plpy__typeio_8c_source.html

 /*

  * transforming Datums to Python objects and vice versa

  *

  * src/pl/plpython/plpy_typeio.c

  */


 #include "postgres.h"


 #include "access/htup_details.h"

 #include "access/transam.h"

 #include "catalog/pg_type.h"

 #include "funcapi.h"

 #include "mb/pg_wchar.h"

 #include "parser/parse_type.h"

 #include "utils/array.h"

 #include "utils/builtins.h"

 #include "utils/fmgroids.h"

 #include "utils/lsyscache.h"

 #include "utils/memutils.h"

 #include "utils/numeric.h"

 #include "utils/syscache.h"

 #include "utils/typcache.h"


 #include "plpython.h"


 #include "plpy_typeio.h"


 #include "plpy_elog.h"

 #include "plpy_main.h"


 /* I/O function caching */

 static void PLy_input_datum_func2(PLyDatumToOb *arg, MemoryContext arg_mcxt, Oid typeOid, HeapTuple typeTup, Oid langid, List *trftypes);

 static void PLy_output_datum_func2(PLyObToDatum *arg, MemoryContext arg_mcxt, HeapTuple typeTup, Oid langid, List *trftypes);


 /* conversion from Datums to Python objects */

 static PyObject *PLyBool_FromBool(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyFloat_FromFloat4(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyFloat_FromFloat8(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyDecimal_FromNumeric(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyInt_FromInt16(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyInt_FromInt32(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyLong_FromInt64(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyLong_FromOid(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyBytes_FromBytea(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyString_FromDatum(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyObject_FromTransform(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyList_FromArray(PLyDatumToOb *arg, Datum d);

 static PyObject *PLyList_FromArray_recurse(PLyDatumToOb *elm, int *dims, int ndim, int dim,

                           char **dataptr_p, bits8 **bitmap_p, int *bitmask_p);


 /* conversion from Python objects to Datums */

 static Datum PLyObject_ToBool(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray);

 static Datum PLyObject_ToBytea(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray);

 static Datum PLyObject_ToComposite(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray);

 static Datum PLyObject_ToDatum(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray);

 static Datum PLyObject_ToTransform(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray);

 static Datum PLySequence_ToArray(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray);

 static void PLySequence_ToArray_recurse(PLyObToDatum *elm, PyObject *list,

                             int *dims, int ndim, int dim,

                             Datum *elems, bool *nulls, int *currelem);


 /* conversion from Python objects to composite Datums (used by triggers and SRFs) */

 static Datum PLyString_ToComposite(PLyTypeInfo *info, TupleDesc desc, PyObject *string, bool inarray);

 static Datum PLyMapping_ToComposite(PLyTypeInfo *info, TupleDesc desc, PyObject *mapping);

 static Datum PLySequence_ToComposite(PLyTypeInfo *info, TupleDesc desc, PyObject *sequence);

 static Datum PLyGenericObject_ToComposite(PLyTypeInfo *info, TupleDesc desc, PyObject *object, bool inarray);


 void

 PLy_typeinfo_init(PLyTypeInfo *arg, MemoryContext mcxt)

 {

     arg->is_rowtype = -1;

     arg->in.r.natts = arg->out.r.natts = 0;

     arg->in.r.atts = NULL;

     arg->out.r.atts = NULL;

     arg->typ_relid = InvalidOid;

     arg->typrel_xmin = InvalidTransactionId;

     ItemPointerSetInvalid(&arg->typrel_tid);

     arg->mcxt = mcxt;

 }


 /*

  * Conversion functions.  Remember output from Python is input to

  * PostgreSQL, and vice versa.

  */

 void

 PLy_input_datum_func(PLyTypeInfo *arg, Oid typeOid, HeapTuple typeTup, Oid langid, List *trftypes)

 {

     if (arg->is_rowtype > 0)

         elog(ERROR, "PLyTypeInfo struct is initialized for Tuple");

     arg->is_rowtype = 0;

     PLy_input_datum_func2(&(arg->in.d), arg->mcxt, typeOid, typeTup, langid, trftypes);

 }


 void

 PLy_output_datum_func(PLyTypeInfo *arg, HeapTuple typeTup, Oid langid, List *trftypes)

 {

     if (arg->is_rowtype > 0)

         elog(ERROR, "PLyTypeInfo struct is initialized for a Tuple");

     arg->is_rowtype = 0;

     PLy_output_datum_func2(&(arg->out.d), arg->mcxt, typeTup, langid, trftypes);

 }


 void

 PLy_input_tuple_funcs(PLyTypeInfo *arg, TupleDesc desc)

 {

     int         i;

     PLyExecutionContext *exec_ctx = PLy_current_execution_context();

     MemoryContext oldcxt;


     oldcxt = MemoryContextSwitchTo(arg->mcxt);


     if (arg->is_rowtype == 0)

         elog(ERROR, "PLyTypeInfo struct is initialized for a Datum");

     arg->is_rowtype = 1;


     if (arg->in.r.natts != desc->natts)

     {

         if (arg->in.r.atts)

             pfree(arg->in.r.atts);

         arg->in.r.natts = desc->natts;

         arg->in.r.atts = palloc0(desc->natts * sizeof(PLyDatumToOb));

     }


     /* Can this be an unnamed tuple? If not, then an Assert would be enough */

     if (desc->tdtypmod != -1)

         elog(ERROR, "received unnamed record type as input");


     Assert(OidIsValid(desc->tdtypeid));


     /*

      * RECORDOID means we got called to create input functions for a tuple

      * fetched by plpy.execute or for an anonymous record type

      */

     if (desc->tdtypeid != RECORDOID)

     {

         HeapTuple   relTup;


         /* Get the pg_class tuple corresponding to the type of the input */

         arg->typ_relid = typeidTypeRelid(desc->tdtypeid);

         relTup = SearchSysCache1(RELOID, ObjectIdGetDatum(arg->typ_relid));

         if (!HeapTupleIsValid(relTup))

             elog(ERROR, "cache lookup failed for relation %u", arg->typ_relid);


         /* Remember XMIN and TID for later validation if cache is still OK */

         arg->typrel_xmin = HeapTupleHeaderGetRawXmin(relTup->t_data);

         arg->typrel_tid = relTup->t_self;


         ReleaseSysCache(relTup);

     }


     for (i = 0; i < desc->natts; i++)

     {

         HeapTuple   typeTup;

         Form_pg_attribute attr = TupleDescAttr(desc, i);


         if (attr->attisdropped)

             continue;


         if (arg->in.r.atts[i].typoid == attr->atttypid)

             continue;           /* already set up this entry */


         typeTup = SearchSysCache1(TYPEOID, ObjectIdGetDatum(attr->atttypid));

         if (!HeapTupleIsValid(typeTup))

             elog(ERROR, "cache lookup failed for type %u",

                  attr->atttypid);


         PLy_input_datum_func2(&(arg->in.r.atts[i]), arg->mcxt,

                               attr->atttypid,

                               typeTup,

                               exec_ctx->curr_proc->langid,

                               exec_ctx->curr_proc->trftypes);


         ReleaseSysCache(typeTup);

     }


     MemoryContextSwitchTo(oldcxt);

 }


 void

 PLy_output_tuple_funcs(PLyTypeInfo *arg, TupleDesc desc)

 {

     int         i;

     PLyExecutionContext *exec_ctx = PLy_current_execution_context();

     MemoryContext oldcxt;


     oldcxt = MemoryContextSwitchTo(arg->mcxt);


     if (arg->is_rowtype == 0)

         elog(ERROR, "PLyTypeInfo struct is initialized for a Datum");

     arg->is_rowtype = 1;


     if (arg->out.r.natts != desc->natts)

     {

         if (arg->out.r.atts)

             pfree(arg->out.r.atts);

         arg->out.r.natts = desc->natts;

         arg->out.r.atts = palloc0(desc->natts * sizeof(PLyObToDatum));

     }


     Assert(OidIsValid(desc->tdtypeid));


     /*

      * RECORDOID means we got called to create output functions for an

      * anonymous record type

      */

     if (desc->tdtypeid != RECORDOID)

     {

         HeapTuple   relTup;


         /* Get the pg_class tuple corresponding to the type of the output */

         arg->typ_relid = typeidTypeRelid(desc->tdtypeid);

         relTup = SearchSysCache1(RELOID, ObjectIdGetDatum(arg->typ_relid));

         if (!HeapTupleIsValid(relTup))

             elog(ERROR, "cache lookup failed for relation %u", arg->typ_relid);


         /* Remember XMIN and TID for later validation if cache is still OK */

         arg->typrel_xmin = HeapTupleHeaderGetRawXmin(relTup->t_data);

         arg->typrel_tid = relTup->t_self;


         ReleaseSysCache(relTup);

     }


     for (i = 0; i < desc->natts; i++)

     {

         HeapTuple   typeTup;

         Form_pg_attribute attr = TupleDescAttr(desc, i);


         if (attr->attisdropped)

             continue;


         if (arg->out.r.atts[i].typoid == attr->atttypid)

             continue;           /* already set up this entry */


         typeTup = SearchSysCache1(TYPEOID, ObjectIdGetDatum(attr->atttypid));

         if (!HeapTupleIsValid(typeTup))

             elog(ERROR, "cache lookup failed for type %u",

                  attr->atttypid);


         PLy_output_datum_func2(&(arg->out.r.atts[i]), arg->mcxt, typeTup,

                                exec_ctx->curr_proc->langid,

                                exec_ctx->curr_proc->trftypes);


         ReleaseSysCache(typeTup);

     }


     MemoryContextSwitchTo(oldcxt);

 }


 void

 PLy_output_record_funcs(PLyTypeInfo *arg, TupleDesc desc)

 {

     /*

      * If the output record functions are already set, we just have to check

      * if the record descriptor has not changed

      */

     if ((arg->is_rowtype == 1) &&

         (arg->out.d.typmod != -1) &&

         (arg->out.d.typmod == desc->tdtypmod))

         return;


     /* bless the record to make it known to the typcache lookup code */

     BlessTupleDesc(desc);

     /* save the freshly generated typmod */

     arg->out.d.typmod = desc->tdtypmod;

     /* proceed with normal I/O function caching */

     PLy_output_tuple_funcs(arg, desc);


     /*

      * it should change is_rowtype to 1, so we won't go through this again

      * unless the output record description changes

      */

     Assert(arg->is_rowtype == 1);

 }


 /*

  * Transform a tuple into a Python dict object.

  */

 PyObject *

 PLyDict_FromTuple(PLyTypeInfo *info, HeapTuple tuple, TupleDesc desc)

 {

     PyObject   *volatile dict;

     PLyExecutionContext *exec_ctx = PLy_current_execution_context();

     MemoryContext scratch_context = PLy_get_scratch_context(exec_ctx);

     MemoryContext oldcontext = CurrentMemoryContext;


     if (info->is_rowtype != 1)

         elog(ERROR, "PLyTypeInfo structure describes a datum");


     dict = PyDict_New();

     if (dict == NULL)

         PLy_elog(ERROR, "could not create new dictionary");


     PG_TRY();

     {

         int         i;


         /*

          * Do the work in the scratch context to avoid leaking memory from the

          * datatype output function calls.

          */

         MemoryContextSwitchTo(scratch_context);

         for (i = 0; i < info->in.r.natts; i++)

         {

             char       *key;

             Datum       vattr;

             bool        is_null;

             PyObject   *value;

             Form_pg_attribute attr = TupleDescAttr(desc, i);


             if (attr->attisdropped)

                 continue;


             key = NameStr(attr->attname);

             vattr = heap_getattr(tuple, (i + 1), desc, &is_null);


             if (is_null || info->in.r.atts[i].func == NULL)

                 PyDict_SetItemString(dict, key, Py_None);

             else

             {

                 value = (info->in.r.atts[i].func) (&info->in.r.atts[i], vattr);

                 PyDict_SetItemString(dict, key, value);

                 Py_DECREF(value);

             }

         }

         MemoryContextSwitchTo(oldcontext);

         MemoryContextReset(scratch_context);

     }

     PG_CATCH();

     {

         MemoryContextSwitchTo(oldcontext);

         Py_DECREF(dict);

         PG_RE_THROW();

     }

     PG_END_TRY();


     return dict;

 }


 /*

  *  Convert a Python object to a composite Datum, using all supported

  *  conversion methods: composite as a string, as a sequence, as a mapping or

  *  as an object that has __getattr__ support.

  */

 Datum

 PLyObject_ToCompositeDatum(PLyTypeInfo *info, TupleDesc desc, PyObject *plrv, bool inarray)

 {

     Datum       datum;


     if (PyString_Check(plrv) || PyUnicode_Check(plrv))

         datum = PLyString_ToComposite(info, desc, plrv, inarray);

     else if (PySequence_Check(plrv))

         /* composite type as sequence (tuple, list etc) */

         datum = PLySequence_ToComposite(info, desc, plrv);

     else if (PyMapping_Check(plrv))

         /* composite type as mapping (currently only dict) */

         datum = PLyMapping_ToComposite(info, desc, plrv);

     else

         /* returned as smth, must provide method __getattr__(name) */

         datum = PLyGenericObject_ToComposite(info, desc, plrv, inarray);


     return datum;

 }


 static void

 PLy_output_datum_func2(PLyObToDatum *arg, MemoryContext arg_mcxt, HeapTuple typeTup, Oid langid, List *trftypes)

 {

     Form_pg_type typeStruct = (Form_pg_type) GETSTRUCT(typeTup);

     Oid         element_type;

     Oid         base_type;

     Oid         funcid;

     MemoryContext oldcxt;


     oldcxt = MemoryContextSwitchTo(arg_mcxt);


     fmgr_info_cxt(typeStruct->typinput, &arg->typfunc, arg_mcxt);

     arg->typoid = HeapTupleGetOid(typeTup);

     arg->typmod = -1;

     arg->typioparam = getTypeIOParam(typeTup);

     arg->typbyval = typeStruct->typbyval;


     element_type = get_base_element_type(arg->typoid);

     base_type = getBaseType(element_type ? element_type : arg->typoid);


     /*

      * Select a conversion function to convert Python objects to PostgreSQL

      * datums.

      */


     if ((funcid = get_transform_tosql(base_type, langid, trftypes)))

     {

         arg->func = PLyObject_ToTransform;

         fmgr_info_cxt(funcid, &arg->typtransform, arg_mcxt);

     }

     else if (typeStruct->typtype == TYPTYPE_COMPOSITE)

     {

         arg->func = PLyObject_ToComposite;

     }

     else

         switch (base_type)

         {

             case BOOLOID:

                 arg->func = PLyObject_ToBool;

                 break;

             case BYTEAOID:

                 arg->func = PLyObject_ToBytea;

                 break;

             default:

                 arg->func = PLyObject_ToDatum;

                 break;

         }


     if (element_type)

     {

         char        dummy_delim;

         Oid         funcid;


         if (type_is_rowtype(element_type))

             arg->func = PLyObject_ToComposite;


         arg->elm = palloc0(sizeof(*arg->elm));

         arg->elm->func = arg->func;

         arg->elm->typtransform = arg->typtransform;

         arg->func = PLySequence_ToArray;


         arg->elm->typoid = element_type;

         arg->elm->typmod = -1;

         get_type_io_data(element_type, IOFunc_input,

                          &arg->elm->typlen, &arg->elm->typbyval, &arg->elm->typalign, &dummy_delim,

                          &arg->elm->typioparam, &funcid);

         fmgr_info_cxt(funcid, &arg->elm->typfunc, arg_mcxt);

     }


     MemoryContextSwitchTo(oldcxt);

 }


 static void

 PLy_input_datum_func2(PLyDatumToOb *arg, MemoryContext arg_mcxt, Oid typeOid, HeapTuple typeTup, Oid langid, List *trftypes)

 {

     Form_pg_type typeStruct = (Form_pg_type) GETSTRUCT(typeTup);

     Oid         element_type;

     Oid         base_type;

     Oid         funcid;

     MemoryContext oldcxt;


     oldcxt = MemoryContextSwitchTo(arg_mcxt);


     /* Get the type's conversion information */

     fmgr_info_cxt(typeStruct->typoutput, &arg->typfunc, arg_mcxt);

     arg->typoid = HeapTupleGetOid(typeTup);

     arg->typmod = -1;

     arg->typioparam = getTypeIOParam(typeTup);

     arg->typbyval = typeStruct->typbyval;

     arg->typlen = typeStruct->typlen;

     arg->typalign = typeStruct->typalign;


     /* Determine which kind of Python object we will convert to */


     element_type = get_base_element_type(typeOid);

     base_type = getBaseType(element_type ? element_type : typeOid);


     if ((funcid = get_transform_fromsql(base_type, langid, trftypes)))

     {

         arg->func = PLyObject_FromTransform;

         fmgr_info_cxt(funcid, &arg->typtransform, arg_mcxt);

     }

     else

         switch (base_type)

         {

             case BOOLOID:

                 arg->func = PLyBool_FromBool;

                 break;

             case FLOAT4OID:

                 arg->func = PLyFloat_FromFloat4;

                 break;

             case FLOAT8OID:

                 arg->func = PLyFloat_FromFloat8;

                 break;

             case NUMERICOID:

                 arg->func = PLyDecimal_FromNumeric;

                 break;

             case INT2OID:

                 arg->func = PLyInt_FromInt16;

                 break;

             case INT4OID:

                 arg->func = PLyInt_FromInt32;

                 break;

             case INT8OID:

                 arg->func = PLyLong_FromInt64;

                 break;

             case OIDOID:

                 arg->func = PLyLong_FromOid;

                 break;

             case BYTEAOID:

                 arg->func = PLyBytes_FromBytea;

                 break;

             default:

                 arg->func = PLyString_FromDatum;

                 break;

         }


     if (element_type)

     {

         char        dummy_delim;

         Oid         funcid;


         arg->elm = palloc0(sizeof(*arg->elm));

         arg->elm->func = arg->func;

         arg->elm->typtransform = arg->typtransform;

         arg->func = PLyList_FromArray;

         arg->elm->typoid = element_type;

         arg->elm->typmod = -1;

         get_type_io_data(element_type, IOFunc_output,

                          &arg->elm->typlen, &arg->elm->typbyval, &arg->elm->typalign, &dummy_delim,

                          &arg->elm->typioparam, &funcid);

         fmgr_info_cxt(funcid, &arg->elm->typfunc, arg_mcxt);

     }


     MemoryContextSwitchTo(oldcxt);

 }


 static PyObject *

 PLyBool_FromBool(PLyDatumToOb *arg, Datum d)

 {

     if (DatumGetBool(d))

         Py_RETURN_TRUE;

     Py_RETURN_FALSE;

 }


 static PyObject *

 PLyFloat_FromFloat4(PLyDatumToOb *arg, Datum d)

 {

     return PyFloat_FromDouble(DatumGetFloat4(d));

 }


 static PyObject *

 PLyFloat_FromFloat8(PLyDatumToOb *arg, Datum d)

 {

     return PyFloat_FromDouble(DatumGetFloat8(d));

 }


 static PyObject *

 PLyDecimal_FromNumeric(PLyDatumToOb *arg, Datum d)

 {

     static PyObject *decimal_constructor;

     char       *str;

     PyObject   *pyvalue;


     /* Try to import cdecimal.  If it doesn't exist, fall back to decimal. */

     if (!decimal_constructor)

     {

         PyObject   *decimal_module;


         decimal_module = PyImport_ImportModule("cdecimal");

         if (!decimal_module)

         {

             PyErr_Clear();

             decimal_module = PyImport_ImportModule("decimal");

         }

         if (!decimal_module)

             PLy_elog(ERROR, "could not import a module for Decimal constructor");


         decimal_constructor = PyObject_GetAttrString(decimal_module, "Decimal");

         if (!decimal_constructor)

             PLy_elog(ERROR, "no Decimal attribute in module");

     }


     str = DatumGetCString(DirectFunctionCall1(numeric_out, d));

     pyvalue = PyObject_CallFunction(decimal_constructor, "s", str);

     if (!pyvalue)

         PLy_elog(ERROR, "conversion from numeric to Decimal failed");


     return pyvalue;

 }


 static PyObject *

 PLyInt_FromInt16(PLyDatumToOb *arg, Datum d)

 {

     return PyInt_FromLong(DatumGetInt16(d));

 }


 static PyObject *

 PLyInt_FromInt32(PLyDatumToOb *arg, Datum d)

 {

     return PyInt_FromLong(DatumGetInt32(d));

 }


 static PyObject *

 PLyLong_FromInt64(PLyDatumToOb *arg, Datum d)

 {

     /* on 32 bit platforms "long" may be too small */

     if (sizeof(int64) > sizeof(long))

         return PyLong_FromLongLong(DatumGetInt64(d));

     else

         return PyLong_FromLong(DatumGetInt64(d));

 }


 static PyObject *

 PLyLong_FromOid(PLyDatumToOb *arg, Datum d)

 {

     return PyLong_FromUnsignedLong(DatumGetObjectId(d));

 }


 static PyObject *

 PLyBytes_FromBytea(PLyDatumToOb *arg, Datum d)

 {

     text       *txt = DatumGetByteaPP(d);

     char       *str = VARDATA_ANY(txt);

     size_t      size = VARSIZE_ANY_EXHDR(txt);


     return PyBytes_FromStringAndSize(str, size);

 }


 static PyObject *

 PLyString_FromDatum(PLyDatumToOb *arg, Datum d)

 {

     char       *x = OutputFunctionCall(&arg->typfunc, d);

     PyObject   *r = PyString_FromString(x);


     pfree(x);

     return r;

 }


 static PyObject *

 PLyObject_FromTransform(PLyDatumToOb *arg, Datum d)

 {

     return (PyObject *) DatumGetPointer(FunctionCall1(&arg->typtransform, d));

 }


 static PyObject *

 PLyList_FromArray(PLyDatumToOb *arg, Datum d)

 {

     ArrayType  *array = DatumGetArrayTypeP(d);

     PLyDatumToOb *elm = arg->elm;

     int         ndim;

     int        *dims;

     char       *dataptr;

     bits8      *bitmap;

     int         bitmask;


     if (ARR_NDIM(array) == 0)

         return PyList_New(0);


     /* Array dimensions and left bounds */

     ndim = ARR_NDIM(array);

     dims = ARR_DIMS(array);

     Assert(ndim < MAXDIM);


     /*

      * We iterate the SQL array in the physical order it's stored in the

      * datum. For example, for a 3-dimensional array the order of iteration

      * would be the following: [0,0,0] elements through [0,0,k], then [0,1,0]

      * through [0,1,k] till [0,m,k], then [1,0,0] through [1,0,k] till

      * [1,m,k], and so on.

      *

      * In Python, there are no multi-dimensional lists as such, but they are

      * represented as a list of lists. So a 3-d array of [n,m,k] elements is a

      * list of n m-element arrays, each element of which is k-element array.

      * PLyList_FromArray_recurse() builds the Python list for a single

      * dimension, and recurses for the next inner dimension.

      */

     dataptr = ARR_DATA_PTR(array);

     bitmap = ARR_NULLBITMAP(array);

     bitmask = 1;


     return PLyList_FromArray_recurse(elm, dims, ndim, 0,

                                      &dataptr, &bitmap, &bitmask);

 }


 static PyObject *

 PLyList_FromArray_recurse(PLyDatumToOb *elm, int *dims, int ndim, int dim,

                           char **dataptr_p, bits8 **bitmap_p, int *bitmask_p)

 {

     int         i;

     PyObject   *list;


     list = PyList_New(dims[dim]);


     if (dim < ndim - 1)

     {

         /* Outer dimension. Recurse for each inner slice. */

         for (i = 0; i < dims[dim]; i++)

         {

             PyObject   *sublist;


             sublist = PLyList_FromArray_recurse(elm, dims, ndim, dim + 1,

                                                 dataptr_p, bitmap_p, bitmask_p);

             PyList_SET_ITEM(list, i, sublist);

         }

     }

     else

     {

         /*

          * Innermost dimension. Fill the list with the values from the array

          * for this slice.

          */

         char       *dataptr = *dataptr_p;

         bits8      *bitmap = *bitmap_p;

         int         bitmask = *bitmask_p;


         for (i = 0; i < dims[dim]; i++)

         {

             /* checking for NULL */

             if (bitmap && (*bitmap & bitmask) == 0)

             {

                 Py_INCREF(Py_None);

                 PyList_SET_ITEM(list, i, Py_None);

             }

             else

             {

                 Datum       itemvalue;


                 itemvalue = fetch_att(dataptr, elm->typbyval, elm->typlen);

                 PyList_SET_ITEM(list, i, elm->func(elm, itemvalue));

                 dataptr = att_addlength_pointer(dataptr, elm->typlen, dataptr);

                 dataptr = (char *) att_align_nominal(dataptr, elm->typalign);

             }


             /* advance bitmap pointer if any */

             if (bitmap)

             {

                 bitmask <<= 1;

                 if (bitmask == 0x100 /* (1<<8) */ )

                 {

                     bitmap++;

                     bitmask = 1;

                 }

             }

         }


         *dataptr_p = dataptr;

         *bitmap_p = bitmap;

         *bitmask_p = bitmask;

     }


     return list;

 }


 /*

  * Convert a Python object to a PostgreSQL bool datum.  This can't go

  * through the generic conversion function, because Python attaches a

  * Boolean value to everything, more things than the PostgreSQL bool

  * type can parse.

  */

 static Datum

 PLyObject_ToBool(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray)

 {

     Datum       rv;


     Assert(plrv != Py_None);

     rv = BoolGetDatum(PyObject_IsTrue(plrv));


     if (get_typtype(arg->typoid) == TYPTYPE_DOMAIN)

         domain_check(rv, false, arg->typoid, &arg->typfunc.fn_extra, arg->typfunc.fn_mcxt);


     return rv;

 }


 /*

  * Convert a Python object to a PostgreSQL bytea datum.  This doesn't

  * go through the generic conversion function to circumvent problems

  * with embedded nulls.  And it's faster this way.

  */

 static Datum

 PLyObject_ToBytea(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray)

 {

     PyObject   *volatile plrv_so = NULL;

     Datum       rv;


     Assert(plrv != Py_None);


     plrv_so = PyObject_Bytes(plrv);

     if (!plrv_so)

         PLy_elog(ERROR, "could not create bytes representation of Python object");


     PG_TRY();

     {

         char       *plrv_sc = PyBytes_AsString(plrv_so);

         size_t      len = PyBytes_Size(plrv_so);

         size_t      size = len + VARHDRSZ;

         bytea      *result = palloc(size);


         SET_VARSIZE(result, size);

         memcpy(VARDATA(result), plrv_sc, len);

         rv = PointerGetDatum(result);

     }

     PG_CATCH();

     {

         Py_XDECREF(plrv_so);

         PG_RE_THROW();

     }

     PG_END_TRY();


     Py_XDECREF(plrv_so);


     if (get_typtype(arg->typoid) == TYPTYPE_DOMAIN)

         domain_check(rv, false, arg->typoid, &arg->typfunc.fn_extra, arg->typfunc.fn_mcxt);


     return rv;

 }


 /*

  * Convert a Python object to a composite type. First look up the type's

  * description, then route the Python object through the conversion function

  * for obtaining PostgreSQL tuples.

  */

 static Datum

 PLyObject_ToComposite(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray)

 {

     Datum       rv;

     PLyTypeInfo info;

     TupleDesc   desc;

     MemoryContext cxt;


     if (typmod != -1)

         elog(ERROR, "received unnamed record type as input");


     /* Create a dummy PLyTypeInfo */

     cxt = AllocSetContextCreate(CurrentMemoryContext,

                                 "PL/Python temp context",

                                 ALLOCSET_DEFAULT_SIZES);

     MemSet(&info, 0, sizeof(PLyTypeInfo));

     PLy_typeinfo_init(&info, cxt);

     /* Mark it as needing output routines lookup */

     info.is_rowtype = 2;


     desc = lookup_rowtype_tupdesc(arg->typoid, arg->typmod);


     /*

      * This will set up the dummy PLyTypeInfo's output conversion routines,

      * since we left is_rowtype as 2. A future optimization could be caching

      * that info instead of looking it up every time a tuple is returned from

      * the function.

      */

     rv = PLyObject_ToCompositeDatum(&info, desc, plrv, inarray);


     ReleaseTupleDesc(desc);


     MemoryContextDelete(cxt);


     return rv;

 }


 /*

  * Convert Python object to C string in server encoding.

  */

 char *

 PLyObject_AsString(PyObject *plrv)

 {

     PyObject   *plrv_bo;

     char       *plrv_sc;

     size_t      plen;

     size_t      slen;


     if (PyUnicode_Check(plrv))

         plrv_bo = PLyUnicode_Bytes(plrv);

     else if (PyFloat_Check(plrv))

     {

         /* use repr() for floats, str() is lossy */

 #if PY_MAJOR_VERSION >= 3

         PyObject   *s = PyObject_Repr(plrv);


         plrv_bo = PLyUnicode_Bytes(s);

         Py_XDECREF(s);

 #else

         plrv_bo = PyObject_Repr(plrv);

 #endif

     }

     else

     {

 #if PY_MAJOR_VERSION >= 3

         PyObject   *s = PyObject_Str(plrv);


         plrv_bo = PLyUnicode_Bytes(s);

         Py_XDECREF(s);

 #else

         plrv_bo = PyObject_Str(plrv);

 #endif

     }

     if (!plrv_bo)

         PLy_elog(ERROR, "could not create string representation of Python object");


     plrv_sc = pstrdup(PyBytes_AsString(plrv_bo));

     plen = PyBytes_Size(plrv_bo);

     slen = strlen(plrv_sc);


     Py_XDECREF(plrv_bo);


     if (slen < plen)

         ereport(ERROR,

                 (errcode(ERRCODE_DATATYPE_MISMATCH),

                  errmsg("could not convert Python object into cstring: Python string representation appears to contain null bytes")));

     else if (slen > plen)

         elog(ERROR, "could not convert Python object into cstring: Python string longer than reported length");

     pg_verifymbstr(plrv_sc, slen, false);


     return plrv_sc;

 }


 /*

  * Generic conversion function: Convert PyObject to cstring and

  * cstring into PostgreSQL type.

  */

 static Datum

 PLyObject_ToDatum(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray)

 {

     char       *str;


     Assert(plrv != Py_None);


     str = PLyObject_AsString(plrv);


     /*

      * If we are parsing a composite type within an array, and the string

      * isn't a valid record literal, there's a high chance that the function

      * did something like:

      *

      * CREATE FUNCTION .. RETURNS comptype[] AS $$ return [['foo', 'bar']] $$

      * LANGUAGE plpython;

      *

      * Before PostgreSQL 10, that was interpreted as a single-dimensional

      * array, containing record ('foo', 'bar'). PostgreSQL 10 added support

      * for multi-dimensional arrays, and it is now interpreted as a

      * two-dimensional array, containing two records, 'foo', and 'bar'.

      * record_in() will throw an error, because "foo" is not a valid record

      * literal.

      *

      * To make that less confusing to users who are upgrading from older

      * versions, try to give a hint in the typical instances of that. If we

      * are parsing an array of composite types, and we see a string literal

      * that is not a valid record literal, give a hint. We only want to give

      * the hint in the narrow case of a malformed string literal, not any

      * error from record_in(), so check for that case here specifically.

      *

      * This check better match the one in record_in(), so that we don't forbid

      * literals that are actually valid!

      */

     if (inarray && arg->typfunc.fn_oid == F_RECORD_IN)

     {

         char       *ptr = str;


         /* Allow leading whitespace */

         while (*ptr && isspace((unsigned char) *ptr))

             ptr++;

         if (*ptr++ != '(')

             ereport(ERROR,

                     (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),

                      errmsg("malformed record literal: \"%s\"", str),

                      errdetail("Missing left parenthesis."),

                      errhint("To return a composite type in an array, return the composite type as a Python tuple, e.g., \"[('foo',)]\".")));

     }


     return InputFunctionCall(&arg->typfunc,

                              str,

                              arg->typioparam,

                              typmod);

 }


 static Datum

 PLyObject_ToTransform(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray)

 {

     return FunctionCall1(&arg->typtransform, PointerGetDatum(plrv));

 }


 static Datum

 PLySequence_ToArray(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray)

 {

     ArrayType  *array;

     int         i;

     Datum      *elems;

     bool       *nulls;

     int64       len;

     int         ndim;

     int         dims[MAXDIM];

     int         lbs[MAXDIM];

     int         currelem;

     Datum       rv;

     PyObject   *pyptr = plrv;

     PyObject   *next;


     Assert(plrv != Py_None);


     /*

      * Determine the number of dimensions, and their sizes.

      */

     ndim = 0;

     len = 1;


     Py_INCREF(plrv);


     for (;;)

     {

         if (!PyList_Check(pyptr))

             break;


         if (ndim == MAXDIM)

             PLy_elog(ERROR, "number of array dimensions exceeds the maximum allowed (%d)", MAXDIM);


         dims[ndim] = PySequence_Length(pyptr);

         if (dims[ndim] < 0)

             PLy_elog(ERROR, "could not determine sequence length for function return value");


         if (dims[ndim] > MaxAllocSize)

             PLy_elog(ERROR, "array size exceeds the maximum allowed");


         len *= dims[ndim];

         if (len > MaxAllocSize)

             PLy_elog(ERROR, "array size exceeds the maximum allowed");


         if (dims[ndim] == 0)

         {

             /* empty sequence */

             break;

         }


         ndim++;


         next = PySequence_GetItem(pyptr, 0);

         Py_XDECREF(pyptr);

         pyptr = next;

     }

     Py_XDECREF(pyptr);


     /*

      * Check for zero dimensions. This happens if the object is a tuple or a

      * string, rather than a list, or is not a sequence at all. We don't map

      * tuples or strings to arrays in general, but in the first level, be

      * lenient, for historical reasons. So if the object is a sequence of any

      * kind, treat it as a one-dimensional array.

      */

     if (ndim == 0)

     {

         if (!PySequence_Check(plrv))

             PLy_elog(ERROR, "return value of function with array return type is not a Python sequence");


         ndim = 1;

         len = dims[0] = PySequence_Length(plrv);

     }


     /*

      * Traverse the Python lists, in depth-first order, and collect all the

      * elements at the bottom level into 'elems'/'nulls' arrays.

      */

     elems = palloc(sizeof(Datum) * len);

     nulls = palloc(sizeof(bool) * len);

     currelem = 0;

     PLySequence_ToArray_recurse(arg->elm, plrv,

                                 dims, ndim, 0,

                                 elems, nulls, &currelem);


     for (i = 0; i < ndim; i++)

         lbs[i] = 1;


     array = construct_md_array(elems,

                                nulls,

                                ndim,

                                dims,

                                lbs,

                                get_base_element_type(arg->typoid),

                                arg->elm->typlen,

                                arg->elm->typbyval,

                                arg->elm->typalign);


     /*

      * If the result type is a domain of array, the resulting array must be

      * checked.

      */

     rv = PointerGetDatum(array);

     if (get_typtype(arg->typoid) == TYPTYPE_DOMAIN)

         domain_check(rv, false, arg->typoid, &arg->typfunc.fn_extra, arg->typfunc.fn_mcxt);

     return rv;

 }


 /*

  * Helper function for PLySequence_ToArray. Traverse a Python list of lists in

  * depth-first order, storing the elements in 'elems'.

  */

 static void

 PLySequence_ToArray_recurse(PLyObToDatum *elm, PyObject *list,

                             int *dims, int ndim, int dim,

                             Datum *elems, bool *nulls, int *currelem)

 {

     int         i;


     if (PySequence_Length(list) != dims[dim])

         ereport(ERROR,

                 (errmsg("wrong length of inner sequence: has length %d, but %d was expected",

                         (int) PySequence_Length(list), dims[dim]),

                  (errdetail("To construct a multidimensional array, the inner sequences must all have the same length."))));


     if (dim < ndim - 1)

     {

         for (i = 0; i < dims[dim]; i++)

         {

             PyObject   *sublist = PySequence_GetItem(list, i);


             PLySequence_ToArray_recurse(elm, sublist, dims, ndim, dim + 1,

                                         elems, nulls, currelem);

             Py_XDECREF(sublist);

         }

     }

     else

     {

         for (i = 0; i < dims[dim]; i++)

         {

             PyObject   *obj = PySequence_GetItem(list, i);


             if (obj == Py_None)

             {

                 nulls[*currelem] = true;

                 elems[*currelem] = (Datum) 0;

             }

             else

             {

                 nulls[*currelem] = false;

                 elems[*currelem] = elm->func(elm, -1, obj, true);

             }

             Py_XDECREF(obj);

             (*currelem)++;

         }

     }

 }


 static Datum

 PLyString_ToComposite(PLyTypeInfo *info, TupleDesc desc, PyObject *string, bool inarray)

 {

     Datum       result;

     HeapTuple   typeTup;

     PLyTypeInfo locinfo;

     PLyExecutionContext *exec_ctx = PLy_current_execution_context();

     MemoryContext cxt;


     /* Create a dummy PLyTypeInfo */

     cxt = AllocSetContextCreate(CurrentMemoryContext,

                                 "PL/Python temp context",

                                 ALLOCSET_DEFAULT_SIZES);

     MemSet(&locinfo, 0, sizeof(PLyTypeInfo));

     PLy_typeinfo_init(&locinfo, cxt);


     typeTup = SearchSysCache1(TYPEOID, ObjectIdGetDatum(desc->tdtypeid));

     if (!HeapTupleIsValid(typeTup))

         elog(ERROR, "cache lookup failed for type %u", desc->tdtypeid);


     PLy_output_datum_func2(&locinfo.out.d, locinfo.mcxt, typeTup,

                            exec_ctx->curr_proc->langid,

                            exec_ctx->curr_proc->trftypes);


     ReleaseSysCache(typeTup);


     result = PLyObject_ToDatum(&locinfo.out.d, desc->tdtypmod, string, inarray);


     MemoryContextDelete(cxt);


     return result;

 }


 static Datum

 PLyMapping_ToComposite(PLyTypeInfo *info, TupleDesc desc, PyObject *mapping)

 {

     Datum       result;

     HeapTuple   tuple;

     Datum      *values;

     bool       *nulls;

     volatile int i;


     Assert(PyMapping_Check(mapping));


     if (info->is_rowtype == 2)

         PLy_output_tuple_funcs(info, desc);

     Assert(info->is_rowtype == 1);


     /* Build tuple */

     values = palloc(sizeof(Datum) * desc->natts);

     nulls = palloc(sizeof(bool) * desc->natts);

     for (i = 0; i < desc->natts; ++i)

     {

         char       *key;

         PyObject   *volatile value;

         PLyObToDatum *att;

         Form_pg_attribute attr = TupleDescAttr(desc, i);


         if (attr->attisdropped)

         {

             values[i] = (Datum) 0;

             nulls[i] = true;

             continue;

         }


         key = NameStr(attr->attname);

         value = NULL;

         att = &info->out.r.atts[i];

         PG_TRY();

         {

             value = PyMapping_GetItemString(mapping, key);

             if (value == Py_None)

             {

                 values[i] = (Datum) NULL;

                 nulls[i] = true;

             }

             else if (value)

             {

                 values[i] = (att->func) (att, -1, value, false);

                 nulls[i] = false;

             }

             else

                 ereport(ERROR,

                         (errcode(ERRCODE_UNDEFINED_COLUMN),

                          errmsg("key \"%s\" not found in mapping", key),

                          errhint("To return null in a column, "

                                  "add the value None to the mapping with the key named after the column.")));


             Py_XDECREF(value);

             value = NULL;

         }

         PG_CATCH();

         {

             Py_XDECREF(value);

             PG_RE_THROW();

         }

         PG_END_TRY();

     }


     tuple = heap_form_tuple(desc, values, nulls);

     result = heap_copy_tuple_as_datum(tuple, desc);

     heap_freetuple(tuple);


     pfree(values);

     pfree(nulls);


     return result;

 }


 static Datum

 PLySequence_ToComposite(PLyTypeInfo *info, TupleDesc desc, PyObject *sequence)

 {

     Datum       result;

     HeapTuple   tuple;

     Datum      *values;

     bool       *nulls;

     volatile int idx;

     volatile int i;


     Assert(PySequence_Check(sequence));


     /*

      * Check that sequence length is exactly same as PG tuple's. We actually

      * can ignore exceeding items or assume missing ones as null but to avoid

      * plpython developer's errors we are strict here

      */

     idx = 0;

     for (i = 0; i < desc->natts; i++)

     {

         if (!TupleDescAttr(desc, i)->attisdropped)

             idx++;

     }

     if (PySequence_Length(sequence) != idx)

         ereport(ERROR,

                 (errcode(ERRCODE_DATATYPE_MISMATCH),

                  errmsg("length of returned sequence did not match number of columns in row")));


     if (info->is_rowtype == 2)

         PLy_output_tuple_funcs(info, desc);

     Assert(info->is_rowtype == 1);


     /* Build tuple */

     values = palloc(sizeof(Datum) * desc->natts);

     nulls = palloc(sizeof(bool) * desc->natts);

     idx = 0;

     for (i = 0; i < desc->natts; ++i)

     {

         PyObject   *volatile value;

         PLyObToDatum *att;


         if (TupleDescAttr(desc, i)->attisdropped)

         {

             values[i] = (Datum) 0;

             nulls[i] = true;

             continue;

         }


         value = NULL;

         att = &info->out.r.atts[i];

         PG_TRY();

         {

             value = PySequence_GetItem(sequence, idx);

             Assert(value);

             if (value == Py_None)

             {

                 values[i] = (Datum) NULL;

                 nulls[i] = true;

             }

             else if (value)

             {

                 values[i] = (att->func) (att, -1, value, false);

                 nulls[i] = false;

             }


             Py_XDECREF(value);

             value = NULL;

         }

         PG_CATCH();

         {

             Py_XDECREF(value);

             PG_RE_THROW();

         }

         PG_END_TRY();


         idx++;

     }


     tuple = heap_form_tuple(desc, values, nulls);

     result = heap_copy_tuple_as_datum(tuple, desc);

     heap_freetuple(tuple);


     pfree(values);

     pfree(nulls);


     return result;

 }


 static Datum

 PLyGenericObject_ToComposite(PLyTypeInfo *info, TupleDesc desc, PyObject *object, bool inarray)

 {

     Datum       result;

     HeapTuple   tuple;

     Datum      *values;

     bool       *nulls;

     volatile int i;


     if (info->is_rowtype == 2)

         PLy_output_tuple_funcs(info, desc);

     Assert(info->is_rowtype == 1);


     /* Build tuple */

     values = palloc(sizeof(Datum) * desc->natts);

     nulls = palloc(sizeof(bool) * desc->natts);

     for (i = 0; i < desc->natts; ++i)

     {

         char       *key;

         PyObject   *volatile value;

         PLyObToDatum *att;

         Form_pg_attribute attr = TupleDescAttr(desc, i);


         if (attr->attisdropped)

         {

             values[i] = (Datum) 0;

             nulls[i] = true;

             continue;

         }


         key = NameStr(attr->attname);

         value = NULL;

         att = &info->out.r.atts[i];

         PG_TRY();

         {

             value = PyObject_GetAttrString(object, key);

             if (value == Py_None)

             {

                 values[i] = (Datum) NULL;

                 nulls[i] = true;

             }

             else if (value)

             {

                 values[i] = (att->func) (att, -1, value, false);

                 nulls[i] = false;

             }

             else

             {

                 /*

                  * No attribute for this column in the object.

                  *

                  * If we are parsing a composite type in an array, a likely

                  * cause is that the function contained something like "[[123,

                  * 'foo']]". Before PostgreSQL 10, that was interpreted as an

                  * array, with a composite type (123, 'foo') in it. But now

                  * it's interpreted as a two-dimensional array, and we try to

                  * interpret "123" as the composite type. See also similar

                  * heuristic in PLyObject_ToDatum().

                  */

                 ereport(ERROR,

                         (errcode(ERRCODE_UNDEFINED_COLUMN),

                          errmsg("attribute \"%s\" does not exist in Python object", key),

                          inarray ?

                          errhint("To return a composite type in an array, return the composite type as a Python tuple, e.g., \"[('foo',)]\".") :

                          errhint("To return null in a column, let the returned object have an attribute named after column with value None.")));

             }


             Py_XDECREF(value);

             value = NULL;

         }

         PG_CATCH();

         {

             Py_XDECREF(value);

             PG_RE_THROW();

         }

         PG_END_TRY();

     }


     tuple = heap_form_tuple(desc, values, nulls);

     result = heap_copy_tuple_as_datum(tuple, desc);

     heap_freetuple(tuple);


     pfree(values);

     pfree(nulls);


     return result;

 }

PLyObToDatum::typfunc
FmgrInfo typfunc
Definition: plpy_typeio.h:58

TYPTYPE_DOMAIN
#define TYPTYPE_DOMAIN
Definition: pg_type.h:722

PLyObject_ToBool
static Datum PLyObject_ToBool(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray)
Definition: plpy_typeio.c:746

get_transform_fromsql
Oid get_transform_fromsql(Oid typid, Oid langid, List *trftypes)
Definition: lsyscache.c:1872

PLyLong_FromInt64
static PyObject * PLyLong_FromInt64(PLyDatumToOb *arg, Datum d)
Definition: plpy_typeio.c:589

PLyTypeInfo::typrel_xmin
TransactionId typrel_xmin
Definition: plpy_typeio.h:96

PLy_output_tuple_funcs
void PLy_output_tuple_funcs(PLyTypeInfo *arg, TupleDesc desc)
Definition: plpy_typeio.c:181

PLyInt_FromInt32
static PyObject * PLyInt_FromInt32(PLyDatumToOb *arg, Datum d)
Definition: plpy_typeio.c:583

MemoryContextDelete
void MemoryContextDelete(MemoryContext context)
Definition: mcxt.c:200

tupleDesc::tdtypeid
Oid tdtypeid
Definition: tupdesc.h:74

PLyExecutionContext
Definition: plpy_main.h:18

errhint
int errhint(const char *fmt,...)
Definition: elog.c:987

PLyTupleToOb::atts
PLyDatumToOb * atts
Definition: plpy_typeio.h:35

VARDATA_ANY
#define VARDATA_ANY(PTR)
Definition: postgres.h:347

VARDATA
#define VARDATA(PTR)
Definition: postgres.h:303

PLyDatumToOb::typioparam
Oid typioparam
Definition: plpy_typeio.h:26

GETSTRUCT
#define GETSTRUCT(TUP)
Definition: htup_details.h:656

PLy_input_datum_func
void PLy_input_datum_func(PLyTypeInfo *arg, Oid typeOid, HeapTuple typeTup, Oid langid, List *trftypes)
Definition: plpy_typeio.c:87

funcapi.h

next
static int32 next
Definition: blutils.c:210

FmgrInfo::fn_mcxt
MemoryContext fn_mcxt
Definition: fmgr.h:65

att_align_nominal
#define att_align_nominal(cur_offset, attalign)
Definition: tupmacs.h:144

PLy_typeinfo_init
void PLy_typeinfo_init(PLyTypeInfo *arg, MemoryContext mcxt)
Definition: plpy_typeio.c:70

lookup_rowtype_tupdesc
TupleDesc lookup_rowtype_tupdesc(Oid type_id, int32 typmod)
Definition: typcache.c:1486

DatumGetInt32
#define DatumGetInt32(X)
Definition: postgres.h:478

PLyBool_FromBool
static PyObject * PLyBool_FromBool(PLyDatumToOb *arg, Datum d)
Definition: plpy_typeio.c:523

MAXDIM
#define MAXDIM
Definition: c.h:413

PyObject_Bytes
#define PyObject_Bytes
Definition: plpython.h:87

PLy_output_datum_func
void PLy_output_datum_func(PLyTypeInfo *arg, HeapTuple typeTup, Oid langid, List *trftypes)
Definition: plpy_typeio.c:96

TYPTYPE_COMPOSITE
#define TYPTYPE_COMPOSITE
Definition: pg_type.h:721

OIDOID
#define OIDOID
Definition: pg_type.h:328

PointerGetDatum
#define PointerGetDatum(X)
Definition: postgres.h:562

NUMERICOID
#define NUMERICOID
Definition: pg_type.h:554

TupleDescAttr
#define TupleDescAttr(tupdesc, i)
Definition: tupdesc.h:84

VARHDRSZ
#define VARHDRSZ
Definition: c.h:439

DatumGetObjectId
#define DatumGetObjectId(X)
Definition: postgres.h:506

pstrdup
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Definition: postgres.h:408

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Definition: pg_type.h:419

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Definition: postgres.h:555

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Definition: plpy_typeio.h:72

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Definition: sort-test.py:11

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struct PLyObToDatum * elm
Definition: plpy_typeio.h:66

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#define VARSIZE_ANY_EXHDR(PTR)
Definition: postgres.h:340

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Definition: mcxt.c:848

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Definition: elog.c:797

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Definition: plpy_typeio.h:65

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Definition: preproc-comment.c:23

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Definition: lsyscache.c:2053

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#define FunctionCall1(flinfo, arg1)
Definition: fmgr.h:603

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Definition: c.h:493

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static PyObject * PLyList_FromArray_recurse(PLyDatumToOb *elm, int *dims, int ndim, int dim, char **dataptr_p, bits8 **bitmap_p, int *bitmask_p)
Definition: plpy_typeio.c:671

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Definition: pg_backup_utils.c:27

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PLyObToDatum * atts
Definition: plpy_typeio.h:71

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Definition: c.h:433

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bool pg_verifymbstr(const char *mbstr, int len, bool noError)
Definition: wchar.c:1866

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Definition: plpy_typeio.h:29

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#define SET_VARSIZE(PTR, len)
Definition: postgres.h:328

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Definition: elog.h:219

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Definition: htup_details.h:695

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ArrayType * construct_md_array(Datum *elems, bool *nulls, int ndims, int *dims, int *lbs, Oid elmtype, int elmlen, bool elmbyval, char elmalign)
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Definition: tupdesc.h:115

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Definition: elog.h:284

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static void PLySequence_ToArray_recurse(PLyObToDatum *elm, PyObject *list, int *dims, int ndim, int dim, Datum *elems, bool *nulls, int *currelem)
Definition: plpy_typeio.c:1084

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Definition: lsyscache.c:2271

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Definition: plpy_typeio.h:41

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Definition: pg_list.h:45

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Definition: array.h:281

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static Datum PLyObject_ToDatum(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray)
Definition: plpy_typeio.c:908

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static Datum PLyObject_ToBytea(PLyObToDatum *arg, int32 typmod, PyObject *plrv, bool inarray)
Definition: plpy_typeio.c:765

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Definition: elog.h:300

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Definition: plpy_typeio.h:59

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Definition: plpy_typeio.h:64

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Definition: plpy_main.c:407

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#define DatumGetArrayTypeP(X)
Definition: array.h:242

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void get_type_io_data(Oid typid, IOFuncSelector which_func, int16 *typlen, bool *typbyval, char *typalign, char *typdelim, Oid *typioparam, Oid *func)
Definition: lsyscache.c:2075