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 "catalog/pg_type.h"

#include "funcapi.h"

#include "mb/pg_wchar.h"

#include "miscadmin.h"

#include "plpy_elog.h"

#include "plpy_main.h"

#include "plpy_typeio.h"

#include "plpy_util.h"

#include "utils/array.h"

#include "utils/builtins.h"

#include "utils/fmgroids.h"

#include "utils/lsyscache.h"

#include "utils/memutils.h"


/* 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 *PLyLong_FromInt16(PLyDatumToOb *arg, Datum d);

static PyObject *PLyLong_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 *PLyUnicode_FromScalar(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);

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

static PyObject *PLyDict_FromTuple(PLyDatumToOb *arg, HeapTuple tuple, TupleDesc desc, bool include_generated);


/* conversion from Python objects to Datums */

static Datum PLyObject_ToBool(PLyObToDatum *arg, PyObject *plrv,

                              bool *isnull, bool inarray);

static Datum PLyObject_ToBytea(PLyObToDatum *arg, PyObject *plrv,

                               bool *isnull, bool inarray);

static Datum PLyObject_ToComposite(PLyObToDatum *arg, PyObject *plrv,

                                   bool *isnull, bool inarray);

static Datum PLyObject_ToScalar(PLyObToDatum *arg, PyObject *plrv,

                                bool *isnull, bool inarray);

static Datum PLyObject_ToDomain(PLyObToDatum *arg, PyObject *plrv,

                                bool *isnull, bool inarray);

static Datum PLyObject_ToTransform(PLyObToDatum *arg, PyObject *plrv,

                                   bool *isnull, bool inarray);

static Datum PLySequence_ToArray(PLyObToDatum *arg, PyObject *plrv,

                                 bool *isnull, bool inarray);

static void PLySequence_ToArray_recurse(PyObject *obj,

                                        ArrayBuildState **astatep,

                                        int *ndims, int *dims, int cur_depth,

                                        PLyObToDatum *elm, Oid elmbasetype);


/* conversion from Python objects to composite Datums */

static Datum PLyUnicode_ToComposite(PLyObToDatum *arg, PyObject *string, bool inarray);

static Datum PLyMapping_ToComposite(PLyObToDatum *arg, TupleDesc desc, PyObject *mapping);

static Datum PLySequence_ToComposite(PLyObToDatum *arg, TupleDesc desc, PyObject *sequence);

static Datum PLyGenericObject_ToComposite(PLyObToDatum *arg, TupleDesc desc, PyObject *object, bool inarray);


/*

 * Conversion functions.  Remember output from Python is input to

 * PostgreSQL, and vice versa.

 */


/*

 * Perform input conversion, given correctly-set-up state information.

 *

 * This is the outer-level entry point for any input conversion.  Internally,

 * the conversion functions recurse directly to each other.

 */

PyObject *


PLy_input_convert(PLyDatumToOb *arg, Datum val)

{

    PyObject   *result;

    PLyExecutionContext *exec_ctx = PLy_current_execution_context();

    MemoryContext scratch_context = PLy_get_scratch_context(exec_ctx);

    MemoryContext oldcontext;


    /*

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

     * datatype output function calls.  (The individual PLyDatumToObFunc

     * functions can't reset the scratch context, because they recurse and an

     * inner one might clobber data an outer one still needs.  So we do it

     * once at the outermost recursion level.)

     *

     * We reset the scratch context before, not after, each conversion cycle.

     * This way we aren't on the hook to release a Python refcount on the

     * result object in case MemoryContextReset throws an error.

     */

    MemoryContextReset(scratch_context);


    oldcontext = MemoryContextSwitchTo(scratch_context);


    result = arg->func(arg, val);


    MemoryContextSwitchTo(oldcontext);


    return result;

}


/*

 * Perform output conversion, given correctly-set-up state information.

 *

 * This is the outer-level entry point for any output conversion.  Internally,

 * the conversion functions recurse directly to each other.

 *

 * The result, as well as any cruft generated along the way, are in the

 * current memory context.  Caller is responsible for cleanup.

 */

Datum


PLy_output_convert(PLyObToDatum *arg, PyObject *val, bool *isnull)

{

    /* at outer level, we are not considering an array element */

    return arg->func(arg, val, isnull, false);

}


/*

 * Transform a tuple into a Python dict object.

 *

 * Note: the tupdesc must match the one used to set up *arg.  We could

 * insist that this function lookup the tupdesc from what is in *arg,

 * but in practice all callers have the right tupdesc available.

 */

PyObject *


PLy_input_from_tuple(PLyDatumToOb *arg, HeapTuple tuple, TupleDesc desc, bool include_generated)

{

    PyObject   *dict;

    PLyExecutionContext *exec_ctx = PLy_current_execution_context();

    MemoryContext scratch_context = PLy_get_scratch_context(exec_ctx);

    MemoryContext oldcontext;


    /*

     * As in PLy_input_convert, do the work in the scratch context.

     */

    MemoryContextReset(scratch_context);


    oldcontext = MemoryContextSwitchTo(scratch_context);


    dict = PLyDict_FromTuple(arg, tuple, desc, include_generated);


    MemoryContextSwitchTo(oldcontext);


    return dict;

}


/*

 * Initialize, or re-initialize, per-column input info for a composite type.

 *

 * This is separate from PLy_input_setup_func() because in cases involving

 * anonymous record types, we need to be passed the tupdesc explicitly.

 * It's caller's responsibility that the tupdesc has adequate lifespan

 * in such cases.  If the tupdesc is for a named composite or registered

 * record type, it does not need to be long-lived.

 */

void


PLy_input_setup_tuple(PLyDatumToOb *arg, TupleDesc desc, PLyProcedure *proc)

{

    int         i;


    /* We should be working on a previously-set-up struct */

    Assert(arg->func == PLyDict_FromComposite);


    /* Save pointer to tupdesc, but only if this is an anonymous record type */

    if (arg->typoid == RECORDOID && arg->typmod < 0)

        arg->tuple.recdesc = desc;


    /* (Re)allocate atts array as needed */

    if (arg->tuple.natts != desc->natts)

    {

        if (arg->tuple.atts)

            pfree(arg->tuple.atts);

        arg->tuple.natts = desc->natts;

        arg->tuple.atts = (PLyDatumToOb *)

            MemoryContextAllocZero(arg->mcxt,

                                   desc->natts * sizeof(PLyDatumToOb));

    }


    /* Fill the atts entries, except for dropped columns */

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

    {

        Form_pg_attribute attr = TupleDescAttr(desc, i);

        PLyDatumToOb *att = &arg->tuple.atts[i];


        if (attr->attisdropped)

            continue;


        if (att->typoid == attr->atttypid && att->typmod == attr->atttypmod)

            continue;           /* already set up this entry */


        PLy_input_setup_func(att, arg->mcxt,

                             attr->atttypid, attr->atttypmod,

                             proc);

    }

}


/*

 * Initialize, or re-initialize, per-column output info for a composite type.

 *

 * This is separate from PLy_output_setup_func() because in cases involving

 * anonymous record types, we need to be passed the tupdesc explicitly.

 * It's caller's responsibility that the tupdesc has adequate lifespan

 * in such cases.  If the tupdesc is for a named composite or registered

 * record type, it does not need to be long-lived.

 */

void


PLy_output_setup_tuple(PLyObToDatum *arg, TupleDesc desc, PLyProcedure *proc)

{

    int         i;


    /* We should be working on a previously-set-up struct */

    Assert(arg->func == PLyObject_ToComposite);


    /* Save pointer to tupdesc, but only if this is an anonymous record type */

    if (arg->typoid == RECORDOID && arg->typmod < 0)

        arg->tuple.recdesc = desc;


    /* (Re)allocate atts array as needed */

    if (arg->tuple.natts != desc->natts)

    {

        if (arg->tuple.atts)

            pfree(arg->tuple.atts);

        arg->tuple.natts = desc->natts;

        arg->tuple.atts = (PLyObToDatum *)

            MemoryContextAllocZero(arg->mcxt,

                                   desc->natts * sizeof(PLyObToDatum));

    }


    /* Fill the atts entries, except for dropped columns */

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

    {

        Form_pg_attribute attr = TupleDescAttr(desc, i);

        PLyObToDatum *att = &arg->tuple.atts[i];


        if (attr->attisdropped)

            continue;


        if (att->typoid == attr->atttypid && att->typmod == attr->atttypmod)

            continue;           /* already set up this entry */


        PLy_output_setup_func(att, arg->mcxt,

                              attr->atttypid, attr->atttypmod,

                              proc);

    }

}


/*

 * Set up output info for a PL/Python function returning record.

 *

 * Note: the given tupdesc is not necessarily long-lived.

 */

void


PLy_output_setup_record(PLyObToDatum *arg, TupleDesc desc, PLyProcedure *proc)

{

    /* Makes no sense unless RECORD */

    Assert(arg->typoid == RECORDOID);

    Assert(desc->tdtypeid == RECORDOID);


    /*

     * Bless the record type if not already done.  We'd have to do this anyway

     * to return a tuple, so we might as well force the issue so we can use

     * the known-record-type code path.

     */

    BlessTupleDesc(desc);


    /*

     * Update arg->typmod, and clear the recdesc link if it's changed. The

     * next call of PLyObject_ToComposite will look up a long-lived tupdesc

     * for the record type.

     */

    arg->typmod = desc->tdtypmod;

    if (arg->tuple.recdesc &&

        arg->tuple.recdesc->tdtypmod != arg->typmod)

        arg->tuple.recdesc = NULL;


    /* Update derived data if necessary */

    PLy_output_setup_tuple(arg, desc, proc);

}


/*

 * Recursively initialize the PLyObToDatum structure(s) needed to construct

 * a SQL value of the specified typeOid/typmod from a Python value.

 * (But note that at this point we may have RECORDOID/-1, ie, an indeterminate

 * record type.)

 * proc is used to look up transform functions.

 */

void


PLy_output_setup_func(PLyObToDatum *arg, MemoryContext arg_mcxt,

                      Oid typeOid, int32 typmod,

                      PLyProcedure *proc)

{

    TypeCacheEntry *typentry;

    char        typtype;

    Oid         trfuncid;

    Oid         typinput;


    /* Since this is recursive, it could theoretically be driven to overflow */

    check_stack_depth();


    arg->typoid = typeOid;

    arg->typmod = typmod;

    arg->mcxt = arg_mcxt;


    /*

     * Fetch typcache entry for the target type, asking for whatever info

     * we'll need later.  RECORD is a special case: just treat it as composite

     * without bothering with the typcache entry.

     */

    if (typeOid != RECORDOID)

    {

        typentry = lookup_type_cache(typeOid, TYPECACHE_DOMAIN_BASE_INFO);

        typtype = typentry->typtype;

        arg->typbyval = typentry->typbyval;

        arg->typlen = typentry->typlen;

        arg->typalign = typentry->typalign;

    }

    else

    {

        typentry = NULL;

        typtype = TYPTYPE_COMPOSITE;

        /* hard-wired knowledge about type RECORD: */

        arg->typbyval = false;

        arg->typlen = -1;

        arg->typalign = TYPALIGN_DOUBLE;

    }


    /*

     * Choose conversion method.  Note that transform functions are checked

     * for composite and scalar types, but not for arrays or domains.  This is

     * somewhat historical, but we'd have a problem allowing them on domains,

     * since we drill down through all levels of a domain nest without looking

     * at the intermediate levels at all.

     */

    if (typtype == TYPTYPE_DOMAIN)

    {

        /* Domain */

        arg->func = PLyObject_ToDomain;

        arg->domain.domain_info = NULL;

        /* Recursively set up conversion info for the element type */

        arg->domain.base = (PLyObToDatum *)

            MemoryContextAllocZero(arg_mcxt, sizeof(PLyObToDatum));

        PLy_output_setup_func(arg->domain.base, arg_mcxt,

                              typentry->domainBaseType,

                              typentry->domainBaseTypmod,

                              proc);

    }

    else if (typentry &&

             IsTrueArrayType(typentry))

    {

        /* Standard array */

        arg->func = PLySequence_ToArray;

        /* Get base type OID to insert into constructed array */

        /* (note this might not be the same as the immediate child type) */

        arg->array.elmbasetype = getBaseType(typentry->typelem);

        /* Recursively set up conversion info for the element type */

        arg->array.elm = (PLyObToDatum *)

            MemoryContextAllocZero(arg_mcxt, sizeof(PLyObToDatum));

        PLy_output_setup_func(arg->array.elm, arg_mcxt,

                              typentry->typelem, typmod,

                              proc);

    }

    else if ((trfuncid = get_transform_tosql(typeOid,

                                             proc->langid,

                                             proc->trftypes)))

    {

        arg->func = PLyObject_ToTransform;

        fmgr_info_cxt(trfuncid, &arg->transform.typtransform, arg_mcxt);

    }

    else if (typtype == TYPTYPE_COMPOSITE)

    {

        /* Named composite type, or RECORD */

        arg->func = PLyObject_ToComposite;

        /* We'll set up the per-field data later */

        arg->tuple.recdesc = NULL;

        arg->tuple.typentry = typentry;

        arg->tuple.tupdescid = INVALID_TUPLEDESC_IDENTIFIER;

        arg->tuple.atts = NULL;

        arg->tuple.natts = 0;

        /* Mark this invalid till needed, too */

        arg->tuple.recinfunc.fn_oid = InvalidOid;

    }

    else

    {

        /* Scalar type, but we have a couple of special cases */

        switch (typeOid)

        {

            case BOOLOID:

                arg->func = PLyObject_ToBool;

                break;

            case BYTEAOID:

                arg->func = PLyObject_ToBytea;

                break;

            default:

                arg->func = PLyObject_ToScalar;

                getTypeInputInfo(typeOid, &typinput, &arg->scalar.typioparam);

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

                break;

        }

    }

}


/*

 * Recursively initialize the PLyDatumToOb structure(s) needed to construct

 * a Python value from a SQL value of the specified typeOid/typmod.

 * (But note that at this point we may have RECORDOID/-1, ie, an indeterminate

 * record type.)

 * proc is used to look up transform functions.

 */

void


PLy_input_setup_func(PLyDatumToOb *arg, MemoryContext arg_mcxt,

                     Oid typeOid, int32 typmod,

                     PLyProcedure *proc)

{

    TypeCacheEntry *typentry;

    char        typtype;

    Oid         trfuncid;

    Oid         typoutput;

    bool        typisvarlena;


    /* Since this is recursive, it could theoretically be driven to overflow */

    check_stack_depth();


    arg->typoid = typeOid;

    arg->typmod = typmod;

    arg->mcxt = arg_mcxt;


    /*

     * Fetch typcache entry for the target type, asking for whatever info

     * we'll need later.  RECORD is a special case: just treat it as composite

     * without bothering with the typcache entry.

     */

    if (typeOid != RECORDOID)

    {

        typentry = lookup_type_cache(typeOid, TYPECACHE_DOMAIN_BASE_INFO);

        typtype = typentry->typtype;

        arg->typbyval = typentry->typbyval;

        arg->typlen = typentry->typlen;

        arg->typalign = typentry->typalign;

    }

    else

    {

        typentry = NULL;

        typtype = TYPTYPE_COMPOSITE;

        /* hard-wired knowledge about type RECORD: */

        arg->typbyval = false;

        arg->typlen = -1;

        arg->typalign = TYPALIGN_DOUBLE;

    }


    /*

     * Choose conversion method.  Note that transform functions are checked

     * for composite and scalar types, but not for arrays or domains.  This is

     * somewhat historical, but we'd have a problem allowing them on domains,

     * since we drill down through all levels of a domain nest without looking

     * at the intermediate levels at all.

     */

    if (typtype == TYPTYPE_DOMAIN)

    {

        /* Domain --- we don't care, just recurse down to the base type */

        PLy_input_setup_func(arg, arg_mcxt,

                             typentry->domainBaseType,

                             typentry->domainBaseTypmod,

                             proc);

    }

    else if (typentry &&

             IsTrueArrayType(typentry))

    {

        /* Standard array */

        arg->func = PLyList_FromArray;

        /* Recursively set up conversion info for the element type */

        arg->array.elm = (PLyDatumToOb *)

            MemoryContextAllocZero(arg_mcxt, sizeof(PLyDatumToOb));

        PLy_input_setup_func(arg->array.elm, arg_mcxt,

                             typentry->typelem, typmod,

                             proc);

    }

    else if ((trfuncid = get_transform_fromsql(typeOid,

                                               proc->langid,

                                               proc->trftypes)))

    {

        arg->func = PLyObject_FromTransform;

        fmgr_info_cxt(trfuncid, &arg->transform.typtransform, arg_mcxt);

    }

    else if (typtype == TYPTYPE_COMPOSITE)

    {

        /* Named composite type, or RECORD */

        arg->func = PLyDict_FromComposite;

        /* We'll set up the per-field data later */

        arg->tuple.recdesc = NULL;

        arg->tuple.typentry = typentry;

        arg->tuple.tupdescid = INVALID_TUPLEDESC_IDENTIFIER;

        arg->tuple.atts = NULL;

        arg->tuple.natts = 0;

    }

    else

    {

        /* Scalar type, but we have a couple of special cases */

        switch (typeOid)

        {

            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 = PLyLong_FromInt16;

                break;

            case INT4OID:

                arg->func = PLyLong_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 = PLyUnicode_FromScalar;

                getTypeOutputInfo(typeOid, &typoutput, &typisvarlena);

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

                break;

        }

    }

}


/*

 * Special-purpose input converters.

 */


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 *


PLyLong_FromInt16(PLyDatumToOb *arg, Datum d)

{

    return PyLong_FromLong(DatumGetInt16(d));

}


static PyObject *


PLyLong_FromInt32(PLyDatumToOb *arg, Datum d)

{

    return PyLong_FromLong(DatumGetInt32(d));

}


static PyObject *


PLyLong_FromInt64(PLyDatumToOb *arg, Datum d)

{

    return PyLong_FromLongLong(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);

}


/*

 * Generic input conversion using a SQL type's output function.

 */

static PyObject *


PLyUnicode_FromScalar(PLyDatumToOb *arg, Datum d)

{

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

    PyObject   *r = PLyUnicode_FromString(x);


    pfree(x);

    return r;

}


/*

 * Convert using a from-SQL transform function.

 */

static PyObject *


PLyObject_FromTransform(PLyDatumToOb *arg, Datum d)

{

    Datum       t;


    t = FunctionCall1(&arg->transform.typtransform, d);

    return (PyObject *) DatumGetPointer(t);

}


/*

 * Convert a SQL array to a Python list.

 */

static PyObject *


PLyList_FromArray(PLyDatumToOb *arg, Datum d)

{

    ArrayType  *array = DatumGetArrayTypeP(d);

    PLyDatumToOb *elm = arg->array.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 (!list)

        return NULL;


    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_SetItem(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_SetItem(list, i, Py_None);

            }

            else

            {

                Datum       itemvalue;


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

                PyList_SetItem(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 composite SQL value to a Python dict.

 */

static PyObject *


PLyDict_FromComposite(PLyDatumToOb *arg, Datum d)

{

    PyObject   *dict;

    HeapTupleHeader td;

    Oid         tupType;

    int32       tupTypmod;

    TupleDesc   tupdesc;

    HeapTupleData tmptup;


    td = DatumGetHeapTupleHeader(d);

    /* Extract rowtype info and find a tupdesc */

    tupType = HeapTupleHeaderGetTypeId(td);

    tupTypmod = HeapTupleHeaderGetTypMod(td);

    tupdesc = lookup_rowtype_tupdesc(tupType, tupTypmod);


    /* Set up I/O funcs if not done yet */

    PLy_input_setup_tuple(arg, tupdesc,

                          PLy_current_execution_context()->curr_proc);


    /* Build a temporary HeapTuple control structure */

    tmptup.t_len = HeapTupleHeaderGetDatumLength(td);

    tmptup.t_data = td;


    dict = PLyDict_FromTuple(arg, &tmptup, tupdesc, true);


    ReleaseTupleDesc(tupdesc);


    return dict;

}


/*

 * Transform a tuple into a Python dict object.

 */

static PyObject *


PLyDict_FromTuple(PLyDatumToOb *arg, HeapTuple tuple, TupleDesc desc, bool include_generated)

{

    PyObject   *volatile dict;


    /* Simple sanity check that desc matches */

    Assert(desc->natts == arg->tuple.natts);


    dict = PyDict_New();

    if (dict == NULL)

        return NULL;


    PG_TRY();

    {

        int         i;


        for (i = 0; i < arg->tuple.natts; i++)

        {

            PLyDatumToOb *att = &arg->tuple.atts[i];

            Form_pg_attribute attr = TupleDescAttr(desc, i);

            char       *key;

            Datum       vattr;

            bool        is_null;

            PyObject   *value;


            if (attr->attisdropped)

                continue;


            if (attr->attgenerated)

            {

                /* don't include unless requested */

                if (!include_generated)

                    continue;

                /* never include virtual columns */

                if (attr->attgenerated == ATTRIBUTE_GENERATED_VIRTUAL)

                    continue;

            }


            key = NameStr(attr->attname);

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


            if (is_null)

                PyDict_SetItemString(dict, key, Py_None);

            else

            {

                value = att->func(att, vattr);

                PyDict_SetItemString(dict, key, value);

                Py_DECREF(value);

            }

        }

    }

    PG_CATCH();

    {

        Py_DECREF(dict);

        PG_RE_THROW();

    }

    PG_END_TRY();


    return dict;

}


/*

 * 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, PyObject *plrv,

                 bool *isnull, bool inarray)

{

    if (plrv == Py_None)

    {

        *isnull = true;

        return (Datum) 0;

    }

    *isnull = false;

    return BoolGetDatum(PyObject_IsTrue(plrv));

}


/*

 * 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, PyObject *plrv,

                  bool *isnull, bool inarray)

{

    PyObject   *volatile plrv_so = NULL;

    Datum       rv = (Datum) 0;


    if (plrv == Py_None)

    {

        *isnull = true;

        return (Datum) 0;

    }

    *isnull = false;


    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_FINALLY();

    {

        Py_XDECREF(plrv_so);

    }

    PG_END_TRY();


    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, PyObject *plrv,

                      bool *isnull, bool inarray)

{

    Datum       rv;

    TupleDesc   desc;


    if (plrv == Py_None)

    {

        *isnull = true;

        return (Datum) 0;

    }

    *isnull = false;


    /*

     * The string conversion case doesn't require a tupdesc, nor per-field

     * conversion data, so just go for it if that's the case to use.

     */

    if (PyUnicode_Check(plrv))

        return PLyUnicode_ToComposite(arg, plrv, inarray);


    /*

     * If we're dealing with a named composite type, we must look up the

     * tupdesc every time, to protect against possible changes to the type.

     * RECORD types can't change between calls; but we must still be willing

     * to set up the info the first time, if nobody did yet.

     */

    if (arg->typoid != RECORDOID)

    {

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

        /* We should have the descriptor of the type's typcache entry */

        Assert(desc == arg->tuple.typentry->tupDesc);

        /* Detect change of descriptor, update cache if needed */

        if (arg->tuple.tupdescid != arg->tuple.typentry->tupDesc_identifier)

        {

            PLy_output_setup_tuple(arg, desc,

                                   PLy_current_execution_context()->curr_proc);

            arg->tuple.tupdescid = arg->tuple.typentry->tupDesc_identifier;

        }

    }

    else

    {

        desc = arg->tuple.recdesc;

        if (desc == NULL)

        {

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

            arg->tuple.recdesc = desc;

        }

        else

        {

            /* Pin descriptor to match unpin below */

            PinTupleDesc(desc);

        }

    }


    /* Simple sanity check on our caching */

    Assert(desc->natts == arg->tuple.natts);


    /*

     * Convert, using the appropriate method depending on the type of the

     * supplied Python object.

     */

    if (PySequence_Check(plrv))

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

        rv = PLySequence_ToComposite(arg, desc, plrv);

    else if (PyMapping_Check(plrv))

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

        rv = PLyMapping_ToComposite(arg, desc, plrv);

    else

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

        rv = PLyGenericObject_ToComposite(arg, desc, plrv, inarray);


    ReleaseTupleDesc(desc);


    return rv;

}


/*

 * Convert Python object to C string in server encoding.

 *

 * Note: this is exported for use by add-on transform modules.

 */

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 */

        PyObject   *s = PyObject_Repr(plrv);


        plrv_bo = PLyUnicode_Bytes(s);

        Py_XDECREF(s);

    }

    else

    {

        PyObject   *s = PyObject_Str(plrv);


        plrv_bo = PLyUnicode_Bytes(s);

        Py_XDECREF(s);

    }

    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 output conversion function: convert PyObject to cstring and

 * cstring into PostgreSQL type.

 */

static Datum


PLyObject_ToScalar(PLyObToDatum *arg, PyObject *plrv,

                   bool *isnull, bool inarray)

{

    char       *str;


    if (plrv == Py_None)

    {

        *isnull = true;

        return (Datum) 0;

    }

    *isnull = false;


    str = PLyObject_AsString(plrv);


    return InputFunctionCall(&arg->scalar.typfunc,

                             str,

                             arg->scalar.typioparam,

                             arg->typmod);

}


/*

 * Convert to a domain type.

 */

static Datum


PLyObject_ToDomain(PLyObToDatum *arg, PyObject *plrv,

                   bool *isnull, bool inarray)

{

    Datum       result;

    PLyObToDatum *base = arg->domain.base;


    result = base->func(base, plrv, isnull, inarray);

    domain_check(result, *isnull, arg->typoid,

                 &arg->domain.domain_info, arg->mcxt);

    return result;

}


/*

 * Convert using a to-SQL transform function.

 */

static Datum


PLyObject_ToTransform(PLyObToDatum *arg, PyObject *plrv,

                      bool *isnull, bool inarray)

{

    if (plrv == Py_None)

    {

        *isnull = true;

        return (Datum) 0;

    }

    *isnull = false;

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

}


/*

 * Convert Python sequence (or list of lists) to SQL array.

 */

static Datum


PLySequence_ToArray(PLyObToDatum *arg, PyObject *plrv,

                    bool *isnull, bool inarray)

{

    ArrayBuildState *astate = NULL;

    int         ndims = 1;

    int         dims[MAXDIM];

    int         lbs[MAXDIM];


    if (plrv == Py_None)

    {

        *isnull = true;

        return (Datum) 0;

    }

    *isnull = false;


    /*

     * For historical reasons, we allow any sequence (not only a list) at the

     * top level when converting a Python object to a SQL array.  However, a

     * multi-dimensional array is recognized only when the object contains

     * true lists.

     */

    if (!PySequence_Check(plrv))

        ereport(ERROR,

                (errcode(ERRCODE_DATATYPE_MISMATCH),

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


    /* Initialize dimensionality info with first-level dimension */

    memset(dims, 0, sizeof(dims));

    dims[0] = PySequence_Length(plrv);


    /*

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

     * elements at the bottom level into an ArrayBuildState.

     */

    PLySequence_ToArray_recurse(plrv, &astate,

                                &ndims, dims, 1,

                                arg->array.elm,

                                arg->array.elmbasetype);


    /* ensure we get zero-D array for no inputs, as per PG convention */

    if (astate == NULL)

        return PointerGetDatum(construct_empty_array(arg->array.elmbasetype));


    for (int i = 0; i < ndims; i++)

        lbs[i] = 1;


    return makeMdArrayResult(astate, ndims, dims, lbs,

                             CurrentMemoryContext, true);

}


/*

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

 * depth-first order, storing the elements in *astatep.

 *

 * The ArrayBuildState is created only when we first find a scalar element;

 * if we didn't do it like that, we'd need some other convention for knowing

 * whether we'd already found any scalars (and thus the number of dimensions

 * is frozen).

 */

static void


PLySequence_ToArray_recurse(PyObject *obj, ArrayBuildState **astatep,

                            int *ndims, int *dims, int cur_depth,

                            PLyObToDatum *elm, Oid elmbasetype)

{

    int         i;

    int         len = PySequence_Length(obj);


    /* We should not get here with a non-sequence object */

    if (len < 0)

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


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

    {

        /* fetch the array element */

        PyObject   *subobj = PySequence_GetItem(obj, i);


        /* need PG_TRY to ensure we release the subobj's refcount */

        PG_TRY();

        {

            /* multi-dimensional array? */

            if (PyList_Check(subobj))

            {

                /* set size when at first element in this level, else compare */

                if (i == 0 && *ndims == cur_depth)

                {

                    /* array after some scalars at same level? */

                    if (*astatep != NULL)

                        ereport(ERROR,

                                (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),

                                 errmsg("multidimensional arrays must have array expressions with matching dimensions")));

                    /* too many dimensions? */

                    if (cur_depth >= MAXDIM)

                        ereport(ERROR,

                                (errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED),

                                 errmsg("number of array dimensions exceeds the maximum allowed (%d)",

                                        MAXDIM)));

                    /* OK, add a dimension */

                    dims[*ndims] = PySequence_Length(subobj);

                    (*ndims)++;

                }

                else if (cur_depth >= *ndims ||

                         PySequence_Length(subobj) != dims[cur_depth])

                    ereport(ERROR,

                            (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),

                             errmsg("multidimensional arrays must have array expressions with matching dimensions")));


                /* recurse to fetch elements of this sub-array */

                PLySequence_ToArray_recurse(subobj, astatep,

                                            ndims, dims, cur_depth + 1,

                                            elm, elmbasetype);

            }

            else

            {

                Datum       dat;

                bool        isnull;


                /* scalar after some sub-arrays at same level? */

                if (*ndims != cur_depth)

                    ereport(ERROR,

                            (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),

                             errmsg("multidimensional arrays must have array expressions with matching dimensions")));


                /* convert non-list object to Datum */

                dat = elm->func(elm, subobj, &isnull, true);


                /* create ArrayBuildState if we didn't already */

                if (*astatep == NULL)

                    *astatep = initArrayResult(elmbasetype,

                                               CurrentMemoryContext, true);


                /* ... and save the element value in it */

                (void) accumArrayResult(*astatep, dat, isnull,

                                        elmbasetype, CurrentMemoryContext);

            }

        }

        PG_FINALLY();

        {

            Py_XDECREF(subobj);

        }

        PG_END_TRY();

    }

}


/*

 * Convert a Python string to composite, using record_in.

 */

static Datum


PLyUnicode_ToComposite(PLyObToDatum *arg, PyObject *string, bool inarray)

{

    char       *str;


    /*

     * Set up call data for record_in, if we didn't already.  (We can't just

     * use DirectFunctionCall, because record_in needs a fn_extra field.)

     */

    if (!OidIsValid(arg->tuple.recinfunc.fn_oid))

        fmgr_info_cxt(F_RECORD_IN, &arg->tuple.recinfunc, arg->mcxt);


    str = PLyObject_AsString(string);


    /*

     * 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)

    {

        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->tuple.recinfunc,

                             str,

                             arg->typoid,

                             arg->typmod);

}


static Datum


PLyMapping_ToComposite(PLyObToDatum *arg, TupleDesc desc, PyObject *mapping)

{

    Datum       result;

    HeapTuple   tuple;

    Datum      *values;

    bool       *nulls;

    volatile int i;


    Assert(PyMapping_Check(mapping));


    /* Build tuple */

    values = palloc_array(Datum, desc->natts);

    nulls = palloc_array(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 = &arg->tuple.atts[i];

        PG_TRY();

        {

            value = PyMapping_GetItemString(mapping, key);

            if (!value)

                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.")));


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


            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(PLyObToDatum *arg, 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 (!TupleDescCompactAttr(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")));


    /* Build tuple */

    values = palloc_array(Datum, desc->natts);

    nulls = palloc_array(bool, desc->natts);

    idx = 0;

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

    {

        PyObject   *volatile value;

        PLyObToDatum *att;


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

        {

            values[i] = (Datum) 0;

            nulls[i] = true;

            continue;

        }


        value = NULL;

        att = &arg->tuple.atts[i];

        PG_TRY();

        {

            value = PySequence_GetItem(sequence, idx);

            Assert(value);


            values[i] = att->func(att, value, &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(PLyObToDatum *arg, TupleDesc desc, PyObject *object, bool inarray)

{

    Datum       result;

    HeapTuple   tuple;

    Datum      *values;

    bool       *nulls;

    volatile int i;


    /* Build tuple */

    values = palloc_array(Datum, desc->natts);

    nulls = palloc_array(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 = &arg->tuple.atts[i];

        PG_TRY();

        {

            value = PyObject_GetAttrString(object, key);

            if (!value)

            {

                /*

                 * 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_ToScalar().

                 */

                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.")));

            }


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


            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;

}


idx
Datum idx(PG_FUNCTION_ARGS)
Definition _int_op.c:262

array.h

ARR_NDIM
#define ARR_NDIM(a)
Definition array.h:290

ARR_DATA_PTR
#define ARR_DATA_PTR(a)
Definition array.h:322

MAXDIM
#define MAXDIM
Definition array.h:75

ARR_NULLBITMAP
#define ARR_NULLBITMAP(a)
Definition array.h:300

DatumGetArrayTypeP
#define DatumGetArrayTypeP(X)
Definition array.h:261

ARR_DIMS
#define ARR_DIMS(a)
Definition array.h:294

accumArrayResult
ArrayBuildState * accumArrayResult(ArrayBuildState *astate, Datum dvalue, bool disnull, Oid element_type, MemoryContext rcontext)
Definition arrayfuncs.c:5351

construct_empty_array
ArrayType * construct_empty_array(Oid elmtype)
Definition arrayfuncs.c:3581

makeMdArrayResult
Datum makeMdArrayResult(ArrayBuildState *astate, int ndims, int *dims, int *lbs, MemoryContext rcontext, bool release)
Definition arrayfuncs.c:5453

initArrayResult
ArrayBuildState * initArrayResult(Oid element_type, MemoryContext rcontext, bool subcontext)
Definition arrayfuncs.c:5294

numeric_out
Datum numeric_out(PG_FUNCTION_ARGS)
Definition numeric.c:799

values
static Datum values[MAXATTR]
Definition bootstrap.c:155

builtins.h

NameStr
#define NameStr(name)
Definition c.h:765

VARHDRSZ
#define VARHDRSZ
Definition c.h:711

Assert
#define Assert(condition)
Definition c.h:873

bits8
uint8 bits8
Definition c.h:553

int32
int32_t int32
Definition c.h:542

OidIsValid
#define OidIsValid(objectId)
Definition c.h:788

domain_check
void domain_check(Datum value, bool isnull, Oid domainType, void **extra, MemoryContext mcxt)
Definition domains.c:346

errdetail
int errdetail(const char *fmt,...)
Definition elog.c:1216

errhint
int errhint(const char *fmt,...)
Definition elog.c:1330

errcode
int errcode(int sqlerrcode)
Definition elog.c:863

errmsg
int errmsg(const char *fmt,...)
Definition elog.c:1080

PG_RE_THROW
#define PG_RE_THROW()
Definition elog.h:405

PG_TRY
#define PG_TRY(...)
Definition elog.h:372

PG_END_TRY
#define PG_END_TRY(...)
Definition elog.h:397

ERROR
#define ERROR
Definition elog.h:39

PG_CATCH
#define PG_CATCH(...)
Definition elog.h:382

elog
#define elog(elevel,...)
Definition elog.h:226

PG_FINALLY
#define PG_FINALLY(...)
Definition elog.h:389

ereport
#define ereport(elevel,...)
Definition elog.h:150

BlessTupleDesc
TupleDesc BlessTupleDesc(TupleDesc tupdesc)
Definition execTuples.c:2260

palloc_array
#define palloc_array(type, count)
Definition fe_memutils.h:76

InputFunctionCall
Datum InputFunctionCall(FmgrInfo *flinfo, char *str, Oid typioparam, int32 typmod)
Definition fmgr.c:1531

fmgr_info_cxt
void fmgr_info_cxt(Oid functionId, FmgrInfo *finfo, MemoryContext mcxt)
Definition fmgr.c:138

OutputFunctionCall
char * OutputFunctionCall(FmgrInfo *flinfo, Datum val)
Definition fmgr.c:1683

DatumGetHeapTupleHeader
#define DatumGetHeapTupleHeader(X)
Definition fmgr.h:296

DatumGetByteaPP
#define DatumGetByteaPP(X)
Definition fmgr.h:292

DirectFunctionCall1
#define DirectFunctionCall1(func, arg1)
Definition fmgr.h:684

FunctionCall1
#define FunctionCall1(flinfo, arg1)
Definition fmgr.h:702

funcapi.h

str
const char * str
Definition hashfn_unstable.h:261

heap_form_tuple
HeapTuple heap_form_tuple(TupleDesc tupleDescriptor, const Datum *values, const bool *isnull)
Definition heaptuple.c:1117

heap_copy_tuple_as_datum
Datum heap_copy_tuple_as_datum(HeapTuple tuple, TupleDesc tupleDesc)
Definition heaptuple.c:1081

heap_freetuple
void heap_freetuple(HeapTuple htup)
Definition heaptuple.c:1435

PLyObject_AsString
#define PLyObject_AsString
Definition hstore_plpython.c:71

htup_details.h

heap_getattr
static Datum heap_getattr(HeapTuple tup, int attnum, TupleDesc tupleDesc, bool *isnull)
Definition htup_details.h:904

HeapTupleHeaderGetTypMod
static int32 HeapTupleHeaderGetTypMod(const HeapTupleHeaderData *tup)
Definition htup_details.h:516

HeapTupleHeaderGetDatumLength
static uint32 HeapTupleHeaderGetDatumLength(const HeapTupleHeaderData *tup)
Definition htup_details.h:492

HeapTupleHeaderGetTypeId
static Oid HeapTupleHeaderGetTypeId(const HeapTupleHeaderData *tup)
Definition htup_details.h:504

val
long val
Definition informix.c:689

value
static struct @172 value

x
int x
Definition isn.c:75

i
int i
Definition isn.c:77

PLy_elog
#define PLy_elog
Definition jsonb_plpython.c:61

decimal_constructor
static PyObject * decimal_constructor
Definition jsonb_plpython.c:26

getTypeOutputInfo
void getTypeOutputInfo(Oid type, Oid *typOutput, bool *typIsVarlena)
Definition lsyscache.c:3057

getTypeInputInfo
void getTypeInputInfo(Oid type, Oid *typInput, Oid *typIOParam)
Definition lsyscache.c:3024

get_transform_tosql
Oid get_transform_tosql(Oid typid, Oid langid, List *trftypes)
Definition lsyscache.c:2292

get_transform_fromsql
Oid get_transform_fromsql(Oid typid, Oid langid, List *trftypes)
Definition lsyscache.c:2270

getBaseType
Oid getBaseType(Oid typid)
Definition lsyscache.c:2671

lsyscache.h

pg_verifymbstr
bool pg_verifymbstr(const char *mbstr, int len, bool noError)
Definition mbutils.c:1559

MemoryContextReset
void MemoryContextReset(MemoryContext context)
Definition mcxt.c:403

MemoryContextAllocZero
void * MemoryContextAllocZero(MemoryContext context, Size size)
Definition mcxt.c:1266

pstrdup
char * pstrdup(const char *in)
Definition mcxt.c:1781

pfree
void pfree(void *pointer)
Definition mcxt.c:1616

palloc
void * palloc(Size size)
Definition mcxt.c:1387

CurrentMemoryContext
MemoryContext CurrentMemoryContext
Definition mcxt.c:160

memutils.h

miscadmin.h

MemoryContextSwitchTo
static MemoryContext MemoryContextSwitchTo(MemoryContext context)
Definition palloc.h:124

Form_pg_attribute
FormData_pg_attribute * Form_pg_attribute
Definition pg_attribute.h:202

arg
void * arg
Definition pg_backup_utils.c:29

len
const void size_t len
Definition pg_crc32c_sse42.c:28

pg_type.h

pg_wchar.h

plpy_elog.h

PLy_current_execution_context
PLyExecutionContext * PLy_current_execution_context(void)
Definition plpy_main.c:336

PLy_get_scratch_context
MemoryContext PLy_get_scratch_context(PLyExecutionContext *context)
Definition plpy_main.c:345

plpy_main.h

PLyLong_FromInt16
static PyObject * PLyLong_FromInt16(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:604

PLy_output_setup_func
void PLy_output_setup_func(PLyObToDatum *arg, MemoryContext arg_mcxt, Oid typeOid, int32 typmod, PLyProcedure *proc)
Definition plpy_typeio.c:296

PLy_input_setup_func
void PLy_input_setup_func(PLyDatumToOb *arg, MemoryContext arg_mcxt, Oid typeOid, int32 typmod, PLyProcedure *proc)
Definition plpy_typeio.c:418

PLyLong_FromInt64
static PyObject * PLyLong_FromInt64(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:616

PLy_input_from_tuple
PyObject * PLy_input_from_tuple(PLyDatumToOb *arg, HeapTuple tuple, TupleDesc desc, bool include_generated)
Definition plpy_typeio.c:134

PLyDict_FromTuple
static PyObject * PLyDict_FromTuple(PLyDatumToOb *arg, HeapTuple tuple, TupleDesc desc, bool include_generated)
Definition plpy_typeio.c:815

PLyMapping_ToComposite
static Datum PLyMapping_ToComposite(PLyObToDatum *arg, TupleDesc desc, PyObject *mapping)
Definition plpy_typeio.c:1345

PLyObject_ToBool
static Datum PLyObject_ToBool(PLyObToDatum *arg, PyObject *plrv, bool *isnull, bool inarray)
Definition plpy_typeio.c:882

PLy_input_setup_tuple
void PLy_input_setup_tuple(PLyDatumToOb *arg, TupleDesc desc, PLyProcedure *proc)
Definition plpy_typeio.c:165

PLy_input_convert
PyObject * PLy_input_convert(PLyDatumToOb *arg, Datum val)
Definition plpy_typeio.c:81

PLyObject_ToBytea
static Datum PLyObject_ToBytea(PLyObToDatum *arg, PyObject *plrv, bool *isnull, bool inarray)
Definition plpy_typeio.c:900

PLyDict_FromComposite
static PyObject * PLyDict_FromComposite(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:781

PLyObject_ToScalar
static Datum PLyObject_ToScalar(PLyObToDatum *arg, PyObject *plrv, bool *isnull, bool inarray)
Definition plpy_typeio.c:1077

PLyObject_ToTransform
static Datum PLyObject_ToTransform(PLyObToDatum *arg, PyObject *plrv, bool *isnull, bool inarray)
Definition plpy_typeio.c:1119

PLyLong_FromInt32
static PyObject * PLyLong_FromInt32(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:610

PLyBool_FromBool
static PyObject * PLyBool_FromBool(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:550

PLy_output_setup_record
void PLy_output_setup_record(PLyObToDatum *arg, TupleDesc desc, PLyProcedure *proc)
Definition plpy_typeio.c:261

PLyUnicode_FromScalar
static PyObject * PLyUnicode_FromScalar(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:642

PLyObject_FromTransform
static PyObject * PLyObject_FromTransform(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:655

PLyFloat_FromFloat8
static PyObject * PLyFloat_FromFloat8(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:564

PLyList_FromArray_recurse
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:707

PLySequence_ToArray_recurse
static void PLySequence_ToArray_recurse(PyObject *obj, ArrayBuildState **astatep, int *ndims, int *dims, int cur_depth, PLyObToDatum *elm, Oid elmbasetype)
Definition plpy_typeio.c:1196

PLyObject_ToComposite
static Datum PLyObject_ToComposite(PLyObToDatum *arg, PyObject *plrv, bool *isnull, bool inarray)
Definition plpy_typeio.c:944

PLyFloat_FromFloat4
static PyObject * PLyFloat_FromFloat4(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:558

PLyLong_FromOid
static PyObject * PLyLong_FromOid(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:622

PLySequence_ToArray
static Datum PLySequence_ToArray(PLyObToDatum *arg, PyObject *plrv, bool *isnull, bool inarray)
Definition plpy_typeio.c:1136

PLyList_FromArray
static PyObject * PLyList_FromArray(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:667

PLySequence_ToComposite
static Datum PLySequence_ToComposite(PLyObToDatum *arg, TupleDesc desc, PyObject *sequence)
Definition plpy_typeio.c:1410

PLyBytes_FromBytea
static PyObject * PLyBytes_FromBytea(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:628

PLyUnicode_ToComposite
static Datum PLyUnicode_ToComposite(PLyObToDatum *arg, PyObject *string, bool inarray)
Definition plpy_typeio.c:1284

PLy_output_setup_tuple
void PLy_output_setup_tuple(PLyObToDatum *arg, TupleDesc desc, PLyProcedure *proc)
Definition plpy_typeio.c:215

PLy_output_convert
Datum PLy_output_convert(PLyObToDatum *arg, PyObject *val, bool *isnull)
Definition plpy_typeio.c:120

PLyObject_ToDomain
static Datum PLyObject_ToDomain(PLyObToDatum *arg, PyObject *plrv, bool *isnull, bool inarray)
Definition plpy_typeio.c:1102

PLyDecimal_FromNumeric
static PyObject * PLyDecimal_FromNumeric(PLyDatumToOb *arg, Datum d)
Definition plpy_typeio.c:570

PLyGenericObject_ToComposite
static Datum PLyGenericObject_ToComposite(PLyObToDatum *arg, TupleDesc desc, PyObject *object, bool inarray)
Definition plpy_typeio.c:1487

plpy_typeio.h

PLyUnicode_Bytes
PyObject * PLyUnicode_Bytes(PyObject *unicode)
Definition plpy_util.c:19

PLyUnicode_FromString
PyObject * PLyUnicode_FromString(const char *s)
Definition plpy_util.c:116

plpy_util.h

postgres.h

DatumGetBool
static bool DatumGetBool(Datum X)
Definition postgres.h:100

DatumGetInt64
static int64 DatumGetInt64(Datum X)
Definition postgres.h:413

PointerGetDatum
static Datum PointerGetDatum(const void *X)
Definition postgres.h:352

DatumGetFloat4
static float4 DatumGetFloat4(Datum X)
Definition postgres.h:461

DatumGetObjectId
static Oid DatumGetObjectId(Datum X)
Definition postgres.h:252

BoolGetDatum
static Datum BoolGetDatum(bool X)
Definition postgres.h:112

DatumGetFloat8
static float8 DatumGetFloat8(Datum X)
Definition postgres.h:495

DatumGetCString
static char * DatumGetCString(Datum X)
Definition postgres.h:365

Datum
uint64_t Datum
Definition postgres.h:70

DatumGetPointer
static Pointer DatumGetPointer(Datum X)
Definition postgres.h:342

DatumGetInt16
static int16 DatumGetInt16(Datum X)
Definition postgres.h:172

DatumGetInt32
static int32 DatumGetInt32(Datum X)
Definition postgres.h:212

InvalidOid
#define InvalidOid
Definition postgres_ext.h:37

Oid
unsigned int Oid
Definition postgres_ext.h:32

fb
static int fb(int x)
Definition preproc-init.c:92

check_stack_depth
void check_stack_depth(void)
Definition stack_depth.c:95

ArrayBuildState
Definition array.h:188

ArrayType
Definition array.h:93

HeapTupleData
Definition htup.h:63

HeapTupleHeaderData
Definition htup_details.h:154

MemoryContextData
Definition memnodes.h:118

PLyArrayToOb::elm
PLyDatumToOb * elm
Definition plpy_typeio.h:37

PLyDatumToOb
Definition plpy_typeio.h:58

PLyDatumToOb::array
PLyArrayToOb array
Definition plpy_typeio.h:69

PLyDatumToOb::tuple
PLyTupleToOb tuple
Definition plpy_typeio.h:70

PLyDatumToOb::typalign
char typalign
Definition plpy_typeio.h:64

PLyDatumToOb::func
PLyDatumToObFunc func
Definition plpy_typeio.h:59

PLyDatumToOb::typbyval
bool typbyval
Definition plpy_typeio.h:62

PLyDatumToOb::typlen
int16 typlen
Definition plpy_typeio.h:63

PLyExecutionContext
Definition plpy_main.h:19

PLyObToDatum
Definition plpy_typeio.h:131

PLyObToDatum::domain
PLyObToDomain domain
Definition plpy_typeio.h:144

PLyObToDatum::tuple
PLyObToTuple tuple
Definition plpy_typeio.h:143

PLyObToDatum::func
PLyObToDatumFunc func
Definition plpy_typeio.h:132

PLyObToDomain::base
PLyObToDatum * base
Definition plpy_typeio.h:121

PLyObToTuple::atts
PLyObToDatum * atts
Definition plpy_typeio.h:113

PLyProcedure
Definition plpy_procedure.h:36

PLyProcedure::trftypes
List * trftypes
Definition plpy_procedure.h:54

PLyProcedure::langid
Oid langid
Definition plpy_procedure.h:53

PLyTupleToOb::atts
PLyDatumToOb * atts
Definition plpy_typeio.h:48

TupleDescData
Definition tupdesc.h:136

TupleDescData::natts
int natts
Definition tupdesc.h:137

TupleDescData::tdtypmod
int32 tdtypmod
Definition tupdesc.h:139

TupleDescData::tdtypeid
Oid tdtypeid
Definition tupdesc.h:138

TypeCacheEntry
Definition typcache.h:32

TypeCacheEntry::domainBaseTypmod
int32 domainBaseTypmod
Definition typcache.h:116

TypeCacheEntry::typelem
Oid typelem
Definition typcache.h:46

TypeCacheEntry::typalign
char typalign
Definition typcache.h:41

TypeCacheEntry::typtype
char typtype
Definition typcache.h:43

TypeCacheEntry::typbyval
bool typbyval
Definition typcache.h:40

TypeCacheEntry::typlen
int16 typlen
Definition typcache.h:39

TypeCacheEntry::domainBaseType
Oid domainBaseType
Definition typcache.h:115

varlena
Definition c.h:706

ReleaseTupleDesc
#define ReleaseTupleDesc(tupdesc)
Definition tupdesc.h:219

PinTupleDesc
#define PinTupleDesc(tupdesc)
Definition tupdesc.h:213

TupleDescAttr
static FormData_pg_attribute * TupleDescAttr(TupleDesc tupdesc, int i)
Definition tupdesc.h:160

TupleDescCompactAttr
static CompactAttribute * TupleDescCompactAttr(TupleDesc tupdesc, int i)
Definition tupdesc.h:175

att_align_nominal
#define att_align_nominal(cur_offset, attalign)
Definition tupmacs.h:145

att_addlength_pointer
#define att_addlength_pointer(cur_offset, attlen, attptr)
Definition tupmacs.h:180

fetch_att
static Datum fetch_att(const void *T, bool attbyval, int attlen)
Definition tupmacs.h:50

lookup_rowtype_tupdesc
TupleDesc lookup_rowtype_tupdesc(Oid type_id, int32 typmod)
Definition typcache.c:1921

lookup_type_cache
TypeCacheEntry * lookup_type_cache(Oid type_id, int flags)
Definition typcache.c:386

INVALID_TUPLEDESC_IDENTIFIER
#define INVALID_TUPLEDESC_IDENTIFIER
Definition typcache.h:157

TYPECACHE_DOMAIN_BASE_INFO
#define TYPECACHE_DOMAIN_BASE_INFO
Definition typcache.h:150

VARSIZE_ANY_EXHDR
static Size VARSIZE_ANY_EXHDR(const void *PTR)
Definition varatt.h:472

VARDATA
static char * VARDATA(const void *PTR)
Definition varatt.h:305

VARDATA_ANY
static char * VARDATA_ANY(const void *PTR)
Definition varatt.h:486

SET_VARSIZE
static void SET_VARSIZE(void *PTR, Size len)
Definition varatt.h:432