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openmpi/ompi/class/ompi_circular_buffer_fifo.h
Galen Shipman d932cfd342 merge of rcache work into the trunk.. lotsa fun ;-).. 
I regression tested before the merge, I will regression test tonight and
correct issues that might have crept in. 

This commit was SVN r7329.
2005-09-12 22:28:23 +00:00

737 строки
21 KiB
C
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/*
* Copyright (c) 2004-2005 The Trustees of Indiana University.
* All rights reserved.
* Copyright (c) 2004-2005 The Trustees of the University of Tennessee.
* All rights reserved.
* Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
* University of Stuttgart. All rights reserved.
* Copyright (c) 2004-2005 The Regents of the University of California.
* All rights reserved.
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*/
#ifndef _OMPI_CIRCULAR_BUFFER_FIFO
#define _OMPI_CIRCULAR_BUFFER_FIFO
#include "ompi/include/constants.h"
#include "include/sys/cache.h"
#include "include/sys/atomic.h"
#include "mca/mpool/mpool.h"
#include "opal/util/pow2.h"
/** @file
*
* This defines a set of functions to create, and manipulate a FIFO
* set up in a circular buffer. FIFO elements are assumed to be
* pointers. Pointers are written to the head, and read from the
* tail. For thread safety, a spin lock is provided in the
* ompi_cb_fifo_ctl_t structure, but it's use must be managed by
* the calling routines - this is not by these set of routines.
* Queues are addressed relative to an offset from the base of
* a memory pool, in this way, different processes with different
* base addresses can access these queue at the same time.
*/
/* error code */
#define OMPI_CB_ERROR -1
#define OMPI_CB_FREE (void *)-2
#define OMPI_CB_RESERVED (void *)-3
#define OMPI_CB_NULL (void *)-4
/*
* Structure used to keep track of the fifo status
*/
struct ompi_cb_fifo_ctl_t {
/* spin-lock for access control */
opal_atomic_lock_t lock;
/* current queue index */
volatile int fifo_index;
/* number of entries that have been used, but not invalidated. used
* for lazy resource reclamation */
volatile int num_to_clear;
};
typedef struct ompi_cb_fifo_ctl_t ompi_cb_fifo_ctl_t;
/* data structure used to describe the fifo */
struct ompi_cb_fifo_t {
/* size of fifo */
int size;
/* frequency of lazy free */
int lazy_free_frequency;
/* fifo memory locality index */
int fifo_memory_locality_index;
/* head memory locality index */
int head_memory_locality_index;
/* tail memory locality index */
int tail_memory_locality_index;
/* head of queue - where next entry will be written */
ompi_cb_fifo_ctl_t *head;
/* tail of queue - next element to read */
ompi_cb_fifo_ctl_t *tail;
/* mask - to handle wrap around */
unsigned int mask;
/* circular buffer array */
volatile void **queue;
};
typedef struct ompi_cb_fifo_t ompi_cb_fifo_t;
/**
* Initialize a fifo
*
* @param size_of_fifo Length of fifo array (IN)
*
* @param fifo_memory_locality_index Locality index to apply to
* the fifo array. Not currently
* in use (IN)
*
* @param tail_memory_locality_index Locality index to apply to the
* head control structure. Not
* currently in use (IN)
*
* @param tail_memory_locality_index Locality index to apply to the
* tail control structure. Not
* currently in use (IN)
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @param memory_allocator Pointer to the memory allocator to use
* to allocate memory for this fifo. (IN)
*
* @returncode Error code
*
*/
static inline int ompi_cb_fifo_init(int size_of_fifo, int lazy_free_freq,
int fifo_memory_locality_index, int head_memory_locality_index,
int tail_memory_locality_index, ompi_cb_fifo_t *fifo,
mca_mpool_base_module_t *memory_allocator)
{
int errorCode = OMPI_SUCCESS,i;
size_t len_to_allocate;
/* verify that size is power of 2, and greatter that 0 - if not,
* round up */
if ( 0 >= size_of_fifo) {
return OMPI_ERROR;
}
/* set fifo size */
fifo->size = opal_round_up_to_nearest_pow2(size_of_fifo);
/* set lazy free frequence */
if( ( 0 >= lazy_free_freq ) ||
( lazy_free_freq > fifo->size) ) {
return OMPI_ERROR;
}
fifo->lazy_free_frequency=lazy_free_freq;
/* this will be used to mask off the higher order bits,
* and use the & operator for the wrap-around */
fifo->mask = (fifo->size - 1);
/* allocate fifo array */
len_to_allocate = sizeof(void *) * fifo->size;
fifo->queue=memory_allocator->mpool_alloc(memory_allocator, len_to_allocate,CACHE_LINE_SIZE, 0, NULL);
if ( NULL == fifo->queue) {
return OMPI_ERR_OUT_OF_RESOURCE;
}
/* initialize the queue entries */
for (i = 0; i < fifo->size; i++) {
fifo->queue[i] = OMPI_CB_FREE;
}
/* change address be relative to the base of the memory segment */
fifo->queue=(volatile void **)( (char *)(fifo->queue) -
(size_t)(memory_allocator->mpool_base(memory_allocator)));
/* allocate head control structure */
len_to_allocate = sizeof(ompi_cb_fifo_ctl_t);
fifo->head=memory_allocator->mpool_alloc(memory_allocator, len_to_allocate,CACHE_LINE_SIZE, 0, NULL);
if ( NULL == fifo->head) {
return OMPI_ERR_OUT_OF_RESOURCE;
}
/* initialize the head structure */
opal_atomic_unlock(&(fifo->head->lock));
fifo->head->fifo_index=0;
fifo->head->num_to_clear=0;
/* allocate tail control structure */
len_to_allocate = sizeof(ompi_cb_fifo_ctl_t);
fifo->tail=memory_allocator->mpool_alloc(memory_allocator, len_to_allocate,CACHE_LINE_SIZE, 0, NULL);
if ( NULL == fifo->tail) {
return OMPI_ERR_OUT_OF_RESOURCE;
}
/* initialize the head structure */
opal_atomic_unlock(&(fifo->tail->lock));
fifo->tail->fifo_index=0;
fifo->tail->num_to_clear=0;
/* set memory locality indecies */
fifo->fifo_memory_locality_index=fifo_memory_locality_index;
fifo->head_memory_locality_index=head_memory_locality_index;
fifo->tail_memory_locality_index=tail_memory_locality_index;
/* change addresses be relative to the base of the memory segment */
fifo->head=(ompi_cb_fifo_ctl_t *)( (char *)(fifo->head) -
(size_t)(memory_allocator->mpool_base(memory_allocator)));
fifo->tail=(ompi_cb_fifo_ctl_t *)( (char *)(fifo->tail) -
(size_t)(memory_allocator->mpool_base(memory_allocator)));
/* return */
return errorCode;
}
/**
* function to cleanup the fifo
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @param memory_allocator Pointer to the memory allocator to use
* to allocate memory for this fifo. (IN)
*
*/
static inline int ompi_cb_fifo_free( ompi_cb_fifo_t *fifo,
mca_mpool_base_module_t *memory_allocator)
{
int errorCode = OMPI_SUCCESS;
char *ptr;
/* make sure null fifo is not passed in */
if ( NULL == fifo) {
return OMPI_ERROR;
}
/* free fifo array */
if( OMPI_CB_NULL != fifo->queue ){
ptr=(char *)(fifo->queue)+(size_t)(memory_allocator->mpool_base(memory_allocator));
memory_allocator->mpool_free(memory_allocator, ptr, NULL);
fifo->queue=OMPI_CB_NULL;
}
/* free head control structure */
if( OMPI_CB_NULL != fifo->head) {
ptr=(char *)(fifo->head)+(size_t)(memory_allocator->mpool_base(memory_allocator));
memory_allocator->mpool_free(memory_allocator, ptr, NULL);
fifo->head=OMPI_CB_NULL;
}
/* free tail control structure */
if( OMPI_CB_NULL != fifo->tail) {
ptr=(char *)(fifo->tail)+(size_t)(memory_allocator->mpool_base(memory_allocator));
memory_allocator->mpool_free(memory_allocator, ptr, NULL);
fifo->tail=OMPI_CB_NULL;
}
/* return */
return errorCode;
}
/**
* Write pointer to the specified slot
*
* @param slot Slot index (IN)
*
* @param data Pointer value to write in specified slot (IN)
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @returncode Slot index to which data is written
*
*/
static inline int ompi_cb_fifo_write_to_slot(int slot, void* data,
ompi_cb_fifo_t *fifo, size_t offset)
{
void **ptr;
int wrote_to_slot = OMPI_CB_ERROR;
/* make sure that this slot is already reserved */
ptr=(void **)( (char *)(fifo->queue) + (size_t)offset);
if (ptr[slot] == OMPI_CB_RESERVED ) {
ptr[slot] = data;
return slot;
} else {
return wrote_to_slot;
}
}
/**
* Try to write pointer to the head of the queue
*
* @param data Pointer value to write in specified slot (IN)
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @returncode Slot index to which data is written
*
*/
static inline int ompi_cb_fifo_write_to_head(void *data, ompi_cb_fifo_t
*fifo, size_t offset)
{
void **ptr;
ompi_cb_fifo_ctl_t *h_ptr;
int slot = OMPI_CB_ERROR, index;
h_ptr=(ompi_cb_fifo_ctl_t *) ((char *)(fifo->head) +
(size_t)offset);
index = h_ptr->fifo_index;
/* make sure the head is pointing at a free element - avoid wrap
* around */
ptr=(void **)( (char *)(fifo->queue) + (size_t)offset);
if (ptr[index] == OMPI_CB_FREE) {
slot = index;
ptr[slot] = data;
(h_ptr->fifo_index)++;
(h_ptr->fifo_index) &= fifo->mask;
}
/* return */
return slot;
}
/**
* Reserve slot in the fifo array
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @returncode Slot index to which data is written
*
* @returncode OMPI_CB_ERROR failed to allocate index
*
*/
static inline int ompi_cb_fifo_get_slot(ompi_cb_fifo_t *fifo,
size_t offset)
{
void **ptr;
ompi_cb_fifo_ctl_t *h_ptr;
int return_value = OMPI_CB_ERROR,index;
h_ptr=(ompi_cb_fifo_ctl_t *)( (char *)(fifo->head) + (size_t)offset);
ptr=(void **)( (char *)(fifo->queue) + (size_t)offset);
index = h_ptr->fifo_index;
/* try and reserve slot */
if ( OMPI_CB_FREE == ptr[index] ) {
ptr[index] = OMPI_CB_RESERVED;
return_value = index;
(h_ptr->fifo_index)++;
(h_ptr->fifo_index) &= fifo->mask;
}
/* return */
return return_value;
}
/**
* Try to read pointer from the tail of the queue
*
* @param data Pointer to where data was be written (OUT)
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @param flush_entries_read force the lazy free to happen (IN)
*
* @param queue_empty checks to see if the fifo is empty, but only if
* flush_entries_read is set (OUT)
*
* @returncode Slot index to which data is written
*
*/
static inline void *ompi_cb_fifo_read_from_tail(ompi_cb_fifo_t *fifo,
bool flush_entries_read, bool *queue_empty, size_t offset)
{
int index = 0,clearIndex, i;
void **q_ptr;
ompi_cb_fifo_ctl_t *h_ptr, *t_ptr;
void *read_from_tail = (void *)OMPI_CB_ERROR;
*queue_empty=false;
h_ptr=(ompi_cb_fifo_ctl_t *)( (char *)(fifo->head) + (size_t)offset);
t_ptr=(ompi_cb_fifo_ctl_t *)( (char *)(fifo->tail) + (size_t)offset);
q_ptr=(void **)( (char *)(fifo->queue) + (size_t)offset);
/* check to see that the data is valid */
if ((q_ptr[t_ptr->fifo_index] == OMPI_CB_FREE) ||
(q_ptr[t_ptr->fifo_index] == OMPI_CB_RESERVED))
{
return (void *)OMPI_CB_FREE;
}
/* set return data */
index = t_ptr->fifo_index;
read_from_tail = (void *)q_ptr[index];
t_ptr->num_to_clear++;
/* increment counter for later lazy free */
(t_ptr->fifo_index)++;
(t_ptr->fifo_index) &= fifo->mask;
/* check to see if time to do a lazy free of queue slots */
if ( (t_ptr->num_to_clear == fifo->lazy_free_frequency) ||
flush_entries_read ) {
clearIndex = index - t_ptr->num_to_clear + 1;
clearIndex &= fifo->mask;
for (i = 0; i < t_ptr->num_to_clear; i++) {
q_ptr[clearIndex] = OMPI_CB_FREE;
clearIndex++;
clearIndex &= fifo->mask;
}
t_ptr->num_to_clear = 0;
/* check to see if queue is empty */
if( flush_entries_read &&
(t_ptr->fifo_index == h_ptr->fifo_index) ) {
*queue_empty=true;
}
}
/* return */
return read_from_tail;
}
/**
* Return the fifo size
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @returncode fifo size
*
*/
static inline int ompi_cb_fifo_size(ompi_cb_fifo_t *fifo) {
return fifo->size;
}
/**
* Initialize a fifo
*
* @param size_of_fifo Length of fifo array (IN)
*
* @param fifo_memory_locality_index Locality index to apply to
* the fifo array. Not currently
* in use (IN)
*
* @param tail_memory_locality_index Locality index to apply to the
* head control structure. Not
* currently in use (IN)
*
* @param tail_memory_locality_index Locality index to apply to the
* tail control structure. Not
* currently in use (IN)
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @param memory_allocator Pointer to the memory allocator to use
* to allocate memory for this fifo. (IN)
*
* @returncode Error code
*
*/
static inline int ompi_cb_fifo_init_same_base_addr(int size_of_fifo,
int lazy_free_freq, int fifo_memory_locality_index,
int head_memory_locality_index, int tail_memory_locality_index,
ompi_cb_fifo_t *fifo, mca_mpool_base_module_t *memory_allocator)
{
int errorCode = OMPI_SUCCESS,i;
size_t len_to_allocate;
/* verify that size is power of 2, and greatter that 0 - if not,
* round up */
if ( 0 >= size_of_fifo) {
return OMPI_ERROR;
}
/* set fifo size */
fifo->size = opal_round_up_to_nearest_pow2(size_of_fifo);
/* set lazy free frequence */
if( ( 0 >= lazy_free_freq ) ||
( lazy_free_freq > fifo->size) ) {
return OMPI_ERROR;
}
fifo->lazy_free_frequency=lazy_free_freq;
/* this will be used to mask off the higher order bits,
* and use the & operator for the wrap-around */
fifo->mask = (fifo->size - 1);
/* allocate fifo array */
len_to_allocate = sizeof(void *) * fifo->size;
fifo->queue=memory_allocator->mpool_alloc(memory_allocator, len_to_allocate,CACHE_LINE_SIZE, 0, NULL);
if ( NULL == fifo->queue) {
return OMPI_ERR_OUT_OF_RESOURCE;
}
/* initialize the queue entries */
for (i = 0; i < fifo->size; i++) {
fifo->queue[i] = OMPI_CB_FREE;
}
/* allocate head control structure */
len_to_allocate = sizeof(ompi_cb_fifo_ctl_t);
fifo->head=memory_allocator->mpool_alloc(memory_allocator, len_to_allocate,CACHE_LINE_SIZE, 0, NULL);
if ( NULL == fifo->head) {
return OMPI_ERR_OUT_OF_RESOURCE;
}
/* initialize the head structure */
opal_atomic_unlock(&(fifo->head->lock));
fifo->head->fifo_index=0;
fifo->head->num_to_clear=0;
/* allocate tail control structure */
len_to_allocate = sizeof(ompi_cb_fifo_ctl_t);
fifo->tail=memory_allocator->mpool_alloc(memory_allocator, len_to_allocate,CACHE_LINE_SIZE, 0, NULL);
if ( NULL == fifo->tail) {
return OMPI_ERR_OUT_OF_RESOURCE;
}
/* initialize the head structure */
opal_atomic_unlock(&(fifo->tail->lock));
fifo->tail->fifo_index=0;
fifo->tail->num_to_clear=0;
/* set memory locality indecies */
fifo->fifo_memory_locality_index=fifo_memory_locality_index;
fifo->head_memory_locality_index=head_memory_locality_index;
fifo->tail_memory_locality_index=tail_memory_locality_index;
/* return */
return errorCode;
}
/**
* function to cleanup the fifo
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @param memory_allocator Pointer to the memory allocator to use
* to allocate memory for this fifo. (IN)
*
*/
static inline int ompi_cb_fifo_free_same_base_addr( ompi_cb_fifo_t *fifo,
mca_mpool_base_module_t *memory_allocator)
{
int errorCode = OMPI_SUCCESS;
char *ptr;
/* make sure null fifo is not passed in */
if ( NULL == fifo) {
return OMPI_ERROR;
}
/* free fifo array */
if( OMPI_CB_NULL != fifo->head ){
ptr=(char *)(fifo->queue);
memory_allocator->mpool_free(memory_allocator, ptr, NULL);
fifo->queue=OMPI_CB_NULL;
}
/* free head control structure */
if( OMPI_CB_NULL != fifo->head) {
ptr=(char *)(fifo->head);
memory_allocator->mpool_free(memory_allocator, ptr, NULL);
fifo->head=OMPI_CB_NULL;
}
/* free tail control structure */
if( OMPI_CB_NULL != fifo->tail) {
ptr=(char *)(fifo->tail);
memory_allocator->mpool_free(memory_allocator, ptr, NULL);
fifo->tail=OMPI_CB_NULL;
}
/* return */
return errorCode;
}
/**
* Write pointer to the specified slot
*
* @param slot Slot index (IN)
*
* @param data Pointer value to write in specified slot (IN)
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @returncode Slot index to which data is written
*
*/
static inline int ompi_cb_fifo_write_to_slot_same_base_addr(int slot, void* data,
ompi_cb_fifo_t *fifo)
{
volatile void **ptr;
int wrote_to_slot = OMPI_CB_ERROR;
/* make sure that this slot is already reserved */
ptr=fifo->queue;
if (ptr[slot] == OMPI_CB_RESERVED ) {
ptr[slot] = data;
return slot;
} else {
return wrote_to_slot;
}
}
/**
* Try to write pointer to the head of the queue
*
* @param data Pointer value to write in specified slot (IN)
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @returncode Slot index to which data is written
*
*/
static inline int ompi_cb_fifo_write_to_head_same_base_addr(void *data, ompi_cb_fifo_t *fifo)
{
volatile void **ptr;
ompi_cb_fifo_ctl_t *h_ptr;
int slot = OMPI_CB_ERROR, index;
h_ptr=fifo->head;
index = h_ptr->fifo_index;
/* make sure the head is pointing at a free element */
ptr=fifo->queue;
if (ptr[index] == OMPI_CB_FREE) {
slot = index;
ptr[slot] = data;
(h_ptr->fifo_index)++;
/* wrap around */
(h_ptr->fifo_index) &= fifo->mask;
}
/* return */
return slot;
}
/**
* Reserve slot in the fifo array
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @returncode Slot index to which data is written
*
* @returncode OMPI_CB_ERROR failed to allocate index
*
*/
static inline int ompi_cb_fifo_get_slot_same_base_addr(ompi_cb_fifo_t *fifo)
{
volatile void **ptr;
ompi_cb_fifo_ctl_t *h_ptr;
int return_value = OMPI_CB_ERROR,index;
h_ptr=fifo->head;
ptr=fifo->queue;
index = h_ptr->fifo_index;
/* try and reserve slot */
if ( OMPI_CB_FREE == ptr[index] ) {
ptr[index] = OMPI_CB_RESERVED;
return_value = index;
(h_ptr->fifo_index)++;
(h_ptr->fifo_index) &= fifo->mask;
}
/* return */
return return_value;
}
/**
* Try to read pointer from the tail of the queue
*
* @param data Pointer to where data was be written (OUT)
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @param flush_entries_read force the lazy free to happen (IN)
*
* @param queue_empty checks to see if the fifo is empty, but only if
* flush_entries_read is set (OUT)
*
* @returncode Slot index to which data is written
*
*/
static inline void *ompi_cb_fifo_read_from_tail_same_base_addr(
ompi_cb_fifo_t *fifo,
bool flush_entries_read, bool *queue_empty)
{
int index = 0,clearIndex, i;
volatile void **q_ptr;
ompi_cb_fifo_ctl_t *h_ptr, *t_ptr;
void *read_from_tail = (void *)OMPI_CB_ERROR;
*queue_empty=false;
h_ptr=fifo->head;
t_ptr=fifo->tail;
q_ptr=fifo->queue;
/* check to see that the data is valid */
if ((q_ptr[t_ptr->fifo_index] == OMPI_CB_FREE) ||
(q_ptr[t_ptr->fifo_index] == OMPI_CB_RESERVED)) {
read_from_tail=(void *)OMPI_CB_FREE;
goto CLEANUP;
}
/* set return data */
index = t_ptr->fifo_index;
read_from_tail = (void *)q_ptr[index];
t_ptr->num_to_clear++;
/* increment counter for later lazy free */
(t_ptr->fifo_index)++;
(t_ptr->fifo_index) &= fifo->mask;
/* check to see if time to do a lazy free of queue slots */
if ( (t_ptr->num_to_clear == fifo->lazy_free_frequency) ||
flush_entries_read ) {
clearIndex = index - t_ptr->num_to_clear + 1;
clearIndex &= fifo->mask;
for (i = 0; i < t_ptr->num_to_clear; i++) {
q_ptr[clearIndex] = OMPI_CB_FREE;
clearIndex++;
clearIndex &= fifo->mask;
}
t_ptr->num_to_clear = 0;
/* check to see if queue is empty */
if( flush_entries_read &&
(t_ptr->fifo_index == h_ptr->fifo_index) ) {
*queue_empty=true;
}
}
CLEANUP:
return read_from_tail;
}
#endif /* !_OMPI_CIRCULAR_BUFFER_FIFO */
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