coreboot-libre-fam15h-rdimm/3rdparty/chromeec/common/queue.c

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2024-03-04 11:14:53 +01:00
/* Copyright 2012 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*
* Queue data structure implementation.
*/
#include "queue.h"
#include "util.h"
static void queue_action_null(struct queue_policy const *policy, size_t count)
{
}
struct queue_policy const queue_policy_null = {
.add = queue_action_null,
.remove = queue_action_null,
};
void queue_init(struct queue const *q)
{
ASSERT(q->policy);
ASSERT(q->policy->add);
ASSERT(q->policy->remove);
q->state->head = 0;
q->state->tail = 0;
}
int queue_is_empty(struct queue const *q)
{
return q->state->head == q->state->tail;
}
size_t queue_count(struct queue const *q)
{
return q->state->tail - q->state->head;
}
size_t queue_space(struct queue const *q)
{
return q->buffer_units - queue_count(q);
}
int queue_is_full(struct queue const *q)
{
return (queue_space(q) == 0);
}
/*
* These pictures make the logic below clearer. The H and T markers are the
* head and tail indicies after they have been modded by the queue size. The
* Empty and Full states are disambiguated by looking at the pre-modded
* indicies.
*
* Empty: T
* T == H H
* |----------------|
*
* Normal: H T
* H < T |---******-------|
*
* Wrapped: T H
* T < H |***----------***|
*
* Full: T
* T == H H
* |****************|
*/
struct queue_chunk queue_get_write_chunk(struct queue const *q, size_t offset)
{
size_t head = q->state->head & q->buffer_units_mask;
size_t tail = (q->state->tail + offset) & q->buffer_units_mask;
size_t last = (tail < head) ? head : /* Wrapped */
q->buffer_units; /* Normal | Empty */
/* Make sure that the offset doesn't exceed free space. */
if (queue_space(q) <= offset)
return ((struct queue_chunk) {
.count = 0,
.buffer = NULL,
});
return ((struct queue_chunk) {
.count = last - tail,
.buffer = q->buffer + (tail * q->unit_bytes),
});
}
struct queue_chunk queue_get_read_chunk(struct queue const *q)
{
size_t head = q->state->head & q->buffer_units_mask;
size_t tail = q->state->tail & q->buffer_units_mask;
size_t last = (queue_is_empty(q) ? head : /* Empty */
((head < tail) ? tail : /* Normal */
q->buffer_units)); /* Wrapped | Full */
return ((struct queue_chunk) {
.count = (last - head),
.buffer = q->buffer + (head * q->unit_bytes),
});
}
size_t queue_advance_head(struct queue const *q, size_t count)
{
size_t transfer = MIN(count, queue_count(q));
q->state->head += transfer;
q->policy->remove(q->policy, transfer);
return transfer;
}
size_t queue_advance_tail(struct queue const *q, size_t count)
{
size_t transfer = MIN(count, queue_space(q));
q->state->tail += transfer;
q->policy->add(q->policy, transfer);
return transfer;
}
size_t queue_add_unit(struct queue const *q, const void *src)
{
size_t tail = q->state->tail & q->buffer_units_mask;
if (queue_space(q) == 0)
return 0;
if (q->unit_bytes == 1)
q->buffer[tail] = *((uint8_t *) src);
else
memcpy(q->buffer + tail * q->unit_bytes, src, q->unit_bytes);
return queue_advance_tail(q, 1);
}
size_t queue_add_units(struct queue const *q, const void *src, size_t count)
{
return queue_add_memcpy(q, src, count, memcpy);
}
size_t queue_add_memcpy(struct queue const *q,
const void *src,
size_t count,
void *(*memcpy)(void *dest,
const void *src,
size_t n))
{
size_t transfer = MIN(count, queue_space(q));
size_t tail = q->state->tail & q->buffer_units_mask;
size_t first = MIN(transfer, q->buffer_units - tail);
memcpy(q->buffer + tail * q->unit_bytes,
src,
first * q->unit_bytes);
if (first < transfer)
memcpy(q->buffer,
((uint8_t const *) src) + first * q->unit_bytes,
(transfer - first) * q->unit_bytes);
return queue_advance_tail(q, transfer);
}
static void queue_read_safe(struct queue const *q,
void *dest,
size_t head,
size_t transfer,
void *(*memcpy)(void *dest,
const void *src,
size_t n))
{
size_t first = MIN(transfer, q->buffer_units - head);
memcpy(dest,
q->buffer + head * q->unit_bytes,
first * q->unit_bytes);
if (first < transfer)
memcpy(((uint8_t *) dest) + first * q->unit_bytes,
q->buffer,
(transfer - first) * q->unit_bytes);
}
size_t queue_remove_unit(struct queue const *q, void *dest)
{
size_t head = q->state->head & q->buffer_units_mask;
if (queue_count(q) == 0)
return 0;
if (q->unit_bytes == 1)
*((uint8_t *) dest) = q->buffer[head];
else
memcpy(dest, q->buffer + head * q->unit_bytes, q->unit_bytes);
return queue_advance_head(q, 1);
}
size_t queue_remove_units(struct queue const *q, void *dest, size_t count)
{
return queue_remove_memcpy(q, dest, count, memcpy);
}
size_t queue_remove_memcpy(struct queue const *q,
void *dest,
size_t count,
void *(*memcpy)(void *dest,
const void *src,
size_t n))
{
size_t transfer = MIN(count, queue_count(q));
size_t head = q->state->head & q->buffer_units_mask;
queue_read_safe(q, dest, head, transfer, memcpy);
return queue_advance_head(q, transfer);
}
size_t queue_peek_units(struct queue const *q,
void *dest,
size_t i,
size_t count)
{
return queue_peek_memcpy(q, dest, i, count, memcpy);
}
size_t queue_peek_memcpy(struct queue const *q,
void *dest,
size_t i,
size_t count,
void *(*memcpy)(void *dest,
const void *src,
size_t n))
{
size_t available = queue_count(q);
size_t transfer = MIN(count, available - i);
if (i < available) {
size_t head = (q->state->head + i) & q->buffer_units_mask;
queue_read_safe(q, dest, head, transfer, memcpy);
}
return transfer;
}