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/*
* array.c
*
*/
#include <assert.h>
#include <stdio.h>
#include <stdlib.h>
#include <roaring/containers/array.h>
#include <roaring/memory.h>
#if CROARING_IS_X64
#ifndef CROARING_COMPILER_SUPPORTS_AVX512
#error "CROARING_COMPILER_SUPPORTS_AVX512 needs to be defined."
#endif // CROARING_COMPILER_SUPPORTS_AVX512
#endif
#ifdef __cplusplus
extern "C" {
namespace roaring {
namespace internal {
#endif
extern inline uint16_t array_container_minimum(const array_container_t *arr);
extern inline uint16_t array_container_maximum(const array_container_t *arr);
extern inline int array_container_index_equalorlarger(
const array_container_t *arr, uint16_t x);
extern inline int array_container_rank(const array_container_t *arr,
uint16_t x);
extern inline uint32_t array_container_rank_many(const array_container_t *arr,
uint64_t start_rank,
const uint32_t *begin,
const uint32_t *end,
uint64_t *ans);
extern inline int array_container_get_index(const array_container_t *arr,
uint16_t x);
extern inline bool array_container_contains(const array_container_t *arr,
uint16_t pos);
extern inline int array_container_cardinality(const array_container_t *array);
extern inline bool array_container_nonzero_cardinality(
const array_container_t *array);
extern inline int32_t array_container_serialized_size_in_bytes(int32_t card);
extern inline bool array_container_empty(const array_container_t *array);
extern inline bool array_container_full(const array_container_t *array);
/* Create a new array with capacity size. Return NULL in case of failure. */
array_container_t *array_container_create_given_capacity(int32_t size) {
array_container_t *container;
if ((container = (array_container_t *)roaring_malloc(
sizeof(array_container_t))) == NULL) {
return NULL;
}
if (size <= 0) { // we don't want to rely on malloc(0)
container->array = NULL;
} else if ((container->array = (uint16_t *)roaring_malloc(sizeof(uint16_t) *
size)) == NULL) {
roaring_free(container);
return NULL;
}
container->capacity = size;
container->cardinality = 0;
return container;
}
/* Create a new array. Return NULL in case of failure. */
array_container_t *array_container_create(void) {
return array_container_create_given_capacity(ARRAY_DEFAULT_INIT_SIZE);
}
/* Create a new array containing all values in [min,max). */
array_container_t *array_container_create_range(uint32_t min, uint32_t max) {
array_container_t *answer =
array_container_create_given_capacity(max - min + 1);
if (answer == NULL) return answer;
answer->cardinality = 0;
for (uint32_t k = min; k < max; k++) {
answer->array[answer->cardinality++] = k;
}
return answer;
}
/* Duplicate container */
ALLOW_UNALIGNED
array_container_t *array_container_clone(const array_container_t *src) {
array_container_t *newcontainer =
array_container_create_given_capacity(src->capacity);
if (newcontainer == NULL) return NULL;
newcontainer->cardinality = src->cardinality;
memcpy(newcontainer->array, src->array,
src->cardinality * sizeof(uint16_t));
return newcontainer;
}
void array_container_offset(const array_container_t *c, container_t **loc,
container_t **hic, uint16_t offset) {
array_container_t *lo = NULL, *hi = NULL;
int top, lo_cap, hi_cap;
top = (1 << 16) - offset;
lo_cap = count_less(c->array, c->cardinality, top);
if (loc && lo_cap) {
lo = array_container_create_given_capacity(lo_cap);
for (int i = 0; i < lo_cap; ++i) {
array_container_add(lo, c->array[i] + offset);
}
*loc = (container_t *)lo;
}
hi_cap = c->cardinality - lo_cap;
if (hic && hi_cap) {
hi = array_container_create_given_capacity(hi_cap);
for (int i = lo_cap; i < c->cardinality; ++i) {
array_container_add(hi, c->array[i] + offset);
}
*hic = (container_t *)hi;
}
}
int array_container_shrink_to_fit(array_container_t *src) {
if (src->cardinality == src->capacity) return 0; // nothing to do
int savings = src->capacity - src->cardinality;
src->capacity = src->cardinality;
if (src->capacity ==
0) { // we do not want to rely on realloc for zero allocs
roaring_free(src->array);
src->array = NULL;
} else {
uint16_t *oldarray = src->array;
src->array = (uint16_t *)roaring_realloc(
oldarray, src->capacity * sizeof(uint16_t));
if (src->array == NULL) roaring_free(oldarray); // should never happen?
}
return savings;
}
/* Free memory. */
void array_container_free(array_container_t *arr) {
if (arr->array !=
NULL) { // Jon Strabala reports that some tools complain otherwise
roaring_free(arr->array);
arr->array = NULL; // pedantic
}
roaring_free(arr);
}
static inline int32_t grow_capacity(int32_t capacity) {
return (capacity <= 0) ? ARRAY_DEFAULT_INIT_SIZE
: capacity < 64 ? capacity * 2
: capacity < 1024 ? capacity * 3 / 2
: capacity * 5 / 4;
}
static inline int32_t clamp(int32_t val, int32_t min, int32_t max) {
return ((val < min) ? min : (val > max) ? max : val);
}
void array_container_grow(array_container_t *container, int32_t min,
bool preserve) {
int32_t max = (min <= DEFAULT_MAX_SIZE ? DEFAULT_MAX_SIZE : 65536);
int32_t new_capacity = clamp(grow_capacity(container->capacity), min, max);
container->capacity = new_capacity;
uint16_t *array = container->array;
if (preserve) {
container->array =
(uint16_t *)roaring_realloc(array, new_capacity * sizeof(uint16_t));
if (container->array == NULL) roaring_free(array);
} else {
// Jon Strabala reports that some tools complain otherwise
if (array != NULL) {
roaring_free(array);
}
container->array =
(uint16_t *)roaring_malloc(new_capacity * sizeof(uint16_t));
}
// if realloc fails, we have container->array == NULL.
}
/* Copy one container into another. We assume that they are distinct. */
void array_container_copy(const array_container_t *src,
array_container_t *dst) {
const int32_t cardinality = src->cardinality;
if (cardinality > dst->capacity) {
array_container_grow(dst, cardinality, false);
}
dst->cardinality = cardinality;
memcpy(dst->array, src->array, cardinality * sizeof(uint16_t));
}
void array_container_add_from_range(array_container_t *arr, uint32_t min,
uint32_t max, uint16_t step) {
for (uint32_t value = min; value < max; value += step) {
array_container_append(arr, value);
}
}
/* Computes the union of array1 and array2 and write the result to arrayout.
* It is assumed that arrayout is distinct from both array1 and array2.
*/
void array_container_union(const array_container_t *array_1,
const array_container_t *array_2,
array_container_t *out) {
const int32_t card_1 = array_1->cardinality, card_2 = array_2->cardinality;
const int32_t max_cardinality = card_1 + card_2;
if (out->capacity < max_cardinality) {
array_container_grow(out, max_cardinality, false);
}
out->cardinality = (int32_t)fast_union_uint16(
array_1->array, card_1, array_2->array, card_2, out->array);
}
/* Computes the difference of array1 and array2 and write the result
* to array out.
* Array out does not need to be distinct from array_1
*/
void array_container_andnot(const array_container_t *array_1,
const array_container_t *array_2,
array_container_t *out) {
if (out->capacity < array_1->cardinality)
array_container_grow(out, array_1->cardinality, false);
#if CROARING_IS_X64
if ((croaring_hardware_support() & ROARING_SUPPORTS_AVX2) &&
(out != array_1) && (out != array_2)) {
out->cardinality = difference_vector16(
array_1->array, array_1->cardinality, array_2->array,
array_2->cardinality, out->array);
} else {
out->cardinality =
difference_uint16(array_1->array, array_1->cardinality,
array_2->array, array_2->cardinality, out->array);
}
#else
out->cardinality =
difference_uint16(array_1->array, array_1->cardinality, array_2->array,
array_2->cardinality, out->array);
#endif
}
/* Computes the symmetric difference of array1 and array2 and write the
* result
* to arrayout.
* It is assumed that arrayout is distinct from both array1 and array2.
*/
void array_container_xor(const array_container_t *array_1,
const array_container_t *array_2,
array_container_t *out) {
const int32_t card_1 = array_1->cardinality, card_2 = array_2->cardinality;
const int32_t max_cardinality = card_1 + card_2;
if (out->capacity < max_cardinality) {
array_container_grow(out, max_cardinality, false);
}
#if CROARING_IS_X64
if (croaring_hardware_support() & ROARING_SUPPORTS_AVX2) {
out->cardinality =
xor_vector16(array_1->array, array_1->cardinality, array_2->array,
array_2->cardinality, out->array);
} else {
out->cardinality =
xor_uint16(array_1->array, array_1->cardinality, array_2->array,
array_2->cardinality, out->array);
}
#else
out->cardinality =
xor_uint16(array_1->array, array_1->cardinality, array_2->array,
array_2->cardinality, out->array);
#endif
}
static inline int32_t minimum_int32(int32_t a, int32_t b) {
return (a < b) ? a : b;
}
/* computes the intersection of array1 and array2 and write the result to
* arrayout.
* It is assumed that arrayout is distinct from both array1 and array2.
* */
void array_container_intersection(const array_container_t *array1,
const array_container_t *array2,
array_container_t *out) {
int32_t card_1 = array1->cardinality, card_2 = array2->cardinality,
min_card = minimum_int32(card_1, card_2);
const int threshold = 64; // subject to tuning
#if CROARING_IS_X64
if (out->capacity < min_card) {
array_container_grow(out, min_card + sizeof(__m128i) / sizeof(uint16_t),
false);
}
#else
if (out->capacity < min_card) {
array_container_grow(out, min_card, false);
}
#endif
if (card_1 * threshold < card_2) {
out->cardinality = intersect_skewed_uint16(
array1->array, card_1, array2->array, card_2, out->array);
} else if (card_2 * threshold < card_1) {
out->cardinality = intersect_skewed_uint16(
array2->array, card_2, array1->array, card_1, out->array);
} else {
#if CROARING_IS_X64
if (croaring_hardware_support() & ROARING_SUPPORTS_AVX2) {
out->cardinality = intersect_vector16(
array1->array, card_1, array2->array, card_2, out->array);
} else {
out->cardinality = intersect_uint16(
array1->array, card_1, array2->array, card_2, out->array);
}
#else
out->cardinality = intersect_uint16(array1->array, card_1,
array2->array, card_2, out->array);
#endif
}
}
/* computes the size of the intersection of array1 and array2
* */
int array_container_intersection_cardinality(const array_container_t *array1,
const array_container_t *array2) {
int32_t card_1 = array1->cardinality, card_2 = array2->cardinality;
const int threshold = 64; // subject to tuning
if (card_1 * threshold < card_2) {
return intersect_skewed_uint16_cardinality(array1->array, card_1,
array2->array, card_2);
} else if (card_2 * threshold < card_1) {
return intersect_skewed_uint16_cardinality(array2->array, card_2,
array1->array, card_1);
} else {
#if CROARING_IS_X64
if (croaring_hardware_support() & ROARING_SUPPORTS_AVX2) {
return intersect_vector16_cardinality(array1->array, card_1,
array2->array, card_2);
} else {
return intersect_uint16_cardinality(array1->array, card_1,
array2->array, card_2);
}
#else
return intersect_uint16_cardinality(array1->array, card_1,
array2->array, card_2);
#endif
}
}
bool array_container_intersect(const array_container_t *array1,
const array_container_t *array2) {
int32_t card_1 = array1->cardinality, card_2 = array2->cardinality;
const int threshold = 64; // subject to tuning
if (card_1 * threshold < card_2) {
return intersect_skewed_uint16_nonempty(array1->array, card_1,
array2->array, card_2);
} else if (card_2 * threshold < card_1) {
return intersect_skewed_uint16_nonempty(array2->array, card_2,
array1->array, card_1);
} else {
// we do not bother vectorizing
return intersect_uint16_nonempty(array1->array, card_1, array2->array,
card_2);
}
}
/* computes the intersection of array1 and array2 and write the result to
* array1.
* */
void array_container_intersection_inplace(array_container_t *src_1,
const array_container_t *src_2) {
int32_t card_1 = src_1->cardinality, card_2 = src_2->cardinality;
const int threshold = 64; // subject to tuning
if (card_1 * threshold < card_2) {
src_1->cardinality = intersect_skewed_uint16(
src_1->array, card_1, src_2->array, card_2, src_1->array);
} else if (card_2 * threshold < card_1) {
src_1->cardinality = intersect_skewed_uint16(
src_2->array, card_2, src_1->array, card_1, src_1->array);
} else {
#if CROARING_IS_X64
if (croaring_hardware_support() & ROARING_SUPPORTS_AVX2) {
src_1->cardinality = intersect_vector16_inplace(
src_1->array, card_1, src_2->array, card_2);
} else {
src_1->cardinality = intersect_uint16(
src_1->array, card_1, src_2->array, card_2, src_1->array);
}
#else
src_1->cardinality = intersect_uint16(
src_1->array, card_1, src_2->array, card_2, src_1->array);
#endif
}
}
ALLOW_UNALIGNED
int array_container_to_uint32_array(void *vout, const array_container_t *cont,
uint32_t base) {
#if CROARING_IS_X64
int support = croaring_hardware_support();
#if CROARING_COMPILER_SUPPORTS_AVX512
if (support & ROARING_SUPPORTS_AVX512) {
return avx512_array_container_to_uint32_array(vout, cont->array,
cont->cardinality, base);
}
#endif
if (support & ROARING_SUPPORTS_AVX2) {
return array_container_to_uint32_array_vector16(
vout, cont->array, cont->cardinality, base);
}
#endif // CROARING_IS_X64
int outpos = 0;
uint32_t *out = (uint32_t *)vout;
size_t i = 0;
for (; i < (size_t)cont->cardinality; ++i) {
const uint32_t val = base + cont->array[i];
memcpy(out + outpos, &val,
sizeof(uint32_t)); // should be compiled as a MOV on x64
outpos++;
}
return outpos;
}
void array_container_printf(const array_container_t *v) {
if (v->cardinality == 0) {
printf("{}");
return;
}
printf("{");
printf("%d", v->array[0]);
for (int i = 1; i < v->cardinality; ++i) {
printf(",%d", v->array[i]);
}
printf("}");
}
void array_container_printf_as_uint32_array(const array_container_t *v,
uint32_t base) {
if (v->cardinality == 0) {
return;
}
printf("%u", v->array[0] + base);
for (int i = 1; i < v->cardinality; ++i) {
printf(",%u", v->array[i] + base);
}
}
/*
* Validate the container. Returns true if valid.
*/
bool array_container_validate(const array_container_t *v, const char **reason) {
if (v->capacity < 0) {
*reason = "negative capacity";
return false;
}
if (v->cardinality < 0) {
*reason = "negative cardinality";
return false;
}
if (v->cardinality > v->capacity) {
*reason = "cardinality exceeds capacity";
return false;
}
if (v->cardinality > DEFAULT_MAX_SIZE) {
*reason = "cardinality exceeds DEFAULT_MAX_SIZE";
return false;
}
if (v->cardinality == 0) {
*reason = "zero cardinality";
return false;
}
if (v->array == NULL) {
*reason = "NULL array pointer";
return false;
}
uint16_t prev = v->array[0];
for (int i = 1; i < v->cardinality; ++i) {
if (v->array[i] <= prev) {
*reason = "array elements not strictly increasing";
return false;
}
prev = v->array[i];
}
return true;
}
/* Compute the number of runs */
int32_t array_container_number_of_runs(const array_container_t *ac) {
// Can SIMD work here?
int32_t nr_runs = 0;
int32_t prev = -2;
for (const uint16_t *p = ac->array; p != ac->array + ac->cardinality; ++p) {
if (*p != prev + 1) nr_runs++;
prev = *p;
}
return nr_runs;
}
/**
* Writes the underlying array to buf, outputs how many bytes were written.
* The number of bytes written should be
* array_container_size_in_bytes(container).
*
*/
int32_t array_container_write(const array_container_t *container, char *buf) {
memcpy(buf, container->array, container->cardinality * sizeof(uint16_t));
return array_container_size_in_bytes(container);
}
bool array_container_is_subset(const array_container_t *container1,
const array_container_t *container2) {
if (container1->cardinality > container2->cardinality) {
return false;
}
int i1 = 0, i2 = 0;
while (i1 < container1->cardinality && i2 < container2->cardinality) {
if (container1->array[i1] == container2->array[i2]) {
i1++;
i2++;
} else if (container1->array[i1] > container2->array[i2]) {
i2++;
} else { // container1->array[i1] < container2->array[i2]
return false;
}
}
if (i1 == container1->cardinality) {
return true;
} else {
return false;
}
}
int32_t array_container_read(int32_t cardinality, array_container_t *container,
const char *buf) {
if (container->capacity < cardinality) {
array_container_grow(container, cardinality, false);
}
container->cardinality = cardinality;
memcpy(container->array, buf, container->cardinality * sizeof(uint16_t));
return array_container_size_in_bytes(container);
}
bool array_container_iterate(const array_container_t *cont, uint32_t base,
roaring_iterator iterator, void *ptr) {
for (int i = 0; i < cont->cardinality; i++)
if (!iterator(cont->array[i] + base, ptr)) return false;
return true;
}
bool array_container_iterate64(const array_container_t *cont, uint32_t base,
roaring_iterator64 iterator, uint64_t high_bits,
void *ptr) {
for (int i = 0; i < cont->cardinality; i++)
if (!iterator(high_bits | (uint64_t)(cont->array[i] + base), ptr))
return false;
return true;
}
#ifdef __cplusplus
}
}
} // extern "C" { namespace roaring { namespace internal {
#endif
|
