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boundedsize_kfifo.h
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boundedsize_kfifo.h
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// Copyright (c) 2012-2013, the Scal Project Authors. All rights reserved.
// Please see the AUTHORS file for details. Use of this source code is governed
// by a BSD license that can be found in the LICENSE file.
// Implementing the queue from:
//
// C.M. Kirsch, M. Lippautz, and H. Payer. Fast and Scalable k-FIFO Queues.
// Technical Report 2012-04, Department of Computer Sciences, University of
// Salzburg, June 2012.
#ifndef SCAL_DATASTRUCTURES_BOUNDEDSIZE_KFIFO_H_
#define SCAL_DATASTRUCTURES_BOUNDEDSIZE_KFIFO_H_
#include <inttypes.h>
#include <stdio.h>
#include <stdlib.h>
#include "datastructures/queue.h"
#include "util/allocation.h"
#include "util/atomic_value_new.h"
#include "util/platform.h"
#include "util/random.h"
#define BSKFIFO_WASTE 1
#ifdef BSKFIFO_WASTE
#define PTR_ALIGNMENT (4096)
#define ITEM_PAD (128 * 4)
#else
#define PTR_ALIGNMENT (128)
#define ITEM_PAD (128)
#endif // BSKFIFO_WASTE
namespace scal {
template<typename T>
class BoundedSizeKFifo : public Queue<T> {
public:
BoundedSizeKFifo(uint64_t k, uint64_t num_segments);
bool enqueue(T item);
bool dequeue(T *item);
private:
typedef TaggedValue<uint64_t> SegmentPtr;
typedef AtomicTaggedValue<uint64_t, PTR_ALIGNMENT, 128> AtomicSegmentPtr;
typedef TaggedValue<T> Item;
typedef AtomicTaggedValue<T, 0, ITEM_PAD> AtomicItem;
_always_inline bool find_index(
uint64_t start_index, bool empty, int64_t *item_index, Item* old);
_always_inline bool advance_head(const SegmentPtr& head_old);
_always_inline bool advance_tail(const SegmentPtr& tail_old);
_always_inline bool queue_full(
const SegmentPtr& head_old, const SegmentPtr& tail_old);
_always_inline bool segment_not_empty(const SegmentPtr& head_old);
_always_inline bool not_in_valid_region(uint64_t tail_old_pointer,
uint64_t tail_current_pointer,
uint64_t head_current_pointer);
_always_inline bool in_valid_region(uint64_t tail_old_pointer,
uint64_t tail_current_pointer,
uint64_t head_current_pointer);
_always_inline bool committed(
const SegmentPtr& tail_old, const Item& new_item, uint64_t item_index);
uint64_t queue_size_;
size_t k_;
AtomicSegmentPtr* head_;
AtomicSegmentPtr* tail_;
AtomicItem* queue_;
uint8_t pad_[
128
- sizeof(queue_size_)
- sizeof(k_)
- sizeof(head_)
- sizeof(tail_)
- sizeof(queue_)];
};
template<typename T>
BoundedSizeKFifo<T>::BoundedSizeKFifo(uint64_t k, uint64_t num_segments)
: queue_size_(k * num_segments)
, k_(k)
, head_(new AtomicSegmentPtr())
, tail_(new AtomicSegmentPtr())
, queue_(static_cast<AtomicItem*>(
CallocAligned(k * num_segments, sizeof(AtomicItem), 64))) {
}
template<typename T>
bool BoundedSizeKFifo<T>::find_index(
uint64_t start_index, bool empty, int64_t *item_index, Item* old) {
const uint64_t random_index = pseudorand() % k_;
uint64_t index;
for (size_t i = 0; i < k_; i++) {
index = (start_index + ((random_index + i) % k_)) % queue_size_;
*old = queue_[index].load();
if ((empty && old->value() == (T)NULL)
|| (!empty && old->value() != (T)NULL)) {
*item_index = index;
return true;
}
}
return false;
}
template<typename T>
bool BoundedSizeKFifo<T>::advance_head(const SegmentPtr& head_old) {
return head_->swap(
head_old, SegmentPtr((head_old.value() + k_) % queue_size_, head_old.tag() + 1));
}
template<typename T>
bool BoundedSizeKFifo<T>::advance_tail(const SegmentPtr& tail_old) {
return tail_->swap(
tail_old, SegmentPtr((tail_old.value() + k_) % queue_size_, tail_old.tag() + 1));
}
template<typename T>
bool BoundedSizeKFifo<T>::queue_full(
const SegmentPtr& head_old, const SegmentPtr& tail_old) {
if (((tail_old.value() + k_) % queue_size_) == head_old.value() &&
(head_old.value() == head_->load().value())) {
return true;
}
return false;
}
template<typename T>
bool BoundedSizeKFifo<T>::segment_not_empty(const SegmentPtr& head_old) {
const uint64_t start = head_old.value();
for (size_t i = 0; i < k_; i++) {
if (queue_[(start + i) % queue_size_].load().value() != (T)NULL) {
return true;
}
}
return false;
}
template<typename T>
bool BoundedSizeKFifo<T>::in_valid_region(uint64_t tail_old_pointer,
uint64_t tail_current_pointer,
uint64_t head_current_pointer) {
bool wrap_around = (tail_current_pointer < head_current_pointer)
? true : false;
if (!wrap_around) {
return (head_current_pointer < tail_old_pointer
&& tail_old_pointer <= tail_current_pointer) ? true : false;
}
return (head_current_pointer < tail_old_pointer
|| tail_old_pointer <= tail_current_pointer) ? true : false;
}
template<typename T>
bool BoundedSizeKFifo<T>::not_in_valid_region(uint64_t tail_old_pointer,
uint64_t tail_current_pointer,
uint64_t head_current_pointer) {
bool wrap_around = (tail_current_pointer < head_current_pointer)
? true : false;
if (!wrap_around) {
return (tail_old_pointer < tail_current_pointer
|| head_current_pointer < tail_old_pointer) ? true : false;
}
return (tail_old_pointer < tail_current_pointer
&& head_current_pointer < tail_old_pointer) ? true : false;
}
template<typename T>
bool BoundedSizeKFifo<T>::committed(const SegmentPtr& tail_old,
//uint64_t tail_old_pointer,
//AtomicValue<T> *new_item,
const Item& new_item,
uint64_t item_index) {
if (queue_[item_index].load() != new_item) {
return true;
}
SegmentPtr tail_current = tail_->load();
SegmentPtr head_current = head_->load();
if (in_valid_region(tail_old.value(), tail_current.value(),
head_current.value())) {
return true;
} else if (not_in_valid_region(tail_old.value(), tail_current.value(),
head_current.value())) {
if (!queue_[item_index].swap(
new_item, Item((T)NULL, new_item.tag() + 1))) {
return true;
}
} else {
if (head_->swap(
head_current, SegmentPtr(head_current.value(),
head_current.tag() + 1))) {
return true;
}
if (!queue_[item_index].swap(
new_item, Item((T)NULL, new_item.tag() + 1))) {
return true;
}
}
return false;
}
template<typename T>
bool BoundedSizeKFifo<T>::dequeue(T *item) {
SegmentPtr tail_old;
SegmentPtr head_old;
int64_t item_index;
Item old_item;
bool found_idx;
while (true) {
head_old = head_->load();
tail_old = tail_->load();
found_idx = find_index(head_old.value(), false, &item_index, &old_item);
if (head_old == head_->load()) {
if (found_idx) {
if (head_old.value() == tail_old.value()) {
advance_tail(tail_old);
}
if (queue_[item_index].swap(
old_item, Item((T)NULL, old_item.tag() + 1))) {
*item = old_item.value();
return true;
}
} else {
if ((head_old.value() == tail_old.value()) &&
(tail_old.value() == tail_->load().value())) {
return false;
}
advance_head(head_old);
}
}
}
}
template<typename T>
bool BoundedSizeKFifo<T>::enqueue(T item) {
TaggedValue<T>::CheckCompatibility(item);
if (item == (T)NULL) {
printf("%s: unable to enqueue NULL or equivalent value\n", __func__);
abort();
}
SegmentPtr tail_old;
SegmentPtr head_old;
int64_t item_index;
Item old_item;
bool found_idx;
while (true) {
tail_old = tail_->load();
head_old = head_->load();
found_idx = find_index(tail_old.value(), true, &item_index, &old_item);
if (tail_old == tail_->load()) {
if (found_idx) {
const Item new_item(item, old_item.tag() + 1);
if (queue_[item_index].swap(old_item, new_item)) {
if (committed(tail_old, new_item, item_index)) {
return true;
}
}
} else {
if (queue_full(head_old, tail_old)) {
if (segment_not_empty(head_old) &&
(head_old.value() == head_->load().value())) {
return false;
}
advance_head(head_old);
}
advance_tail(tail_old);
}
}
}
}
} // namespace scal
#endif // SCAL_DATASTRUCTURES_BOUNDEDSIZE_KFIFO_H_