while (sz < padded_sz)
((char *) out)[sz++] = 0;
SET_VARSIZE(out, padded_sz);
- memcpy((void *) VARDATA(out), (void *) VARBITS(leaf), VARBITBYTES(leaf));
+ memcpy(VARDATA(out), VARBITS(leaf), VARBITBYTES(leaf));
return out;
}
{
Interval *key = DatumGetIntervalP(entry->key);
- memcpy((void *) r, (void *) key, INTERVALSIZE);
- memcpy((void *) (r + INTERVALSIZE), (void *) key, INTERVALSIZE);
+ memcpy(r, key, INTERVALSIZE);
+ memcpy(r + INTERVALSIZE, key, INTERVALSIZE);
}
else
{
Assert(tinfo->indexsize >= 2 * tinfo->size);
- memcpy((void *) &r[0], leaf, tinfo->size);
- memcpy((void *) &r[tinfo->size], leaf, tinfo->size);
+ memcpy(&r[0], leaf, tinfo->size);
+ memcpy(&r[tinfo->size], leaf, tinfo->size);
retval = palloc(sizeof(GISTENTRY));
gistentryinit(*retval, PointerGetDatum(r), entry->rel, entry->page,
entry->offset, false);
o.lower = &((GBT_NUMKEY *) out)[0];
o.upper = &((GBT_NUMKEY *) out)[tinfo->size];
- memcpy((void *) out, (void *) cur, 2 * tinfo->size);
+ memcpy(out, cur, 2 * tinfo->size);
for (i = 1; i < numranges; i++)
{
arr[i].t = (GBT_NUMKEY *) DatumGetPointer((entryvec->vector[i].key));
arr[i].i = i;
}
- qsort_arg((void *) &arr[FirstOffsetNumber], maxoff - FirstOffsetNumber + 1, sizeof(Nsrt), (qsort_arg_comparator) tinfo->f_cmp, (void *) flinfo);
+ qsort_arg(&arr[FirstOffsetNumber], maxoff - FirstOffsetNumber + 1, sizeof(Nsrt), (qsort_arg_comparator) tinfo->f_cmp, flinfo);
/* We do simply create two parts */
varg.tinfo = tinfo;
varg.collation = collation;
varg.flinfo = flinfo;
- qsort_arg((void *) &arr[FirstOffsetNumber],
+ qsort_arg(&arr[FirstOffsetNumber],
maxoff - FirstOffsetNumber + 1,
sizeof(Vsrt),
gbt_vsrt_cmp,
- (void *) &varg);
+ &varg);
/* We do simply create two parts */
retval = palloc(sizeof(GISTENTRY));
- memcpy((void *) r, (void *) key, UUID_LEN);
- memcpy((void *) (r + UUID_LEN), (void *) key, UUID_LEN);
+ memcpy(r, key, UUID_LEN);
+ memcpy(r + UUID_LEN, key, UUID_LEN);
gistentryinit(*retval, PointerGetDatum(r),
entry->rel, entry->page,
entry->offset, false);
llen = strlen(lcstr);
rlen = strlen(rcstr);
- result = memcmp((void *) lcstr, (void *) rcstr, Min(llen, rlen));
+ result = memcmp(lcstr, rcstr, Min(llen, rlen));
if (result == 0)
{
if (llen < rlen)
size_beta = hemdist(datum_r, _j, siglen);
costvector[j - 1].cost = abs(size_alpha - size_beta);
}
- qsort((void *) costvector, maxoff, sizeof(SPLITCOST), comparecost);
+ qsort(costvector, maxoff, sizeof(SPLITCOST), comparecost);
union_l = GETSIGN(datum_l);
union_r = GETSIGN(datum_r);
if (ISALLTRUE(datum_l) || ISALLTRUE(_j))
{
if (!ISALLTRUE(datum_l))
- memset((void *) union_l, 0xff, siglen);
+ memset(union_l, 0xff, siglen);
}
else
{
if (ISALLTRUE(datum_r) || ISALLTRUE(_j))
{
if (!ISALLTRUE(datum_r))
- memset((void *) union_r, 0xff, siglen);
+ memset(union_r, 0xff, siglen);
}
else
{
return l;
}
- qsort((void *) a, l, sizeof(Pairs), comparePairs);
+ qsort(a, l, sizeof(Pairs), comparePairs);
/*
* We can't use qunique here because we have some clean-up code to run on
/*
* shunt everything down to start at the right place
*/
- memmove((void *) &dr[0], (void *) &dr[2 * j], 2 * (len - j) * sizeof(int32));
+ memmove(&dr[0], &dr[2 * j], 2 * (len - j) * sizeof(int32));
}
/*
min = ((int64) dr[i] - (int64) dr[i - 1]);
cand = i;
}
- memmove((void *) &dr[cand - 1], (void *) &dr[cand + 1], (len - cand - 1) * sizeof(int32));
+ memmove(&dr[cand - 1], &dr[cand + 1], (len - cand - 1) * sizeof(int32));
len -= 2;
}
pfree(union_d);
costvector[i - 1].cost = fabsf((size_alpha - size_l) - (size_beta - size_r));
}
- qsort((void *) costvector, maxoff, sizeof(SPLITCOST), comparecost);
+ qsort(costvector, maxoff, sizeof(SPLITCOST), comparecost);
/*
* Now split up the regions between the two seeds. An important property
{
bool r = false;
- qsort_arg(a, len, sizeof(int32), isort_cmp, (void *) &r);
+ qsort_arg(a, len, sizeof(int32), isort_cmp, &r);
return r;
}
size_beta = hemdist(datum_r, _j, siglen);
costvector[j - 1].cost = abs(size_alpha - size_beta);
}
- qsort((void *) costvector, maxoff, sizeof(SPLITCOST), comparecost);
+ qsort(costvector, maxoff, sizeof(SPLITCOST), comparecost);
union_l = GETSIGN(datum_l);
union_r = GETSIGN(datum_r);
if (ISALLTRUE(datum_l) || ISALLTRUE(_j))
{
if (!ISALLTRUE(datum_l))
- memset((void *) union_l, 0xff, siglen);
+ memset(union_l, 0xff, siglen);
}
else
{
if (ISALLTRUE(datum_r) || ISALLTRUE(_j))
{
if (!ISALLTRUE(datum_r))
- memset((void *) union_r, 0xff, siglen);
+ memset(union_r, 0xff, siglen);
}
else
{
size_beta = hemdist(datum_r, _j, siglen);
costvector[j - 1].cost = abs(size_alpha - size_beta);
}
- qsort((void *) costvector, maxoff, sizeof(SPLITCOST), comparecost);
+ qsort(costvector, maxoff, sizeof(SPLITCOST), comparecost);
union_l = LTG_SIGN(datum_l);
union_r = LTG_SIGN(datum_r);
if (LTG_ISALLTRUE(datum_l) || LTG_ISALLTRUE(_j))
{
if (!LTG_ISALLTRUE(datum_l))
- memset((void *) union_l, 0xff, siglen);
+ memset(union_l, 0xff, siglen);
}
else
{
if (LTG_ISALLTRUE(datum_r) || LTG_ISALLTRUE(_j))
{
if (!LTG_ISALLTRUE(datum_r))
- memset((void *) union_r, 0xff, siglen);
+ memset(union_r, 0xff, siglen);
}
else
{
array[j].r = LTG_GETLNODE(lu, siglen);
}
- qsort((void *) &array[FirstOffsetNumber], maxoff - FirstOffsetNumber + 1,
+ qsort(&array[FirstOffsetNumber], maxoff - FirstOffsetNumber + 1,
sizeof(RIX), treekey_cmp);
lu_l = lu_r = ru_l = ru_r = NULL;
int32 tmp = state->curop - state->op;
state->lenop *= 2;
- state->op = (char *) repalloc((void *) state->op, state->lenop);
+ state->op = (char *) repalloc(state->op, state->lenop);
state->curop = state->op + tmp;
}
- memcpy((void *) state->curop, (void *) strval, lenval);
+ memcpy(state->curop, strval, lenval);
state->curop += lenval;
*(state->curop) = '\0';
state->curop++;
}
/* set user-friendly operand view */
- memcpy((void *) GETOPERAND(query), (void *) state.op, state.sumlen);
+ memcpy(GETOPERAND(query), state.op, state.sumlen);
pfree(state.op);
/* set left operand's position for every operator */
* array.
*/
if (ntids > 1)
- qsort((void *) tids, ntids, sizeof(ItemPointerData), tidcmp);
+ qsort(tids, ntids, sizeof(ItemPointerData), tidcmp);
curr_start_ptr = next_start_ptr = 0;
nblocks = RelationGetNumberOfBlocks(rel);
trgm *ptr = GETARR(a);
int32 tmp = 0;
- MemSet((void *) sign, 0, siglen);
+ MemSet(sign, 0, siglen);
SETBIT(sign, SIGLENBIT(siglen)); /* set last unused bit */
for (k = 0; k < len; k++)
{
else if (ISALLTRUE(key))
item->allistrue = true;
else
- memcpy((void *) item->sign, (void *) GETSIGN(key), siglen);
+ memcpy(item->sign, GETSIGN(key), siglen);
}
#define WISH_F(a,b,c) (double)( -(double)(((a)-(b))*((a)-(b))*((a)-(b)))*(c) )
size_beta = hemdistcache(&(cache[seed_2]), &(cache[j]), siglen);
costvector[j - 1].cost = abs(size_alpha - size_beta);
}
- qsort((void *) costvector, maxoff, sizeof(SPLITCOST), comparecost);
+ qsort(costvector, maxoff, sizeof(SPLITCOST), comparecost);
for (k = 0; k < maxoff; k++)
{
if (ISALLTRUE(datum_l) || cache[j].allistrue)
{
if (!ISALLTRUE(datum_l))
- memset((void *) GETSIGN(datum_l), 0xff, siglen);
+ memset(GETSIGN(datum_l), 0xff, siglen);
}
else
{
if (ISALLTRUE(datum_r) || cache[j].allistrue)
{
if (!ISALLTRUE(datum_r))
- memset((void *) GETSIGN(datum_r), 0xff, siglen);
+ memset(GETSIGN(datum_r), 0xff, siglen);
}
else
{
*/
if (len > 1)
{
- qsort((void *) GETARR(trg), len, sizeof(trgm), comp_trgm);
+ qsort(GETARR(trg), len, sizeof(trgm), comp_trgm);
len = qunique(GETARR(trg), len, sizeof(trgm), comp_trgm);
}
*/
if (len > 1)
{
- qsort((void *) GETARR(trg), len, sizeof(trgm), comp_trgm);
+ qsort(GETARR(trg), len, sizeof(trgm), comp_trgm);
len = qunique(GETARR(trg), len, sizeof(trgm), comp_trgm);
}
* VARDATA is a pointer to the data region of the new struct. The source
* could be a short datum, so retrieve its data through VARDATA_ANY.
*/
- memcpy((void *) VARDATA(new_t), /* destination */
- (void *) VARDATA_ANY(t), /* source */
+ memcpy(VARDATA(new_t), /* destination */
+ VARDATA_ANY(t), /* source */
VARSIZE_ANY_EXHDR(t)); /* how many bytes */
PG_RETURN_TEXT_P(new_t);
}
*/
qsort_arg(&range->values[start],
range->nvalues, sizeof(Datum),
- compare_values, (void *) &cxt);
+ compare_values, &cxt);
n = 1;
for (i = 1; i < range->nvalues; i++)
* some of the points) and do merge sort.
*/
qsort_arg(eranges, neranges, sizeof(ExpandedRange),
- compare_expanded_ranges, (void *) &cxt);
+ compare_expanded_ranges, &cxt);
/*
* Deduplicate the ranges - simply compare each range to the preceding
* sorted result.
*/
qsort_arg(values, nvalues, sizeof(Datum),
- compare_values, (void *) &cxt);
+ compare_values, &cxt);
/* We have nvalues boundary values, which means nvalues/2 ranges. */
for (i = 0; i < (nvalues / 2); i++)
arg.collation = ginstate->supportCollation[attnum - 1];
arg.haveDups = false;
qsort_arg(keydata, *nentries, sizeof(keyEntryData),
- cmpEntries, (void *) &arg);
+ cmpEntries, &arg);
if (arg.haveDups)
{
numranges = entryvec->n;
pageunion = (BOX *) palloc(sizeof(BOX));
cur = DatumGetBoxP(entryvec->vector[0].key);
- memcpy((void *) pageunion, (void *) cur, sizeof(BOX));
+ memcpy(pageunion, cur, sizeof(BOX));
for (i = 1; i < numranges; i++)
{
BOX *r;
r = (BOX *) palloc(sizeof(BOX));
- memcpy((void *) r, (void *) &(in->boundbox), sizeof(BOX));
+ memcpy(r, &(in->boundbox), sizeof(BOX));
retval = (GISTENTRY *) palloc(sizeof(GISTENTRY));
gistentryinit(*retval, PointerGetDatum(r),
IndexTuple *
gistjoinvector(IndexTuple *itvec, int *len, IndexTuple *additvec, int addlen)
{
- itvec = (IndexTuple *) repalloc((void *) itvec, sizeof(IndexTuple) * ((*len) + addlen));
+ itvec = (IndexTuple *) repalloc(itvec, sizeof(IndexTuple) * ((*len) + addlen));
memmove(&itvec[*len], additvec, sizeof(IndexTuple) * addlen);
*len += addlen;
return itvec;
fmgr_info(cmp_proc, &cxt.flinfo);
cxt.collation = skey->sk_collation;
cxt.reverse = reverse;
- qsort_arg((void *) elems, nelems, sizeof(Datum),
- _bt_compare_array_elements, (void *) &cxt);
+ qsort_arg(elems, nelems, sizeof(Datum),
+ _bt_compare_array_elements, &cxt);
/* Now scan the sorted elements and remove duplicates */
return qunique_arg(elems, nelems, sizeof(Datum),
* first within ObjectAddressAndFlags.
*/
if (numDependentObjects > 1)
- qsort((void *) dependentObjects, numDependentObjects,
+ qsort(dependentObjects, numDependentObjects,
sizeof(ObjectAddressAndFlags),
object_address_comparator);
return; /* nothing to do */
/* Sort the refs so that duplicates are adjacent */
- qsort((void *) addrs->refs, addrs->numrefs, sizeof(ObjectAddress),
+ qsort(addrs->refs, addrs->numrefs, sizeof(ObjectAddress),
object_address_comparator);
/* Remove dups */
sort_object_addresses(ObjectAddresses *addrs)
{
if (addrs->numrefs > 1)
- qsort((void *) addrs->refs, addrs->numrefs,
+ qsort(addrs->refs, addrs->numrefs,
sizeof(ObjectAddress),
object_address_comparator);
}
* Sort and report local and shared objects.
*/
if (numobjects > 1)
- qsort((void *) objects, numobjects,
+ qsort(objects, numobjects,
sizeof(ShDependObjectInfo), shared_dependency_comparator);
for (int i = 0; i < numobjects; i++)
* tuples are already sorted.
*/
if (numrows == targrows)
- qsort_interruptible((void *) rows, numrows, sizeof(HeapTuple),
+ qsort_interruptible(rows, numrows, sizeof(HeapTuple),
compare_rows, NULL);
/*
/* Sort the collected values */
cxt.ssup = &ssup;
cxt.tupnoLink = tupnoLink;
- qsort_interruptible((void *) values, values_cnt, sizeof(ScalarItem),
- compare_scalars, (void *) &cxt);
+ qsort_interruptible(values, values_cnt, sizeof(ScalarItem),
+ compare_scalars, &cxt);
/*
* Now scan the values in order, find the most common ones, and also
deltafrac;
/* Sort the MCV items into position order to speed next loop */
- qsort_interruptible((void *) track, num_mcv, sizeof(ScalarMCVItem),
+ qsort_interruptible(track, num_mcv, sizeof(ScalarMCVItem),
compare_mcvs, NULL);
/*
* created such a pg_collation entry above, and that one will win.)
*/
if (naliases > 1)
- qsort((void *) aliases, naliases, sizeof(CollAliasData), cmpaliases);
+ qsort(aliases, naliases, sizeof(CollAliasData), cmpaliases);
/* Now add aliases, ignoring any that match pre-existing entries */
for (i = 0; i < naliases; i++)
if (item < litem || item > ritem)
return false;
- res = (ItemPointer) bsearch((void *) itemptr,
- (void *) dead_items->items,
+ res = (ItemPointer) bsearch(itemptr,
+ dead_items->items,
dead_items->num_items,
sizeof(ItemPointerData),
vac_cmp_itemptr);
/* CurrentOfExpr could never appear OR'd with something else */
Assert(!tidstate->tss_isCurrentOf);
- qsort((void *) tidList, numTids, sizeof(ItemPointerData),
+ qsort(tidList, numTids, sizeof(ItemPointerData),
itemptr_comparator);
numTids = qunique(tidList, numTids, sizeof(ItemPointerData),
itemptr_comparator);
if (ptbase != NULL)
pg_atomic_init_u32(&ptbase->refcount, 0);
if (npages > 1)
- qsort_arg((void *) (ptpages->index), npages, sizeof(int),
- tbm_shared_comparator, (void *) ptbase->ptentry);
+ qsort_arg(ptpages->index, npages, sizeof(int),
+ tbm_shared_comparator, ptbase->ptentry);
if (nchunks > 1)
- qsort_arg((void *) (ptchunks->index), nchunks, sizeof(int),
- tbm_shared_comparator, (void *) ptbase->ptentry);
+ qsort_arg(ptchunks->index, nchunks, sizeof(int),
+ tbm_shared_comparator, ptbase->ptentry);
}
/*
Assert(j == ndatums);
qsort_arg(all_values, ndatums, sizeof(PartitionListValue),
- qsort_partition_list_value_cmp, (void *) key);
+ qsort_partition_list_value_cmp, key);
boundinfo->ndatums = ndatums;
boundinfo->datums = (Datum **) palloc0(ndatums * sizeof(Datum *));
qsort_arg(all_bounds, ndatums,
sizeof(PartitionRangeBound *),
qsort_partition_rbound_cmp,
- (void *) key);
+ key);
/* Save distinct bounds from all_bounds into rbounds. */
rbounds = (PartitionRangeBound **)
}
/* do the sort, using the multi-sort */
- qsort_interruptible((void *) items, nrows, sizeof(SortItem),
+ qsort_interruptible(items, nrows, sizeof(SortItem),
multi_sort_compare, mss);
return items;
Assert(j + 1 == ngroups);
/* Sort the distinct groups by frequency (in descending order). */
- qsort_interruptible((void *) groups, ngroups, sizeof(SortItem),
+ qsort_interruptible(groups, ngroups, sizeof(SortItem),
compare_sort_item_count, NULL);
*ndistinct = ngroups;
}
/* sort the values, deduplicate */
- qsort_interruptible((void *) result[dim], ngroups, sizeof(SortItem),
+ qsort_interruptible(result[dim], ngroups, sizeof(SortItem),
sort_item_compare, ssup);
/*
}
/* We can sort the array now ... */
- qsort_interruptible((void *) items, numrows, sizeof(SortItem),
+ qsort_interruptible(items, numrows, sizeof(SortItem),
multi_sort_compare, mss);
/* ... and count the number of distinct combinations */
pg_read_barrier(); /* pairs with GetNewTransactionId */
memcpy(snapshot->subxip + subcount,
- (void *) proc->subxids.xids,
+ proc->subxids.xids,
nsubxids * sizeof(TransactionId));
subcount += nsubxids;
}
/* barrier not really required, as XidGenLock is held, but ... */
pg_read_barrier(); /* pairs with GetNewTransactionId */
- memcpy(&xids[count], (void *) proc->subxids.xids,
+ memcpy(&xids[count], proc->subxids.xids,
nsubxids * sizeof(TransactionId));
count += nsubxids;
subcount += nsubxids;
if (Conf->maffixes)
{
Conf->maffixes *= 2;
- Conf->Affix = (AFFIX *) repalloc((void *) Conf->Affix, Conf->maffixes * sizeof(AFFIX));
+ Conf->Affix = (AFFIX *) repalloc(Conf->Affix, Conf->maffixes * sizeof(AFFIX));
}
else
{
{
Conf->mCompoundAffixFlag *= 2;
Conf->CompoundAffixFlags = (CompoundAffixFlag *)
- repalloc((void *) Conf->CompoundAffixFlags,
+ repalloc(Conf->CompoundAffixFlags,
Conf->mCompoundAffixFlag * sizeof(CompoundAffixFlag));
}
else
setCompoundAffixFlagValue(Conf, &key, sflag, 0);
found = (CompoundAffixFlag *)
- bsearch(&key, (void *) Conf->CompoundAffixFlags,
+ bsearch(&key, Conf->CompoundAffixFlags,
Conf->nCompoundAffixFlag, sizeof(CompoundAffixFlag),
cmpcmdflag);
if (found != NULL)
tsearch_readline_end(&trst);
if (Conf->nCompoundAffixFlag > 1)
- qsort((void *) Conf->CompoundAffixFlags, Conf->nCompoundAffixFlag,
+ qsort(Conf->CompoundAffixFlags, Conf->nCompoundAffixFlag,
sizeof(CompoundAffixFlag), cmpcmdflag);
if (!tsearch_readline_begin(&trst, filename))
else
{
/* Count the number of different flags used in the dictionary */
- qsort((void *) Conf->Spell, Conf->nspell, sizeof(SPELL *),
+ qsort(Conf->Spell, Conf->nspell, sizeof(SPELL *),
cmpspellaffix);
naffix = 0;
}
/* Start build a prefix tree */
- qsort((void *) Conf->Spell, Conf->nspell, sizeof(SPELL *), cmpspell);
+ qsort(Conf->Spell, Conf->nspell, sizeof(SPELL *), cmpspell);
Conf->Dictionary = mkSPNode(Conf, 0, Conf->nspell, 0);
}
/* Store compound affixes in the Conf->CompoundAffix array */
if (Conf->naffixes > 1)
- qsort((void *) Conf->Affix, Conf->naffixes, sizeof(AFFIX), cmpaffix);
+ qsort(Conf->Affix, Conf->naffixes, sizeof(AFFIX), cmpaffix);
Conf->CompoundAffix = ptr = (CMPDAffix *) palloc(sizeof(CMPDAffix) * Conf->naffixes);
ptr->affix = NULL;
/*
* Sort words with its positions
*/
- qsort((void *) a, l, sizeof(ParsedWord), compareWORD);
+ qsort(a, l, sizeof(ParsedWord), compareWORD);
/*
* Initialize first word and its first position
if (prs->curwords == prs->lenwords)
{
prs->lenwords *= 2;
- prs->words = (ParsedWord *) repalloc((void *) prs->words, prs->lenwords * sizeof(ParsedWord));
+ prs->words = (ParsedWord *) repalloc(prs->words, prs->lenwords * sizeof(ParsedWord));
}
if (ptr->flags & TSL_ADDPOS)
if (prs->curwords >= prs->lenwords)
{
prs->lenwords *= 2;
- prs->words = (HeadlineWordEntry *) repalloc((void *) prs->words, prs->lenwords * sizeof(HeadlineWordEntry));
+ prs->words = (HeadlineWordEntry *) repalloc(prs->words, prs->lenwords * sizeof(HeadlineWordEntry));
}
memset(&(prs->words[prs->curwords]), 0, sizeof(HeadlineWordEntry));
prs->words[prs->curwords].type = (uint8) type;
while (prs->curwords + query->size >= prs->lenwords)
{
prs->lenwords *= 2;
- prs->words = (HeadlineWordEntry *) repalloc((void *) prs->words, prs->lenwords * sizeof(HeadlineWordEntry));
+ prs->words = (HeadlineWordEntry *) repalloc(prs->words, prs->lenwords * sizeof(HeadlineWordEntry));
}
word = &(prs->words[prs->curwords - 1]);
else
{
reallen *= 2;
- stop = (char **) repalloc((void *) stop,
- sizeof(char *) * reallen);
+ stop = (char **) repalloc(stop, sizeof(char *) * reallen);
}
}
len = ARRNELEM(a);
int32 *ptr = GETARR(a);
- MemSet((void *) sign, 0, siglen);
+ MemSet(sign, 0, siglen);
for (k = 0; k < len; k++)
HASH(sign, ptr[k], siglen);
}
* val->size
*/
len = CALCGTSIZE(ARRKEY, len);
- res = (SignTSVector *) repalloc((void *) res, len);
+ res = (SignTSVector *) repalloc(res, len);
SET_VARSIZE(res, len);
}
else if (ISALLTRUE(key))
item->allistrue = true;
else
- memcpy((void *) item->sign, (void *) GETSIGN(key), siglen);
+ memcpy(item->sign, GETSIGN(key), siglen);
}
#define WISH_F(a,b,c) (double)( -(double)(((a)-(b))*((a)-(b))*((a)-(b)))*(c) )
size_beta = hemdistcache(&(cache[seed_2]), &(cache[j]), siglen);
costvector[j - 1].cost = abs(size_alpha - size_beta);
}
- qsort((void *) costvector, maxoff, sizeof(SPLITCOST), comparecost);
+ qsort(costvector, maxoff, sizeof(SPLITCOST), comparecost);
for (k = 0; k < maxoff; k++)
{
if (ISALLTRUE(datum_l) || cache[j].allistrue)
{
if (!ISALLTRUE(datum_l))
- memset((void *) GETSIGN(datum_l), 0xff, siglen);
+ memset(GETSIGN(datum_l), 0xff, siglen);
}
else
{
if (ISALLTRUE(datum_r) || cache[j].allistrue)
{
if (!ISALLTRUE(datum_r))
- memset((void *) GETSIGN(datum_r), 0xff, siglen);
+ memset(GETSIGN(datum_r), 0xff, siglen);
}
else
{
int used = state->curop - state->op;
state->lenop *= 2;
- state->op = (char *) repalloc((void *) state->op, state->lenop);
+ state->op = (char *) repalloc(state->op, state->lenop);
state->curop = state->op + used;
}
- memcpy((void *) state->curop, (void *) strval, lenval);
+ memcpy(state->curop, strval, lenval);
state->curop += lenval;
*(state->curop) = '\0';
state->curop++;
}
/* Copy all the operand strings to TSQuery */
- memcpy((void *) GETOPERAND(query), (void *) state.op, state.sumlen);
+ memcpy(GETOPERAND(query), state.op, state.sumlen);
pfree(state.op);
/*
if (state->cur == state->len)
{
state->len *= 2;
- state->ptr = (QueryItem *) repalloc((void *) state->ptr, state->len * sizeof(QueryItem));
+ state->ptr = (QueryItem *) repalloc(state->ptr, state->len * sizeof(QueryItem));
}
- memcpy((void *) &(state->ptr[state->cur]), (void *) node->valnode, sizeof(QueryItem));
+ memcpy(&(state->ptr[state->cur]), node->valnode, sizeof(QueryItem));
if (node->valnode->type == QI_VAL)
state->cur++;
else if (node->valnode->qoperator.oper == OP_NOT)
size_beta = hemdist(GETENTRY(entryvec, seed_2), GETENTRY(entryvec, j));
costvector[j - 1].cost = abs(size_alpha - size_beta);
}
- qsort((void *) costvector, maxoff, sizeof(SPLITCOST), comparecost);
+ qsort(costvector, maxoff, sizeof(SPLITCOST), comparecost);
for (k = 0; k < maxoff; k++)
{
for (i = 0; i < in->nchild; i++)
QTNSort(in->child[i]);
if (in->nchild > 1 && in->valnode->qoperator.oper != OP_PHRASE)
- qsort((void *) in->child, in->nchild, sizeof(QTNode *), cmpQTN);
+ qsort(in->child, in->nchild, sizeof(QTNode *), cmpQTN);
}
/*
if (*size < 2)
return res;
- qsort_arg(res, *size, sizeof(QueryOperand *), compareQueryOperand, (void *) operand);
+ qsort_arg(res, *size, sizeof(QueryOperand *), compareQueryOperand, operand);
ptr = res + 1;
prevptr = res;
/*
* Sort representation in ascending order by pos and entry
*/
- qsort((void *) doc, cur, sizeof(DocRepresentation), compareDocR);
+ qsort(doc, cur, sizeof(DocRepresentation), compareDocR);
/*
* Join QueryItem per WordEntry and it's position
if (l <= 1)
return l;
- qsort((void *) a, l, sizeof(WordEntryPos), compareWordEntryPos);
+ qsort(a, l, sizeof(WordEntryPos), compareWordEntryPos);
res = a;
ptr = a + 1;
Assert(l >= 1);
if (l > 1)
- qsort_arg((void *) a, l, sizeof(WordEntryIN), compareentry,
- (void *) buf);
+ qsort_arg(a, l, sizeof(WordEntryIN), compareentry, buf);
buflen = 0;
res = a;
{
arrlen *= 2;
arr = (WordEntryIN *)
- repalloc((void *) arr, sizeof(WordEntryIN) * arrlen);
+ repalloc(arr, sizeof(WordEntryIN) * arrlen);
}
while ((cur - tmpbuf) + toklen >= buflen)
{
int dist = cur - tmpbuf;
buflen *= 2;
- tmpbuf = (char *) repalloc((void *) tmpbuf, buflen);
+ tmpbuf = (char *) repalloc(tmpbuf, buflen);
cur = tmpbuf + dist;
}
arr[len].entry.len = toklen;
arr[len].entry.pos = cur - tmpbuf;
- memcpy((void *) cur, (void *) token, toklen);
+ memcpy(cur, token, toklen);
cur += toklen;
if (poslen != 0)
SET_VARSIZE(vec, hdrlen + datalen);
if (needSort)
- qsort_arg((void *) ARRPTR(vec), vec->size, sizeof(WordEntry),
- compareentry, (void *) STRPTR(vec));
+ qsort_arg(ARRPTR(vec), vec->size, sizeof(WordEntry),
+ compareentry, STRPTR(vec));
PG_RETURN_TSVECTOR(vec);
}
return -1;
}
- memset((void *) &serv_addr, 0, sizeof(serv_addr));
+ memset(&serv_addr, 0, sizeof(serv_addr));
serv_addr.sin_family = AF_INET;
serv_addr.sin_port = pg_hton16(0);
serv_addr.sin_addr.s_addr = pg_hton32(INADDR_LOOPBACK);
}
if (ntes > 1)
- qsort((void *) tes, ntes, sizeof(TocEntry *),
- TocEntrySizeCompare);
+ qsort(tes, ntes, sizeof(TocEntry *), TocEntrySizeCompare);
for (int i = 0; i < ntes; i++)
DispatchJobForTocEntry(AH, pstate, tes[i], ACT_DUMP,
sortDumpableObjectsByTypeName(DumpableObject **objs, int numObjs)
{
if (numObjs > 1)
- qsort((void *) objs, numObjs, sizeof(DumpableObject *),
+ qsort(objs, numObjs, sizeof(DumpableObject *),
DOTypeNameCompare);
}
* consistent order, which is important for reproducible behavior if one
* library depends on another.
*/
- qsort((void *) os_info.libraries, os_info.num_libraries,
+ qsort(os_info.libraries, os_info.num_libraries,
sizeof(LibraryInfo), library_name_compare);
for (libnum = 0; libnum < os_info.num_libraries; libnum++)
/* Sort if we have to */
if (!variables->vars_sorted)
{
- qsort((void *) variables->vars, variables->nvars, sizeof(Variable),
+ qsort(variables->vars, variables->nvars, sizeof(Variable),
compareVariableNames);
variables->vars_sorted = true;
}
/* Now we can search */
key.name = name;
- return (Variable *) bsearch((void *) &key,
- (void *) variables->vars,
+ return (Variable *) bsearch(&key,
+ variables->vars,
variables->nvars,
sizeof(Variable),
compareVariableNames);
* VARDATA is a pointer to the data region of the new struct. The source
* could be a short datum, so retrieve its data through VARDATA_ANY.
*/
- memcpy((void *) VARDATA(new_t), /* destination */
- (void *) VARDATA_ANY(t), /* source */
+ memcpy(VARDATA(new_t), /* destination */
+ VARDATA_ANY(t), /* source */
VARSIZE_ANY_EXHDR(t)); /* how many bytes */
PG_RETURN_TEXT_P(new_t);
}
projects / postgresql-pgindent.git / commitdiff