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/*------------------------------------------------------------------------- * * expandeddatum.h * Declarations for access to "expanded" value representations. * * Complex data types, particularly container types such as arrays and * records, usually have on-disk representations that are compact but not * especially convenient to modify. What's more, when we do modify them, * having to recopy all the rest of the value can be extremely inefficient. * Therefore, we provide a notion of an "expanded" representation that is used * only in memory and is optimized more for computation than storage. * The format appearing on disk is called the data type's "flattened" * representation, since it is required to be a contiguous blob of bytes -- * but the type can have an expanded representation that is not. Data types * must provide means to translate an expanded representation back to * flattened form. * * An expanded object is meant to survive across multiple operations, but * not to be enormously long-lived; for example it might be a local variable * in a PL/pgSQL procedure. So its extra bulk compared to the on-disk format * is a worthwhile trade-off. * * References to expanded objects are a type of TOAST pointer. * Because of longstanding conventions in Postgres, this means that the * flattened form of such an object must always be a varlena object. * Fortunately that's no restriction in practice. * * There are actually two kinds of TOAST pointers for expanded objects: * read-only and read-write pointers. Possession of one of the latter * authorizes a function to modify the value in-place rather than copying it * as would normally be required. Functions should always return a read-write * pointer to any new expanded object they create. Functions that modify an * argument value in-place must take care that they do not corrupt the old * value if they fail partway through. * * * Portions Copyright (c) 1996-2016, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * src/include/utils/expandeddatum.h * *------------------------------------------------------------------------- */ #ifndef EXPANDEDDATUM_H #define EXPANDEDDATUM_H /* Size of an EXTERNAL datum that contains a pointer to an expanded object */ #define EXPANDED_POINTER_SIZE (VARHDRSZ_EXTERNAL + sizeof(varatt_expanded)) /* * "Methods" that must be provided for any expanded object. * * get_flat_size: compute space needed for flattened representation (total, * including header). * * flatten_into: construct flattened representation in the caller-allocated * space at *result, of size allocated_size (which will always be the result * of a preceding get_flat_size call; it's passed for cross-checking). * * The flattened representation must be a valid in-line, non-compressed, * 4-byte-header varlena object. * * Note: construction of a heap tuple from an expanded datum calls * get_flat_size twice, so it's worthwhile to make sure that that doesn't * incur too much overhead. */ typedef Size (*EOM_get_flat_size_method) (ExpandedObjectHeader *eohptr); typedef void (*EOM_flatten_into_method) (ExpandedObjectHeader *eohptr, void *result, Size allocated_size); /* Struct of function pointers for an expanded object's methods */ typedef struct ExpandedObjectMethods { EOM_get_flat_size_method get_flat_size; EOM_flatten_into_method flatten_into; } ExpandedObjectMethods; /* * Every expanded object must contain this header; typically the header * is embedded in some larger struct that adds type-specific fields. * * It is presumed that the header object and all subsidiary data are stored * in eoh_context, so that the object can be freed by deleting that context, * or its storage lifespan can be altered by reparenting the context. * (In principle the object could own additional resources, such as malloc'd * storage, and use a memory context reset callback to free them upon reset or * deletion of eoh_context.) * * We set up two TOAST pointers within the standard header, one read-write * and one read-only. This allows functions to return either kind of pointer * without making an additional allocation, and in particular without worrying * whether a separately palloc'd object would have sufficient lifespan. * But note that these pointers are just a convenience; a pointer object * appearing somewhere else would still be legal. * * The typedef declaration for this appears in postgres.h. */ struct ExpandedObjectHeader { /* Phony varlena header */ int32 vl_len_; /* always EOH_HEADER_MAGIC, see below */ /* Pointer to methods required for object type */ const ExpandedObjectMethods *eoh_methods; /* Memory context containing this header and subsidiary data */ MemoryContext eoh_context; /* Standard R/W TOAST pointer for this object is kept here */ char eoh_rw_ptr[EXPANDED_POINTER_SIZE]; /* Standard R/O TOAST pointer for this object is kept here */ char eoh_ro_ptr[EXPANDED_POINTER_SIZE]; }; /* * Particularly for read-only functions, it is handy to be able to work with * either regular "flat" varlena inputs or expanded inputs of the same data * type. To allow determining which case an argument-fetching function has * returned, the first int32 of an ExpandedObjectHeader always contains -1 * (EOH_HEADER_MAGIC to the code). This works since no 4-byte-header varlena * could have that as its first 4 bytes. Caution: we could not reliably tell * the difference between an ExpandedObjectHeader and a short-header object * with this trick. However, it works fine if the argument fetching code * always returns either a 4-byte-header flat object or an expanded object. */ #define EOH_HEADER_MAGIC (-1) #define VARATT_IS_EXPANDED_HEADER(PTR) \ (((varattrib_4b *) (PTR))->va_4byte.va_header == EOH_HEADER_MAGIC) /* * Generic support functions for expanded objects. * (More of these might be worth inlining later.) */ #define EOHPGetRWDatum(eohptr) PointerGetDatum((eohptr)->eoh_rw_ptr) #define EOHPGetRODatum(eohptr) PointerGetDatum((eohptr)->eoh_ro_ptr) /* Does the Datum represent a writable expanded object? */ #define DatumIsReadWriteExpandedObject(d, isnull, typlen) \ (((isnull) || (typlen) != -1) ? false : \ VARATT_IS_EXTERNAL_EXPANDED_RW(DatumGetPointer(d))) #define MakeExpandedObjectReadOnly(d, isnull, typlen) \ (((isnull) || (typlen) != -1) ? (d) : \ MakeExpandedObjectReadOnlyInternal(d)) extern ExpandedObjectHeader *DatumGetEOHP(Datum d); extern void EOH_init_header(ExpandedObjectHeader *eohptr, const ExpandedObjectMethods *methods, MemoryContext obj_context); extern Size EOH_get_flat_size(ExpandedObjectHeader *eohptr); extern void EOH_flatten_into(ExpandedObjectHeader *eohptr, void *result, Size allocated_size); extern Datum MakeExpandedObjectReadOnlyInternal(Datum d); extern Datum TransferExpandedObject(Datum d, MemoryContext new_parent); extern void DeleteExpandedObject(Datum d); #endif /* EXPANDEDDATUM_H */