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dictobject.c
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dictobject.c
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/* Dictionary object implementation using a hash table */
#include "Python.h"
/*
* MINSIZE is the minimum size of a dictionary.
*/
#define MINSIZE 4
/* define this out if you don't want conversion statistics on exit */
#undef SHOW_CONVERSION_COUNTS
/*
Table of irreducible polynomials to efficiently cycle through
GF(2^n)-{0}, 2<=n<=30. A table size is always a power of 2.
*/
static long polys[] = {
4 + 3,
8 + 3,
16 + 3,
32 + 5,
64 + 3,
128 + 3,
256 + 29,
512 + 17,
1024 + 9,
2048 + 5,
4096 + 83,
8192 + 27,
16384 + 43,
32768 + 3,
65536 + 45,
131072 + 9,
262144 + 39,
524288 + 39,
1048576 + 9,
2097152 + 5,
4194304 + 3,
8388608 + 33,
16777216 + 27,
33554432 + 9,
67108864 + 71,
134217728 + 39,
268435456 + 9,
536870912 + 5,
1073741824 + 83,
0
};
/* Object used as dummy key to fill deleted entries */
static PyObject *dummy; /* Initialized by first call to newdictobject() */
/*
There are three kinds of slots in the table:
1. Unused. me_key == me_value == NULL
Does not hold an active (key, value) pair now and never did. Unused can
transition to Active upon key insertion. This is the only case in which
me_key is NULL, and is each slot's initial state.
2. Active. me_key != NULL and me_key != dummy and me_value != NULL
Holds an active (key, value) pair. Active can transition to Dummy upon
key deletion. This is the only case in which me_value != NULL.
3. Dummy. me_key == dummy and me_value == NULL
Previously held an active (key, value) pair, but that was deleted and an
active pair has not yet overwritten the slot. Dummy can transition to
Active upon key insertion. Dummy slots cannot be made Unused again
(cannot have me_key set to NULL), else the probe sequence in case of
collision would have no way to know they were once active.
Note: .popitem() abuses the me_hash field of an Unused or Dummy slot to
hold a search finger. The me_hash field of Unused or Dummy slots has no
meaning otherwise.
*/
typedef struct {
long me_hash; /* cached hash code of me_key */
PyObject *me_key;
PyObject *me_value;
#ifdef USE_CACHE_ALIGNED
long aligner;
#endif
} dictentry;
/*
To ensure the lookup algorithm terminates, there must be at least one Unused
slot (NULL key) in the table.
The value ma_fill is the number of non-NULL keys (sum of Active and Dummy);
ma_used is the number of non-NULL, non-dummy keys (== the number of non-NULL
values == the number of Active items).
To avoid slowing down lookups on a near-full table, we resize the table when
it is more than half filled.
*/
typedef struct dictobject dictobject;
struct dictobject {
PyObject_HEAD
int ma_fill; /* # Active + # Dummy */
int ma_used; /* # Active */
int ma_size; /* total # slots in ma_table */
int ma_poly; /* appopriate entry from polys vector */
dictentry *ma_table;
dictentry *(*ma_lookup)(dictobject *mp, PyObject *key, long hash);
};
/* forward declarations */
static dictentry *
lookdict_string(dictobject *mp, PyObject *key, long hash);
#ifdef SHOW_CONVERSION_COUNTS
static long created = 0L;
static long converted = 0L;
static void
show_counts(void)
{
fprintf(stderr, "created %ld string dicts\n", created);
fprintf(stderr, "converted %ld to normal dicts\n", converted);
fprintf(stderr, "%.2f%% conversion rate\n", (100.0*converted)/created);
}
#endif
PyObject *
PyDict_New(void)
{
register dictobject *mp;
if (dummy == NULL) { /* Auto-initialize dummy */
dummy = PyString_FromString("<dummy key>");
if (dummy == NULL)
return NULL;
#ifdef SHOW_CONVERSION_COUNTS
Py_AtExit(show_counts);
#endif
}
mp = PyObject_NEW(dictobject, &PyDict_Type);
if (mp == NULL)
return NULL;
mp->ma_size = 0;
mp->ma_poly = 0;
mp->ma_table = NULL;
mp->ma_fill = 0;
mp->ma_used = 0;
mp->ma_lookup = lookdict_string;
#ifdef SHOW_CONVERSION_COUNTS
++created;
#endif
PyObject_GC_Init(mp);
return (PyObject *)mp;
}
/*
The basic lookup function used by all operations.
This is based on Algorithm D from Knuth Vol. 3, Sec. 6.4.
Open addressing is preferred over chaining since the link overhead for
chaining would be substantial (100% with typical malloc overhead).
However, instead of going through the table at constant steps, we cycle
through the values of GF(2^n). This avoids modulo computations, being
much cheaper on RISC machines, without leading to clustering.
The initial probe index is computed as hash mod the table size.
Subsequent probe indices use the values of x^i in GF(2^n)-{0} as an offset,
where x is a root. The initial offset is derived from hash, too.
All arithmetic on hash should ignore overflow.
(This version is due to Reimer Behrends, some ideas are also due to
Jyrki Alakuijala and Vladimir Marangozov.)
This function must never return NULL; failures are indicated by returning
a dictentry* for which the me_value field is NULL. Exceptions are never
reported by this function, and outstanding exceptions are maintained.
*/
static dictentry *
lookdict(dictobject *mp, PyObject *key, register long hash)
{
register int i;
register unsigned incr;
register dictentry *freeslot;
register unsigned int mask = mp->ma_size-1;
dictentry *ep0 = mp->ma_table;
register dictentry *ep;
register int restore_error = 0;
register int checked_error = 0;
register int cmp;
PyObject *err_type, *err_value, *err_tb;
/* We must come up with (i, incr) such that 0 <= i < ma_size
and 0 < incr < ma_size and both are a function of hash.
i is the initial table index and incr the initial probe offset. */
i = (~hash) & mask;
/* We use ~hash instead of hash, as degenerate hash functions, such
as for ints <sigh>, can have lots of leading zeros. It's not
really a performance risk, but better safe than sorry.
12-Dec-00 tim: so ~hash produces lots of leading ones instead --
what's the gain? */
ep = &ep0[i];
if (ep->me_key == NULL || ep->me_key == key)
return ep;
if (ep->me_key == dummy)
freeslot = ep;
else {
if (ep->me_hash == hash) {
/* error can't have been checked yet */
checked_error = 1;
if (PyErr_Occurred()) {
restore_error = 1;
PyErr_Fetch(&err_type, &err_value, &err_tb);
}
cmp = PyObject_RichCompareBool(ep->me_key, key, Py_EQ);
if (cmp > 0) {
if (restore_error)
PyErr_Restore(err_type, err_value,
err_tb);
return ep;
}
else if (cmp < 0)
PyErr_Clear();
}
freeslot = NULL;
}
/* Derive incr from hash, just to make it more arbitrary. Note that
incr must not be 0, or we will get into an infinite loop.*/
incr = (hash ^ ((unsigned long)hash >> 3)) & mask;
if (!incr)
incr = mask;
for (;;) {
ep = &ep0[(i+incr)&mask];
if (ep->me_key == NULL) {
if (restore_error)
PyErr_Restore(err_type, err_value, err_tb);
if (freeslot != NULL)
return freeslot;
else
return ep;
}
if (ep->me_key == dummy) {
if (freeslot == NULL)
freeslot = ep;
}
else if (ep->me_key == key) {
if (restore_error)
PyErr_Restore(err_type, err_value, err_tb);
return ep;
}
else if (ep->me_hash == hash) {
if (!checked_error) {
checked_error = 1;
if (PyErr_Occurred()) {
restore_error = 1;
PyErr_Fetch(&err_type, &err_value,
&err_tb);
}
}
cmp = PyObject_RichCompareBool(ep->me_key, key, Py_EQ);
if (cmp > 0) {
if (restore_error)
PyErr_Restore(err_type, err_value,
err_tb);
return ep;
}
else if (cmp < 0)
PyErr_Clear();
}
/* Cycle through GF(2^n)-{0} */
incr = incr << 1;
if (incr > mask)
incr ^= mp->ma_poly; /* This will implicitly clear
the highest bit */
}
}
/*
* Hacked up version of lookdict which can assume keys are always strings;
* this assumption allows testing for errors during PyObject_Compare() to
* be dropped; string-string comparisons never raise exceptions. This also
* means we don't need to go through PyObject_Compare(); we can always use
* the tp_compare slot of the string type object directly.
*
* This really only becomes meaningful if proper error handling in lookdict()
* is too expensive.
*/
static dictentry *
lookdict_string(dictobject *mp, PyObject *key, register long hash)
{
register int i;
register unsigned incr;
register dictentry *freeslot;
register unsigned int mask = mp->ma_size-1;
dictentry *ep0 = mp->ma_table;
register dictentry *ep;
cmpfunc compare = PyString_Type.tp_compare;
/* make sure this function doesn't have to handle non-string keys */
if (!PyString_Check(key)) {
#ifdef SHOW_CONVERSION_COUNTS
++converted;
#endif
mp->ma_lookup = lookdict;
return lookdict(mp, key, hash);
}
/* We must come up with (i, incr) such that 0 <= i < ma_size
and 0 < incr < ma_size and both are a function of hash */
i = (~hash) & mask;
/* We use ~hash instead of hash, as degenerate hash functions, such
as for ints <sigh>, can have lots of leading zeros. It's not
really a performance risk, but better safe than sorry. */
ep = &ep0[i];
if (ep->me_key == NULL || ep->me_key == key)
return ep;
if (ep->me_key == dummy)
freeslot = ep;
else {
if (ep->me_hash == hash
&& compare(ep->me_key, key) == 0) {
return ep;
}
freeslot = NULL;
}
/* Derive incr from hash, just to make it more arbitrary. Note that
incr must not be 0, or we will get into an infinite loop.*/
incr = (hash ^ ((unsigned long)hash >> 3)) & mask;
if (!incr)
incr = mask;
for (;;) {
ep = &ep0[(i+incr)&mask];
if (ep->me_key == NULL) {
if (freeslot != NULL)
return freeslot;
else
return ep;
}
if (ep->me_key == dummy) {
if (freeslot == NULL)
freeslot = ep;
}
else if (ep->me_key == key
|| (ep->me_hash == hash
&& compare(ep->me_key, key) == 0)) {
return ep;
}
/* Cycle through GF(2^n)-{0} */
incr = incr << 1;
if (incr > mask)
incr ^= mp->ma_poly; /* This will implicitly clear
the highest bit */
}
}
/*
Internal routine to insert a new item into the table.
Used both by the internal resize routine and by the public insert routine.
Eats a reference to key and one to value.
*/
static void
insertdict(register dictobject *mp, PyObject *key, long hash, PyObject *value)
{
PyObject *old_value;
register dictentry *ep;
ep = (mp->ma_lookup)(mp, key, hash);
if (ep->me_value != NULL) {
old_value = ep->me_value;
ep->me_value = value;
Py_DECREF(old_value); /* which **CAN** re-enter */
Py_DECREF(key);
}
else {
if (ep->me_key == NULL)
mp->ma_fill++;
else
Py_DECREF(ep->me_key);
ep->me_key = key;
ep->me_hash = hash;
ep->me_value = value;
mp->ma_used++;
}
}
/*
Restructure the table by allocating a new table and reinserting all
items again. When entries have been deleted, the new table may
actually be smaller than the old one.
*/
static int
dictresize(dictobject *mp, int minused)
{
register int oldsize = mp->ma_size;
register int newsize, newpoly;
register dictentry *oldtable = mp->ma_table;
register dictentry *newtable;
register dictentry *ep;
register int i;
for (i = 0, newsize = MINSIZE; ; i++, newsize <<= 1) {
if (i > sizeof(polys)/sizeof(polys[0])) {
/* Ran out of polynomials */
PyErr_NoMemory();
return -1;
}
if (newsize > minused) {
newpoly = polys[i];
break;
}
}
newtable = PyMem_NEW(dictentry, newsize);
if (newtable == NULL) {
PyErr_NoMemory();
return -1;
}
memset(newtable, '\0', sizeof(dictentry) * newsize);
mp->ma_size = newsize;
mp->ma_poly = newpoly;
mp->ma_table = newtable;
mp->ma_fill = 0;
mp->ma_used = 0;
/* Make two passes, so we can avoid decrefs
(and possible side effects) till the table is copied */
for (i = 0, ep = oldtable; i < oldsize; i++, ep++) {
if (ep->me_value != NULL)
insertdict(mp,ep->me_key,ep->me_hash,ep->me_value);
}
for (i = 0, ep = oldtable; i < oldsize; i++, ep++) {
if (ep->me_value == NULL) {
Py_XDECREF(ep->me_key);
}
}
if (oldtable != NULL)
PyMem_DEL(oldtable);
return 0;
}
PyObject *
PyDict_GetItem(PyObject *op, PyObject *key)
{
long hash;
dictobject *mp = (dictobject *)op;
if (!PyDict_Check(op)) {
return NULL;
}
if (mp->ma_table == NULL)
return NULL;
#ifdef CACHE_HASH
if (!PyString_Check(key) ||
(hash = ((PyStringObject *) key)->ob_shash) == -1)
#endif
{
hash = PyObject_Hash(key);
if (hash == -1) {
PyErr_Clear();
return NULL;
}
}
return (mp->ma_lookup)(mp, key, hash)->me_value;
}
int
PyDict_SetItem(register PyObject *op, PyObject *key, PyObject *value)
{
register dictobject *mp;
register long hash;
if (!PyDict_Check(op)) {
PyErr_BadInternalCall();
return -1;
}
mp = (dictobject *)op;
#ifdef CACHE_HASH
if (PyString_Check(key)) {
#ifdef INTERN_STRINGS
if (((PyStringObject *)key)->ob_sinterned != NULL) {
key = ((PyStringObject *)key)->ob_sinterned;
hash = ((PyStringObject *)key)->ob_shash;
}
else
#endif
{
hash = ((PyStringObject *)key)->ob_shash;
if (hash == -1)
hash = PyObject_Hash(key);
}
}
else
#endif
{
hash = PyObject_Hash(key);
if (hash == -1)
return -1;
}
/* if fill >= 2/3 size, double in size */
if (mp->ma_fill*3 >= mp->ma_size*2) {
if (dictresize(mp, mp->ma_used*2) != 0) {
if (mp->ma_fill+1 > mp->ma_size)
return -1;
}
}
Py_INCREF(value);
Py_INCREF(key);
insertdict(mp, key, hash, value);
return 0;
}
int
PyDict_DelItem(PyObject *op, PyObject *key)
{
register dictobject *mp;
register long hash;
register dictentry *ep;
PyObject *old_value, *old_key;
if (!PyDict_Check(op)) {
PyErr_BadInternalCall();
return -1;
}
#ifdef CACHE_HASH
if (!PyString_Check(key) ||
(hash = ((PyStringObject *) key)->ob_shash) == -1)
#endif
{
hash = PyObject_Hash(key);
if (hash == -1)
return -1;
}
mp = (dictobject *)op;
if (((dictobject *)op)->ma_table == NULL)
goto empty;
ep = (mp->ma_lookup)(mp, key, hash);
if (ep->me_value == NULL) {
empty:
PyErr_SetObject(PyExc_KeyError, key);
return -1;
}
old_key = ep->me_key;
Py_INCREF(dummy);
ep->me_key = dummy;
old_value = ep->me_value;
ep->me_value = NULL;
mp->ma_used--;
Py_DECREF(old_value);
Py_DECREF(old_key);
return 0;
}
void
PyDict_Clear(PyObject *op)
{
int i, n;
register dictentry *table;
dictobject *mp;
if (!PyDict_Check(op))
return;
mp = (dictobject *)op;
table = mp->ma_table;
if (table == NULL)
return;
n = mp->ma_size;
mp->ma_size = mp->ma_used = mp->ma_fill = 0;
mp->ma_table = NULL;
for (i = 0; i < n; i++) {
Py_XDECREF(table[i].me_key);
Py_XDECREF(table[i].me_value);
}
PyMem_DEL(table);
}
int
PyDict_Next(PyObject *op, int *ppos, PyObject **pkey, PyObject **pvalue)
{
int i;
register dictobject *mp;
if (!PyDict_Check(op))
return 0;
mp = (dictobject *)op;
i = *ppos;
if (i < 0)
return 0;
while (i < mp->ma_size && mp->ma_table[i].me_value == NULL)
i++;
*ppos = i+1;
if (i >= mp->ma_size)
return 0;
if (pkey)
*pkey = mp->ma_table[i].me_key;
if (pvalue)
*pvalue = mp->ma_table[i].me_value;
return 1;
}
/* Methods */
static void
dict_dealloc(register dictobject *mp)
{
register int i;
register dictentry *ep;
Py_TRASHCAN_SAFE_BEGIN(mp)
PyObject_GC_Fini(mp);
for (i = 0, ep = mp->ma_table; i < mp->ma_size; i++, ep++) {
if (ep->me_key != NULL) {
Py_DECREF(ep->me_key);
}
if (ep->me_value != NULL) {
Py_DECREF(ep->me_value);
}
}
if (mp->ma_table != NULL)
PyMem_DEL(mp->ma_table);
mp = (dictobject *) PyObject_AS_GC(mp);
PyObject_DEL(mp);
Py_TRASHCAN_SAFE_END(mp)
}
static int
dict_print(register dictobject *mp, register FILE *fp, register int flags)
{
register int i;
register int any;
register dictentry *ep;
i = Py_ReprEnter((PyObject*)mp);
if (i != 0) {
if (i < 0)
return i;
fprintf(fp, "{...}");
return 0;
}
fprintf(fp, "{");
any = 0;
for (i = 0, ep = mp->ma_table; i < mp->ma_size; i++, ep++) {
if (ep->me_value != NULL) {
if (any++ > 0)
fprintf(fp, ", ");
if (PyObject_Print((PyObject *)ep->me_key, fp, 0)!=0) {
Py_ReprLeave((PyObject*)mp);
return -1;
}
fprintf(fp, ": ");
if (PyObject_Print(ep->me_value, fp, 0) != 0) {
Py_ReprLeave((PyObject*)mp);
return -1;
}
}
}
fprintf(fp, "}");
Py_ReprLeave((PyObject*)mp);
return 0;
}
static PyObject *
dict_repr(dictobject *mp)
{
auto PyObject *v;
PyObject *sepa, *colon;
register int i;
register int any;
register dictentry *ep;
i = Py_ReprEnter((PyObject*)mp);
if (i != 0) {
if (i > 0)
return PyString_FromString("{...}");
return NULL;
}
v = PyString_FromString("{");
sepa = PyString_FromString(", ");
colon = PyString_FromString(": ");
any = 0;
for (i = 0, ep = mp->ma_table; i < mp->ma_size && v; i++, ep++) {
if (ep->me_value != NULL) {
if (any++)
PyString_Concat(&v, sepa);
PyString_ConcatAndDel(&v, PyObject_Repr(ep->me_key));
PyString_Concat(&v, colon);
PyString_ConcatAndDel(&v, PyObject_Repr(ep->me_value));
}
}
PyString_ConcatAndDel(&v, PyString_FromString("}"));
Py_ReprLeave((PyObject*)mp);
Py_XDECREF(sepa);
Py_XDECREF(colon);
return v;
}
static int
dict_length(dictobject *mp)
{
return mp->ma_used;
}
static PyObject *
dict_subscript(dictobject *mp, register PyObject *key)
{
PyObject *v;
long hash;
if (mp->ma_table == NULL) {
PyErr_SetObject(PyExc_KeyError, key);
return NULL;
}
#ifdef CACHE_HASH
if (!PyString_Check(key) ||
(hash = ((PyStringObject *) key)->ob_shash) == -1)
#endif
{
hash = PyObject_Hash(key);
if (hash == -1)
return NULL;
}
v = (mp->ma_lookup)(mp, key, hash) -> me_value;
if (v == NULL)
PyErr_SetObject(PyExc_KeyError, key);
else
Py_INCREF(v);
return v;
}
static int
dict_ass_sub(dictobject *mp, PyObject *v, PyObject *w)
{
if (w == NULL)
return PyDict_DelItem((PyObject *)mp, v);
else
return PyDict_SetItem((PyObject *)mp, v, w);
}
static PyMappingMethods dict_as_mapping = {
(inquiry)dict_length, /*mp_length*/
(binaryfunc)dict_subscript, /*mp_subscript*/
(objobjargproc)dict_ass_sub, /*mp_ass_subscript*/
};
static PyObject *
dict_keys(register dictobject *mp, PyObject *args)
{
register PyObject *v;
register int i, j;
if (!PyArg_NoArgs(args))
return NULL;
v = PyList_New(mp->ma_used);
if (v == NULL)
return NULL;
for (i = 0, j = 0; i < mp->ma_size; i++) {
if (mp->ma_table[i].me_value != NULL) {
PyObject *key = mp->ma_table[i].me_key;
Py_INCREF(key);
PyList_SetItem(v, j, key);
j++;
}
}
return v;
}
static PyObject *
dict_values(register dictobject *mp, PyObject *args)
{
register PyObject *v;
register int i, j;
if (!PyArg_NoArgs(args))
return NULL;
v = PyList_New(mp->ma_used);
if (v == NULL)
return NULL;
for (i = 0, j = 0; i < mp->ma_size; i++) {
if (mp->ma_table[i].me_value != NULL) {
PyObject *value = mp->ma_table[i].me_value;
Py_INCREF(value);
PyList_SetItem(v, j, value);
j++;
}
}
return v;
}
static PyObject *
dict_items(register dictobject *mp, PyObject *args)
{
register PyObject *v;
register int i, j;
if (!PyArg_NoArgs(args))
return NULL;
v = PyList_New(mp->ma_used);
if (v == NULL)
return NULL;
for (i = 0, j = 0; i < mp->ma_size; i++) {
if (mp->ma_table[i].me_value != NULL) {
PyObject *key = mp->ma_table[i].me_key;
PyObject *value = mp->ma_table[i].me_value;
PyObject *item = PyTuple_New(2);
if (item == NULL) {
Py_DECREF(v);
return NULL;
}
Py_INCREF(key);
PyTuple_SetItem(item, 0, key);
Py_INCREF(value);
PyTuple_SetItem(item, 1, value);
PyList_SetItem(v, j, item);
j++;
}
}
return v;
}
static PyObject *
dict_update(register dictobject *mp, PyObject *args)
{
register int i;
dictobject *other;
dictentry *entry;
if (!PyArg_Parse(args, "O!", &PyDict_Type, &other))
return NULL;
if (other == mp || other->ma_used == 0)
goto done; /* a.update(a) or a.update({}); nothing to do */
/* Do one big resize at the start, rather than incrementally
resizing as we insert new items. Expect that there will be
no (or few) overlapping keys. */
if ((mp->ma_fill + other->ma_used)*3 >= mp->ma_size*2) {
if (dictresize(mp, (mp->ma_used + other->ma_used)*3/2) != 0)
return NULL;
}
for (i = 0; i < other->ma_size; i++) {
entry = &other->ma_table[i];
if (entry->me_value != NULL) {
Py_INCREF(entry->me_key);
Py_INCREF(entry->me_value);
insertdict(mp, entry->me_key, entry->me_hash,
entry->me_value);
}
}
done:
Py_INCREF(Py_None);
return Py_None;
}
static PyObject *
dict_copy(register dictobject *mp, PyObject *args)
{
if (!PyArg_Parse(args, ""))
return NULL;
return PyDict_Copy((PyObject*)mp);
}
PyObject *
PyDict_Copy(PyObject *o)
{
register dictobject *mp;
register int i;
dictobject *copy;
dictentry *entry;
if (o == NULL || !PyDict_Check(o)) {
PyErr_BadInternalCall();
return NULL;
}
mp = (dictobject *)o;
copy = (dictobject *)PyDict_New();
if (copy == NULL)
return NULL;
if (mp->ma_used > 0) {
if (dictresize(copy, mp->ma_used*3/2) != 0)
return NULL;
for (i = 0; i < mp->ma_size; i++) {
entry = &mp->ma_table[i];
if (entry->me_value != NULL) {
Py_INCREF(entry->me_key);
Py_INCREF(entry->me_value);
insertdict(copy, entry->me_key, entry->me_hash,
entry->me_value);
}
}
}
return (PyObject *)copy;
}
int
PyDict_Size(PyObject *mp)
{
if (mp == NULL || !PyDict_Check(mp)) {
PyErr_BadInternalCall();
return 0;
}
return ((dictobject *)mp)->ma_used;
}
PyObject *
PyDict_Keys(PyObject *mp)
{
if (mp == NULL || !PyDict_Check(mp)) {
PyErr_BadInternalCall();
return NULL;
}
return dict_keys((dictobject *)mp, (PyObject *)NULL);
}
PyObject *
PyDict_Values(PyObject *mp)
{
if (mp == NULL || !PyDict_Check(mp)) {
PyErr_BadInternalCall();
return NULL;
}
return dict_values((dictobject *)mp, (PyObject *)NULL);
}
PyObject *
PyDict_Items(PyObject *mp)
{
if (mp == NULL || !PyDict_Check(mp)) {
PyErr_BadInternalCall();
return NULL;
}
return dict_items((dictobject *)mp, (PyObject *)NULL);
}
/* Subroutine which returns the smallest key in a for which b's value
is different or absent. The value is returned too, through the
pval argument. No reference counts are incremented. */
static PyObject *
characterize(dictobject *a, dictobject *b, PyObject **pval)
{
PyObject *diff = NULL;
int i, cmp;
*pval = NULL;
for (i = 0; i < a->ma_size; i++) {
if (a->ma_table[i].me_value != NULL) {
PyObject *key = a->ma_table[i].me_key;
PyObject *aval, *bval;
if (diff != NULL) {
cmp = PyObject_RichCompareBool(diff, key, Py_LT);
if (cmp < 0)
return NULL;
if (cmp > 0)
continue;
}
aval = a->ma_table[i].me_value;
bval = PyDict_GetItem((PyObject *)b, key);
if (bval == NULL)
cmp = 0;
else {
cmp = PyObject_RichCompareBool(aval, bval, Py_EQ);
if (cmp < 0)
return NULL;
}
if (cmp == 0)
{
diff = key;
*pval = aval;
}
}
}
return diff;
}
static int
dict_compare(dictobject *a, dictobject *b)
{
PyObject *adiff, *bdiff, *aval, *bval;
int res;
/* Compare lengths first */
if (a->ma_used < b->ma_used)
return -1; /* a is shorter */
else if (a->ma_used > b->ma_used)
return 1; /* b is shorter */
/* Same length -- check all keys */
adiff = characterize(a, b, &aval);
if (adiff == NULL && PyErr_Occurred())
return -1;
if (adiff == NULL)
return 0; /* a is a subset with the same length */
bdiff = characterize(b, a, &bval);
if (bdiff == NULL && PyErr_Occurred())
return -1;
/* bdiff == NULL would be impossible now */
res = PyObject_Compare(adiff, bdiff);
if (res == 0)
res = PyObject_Compare(aval, bval);
return res;
}
static PyObject *
dict_has_key(register dictobject *mp, PyObject *args)
{
PyObject *key;
long hash;
register long ok;
if (!PyArg_ParseTuple(args, "O:has_key", &key))
return NULL;
#ifdef CACHE_HASH
if (!PyString_Check(key) ||
(hash = ((PyStringObject *) key)->ob_shash) == -1)
#endif
{
hash = PyObject_Hash(key);
if (hash == -1)
return NULL;
}
ok = (mp->ma_size != 0