jsonfuncs.c

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/*-------------------------------------------------------------------------
 *
 * jsonfuncs.c
 *      Functions to process JSON data types.
 *
 * Portions Copyright (c) 1996-2019, PostgreSQL Global Development Group
 * Portions Copyright (c) 1994, Regents of the University of California
 *
 * IDENTIFICATION
 *    src/backend/utils/adt/jsonfuncs.c
 *
 *-------------------------------------------------------------------------
 */

#include "postgres.h"

#include <limits.h>

#include "access/htup_details.h"
#include "catalog/pg_type.h"
#include "fmgr.h"
#include "funcapi.h"
#include "lib/stringinfo.h"
#include "mb/pg_wchar.h"
#include "miscadmin.h"
#include "utils/array.h"
#include "utils/builtins.h"
#include "utils/hsearch.h"
#include "utils/json.h"
#include "utils/jsonapi.h"
#include "utils/jsonb.h"
#include "utils/lsyscache.h"
#include "utils/memutils.h"
#include "utils/syscache.h"
#include "utils/typcache.h"

/* Operations available for setPath */
#define JB_PATH_CREATE                  0x0001
#define JB_PATH_DELETE                  0x0002
#define JB_PATH_REPLACE                 0x0004
#define JB_PATH_INSERT_BEFORE           0x0008
#define JB_PATH_INSERT_AFTER            0x0010
#define JB_PATH_CREATE_OR_INSERT \
    (JB_PATH_INSERT_BEFORE | JB_PATH_INSERT_AFTER | JB_PATH_CREATE)

/* state for json_object_keys */
typedef struct OkeysState
{
    JsonLexContext *lex;
    char      **result;
    int         result_size;
    int         result_count;
    int         sent_count;
} OkeysState;

/* state for iterate_json_values function */
typedef struct IterateJsonStringValuesState
{
    JsonLexContext *lex;
    JsonIterateStringValuesAction action;   /* an action that will be applied
                                             * to each json value */
    void       *action_state;   /* any necessary context for iteration */
    uint32      flags;          /* what kind of elements from a json we want
                                 * to iterate */
} IterateJsonStringValuesState;

/* state for transform_json_string_values function */
typedef struct TransformJsonStringValuesState
{
    JsonLexContext *lex;
    StringInfo  strval;         /* resulting json */
    JsonTransformStringValuesAction action; /* an action that will be applied
                                             * to each json value */
    void       *action_state;   /* any necessary context for transformation */
} TransformJsonStringValuesState;

/* state for json_get* functions */
typedef struct GetState
{
    JsonLexContext *lex;
    text       *tresult;
    char       *result_start;
    bool        normalize_results;
    bool        next_scalar;
    int         npath;          /* length of each path-related array */
    char      **path_names;     /* field name(s) being sought */
    int        *path_indexes;   /* array index(es) being sought */
    bool       *pathok;         /* is path matched to current depth? */
    int        *array_cur_index;    /* current element index at each path
                                     * level */
} GetState;

/* state for json_array_length */
typedef struct AlenState
{
    JsonLexContext *lex;
    int         count;
} AlenState;

/* state for json_each */
typedef struct EachState
{
    JsonLexContext *lex;
    Tuplestorestate *tuple_store;
    TupleDesc   ret_tdesc;
    MemoryContext tmp_cxt;
    char       *result_start;
    bool        normalize_results;
    bool        next_scalar;
    char       *normalized_scalar;
} EachState;

/* state for json_array_elements */
typedef struct ElementsState
{
    JsonLexContext *lex;
    const char *function_name;
    Tuplestorestate *tuple_store;
    TupleDesc   ret_tdesc;
    MemoryContext tmp_cxt;
    char       *result_start;
    bool        normalize_results;
    bool        next_scalar;
    char       *normalized_scalar;
} ElementsState;

/* state for get_json_object_as_hash */
typedef struct JHashState
{
    JsonLexContext *lex;
    const char *function_name;
    HTAB       *hash;
    char       *saved_scalar;
    char       *save_json_start;
    JsonTokenType saved_token_type;
} JHashState;

/* hashtable element */
typedef struct JsonHashEntry
{
    char        fname[NAMEDATALEN]; /* hash key (MUST BE FIRST) */
    char       *val;
    JsonTokenType type;
} JsonHashEntry;

/* structure to cache type I/O metadata needed for populate_scalar() */
typedef struct ScalarIOData
{
    Oid         typioparam;
    FmgrInfo    typiofunc;
} ScalarIOData;

/* these two structures are used recursively */
typedef struct ColumnIOData ColumnIOData;
typedef struct RecordIOData RecordIOData;

/* structure to cache metadata needed for populate_array() */
typedef struct ArrayIOData
{
    ColumnIOData *element_info; /* metadata cache */
    Oid         element_type;   /* array element type id */
    int32       element_typmod; /* array element type modifier */
} ArrayIOData;

/* structure to cache metadata needed for populate_composite() */
typedef struct CompositeIOData
{
    /*
     * We use pointer to a RecordIOData here because variable-length struct
     * RecordIOData can't be used directly in ColumnIOData.io union
     */
    RecordIOData *record_io;    /* metadata cache for populate_record() */
    TupleDesc   tupdesc;        /* cached tuple descriptor */
    /* these fields differ from target type only if domain over composite: */
    Oid         base_typid;     /* base type id */
    int32       base_typmod;    /* base type modifier */
    /* this field is used only if target type is domain over composite: */
    void       *domain_info;    /* opaque cache for domain checks */
} CompositeIOData;

/* structure to cache metadata needed for populate_domain() */
typedef struct DomainIOData
{
    ColumnIOData *base_io;      /* metadata cache */
    Oid         base_typid;     /* base type id */
    int32       base_typmod;    /* base type modifier */
    void       *domain_info;    /* opaque cache for domain checks */
} DomainIOData;

/* enumeration type categories */
typedef enum TypeCat
{
    TYPECAT_SCALAR = 's',
    TYPECAT_ARRAY = 'a',
    TYPECAT_COMPOSITE = 'c',
    TYPECAT_COMPOSITE_DOMAIN = 'C',
    TYPECAT_DOMAIN = 'd'
} TypeCat;

/* these two are stolen from hstore / record_out, used in populate_record* */

/* structure to cache record metadata needed for populate_record_field() */
struct ColumnIOData
{
    Oid         typid;          /* column type id */
    int32       typmod;         /* column type modifier */
    TypeCat     typcat;         /* column type category */
    ScalarIOData scalar_io;     /* metadata cache for directi conversion
                                 * through input function */
    union
    {
        ArrayIOData array;
        CompositeIOData composite;
        DomainIOData domain;
    }           io;             /* metadata cache for various column type
                                 * categories */
};

/* structure to cache record metadata needed for populate_record() */
struct RecordIOData
{
    Oid         record_type;
    int32       record_typmod;
    int         ncolumns;
    ColumnIOData columns[FLEXIBLE_ARRAY_MEMBER];
};

/* per-query cache for populate_record_worker and populate_recordset_worker */
typedef struct PopulateRecordCache
{
    Oid         argtype;        /* declared type of the record argument */
    ColumnIOData c;             /* metadata cache for populate_composite() */
    MemoryContext fn_mcxt;      /* where this is stored */
} PopulateRecordCache;

/* per-call state for populate_recordset */
typedef struct PopulateRecordsetState
{
    JsonLexContext *lex;
    const char *function_name;
    HTAB       *json_hash;
    char       *saved_scalar;
    char       *save_json_start;
    JsonTokenType saved_token_type;
    Tuplestorestate *tuple_store;
    HeapTupleHeader rec;
    PopulateRecordCache *cache;
} PopulateRecordsetState;

/* common data for populate_array_json() and populate_array_dim_jsonb() */
typedef struct PopulateArrayContext
{
    ArrayBuildState *astate;    /* array build state */
    ArrayIOData *aio;           /* metadata cache */
    MemoryContext acxt;         /* array build memory context */
    MemoryContext mcxt;         /* cache memory context */
    const char *colname;        /* for diagnostics only */
    int        *dims;           /* dimensions */
    int        *sizes;          /* current dimension counters */
    int         ndims;          /* number of dimensions */
} PopulateArrayContext;

/* state for populate_array_json() */
typedef struct PopulateArrayState
{
    JsonLexContext *lex;        /* json lexer */
    PopulateArrayContext *ctx;  /* context */
    char       *element_start;  /* start of the current array element */
    char       *element_scalar; /* current array element token if it is a
                                 * scalar */
    JsonTokenType element_type; /* current array element type */
} PopulateArrayState;

/* state for json_strip_nulls */
typedef struct StripnullState
{
    JsonLexContext *lex;
    StringInfo  strval;
    bool        skip_next_null;
} StripnullState;

/* structure for generalized json/jsonb value passing */
typedef struct JsValue
{
    bool        is_json;        /* json/jsonb */
    union
    {
        struct
        {
            char       *str;    /* json string */
            int         len;    /* json string length or -1 if null-terminated */
            JsonTokenType type; /* json type */
        }           json;       /* json value */

        JsonbValue *jsonb;      /* jsonb value */
    }           val;
} JsValue;

typedef struct JsObject
{
    bool        is_json;        /* json/jsonb */
    union
    {
        HTAB       *json_hash;
        JsonbContainer *jsonb_cont;
    }           val;
} JsObject;

/* useful macros for testing JsValue properties */
#define JsValueIsNull(jsv) \
    ((jsv)->is_json ?  \
        (!(jsv)->val.json.str || (jsv)->val.json.type == JSON_TOKEN_NULL) : \
        (!(jsv)->val.jsonb || (jsv)->val.jsonb->type == jbvNull))

#define JsValueIsString(jsv) \
    ((jsv)->is_json ? (jsv)->val.json.type == JSON_TOKEN_STRING \
        : ((jsv)->val.jsonb && (jsv)->val.jsonb->type == jbvString))

#define JsObjectIsEmpty(jso) \
    ((jso)->is_json \
        ? hash_get_num_entries((jso)->val.json_hash) == 0 \
        : ((jso)->val.jsonb_cont == NULL || \
           JsonContainerSize((jso)->val.jsonb_cont) == 0))

#define JsObjectFree(jso) \
    do { \
        if ((jso)->is_json) \
            hash_destroy((jso)->val.json_hash); \
    } while (0)

/* semantic action functions for json_object_keys */
static void okeys_object_field_start(void *state, char *fname, bool isnull);
static void okeys_array_start(void *state);
static void okeys_scalar(void *state, char *token, JsonTokenType tokentype);

/* semantic action functions for json_get* functions */
static void get_object_start(void *state);
static void get_object_end(void *state);
static void get_object_field_start(void *state, char *fname, bool isnull);
static void get_object_field_end(void *state, char *fname, bool isnull);
static void get_array_start(void *state);
static void get_array_end(void *state);
static void get_array_element_start(void *state, bool isnull);
static void get_array_element_end(void *state, bool isnull);
static void get_scalar(void *state, char *token, JsonTokenType tokentype);

/* common worker function for json getter functions */
static Datum get_path_all(FunctionCallInfo fcinfo, bool as_text);
static text *get_worker(text *json, char **tpath, int *ipath, int npath,
                        bool normalize_results);
static Datum get_jsonb_path_all(FunctionCallInfo fcinfo, bool as_text);
static text *JsonbValueAsText(JsonbValue *v);

/* semantic action functions for json_array_length */
static void alen_object_start(void *state);
static void alen_scalar(void *state, char *token, JsonTokenType tokentype);
static void alen_array_element_start(void *state, bool isnull);

/* common workers for json{b}_each* functions */
static Datum each_worker(FunctionCallInfo fcinfo, bool as_text);
static Datum each_worker_jsonb(FunctionCallInfo fcinfo, const char *funcname,
                               bool as_text);

/* semantic action functions for json_each */
static void each_object_field_start(void *state, char *fname, bool isnull);
static void each_object_field_end(void *state, char *fname, bool isnull);
static void each_array_start(void *state);
static void each_scalar(void *state, char *token, JsonTokenType tokentype);

/* common workers for json{b}_array_elements_* functions */
static Datum elements_worker(FunctionCallInfo fcinfo, const char *funcname,
                             bool as_text);
static Datum elements_worker_jsonb(FunctionCallInfo fcinfo, const char *funcname,
                                   bool as_text);

/* semantic action functions for json_array_elements */
static void elements_object_start(void *state);
static void elements_array_element_start(void *state, bool isnull);
static void elements_array_element_end(void *state, bool isnull);
static void elements_scalar(void *state, char *token, JsonTokenType tokentype);

/* turn a json object into a hash table */
static HTAB *get_json_object_as_hash(char *json, int len, const char *funcname);

/* semantic actions for populate_array_json */
static void populate_array_object_start(void *_state);
static void populate_array_array_end(void *_state);
static void populate_array_element_start(void *_state, bool isnull);
static void populate_array_element_end(void *_state, bool isnull);
static void populate_array_scalar(void *_state, char *token, JsonTokenType tokentype);

/* semantic action functions for get_json_object_as_hash */
static void hash_object_field_start(void *state, char *fname, bool isnull);
static void hash_object_field_end(void *state, char *fname, bool isnull);
static void hash_array_start(void *state);
static void hash_scalar(void *state, char *token, JsonTokenType tokentype);

/* semantic action functions for populate_recordset */
static void populate_recordset_object_field_start(void *state, char *fname, bool isnull);
static void populate_recordset_object_field_end(void *state, char *fname, bool isnull);
static void populate_recordset_scalar(void *state, char *token, JsonTokenType tokentype);
static void populate_recordset_object_start(void *state);
static void populate_recordset_object_end(void *state);
static void populate_recordset_array_start(void *state);
static void populate_recordset_array_element_start(void *state, bool isnull);

/* semantic action functions for json_strip_nulls */
static void sn_object_start(void *state);
static void sn_object_end(void *state);
static void sn_array_start(void *state);
static void sn_array_end(void *state);
static void sn_object_field_start(void *state, char *fname, bool isnull);
static void sn_array_element_start(void *state, bool isnull);
static void sn_scalar(void *state, char *token, JsonTokenType tokentype);

/* worker functions for populate_record, to_record, populate_recordset and to_recordset */
static Datum populate_recordset_worker(FunctionCallInfo fcinfo, const char *funcname,
                                       bool is_json, bool have_record_arg);
static Datum populate_record_worker(FunctionCallInfo fcinfo, const char *funcname,
                                    bool is_json, bool have_record_arg);

/* helper functions for populate_record[set] */
static HeapTupleHeader populate_record(TupleDesc tupdesc, RecordIOData **record_p,
                                       HeapTupleHeader defaultval, MemoryContext mcxt,
                                       JsObject *obj);
static void get_record_type_from_argument(FunctionCallInfo fcinfo,
                                          const char *funcname,
                                          PopulateRecordCache *cache);
static void get_record_type_from_query(FunctionCallInfo fcinfo,
                                       const char *funcname,
                                       PopulateRecordCache *cache);
static void JsValueToJsObject(JsValue *jsv, JsObject *jso);
static Datum populate_composite(CompositeIOData *io, Oid typid,
                                const char *colname, MemoryContext mcxt,
                                HeapTupleHeader defaultval, JsValue *jsv, bool isnull);
static Datum populate_scalar(ScalarIOData *io, Oid typid, int32 typmod, JsValue *jsv);
static void prepare_column_cache(ColumnIOData *column, Oid typid, int32 typmod,
                                 MemoryContext mcxt, bool need_scalar);
static Datum populate_record_field(ColumnIOData *col, Oid typid, int32 typmod,
                                   const char *colname, MemoryContext mcxt, Datum defaultval,
                                   JsValue *jsv, bool *isnull);
static RecordIOData *allocate_record_info(MemoryContext mcxt, int ncolumns);
static bool JsObjectGetField(JsObject *obj, char *field, JsValue *jsv);
static void populate_recordset_record(PopulateRecordsetState *state, JsObject *obj);
static void populate_array_json(PopulateArrayContext *ctx, char *json, int len);
static void populate_array_dim_jsonb(PopulateArrayContext *ctx, JsonbValue *jbv,
                                     int ndim);
static void populate_array_report_expected_array(PopulateArrayContext *ctx, int ndim);
static void populate_array_assign_ndims(PopulateArrayContext *ctx, int ndims);
static void populate_array_check_dimension(PopulateArrayContext *ctx, int ndim);
static void populate_array_element(PopulateArrayContext *ctx, int ndim, JsValue *jsv);
static Datum populate_array(ArrayIOData *aio, const char *colname,
                            MemoryContext mcxt, JsValue *jsv);
static Datum populate_domain(DomainIOData *io, Oid typid, const char *colname,
                             MemoryContext mcxt, JsValue *jsv, bool isnull);

/* functions supporting jsonb_delete, jsonb_set and jsonb_concat */
static JsonbValue *IteratorConcat(JsonbIterator **it1, JsonbIterator **it2,
                                  JsonbParseState **state);
static JsonbValue *setPath(JsonbIterator **it, Datum *path_elems,
                           bool *path_nulls, int path_len,
                           JsonbParseState **st, int level, Jsonb *newval,
                           int op_type);
static void setPathObject(JsonbIterator **it, Datum *path_elems,
                          bool *path_nulls, int path_len, JsonbParseState **st,
                          int level,
                          Jsonb *newval, uint32 npairs, int op_type);
static void setPathArray(JsonbIterator **it, Datum *path_elems,
                         bool *path_nulls, int path_len, JsonbParseState **st,
                         int level, Jsonb *newval, uint32 nelems, int op_type);
static void addJsonbToParseState(JsonbParseState **jbps, Jsonb *jb);

/* function supporting iterate_json_values */
static void iterate_values_scalar(void *state, char *token, JsonTokenType tokentype);
static void iterate_values_object_field_start(void *state, char *fname, bool isnull);

/* functions supporting transform_json_string_values */
static void transform_string_values_object_start(void *state);
static void transform_string_values_object_end(void *state);
static void transform_string_values_array_start(void *state);
static void transform_string_values_array_end(void *state);
static void transform_string_values_object_field_start(void *state, char *fname, bool isnull);
static void transform_string_values_array_element_start(void *state, bool isnull);
static void transform_string_values_scalar(void *state, char *token, JsonTokenType tokentype);

/*
 * SQL function json_object_keys
 *
 * Returns the set of keys for the object argument.
 *
 * This SRF operates in value-per-call mode. It processes the
 * object during the first call, and the keys are simply stashed
 * in an array, whose size is expanded as necessary. This is probably
 * safe enough for a list of keys of a single object, since they are
 * limited in size to NAMEDATALEN and the number of keys is unlikely to
 * be so huge that it has major memory implications.
 */
Datum
jsonb_object_keys(PG_FUNCTION_ARGS)
{
    FuncCallContext *funcctx;
    OkeysState *state;
    int         i;

    if (SRF_IS_FIRSTCALL())
    {
        MemoryContext oldcontext;
        Jsonb      *jb = PG_GETARG_JSONB_P(0);
        bool        skipNested = false;
        JsonbIterator *it;
        JsonbValue  v;
        JsonbIteratorToken r;

        if (JB_ROOT_IS_SCALAR(jb))
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                     errmsg("cannot call %s on a scalar",
                            "jsonb_object_keys")));
        else if (JB_ROOT_IS_ARRAY(jb))
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                     errmsg("cannot call %s on an array",
                            "jsonb_object_keys")));

        funcctx = SRF_FIRSTCALL_INIT();
        oldcontext = MemoryContextSwitchTo(funcctx->multi_call_memory_ctx);

        state = palloc(sizeof(OkeysState));

        state->result_size = JB_ROOT_COUNT(jb);
        state->result_count = 0;
        state->sent_count = 0;
        state->result = palloc(state->result_size * sizeof(char *));

        it = JsonbIteratorInit(&jb->root);

        while ((r = JsonbIteratorNext(&it, &v, skipNested)) != WJB_DONE)
        {
            skipNested = true;

            if (r == WJB_KEY)
            {
                char       *cstr;

                cstr = palloc(v.val.string.len + 1 * sizeof(char));
                memcpy(cstr, v.val.string.val, v.val.string.len);
                cstr[v.val.string.len] = '\0';
                state->result[state->result_count++] = cstr;
            }
        }

        MemoryContextSwitchTo(oldcontext);
        funcctx->user_fctx = (void *) state;
    }

    funcctx = SRF_PERCALL_SETUP();
    state = (OkeysState *) funcctx->user_fctx;

    if (state->sent_count < state->result_count)
    {
        char       *nxt = state->result[state->sent_count++];

        SRF_RETURN_NEXT(funcctx, CStringGetTextDatum(nxt));
    }

    /* cleanup to reduce or eliminate memory leaks */
    for (i = 0; i < state->result_count; i++)
        pfree(state->result[i]);
    pfree(state->result);
    pfree(state);

    SRF_RETURN_DONE(funcctx);
}


Datum
json_object_keys(PG_FUNCTION_ARGS)
{
    FuncCallContext *funcctx;
    OkeysState *state;
    int         i;

    if (SRF_IS_FIRSTCALL())
    {
        text       *json = PG_GETARG_TEXT_PP(0);
        JsonLexContext *lex = makeJsonLexContext(json, true);
        JsonSemAction *sem;
        MemoryContext oldcontext;

        funcctx = SRF_FIRSTCALL_INIT();
        oldcontext = MemoryContextSwitchTo(funcctx->multi_call_memory_ctx);

        state = palloc(sizeof(OkeysState));
        sem = palloc0(sizeof(JsonSemAction));

        state->lex = lex;
        state->result_size = 256;
        state->result_count = 0;
        state->sent_count = 0;
        state->result = palloc(256 * sizeof(char *));

        sem->semstate = (void *) state;
        sem->array_start = okeys_array_start;
        sem->scalar = okeys_scalar;
        sem->object_field_start = okeys_object_field_start;
        /* remainder are all NULL, courtesy of palloc0 above */

        pg_parse_json(lex, sem);
        /* keys are now in state->result */

        pfree(lex->strval->data);
        pfree(lex->strval);
        pfree(lex);
        pfree(sem);

        MemoryContextSwitchTo(oldcontext);
        funcctx->user_fctx = (void *) state;
    }

    funcctx = SRF_PERCALL_SETUP();
    state = (OkeysState *) funcctx->user_fctx;

    if (state->sent_count < state->result_count)
    {
        char       *nxt = state->result[state->sent_count++];

        SRF_RETURN_NEXT(funcctx, CStringGetTextDatum(nxt));
    }

    /* cleanup to reduce or eliminate memory leaks */
    for (i = 0; i < state->result_count; i++)
        pfree(state->result[i]);
    pfree(state->result);
    pfree(state);

    SRF_RETURN_DONE(funcctx);
}

static void
okeys_object_field_start(void *state, char *fname, bool isnull)
{
    OkeysState *_state = (OkeysState *) state;

    /* only collecting keys for the top level object */
    if (_state->lex->lex_level != 1)
        return;

    /* enlarge result array if necessary */
    if (_state->result_count >= _state->result_size)
    {
        _state->result_size *= 2;
        _state->result = (char **)
            repalloc(_state->result, sizeof(char *) * _state->result_size);
    }

    /* save a copy of the field name */
    _state->result[_state->result_count++] = pstrdup(fname);
}

static void
okeys_array_start(void *state)
{
    OkeysState *_state = (OkeysState *) state;

    /* top level must be a json object */
    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot call %s on an array",
                        "json_object_keys")));
}

static void
okeys_scalar(void *state, char *token, JsonTokenType tokentype)
{
    OkeysState *_state = (OkeysState *) state;

    /* top level must be a json object */
    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot call %s on a scalar",
                        "json_object_keys")));
}

/*
 * json and jsonb getter functions
 * these implement the -> ->> #> and #>> operators
 * and the json{b?}_extract_path*(json, text, ...) functions
 */


Datum
json_object_field(PG_FUNCTION_ARGS)
{
    text       *json = PG_GETARG_TEXT_PP(0);
    text       *fname = PG_GETARG_TEXT_PP(1);
    char       *fnamestr = text_to_cstring(fname);
    text       *result;

    result = get_worker(json, &fnamestr, NULL, 1, false);

    if (result != NULL)
        PG_RETURN_TEXT_P(result);
    else
        PG_RETURN_NULL();
}

Datum
jsonb_object_field(PG_FUNCTION_ARGS)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);
    text       *key = PG_GETARG_TEXT_PP(1);
    JsonbValue *v;
    JsonbValue  vbuf;

    if (!JB_ROOT_IS_OBJECT(jb))
        PG_RETURN_NULL();

    v = getKeyJsonValueFromContainer(&jb->root,
                                     VARDATA_ANY(key),
                                     VARSIZE_ANY_EXHDR(key),
                                     &vbuf);

    if (v != NULL)
        PG_RETURN_JSONB_P(JsonbValueToJsonb(v));

    PG_RETURN_NULL();
}

Datum
json_object_field_text(PG_FUNCTION_ARGS)
{
    text       *json = PG_GETARG_TEXT_PP(0);
    text       *fname = PG_GETARG_TEXT_PP(1);
    char       *fnamestr = text_to_cstring(fname);
    text       *result;

    result = get_worker(json, &fnamestr, NULL, 1, true);

    if (result != NULL)
        PG_RETURN_TEXT_P(result);
    else
        PG_RETURN_NULL();
}

Datum
jsonb_object_field_text(PG_FUNCTION_ARGS)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);
    text       *key = PG_GETARG_TEXT_PP(1);
    JsonbValue *v;
    JsonbValue  vbuf;

    if (!JB_ROOT_IS_OBJECT(jb))
        PG_RETURN_NULL();

    v = getKeyJsonValueFromContainer(&jb->root,
                                     VARDATA_ANY(key),
                                     VARSIZE_ANY_EXHDR(key),
                                     &vbuf);

    if (v != NULL && v->type != jbvNull)
        PG_RETURN_TEXT_P(JsonbValueAsText(v));

    PG_RETURN_NULL();
}

Datum
json_array_element(PG_FUNCTION_ARGS)
{
    text       *json = PG_GETARG_TEXT_PP(0);
    int         element = PG_GETARG_INT32(1);
    text       *result;

    result = get_worker(json, NULL, &element, 1, false);

    if (result != NULL)
        PG_RETURN_TEXT_P(result);
    else
        PG_RETURN_NULL();
}

Datum
jsonb_array_element(PG_FUNCTION_ARGS)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);
    int         element = PG_GETARG_INT32(1);
    JsonbValue *v;

    if (!JB_ROOT_IS_ARRAY(jb))
        PG_RETURN_NULL();

    /* Handle negative subscript */
    if (element < 0)
    {
        uint32      nelements = JB_ROOT_COUNT(jb);

        if (-element > nelements)
            PG_RETURN_NULL();
        else
            element += nelements;
    }

    v = getIthJsonbValueFromContainer(&jb->root, element);
    if (v != NULL)
        PG_RETURN_JSONB_P(JsonbValueToJsonb(v));

    PG_RETURN_NULL();
}

Datum
json_array_element_text(PG_FUNCTION_ARGS)
{
    text       *json = PG_GETARG_TEXT_PP(0);
    int         element = PG_GETARG_INT32(1);
    text       *result;

    result = get_worker(json, NULL, &element, 1, true);

    if (result != NULL)
        PG_RETURN_TEXT_P(result);
    else
        PG_RETURN_NULL();
}

Datum
jsonb_array_element_text(PG_FUNCTION_ARGS)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);
    int         element = PG_GETARG_INT32(1);
    JsonbValue *v;

    if (!JB_ROOT_IS_ARRAY(jb))
        PG_RETURN_NULL();

    /* Handle negative subscript */
    if (element < 0)
    {
        uint32      nelements = JB_ROOT_COUNT(jb);

        if (-element > nelements)
            PG_RETURN_NULL();
        else
            element += nelements;
    }

    v = getIthJsonbValueFromContainer(&jb->root, element);

    if (v != NULL && v->type != jbvNull)
        PG_RETURN_TEXT_P(JsonbValueAsText(v));

    PG_RETURN_NULL();
}

Datum
json_extract_path(PG_FUNCTION_ARGS)
{
    return get_path_all(fcinfo, false);
}

Datum
json_extract_path_text(PG_FUNCTION_ARGS)
{
    return get_path_all(fcinfo, true);
}

/*
 * common routine for extract_path functions
 */
static Datum
get_path_all(FunctionCallInfo fcinfo, bool as_text)
{
    text       *json = PG_GETARG_TEXT_PP(0);
    ArrayType  *path = PG_GETARG_ARRAYTYPE_P(1);
    text       *result;
    Datum      *pathtext;
    bool       *pathnulls;
    int         npath;
    char      **tpath;
    int        *ipath;
    int         i;

    /*
     * If the array contains any null elements, return NULL, on the grounds
     * that you'd have gotten NULL if any RHS value were NULL in a nested
     * series of applications of the -> operator.  (Note: because we also
     * return NULL for error cases such as no-such-field, this is true
     * regardless of the contents of the rest of the array.)
     */
    if (array_contains_nulls(path))
        PG_RETURN_NULL();

    deconstruct_array(path, TEXTOID, -1, false, 'i',
                      &pathtext, &pathnulls, &npath);

    tpath = palloc(npath * sizeof(char *));
    ipath = palloc(npath * sizeof(int));

    for (i = 0; i < npath; i++)
    {
        Assert(!pathnulls[i]);
        tpath[i] = TextDatumGetCString(pathtext[i]);

        /*
         * we have no idea at this stage what structure the document is so
         * just convert anything in the path that we can to an integer and set
         * all the other integers to INT_MIN which will never match.
         */
        if (*tpath[i] != '\0')
        {
            long        ind;
            char       *endptr;

            errno = 0;
            ind = strtol(tpath[i], &endptr, 10);
            if (*endptr == '\0' && errno == 0 && ind <= INT_MAX && ind >= INT_MIN)
                ipath[i] = (int) ind;
            else
                ipath[i] = INT_MIN;
        }
        else
            ipath[i] = INT_MIN;
    }

    result = get_worker(json, tpath, ipath, npath, as_text);

    if (result != NULL)
        PG_RETURN_TEXT_P(result);
    else
        PG_RETURN_NULL();
}

/*
 * get_worker
 *
 * common worker for all the json getter functions
 *
 * json: JSON object (in text form)
 * tpath[]: field name(s) to extract
 * ipath[]: array index(es) (zero-based) to extract, accepts negatives
 * npath: length of tpath[] and/or ipath[]
 * normalize_results: true to de-escape string and null scalars
 *
 * tpath can be NULL, or any one tpath[] entry can be NULL, if an object
 * field is not to be matched at that nesting level.  Similarly, ipath can
 * be NULL, or any one ipath[] entry can be INT_MIN if an array element is
 * not to be matched at that nesting level (a json datum should never be
 * large enough to have -INT_MIN elements due to MaxAllocSize restriction).
 */
static text *
get_worker(text *json,
           char **tpath,
           int *ipath,
           int npath,
           bool normalize_results)
{
    JsonLexContext *lex = makeJsonLexContext(json, true);
    JsonSemAction *sem = palloc0(sizeof(JsonSemAction));
    GetState   *state = palloc0(sizeof(GetState));

    Assert(npath >= 0);

    state->lex = lex;
    /* is it "_as_text" variant? */
    state->normalize_results = normalize_results;
    state->npath = npath;
    state->path_names = tpath;
    state->path_indexes = ipath;
    state->pathok = palloc0(sizeof(bool) * npath);
    state->array_cur_index = palloc(sizeof(int) * npath);

    if (npath > 0)
        state->pathok[0] = true;

    sem->semstate = (void *) state;

    /*
     * Not all variants need all the semantic routines. Only set the ones that
     * are actually needed for maximum efficiency.
     */
    sem->scalar = get_scalar;
    if (npath == 0)
    {
        sem->object_start = get_object_start;
        sem->object_end = get_object_end;
        sem->array_start = get_array_start;
        sem->array_end = get_array_end;
    }
    if (tpath != NULL)
    {
        sem->object_field_start = get_object_field_start;
        sem->object_field_end = get_object_field_end;
    }
    if (ipath != NULL)
    {
        sem->array_start = get_array_start;
        sem->array_element_start = get_array_element_start;
        sem->array_element_end = get_array_element_end;
    }

    pg_parse_json(lex, sem);

    return state->tresult;
}

static void
get_object_start(void *state)
{
    GetState   *_state = (GetState *) state;
    int         lex_level = _state->lex->lex_level;

    if (lex_level == 0 && _state->npath == 0)
    {
        /*
         * Special case: we should match the entire object.  We only need this
         * at outermost level because at nested levels the match will have
         * been started by the outer field or array element callback.
         */
        _state->result_start = _state->lex->token_start;
    }
}

static void
get_object_end(void *state)
{
    GetState   *_state = (GetState *) state;
    int         lex_level = _state->lex->lex_level;

    if (lex_level == 0 && _state->npath == 0)
    {
        /* Special case: return the entire object */
        char       *start = _state->result_start;
        int         len = _state->lex->prev_token_terminator - start;

        _state->tresult = cstring_to_text_with_len(start, len);
    }
}

static void
get_object_field_start(void *state, char *fname, bool isnull)
{
    GetState   *_state = (GetState *) state;
    bool        get_next = false;
    int         lex_level = _state->lex->lex_level;

    if (lex_level <= _state->npath &&
        _state->pathok[lex_level - 1] &&
        _state->path_names != NULL &&
        _state->path_names[lex_level - 1] != NULL &&
        strcmp(fname, _state->path_names[lex_level - 1]) == 0)
    {
        if (lex_level < _state->npath)
        {
            /* if not at end of path just mark path ok */
            _state->pathok[lex_level] = true;
        }
        else
        {
            /* end of path, so we want this value */
            get_next = true;
        }
    }

    if (get_next)
    {
        /* this object overrides any previous matching object */
        _state->tresult = NULL;
        _state->result_start = NULL;

        if (_state->normalize_results &&
            _state->lex->token_type == JSON_TOKEN_STRING)
        {
            /* for as_text variants, tell get_scalar to set it for us */
            _state->next_scalar = true;
        }
        else
        {
            /* for non-as_text variants, just note the json starting point */
            _state->result_start = _state->lex->token_start;
        }
    }
}

static void
get_object_field_end(void *state, char *fname, bool isnull)
{
    GetState   *_state = (GetState *) state;
    bool        get_last = false;
    int         lex_level = _state->lex->lex_level;

    /* same tests as in get_object_field_start */
    if (lex_level <= _state->npath &&
        _state->pathok[lex_level - 1] &&
        _state->path_names != NULL &&
        _state->path_names[lex_level - 1] != NULL &&
        strcmp(fname, _state->path_names[lex_level - 1]) == 0)
    {
        if (lex_level < _state->npath)
        {
            /* done with this field so reset pathok */
            _state->pathok[lex_level] = false;
        }
        else
        {
            /* end of path, so we want this value */
            get_last = true;
        }
    }

    /* for as_text scalar case, our work is already done */
    if (get_last && _state->result_start != NULL)
    {
        /*
         * make a text object from the string from the previously noted json
         * start up to the end of the previous token (the lexer is by now
         * ahead of us on whatever came after what we're interested in).
         */
        if (isnull && _state->normalize_results)
            _state->tresult = (text *) NULL;
        else
        {
            char       *start = _state->result_start;
            int         len = _state->lex->prev_token_terminator - start;

            _state->tresult = cstring_to_text_with_len(start, len);
        }

        /* this should be unnecessary but let's do it for cleanliness: */
        _state->result_start = NULL;
    }
}

static void
get_array_start(void *state)
{
    GetState   *_state = (GetState *) state;
    int         lex_level = _state->lex->lex_level;

    if (lex_level < _state->npath)
    {
        /* Initialize counting of elements in this array */
        _state->array_cur_index[lex_level] = -1;

        /* INT_MIN value is reserved to represent invalid subscript */
        if (_state->path_indexes[lex_level] < 0 &&
            _state->path_indexes[lex_level] != INT_MIN)
        {
            /* Negative subscript -- convert to positive-wise subscript */
            int         nelements = json_count_array_elements(_state->lex);

            if (-_state->path_indexes[lex_level] <= nelements)
                _state->path_indexes[lex_level] += nelements;
        }
    }
    else if (lex_level == 0 && _state->npath == 0)
    {
        /*
         * Special case: we should match the entire array.  We only need this
         * at the outermost level because at nested levels the match will have
         * been started by the outer field or array element callback.
         */
        _state->result_start = _state->lex->token_start;
    }
}

static void
get_array_end(void *state)
{
    GetState   *_state = (GetState *) state;
    int         lex_level = _state->lex->lex_level;

    if (lex_level == 0 && _state->npath == 0)
    {
        /* Special case: return the entire array */
        char       *start = _state->result_start;
        int         len = _state->lex->prev_token_terminator - start;

        _state->tresult = cstring_to_text_with_len(start, len);
    }
}

static void
get_array_element_start(void *state, bool isnull)
{
    GetState   *_state = (GetState *) state;
    bool        get_next = false;
    int         lex_level = _state->lex->lex_level;

    /* Update array element counter */
    if (lex_level <= _state->npath)
        _state->array_cur_index[lex_level - 1]++;

    if (lex_level <= _state->npath &&
        _state->pathok[lex_level - 1] &&
        _state->path_indexes != NULL &&
        _state->array_cur_index[lex_level - 1] == _state->path_indexes[lex_level - 1])
    {
        if (lex_level < _state->npath)
        {
            /* if not at end of path just mark path ok */
            _state->pathok[lex_level] = true;
        }
        else
        {
            /* end of path, so we want this value */
            get_next = true;
        }
    }

    /* same logic as for objects */
    if (get_next)
    {
        _state->tresult = NULL;
        _state->result_start = NULL;

        if (_state->normalize_results &&
            _state->lex->token_type == JSON_TOKEN_STRING)
        {
            _state->next_scalar = true;
        }
        else
        {
            _state->result_start = _state->lex->token_start;
        }
    }
}

static void
get_array_element_end(void *state, bool isnull)
{
    GetState   *_state = (GetState *) state;
    bool        get_last = false;
    int         lex_level = _state->lex->lex_level;

    /* same tests as in get_array_element_start */
    if (lex_level <= _state->npath &&
        _state->pathok[lex_level - 1] &&
        _state->path_indexes != NULL &&
        _state->array_cur_index[lex_level - 1] == _state->path_indexes[lex_level - 1])
    {
        if (lex_level < _state->npath)
        {
            /* done with this element so reset pathok */
            _state->pathok[lex_level] = false;
        }
        else
        {
            /* end of path, so we want this value */
            get_last = true;
        }
    }

    /* same logic as for objects */
    if (get_last && _state->result_start != NULL)
    {
        if (isnull && _state->normalize_results)
            _state->tresult = (text *) NULL;
        else
        {
            char       *start = _state->result_start;
            int         len = _state->lex->prev_token_terminator - start;

            _state->tresult = cstring_to_text_with_len(start, len);
        }

        _state->result_start = NULL;
    }
}

static void
get_scalar(void *state, char *token, JsonTokenType tokentype)
{
    GetState   *_state = (GetState *) state;
    int         lex_level = _state->lex->lex_level;

    /* Check for whole-object match */
    if (lex_level == 0 && _state->npath == 0)
    {
        if (_state->normalize_results && tokentype == JSON_TOKEN_STRING)
        {
            /* we want the de-escaped string */
            _state->next_scalar = true;
        }
        else if (_state->normalize_results && tokentype == JSON_TOKEN_NULL)
        {
            _state->tresult = (text *) NULL;
        }
        else
        {
            /*
             * This is a bit hokey: we will suppress whitespace after the
             * scalar token, but not whitespace before it.  Probably not worth
             * doing our own space-skipping to avoid that.
             */
            char       *start = _state->lex->input;
            int         len = _state->lex->prev_token_terminator - start;

            _state->tresult = cstring_to_text_with_len(start, len);
        }
    }

    if (_state->next_scalar)
    {
        /* a de-escaped text value is wanted, so supply it */
        _state->tresult = cstring_to_text(token);
        /* make sure the next call to get_scalar doesn't overwrite it */
        _state->next_scalar = false;
    }
}

Datum
jsonb_extract_path(PG_FUNCTION_ARGS)
{
    return get_jsonb_path_all(fcinfo, false);
}

Datum
jsonb_extract_path_text(PG_FUNCTION_ARGS)
{
    return get_jsonb_path_all(fcinfo, true);
}

static Datum
get_jsonb_path_all(FunctionCallInfo fcinfo, bool as_text)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);
    ArrayType  *path = PG_GETARG_ARRAYTYPE_P(1);
    Datum      *pathtext;
    bool       *pathnulls;
    int         npath;
    int         i;
    bool        have_object = false,
                have_array = false;
    JsonbValue *jbvp = NULL;
    JsonbValue  jbvbuf;
    JsonbContainer *container;

    /*
     * If the array contains any null elements, return NULL, on the grounds
     * that you'd have gotten NULL if any RHS value were NULL in a nested
     * series of applications of the -> operator.  (Note: because we also
     * return NULL for error cases such as no-such-field, this is true
     * regardless of the contents of the rest of the array.)
     */
    if (array_contains_nulls(path))
        PG_RETURN_NULL();

    deconstruct_array(path, TEXTOID, -1, false, 'i',
                      &pathtext, &pathnulls, &npath);

    /* Identify whether we have object, array, or scalar at top-level */
    container = &jb->root;

    if (JB_ROOT_IS_OBJECT(jb))
        have_object = true;
    else if (JB_ROOT_IS_ARRAY(jb) && !JB_ROOT_IS_SCALAR(jb))
        have_array = true;
    else
    {
        Assert(JB_ROOT_IS_ARRAY(jb) && JB_ROOT_IS_SCALAR(jb));
        /* Extract the scalar value, if it is what we'll return */
        if (npath <= 0)
            jbvp = getIthJsonbValueFromContainer(container, 0);
    }

    /*
     * If the array is empty, return the entire LHS object, on the grounds
     * that we should do zero field or element extractions.  For the
     * non-scalar case we can just hand back the object without much work. For
     * the scalar case, fall through and deal with the value below the loop.
     * (This inconsistency arises because there's no easy way to generate a
     * JsonbValue directly for root-level containers.)
     */
    if (npath <= 0 && jbvp == NULL)
    {
        if (as_text)
        {
            PG_RETURN_TEXT_P(cstring_to_text(JsonbToCString(NULL,
                                                            container,
                                                            VARSIZE(jb))));
        }
        else
        {
            /* not text mode - just hand back the jsonb */
            PG_RETURN_JSONB_P(jb);
        }
    }

    for (i = 0; i < npath; i++)
    {
        if (have_object)
        {
            jbvp = getKeyJsonValueFromContainer(container,
                                                VARDATA(pathtext[i]),
                                                VARSIZE(pathtext[i]) - VARHDRSZ,
                                                &jbvbuf);
        }
        else if (have_array)
        {
            long        lindex;
            uint32      index;
            char       *indextext = TextDatumGetCString(pathtext[i]);
            char       *endptr;

            errno = 0;
            lindex = strtol(indextext, &endptr, 10);
            if (endptr == indextext || *endptr != '\0' || errno != 0 ||
                lindex > INT_MAX || lindex < INT_MIN)
                PG_RETURN_NULL();

            if (lindex >= 0)
            {
                index = (uint32) lindex;
            }
            else
            {
                /* Handle negative subscript */
                uint32      nelements;

                /* Container must be array, but make sure */
                if (!JsonContainerIsArray(container))
                    elog(ERROR, "not a jsonb array");

                nelements = JsonContainerSize(container);

                if (-lindex > nelements)
                    PG_RETURN_NULL();
                else
                    index = nelements + lindex;
            }

            jbvp = getIthJsonbValueFromContainer(container, index);
        }
        else
        {
            /* scalar, extraction yields a null */
            PG_RETURN_NULL();
        }

        if (jbvp == NULL)
            PG_RETURN_NULL();
        else if (i == npath - 1)
            break;

        if (jbvp->type == jbvBinary)
        {
            container = jbvp->val.binary.data;
            have_object = JsonContainerIsObject(container);
            have_array = JsonContainerIsArray(container);
            Assert(!JsonContainerIsScalar(container));
        }
        else
        {
            Assert(IsAJsonbScalar(jbvp));
            have_object = false;
            have_array = false;
        }
    }

    if (as_text)
    {
        if (jbvp->type == jbvNull)
            PG_RETURN_NULL();

        PG_RETURN_TEXT_P(JsonbValueAsText(jbvp));
    }
    else
    {
        Jsonb      *res = JsonbValueToJsonb(jbvp);

        /* not text mode - just hand back the jsonb */
        PG_RETURN_JSONB_P(res);
    }
}

/*
 * Return the text representation of the given JsonbValue.
 */
static text *
JsonbValueAsText(JsonbValue *v)
{
    switch (v->type)
    {
        case jbvNull:
            return NULL;

        case jbvBool:
            return v->val.boolean ?
                cstring_to_text_with_len("true", 4) :
                cstring_to_text_with_len("false", 5);

        case jbvString:
            return cstring_to_text_with_len(v->val.string.val,
                                            v->val.string.len);

        case jbvNumeric:
            {
                Datum       cstr;

                cstr = DirectFunctionCall1(numeric_out,
                                           PointerGetDatum(v->val.numeric));

                return cstring_to_text(DatumGetCString(cstr));
            }

        case jbvBinary:
            {
                StringInfoData jtext;

                initStringInfo(&jtext);
                (void) JsonbToCString(&jtext, v->val.binary.data,
                                      v->val.binary.len);

                return cstring_to_text_with_len(jtext.data, jtext.len);
            }

        default:
            elog(ERROR, "unrecognized jsonb type: %d", (int) v->type);
            return NULL;
    }
}

/*
 * SQL function json_array_length(json) -> int
 */
Datum
json_array_length(PG_FUNCTION_ARGS)
{
    text       *json = PG_GETARG_TEXT_PP(0);
    AlenState  *state;
    JsonLexContext *lex;
    JsonSemAction *sem;

    lex = makeJsonLexContext(json, false);
    state = palloc0(sizeof(AlenState));
    sem = palloc0(sizeof(JsonSemAction));

    /* palloc0 does this for us */
#if 0
    state->count = 0;
#endif
    state->lex = lex;

    sem->semstate = (void *) state;
    sem->object_start = alen_object_start;
    sem->scalar = alen_scalar;
    sem->array_element_start = alen_array_element_start;

    pg_parse_json(lex, sem);

    PG_RETURN_INT32(state->count);
}

Datum
jsonb_array_length(PG_FUNCTION_ARGS)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);

    if (JB_ROOT_IS_SCALAR(jb))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot get array length of a scalar")));
    else if (!JB_ROOT_IS_ARRAY(jb))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot get array length of a non-array")));

    PG_RETURN_INT32(JB_ROOT_COUNT(jb));
}

/*
 * These next two checks ensure that the json is an array (since it can't be
 * a scalar or an object).
 */

static void
alen_object_start(void *state)
{
    AlenState  *_state = (AlenState *) state;

    /* json structure check */
    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot get array length of a non-array")));
}

static void
alen_scalar(void *state, char *token, JsonTokenType tokentype)
{
    AlenState  *_state = (AlenState *) state;

    /* json structure check */
    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot get array length of a scalar")));
}

static void
alen_array_element_start(void *state, bool isnull)
{
    AlenState  *_state = (AlenState *) state;

    /* just count up all the level 1 elements */
    if (_state->lex->lex_level == 1)
        _state->count++;
}

/*
 * SQL function json_each and json_each_text
 *
 * decompose a json object into key value pairs.
 *
 * Unlike json_object_keys() these SRFs operate in materialize mode,
 * stashing results into a Tuplestore object as they go.
 * The construction of tuples is done using a temporary memory context
 * that is cleared out after each tuple is built.
 */
Datum
json_each(PG_FUNCTION_ARGS)
{
    return each_worker(fcinfo, false);
}

Datum
jsonb_each(PG_FUNCTION_ARGS)
{
    return each_worker_jsonb(fcinfo, "jsonb_each", false);
}

Datum
json_each_text(PG_FUNCTION_ARGS)
{
    return each_worker(fcinfo, true);
}

Datum
jsonb_each_text(PG_FUNCTION_ARGS)
{
    return each_worker_jsonb(fcinfo, "jsonb_each_text", true);
}

static Datum
each_worker_jsonb(FunctionCallInfo fcinfo, const char *funcname, bool as_text)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);
    ReturnSetInfo *rsi;
    Tuplestorestate *tuple_store;
    TupleDesc   tupdesc;
    TupleDesc   ret_tdesc;
    MemoryContext old_cxt,
                tmp_cxt;
    bool        skipNested = false;
    JsonbIterator *it;
    JsonbValue  v;
    JsonbIteratorToken r;

    if (!JB_ROOT_IS_OBJECT(jb))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot call %s on a non-object",
                        funcname)));

    rsi = (ReturnSetInfo *) fcinfo->resultinfo;

    if (!rsi || !IsA(rsi, ReturnSetInfo) ||
        (rsi->allowedModes & SFRM_Materialize) == 0 ||
        rsi->expectedDesc == NULL)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("set-valued function called in context that "
                        "cannot accept a set")));

    rsi->returnMode = SFRM_Materialize;

    if (get_call_result_type(fcinfo, NULL, &tupdesc) != TYPEFUNC_COMPOSITE)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("function returning record called in context "
                        "that cannot accept type record")));

    old_cxt = MemoryContextSwitchTo(rsi->econtext->ecxt_per_query_memory);

    ret_tdesc = CreateTupleDescCopy(tupdesc);
    BlessTupleDesc(ret_tdesc);
    tuple_store =
        tuplestore_begin_heap(rsi->allowedModes & SFRM_Materialize_Random,
                              false, work_mem);

    MemoryContextSwitchTo(old_cxt);

    tmp_cxt = AllocSetContextCreate(CurrentMemoryContext,
                                    "jsonb_each temporary cxt",
                                    ALLOCSET_DEFAULT_SIZES);

    it = JsonbIteratorInit(&jb->root);

    while ((r = JsonbIteratorNext(&it, &v, skipNested)) != WJB_DONE)
    {
        skipNested = true;

        if (r == WJB_KEY)
        {
            text       *key;
            HeapTuple   tuple;
            Datum       values[2];
            bool        nulls[2] = {false, false};

            /* Use the tmp context so we can clean up after each tuple is done */
            old_cxt = MemoryContextSwitchTo(tmp_cxt);

            key = cstring_to_text_with_len(v.val.string.val, v.val.string.len);

            /*
             * The next thing the iterator fetches should be the value, no
             * matter what shape it is.
             */
            r = JsonbIteratorNext(&it, &v, skipNested);
            Assert(r != WJB_DONE);

            values[0] = PointerGetDatum(key);

            if (as_text)
            {
                if (v.type == jbvNull)
                {
                    /* a json null is an sql null in text mode */
                    nulls[1] = true;
                    values[1] = (Datum) NULL;
                }
                else
                    values[1] = PointerGetDatum(JsonbValueAsText(&v));
            }
            else
            {
                /* Not in text mode, just return the Jsonb */
                Jsonb      *val = JsonbValueToJsonb(&v);

                values[1] = PointerGetDatum(val);
            }

            tuple = heap_form_tuple(ret_tdesc, values, nulls);

            tuplestore_puttuple(tuple_store, tuple);

            /* clean up and switch back */
            MemoryContextSwitchTo(old_cxt);
            MemoryContextReset(tmp_cxt);
        }
    }

    MemoryContextDelete(tmp_cxt);

    rsi->setResult = tuple_store;
    rsi->setDesc = ret_tdesc;

    PG_RETURN_NULL();
}


static Datum
each_worker(FunctionCallInfo fcinfo, bool as_text)
{
    text       *json = PG_GETARG_TEXT_PP(0);
    JsonLexContext *lex;
    JsonSemAction *sem;
    ReturnSetInfo *rsi;
    MemoryContext old_cxt;
    TupleDesc   tupdesc;
    EachState  *state;

    lex = makeJsonLexContext(json, true);
    state = palloc0(sizeof(EachState));
    sem = palloc0(sizeof(JsonSemAction));

    rsi = (ReturnSetInfo *) fcinfo->resultinfo;

    if (!rsi || !IsA(rsi, ReturnSetInfo) ||
        (rsi->allowedModes & SFRM_Materialize) == 0 ||
        rsi->expectedDesc == NULL)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("set-valued function called in context that "
                        "cannot accept a set")));

    rsi->returnMode = SFRM_Materialize;

    (void) get_call_result_type(fcinfo, NULL, &tupdesc);

    /* make these in a sufficiently long-lived memory context */
    old_cxt = MemoryContextSwitchTo(rsi->econtext->ecxt_per_query_memory);

    state->ret_tdesc = CreateTupleDescCopy(tupdesc);
    BlessTupleDesc(state->ret_tdesc);
    state->tuple_store =
        tuplestore_begin_heap(rsi->allowedModes & SFRM_Materialize_Random,
                              false, work_mem);

    MemoryContextSwitchTo(old_cxt);

    sem->semstate = (void *) state;
    sem->array_start = each_array_start;
    sem->scalar = each_scalar;
    sem->object_field_start = each_object_field_start;
    sem->object_field_end = each_object_field_end;

    state->normalize_results = as_text;
    state->next_scalar = false;
    state->lex = lex;
    state->tmp_cxt = AllocSetContextCreate(CurrentMemoryContext,
                                           "json_each temporary cxt",
                                           ALLOCSET_DEFAULT_SIZES);

    pg_parse_json(lex, sem);

    MemoryContextDelete(state->tmp_cxt);

    rsi->setResult = state->tuple_store;
    rsi->setDesc = state->ret_tdesc;

    PG_RETURN_NULL();
}


static void
each_object_field_start(void *state, char *fname, bool isnull)
{
    EachState  *_state = (EachState *) state;

    /* save a pointer to where the value starts */
    if (_state->lex->lex_level == 1)
    {
        /*
         * next_scalar will be reset in the object_field_end handler, and
         * since we know the value is a scalar there is no danger of it being
         * on while recursing down the tree.
         */
        if (_state->normalize_results && _state->lex->token_type == JSON_TOKEN_STRING)
            _state->next_scalar = true;
        else
            _state->result_start = _state->lex->token_start;
    }
}

static void
each_object_field_end(void *state, char *fname, bool isnull)
{
    EachState  *_state = (EachState *) state;
    MemoryContext old_cxt;
    int         len;
    text       *val;
    HeapTuple   tuple;
    Datum       values[2];
    bool        nulls[2] = {false, false};

    /* skip over nested objects */
    if (_state->lex->lex_level != 1)
        return;

    /* use the tmp context so we can clean up after each tuple is done */
    old_cxt = MemoryContextSwitchTo(_state->tmp_cxt);

    values[0] = CStringGetTextDatum(fname);

    if (isnull && _state->normalize_results)
    {
        nulls[1] = true;
        values[1] = (Datum) 0;
    }
    else if (_state->next_scalar)
    {
        values[1] = CStringGetTextDatum(_state->normalized_scalar);
        _state->next_scalar = false;
    }
    else
    {
        len = _state->lex->prev_token_terminator - _state->result_start;
        val = cstring_to_text_with_len(_state->result_start, len);
        values[1] = PointerGetDatum(val);
    }

    tuple = heap_form_tuple(_state->ret_tdesc, values, nulls);

    tuplestore_puttuple(_state->tuple_store, tuple);

    /* clean up and switch back */
    MemoryContextSwitchTo(old_cxt);
    MemoryContextReset(_state->tmp_cxt);
}

static void
each_array_start(void *state)
{
    EachState  *_state = (EachState *) state;

    /* json structure check */
    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot deconstruct an array as an object")));
}

static void
each_scalar(void *state, char *token, JsonTokenType tokentype)
{
    EachState  *_state = (EachState *) state;

    /* json structure check */
    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot deconstruct a scalar")));

    /* supply de-escaped value if required */
    if (_state->next_scalar)
        _state->normalized_scalar = token;
}

/*
 * SQL functions json_array_elements and json_array_elements_text
 *
 * get the elements from a json array
 *
 * a lot of this processing is similar to the json_each* functions
 */

Datum
jsonb_array_elements(PG_FUNCTION_ARGS)
{
    return elements_worker_jsonb(fcinfo, "jsonb_array_elements", false);
}

Datum
jsonb_array_elements_text(PG_FUNCTION_ARGS)
{
    return elements_worker_jsonb(fcinfo, "jsonb_array_elements_text", true);
}

static Datum
elements_worker_jsonb(FunctionCallInfo fcinfo, const char *funcname,
                      bool as_text)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);
    ReturnSetInfo *rsi;
    Tuplestorestate *tuple_store;
    TupleDesc   tupdesc;
    TupleDesc   ret_tdesc;
    MemoryContext old_cxt,
                tmp_cxt;
    bool        skipNested = false;
    JsonbIterator *it;
    JsonbValue  v;
    JsonbIteratorToken r;

    if (JB_ROOT_IS_SCALAR(jb))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot extract elements from a scalar")));
    else if (!JB_ROOT_IS_ARRAY(jb))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot extract elements from an object")));

    rsi = (ReturnSetInfo *) fcinfo->resultinfo;

    if (!rsi || !IsA(rsi, ReturnSetInfo) ||
        (rsi->allowedModes & SFRM_Materialize) == 0 ||
        rsi->expectedDesc == NULL)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("set-valued function called in context that "
                        "cannot accept a set")));

    rsi->returnMode = SFRM_Materialize;

    /* it's a simple type, so don't use get_call_result_type() */
    tupdesc = rsi->expectedDesc;

    old_cxt = MemoryContextSwitchTo(rsi->econtext->ecxt_per_query_memory);

    ret_tdesc = CreateTupleDescCopy(tupdesc);
    BlessTupleDesc(ret_tdesc);
    tuple_store =
        tuplestore_begin_heap(rsi->allowedModes & SFRM_Materialize_Random,
                              false, work_mem);

    MemoryContextSwitchTo(old_cxt);

    tmp_cxt = AllocSetContextCreate(CurrentMemoryContext,
                                    "jsonb_array_elements temporary cxt",
                                    ALLOCSET_DEFAULT_SIZES);

    it = JsonbIteratorInit(&jb->root);

    while ((r = JsonbIteratorNext(&it, &v, skipNested)) != WJB_DONE)
    {
        skipNested = true;

        if (r == WJB_ELEM)
        {
            HeapTuple   tuple;
            Datum       values[1];
            bool        nulls[1] = {false};

            /* use the tmp context so we can clean up after each tuple is done */
            old_cxt = MemoryContextSwitchTo(tmp_cxt);

            if (as_text)
            {
                if (v.type == jbvNull)
                {
                    /* a json null is an sql null in text mode */
                    nulls[0] = true;
                    values[0] = (Datum) NULL;
                }
                else
                    values[0] = PointerGetDatum(JsonbValueAsText(&v));
            }
            else
            {
                /* Not in text mode, just return the Jsonb */
                Jsonb      *val = JsonbValueToJsonb(&v);

                values[0] = PointerGetDatum(val);
            }

            tuple = heap_form_tuple(ret_tdesc, values, nulls);

            tuplestore_puttuple(tuple_store, tuple);

            /* clean up and switch back */
            MemoryContextSwitchTo(old_cxt);
            MemoryContextReset(tmp_cxt);
        }
    }

    MemoryContextDelete(tmp_cxt);

    rsi->setResult = tuple_store;
    rsi->setDesc = ret_tdesc;

    PG_RETURN_NULL();
}

Datum
json_array_elements(PG_FUNCTION_ARGS)
{
    return elements_worker(fcinfo, "json_array_elements", false);
}

Datum
json_array_elements_text(PG_FUNCTION_ARGS)
{
    return elements_worker(fcinfo, "json_array_elements_text", true);
}

static Datum
elements_worker(FunctionCallInfo fcinfo, const char *funcname, bool as_text)
{
    text       *json = PG_GETARG_TEXT_PP(0);

    /* elements only needs escaped strings when as_text */
    JsonLexContext *lex = makeJsonLexContext(json, as_text);
    JsonSemAction *sem;
    ReturnSetInfo *rsi;
    MemoryContext old_cxt;
    TupleDesc   tupdesc;
    ElementsState *state;

    state = palloc0(sizeof(ElementsState));
    sem = palloc0(sizeof(JsonSemAction));

    rsi = (ReturnSetInfo *) fcinfo->resultinfo;

    if (!rsi || !IsA(rsi, ReturnSetInfo) ||
        (rsi->allowedModes & SFRM_Materialize) == 0 ||
        rsi->expectedDesc == NULL)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("set-valued function called in context that "
                        "cannot accept a set")));

    rsi->returnMode = SFRM_Materialize;

    /* it's a simple type, so don't use get_call_result_type() */
    tupdesc = rsi->expectedDesc;

    /* make these in a sufficiently long-lived memory context */
    old_cxt = MemoryContextSwitchTo(rsi->econtext->ecxt_per_query_memory);

    state->ret_tdesc = CreateTupleDescCopy(tupdesc);
    BlessTupleDesc(state->ret_tdesc);
    state->tuple_store =
        tuplestore_begin_heap(rsi->allowedModes & SFRM_Materialize_Random,
                              false, work_mem);

    MemoryContextSwitchTo(old_cxt);

    sem->semstate = (void *) state;
    sem->object_start = elements_object_start;
    sem->scalar = elements_scalar;
    sem->array_element_start = elements_array_element_start;
    sem->array_element_end = elements_array_element_end;

    state->function_name = funcname;
    state->normalize_results = as_text;
    state->next_scalar = false;
    state->lex = lex;
    state->tmp_cxt = AllocSetContextCreate(CurrentMemoryContext,
                                           "json_array_elements temporary cxt",
                                           ALLOCSET_DEFAULT_SIZES);

    pg_parse_json(lex, sem);

    MemoryContextDelete(state->tmp_cxt);

    rsi->setResult = state->tuple_store;
    rsi->setDesc = state->ret_tdesc;

    PG_RETURN_NULL();
}

static void
elements_array_element_start(void *state, bool isnull)
{
    ElementsState *_state = (ElementsState *) state;

    /* save a pointer to where the value starts */
    if (_state->lex->lex_level == 1)
    {
        /*
         * next_scalar will be reset in the array_element_end handler, and
         * since we know the value is a scalar there is no danger of it being
         * on while recursing down the tree.
         */
        if (_state->normalize_results && _state->lex->token_type == JSON_TOKEN_STRING)
            _state->next_scalar = true;
        else
            _state->result_start = _state->lex->token_start;
    }
}

static void
elements_array_element_end(void *state, bool isnull)
{
    ElementsState *_state = (ElementsState *) state;
    MemoryContext old_cxt;
    int         len;
    text       *val;
    HeapTuple   tuple;
    Datum       values[1];
    bool        nulls[1] = {false};

    /* skip over nested objects */
    if (_state->lex->lex_level != 1)
        return;

    /* use the tmp context so we can clean up after each tuple is done */
    old_cxt = MemoryContextSwitchTo(_state->tmp_cxt);

    if (isnull && _state->normalize_results)
    {
        nulls[0] = true;
        values[0] = (Datum) NULL;
    }
    else if (_state->next_scalar)
    {
        values[0] = CStringGetTextDatum(_state->normalized_scalar);
        _state->next_scalar = false;
    }
    else
    {
        len = _state->lex->prev_token_terminator - _state->result_start;
        val = cstring_to_text_with_len(_state->result_start, len);
        values[0] = PointerGetDatum(val);
    }

    tuple = heap_form_tuple(_state->ret_tdesc, values, nulls);

    tuplestore_puttuple(_state->tuple_store, tuple);

    /* clean up and switch back */
    MemoryContextSwitchTo(old_cxt);
    MemoryContextReset(_state->tmp_cxt);
}

static void
elements_object_start(void *state)
{
    ElementsState *_state = (ElementsState *) state;

    /* json structure check */
    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot call %s on a non-array",
                        _state->function_name)));
}

static void
elements_scalar(void *state, char *token, JsonTokenType tokentype)
{
    ElementsState *_state = (ElementsState *) state;

    /* json structure check */
    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot call %s on a scalar",
                        _state->function_name)));

    /* supply de-escaped value if required */
    if (_state->next_scalar)
        _state->normalized_scalar = token;
}

/*
 * SQL function json_populate_record
 *
 * set fields in a record from the argument json
 *
 * Code adapted shamelessly from hstore's populate_record
 * which is in turn partly adapted from record_out.
 *
 * The json is decomposed into a hash table, in which each
 * field in the record is then looked up by name. For jsonb
 * we fetch the values direct from the object.
 */
Datum
jsonb_populate_record(PG_FUNCTION_ARGS)
{
    return populate_record_worker(fcinfo, "jsonb_populate_record",
                                  false, true);
}

Datum
jsonb_to_record(PG_FUNCTION_ARGS)
{
    return populate_record_worker(fcinfo, "jsonb_to_record",
                                  false, false);
}

Datum
json_populate_record(PG_FUNCTION_ARGS)
{
    return populate_record_worker(fcinfo, "json_populate_record",
                                  true, true);
}

Datum
json_to_record(PG_FUNCTION_ARGS)
{
    return populate_record_worker(fcinfo, "json_to_record",
                                  true, false);
}

/* helper function for diagnostics */
static void
populate_array_report_expected_array(PopulateArrayContext *ctx, int ndim)
{
    if (ndim <= 0)
    {
        if (ctx->colname)
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),
                     errmsg("expected JSON array"),
                     errhint("See the value of key \"%s\".", ctx->colname)));
        else
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),
                     errmsg("expected JSON array")));
    }
    else
    {
        StringInfoData indices;
        int         i;

        initStringInfo(&indices);

        Assert(ctx->ndims > 0 && ndim < ctx->ndims);

        for (i = 0; i < ndim; i++)
            appendStringInfo(&indices, "[%d]", ctx->sizes[i]);

        if (ctx->colname)
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),
                     errmsg("expected JSON array"),
                     errhint("See the array element %s of key \"%s\".",
                             indices.data, ctx->colname)));
        else
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),
                     errmsg("expected JSON array"),
                     errhint("See the array element %s.",
                             indices.data)));
    }
}

/* set the number of dimensions of the populated array when it becomes known */
static void
populate_array_assign_ndims(PopulateArrayContext *ctx, int ndims)
{
    int         i;

    Assert(ctx->ndims <= 0);

    if (ndims <= 0)
        populate_array_report_expected_array(ctx, ndims);

    ctx->ndims = ndims;
    ctx->dims = palloc(sizeof(int) * ndims);
    ctx->sizes = palloc0(sizeof(int) * ndims);

    for (i = 0; i < ndims; i++)
        ctx->dims[i] = -1;      /* dimensions are unknown yet */
}

/* check the populated subarray dimension */
static void
populate_array_check_dimension(PopulateArrayContext *ctx, int ndim)
{
    int         dim = ctx->sizes[ndim]; /* current dimension counter */

    if (ctx->dims[ndim] == -1)
        ctx->dims[ndim] = dim;  /* assign dimension if not yet known */
    else if (ctx->dims[ndim] != dim)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),
                 errmsg("malformed JSON array"),
                 errdetail("Multidimensional arrays must have "
                           "sub-arrays with matching dimensions.")));

    /* reset the current array dimension size counter */
    ctx->sizes[ndim] = 0;

    /* increment the parent dimension counter if it is a nested sub-array */
    if (ndim > 0)
        ctx->sizes[ndim - 1]++;
}

static void
populate_array_element(PopulateArrayContext *ctx, int ndim, JsValue *jsv)
{
    Datum       element;
    bool        element_isnull;

    /* populate the array element */
    element = populate_record_field(ctx->aio->element_info,
                                    ctx->aio->element_type,
                                    ctx->aio->element_typmod,
                                    NULL, ctx->mcxt, PointerGetDatum(NULL),
                                    jsv, &element_isnull);

    accumArrayResult(ctx->astate, element, element_isnull,
                     ctx->aio->element_type, ctx->acxt);

    Assert(ndim > 0);
    ctx->sizes[ndim - 1]++;     /* increment current dimension counter */
}

/* json object start handler for populate_array_json() */
static void
populate_array_object_start(void *_state)
{
    PopulateArrayState *state = (PopulateArrayState *) _state;
    int         ndim = state->lex->lex_level;

    if (state->ctx->ndims <= 0)
        populate_array_assign_ndims(state->ctx, ndim);
    else if (ndim < state->ctx->ndims)
        populate_array_report_expected_array(state->ctx, ndim);
}

/* json array end handler for populate_array_json() */
static void
populate_array_array_end(void *_state)
{
    PopulateArrayState *state = (PopulateArrayState *) _state;
    PopulateArrayContext *ctx = state->ctx;
    int         ndim = state->lex->lex_level;

    if (ctx->ndims <= 0)
        populate_array_assign_ndims(ctx, ndim + 1);

    if (ndim < ctx->ndims)
        populate_array_check_dimension(ctx, ndim);
}

/* json array element start handler for populate_array_json() */
static void
populate_array_element_start(void *_state, bool isnull)
{
    PopulateArrayState *state = (PopulateArrayState *) _state;
    int         ndim = state->lex->lex_level;

    if (state->ctx->ndims <= 0 || ndim == state->ctx->ndims)
    {
        /* remember current array element start */
        state->element_start = state->lex->token_start;
        state->element_type = state->lex->token_type;
        state->element_scalar = NULL;
    }
}

/* json array element end handler for populate_array_json() */
static void
populate_array_element_end(void *_state, bool isnull)
{
    PopulateArrayState *state = (PopulateArrayState *) _state;
    PopulateArrayContext *ctx = state->ctx;
    int         ndim = state->lex->lex_level;

    Assert(ctx->ndims > 0);

    if (ndim == ctx->ndims)
    {
        JsValue     jsv;

        jsv.is_json = true;
        jsv.val.json.type = state->element_type;

        if (isnull)
        {
            Assert(jsv.val.json.type == JSON_TOKEN_NULL);
            jsv.val.json.str = NULL;
            jsv.val.json.len = 0;
        }
        else if (state->element_scalar)
        {
            jsv.val.json.str = state->element_scalar;
            jsv.val.json.len = -1;  /* null-terminated */
        }
        else
        {
            jsv.val.json.str = state->element_start;
            jsv.val.json.len = (state->lex->prev_token_terminator -
                                state->element_start) * sizeof(char);
        }

        populate_array_element(ctx, ndim, &jsv);
    }
}

/* json scalar handler for populate_array_json() */
static void
populate_array_scalar(void *_state, char *token, JsonTokenType tokentype)
{
    PopulateArrayState *state = (PopulateArrayState *) _state;
    PopulateArrayContext *ctx = state->ctx;
    int         ndim = state->lex->lex_level;

    if (ctx->ndims <= 0)
        populate_array_assign_ndims(ctx, ndim);
    else if (ndim < ctx->ndims)
        populate_array_report_expected_array(ctx, ndim);

    if (ndim == ctx->ndims)
    {
        /* remember the scalar element token */
        state->element_scalar = token;
        /* element_type must already be set in populate_array_element_start() */
        Assert(state->element_type == tokentype);
    }
}

/* parse a json array and populate array */
static void
populate_array_json(PopulateArrayContext *ctx, char *json, int len)
{
    PopulateArrayState state;
    JsonSemAction sem;

    state.lex = makeJsonLexContextCstringLen(json, len, true);
    state.ctx = ctx;

    memset(&sem, 0, sizeof(sem));
    sem.semstate = (void *) &state;
    sem.object_start = populate_array_object_start;
    sem.array_end = populate_array_array_end;
    sem.array_element_start = populate_array_element_start;
    sem.array_element_end = populate_array_element_end;
    sem.scalar = populate_array_scalar;

    pg_parse_json(state.lex, &sem);

    /* number of dimensions should be already known */
    Assert(ctx->ndims > 0 && ctx->dims);

    pfree(state.lex);
}

/*
 * populate_array_dim_jsonb() -- Iterate recursively through jsonb sub-array
 *      elements and accumulate result using given ArrayBuildState.
 */
static void
populate_array_dim_jsonb(PopulateArrayContext *ctx, /* context */
                         JsonbValue *jbv,   /* jsonb sub-array */
                         int ndim)  /* current dimension */
{
    JsonbContainer *jbc = jbv->val.binary.data;
    JsonbIterator *it;
    JsonbIteratorToken tok;
    JsonbValue  val;
    JsValue     jsv;

    check_stack_depth();

    if (jbv->type != jbvBinary || !JsonContainerIsArray(jbc))
        populate_array_report_expected_array(ctx, ndim - 1);

    Assert(!JsonContainerIsScalar(jbc));

    it = JsonbIteratorInit(jbc);

    tok = JsonbIteratorNext(&it, &val, true);
    Assert(tok == WJB_BEGIN_ARRAY);

    tok = JsonbIteratorNext(&it, &val, true);

    /*
     * If the number of dimensions is not yet known and we have found end of
     * the array, or the first child element is not an array, then assign the
     * number of dimensions now.
     */
    if (ctx->ndims <= 0 &&
        (tok == WJB_END_ARRAY ||
         (tok == WJB_ELEM &&
          (val.type != jbvBinary ||
           !JsonContainerIsArray(val.val.binary.data)))))
        populate_array_assign_ndims(ctx, ndim);

    jsv.is_json = false;
    jsv.val.jsonb = &val;

    /* process all the array elements */
    while (tok == WJB_ELEM)
    {
        /*
         * Recurse only if the dimensions of dimensions is still unknown or if
         * it is not the innermost dimension.
         */
        if (ctx->ndims > 0 && ndim >= ctx->ndims)
            populate_array_element(ctx, ndim, &jsv);
        else
        {
            /* populate child sub-array */
            populate_array_dim_jsonb(ctx, &val, ndim + 1);

            /* number of dimensions should be already known */
            Assert(ctx->ndims > 0 && ctx->dims);

            populate_array_check_dimension(ctx, ndim);
        }

        tok = JsonbIteratorNext(&it, &val, true);
    }

    Assert(tok == WJB_END_ARRAY);

    /* free iterator, iterating until WJB_DONE */
    tok = JsonbIteratorNext(&it, &val, true);
    Assert(tok == WJB_DONE && !it);
}

/* recursively populate an array from json/jsonb */
static Datum
populate_array(ArrayIOData *aio,
               const char *colname,
               MemoryContext mcxt,
               JsValue *jsv)
{
    PopulateArrayContext ctx;
    Datum       result;
    int        *lbs;
    int         i;

    ctx.aio = aio;
    ctx.mcxt = mcxt;
    ctx.acxt = CurrentMemoryContext;
    ctx.astate = initArrayResult(aio->element_type, ctx.acxt, true);
    ctx.colname = colname;
    ctx.ndims = 0;              /* unknown yet */
    ctx.dims = NULL;
    ctx.sizes = NULL;

    if (jsv->is_json)
        populate_array_json(&ctx, jsv->val.json.str,
                            jsv->val.json.len >= 0 ? jsv->val.json.len
                            : strlen(jsv->val.json.str));
    else
    {
        populate_array_dim_jsonb(&ctx, jsv->val.jsonb, 1);
        ctx.dims[0] = ctx.sizes[0];
    }

    Assert(ctx.ndims > 0);

    lbs = palloc(sizeof(int) * ctx.ndims);

    for (i = 0; i < ctx.ndims; i++)
        lbs[i] = 1;

    result = makeMdArrayResult(ctx.astate, ctx.ndims, ctx.dims, lbs,
                               ctx.acxt, true);

    pfree(ctx.dims);
    pfree(ctx.sizes);
    pfree(lbs);

    return result;
}

static void
JsValueToJsObject(JsValue *jsv, JsObject *jso)
{
    jso->is_json = jsv->is_json;

    if (jsv->is_json)
    {
        /* convert plain-text json into a hash table */
        jso->val.json_hash =
            get_json_object_as_hash(jsv->val.json.str,
                                    jsv->val.json.len >= 0
                                    ? jsv->val.json.len
                                    : strlen(jsv->val.json.str),
                                    "populate_composite");
    }
    else
    {
        JsonbValue *jbv = jsv->val.jsonb;

        if (jbv->type == jbvBinary &&
            JsonContainerIsObject(jbv->val.binary.data))
        {
            jso->val.jsonb_cont = jbv->val.binary.data;
        }
        else
        {
            bool        is_scalar;

            is_scalar = IsAJsonbScalar(jbv) ||
                (jbv->type == jbvBinary &&
                 JsonContainerIsScalar(jbv->val.binary.data));
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                     is_scalar
                     ? errmsg("cannot call %s on a scalar",
                              "populate_composite")
                     : errmsg("cannot call %s on an array",
                              "populate_composite")));
        }
    }
}

/* acquire or update cached tuple descriptor for a composite type */
static void
update_cached_tupdesc(CompositeIOData *io, MemoryContext mcxt)
{
    if (!io->tupdesc ||
        io->tupdesc->tdtypeid != io->base_typid ||
        io->tupdesc->tdtypmod != io->base_typmod)
    {
        TupleDesc   tupdesc = lookup_rowtype_tupdesc(io->base_typid,
                                                     io->base_typmod);
        MemoryContext oldcxt;

        if (io->tupdesc)
            FreeTupleDesc(io->tupdesc);

        /* copy tuple desc without constraints into cache memory context */
        oldcxt = MemoryContextSwitchTo(mcxt);
        io->tupdesc = CreateTupleDescCopy(tupdesc);
        MemoryContextSwitchTo(oldcxt);

        ReleaseTupleDesc(tupdesc);
    }
}

/* recursively populate a composite (row type) value from json/jsonb */
static Datum
populate_composite(CompositeIOData *io,
                   Oid typid,
                   const char *colname,
                   MemoryContext mcxt,
                   HeapTupleHeader defaultval,
                   JsValue *jsv,
                   bool isnull)
{
    Datum       result;

    /* acquire/update cached tuple descriptor */
    update_cached_tupdesc(io, mcxt);

    if (isnull)
        result = (Datum) 0;
    else
    {
        HeapTupleHeader tuple;
        JsObject    jso;

        /* prepare input value */
        JsValueToJsObject(jsv, &jso);

        /* populate resulting record tuple */
        tuple = populate_record(io->tupdesc, &io->record_io,
                                defaultval, mcxt, &jso);
        result = HeapTupleHeaderGetDatum(tuple);

        JsObjectFree(&jso);
    }

    /*
     * If it's domain over composite, check domain constraints.  (This should
     * probably get refactored so that we can see the TYPECAT value, but for
     * now, we can tell by comparing typid to base_typid.)
     */
    if (typid != io->base_typid && typid != RECORDOID)
        domain_check(result, isnull, typid, &io->domain_info, mcxt);

    return result;
}

/* populate non-null scalar value from json/jsonb value */
static Datum
populate_scalar(ScalarIOData *io, Oid typid, int32 typmod, JsValue *jsv)
{
    Datum       res;
    char       *str = NULL;
    char       *json = NULL;

    if (jsv->is_json)
    {
        int         len = jsv->val.json.len;

        json = jsv->val.json.str;
        Assert(json);
        if (len >= 0)
        {
            /* Need to copy non-null-terminated string */
            str = palloc(len + 1 * sizeof(char));
            memcpy(str, json, len);
            str[len] = '\0';
        }
        else
            str = json;         /* string is already null-terminated */

        /* If converting to json/jsonb, make string into valid JSON literal */
        if ((typid == JSONOID || typid == JSONBOID) &&
            jsv->val.json.type == JSON_TOKEN_STRING)
        {
            StringInfoData buf;

            initStringInfo(&buf);
            escape_json(&buf, str);
            /* free temporary buffer */
            if (str != json)
                pfree(str);
            str = buf.data;
        }
    }
    else
    {
        JsonbValue *jbv = jsv->val.jsonb;

        if (typid == JSONBOID)
        {
            Jsonb      *jsonb = JsonbValueToJsonb(jbv); /* directly use jsonb */

            return JsonbPGetDatum(jsonb);
        }
        /* convert jsonb to string for typio call */
        else if (typid == JSONOID && jbv->type != jbvBinary)
        {
            /*
             * Convert scalar jsonb (non-scalars are passed here as jbvBinary)
             * to json string, preserving quotes around top-level strings.
             */
            Jsonb      *jsonb = JsonbValueToJsonb(jbv);

            str = JsonbToCString(NULL, &jsonb->root, VARSIZE(jsonb));
        }
        else if (jbv->type == jbvString)    /* quotes are stripped */
            str = pnstrdup(jbv->val.string.val, jbv->val.string.len);
        else if (jbv->type == jbvBool)
            str = pstrdup(jbv->val.boolean ? "true" : "false");
        else if (jbv->type == jbvNumeric)
            str = DatumGetCString(DirectFunctionCall1(numeric_out,
                                                      PointerGetDatum(jbv->val.numeric)));
        else if (jbv->type == jbvBinary)
            str = JsonbToCString(NULL, jbv->val.binary.data,
                                 jbv->val.binary.len);
        else
            elog(ERROR, "unrecognized jsonb type: %d", (int) jbv->type);
    }

    res = InputFunctionCall(&io->typiofunc, str, io->typioparam, typmod);

    /* free temporary buffer */
    if (str != json)
        pfree(str);

    return res;
}

static Datum
populate_domain(DomainIOData *io,
                Oid typid,
                const char *colname,
                MemoryContext mcxt,
                JsValue *jsv,
                bool isnull)
{
    Datum       res;

    if (isnull)
        res = (Datum) 0;
    else
    {
        res = populate_record_field(io->base_io,
                                    io->base_typid, io->base_typmod,
                                    colname, mcxt, PointerGetDatum(NULL),
                                    jsv, &isnull);
        Assert(!isnull);
    }

    domain_check(res, isnull, typid, &io->domain_info, mcxt);

    return res;
}

/* prepare column metadata cache for the given type */
static void
prepare_column_cache(ColumnIOData *column,
                     Oid typid,
                     int32 typmod,
                     MemoryContext mcxt,
                     bool need_scalar)
{
    HeapTuple   tup;
    Form_pg_type type;

    column->typid = typid;
    column->typmod = typmod;

    tup = SearchSysCache1(TYPEOID, ObjectIdGetDatum(typid));
    if (!HeapTupleIsValid(tup))
        elog(ERROR, "cache lookup failed for type %u", typid);

    type = (Form_pg_type) GETSTRUCT(tup);

    if (type->typtype == TYPTYPE_DOMAIN)
    {
        /*
         * We can move directly to the bottom base type; domain_check() will
         * take care of checking all constraints for a stack of domains.
         */
        Oid         base_typid;
        int32       base_typmod = typmod;

        base_typid = getBaseTypeAndTypmod(typid, &base_typmod);
        if (get_typtype(base_typid) == TYPTYPE_COMPOSITE)
        {
            /* domain over composite has its own code path */
            column->typcat = TYPECAT_COMPOSITE_DOMAIN;
            column->io.composite.record_io = NULL;
            column->io.composite.tupdesc = NULL;
            column->io.composite.base_typid = base_typid;
            column->io.composite.base_typmod = base_typmod;
            column->io.composite.domain_info = NULL;
        }
        else
        {
            /* domain over anything else */
            column->typcat = TYPECAT_DOMAIN;
            column->io.domain.base_typid = base_typid;
            column->io.domain.base_typmod = base_typmod;
            column->io.domain.base_io =
                MemoryContextAllocZero(mcxt, sizeof(ColumnIOData));
            column->io.domain.domain_info = NULL;
        }
    }
    else if (type->typtype == TYPTYPE_COMPOSITE || typid == RECORDOID)
    {
        column->typcat = TYPECAT_COMPOSITE;
        column->io.composite.record_io = NULL;
        column->io.composite.tupdesc = NULL;
        column->io.composite.base_typid = typid;
        column->io.composite.base_typmod = typmod;
        column->io.composite.domain_info = NULL;
    }
    else if (type->typlen == -1 && OidIsValid(type->typelem))
    {
        column->typcat = TYPECAT_ARRAY;
        column->io.array.element_info = MemoryContextAllocZero(mcxt,
                                                               sizeof(ColumnIOData));
        column->io.array.element_type = type->typelem;
        /* array element typemod stored in attribute's typmod */
        column->io.array.element_typmod = typmod;
    }
    else
    {
        column->typcat = TYPECAT_SCALAR;
        need_scalar = true;
    }

    /* caller can force us to look up scalar_io info even for non-scalars */
    if (need_scalar)
    {
        Oid         typioproc;

        getTypeInputInfo(typid, &typioproc, &column->scalar_io.typioparam);
        fmgr_info_cxt(typioproc, &column->scalar_io.typiofunc, mcxt);
    }

    ReleaseSysCache(tup);
}

/* recursively populate a record field or an array element from a json/jsonb value */
static Datum
populate_record_field(ColumnIOData *col,
                      Oid typid,
                      int32 typmod,
                      const char *colname,
                      MemoryContext mcxt,
                      Datum defaultval,
                      JsValue *jsv,
                      bool *isnull)
{
    TypeCat     typcat;

    check_stack_depth();

    /*
     * Prepare column metadata cache for the given type.  Force lookup of the
     * scalar_io data so that the json string hack below will work.
     */
    if (col->typid != typid || col->typmod != typmod)
        prepare_column_cache(col, typid, typmod, mcxt, true);

    *isnull = JsValueIsNull(jsv);

    typcat = col->typcat;

    /* try to convert json string to a non-scalar type through input function */
    if (JsValueIsString(jsv) &&
        (typcat == TYPECAT_ARRAY ||
         typcat == TYPECAT_COMPOSITE ||
         typcat == TYPECAT_COMPOSITE_DOMAIN))
        typcat = TYPECAT_SCALAR;

    /* we must perform domain checks for NULLs, otherwise exit immediately */
    if (*isnull &&
        typcat != TYPECAT_DOMAIN &&
        typcat != TYPECAT_COMPOSITE_DOMAIN)
        return (Datum) 0;

    switch (typcat)
    {
        case TYPECAT_SCALAR:
            return populate_scalar(&col->scalar_io, typid, typmod, jsv);

        case TYPECAT_ARRAY:
            return populate_array(&col->io.array, colname, mcxt, jsv);

        case TYPECAT_COMPOSITE:
        case TYPECAT_COMPOSITE_DOMAIN:
            return populate_composite(&col->io.composite, typid,
                                      colname, mcxt,
                                      DatumGetPointer(defaultval)
                                      ? DatumGetHeapTupleHeader(defaultval)
                                      : NULL,
                                      jsv, *isnull);

        case TYPECAT_DOMAIN:
            return populate_domain(&col->io.domain, typid, colname, mcxt,
                                   jsv, *isnull);

        default:
            elog(ERROR, "unrecognized type category '%c'", typcat);
            return (Datum) 0;
    }
}

static RecordIOData *
allocate_record_info(MemoryContext mcxt, int ncolumns)
{
    RecordIOData *data = (RecordIOData *)
    MemoryContextAlloc(mcxt,
                       offsetof(RecordIOData, columns) +
                       ncolumns * sizeof(ColumnIOData));

    data->record_type = InvalidOid;
    data->record_typmod = 0;
    data->ncolumns = ncolumns;
    MemSet(data->columns, 0, sizeof(ColumnIOData) * ncolumns);

    return data;
}

static bool
JsObjectGetField(JsObject *obj, char *field, JsValue *jsv)
{
    jsv->is_json = obj->is_json;

    if (jsv->is_json)
    {
        JsonHashEntry *hashentry = hash_search(obj->val.json_hash, field,
                                               HASH_FIND, NULL);

        jsv->val.json.type = hashentry ? hashentry->type : JSON_TOKEN_NULL;
        jsv->val.json.str = jsv->val.json.type == JSON_TOKEN_NULL ? NULL :
            hashentry->val;
        jsv->val.json.len = jsv->val.json.str ? -1 : 0; /* null-terminated */

        return hashentry != NULL;
    }
    else
    {
        jsv->val.jsonb = !obj->val.jsonb_cont ? NULL :
            getKeyJsonValueFromContainer(obj->val.jsonb_cont, field, strlen(field),
                                         NULL);

        return jsv->val.jsonb != NULL;
    }
}

/* populate a record tuple from json/jsonb value */
static HeapTupleHeader
populate_record(TupleDesc tupdesc,
                RecordIOData **record_p,
                HeapTupleHeader defaultval,
                MemoryContext mcxt,
                JsObject *obj)
{
    RecordIOData *record = *record_p;
    Datum      *values;
    bool       *nulls;
    HeapTuple   res;
    int         ncolumns = tupdesc->natts;
    int         i;

    /*
     * if the input json is empty, we can only skip the rest if we were passed
     * in a non-null record, since otherwise there may be issues with domain
     * nulls.
     */
    if (defaultval && JsObjectIsEmpty(obj))
        return defaultval;

    /* (re)allocate metadata cache */
    if (record == NULL ||
        record->ncolumns != ncolumns)
        *record_p = record = allocate_record_info(mcxt, ncolumns);

    /* invalidate metadata cache if the record type has changed */
    if (record->record_type != tupdesc->tdtypeid ||
        record->record_typmod != tupdesc->tdtypmod)
    {
        MemSet(record, 0, offsetof(RecordIOData, columns) +
               ncolumns * sizeof(ColumnIOData));
        record->record_type = tupdesc->tdtypeid;
        record->record_typmod = tupdesc->tdtypmod;
        record->ncolumns = ncolumns;
    }

    values = (Datum *) palloc(ncolumns * sizeof(Datum));
    nulls = (bool *) palloc(ncolumns * sizeof(bool));

    if (defaultval)
    {
        HeapTupleData tuple;

        /* Build a temporary HeapTuple control structure */
        tuple.t_len = HeapTupleHeaderGetDatumLength(defaultval);
        ItemPointerSetInvalid(&(tuple.t_self));
        tuple.t_tableOid = InvalidOid;
        tuple.t_data = defaultval;

        /* Break down the tuple into fields */
        heap_deform_tuple(&tuple, tupdesc, values, nulls);
    }
    else
    {
        for (i = 0; i < ncolumns; ++i)
        {
            values[i] = (Datum) 0;
            nulls[i] = true;
        }
    }

    for (i = 0; i < ncolumns; ++i)
    {
        Form_pg_attribute att = TupleDescAttr(tupdesc, i);
        char       *colname = NameStr(att->attname);
        JsValue     field = {0};
        bool        found;

        /* Ignore dropped columns in datatype */
        if (att->attisdropped)
        {
            nulls[i] = true;
            continue;
        }

        found = JsObjectGetField(obj, colname, &field);

        /*
         * we can't just skip here if the key wasn't found since we might have
         * a domain to deal with. If we were passed in a non-null record
         * datum, we assume that the existing values are valid (if they're
         * not, then it's not our fault), but if we were passed in a null,
         * then every field which we don't populate needs to be run through
         * the input function just in case it's a domain type.
         */
        if (defaultval && !found)
            continue;

        values[i] = populate_record_field(&record->columns[i],
                                          att->atttypid,
                                          att->atttypmod,
                                          colname,
                                          mcxt,
                                          nulls[i] ? (Datum) 0 : values[i],
                                          &field,
                                          &nulls[i]);
    }

    res = heap_form_tuple(tupdesc, values, nulls);

    pfree(values);
    pfree(nulls);

    return res->t_data;
}

/*
 * Setup for json{b}_populate_record{set}: result type will be same as first
 * argument's type --- unless first argument is "null::record", which we can't
 * extract type info from; we handle that later.
 */
static void
get_record_type_from_argument(FunctionCallInfo fcinfo,
                              const char *funcname,
                              PopulateRecordCache *cache)
{
    cache->argtype = get_fn_expr_argtype(fcinfo->flinfo, 0);
    prepare_column_cache(&cache->c,
                         cache->argtype, -1,
                         cache->fn_mcxt, false);
    if (cache->c.typcat != TYPECAT_COMPOSITE &&
        cache->c.typcat != TYPECAT_COMPOSITE_DOMAIN)
        ereport(ERROR,
                (errcode(ERRCODE_DATATYPE_MISMATCH),
        /* translator: %s is a function name, eg json_to_record */
                 errmsg("first argument of %s must be a row type",
                        funcname)));
}

/*
 * Setup for json{b}_to_record{set}: result type is specified by calling
 * query.  We'll also use this code for json{b}_populate_record{set},
 * if we discover that the first argument is a null of type RECORD.
 *
 * Here it is syntactically impossible to specify the target type
 * as domain-over-composite.
 */
static void
get_record_type_from_query(FunctionCallInfo fcinfo,
                           const char *funcname,
                           PopulateRecordCache *cache)
{
    TupleDesc   tupdesc;
    MemoryContext old_cxt;

    if (get_call_result_type(fcinfo, NULL, &tupdesc) != TYPEFUNC_COMPOSITE)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
        /* translator: %s is a function name, eg json_to_record */
                 errmsg("could not determine row type for result of %s",
                        funcname),
                 errhint("Provide a non-null record argument, "
                         "or call the function in the FROM clause "
                         "using a column definition list.")));

    Assert(tupdesc);
    cache->argtype = tupdesc->tdtypeid;

    /* If we go through this more than once, avoid memory leak */
    if (cache->c.io.composite.tupdesc)
        FreeTupleDesc(cache->c.io.composite.tupdesc);

    /* Save identified tupdesc */
    old_cxt = MemoryContextSwitchTo(cache->fn_mcxt);
    cache->c.io.composite.tupdesc = CreateTupleDescCopy(tupdesc);
    cache->c.io.composite.base_typid = tupdesc->tdtypeid;
    cache->c.io.composite.base_typmod = tupdesc->tdtypmod;
    MemoryContextSwitchTo(old_cxt);
}

/*
 * common worker for json{b}_populate_record() and json{b}_to_record()
 * is_json and have_record_arg identify the specific function
 */
static Datum
populate_record_worker(FunctionCallInfo fcinfo, const char *funcname,
                       bool is_json, bool have_record_arg)
{
    int         json_arg_num = have_record_arg ? 1 : 0;
    JsValue     jsv = {0};
    HeapTupleHeader rec;
    Datum       rettuple;
    JsonbValue  jbv;
    MemoryContext fnmcxt = fcinfo->flinfo->fn_mcxt;
    PopulateRecordCache *cache = fcinfo->flinfo->fn_extra;

    /*
     * If first time through, identify input/result record type.  Note that
     * this stanza looks only at fcinfo context, which can't change during the
     * query; so we may not be able to fully resolve a RECORD input type yet.
     */
    if (!cache)
    {
        fcinfo->flinfo->fn_extra = cache =
            MemoryContextAllocZero(fnmcxt, sizeof(*cache));
        cache->fn_mcxt = fnmcxt;

        if (have_record_arg)
            get_record_type_from_argument(fcinfo, funcname, cache);
        else
            get_record_type_from_query(fcinfo, funcname, cache);
    }

    /* Collect record arg if we have one */
    if (!have_record_arg)
        rec = NULL;             /* it's json{b}_to_record() */
    else if (!PG_ARGISNULL(0))
    {
        rec = PG_GETARG_HEAPTUPLEHEADER(0);

        /*
         * When declared arg type is RECORD, identify actual record type from
         * the tuple itself.
         */
        if (cache->argtype == RECORDOID)
        {
            cache->c.io.composite.base_typid = HeapTupleHeaderGetTypeId(rec);
            cache->c.io.composite.base_typmod = HeapTupleHeaderGetTypMod(rec);
        }
    }
    else
    {
        rec = NULL;

        /*
         * When declared arg type is RECORD, identify actual record type from
         * calling query, or fail if we can't.
         */
        if (cache->argtype == RECORDOID)
        {
            get_record_type_from_query(fcinfo, funcname, cache);
            /* This can't change argtype, which is important for next time */
            Assert(cache->argtype == RECORDOID);
        }
    }

    /* If no JSON argument, just return the record (if any) unchanged */
    if (PG_ARGISNULL(json_arg_num))
    {
        if (rec)
            PG_RETURN_POINTER(rec);
        else
            PG_RETURN_NULL();
    }

    jsv.is_json = is_json;

    if (is_json)
    {
        text       *json = PG_GETARG_TEXT_PP(json_arg_num);

        jsv.val.json.str = VARDATA_ANY(json);
        jsv.val.json.len = VARSIZE_ANY_EXHDR(json);
        jsv.val.json.type = JSON_TOKEN_INVALID; /* not used in
                                                 * populate_composite() */
    }
    else
    {
        Jsonb      *jb = PG_GETARG_JSONB_P(json_arg_num);

        jsv.val.jsonb = &jbv;

        /* fill binary jsonb value pointing to jb */
        jbv.type = jbvBinary;
        jbv.val.binary.data = &jb->root;
        jbv.val.binary.len = VARSIZE(jb) - VARHDRSZ;
    }

    rettuple = populate_composite(&cache->c.io.composite, cache->argtype,
                                  NULL, fnmcxt, rec, &jsv, false);

    PG_RETURN_DATUM(rettuple);
}

/*
 * get_json_object_as_hash
 *
 * decompose a json object into a hash table.
 */
static HTAB *
get_json_object_as_hash(char *json, int len, const char *funcname)
{
    HASHCTL     ctl;
    HTAB       *tab;
    JHashState *state;
    JsonLexContext *lex = makeJsonLexContextCstringLen(json, len, true);
    JsonSemAction *sem;

    memset(&ctl, 0, sizeof(ctl));
    ctl.keysize = NAMEDATALEN;
    ctl.entrysize = sizeof(JsonHashEntry);
    ctl.hcxt = CurrentMemoryContext;
    tab = hash_create("json object hashtable",
                      100,
                      &ctl,
                      HASH_ELEM | HASH_CONTEXT);

    state = palloc0(sizeof(JHashState));
    sem = palloc0(sizeof(JsonSemAction));

    state->function_name = funcname;
    state->hash = tab;
    state->lex = lex;

    sem->semstate = (void *) state;
    sem->array_start = hash_array_start;
    sem->scalar = hash_scalar;
    sem->object_field_start = hash_object_field_start;
    sem->object_field_end = hash_object_field_end;

    pg_parse_json(lex, sem);

    return tab;
}

static void
hash_object_field_start(void *state, char *fname, bool isnull)
{
    JHashState *_state = (JHashState *) state;

    if (_state->lex->lex_level > 1)
        return;

    /* remember token type */
    _state->saved_token_type = _state->lex->token_type;

    if (_state->lex->token_type == JSON_TOKEN_ARRAY_START ||
        _state->lex->token_type == JSON_TOKEN_OBJECT_START)
    {
        /* remember start position of the whole text of the subobject */
        _state->save_json_start = _state->lex->token_start;
    }
    else
    {
        /* must be a scalar */
        _state->save_json_start = NULL;
    }
}

static void
hash_object_field_end(void *state, char *fname, bool isnull)
{
    JHashState *_state = (JHashState *) state;
    JsonHashEntry *hashentry;
    bool        found;

    /*
     * Ignore nested fields.
     */
    if (_state->lex->lex_level > 1)
        return;

    /*
     * Ignore field names >= NAMEDATALEN - they can't match a record field.
     * (Note: without this test, the hash code would truncate the string at
     * NAMEDATALEN-1, and could then match against a similarly-truncated
     * record field name.  That would be a reasonable behavior, but this code
     * has previously insisted on exact equality, so we keep this behavior.)
     */
    if (strlen(fname) >= NAMEDATALEN)
        return;

    hashentry = hash_search(_state->hash, fname, HASH_ENTER, &found);

    /*
     * found being true indicates a duplicate. We don't do anything about
     * that, a later field with the same name overrides the earlier field.
     */

    hashentry->type = _state->saved_token_type;
    Assert(isnull == (hashentry->type == JSON_TOKEN_NULL));

    if (_state->save_json_start != NULL)
    {
        int         len = _state->lex->prev_token_terminator - _state->save_json_start;
        char       *val = palloc((len + 1) * sizeof(char));

        memcpy(val, _state->save_json_start, len);
        val[len] = '\0';
        hashentry->val = val;
    }
    else
    {
        /* must have had a scalar instead */
        hashentry->val = _state->saved_scalar;
    }
}

static void
hash_array_start(void *state)
{
    JHashState *_state = (JHashState *) state;

    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot call %s on an array", _state->function_name)));
}

static void
hash_scalar(void *state, char *token, JsonTokenType tokentype)
{
    JHashState *_state = (JHashState *) state;

    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot call %s on a scalar", _state->function_name)));

    if (_state->lex->lex_level == 1)
    {
        _state->saved_scalar = token;
        /* saved_token_type must already be set in hash_object_field_start() */
        Assert(_state->saved_token_type == tokentype);
    }
}


/*
 * SQL function json_populate_recordset
 *
 * set fields in a set of records from the argument json,
 * which must be an array of objects.
 *
 * similar to json_populate_record, but the tuple-building code
 * is pushed down into the semantic action handlers so it's done
 * per object in the array.
 */
Datum
jsonb_populate_recordset(PG_FUNCTION_ARGS)
{
    return populate_recordset_worker(fcinfo, "jsonb_populate_recordset",
                                     false, true);
}

Datum
jsonb_to_recordset(PG_FUNCTION_ARGS)
{
    return populate_recordset_worker(fcinfo, "jsonb_to_recordset",
                                     false, false);
}

Datum
json_populate_recordset(PG_FUNCTION_ARGS)
{
    return populate_recordset_worker(fcinfo, "json_populate_recordset",
                                     true, true);
}

Datum
json_to_recordset(PG_FUNCTION_ARGS)
{
    return populate_recordset_worker(fcinfo, "json_to_recordset",
                                     true, false);
}

static void
populate_recordset_record(PopulateRecordsetState *state, JsObject *obj)
{
    PopulateRecordCache *cache = state->cache;
    HeapTupleHeader tuphead;
    HeapTupleData tuple;

    /* acquire/update cached tuple descriptor */
    update_cached_tupdesc(&cache->c.io.composite, cache->fn_mcxt);

    /* replace record fields from json */
    tuphead = populate_record(cache->c.io.composite.tupdesc,
                              &cache->c.io.composite.record_io,
                              state->rec,
                              cache->fn_mcxt,
                              obj);

    /* if it's domain over composite, check domain constraints */
    if (cache->c.typcat == TYPECAT_COMPOSITE_DOMAIN)
        domain_check(HeapTupleHeaderGetDatum(tuphead), false,
                     cache->argtype,
                     &cache->c.io.composite.domain_info,
                     cache->fn_mcxt);

    /* ok, save into tuplestore */
    tuple.t_len = HeapTupleHeaderGetDatumLength(tuphead);
    ItemPointerSetInvalid(&(tuple.t_self));
    tuple.t_tableOid = InvalidOid;
    tuple.t_data = tuphead;

    tuplestore_puttuple(state->tuple_store, &tuple);
}

/*
 * common worker for json{b}_populate_recordset() and json{b}_to_recordset()
 * is_json and have_record_arg identify the specific function
 */
static Datum
populate_recordset_worker(FunctionCallInfo fcinfo, const char *funcname,
                          bool is_json, bool have_record_arg)
{
    int         json_arg_num = have_record_arg ? 1 : 0;
    ReturnSetInfo *rsi;
    MemoryContext old_cxt;
    HeapTupleHeader rec;
    PopulateRecordCache *cache = fcinfo->flinfo->fn_extra;
    PopulateRecordsetState *state;

    rsi = (ReturnSetInfo *) fcinfo->resultinfo;

    if (!rsi || !IsA(rsi, ReturnSetInfo) ||
        (rsi->allowedModes & SFRM_Materialize) == 0)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("set-valued function called in context that "
                        "cannot accept a set")));

    rsi->returnMode = SFRM_Materialize;

    /*
     * If first time through, identify input/result record type.  Note that
     * this stanza looks only at fcinfo context, which can't change during the
     * query; so we may not be able to fully resolve a RECORD input type yet.
     */
    if (!cache)
    {
        fcinfo->flinfo->fn_extra = cache =
            MemoryContextAllocZero(fcinfo->flinfo->fn_mcxt, sizeof(*cache));
        cache->fn_mcxt = fcinfo->flinfo->fn_mcxt;

        if (have_record_arg)
            get_record_type_from_argument(fcinfo, funcname, cache);
        else
            get_record_type_from_query(fcinfo, funcname, cache);
    }

    /* Collect record arg if we have one */
    if (!have_record_arg)
        rec = NULL;             /* it's json{b}_to_recordset() */
    else if (!PG_ARGISNULL(0))
    {
        rec = PG_GETARG_HEAPTUPLEHEADER(0);

        /*
         * When declared arg type is RECORD, identify actual record type from
         * the tuple itself.
         */
        if (cache->argtype == RECORDOID)
        {
            cache->c.io.composite.base_typid = HeapTupleHeaderGetTypeId(rec);
            cache->c.io.composite.base_typmod = HeapTupleHeaderGetTypMod(rec);
        }
    }
    else
    {
        rec = NULL;

        /*
         * When declared arg type is RECORD, identify actual record type from
         * calling query, or fail if we can't.
         */
        if (cache->argtype == RECORDOID)
        {
            get_record_type_from_query(fcinfo, funcname, cache);
            /* This can't change argtype, which is important for next time */
            Assert(cache->argtype == RECORDOID);
        }
    }

    /* if the json is null send back an empty set */
    if (PG_ARGISNULL(json_arg_num))
        PG_RETURN_NULL();

    /*
     * Forcibly update the cached tupdesc, to ensure we have the right tupdesc
     * to return even if the JSON contains no rows.
     */
    update_cached_tupdesc(&cache->c.io.composite, cache->fn_mcxt);

    state = palloc0(sizeof(PopulateRecordsetState));

    /* make tuplestore in a sufficiently long-lived memory context */
    old_cxt = MemoryContextSwitchTo(rsi->econtext->ecxt_per_query_memory);
    state->tuple_store = tuplestore_begin_heap(rsi->allowedModes &
                                               SFRM_Materialize_Random,
                                               false, work_mem);
    MemoryContextSwitchTo(old_cxt);

    state->function_name = funcname;
    state->cache = cache;
    state->rec = rec;

    if (is_json)
    {
        text       *json = PG_GETARG_TEXT_PP(json_arg_num);
        JsonLexContext *lex;
        JsonSemAction *sem;

        sem = palloc0(sizeof(JsonSemAction));

        lex = makeJsonLexContext(json, true);

        sem->semstate = (void *) state;
        sem->array_start = populate_recordset_array_start;
        sem->array_element_start = populate_recordset_array_element_start;
        sem->scalar = populate_recordset_scalar;
        sem->object_field_start = populate_recordset_object_field_start;
        sem->object_field_end = populate_recordset_object_field_end;
        sem->object_start = populate_recordset_object_start;
        sem->object_end = populate_recordset_object_end;

        state->lex = lex;

        pg_parse_json(lex, sem);
    }
    else
    {
        Jsonb      *jb = PG_GETARG_JSONB_P(json_arg_num);
        JsonbIterator *it;
        JsonbValue  v;
        bool        skipNested = false;
        JsonbIteratorToken r;

        if (JB_ROOT_IS_SCALAR(jb) || !JB_ROOT_IS_ARRAY(jb))
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                     errmsg("cannot call %s on a non-array",
                            funcname)));

        it = JsonbIteratorInit(&jb->root);

        while ((r = JsonbIteratorNext(&it, &v, skipNested)) != WJB_DONE)
        {
            skipNested = true;

            if (r == WJB_ELEM)
            {
                JsObject    obj;

                if (v.type != jbvBinary ||
                    !JsonContainerIsObject(v.val.binary.data))
                    ereport(ERROR,
                            (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                             errmsg("argument of %s must be an array of objects",
                                    funcname)));

                obj.is_json = false;
                obj.val.jsonb_cont = v.val.binary.data;

                populate_recordset_record(state, &obj);
            }
        }
    }

    /*
     * Note: we must copy the cached tupdesc because the executor will free
     * the passed-back setDesc, but we want to hang onto the cache in case
     * we're called again in the same query.
     */
    rsi->setResult = state->tuple_store;
    rsi->setDesc = CreateTupleDescCopy(cache->c.io.composite.tupdesc);

    PG_RETURN_NULL();
}

static void
populate_recordset_object_start(void *state)
{
    PopulateRecordsetState *_state = (PopulateRecordsetState *) state;
    int         lex_level = _state->lex->lex_level;
    HASHCTL     ctl;

    /* Reject object at top level: we must have an array at level 0 */
    if (lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot call %s on an object",
                        _state->function_name)));

    /* Nested objects require no special processing */
    if (lex_level > 1)
        return;

    /* Object at level 1: set up a new hash table for this object */
    memset(&ctl, 0, sizeof(ctl));
    ctl.keysize = NAMEDATALEN;
    ctl.entrysize = sizeof(JsonHashEntry);
    ctl.hcxt = CurrentMemoryContext;
    _state->json_hash = hash_create("json object hashtable",
                                    100,
                                    &ctl,
                                    HASH_ELEM | HASH_CONTEXT);
}

static void
populate_recordset_object_end(void *state)
{
    PopulateRecordsetState *_state = (PopulateRecordsetState *) state;
    JsObject    obj;

    /* Nested objects require no special processing */
    if (_state->lex->lex_level > 1)
        return;

    obj.is_json = true;
    obj.val.json_hash = _state->json_hash;

    /* Otherwise, construct and return a tuple based on this level-1 object */
    populate_recordset_record(_state, &obj);

    /* Done with hash for this object */
    hash_destroy(_state->json_hash);
    _state->json_hash = NULL;
}

static void
populate_recordset_array_element_start(void *state, bool isnull)
{
    PopulateRecordsetState *_state = (PopulateRecordsetState *) state;

    if (_state->lex->lex_level == 1 &&
        _state->lex->token_type != JSON_TOKEN_OBJECT_START)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("argument of %s must be an array of objects",
                        _state->function_name)));
}

static void
populate_recordset_array_start(void *state)
{
    /* nothing to do */
}

static void
populate_recordset_scalar(void *state, char *token, JsonTokenType tokentype)
{
    PopulateRecordsetState *_state = (PopulateRecordsetState *) state;

    if (_state->lex->lex_level == 0)
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot call %s on a scalar",
                        _state->function_name)));

    if (_state->lex->lex_level == 2)
        _state->saved_scalar = token;
}

static void
populate_recordset_object_field_start(void *state, char *fname, bool isnull)
{
    PopulateRecordsetState *_state = (PopulateRecordsetState *) state;

    if (_state->lex->lex_level > 2)
        return;

    _state->saved_token_type = _state->lex->token_type;

    if (_state->lex->token_type == JSON_TOKEN_ARRAY_START ||
        _state->lex->token_type == JSON_TOKEN_OBJECT_START)
    {
        _state->save_json_start = _state->lex->token_start;
    }
    else
    {
        _state->save_json_start = NULL;
    }
}

static void
populate_recordset_object_field_end(void *state, char *fname, bool isnull)
{
    PopulateRecordsetState *_state = (PopulateRecordsetState *) state;
    JsonHashEntry *hashentry;
    bool        found;

    /*
     * Ignore nested fields.
     */
    if (_state->lex->lex_level > 2)
        return;

    /*
     * Ignore field names >= NAMEDATALEN - they can't match a record field.
     * (Note: without this test, the hash code would truncate the string at
     * NAMEDATALEN-1, and could then match against a similarly-truncated
     * record field name.  That would be a reasonable behavior, but this code
     * has previously insisted on exact equality, so we keep this behavior.)
     */
    if (strlen(fname) >= NAMEDATALEN)
        return;

    hashentry = hash_search(_state->json_hash, fname, HASH_ENTER, &found);

    /*
     * found being true indicates a duplicate. We don't do anything about
     * that, a later field with the same name overrides the earlier field.
     */

    hashentry->type = _state->saved_token_type;
    Assert(isnull == (hashentry->type == JSON_TOKEN_NULL));

    if (_state->save_json_start != NULL)
    {
        int         len = _state->lex->prev_token_terminator - _state->save_json_start;
        char       *val = palloc((len + 1) * sizeof(char));

        memcpy(val, _state->save_json_start, len);
        val[len] = '\0';
        hashentry->val = val;
    }
    else
    {
        /* must have had a scalar instead */
        hashentry->val = _state->saved_scalar;
    }
}

/*
 * Semantic actions for json_strip_nulls.
 *
 * Simply repeat the input on the output unless we encounter
 * a null object field. State for this is set when the field
 * is started and reset when the scalar action (which must be next)
 * is called.
 */

static void
sn_object_start(void *state)
{
    StripnullState *_state = (StripnullState *) state;

    appendStringInfoCharMacro(_state->strval, '{');
}

static void
sn_object_end(void *state)
{
    StripnullState *_state = (StripnullState *) state;

    appendStringInfoCharMacro(_state->strval, '}');
}

static void
sn_array_start(void *state)
{
    StripnullState *_state = (StripnullState *) state;

    appendStringInfoCharMacro(_state->strval, '[');
}

static void
sn_array_end(void *state)
{
    StripnullState *_state = (StripnullState *) state;

    appendStringInfoCharMacro(_state->strval, ']');
}

static void
sn_object_field_start(void *state, char *fname, bool isnull)
{
    StripnullState *_state = (StripnullState *) state;

    if (isnull)
    {
        /*
         * The next thing must be a scalar or isnull couldn't be true, so
         * there is no danger of this state being carried down into a nested
         * object or array. The flag will be reset in the scalar action.
         */
        _state->skip_next_null = true;
        return;
    }

    if (_state->strval->data[_state->strval->len - 1] != '{')
        appendStringInfoCharMacro(_state->strval, ',');

    /*
     * Unfortunately we don't have the quoted and escaped string any more, so
     * we have to re-escape it.
     */
    escape_json(_state->strval, fname);

    appendStringInfoCharMacro(_state->strval, ':');
}

static void
sn_array_element_start(void *state, bool isnull)
{
    StripnullState *_state = (StripnullState *) state;

    if (_state->strval->data[_state->strval->len - 1] != '[')
        appendStringInfoCharMacro(_state->strval, ',');
}

static void
sn_scalar(void *state, char *token, JsonTokenType tokentype)
{
    StripnullState *_state = (StripnullState *) state;

    if (_state->skip_next_null)
    {
        Assert(tokentype == JSON_TOKEN_NULL);
        _state->skip_next_null = false;
        return;
    }

    if (tokentype == JSON_TOKEN_STRING)
        escape_json(_state->strval, token);
    else
        appendStringInfoString(_state->strval, token);
}

/*
 * SQL function json_strip_nulls(json) -> json
 */
Datum
json_strip_nulls(PG_FUNCTION_ARGS)
{
    text       *json = PG_GETARG_TEXT_PP(0);
    StripnullState *state;
    JsonLexContext *lex;
    JsonSemAction *sem;

    lex = makeJsonLexContext(json, true);
    state = palloc0(sizeof(StripnullState));
    sem = palloc0(sizeof(JsonSemAction));

    state->strval = makeStringInfo();
    state->skip_next_null = false;
    state->lex = lex;

    sem->semstate = (void *) state;
    sem->object_start = sn_object_start;
    sem->object_end = sn_object_end;
    sem->array_start = sn_array_start;
    sem->array_end = sn_array_end;
    sem->scalar = sn_scalar;
    sem->array_element_start = sn_array_element_start;
    sem->object_field_start = sn_object_field_start;

    pg_parse_json(lex, sem);

    PG_RETURN_TEXT_P(cstring_to_text_with_len(state->strval->data,
                                              state->strval->len));

}

/*
 * SQL function jsonb_strip_nulls(jsonb) -> jsonb
 */
Datum
jsonb_strip_nulls(PG_FUNCTION_ARGS)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);
    JsonbIterator *it;
    JsonbParseState *parseState = NULL;
    JsonbValue *res = NULL;
    JsonbValue  v,
                k;
    JsonbIteratorToken type;
    bool        last_was_key = false;

    if (JB_ROOT_IS_SCALAR(jb))
        PG_RETURN_POINTER(jb);

    it = JsonbIteratorInit(&jb->root);

    while ((type = JsonbIteratorNext(&it, &v, false)) != WJB_DONE)
    {
        Assert(!(type == WJB_KEY && last_was_key));

        if (type == WJB_KEY)
        {
            /* stash the key until we know if it has a null value */
            k = v;
            last_was_key = true;
            continue;
        }

        if (last_was_key)
        {
            /* if the last element was a key this one can't be */
            last_was_key = false;

            /* skip this field if value is null */
            if (type == WJB_VALUE && v.type == jbvNull)
                continue;

            /* otherwise, do a delayed push of the key */
            (void) pushJsonbValue(&parseState, WJB_KEY, &k);
        }

        if (type == WJB_VALUE || type == WJB_ELEM)
            res = pushJsonbValue(&parseState, type, &v);
        else
            res = pushJsonbValue(&parseState, type, NULL);
    }

    Assert(res != NULL);

    PG_RETURN_POINTER(JsonbValueToJsonb(res));
}

/*
 * Add values from the jsonb to the parse state.
 *
 * If the parse state container is an object, the jsonb is pushed as
 * a value, not a key.
 *
 * This needs to be done using an iterator because pushJsonbValue doesn't
 * like getting jbvBinary values, so we can't just push jb as a whole.
 */
static void
addJsonbToParseState(JsonbParseState **jbps, Jsonb *jb)
{
    JsonbIterator *it;
    JsonbValue *o = &(*jbps)->contVal;
    JsonbValue  v;
    JsonbIteratorToken type;

    it = JsonbIteratorInit(&jb->root);

    Assert(o->type == jbvArray || o->type == jbvObject);

    if (JB_ROOT_IS_SCALAR(jb))
    {
        (void) JsonbIteratorNext(&it, &v, false);   /* skip array header */
        Assert(v.type == jbvArray);
        (void) JsonbIteratorNext(&it, &v, false);   /* fetch scalar value */

        switch (o->type)
        {
            case jbvArray:
                (void) pushJsonbValue(jbps, WJB_ELEM, &v);
                break;
            case jbvObject:
                (void) pushJsonbValue(jbps, WJB_VALUE, &v);
                break;
            default:
                elog(ERROR, "unexpected parent of nested structure");
        }
    }
    else
    {
        while ((type = JsonbIteratorNext(&it, &v, false)) != WJB_DONE)
        {
            if (type == WJB_KEY || type == WJB_VALUE || type == WJB_ELEM)
                (void) pushJsonbValue(jbps, type, &v);
            else
                (void) pushJsonbValue(jbps, type, NULL);
        }
    }

}

/*
 * SQL function jsonb_pretty (jsonb)
 *
 * Pretty-printed text for the jsonb
 */
Datum
jsonb_pretty(PG_FUNCTION_ARGS)
{
    Jsonb      *jb = PG_GETARG_JSONB_P(0);
    StringInfo  str = makeStringInfo();

    JsonbToCStringIndent(str, &jb->root, VARSIZE(jb));

    PG_RETURN_TEXT_P(cstring_to_text_with_len(str->data, str->len));
}

/*
 * SQL function jsonb_concat (jsonb, jsonb)
 *
 * function for || operator
 */
Datum
jsonb_concat(PG_FUNCTION_ARGS)
{
    Jsonb      *jb1 = PG_GETARG_JSONB_P(0);
    Jsonb      *jb2 = PG_GETARG_JSONB_P(1);
    JsonbParseState *state = NULL;
    JsonbValue *res;
    JsonbIterator *it1,
               *it2;

    /*
     * If one of the jsonb is empty, just return the other if it's not scalar
     * and both are of the same kind.  If it's a scalar or they are of
     * different kinds we need to perform the concatenation even if one is
     * empty.
     */
    if (JB_ROOT_IS_OBJECT(jb1) == JB_ROOT_IS_OBJECT(jb2))
    {
        if (JB_ROOT_COUNT(jb1) == 0 && !JB_ROOT_IS_SCALAR(jb2))
            PG_RETURN_JSONB_P(jb2);
        else if (JB_ROOT_COUNT(jb2) == 0 && !JB_ROOT_IS_SCALAR(jb1))
            PG_RETURN_JSONB_P(jb1);
    }

    it1 = JsonbIteratorInit(&jb1->root);
    it2 = JsonbIteratorInit(&jb2->root);

    res = IteratorConcat(&it1, &it2, &state);

    Assert(res != NULL);

    PG_RETURN_JSONB_P(JsonbValueToJsonb(res));
}


/*
 * SQL function jsonb_delete (jsonb, text)
 *
 * return a copy of the jsonb with the indicated item
 * removed.
 */
Datum
jsonb_delete(PG_FUNCTION_ARGS)
{
    Jsonb      *in = PG_GETARG_JSONB_P(0);
    text       *key = PG_GETARG_TEXT_PP(1);
    char       *keyptr = VARDATA_ANY(key);
    int         keylen = VARSIZE_ANY_EXHDR(key);
    JsonbParseState *state = NULL;
    JsonbIterator *it;
    JsonbValue  v,
               *res = NULL;
    bool        skipNested = false;
    JsonbIteratorToken r;

    if (JB_ROOT_IS_SCALAR(in))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot delete from scalar")));

    if (JB_ROOT_COUNT(in) == 0)
        PG_RETURN_JSONB_P(in);

    it = JsonbIteratorInit(&in->root);

    while ((r = JsonbIteratorNext(&it, &v, skipNested)) != WJB_DONE)
    {
        skipNested = true;

        if ((r == WJB_ELEM || r == WJB_KEY) &&
            (v.type == jbvString && keylen == v.val.string.len &&
             memcmp(keyptr, v.val.string.val, keylen) == 0))
        {
            /* skip corresponding value as well */
            if (r == WJB_KEY)
                (void) JsonbIteratorNext(&it, &v, true);

            continue;
        }

        res = pushJsonbValue(&state, r, r < WJB_BEGIN_ARRAY ? &v : NULL);
    }

    Assert(res != NULL);

    PG_RETURN_JSONB_P(JsonbValueToJsonb(res));
}

/*
 * SQL function jsonb_delete (jsonb, variadic text[])
 *
 * return a copy of the jsonb with the indicated items
 * removed.
 */
Datum
jsonb_delete_array(PG_FUNCTION_ARGS)
{
    Jsonb      *in = PG_GETARG_JSONB_P(0);
    ArrayType  *keys = PG_GETARG_ARRAYTYPE_P(1);
    Datum      *keys_elems;
    bool       *keys_nulls;
    int         keys_len;
    JsonbParseState *state = NULL;
    JsonbIterator *it;
    JsonbValue  v,
               *res = NULL;
    bool        skipNested = false;
    JsonbIteratorToken r;

    if (ARR_NDIM(keys) > 1)
        ereport(ERROR,
                (errcode(ERRCODE_ARRAY_SUBSCRIPT_ERROR),
                 errmsg("wrong number of array subscripts")));

    if (JB_ROOT_IS_SCALAR(in))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot delete from scalar")));

    if (JB_ROOT_COUNT(in) == 0)
        PG_RETURN_JSONB_P(in);

    deconstruct_array(keys, TEXTOID, -1, false, 'i',
                      &keys_elems, &keys_nulls, &keys_len);

    if (keys_len == 0)
        PG_RETURN_JSONB_P(in);

    it = JsonbIteratorInit(&in->root);

    while ((r = JsonbIteratorNext(&it, &v, skipNested)) != WJB_DONE)
    {
        skipNested = true;

        if ((r == WJB_ELEM || r == WJB_KEY) && v.type == jbvString)
        {
            int         i;
            bool        found = false;

            for (i = 0; i < keys_len; i++)
            {
                char       *keyptr;
                int         keylen;

                if (keys_nulls[i])
                    continue;

                keyptr = VARDATA_ANY(keys_elems[i]);
                keylen = VARSIZE_ANY_EXHDR(keys_elems[i]);
                if (keylen == v.val.string.len &&
                    memcmp(keyptr, v.val.string.val, keylen) == 0)
                {
                    found = true;
                    break;
                }
            }
            if (found)
            {
                /* skip corresponding value as well */
                if (r == WJB_KEY)
                    (void) JsonbIteratorNext(&it, &v, true);

                continue;
            }
        }

        res = pushJsonbValue(&state, r, r < WJB_BEGIN_ARRAY ? &v : NULL);
    }

    Assert(res != NULL);

    PG_RETURN_JSONB_P(JsonbValueToJsonb(res));
}

/*
 * SQL function jsonb_delete (jsonb, int)
 *
 * return a copy of the jsonb with the indicated item
 * removed. Negative int means count back from the
 * end of the items.
 */
Datum
jsonb_delete_idx(PG_FUNCTION_ARGS)
{
    Jsonb      *in = PG_GETARG_JSONB_P(0);
    int         idx = PG_GETARG_INT32(1);
    JsonbParseState *state = NULL;
    JsonbIterator *it;
    uint32      i = 0,
                n;
    JsonbValue  v,
               *res = NULL;
    JsonbIteratorToken r;

    if (JB_ROOT_IS_SCALAR(in))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot delete from scalar")));

    if (JB_ROOT_IS_OBJECT(in))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot delete from object using integer index")));

    if (JB_ROOT_COUNT(in) == 0)
        PG_RETURN_JSONB_P(in);

    it = JsonbIteratorInit(&in->root);

    r = JsonbIteratorNext(&it, &v, false);
    Assert(r == WJB_BEGIN_ARRAY);
    n = v.val.array.nElems;

    if (idx < 0)
    {
        if (-idx > n)
            idx = n;
        else
            idx = n + idx;
    }

    if (idx >= n)
        PG_RETURN_JSONB_P(in);

    pushJsonbValue(&state, r, NULL);

    while ((r = JsonbIteratorNext(&it, &v, true)) != WJB_DONE)
    {
        if (r == WJB_ELEM)
        {
            if (i++ == idx)
                continue;
        }

        res = pushJsonbValue(&state, r, r < WJB_BEGIN_ARRAY ? &v : NULL);
    }

    Assert(res != NULL);

    PG_RETURN_JSONB_P(JsonbValueToJsonb(res));
}

/*
 * SQL function jsonb_set(jsonb, text[], jsonb, boolean)
 */
Datum
jsonb_set(PG_FUNCTION_ARGS)
{
    Jsonb      *in = PG_GETARG_JSONB_P(0);
    ArrayType  *path = PG_GETARG_ARRAYTYPE_P(1);
    Jsonb      *newval = PG_GETARG_JSONB_P(2);
    bool        create = PG_GETARG_BOOL(3);
    JsonbValue *res = NULL;
    Datum      *path_elems;
    bool       *path_nulls;
    int         path_len;
    JsonbIterator *it;
    JsonbParseState *st = NULL;

    if (ARR_NDIM(path) > 1)
        ereport(ERROR,
                (errcode(ERRCODE_ARRAY_SUBSCRIPT_ERROR),
                 errmsg("wrong number of array subscripts")));

    if (JB_ROOT_IS_SCALAR(in))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot set path in scalar")));

    if (JB_ROOT_COUNT(in) == 0 && !create)
        PG_RETURN_JSONB_P(in);

    deconstruct_array(path, TEXTOID, -1, false, 'i',
                      &path_elems, &path_nulls, &path_len);

    if (path_len == 0)
        PG_RETURN_JSONB_P(in);

    it = JsonbIteratorInit(&in->root);

    res = setPath(&it, path_elems, path_nulls, path_len, &st,
                  0, newval, create ? JB_PATH_CREATE : JB_PATH_REPLACE);

    Assert(res != NULL);

    PG_RETURN_JSONB_P(JsonbValueToJsonb(res));
}


/*
 * SQL function jsonb_delete_path(jsonb, text[])
 */
Datum
jsonb_delete_path(PG_FUNCTION_ARGS)
{
    Jsonb      *in = PG_GETARG_JSONB_P(0);
    ArrayType  *path = PG_GETARG_ARRAYTYPE_P(1);
    JsonbValue *res = NULL;
    Datum      *path_elems;
    bool       *path_nulls;
    int         path_len;
    JsonbIterator *it;
    JsonbParseState *st = NULL;

    if (ARR_NDIM(path) > 1)
        ereport(ERROR,
                (errcode(ERRCODE_ARRAY_SUBSCRIPT_ERROR),
                 errmsg("wrong number of array subscripts")));

    if (JB_ROOT_IS_SCALAR(in))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot delete path in scalar")));

    if (JB_ROOT_COUNT(in) == 0)
        PG_RETURN_JSONB_P(in);

    deconstruct_array(path, TEXTOID, -1, false, 'i',
                      &path_elems, &path_nulls, &path_len);

    if (path_len == 0)
        PG_RETURN_JSONB_P(in);

    it = JsonbIteratorInit(&in->root);

    res = setPath(&it, path_elems, path_nulls, path_len, &st,
                  0, NULL, JB_PATH_DELETE);

    Assert(res != NULL);

    PG_RETURN_JSONB_P(JsonbValueToJsonb(res));
}

/*
 * SQL function jsonb_insert(jsonb, text[], jsonb, boolean)
 */
Datum
jsonb_insert(PG_FUNCTION_ARGS)
{
    Jsonb      *in = PG_GETARG_JSONB_P(0);
    ArrayType  *path = PG_GETARG_ARRAYTYPE_P(1);
    Jsonb      *newval = PG_GETARG_JSONB_P(2);
    bool        after = PG_GETARG_BOOL(3);
    JsonbValue *res = NULL;
    Datum      *path_elems;
    bool       *path_nulls;
    int         path_len;
    JsonbIterator *it;
    JsonbParseState *st = NULL;

    if (ARR_NDIM(path) > 1)
        ereport(ERROR,
                (errcode(ERRCODE_ARRAY_SUBSCRIPT_ERROR),
                 errmsg("wrong number of array subscripts")));

    if (JB_ROOT_IS_SCALAR(in))
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("cannot set path in scalar")));

    deconstruct_array(path, TEXTOID, -1, false, 'i',
                      &path_elems, &path_nulls, &path_len);

    if (path_len == 0)
        PG_RETURN_JSONB_P(in);

    it = JsonbIteratorInit(&in->root);

    res = setPath(&it, path_elems, path_nulls, path_len, &st, 0, newval,
                  after ? JB_PATH_INSERT_AFTER : JB_PATH_INSERT_BEFORE);

    Assert(res != NULL);

    PG_RETURN_JSONB_P(JsonbValueToJsonb(res));
}

/*
 * Iterate over all jsonb objects and merge them into one.
 * The logic of this function copied from the same hstore function,
 * except the case, when it1 & it2 represents jbvObject.
 * In that case we just append the content of it2 to it1 without any
 * verifications.
 */
static JsonbValue *
IteratorConcat(JsonbIterator **it1, JsonbIterator **it2,
               JsonbParseState **state)
{
    JsonbValue  v1,
                v2,
               *res = NULL;
    JsonbIteratorToken r1,
                r2,
                rk1,
                rk2;

    r1 = rk1 = JsonbIteratorNext(it1, &v1, false);
    r2 = rk2 = JsonbIteratorNext(it2, &v2, false);

    /*
     * Both elements are objects.
     */
    if (rk1 == WJB_BEGIN_OBJECT && rk2 == WJB_BEGIN_OBJECT)
    {
        /*
         * Append the all tokens from v1 to res, except last WJB_END_OBJECT
         * (because res will not be finished yet).
         */
        pushJsonbValue(state, r1, NULL);
        while ((r1 = JsonbIteratorNext(it1, &v1, true)) != WJB_END_OBJECT)
            pushJsonbValue(state, r1, &v1);

        /*
         * Append the all tokens from v2 to res, include last WJB_END_OBJECT
         * (the concatenation will be completed).
         */
        while ((r2 = JsonbIteratorNext(it2, &v2, true)) != WJB_DONE)
            res = pushJsonbValue(state, r2, r2 != WJB_END_OBJECT ? &v2 : NULL);
    }

    /*
     * Both elements are arrays (either can be scalar).
     */
    else if (rk1 == WJB_BEGIN_ARRAY && rk2 == WJB_BEGIN_ARRAY)
    {
        pushJsonbValue(state, r1, NULL);

        while ((r1 = JsonbIteratorNext(it1, &v1, true)) != WJB_END_ARRAY)
        {
            Assert(r1 == WJB_ELEM);
            pushJsonbValue(state, r1, &v1);
        }

        while ((r2 = JsonbIteratorNext(it2, &v2, true)) != WJB_END_ARRAY)
        {
            Assert(r2 == WJB_ELEM);
            pushJsonbValue(state, WJB_ELEM, &v2);
        }

        res = pushJsonbValue(state, WJB_END_ARRAY, NULL /* signal to sort */ );
    }
    /* have we got array || object or object || array? */
    else if (((rk1 == WJB_BEGIN_ARRAY && !(*it1)->isScalar) && rk2 == WJB_BEGIN_OBJECT) ||
             (rk1 == WJB_BEGIN_OBJECT && (rk2 == WJB_BEGIN_ARRAY && !(*it2)->isScalar)))
    {

        JsonbIterator **it_array = rk1 == WJB_BEGIN_ARRAY ? it1 : it2;
        JsonbIterator **it_object = rk1 == WJB_BEGIN_OBJECT ? it1 : it2;

        bool        prepend = (rk1 == WJB_BEGIN_OBJECT);

        pushJsonbValue(state, WJB_BEGIN_ARRAY, NULL);

        if (prepend)
        {
            pushJsonbValue(state, WJB_BEGIN_OBJECT, NULL);
            while ((r1 = JsonbIteratorNext(it_object, &v1, true)) != WJB_DONE)
                pushJsonbValue(state, r1, r1 != WJB_END_OBJECT ? &v1 : NULL);

            while ((r2 = JsonbIteratorNext(it_array, &v2, true)) != WJB_DONE)
                res = pushJsonbValue(state, r2, r2 != WJB_END_ARRAY ? &v2 : NULL);
        }
        else
        {
            while ((r1 = JsonbIteratorNext(it_array, &v1, true)) != WJB_END_ARRAY)
                pushJsonbValue(state, r1, &v1);

            pushJsonbValue(state, WJB_BEGIN_OBJECT, NULL);
            while ((r2 = JsonbIteratorNext(it_object, &v2, true)) != WJB_DONE)
                pushJsonbValue(state, r2, r2 != WJB_END_OBJECT ? &v2 : NULL);

            res = pushJsonbValue(state, WJB_END_ARRAY, NULL);
        }
    }
    else
    {
        /*
         * This must be scalar || object or object || scalar, as that's all
         * that's left. Both of these make no sense, so error out.
         */
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                 errmsg("invalid concatenation of jsonb objects")));
    }

    return res;
}

/*
 * Do most of the heavy work for jsonb_set/jsonb_insert
 *
 * If JB_PATH_DELETE bit is set in op_type, the element is to be removed.
 *
 * If any bit mentioned in JB_PATH_CREATE_OR_INSERT is set in op_type,
 * we create the new value if the key or array index does not exist.
 *
 * Bits JB_PATH_INSERT_BEFORE and JB_PATH_INSERT_AFTER in op_type
 * behave as JB_PATH_CREATE if new value is inserted in JsonbObject.
 *
 * All path elements before the last must already exist
 * whatever bits in op_type are set, or nothing is done.
 */
static JsonbValue *
setPath(JsonbIterator **it, Datum *path_elems,
        bool *path_nulls, int path_len,
        JsonbParseState **st, int level, Jsonb *newval, int op_type)
{
    JsonbValue  v;
    JsonbIteratorToken r;
    JsonbValue *res;

    check_stack_depth();

    if (path_nulls[level])
        ereport(ERROR,
                (errcode(ERRCODE_NULL_VALUE_NOT_ALLOWED),
                 errmsg("path element at position %d is null",
                        level + 1)));

    r = JsonbIteratorNext(it, &v, false);

    switch (r)
    {
        case WJB_BEGIN_ARRAY:
            (void) pushJsonbValue(st, r, NULL);
            setPathArray(it, path_elems, path_nulls, path_len, st, level,
                         newval, v.val.array.nElems, op_type);
            r = JsonbIteratorNext(it, &v, false);
            Assert(r == WJB_END_ARRAY);
            res = pushJsonbValue(st, r, NULL);
            break;
        case WJB_BEGIN_OBJECT:
            (void) pushJsonbValue(st, r, NULL);
            setPathObject(it, path_elems, path_nulls, path_len, st, level,
                          newval, v.val.object.nPairs, op_type);
            r = JsonbIteratorNext(it, &v, true);
            Assert(r == WJB_END_OBJECT);
            res = pushJsonbValue(st, r, NULL);
            break;
        case WJB_ELEM:
        case WJB_VALUE:
            res = pushJsonbValue(st, r, &v);
            break;
        default:
            elog(ERROR, "unrecognized iterator result: %d", (int) r);
            res = NULL;         /* keep compiler quiet */
            break;
    }

    return res;
}

/*
 * Object walker for setPath
 */
static void
setPathObject(JsonbIterator **it, Datum *path_elems, bool *path_nulls,
              int path_len, JsonbParseState **st, int level,
              Jsonb *newval, uint32 npairs, int op_type)
{
    JsonbValue  v;
    int         i;
    JsonbValue  k;
    bool        done = false;

    if (level >= path_len || path_nulls[level])
        done = true;

    /* empty object is a special case for create */
    if ((npairs == 0) && (op_type & JB_PATH_CREATE_OR_INSERT) &&
        (level == path_len - 1))
    {
        JsonbValue  newkey;

        newkey.type = jbvString;
        newkey.val.string.len = VARSIZE_ANY_EXHDR(path_elems[level]);
        newkey.val.string.val = VARDATA_ANY(path_elems[level]);

        (void) pushJsonbValue(st, WJB_KEY, &newkey);
        addJsonbToParseState(st, newval);
    }

    for (i = 0; i < npairs; i++)
    {
        JsonbIteratorToken r = JsonbIteratorNext(it, &k, true);

        Assert(r == WJB_KEY);

        if (!done &&
            k.val.string.len == VARSIZE_ANY_EXHDR(path_elems[level]) &&
            memcmp(k.val.string.val, VARDATA_ANY(path_elems[level]),
                   k.val.string.len) == 0)
        {
            if (level == path_len - 1)
            {
                /*
                 * called from jsonb_insert(), it forbids redefining an
                 * existing value
                 */
                if (op_type & (JB_PATH_INSERT_BEFORE | JB_PATH_INSERT_AFTER))
                    ereport(ERROR,
                            (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                             errmsg("cannot replace existing key"),
                             errhint("Try using the function jsonb_set "
                                     "to replace key value.")));

                r = JsonbIteratorNext(it, &v, true);    /* skip value */
                if (!(op_type & JB_PATH_DELETE))
                {
                    (void) pushJsonbValue(st, WJB_KEY, &k);
                    addJsonbToParseState(st, newval);
                }
                done = true;
            }
            else
            {
                (void) pushJsonbValue(st, r, &k);
                setPath(it, path_elems, path_nulls, path_len,
                        st, level + 1, newval, op_type);
            }
        }
        else
        {
            if ((op_type & JB_PATH_CREATE_OR_INSERT) && !done &&
                level == path_len - 1 && i == npairs - 1)
            {
                JsonbValue  newkey;

                newkey.type = jbvString;
                newkey.val.string.len = VARSIZE_ANY_EXHDR(path_elems[level]);
                newkey.val.string.val = VARDATA_ANY(path_elems[level]);

                (void) pushJsonbValue(st, WJB_KEY, &newkey);
                addJsonbToParseState(st, newval);
            }

            (void) pushJsonbValue(st, r, &k);
            r = JsonbIteratorNext(it, &v, false);
            (void) pushJsonbValue(st, r, r < WJB_BEGIN_ARRAY ? &v : NULL);
            if (r == WJB_BEGIN_ARRAY || r == WJB_BEGIN_OBJECT)
            {
                int         walking_level = 1;

                while (walking_level != 0)
                {
                    r = JsonbIteratorNext(it, &v, false);

                    if (r == WJB_BEGIN_ARRAY || r == WJB_BEGIN_OBJECT)
                        ++walking_level;
                    if (r == WJB_END_ARRAY || r == WJB_END_OBJECT)
                        --walking_level;

                    (void) pushJsonbValue(st, r, r < WJB_BEGIN_ARRAY ? &v : NULL);
                }
            }
        }
    }
}

/*
 * Array walker for setPath
 */
static void
setPathArray(JsonbIterator **it, Datum *path_elems, bool *path_nulls,
             int path_len, JsonbParseState **st, int level,
             Jsonb *newval, uint32 nelems, int op_type)
{
    JsonbValue  v;
    int         idx,
                i;
    bool        done = false;

    /* pick correct index */
    if (level < path_len && !path_nulls[level])
    {
        char       *c = TextDatumGetCString(path_elems[level]);
        long        lindex;
        char       *badp;

        errno = 0;
        lindex = strtol(c, &badp, 10);
        if (errno != 0 || badp == c || *badp != '\0' || lindex > INT_MAX ||
            lindex < INT_MIN)
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION),
                     errmsg("path element at position %d is not an integer: \"%s\"",
                            level + 1, c)));
        idx = lindex;
    }
    else
        idx = nelems;

    if (idx < 0)
    {
        if (-idx > nelems)
            idx = INT_MIN;
        else
            idx = nelems + idx;
    }

    if (idx > 0 && idx > nelems)
        idx = nelems;

    /*
     * if we're creating, and idx == INT_MIN, we prepend the new value to the
     * array also if the array is empty - in which case we don't really care
     * what the idx value is
     */

    if ((idx == INT_MIN || nelems == 0) && (level == path_len - 1) &&
        (op_type & JB_PATH_CREATE_OR_INSERT))
    {
        Assert(newval != NULL);
        addJsonbToParseState(st, newval);
        done = true;
    }

    /* iterate over the array elements */
    for (i = 0; i < nelems; i++)
    {
        JsonbIteratorToken r;

        if (i == idx && level < path_len)
        {
            if (level == path_len - 1)
            {
                r = JsonbIteratorNext(it, &v, true);    /* skip */

                if (op_type & (JB_PATH_INSERT_BEFORE | JB_PATH_CREATE))
                    addJsonbToParseState(st, newval);

                /*
                 * We should keep current value only in case of
                 * JB_PATH_INSERT_BEFORE or JB_PATH_INSERT_AFTER because
                 * otherwise it should be deleted or replaced
                 */
                if (op_type & (JB_PATH_INSERT_AFTER | JB_PATH_INSERT_BEFORE))
                    (void) pushJsonbValue(st, r, &v);

                if (op_type & (JB_PATH_INSERT_AFTER | JB_PATH_REPLACE))
                    addJsonbToParseState(st, newval);

                done = true;
            }
            else
                (void) setPath(it, path_elems, path_nulls, path_len,
                               st, level + 1, newval, op_type);
        }
        else
        {
            r = JsonbIteratorNext(it, &v, false);

            (void) pushJsonbValue(st, r, r < WJB_BEGIN_ARRAY ? &v : NULL);

            if (r == WJB_BEGIN_ARRAY || r == WJB_BEGIN_OBJECT)
            {
                int         walking_level = 1;

                while (walking_level != 0)
                {
                    r = JsonbIteratorNext(it, &v, false);

                    if (r == WJB_BEGIN_ARRAY || r == WJB_BEGIN_OBJECT)
                        ++walking_level;
                    if (r == WJB_END_ARRAY || r == WJB_END_OBJECT)
                        --walking_level;

                    (void) pushJsonbValue(st, r, r < WJB_BEGIN_ARRAY ? &v : NULL);
                }
            }

            if ((op_type & JB_PATH_CREATE_OR_INSERT) && !done &&
                level == path_len - 1 && i == nelems - 1)
            {
                addJsonbToParseState(st, newval);
            }
        }
    }
}

/*
 * Parse information about what elements of a jsonb document we want to iterate
 * in functions iterate_json(b)_values. This information is presented in jsonb
 * format, so that it can be easily extended in the future.
 */
uint32
parse_jsonb_index_flags(Jsonb *jb)
{
    JsonbIterator *it;
    JsonbValue  v;
    JsonbIteratorToken type;
    uint32      flags = 0;

    it = JsonbIteratorInit(&jb->root);

    type = JsonbIteratorNext(&it, &v, false);

    /*
     * We iterate over array (scalar internally is represented as array, so,
     * we will accept it too) to check all its elements.  Flag names are
     * chosen the same as jsonb_typeof uses.
     */
    if (type != WJB_BEGIN_ARRAY)
        ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                        errmsg("wrong flag type, only arrays and scalars are allowed")));

    while ((type = JsonbIteratorNext(&it, &v, false)) == WJB_ELEM)
    {
        if (v.type != jbvString)
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                     errmsg("flag array element is not a string"),
                     errhint("Possible values are: \"string\", \"numeric\", \"boolean\", \"key\", and \"all\".")));

        if (v.val.string.len == 3 &&
            pg_strncasecmp(v.val.string.val, "all", 3) == 0)
            flags |= jtiAll;
        else if (v.val.string.len == 3 &&
                 pg_strncasecmp(v.val.string.val, "key", 3) == 0)
            flags |= jtiKey;
        else if (v.val.string.len == 6 &&
                 pg_strncasecmp(v.val.string.val, "string", 5) == 0)
            flags |= jtiString;
        else if (v.val.string.len == 7 &&
                 pg_strncasecmp(v.val.string.val, "numeric", 7) == 0)
            flags |= jtiNumeric;
        else if (v.val.string.len == 7 &&
                 pg_strncasecmp(v.val.string.val, "boolean", 7) == 0)
            flags |= jtiBool;
        else
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_PARAMETER_VALUE),
                     errmsg("wrong flag in flag array: \"%s\"",
                            pnstrdup(v.val.string.val, v.val.string.len)),
                     errhint("Possible values are: \"string\", \"numeric\", \"boolean\", \"key\", and \"all\".")));
    }

    /* expect end of array now */
    if (type != WJB_END_ARRAY)
        elog(ERROR, "unexpected end of flag array");

    /* get final WJB_DONE and free iterator */
    type = JsonbIteratorNext(&it, &v, false);
    if (type != WJB_DONE)
        elog(ERROR, "unexpected end of flag array");

    return flags;
}

/*
 * Iterate over jsonb values or elements, specified by flags, and pass them
 * together with an iteration state to a specified JsonIterateStringValuesAction.
 */
void
iterate_jsonb_values(Jsonb *jb, uint32 flags, void *state,
                     JsonIterateStringValuesAction action)
{
    JsonbIterator *it;
    JsonbValue  v;
    JsonbIteratorToken type;

    it = JsonbIteratorInit(&jb->root);

    /*
     * Just recursively iterating over jsonb and call callback on all
     * corresponding elements
     */
    while ((type = JsonbIteratorNext(&it, &v, false)) != WJB_DONE)
    {
        if (type == WJB_KEY)
        {
            if (flags & jtiKey)
                action(state, v.val.string.val, v.val.string.len);

            continue;
        }
        else if (!(type == WJB_VALUE || type == WJB_ELEM))
        {
            /* do not call callback for composite JsonbValue */
            continue;
        }

        /* JsonbValue is a value of object or element of array */
        switch (v.type)
        {
            case jbvString:
                if (flags & jtiString)
                    action(state, v.val.string.val, v.val.string.len);
                break;
            case jbvNumeric:
                if (flags & jtiNumeric)
                {
                    char       *val;

                    val = DatumGetCString(DirectFunctionCall1(numeric_out,
                                                              NumericGetDatum(v.val.numeric)));

                    action(state, val, strlen(val));
                    pfree(val);
                }
                break;
            case jbvBool:
                if (flags & jtiBool)
                {
                    if (v.val.boolean)
                        action(state, "true", 4);
                    else
                        action(state, "false", 5);
                }
                break;
            default:
                /* do not call callback for composite JsonbValue */
                break;
        }
    }
}

/*
 * Iterate over json values and elements, specified by flags, and pass them
 * together with an iteration state to a specified JsonIterateStringValuesAction.
 */
void
iterate_json_values(text *json, uint32 flags, void *action_state,
                    JsonIterateStringValuesAction action)
{
    JsonLexContext *lex = makeJsonLexContext(json, true);
    JsonSemAction *sem = palloc0(sizeof(JsonSemAction));
    IterateJsonStringValuesState *state = palloc0(sizeof(IterateJsonStringValuesState));

    state->lex = lex;
    state->action = action;
    state->action_state = action_state;
    state->flags = flags;

    sem->semstate = (void *) state;
    sem->scalar = iterate_values_scalar;
    sem->object_field_start = iterate_values_object_field_start;

    pg_parse_json(lex, sem);
}

/*
 * An auxiliary function for iterate_json_values to invoke a specified
 * JsonIterateStringValuesAction for specified values.
 */
static void
iterate_values_scalar(void *state, char *token, JsonTokenType tokentype)
{
    IterateJsonStringValuesState *_state = (IterateJsonStringValuesState *) state;

    switch (tokentype)
    {
        case JSON_TOKEN_STRING:
            if (_state->flags & jtiString)
                _state->action(_state->action_state, token, strlen(token));
            break;
        case JSON_TOKEN_NUMBER:
            if (_state->flags & jtiNumeric)
                _state->action(_state->action_state, token, strlen(token));
            break;
        case JSON_TOKEN_TRUE:
        case JSON_TOKEN_FALSE:
            if (_state->flags & jtiBool)
                _state->action(_state->action_state, token, strlen(token));
            break;
        default:
            /* do not call callback for any other token */
            break;
    }
}

static void
iterate_values_object_field_start(void *state, char *fname, bool isnull)
{
    IterateJsonStringValuesState *_state = (IterateJsonStringValuesState *) state;

    if (_state->flags & jtiKey)
    {
        char       *val = pstrdup(fname);

        _state->action(_state->action_state, val, strlen(val));
    }
}

/*
 * Iterate over a jsonb, and apply a specified JsonTransformStringValuesAction
 * to every string value or element. Any necessary context for a
 * JsonTransformStringValuesAction can be passed in the action_state variable.
 * Function returns a copy of an original jsonb object with transformed values.
 */
Jsonb *
transform_jsonb_string_values(Jsonb *jsonb, void *action_state,
                              JsonTransformStringValuesAction transform_action)
{
    JsonbIterator *it;
    JsonbValue  v,
               *res = NULL;
    JsonbIteratorToken type;
    JsonbParseState *st = NULL;
    text       *out;
    bool        is_scalar = false;

    it = JsonbIteratorInit(&jsonb->root);
    is_scalar = it->isScalar;

    while ((type = JsonbIteratorNext(&it, &v, false)) != WJB_DONE)
    {
        if ((type == WJB_VALUE || type == WJB_ELEM) && v.type == jbvString)
        {
            out = transform_action(action_state, v.val.string.val, v.val.string.len);
            v.val.string.val = VARDATA_ANY(out);
            v.val.string.len = VARSIZE_ANY_EXHDR(out);
            res = pushJsonbValue(&st, type, type < WJB_BEGIN_ARRAY ? &v : NULL);
        }
        else
        {
            res = pushJsonbValue(&st, type, (type == WJB_KEY ||
                                             type == WJB_VALUE ||
                                             type == WJB_ELEM) ? &v : NULL);
        }
    }

    if (res->type == jbvArray)
        res->val.array.rawScalar = is_scalar;

    return JsonbValueToJsonb(res);
}

/*
 * Iterate over a json, and apply a specified JsonTransformStringValuesAction
 * to every string value or element. Any necessary context for a
 * JsonTransformStringValuesAction can be passed in the action_state variable.
 * Function returns a StringInfo, which is a copy of an original json with
 * transformed values.
 */
text *
transform_json_string_values(text *json, void *action_state,
                             JsonTransformStringValuesAction transform_action)
{
    JsonLexContext *lex = makeJsonLexContext(json, true);
    JsonSemAction *sem = palloc0(sizeof(JsonSemAction));
    TransformJsonStringValuesState *state = palloc0(sizeof(TransformJsonStringValuesState));

    state->lex = lex;
    state->strval = makeStringInfo();
    state->action = transform_action;
    state->action_state = action_state;

    sem->semstate = (void *) state;
    sem->scalar = transform_string_values_scalar;
    sem->object_start = transform_string_values_object_start;
    sem->object_end = transform_string_values_object_end;
    sem->array_start = transform_string_values_array_start;
    sem->array_end = transform_string_values_array_end;
    sem->scalar = transform_string_values_scalar;
    sem->array_element_start = transform_string_values_array_element_start;
    sem->object_field_start = transform_string_values_object_field_start;

    pg_parse_json(lex, sem);

    return cstring_to_text_with_len(state->strval->data, state->strval->len);
}

/*
 * Set of auxiliary functions for transform_json_string_values to invoke a
 * specified JsonTransformStringValuesAction for all values and left everything
 * else untouched.
 */
static void
transform_string_values_object_start(void *state)
{
    TransformJsonStringValuesState *_state = (TransformJsonStringValuesState *) state;

    appendStringInfoCharMacro(_state->strval, '{');
}

static void
transform_string_values_object_end(void *state)
{
    TransformJsonStringValuesState *_state = (TransformJsonStringValuesState *) state;

    appendStringInfoCharMacro(_state->strval, '}');
}

static void
transform_string_values_array_start(void *state)
{
    TransformJsonStringValuesState *_state = (TransformJsonStringValuesState *) state;

    appendStringInfoCharMacro(_state->strval, '[');
}

static void
transform_string_values_array_end(void *state)
{
    TransformJsonStringValuesState *_state = (TransformJsonStringValuesState *) state;

    appendStringInfoCharMacro(_state->strval, ']');
}

static void
transform_string_values_object_field_start(void *state, char *fname, bool isnull)
{
    TransformJsonStringValuesState *_state = (TransformJsonStringValuesState *) state;

    if (_state->strval->data[_state->strval->len - 1] != '{')
        appendStringInfoCharMacro(_state->strval, ',');

    /*
     * Unfortunately we don't have the quoted and escaped string any more, so
     * we have to re-escape it.
     */
    escape_json(_state->strval, fname);
    appendStringInfoCharMacro(_state->strval, ':');
}

static void
transform_string_values_array_element_start(void *state, bool isnull)
{
    TransformJsonStringValuesState *_state = (TransformJsonStringValuesState *) state;

    if (_state->strval->data[_state->strval->len - 1] != '[')
        appendStringInfoCharMacro(_state->strval, ',');
}

static void
transform_string_values_scalar(void *state, char *token, JsonTokenType tokentype)
{
    TransformJsonStringValuesState *_state = (TransformJsonStringValuesState *) state;

    if (tokentype == JSON_TOKEN_STRING)
    {
        text       *out = _state->action(_state->action_state, token, strlen(token));

        escape_json(_state->strval, text_to_cstring(out));
    }
    else
        appendStringInfoString(_state->strval, token);
}