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/* SPDX-License-Identifier: LGPL-2.1-only */
/* Copyright (C) 2020-2021 Gediminas Jakutis */
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include <rin/definitions.h>
#include <rin/diagnostic.h>
#include "defs.h"
#include "stream.h"
#include "cache.h"
int cache_create(struct stream * const in)
{
int ret = 0;
void *cache;
try(in->settings->access != cached, err, EINVAL, "cannot create cache: stream is uncached");
try(!(cache = calloc(in->n, in->settings->stride)), err, ENOMEM, "out of memory");
/* yeah... */
in->cache = cache;
in->cache_a = cache;
in->cache_l = cache;
err:
return ret;
}
int cache_populate(struct stream * const in)
{
int ret = 0;
size_t i;
struct entry_l *tmp;
try(in->settings->access != cached, err, EINVAL, "cannot populate cache: stream is uncached");
try(!in->cache, err, EINVAL, "stream has no cache allocated");
/* if reading a a randstream, fall back to the one-element-at-a-time mode */
if (in->type == stream_randread) {
for (i = 0; i < in->n && !ret; ++i) {
errno = 0;
tmp = in->get_next_element_direct(in);
if (tmp) { /* non-cache reads CAN fail */
put(in, tmp);
} else {
ret = errno;
break;
}
}
} else if (in->type == stream_in) {
try_s((ret == stream_readfile(in)), err);
} else {
try(1, err, EINVAL, "cannot populate a non-reading stream cache");
}
err:
return ret;
}
int cache_destroy(struct stream * const in)
{
int ret = 0;
try(in->settings->access != cached, err, EINVAL, "cannot destroy cache: stream is uncached");
free(in->cache);
in->cache_l = NULL;
in->cache_a = NULL;
in->cache = NULL;
err:
return ret;
}
int cache_transfer(struct stream * const src, struct stream * const dest)
{
int ret = 0;
try(src->settings->access != cached || dest->settings->access != cached, err, EINVAL, "cannot transfer caches of uncached streams");
try(!src->cache, err, EINVAL, "no cache to transfer");
try(dest->cache, err, EINVAL, "cannot transfer cache: recipient cache already exists");
dest->cache = src->cache;
dest->cache_a = (struct entry *) src->cache;
dest->cache_l = (struct entry_l *) src->cache;
src->cache = NULL;
src->cache_a = NULL;
src->cache_l = NULL;
err:
return ret;
}
int cache_block_copy(struct stream const * const src, struct stream * const dest)
{
int ret = 0;
try(src->settings->access != cached || dest->settings->access != cached, err, EINVAL, "cannot cache-copy between uncached streams");
try(!src->cache, err, EINVAL, "no cache to transfer");
try(src->n < dest->settings->to, err, EINVAL, "invalid copy size");
try(!dest->cache, err, EINVAL, "no cache to transfer to");
memcpy(dest->cache, src->cache_a + dest->settings->ss, (dest->settings->to - dest->settings->ss) * dest->settings->stride);
dest->n = dest->settings->to - dest->settings->ss;
err:
return ret;
}
int cache_list_copy(struct stream * const src, struct stream * const dest)
{
int ret = 0;
struct entry_l *tmp;
try(src->settings->access != cached || dest->settings->access != cached, err, EINVAL, "cannot cache-copy between uncached streams");
try(!src->cache, err, EINVAL, "no cache to transfer");
try(!(src->n > dest->settings->to), err, EINVAL, "invalid copy size");
try(!dest->cache, err, EINVAL, "no cache to transfer to");
while ((tmp = get(src))) {
put(dest, tmp);
}
cache_rewind(src);
err:
return ret;
}
int cache_block_split(struct stream * const src, struct stream * const A, struct stream * const B)
{
int ret = 0;
struct settings tmp_settings;
try(src->n < 2, err, EINVAL, "cannot split single element stream.");
/* setting up minimal stream basics */
A->n = src->n / 2;
B->n = src->n / 2 + (src->n & 1ul);
A->index = B->index = 0;
A->type = B->type = stream_cache; /* disallow any stream operations other than split/merge on children */
A->fd = B->fd = -1; /* if we're splitting, these are for holding cache only */
/* we only care about these three functions for these temporary streams */
A->get_next_element_cache = B->get_next_element_cache = src->get_next_element_cache;
A->place_next_element_cache = B->place_next_element_cache = src->place_next_element_cache;
A->split = B->split = src->split;
A->rewind = B->rewind = src->rewind;
tmp_settings = *src->settings;
A->settings = B->settings = &tmp_settings;
/* setting up A */
tmp_settings.ss = 0;
tmp_settings.to = A->n;
try_s((ret = cache_create(A)), err);
try_s((ret = cache_block_copy(src, A)), err);
/* setting up B */
tmp_settings.ss = A->n;
tmp_settings.to = src->n;
try_s((ret = cache_create(B)), err);
try_s((ret = cache_block_copy(src, B)), err);
A->settings = B->settings = src->settings;
err:
return ret;
}
int cache_list_split(struct stream * const src, struct stream * const A, struct stream * const B)
{
int ret = ENOSYS;
(void) src;
(void) A;
(void) B;
rin_warn("stub!");
return ret;
}
struct entry_l *cached_get_array(struct stream * const in)
{
struct entry_l *ret = NULL;
if (in->index < in->n) {
ret = (struct entry_l *)(in->cache_a + in->index);
++in->index;
}
return ret;
}
struct entry_l *cached_get_list(struct stream * const in)
{
struct entry_l *ret = NULL;
if (in->index < in->n) {
ret = in->cnode;
in->cnode = ret->next;
++in->index;
}
return ret;
}
int cached_put_array(struct stream * const in, const struct entry_l * const data)
{
int ret = 0;
if (in->index < in->n) {
in->cache_a[in->index].val = data->val;
++in->index;
}
return ret;
}
/* This is were fun with the fact mergesort is NOT an in-place algorightm begins.
* Since we only ever need to "put" on a) generating data and b) merging lists,
* we basically have to generate the list anew each and every time. For generating,
* it's a no-brainer, but for lists, while reusing existing nodes COULD be done in
* a chached variant, file variant cannot do this, as cross-file links are not
* something that could be handled without going into pretty insane (and laughably
* inefficient) lenghts either way.
*
* And thus alas, we have no option but to just make a list anew
*/
int cached_put_list(struct stream * const restrict in, const struct entry_l * const node)
{
int ret = 0;
if (!in->cnode) { /* if this is the very first one */
in->cnode = in->cache_l;
in->cnode->val = node->val;
in->cnode->next = NULL;
in->index = 0;
} else {
in->cnode->next = in->cnode + 1; /* lol says librin, lmao */
in->cnode = in->cnode->next;
in->cnode->val = node->val;
in->cnode->next = NULL;
++in->index;
}
return ret;
}
int cache_rewind(struct stream * const in)
{
int ret = 0;
in->cnode = in->cnode ? in->cache_l : NULL;
in->index = 0;
return ret;
}
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