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/*
* mixed_xor.c
*/
#include <assert.h>
#include <string.h>
#include <roaring/bitset_util.h>
#include <roaring/containers/containers.h>
#include <roaring/containers/convert.h>
#include <roaring/containers/mixed_xor.h>
#include <roaring/containers/perfparameters.h>
#ifdef __cplusplus
extern "C" {
namespace roaring {
namespace internal {
#endif
/* Compute the xor of src_1 and src_2 and write the result to
* dst (which has no container initially).
* Result is true iff dst is a bitset */
bool array_bitset_container_xor(const array_container_t *src_1,
const bitset_container_t *src_2,
container_t **dst) {
bitset_container_t *result = bitset_container_create();
bitset_container_copy(src_2, result);
result->cardinality = (int32_t)bitset_flip_list_withcard(
result->words, result->cardinality, src_1->array, src_1->cardinality);
// do required type conversions.
if (result->cardinality <= DEFAULT_MAX_SIZE) {
*dst = array_container_from_bitset(result);
bitset_container_free(result);
return false; // not bitset
}
*dst = result;
return true; // bitset
}
/* Compute the xor of src_1 and src_2 and write the result to
* dst. It is allowed for src_2 to be dst. This version does not
* update the cardinality of dst (it is set to BITSET_UNKNOWN_CARDINALITY).
*/
void array_bitset_container_lazy_xor(const array_container_t *src_1,
const bitset_container_t *src_2,
bitset_container_t *dst) {
if (src_2 != dst) bitset_container_copy(src_2, dst);
bitset_flip_list(dst->words, src_1->array, src_1->cardinality);
dst->cardinality = BITSET_UNKNOWN_CARDINALITY;
}
/* Compute the xor of src_1 and src_2 and write the result to
* dst. Result may be either a bitset or an array container
* (returns "result is bitset"). dst does not initially have
* any container, but becomes either a bitset container (return
* result true) or an array container.
*/
bool run_bitset_container_xor(const run_container_t *src_1,
const bitset_container_t *src_2,
container_t **dst) {
bitset_container_t *result = bitset_container_create();
bitset_container_copy(src_2, result);
for (int32_t rlepos = 0; rlepos < src_1->n_runs; ++rlepos) {
rle16_t rle = src_1->runs[rlepos];
bitset_flip_range(result->words, rle.value,
rle.value + rle.length + UINT32_C(1));
}
result->cardinality = bitset_container_compute_cardinality(result);
if (result->cardinality <= DEFAULT_MAX_SIZE) {
*dst = array_container_from_bitset(result);
bitset_container_free(result);
return false; // not bitset
}
*dst = result;
return true; // bitset
}
/* lazy xor. Dst is initialized and may be equal to src_2.
* Result is left as a bitset container, even if actual
* cardinality would dictate an array container.
*/
void run_bitset_container_lazy_xor(const run_container_t *src_1,
const bitset_container_t *src_2,
bitset_container_t *dst) {
if (src_2 != dst) bitset_container_copy(src_2, dst);
for (int32_t rlepos = 0; rlepos < src_1->n_runs; ++rlepos) {
rle16_t rle = src_1->runs[rlepos];
bitset_flip_range(dst->words, rle.value,
rle.value + rle.length + UINT32_C(1));
}
dst->cardinality = BITSET_UNKNOWN_CARDINALITY;
}
/* dst does not indicate a valid container initially. Eventually it
* can become any kind of container.
*/
int array_run_container_xor(const array_container_t *src_1,
const run_container_t *src_2, container_t **dst) {
// semi following Java XOR implementation as of May 2016
// the C OR implementation works quite differently and can return a run
// container
// TODO could optimize for full run containers.
// use of lazy following Java impl.
const int arbitrary_threshold = 32;
if (src_1->cardinality < arbitrary_threshold) {
run_container_t *ans = run_container_create();
array_run_container_lazy_xor(src_1, src_2, ans); // keeps runs.
uint8_t typecode_after;
*dst =
convert_run_to_efficient_container_and_free(ans, &typecode_after);
return typecode_after;
}
int card = run_container_cardinality(src_2);
if (card <= DEFAULT_MAX_SIZE) {
// Java implementation works with the array, xoring the run elements via
// iterator
array_container_t *temp = array_container_from_run(src_2);
bool ret_is_bitset = array_array_container_xor(temp, src_1, dst);
array_container_free(temp);
return ret_is_bitset ? BITSET_CONTAINER_TYPE : ARRAY_CONTAINER_TYPE;
} else { // guess that it will end up as a bitset
bitset_container_t *result = bitset_container_from_run(src_2);
bool is_bitset = bitset_array_container_ixor(result, src_1, dst);
// any necessary type conversion has been done by the ixor
int retval = (is_bitset ? BITSET_CONTAINER_TYPE : ARRAY_CONTAINER_TYPE);
return retval;
}
}
/* Dst is a valid run container. (Can it be src_2? Let's say not.)
* Leaves result as run container, even if other options are
* smaller.
*/
void array_run_container_lazy_xor(const array_container_t *src_1,
const run_container_t *src_2,
run_container_t *dst) {
run_container_grow(dst, src_1->cardinality + src_2->n_runs, false);
int32_t rlepos = 0;
int32_t arraypos = 0;
dst->n_runs = 0;
while ((rlepos < src_2->n_runs) && (arraypos < src_1->cardinality)) {
if (src_2->runs[rlepos].value <= src_1->array[arraypos]) {
run_container_smart_append_exclusive(dst, src_2->runs[rlepos].value,
src_2->runs[rlepos].length);
rlepos++;
} else {
run_container_smart_append_exclusive(dst, src_1->array[arraypos],
0);
arraypos++;
}
}
while (arraypos < src_1->cardinality) {
run_container_smart_append_exclusive(dst, src_1->array[arraypos], 0);
arraypos++;
}
while (rlepos < src_2->n_runs) {
run_container_smart_append_exclusive(dst, src_2->runs[rlepos].value,
src_2->runs[rlepos].length);
rlepos++;
}
}
/* dst does not indicate a valid container initially. Eventually it
* can become any kind of container.
*/
int run_run_container_xor(const run_container_t *src_1,
const run_container_t *src_2, container_t **dst) {
run_container_t *ans = run_container_create();
run_container_xor(src_1, src_2, ans);
uint8_t typecode_after;
*dst = convert_run_to_efficient_container_and_free(ans, &typecode_after);
return typecode_after;
}
/*
* Java implementation (as of May 2016) for array_run, run_run
* and bitset_run don't do anything different for inplace.
* Could adopt the mixed_union.c approach instead (ie, using
* smart_append_exclusive)
*
*/
bool array_array_container_xor(const array_container_t *src_1,
const array_container_t *src_2,
container_t **dst) {
int totalCardinality =
src_1->cardinality + src_2->cardinality; // upper bound
if (totalCardinality <= DEFAULT_MAX_SIZE) {
*dst = array_container_create_given_capacity(totalCardinality);
array_container_xor(src_1, src_2, CAST_array(*dst));
return false; // not a bitset
}
*dst = bitset_container_from_array(src_1);
bool returnval = true; // expect a bitset
bitset_container_t *ourbitset = CAST_bitset(*dst);
ourbitset->cardinality = (uint32_t)bitset_flip_list_withcard(
ourbitset->words, src_1->cardinality, src_2->array, src_2->cardinality);
if (ourbitset->cardinality <= DEFAULT_MAX_SIZE) {
// need to convert!
*dst = array_container_from_bitset(ourbitset);
bitset_container_free(ourbitset);
returnval = false; // not going to be a bitset
}
return returnval;
}
bool array_array_container_lazy_xor(const array_container_t *src_1,
const array_container_t *src_2,
container_t **dst) {
int totalCardinality = src_1->cardinality + src_2->cardinality;
//
// We assume that operations involving bitset containers will be faster than
// operations involving solely array containers, except maybe when array
// containers are small. Indeed, for example, it is cheap to compute the
// exclusive union between an array and a bitset container, generally more
// so than between a large array and another array. So it is advantageous to
// favour bitset containers during the computation. Of course, if we convert
// array containers eagerly to bitset containers, we may later need to
// revert the bitset containers to array containerr to satisfy the Roaring
// format requirements, but such one-time conversions at the end may not be
// overly expensive. We arrived to this design based on extensive
// benchmarking on unions. For XOR/exclusive union, we simply followed the
// heuristic used by the unions (see mixed_union.c). Further tuning is
// possible.
//
if (totalCardinality <= ARRAY_LAZY_LOWERBOUND) {
*dst = array_container_create_given_capacity(totalCardinality);
if (*dst != NULL) array_container_xor(src_1, src_2, CAST_array(*dst));
return false; // not a bitset
}
*dst = bitset_container_from_array(src_1);
bool returnval = true; // expect a bitset (maybe, for XOR??)
if (*dst != NULL) {
bitset_container_t *ourbitset = CAST_bitset(*dst);
bitset_flip_list(ourbitset->words, src_2->array, src_2->cardinality);
ourbitset->cardinality = BITSET_UNKNOWN_CARDINALITY;
}
return returnval;
}
/* Compute the xor of src_1 and src_2 and write the result to
* dst (which has no container initially). Return value is
* "dst is a bitset"
*/
bool bitset_bitset_container_xor(const bitset_container_t *src_1,
const bitset_container_t *src_2,
container_t **dst) {
bitset_container_t *ans = bitset_container_create();
int card = bitset_container_xor(src_1, src_2, ans);
if (card <= DEFAULT_MAX_SIZE) {
*dst = array_container_from_bitset(ans);
bitset_container_free(ans);
return false; // not bitset
} else {
*dst = ans;
return true;
}
}
/* Compute the xor of src_1 and src_2 and write the result to
* dst (which has no container initially). It will modify src_1
* to be dst if the result is a bitset. Otherwise, it will
* free src_1 and dst will be a new array container. In both
* cases, the caller is responsible for deallocating dst.
* Returns true iff dst is a bitset */
bool bitset_array_container_ixor(bitset_container_t *src_1,
const array_container_t *src_2,
container_t **dst) {
*dst = src_1;
src_1->cardinality = (uint32_t)bitset_flip_list_withcard(
src_1->words, src_1->cardinality, src_2->array, src_2->cardinality);
if (src_1->cardinality <= DEFAULT_MAX_SIZE) {
*dst = array_container_from_bitset(src_1);
bitset_container_free(src_1);
return false; // not bitset
} else
return true;
}
/* a bunch of in-place, some of which may not *really* be inplace.
* TODO: write actual inplace routine if efficiency warrants it
* Anything inplace with a bitset is a good candidate
*/
bool bitset_bitset_container_ixor(bitset_container_t *src_1,
const bitset_container_t *src_2,
container_t **dst) {
int card = bitset_container_xor(src_1, src_2, src_1);
if (card <= DEFAULT_MAX_SIZE) {
*dst = array_container_from_bitset(src_1);
bitset_container_free(src_1);
return false; // not bitset
} else {
*dst = src_1;
return true;
}
}
bool array_bitset_container_ixor(array_container_t *src_1,
const bitset_container_t *src_2,
container_t **dst) {
bool ans = array_bitset_container_xor(src_1, src_2, dst);
array_container_free(src_1);
return ans;
}
/* Compute the xor of src_1 and src_2 and write the result to
* dst. Result may be either a bitset or an array container
* (returns "result is bitset"). dst does not initially have
* any container, but becomes either a bitset container (return
* result true) or an array container.
*/
bool run_bitset_container_ixor(run_container_t *src_1,
const bitset_container_t *src_2,
container_t **dst) {
bool ans = run_bitset_container_xor(src_1, src_2, dst);
run_container_free(src_1);
return ans;
}
bool bitset_run_container_ixor(bitset_container_t *src_1,
const run_container_t *src_2,
container_t **dst) {
bool ans = run_bitset_container_xor(src_2, src_1, dst);
bitset_container_free(src_1);
return ans;
}
/* dst does not indicate a valid container initially. Eventually it
* can become any kind of container.
*/
int array_run_container_ixor(array_container_t *src_1,
const run_container_t *src_2, container_t **dst) {
int ans = array_run_container_xor(src_1, src_2, dst);
array_container_free(src_1);
return ans;
}
int run_array_container_ixor(run_container_t *src_1,
const array_container_t *src_2,
container_t **dst) {
int ans = array_run_container_xor(src_2, src_1, dst);
run_container_free(src_1);
return ans;
}
bool array_array_container_ixor(array_container_t *src_1,
const array_container_t *src_2,
container_t **dst) {
bool ans = array_array_container_xor(src_1, src_2, dst);
array_container_free(src_1);
return ans;
}
int run_run_container_ixor(run_container_t *src_1, const run_container_t *src_2,
container_t **dst) {
int ans = run_run_container_xor(src_1, src_2, dst);
run_container_free(src_1);
return ans;
}
#ifdef __cplusplus
}
}
} // extern "C" { namespace roaring { namespace internal {
#endif
|