* It is a cstring datatype */ char *s = (char *) DatumGetPointer(value); if (!PointerIsValid(s)) ereport(ERROR, (errcode(ERRCODE_DATA_EXCEPTION), errmsg("invalid Datum pointer"))); size = (Size) (strlen(s) + 1); } else { elog(ERROR, "invalid typLen: %d", typLen); size = 0; /* keep compiler quiet */ } } return size; } /*------------------------------------------------------------------------- * datumCopy * * Make a copy of a non-NULL datum. * * If the datatype is pass-by-reference, memory is obtained with palloc(). * * If the value is a reference to an expanded object, we flatten into memory * obtained with palloc(). We need to copy because one of the main uses of * this function is to copy a datum out of a transient memory context that's * about to be destroyed, and the expanded object is probably in a child * context that will also go away. Moreover, many callers assume that the * result is a single pfree-able chunk. *------------------------------------------------------------------------- */ Datum datumCopy(Datum value, bool typByVal, int typLen) { Datum res; if (typByVal) res = value; else if (typLen == -1) { /* It is a varlena datatype */ struct varlena *vl = (struct varlena *) DatumGetPointer(value); if (VARATT_IS_EXTERNAL_EXPANDED(vl)) { /* Flatten into the caller's memory context */ ExpandedObjectHeader *eoh = DatumGetEOHP(value); Size resultsize; char *resultptr; resultsize = EOH_get_flat_size(eoh); resultptr = (char *) palloc(resultsize); EOH_flatten_into(eoh, (void *) resultptr, resultsize); res = PointerGetDatum(resultptr); } else { /* Otherwise, just copy the varlena datum verbatim */ Size realSize; char *resultptr; realSize = (Size) VARSIZE_ANY(vl); resultptr = (char *) palloc(realSize); memcpy(resultptr, vl, realSize); res = PointerGetDatum(resultptr); } } else { /* Pass by reference, but not varlena, so not toasted */ Size realSize; char *resultptr; realSize = datumGetSize(value, typByVal, typLen); resultptr = (char *) palloc(realSize); memcpy(resultptr, DatumGetPointer(value), realSize); res = PointerGetDatum(resultptr); } return res; } /*------------------------------------------------------------------------- * datumTransfer * * Transfer a non-NULL datum into the current memory context. * * This is equivalent to datumCopy() except when the datum is a read-write * pointer to an expanded object. In that case we merely reparent the object * into the current context, and return its standard R/W pointer (in case the * given one is a transient pointer of shorter lifespan). *------------------------------------------------------------------------- */ Datum datumTransfer(Datum value, bool typByVal, int typLen) { if (!typByVal && typLen == -1 && VARATT_IS_EXTERNAL_EXPANDED_RW(DatumGetPointer(value))) value = TransferExpandedObject(value, CurrentMemoryContext); else value = datumCopy(value, typByVal, typLen); return value; } /*------------------------------------------------------------------------- * datumIsEqual * * Return true if two datums are equal, false otherwise * * NOTE: XXX! * We just compare the bytes of the two values, one by one. * This routine will return false if there are 2 different * representations of the same value (something along the lines * of say the representation of zero in one's complement arithmetic). * Also, it will probably not give the answer you want if either * datum has been "toasted". * * Do not try to make this any smarter than it currently is with respect * to "toasted" datums, because some of the callers could be working in the * context of an aborted transaction. *------------------------------------------------------------------------- */ bool datumIsEqual(Datum value1, Datum value2, bool typByVal, int typLen) { bool res; if (typByVal) { /* * just compare the two datums. NOTE: just comparing "len" bytes will * not do the work, because we do not know how these bytes are aligned * inside the "Datum". We assume instead that any given datatype is * consistent about how it fills extraneous bits in the Datum. */ res = (value1 == value2); } else { Size size1, size2; char *s1, *s2; /* * Compare the bytes pointed by the pointers stored in the datums. */ size1 = datumGetSize(value1, typByVal, typLen); size2 = datumGetSize(value2, typByVal, typLen); if (size1 != size2) return false; s1 = (char *) DatumGetPointer(value1); s2 = (char *) DatumGetPointer(value2); res = (memcmp(s1, s2, size1) == 0); } return res; } /*------------------------------------------------------------------------- * datum_image_eq * * Compares two datums for identical contents, based on byte images. Return * true if the two datums are equal, false otherwise. *------------------------------------------------------------------------- */ bool datum_image_eq(Datum value1, Datum value2, bool typByVal, int typLen) { Size len1, len2; bool result = true; if (typByVal) { result = (value1 == value2); } else if (typLen > 0) { result = (memcmp(DatumGetPointer(value1), DatumGetPointer(value2), typLen) == 0); } else if (typLen == -1) { len1 = toast_raw_datum_size(value1); len2 = toast_raw_datum_size(value2); /* No need to de-toast if lengths don't match. */ if (len1 != len2) result = false; else { struct varlena *arg1val; struct varlena *arg2val; arg1val = PG_DETOAST_DATUM_PACKED(value1); arg2val = PG_DETOAST_DATUM_PACKED(value2); result = (memcmp(VARDATA_ANY(arg1val), VARDATA_ANY(arg2val), len1 - VARHDRSZ) == 0); /* Only free memory if it's a copy made here. */ if ((Pointer) arg1val != (Pointer) value1) pfree(arg1val); if ((Pointer) arg2val != (Pointer) value2) pfree(arg2val); } } else if (typLen == -2) { char *s1, *s2; /* Compare cstring datums */ s1 = DatumGetCString(value1); s2 = DatumGetCString(value2); len1 = strlen(s1) + 1; len2 = strlen(s2) + 1; if (len1 != len2) return false; result = (memcmp(s1, s2, len1) == 0); } else elog(ERROR, "unexpected typLen: %d", typLen); return result; } /*------------------------------------------------------------------------- * datum_image_hash * * Generate a hash value based on the binary representation of 'value'. Most * use cases will want to use the hash function specific to the Datum's type, * however, some corner cases require generating a hash value based on the * actual bits rather than the logical value. *------------------------------------------------------------------------- */ uint32 datum_image_hash(Datum value, bool typByVal, int typLen) { Size len; uint32 result; if (typByVal) result = hash_bytes((unsigned char *) &value, sizeof(Datum)); else if (typLen > 0) result = hash_bytes((unsigned char *) DatumGetPointer(value), typLen); else if (typLen == -1) { struct varlena *val; len = toast_raw_datum_size(value); val = PG_DETOAST_DATUM_PACKED(value); result = hash_bytes((unsigned char *) VARDATA_ANY(val), len - VARHDRSZ); /* Only free memory if it's a copy made here. */ if ((Pointer) val != (Pointer) value) pfree(val); } else if (typLen == -2) { char *s; s = DatumGetCString(value); len = strlen(s) + 1; result = hash_bytes((unsigned char *) s, len); } else { elog(ERROR, "unexpected typLen: %d", typLen); result = 0; /* keep compiler quiet */ } return result; } /*------------------------------------------------------------------------- * btequalimage * * Generic "equalimage" support function. * * B-Tree operator classes whose equality function could safely be replaced by * datum_image_eq() in all cases can use this as their "equalimage" support * function. * * Currently, we unconditionally assume that any B-Tree operator class that * registers btequalimage as its support function 4 must be able to safely use * optimizations like deduplication (i.e. we return true unconditionally). If * it ever proved necessary to rescind support for an operator class, we could * do that in a targeted fashion by doing something with the opcintype * argument. *------------------------------------------------------------------------- */ Datum btequalimage(PG_FUNCTION_ARGS) { /* Oid opcintype = PG_GETARG_OID(0); */ PG_RETURN_BOOL(true); } /*------------------------------------------------------------------------- * datumEstimateSpace * * Compute the amount of space that datumSerialize will require for a * particular Datum. *------------------------------------------------------------------------- */ Size datumEstimateSpace(Datum value, bool isnull, bool typByVal, int typLen) { Size sz = sizeof(int); if (!isnull) { /* no need to use add_size, can't overflow */ if (typByVal) sz += sizeof(Datum); else if (typLen == -1 && VARATT_IS_EXTERNAL_EXPANDED(DatumGetPointer(value))) { /* Expanded objects need to be flattened, see comment below */ sz += EOH_get_flat_size(DatumGetEOHP(value)); } else sz += datumGetSize(value, typByVal, typLen); } return sz; } /*------------------------------------------------------------------------- * datumSerialize * * Serialize a possibly-NULL datum into caller-provided storage. * * Note: "expanded" objects are flattened so as to produce a self-contained * representation, but other sorts of toast pointers are transferred as-is. * This is because the intended use of this function is to pass the value * to another process within the same database server. The other process * could not access an "expanded" object within this process's memory, but * we assume it can dereference the same TOAST pointers this one can. * * The format is as follows: first, we write a 4-byte header word, which * is either the length of a pass-by-reference datum, -1 for a * pass-by-value datum, or -2 for a NULL. If the value is NULL, nothing * further is written. If it is pass-by-value, sizeof(Datum) bytes * follow. Otherwise, the number of bytes indicated by the header word * follow. The caller is responsible for ensuring that there is enough * storage to store the number of bytes that will be written; use * datumEstimateSpace() to find out how many will be needed. * *start_address is updated to point to the byte immediately following * those written. *------------------------------------------------------------------------- */ void datumSerialize(Datum value, bool isnull, bool typByVal, int typLen, char **start_address) { ExpandedObjectHeader *eoh = NULL; int header; /* Write header word. */ if (isnull) header = -2; else if (typByVal) header = -1; else if (typLen == -1 && VARATT_IS_EXTERNAL_EXPANDED(DatumGetPointer(value))) { eoh = DatumGetEOHP(value); header = EOH_get_flat_size(eoh); } else header = datumGetSize(value, typByVal, typLen); memcpy(*start_address, &header, sizeof(int)); *start_address += sizeof(int); /* If not null, write payload bytes. */ if (!isnull) { if (typByVal) { memcpy(*start_address, &value, sizeof(Datum)); *start_address += sizeof(Datum); } else if (eoh) { char *tmp; /* * EOH_flatten_into expects the target address to be maxaligned, * so we can't store directly to *start_address. */ tmp = (char *) palloc(header); EOH_flatten_into(eoh, (void *) tmp, header); memcpy(*start_address, tmp, header); *start_address += header; /* be tidy. */ pfree(tmp); } else { memcpy(*start_address, DatumGetPointer(value), header); *start_address += header; } } } /*------------------------------------------------------------------------- * datumRestore * * Restore a possibly-NULL datum previously serialized by datumSerialize. * *start_address is updated according to the number of bytes consumed. *------------------------------------------------------------------------- */ Datum datumRestore(char **start_address, bool *isnull) { int header; void *d; /* Read header word. */ memcpy(&header, *start_address, sizeof(int)); *start_address += sizeof(int); /* If this datum is NULL, we can stop here. */ if (header == -2) { *isnull = true; return (Datum) 0; } /* OK, datum is not null. */ *isnull = false; /* If this datum is pass-by-value, sizeof(Datum) bytes follow. */ if (header == -1) { Datum val; memcpy(&val, *start_address, sizeof(Datum)); *start_address += sizeof(Datum); return val; } /* Pass-by-reference case; copy indicated number of bytes. */ Assert(header > 0); d = palloc(header); memcpy(d, *start_address, header); *start_address += header; return PointerGetDatum(d); }