/* Tuple object implementation */

#include "Python.h"

#include "pycore_object.h"

#include "pycore_pystate.h"

#include "pycore_accu.h"

/*[clinic input]

class tuple "PyTupleObject *" "&PyTuple_Type"

[clinic start generated code]*/

/*[clinic end generated code: output=da39a3ee5e6b4b0d input=f051ba3cfdf9a189]*/

#include "clinic/tupleobject.c.h"

/* Speed optimization to avoid frequent malloc/free of small tuples */

#ifndef PyTuple_MAXSAVESIZE

#define PyTuple_MAXSAVESIZE     20  /* Largest tuple to save on free list */

#endif

#ifndef PyTuple_MAXFREELIST

#define PyTuple_MAXFREELIST  2000  /* Maximum number of tuples of each size to save */

#endif

#if PyTuple_MAXSAVESIZE > 0

/* Entries 1 up to PyTuple_MAXSAVESIZE are free lists, entry 0 is the empty

   tuple () of which at most one instance will be allocated.

*/

static PyTupleObject *free_list[PyTuple_MAXSAVESIZE];

static int numfree[PyTuple_MAXSAVESIZE];

#endif

#ifdef COUNT_ALLOCS

Py_ssize_t _Py_fast_tuple_allocs;

Py_ssize_t _Py_tuple_zero_allocs;

#endif

/* Debug statistic to count GC tracking of tuples.

   Please note that tuples are only untracked when considered by the GC, and

   many of them will be dead before. Therefore, a tracking rate close to 100%

   does not necessarily prove that the heuristic is inefficient.

*/

#ifdef SHOW_TRACK_COUNT

static Py_ssize_t count_untracked = 0;

static Py_ssize_t count_tracked = 0;

static void

show_track(void)

{

    PyInterpreterState *interp = _PyInterpreterState_Get();

    if (!interp->config.show_alloc_count) {

        return;

    }

    fprintf(stderr, "Tuples created: %" PY_FORMAT_SIZE_T "d\n",

        count_tracked + count_untracked);

    fprintf(stderr, "Tuples tracked by the GC: %" PY_FORMAT_SIZE_T

        "d\n", count_tracked);

    fprintf(stderr, "%.2f%% tuple tracking rate\n\n",

        (100.0*count_tracked/(count_untracked+count_tracked)));

}

#endif

/* Print summary info about the state of the optimized allocator */

void

_PyTuple_DebugMallocStats(FILE *out)

{

#if PyTuple_MAXSAVESIZE > 0

    int i;

    char buf[128];

    for (i = 1; i < PyTuple_MAXSAVESIZE; i++) {

        PyOS_snprintf(buf, sizeof(buf),

                      "free %d-sized PyTupleObject", i);

        _PyDebugAllocatorStats(out,

                               buf,

                               numfree[i], _PyObject_VAR_SIZE(&PyTuple_Type, i));

    }

#endif

}

PyObject *

PyTuple_New(Py_ssize_t size)

{

    PyTupleObject *op;

    Py_ssize_t i;

    if (size < 0) {

        PyErr_BadInternalCall();

        return NULL;

    }

#if PyTuple_MAXSAVESIZE > 0

    if (size == 0 && free_list[0]) {

        op = free_list[0];

        Py_INCREF(op);

#ifdef COUNT_ALLOCS

        _Py_tuple_zero_allocs++;

#endif

        return (PyObject *) op;

    }

    if (size < PyTuple_MAXSAVESIZE && (op = free_list[size]) != NULL) {

        free_list[size] = (PyTupleObject *) op->ob_item[0];

        numfree[size]--;

#ifdef COUNT_ALLOCS

        _Py_fast_tuple_allocs++;

#endif

        /* Inline PyObject_InitVar */

#ifdef Py_TRACE_REFS

        Py_SIZE(op) = size;

        Py_TYPE(op) = &PyTuple_Type;

#endif

        _Py_NewReference((PyObject *)op);

    }

    else

#endif

    {

        /* Check for overflow */

        if ((size_t)size > ((size_t)PY_SSIZE_T_MAX - sizeof(PyTupleObject) -

                    sizeof(PyObject *)) / sizeof(PyObject *)) {

            return PyErr_NoMemory();

        }

        op = PyObject_GC_NewVar(PyTupleObject, &PyTuple_Type, size);

        if (op == NULL)

            return NULL;

    }

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

        op->ob_item[i] = NULL;

#if PyTuple_MAXSAVESIZE > 0

    if (size == 0) {

        free_list[0] = op;

        ++numfree[0];

        Py_INCREF(op);          /* extra INCREF so that this is never freed */

    }

#endif

#ifdef SHOW_TRACK_COUNT

    count_tracked++;

#endif

    _PyObject_GC_TRACK(op);

    return (PyObject *) op;

}

Py_ssize_t

PyTuple_Size(PyObject *op)

{

    if (!PyTuple_Check(op)) {

        PyErr_BadInternalCall();

        return -1;

    }

    else

        return Py_SIZE(op);

}

PyObject *

PyTuple_GetItem(PyObject *op, Py_ssize_t i)

{

    if (!PyTuple_Check(op)) {

        PyErr_BadInternalCall();

        return NULL;

    }

    if (i < 0 || i >= Py_SIZE(op)) {

        PyErr_SetString(PyExc_IndexError, "tuple index out of range");

        return NULL;

    }

    return ((PyTupleObject *)op) -> ob_item[i];

}

int

PyTuple_SetItem(PyObject *op, Py_ssize_t i, PyObject *newitem)

{

    PyObject **p;

    if (!PyTuple_Check(op) || op->ob_refcnt != 1) {

        Py_XDECREF(newitem);

        PyErr_BadInternalCall();

        return -1;

    }

    if (i < 0 || i >= Py_SIZE(op)) {

        Py_XDECREF(newitem);

        PyErr_SetString(PyExc_IndexError,

                        "tuple assignment index out of range");

        return -1;

    }

    p = ((PyTupleObject *)op) -> ob_item + i;

    Py_XSETREF(*p, newitem);

    return 0;

}

void

_PyTuple_MaybeUntrack(PyObject *op)

{

    PyTupleObject *t;

    Py_ssize_t i, n;

    if (!PyTuple_CheckExact(op) || !_PyObject_GC_IS_TRACKED(op))

        return;

    t = (PyTupleObject *) op;

    n = Py_SIZE(t);

    for (i = 0; i < n; i++) {

        PyObject *elt = PyTuple_GET_ITEM(t, i);

        /* Tuple with NULL elements aren't

           fully constructed, don't untrack

           them yet. */

        if (!elt ||

            _PyObject_GC_MAY_BE_TRACKED(elt))

            return;

    }

#ifdef SHOW_TRACK_COUNT

    count_tracked--;

    count_untracked++;

#endif

    _PyObject_GC_UNTRACK(op);

}

PyObject *

PyTuple_Pack(Py_ssize_t n, ...)

{

    Py_ssize_t i;

    PyObject *o;

    PyObject *result;

    PyObject **items;

    va_list vargs;

    va_start(vargs, n);

    result = PyTuple_New(n);

    if (result == NULL) {

        va_end(vargs);

        return NULL;

    }

    items = ((PyTupleObject *)result)->ob_item;

    for (i = 0; i < n; i++) {

        o = va_arg(vargs, PyObject *);

        Py_INCREF(o);

        items[i] = o;

    }

    va_end(vargs);

    return result;

}

/* Methods */

static void

tupledealloc(PyTupleObject *op)

{

    Py_ssize_t i;

    Py_ssize_t len =  Py_SIZE(op);

    PyObject_GC_UnTrack(op);

    Py_TRASHCAN_BEGIN(op, tupledealloc)

    if (len > 0) {

        i = len;

        while (--i >= 0)

            Py_XDECREF(op->ob_item[i]);

#if PyTuple_MAXSAVESIZE > 0

        if (len < PyTuple_MAXSAVESIZE &&

            numfree[len] < PyTuple_MAXFREELIST &&

            Py_TYPE(op) == &PyTuple_Type)

        {

            op->ob_item[0] = (PyObject *) free_list[len];

            numfree[len]++;

            free_list[len] = op;

            goto done; /* return */

        }

#endif

    }

    Py_TYPE(op)->tp_free((PyObject *)op);

done:

    Py_TRASHCAN_END

}

static PyObject *

tuplerepr(PyTupleObject *v)

{

    Py_ssize_t i, n;

    _PyUnicodeWriter writer;

    n = Py_SIZE(v);

    if (n == 0)

        return PyUnicode_FromString("()");

    /* While not mutable, it is still possible to end up with a cycle in a

       tuple through an object that stores itself within a tuple (and thus

       infinitely asks for the repr of itself). This should only be

       possible within a type. */

    i = Py_ReprEnter((PyObject *)v);

    if (i != 0) {

        return i > 0 ? PyUnicode_FromString("(...)") : NULL;

    }

    _PyUnicodeWriter_Init(&writer);

    writer.overallocate = 1;

    if (Py_SIZE(v) > 1) {

        /* "(" + "1" + ", 2" * (len - 1) + ")" */

        writer.min_length = 1 + 1 + (2 + 1) * (Py_SIZE(v) - 1) + 1;

    }

    else {

        /* "(1,)" */

        writer.min_length = 4;

    }

    if (_PyUnicodeWriter_WriteChar(&writer, '(') < 0)

        goto error;

    /* Do repr() on each element. */

    for (i = 0; i < n; ++i) {

        PyObject *s;

        if (i > 0) {

            if (_PyUnicodeWriter_WriteASCIIString(&writer, ", ", 2) < 0)

                goto error;

        }

        s = PyObject_Repr(v->ob_item[i]);

        if (s == NULL)

            goto error;

        if (_PyUnicodeWriter_WriteStr(&writer, s) < 0) {

            Py_DECREF(s);

            goto error;

        }

        Py_DECREF(s);

    }

    writer.overallocate = 0;

    if (n > 1) {

        if (_PyUnicodeWriter_WriteChar(&writer, ')') < 0)

            goto error;

    }

    else {

        if (_PyUnicodeWriter_WriteASCIIString(&writer, ",)", 2) < 0)

            goto error;

    }

    Py_ReprLeave((PyObject *)v);

    return _PyUnicodeWriter_Finish(&writer);

error:

    _PyUnicodeWriter_Dealloc(&writer);

    Py_ReprLeave((PyObject *)v);

    return NULL;

}

/* Hash for tuples. This is a slightly simplified version of the xxHash

   non-cryptographic hash:

   - we do not use any parallellism, there is only 1 accumulator.

   - we drop the final mixing since this is just a permutation of the

     output space: it does not help against collisions.

   - at the end, we mangle the length with a single constant.

   For the xxHash specification, see

   https://github.com/Cyan4973/xxHash/blob/master/doc/xxhash_spec.md

   Below are the official constants from the xxHash specification. Optimizing

   compilers should emit a single "rotate" instruction for the

   _PyHASH_XXROTATE() expansion. If that doesn't happen for some important

   platform, the macro could be changed to expand to a platform-specific rotate

   spelling instead.

*/

#if SIZEOF_PY_UHASH_T > 4

#define _PyHASH_XXPRIME_1 ((Py_uhash_t)11400714785074694791ULL)

#define _PyHASH_XXPRIME_2 ((Py_uhash_t)14029467366897019727ULL)

#define _PyHASH_XXPRIME_5 ((Py_uhash_t)2870177450012600261ULL)

#define _PyHASH_XXROTATE(x) ((x << 31) | (x >> 33))  /* Rotate left 31 bits */

#else

#define _PyHASH_XXPRIME_1 ((Py_uhash_t)2654435761UL)

#define _PyHASH_XXPRIME_2 ((Py_uhash_t)2246822519UL)

#define _PyHASH_XXPRIME_5 ((Py_uhash_t)374761393UL)

#define _PyHASH_XXROTATE(x) ((x << 13) | (x >> 19))  /* Rotate left 13 bits */

#endif

/* Tests have shown that it's not worth to cache the hash value, see

   https://bugs.python.org/issue9685 */

static Py_hash_t

tuplehash(PyTupleObject *v)

{

    Py_ssize_t i, len = Py_SIZE(v);

    PyObject **item = v->ob_item;

    Py_uhash_t acc = _PyHASH_XXPRIME_5;

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

        Py_uhash_t lane = PyObject_Hash(item[i]);

        if (lane == (Py_uhash_t)-1) {

            return -1;

        }

        acc += lane * _PyHASH_XXPRIME_2;

        acc = _PyHASH_XXROTATE(acc);

        acc *= _PyHASH_XXPRIME_1;

    }

    /* Add input length, mangled to keep the historical value of hash(()). */

    acc += len ^ (_PyHASH_XXPRIME_5 ^ 3527539UL);

    if (acc == (Py_uhash_t)-1) {

        return 1546275796;

    }

    return acc;

}

static Py_ssize_t

tuplelength(PyTupleObject *a)

{

    return Py_SIZE(a);

}

static int

tuplecontains(PyTupleObject *a, PyObject *el)

{

    Py_ssize_t i;

    int cmp;

    for (i = 0, cmp = 0 ; cmp == 0 && i < Py_SIZE(a); ++i)

        cmp = PyObject_RichCompareBool(el, PyTuple_GET_ITEM(a, i),

                                           Py_EQ);

    return cmp;

}

static PyObject *

tupleitem(PyTupleObject *a, Py_ssize_t i)

{

    if (i < 0 || i >= Py_SIZE(a)) {

        PyErr_SetString(PyExc_IndexError, "tuple index out of range");

        return NULL;

    }

    Py_INCREF(a->ob_item[i]);

    return a->ob_item[i];

}

PyObject *

_PyTuple_FromArray(PyObject *const *src, Py_ssize_t n)

{

    PyTupleObject *tuple = (PyTupleObject *)PyTuple_New(n);

    if (tuple == NULL) {

        return NULL;

    }

    PyObject **dst = tuple->ob_item;

    for (Py_ssize_t i = 0; i < n; i++) {

        PyObject *item = src[i];

        Py_INCREF(item);

        dst[i] = item;

    }

    return (PyObject *)tuple;

}

static PyObject *

tupleslice(PyTupleObject *a, Py_ssize_t ilow,

           Py_ssize_t ihigh)

{

    if (ilow < 0)

        ilow = 0;

    if (ihigh > Py_SIZE(a))

        ihigh = Py_SIZE(a);

    if (ihigh < ilow)

        ihigh = ilow;

    if (ilow == 0 && ihigh == Py_SIZE(a) && PyTuple_CheckExact(a)) {

        Py_INCREF(a);

        return (PyObject *)a;

    }

    return _PyTuple_FromArray(a->ob_item + ilow, ihigh - ilow);

}

PyObject *

PyTuple_GetSlice(PyObject *op, Py_ssize_t i, Py_ssize_t j)

{

    if (op == NULL || !PyTuple_Check(op)) {

        PyErr_BadInternalCall();

        return NULL;

    }

    return tupleslice((PyTupleObject *)op, i, j);

}

static PyObject *

tupleconcat(PyTupleObject *a, PyObject *bb)

{

    Py_ssize_t size;

    Py_ssize_t i;

    PyObject **src, **dest;

    PyTupleObject *np;

    if (Py_SIZE(a) == 0 && PyTuple_CheckExact(bb)) {

        Py_INCREF(bb);

        return bb;

    }

    if (!PyTuple_Check(bb)) {

        PyErr_Format(PyExc_TypeError,

             "can only concatenate tuple (not \"%.200s\") to tuple",

                 Py_TYPE(bb)->tp_name);

        return NULL;

    }

#define b ((PyTupleObject *)bb)

    if (Py_SIZE(b) == 0 && PyTuple_CheckExact(a)) {

        Py_INCREF(a);

        return (PyObject *)a;

    }

    if (Py_SIZE(a) > PY_SSIZE_T_MAX - Py_SIZE(b))

        return PyErr_NoMemory();

    size = Py_SIZE(a) + Py_SIZE(b);

    np = (PyTupleObject *) PyTuple_New(size);

    if (np == NULL) {

        return NULL;

    }

    src = a->ob_item;

    dest = np->ob_item;

    for (i = 0; i < Py_SIZE(a); i++) {

        PyObject *v = src[i];

        Py_INCREF(v);

        dest[i] = v;

    }

    src = b->ob_item;

    dest = np->ob_item + Py_SIZE(a);

    for (i = 0; i < Py_SIZE(b); i++) {

        PyObject *v = src[i];

        Py_INCREF(v);

        dest[i] = v;

    }

    return (PyObject *)np;

#undef b

}

static PyObject *

tuplerepeat(PyTupleObject *a, Py_ssize_t n)

{

    Py_ssize_t i, j;

    Py_ssize_t size;

    PyTupleObject *np;

    PyObject **p, **items;

    if (n < 0)

        n = 0;

    if (Py_SIZE(a) == 0 || n == 1) {

        if (PyTuple_CheckExact(a)) {

            /* Since tuples are immutable, we can return a shared

               copy in this case */

            Py_INCREF(a);

            return (PyObject *)a;

        }

        if (Py_SIZE(a) == 0)

            return PyTuple_New(0);

    }

    if (n > PY_SSIZE_T_MAX / Py_SIZE(a))

        return PyErr_NoMemory();

    size = Py_SIZE(a) * n;

    np = (PyTupleObject *) PyTuple_New(size);

    if (np == NULL)

        return NULL;

    p = np->ob_item;

    items = a->ob_item;

    for (i = 0; i < n; i++) {

        for (j = 0; j < Py_SIZE(a); j++) {

            *p = items[j];

            Py_INCREF(*p);

            p++;

        }

    }

    return (PyObject *) np;

}

/*[clinic input]

tuple.index

    value: object

    start: slice_index(accept={int}) = 0

    stop: slice_index(accept={int}, c_default="PY_SSIZE_T_MAX") = sys.maxsize

    /

Return first index of value.

Raises ValueError if the value is not present.

[clinic start generated code]*/

static PyObject *

tuple_index_impl(PyTupleObject *self, PyObject *value, Py_ssize_t start,

                 Py_ssize_t stop)

/*[clinic end generated code: output=07b6f9f3cb5c33eb input=fb39e9874a21fe3f]*/

{

    Py_ssize_t i;

    if (start < 0) {

        start += Py_SIZE(self);

        if (start < 0)

            start = 0;

    }

    if (stop < 0) {

        stop += Py_SIZE(self);

    }

    else if (stop > Py_SIZE(self)) {

        stop = Py_SIZE(self);

    }

    for (i = start; i < stop; i++) {

        int cmp = PyObject_RichCompareBool(self->ob_item[i], value, Py_EQ);

        if (cmp > 0)

            return PyLong_FromSsize_t(i);

        else if (cmp < 0)

            return NULL;

    }

    PyErr_SetString(PyExc_ValueError, "tuple.index(x): x not in tuple");

    return NULL;

}

/*[clinic input]

tuple.count

     value: object

     /

Return number of occurrences of value.

[clinic start generated code]*/

static PyObject *

tuple_count(PyTupleObject *self, PyObject *value)

/*[clinic end generated code: output=aa927affc5a97605 input=531721aff65bd772]*/

{

    Py_ssize_t count = 0;

    Py_ssize_t i;

    for (i = 0; i < Py_SIZE(self); i++) {

        int cmp = PyObject_RichCompareBool(self->ob_item[i], value, Py_EQ);

        if (cmp > 0)

            count++;

        else if (cmp < 0)

            return NULL;

    }

    return PyLong_FromSsize_t(count);

}

static int

tupletraverse(PyTupleObject *o, visitproc visit, void *arg)

{

    Py_ssize_t i;

    for (i = Py_SIZE(o); --i >= 0; )

        Py_VISIT(o->ob_item[i]);

    return 0;

}

static PyObject *

tuplerichcompare(PyObject *v, PyObject *w, int op)

{

    PyTupleObject *vt, *wt;

    Py_ssize_t i;

    Py_ssize_t vlen, wlen;

    if (!PyTuple_Check(v) || !PyTuple_Check(w))

        Py_RETURN_NOTIMPLEMENTED;

    vt = (PyTupleObject *)v;

    wt = (PyTupleObject *)w;

    vlen = Py_SIZE(vt);

    wlen = Py_SIZE(wt);

    /* Note:  the corresponding code for lists has an "early out" test

     * here when op is EQ or NE and the lengths differ.  That pays there,

     * but Tim was unable to find any real code where EQ/NE tuple

     * compares don't have the same length, so testing for it here would

     * have cost without benefit.

     */

    /* Search for the first index where items are different.

     * Note that because tuples are immutable, it's safe to reuse

     * vlen and wlen across the comparison calls.

     */

    for (i = 0; i < vlen && i < wlen; i++) {

        int k = PyObject_RichCompareBool(vt->ob_item[i],

                                         wt->ob_item[i], Py_EQ);

        if (k < 0)

            return NULL;

        if (!k)

            break;

    }

    if (i >= vlen || i >= wlen) {

        /* No more items to compare -- compare sizes */

        Py_RETURN_RICHCOMPARE(vlen, wlen, op);

    }

    /* We have an item that differs -- shortcuts for EQ/NE */

    if (op == Py_EQ) {

        Py_RETURN_FALSE;

    }

    if (op == Py_NE) {

        Py_RETURN_TRUE;

    }

    /* Compare the final item again using the proper operator */

    return PyObject_RichCompare(vt->ob_item[i], wt->ob_item[i], op);

}

static PyObject *

tuple_subtype_new(PyTypeObject *type, PyObject *iterable);

/*[clinic input]

@classmethod

tuple.__new__ as tuple_new

    iterable: object(c_default="NULL") = ()

    /

Built-in immutable sequence.

If no argument is given, the constructor returns an empty tuple.

If iterable is specified the tuple is initialized from iterable's items.

If the argument is a tuple, the return value is the same object.

[clinic start generated code]*/

static PyObject *

tuple_new_impl(PyTypeObject *type, PyObject *iterable)

/*[clinic end generated code: output=4546d9f0d469bce7 input=86963bcde633b5a2]*/

{

    if (type != &PyTuple_Type)

        return tuple_subtype_new(type, iterable);

    if (iterable == NULL)

        return PyTuple_New(0);

    else

        return PySequence_Tuple(iterable);

}

static PyObject *

tuple_subtype_new(PyTypeObject *type, PyObject *iterable)

{

    PyObject *tmp, *newobj, *item;

    Py_ssize_t i, n;

    assert(PyType_IsSubtype(type, &PyTuple_Type));

    tmp = tuple_new_impl(&PyTuple_Type, iterable);

    if (tmp == NULL)

        return NULL;

    assert(PyTuple_Check(tmp));

    newobj = type->tp_alloc(type, n = PyTuple_GET_SIZE(tmp));

    if (newobj == NULL) {

        Py_DECREF(tmp);

        return NULL;

    }

    for (i = 0; i < n; i++) {

        item = PyTuple_GET_ITEM(tmp, i);

        Py_INCREF(item);

        PyTuple_SET_ITEM(newobj, i, item);

    }

    Py_DECREF(tmp);

    return newobj;

}

static PySequenceMethods tuple_as_sequence = {

    (lenfunc)tuplelength,                       /* sq_length */

    (binaryfunc)tupleconcat,                    /* sq_concat */

    (ssizeargfunc)tuplerepeat,                  /* sq_repeat */

    (ssizeargfunc)tupleitem,                    /* sq_item */

    0,                                          /* sq_slice */

    0,                                          /* sq_ass_item */

    0,                                          /* sq_ass_slice */

    (objobjproc)tuplecontains,                  /* sq_contains */

};

static PyObject*

tuplesubscript(PyTupleObject* self, PyObject* item)

{

    if (PyIndex_Check(item)) {

        Py_ssize_t i = PyNumber_AsSsize_t(item, PyExc_IndexError);

        if (i == -1 && PyErr_Occurred())

            return NULL;

        if (i < 0)

            i += PyTuple_GET_SIZE(self);

        return tupleitem(self, i);

    }

    else if (PySlice_Check(item)) {

        Py_ssize_t start, stop, step, slicelength, i;

        size_t cur;

        PyObject* result;

        PyObject* it;

        PyObject **src, **dest;

        if (PySlice_Unpack(item, &start, &stop, &step) < 0) {

            return NULL;

        }

        slicelength = PySlice_AdjustIndices(PyTuple_GET_SIZE(self), &start,

                                            &stop, step);

        if (slicelength <= 0) {

            return PyTuple_New(0);

        }

        else if (start == 0 && step == 1 &&

                 slicelength == PyTuple_GET_SIZE(self) &&

                 PyTuple_CheckExact(self)) {

            Py_INCREF(self);

            return (PyObject *)self;

        }

        else {

            result = PyTuple_New(slicelength);

            if (!result) return NULL;

            src = self->ob_item;

            dest = ((PyTupleObject *)result)->ob_item;

            for (cur = start, i = 0; i < slicelength;

                 cur += step, i++) {

                it = src[cur];

                Py_INCREF(it);

                dest[i] = it;

            }

            return result;

        }

    }

    else {

        PyErr_Format(PyExc_TypeError,

                     "tuple indices must be integers or slices, not %.200s",

                     Py_TYPE(item)->tp_name);

        return NULL;

    }

}

/*[clinic input]

tuple.__getnewargs__

[clinic start generated code]*/

static PyObject *

tuple___getnewargs___impl(PyTupleObject *self)

/*[clinic end generated code: output=25e06e3ee56027e2 input=1aeb4b286a21639a]*/

{

    return Py_BuildValue("(N)", tupleslice(self, 0, Py_SIZE(self)));

}

static PyMethodDef tuple_methods[] = {

    TUPLE___GETNEWARGS___METHODDEF

    TUPLE_INDEX_METHODDEF

    TUPLE_COUNT_METHODDEF

    {NULL,              NULL}           /* sentinel */

};

static PyMappingMethods tuple_as_mapping = {

    (lenfunc)tuplelength,

    (binaryfunc)tuplesubscript,

    0

};

static PyObject *tuple_iter(PyObject *seq);

PyTypeObject PyTuple_Type = {

    PyVarObject_HEAD_INIT(&PyType_Type, 0)

    "tuple",

    sizeof(PyTupleObject) - sizeof(PyObject *),

    sizeof(PyObject *),

    (destructor)tupledealloc,                   /* tp_dealloc */

    0,                                          /* tp_vectorcall_offset */

    0,                                          /* tp_getattr */

    0,                                          /* tp_setattr */

    0,                                          /* tp_as_async */

    (reprfunc)tuplerepr,                        /* tp_repr */

    0,                                          /* tp_as_number */

    &tuple_as_sequence,                         /* tp_as_sequence */

    &tuple_as_mapping,                          /* tp_as_mapping */

    (hashfunc)tuplehash,                        /* tp_hash */

    0,                                          /* tp_call */

    0,                                          /* tp_str */

    PyObject_GenericGetAttr,                    /* tp_getattro */

    0,                                          /* tp_setattro */

    0,                                          /* tp_as_buffer */

    Py_TPFLAGS_DEFAULT | Py_TPFLAGS_HAVE_GC |

        Py_TPFLAGS_BASETYPE | Py_TPFLAGS_TUPLE_SUBCLASS, /* tp_flags */

    tuple_new__doc__,                           /* tp_doc */

    (traverseproc)tupletraverse,                /* tp_traverse */

    0,                                          /* tp_clear */

    tuplerichcompare,                           /* tp_richcompare */

    0,                                          /* tp_weaklistoffset */

    tuple_iter,                                 /* tp_iter */

    0,                                          /* tp_iternext */

    tuple_methods,                              /* tp_methods */

    0,                                          /* tp_members */

    0,                                          /* tp_getset */

    0,                                          /* tp_base */

    0,                                          /* tp_dict */

    0,                                          /* tp_descr_get */

    0,                                          /* tp_descr_set */

    0,                                          /* tp_dictoffset */

    0,                                          /* tp_init */

    0,                                          /* tp_alloc */

    tuple_new,                                  /* tp_new */

    PyObject_GC_Del,                            /* tp_free */

};

/* The following function breaks the notion that tuples are immutable:

   it changes the size of a tuple.  We get away with this only if there

   is only one module referencing the object.  You can also think of it

   as creating a new tuple object and destroying the old one, only more

   efficiently.  In any case, don't use this if the tuple may already be

   known to some other part of the code. */

int

_PyTuple_Resize(PyObject **pv, Py_ssize_t newsize)

{

    PyTupleObject *v;

    PyTupleObject *sv;

    Py_ssize_t i;

    Py_ssize_t oldsize;

    v = (PyTupleObject *) *pv;

    if (v == NULL || Py_TYPE(v) != &PyTuple_Type ||

        (Py_SIZE(v) != 0 && Py_REFCNT(v) != 1)) {

        *pv = 0;

        Py_XDECREF(v);

        PyErr_BadInternalCall();

        return -1;

    }

    oldsize = Py_SIZE(v);

    if (oldsize == newsize)

        return 0;

    if (oldsize == 0) {

        /* Empty tuples are often shared, so we should never

           resize them in-place even if we do own the only

           (current) reference */

        Py_DECREF(v);

        *pv = PyTuple_New(newsize);

        return *pv == NULL ? -1 : 0;

    }

    /* XXX UNREF/NEWREF interface should be more symmetrical */

    _Py_DEC_REFTOTAL;

    if (_PyObject_GC_IS_TRACKED(v))

        _PyObject_GC_UNTRACK(v);

    _Py_ForgetReference((PyObject *) v);

    /* DECREF items deleted by shrinkage */

    for (i = newsize; i < oldsize; i++) {

        Py_CLEAR(v->ob_item[i]);

    }

    sv = PyObject_GC_Resize(PyTupleObject, v, newsize);

    if (sv == NULL) {

        *pv = NULL;

        PyObject_GC_Del(v);

        return -1;

    }

    _Py_NewReference((PyObject *) sv);

    /* Zero out items added by growing */

    if (newsize > oldsize)

        memset(&sv->ob_item[oldsize], 0,

               sizeof(*sv->ob_item) * (newsize - oldsize));

    *pv = (PyObject *) sv;

    _PyObject_GC_TRACK(sv);

    return 0;

}

int

PyTuple_ClearFreeList(void)

{

    int freelist_size = 0;

#if PyTuple_MAXSAVESIZE > 0

    int i;

    for (i = 1; i < PyTuple_MAXSAVESIZE; i++) {

        PyTupleObject *p, *q;

        p = free_list[i];

        freelist_size += numfree[i];

        free_list[i] = NULL;

        numfree[i] = 0;

        while (p) {

            q = p;

            p = (PyTupleObject *)(p->ob_item[0]);

            PyObject_GC_Del(q);

        }

    }

#endif

    return freelist_size;

}

void

PyTuple_Fini(void)

{

#if PyTuple_MAXSAVESIZE > 0

    /* empty tuples are used all over the place and applications may

     * rely on the fact that an empty tuple is a singleton. */

    Py_CLEAR(free_list[0]);

    (void)PyTuple_ClearFreeList();

#endif

#ifdef SHOW_TRACK_COUNT

    show_track();

#endif

}

/*********************** Tuple Iterator **************************/

typedef struct {

    PyObject_HEAD

    Py_ssize_t it_index;

    PyTupleObject *it_seq; /* Set to NULL when iterator is exhausted */

} tupleiterobject;

static void

tupleiter_dealloc(tupleiterobject *it)

{

    _PyObject_GC_UNTRACK(it);

    Py_XDECREF(it->it_seq);

    PyObject_GC_Del(it);

}

static int