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openmpi/ompi/class/ompi_fifo.h

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/*
* Copyright (c) 2004-2005 The Trustees of Indiana University and Indiana
* University Research and Technology
* Corporation. All rights reserved.
* Copyright (c) 2004-2006 The University of Tennessee and The University
* of Tennessee Research Foundation. 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_FIFO
#define _OMPI_FIFO
#include "ompi/constants.h"
#include "opal/sys/cache.h"
#include "opal/sys/atomic.h"
#include "ompi/mca/mpool/mpool.h"
#include "ompi/class/ompi_circular_buffer_fifo.h"
/** @file
*
* This defines a set of functions to create, and manipulate a FIFO
* implemented as a link list of circular buffer FIFO's. 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. When a write to a circular buffer queue will overflow
* that queue, the next circular buffer queue if the link list is
* used, if it is empty, or a new one is inserted into the list.
*
* This set of routines is currently exclusively used by the sm btl,
* and has been tailored to meet its needs (i.e., it is probably not
* suitable as a general purpose fifo).
*
* Before describing any further, a note about mmap() is in order.
* mmap() is used to create/attach shared memory segments to a
* process. It is used by OMPI to manage shared memory.
* Specifically, each process ends up calling mmap() to create or
* attach shared memory; the end result is that multiple processes
* have the same shared memory segment attached to their process.
* This shared memory is therefore used here in the fifo code.
*
* However, it is important to note that when attaching the same
* shared memory segment to multiple processes, mmap() does *not* need
* to return the same virtual address to the beginning of the shared
* memory segment to each process. That is, the virtual address
* returned in each process will point to the same shared memory
* segment as all others, but its virtual address value may be
* different. Specifically, process A may get the value X back from
* mmap(), while process B, who attached the same shared memory
* segment as process A, may get back the value Y from mmap().
* Process C may attach the same shared memory segment and get back
* value X from mmap(). This is perfectly legal mmap() behavior.
*
* As such, our code -- including this fifo code -- needs to be able
* to handle the cases where the base address is the same and the
* cases where it is different.
*
* There are four main interface functions:
*
* ompi_fifo_init_same_base_addr(): create a fifo for the case where
* the creating process shares a common shared memory segment base
* address.
*
* ompi_fifo_write_to_head_same_base_addr(): write a value to the head
* of the fifo for the case where the shared memory segment virtual
* address is the same as the process who created the fifo.
*
* ompi_fifo_read_from_tail_same_base_addr(): read a value from the
* tail of the fifo for the case where the shared memory segment
* virtual address is the same as the process who created the fifo.
*
* ompi_fifo_read_from_tail(): read a value from the tail of the fifo
* for the case where the shared memory segment virtual address is
* *not* the same as the process who created the fifo.
*
* The data structures used in these fifos are carefully structured to
* be lockless, even when used in shared memory. However, this is
* predicated upon there being only exactly *ONE* concurrent writer
* and *ONE* concurrent reader (in terms of the sm btl, two fifos are
* established between each process pair; one for data flowing A->B
* and one for data flowing B->A). Hence, the writer always looks at
* the "head" and the reader always looks at the "tail."
*
* The general scheme of the fifo is that this class is an upper-level
* manager for the ompi_circular_buffer_fifo_t class. When an
* ompi_fifo_t instance is created, it creates an
* ompi_circular_buffer_fifo_t. Items can then be put into the fifo
* until the circular buffer fills up (i.e., items have not been
* removed from the circular buffer, so it gets full). The
* ompi_fifo_t class will manage this case and create another
* circular_buffer and start putting items in there. This can
* continue indefinitely; the ompi_fifo_t class will create a linked
* list of circular buffers in order to create storage for any items
* that need to be put in the fifo.
*
* The tail will then read from these circular buffers in order,
* draining them as it goes.
*
* The linked list of circular buffers is created in a circle, so if
* you have N circular buffers, the fill pattern will essentially go
* in a circle (assuming that the reader is dutifully reading/draining
* behind the writer). Yes, this means that we have a ring of
* circular buffers. A single circular buffer is treated as a
* standalone entitle, a reader/writer pair can utilize it
* indefinitely; they will never move on to the next circular buffer
* unless the writer gets so far ahead of the reader that the current
* circular buffer fills up and the writer moves on to the next
* circular buffer. In this case, the reader will eventually drain
* the current circular buffer and then move on to the next circular
* buffer (and assumedly eventually catch up to the writer).
*
* The natural question of "why bother doing this instead of just
* having an array of pointers that you realloc?" arises. The intent
* with this class is to have a lockless structure -- using realloc,
* by definition, means that you would have to lock every single
* access to the array to ensure that it doesn't get realloc'ed from
* underneath you. This is definitely something we want to avoid for
* performance reasons.
*
* Hence, once you get your head wrapped around this scheme, it
* actually does make sense (and give good performance).
*
********************************* NOTE *******************************
*
* Although the scheme is designed to be lockless, there is currently
* one lock used in this scheme. There is a nasty race condition
* between multiple processes that if the writer fills up a circular
* buffer before anything this read, it can make the decision to
* create a new circular buffer (because that one is full). However,
* if, at the same time, the reader takes over -- after the decision
* has been made to make a new circular buffer, and after some [but
* not all] of the data fields are updated to reflect this -- the
* reader can drain the entire current circular buffer, obviating the
* need to make a new circular buffer (because there's now space
* available in the current one). The reader will then update some
* data fields in the fifo.
*
* This can lead to a fifo management consistency error -- the reader
* thinks it is advancing to the next circular bufer but it really
* ends up back on the same circular buffer (because the writer had
* not updated the "next cb" field yet). The reader is then stuck in
* a cb where nothing will arrive until the writer loops all the way
* around (i.e., through all other existing circular buffers) and
* starts writing to the circular buffer where the reader is waiting.
* This effectively means that the reader will miss a lot of messages.
*
* So we had to add a lock to protect this -- when the writer decides
* to make a new circular buffer and when the reader decides to move
* to the new circular buffer. It is a rather coarse-grained lock; it
* convers a relatively large chunk of code in the writing_to_head
* function, but, interestingly enough, this seems to create *better*
* performance for sending large messages via shared memory (i.e.,
* netpipe graphs with and without this lock show that using the lock
* gives better overall bandwidth for large messages). We do lose a
* bit of overall bandwidth for mid-range message sizes, though.
*
* We feel that this lock can probably be eventually removed from the
* implementation; we recognized this race condition and ran out of
* time to fix is properly (i.e., in a lockless way). As such, we
* employed a lock to serialize the access and protect it that way.
* This issue should be revisited someday to remove the lock.
*
* See the notes in the writer function for more details on the lock.
*/
/*
* Structure by the the ompi_fifo routines to keep track of some
* extra queue information not needed by the ompi_cb_fifo routines.
*/
struct ompi_cb_fifo_wrapper_t {
/* pointer to ompi_cb_fifo_ctl_t structure in use */
ompi_cb_fifo_t cb_fifo;
/* pointer to next ompi_cb_fifo_ctl_t structure. This is always
stored as an absolute address. */
volatile struct ompi_cb_fifo_wrapper_t *next_fifo_wrapper;
/* flag indicating if cb_fifo has over flown - need this to force
* release of entries already read */
volatile bool cb_overflow;
};
typedef struct ompi_cb_fifo_wrapper_t ompi_cb_fifo_wrapper_t;
/* data structure used to describe the fifo */
struct ompi_fifo_t {
/* pointer to head (write) ompi_cb_fifo_t structure. This is
always stored as an absolute address. */
volatile ompi_cb_fifo_wrapper_t *head;
/* pointer to tail (read) ompi_cb_fifo_t structure. This is
always stored as an absolute address. */
volatile ompi_cb_fifo_wrapper_t *tail;
/* locks for thread synchronization */
opal_atomic_lock_t head_lock;
opal_atomic_lock_t tail_lock;
/* locks for multi-process synchronization */
opal_atomic_lock_t fifo_lock;
};
typedef struct ompi_fifo_t ompi_fifo_t;
/*
* structure used to track which circular buffer slot to write to
*/
struct cb_slot_t {
/* pointer to circular buffer fifo structures */
ompi_cb_fifo_t *cb;
/* index in circular buffer */
int index;
};
typedef struct cb_slot_t cb_slot_t;
/**
* Initialize a fifo
*
* @param size_of_cb_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 head_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_fifo_init_same_base_addr(int size_of_cb_fifo,
int lazy_free_freq, int fifo_memory_locality_index,
int head_memory_locality_index, int tail_memory_locality_index,
ompi_fifo_t *fifo, mca_mpool_base_module_t *memory_allocator)
{
int error_code=OMPI_SUCCESS;
size_t len_to_allocate;
/* allocate head ompi_cb_fifo_t structure */
len_to_allocate=sizeof(ompi_cb_fifo_wrapper_t);
fifo->head = (ompi_cb_fifo_wrapper_t*)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 circular buffer fifo head structure */
error_code=ompi_cb_fifo_init_same_base_addr(size_of_cb_fifo,
lazy_free_freq, fifo_memory_locality_index,
head_memory_locality_index, tail_memory_locality_index,
(ompi_cb_fifo_t *)&(fifo->head->cb_fifo),
memory_allocator);
if ( OMPI_SUCCESS != error_code ) {
return error_code;
}
/* finish head initialization */
opal_atomic_init(&(fifo->fifo_lock), OPAL_ATOMIC_UNLOCKED);
fifo->head->next_fifo_wrapper = fifo->head;
fifo->head->cb_overflow=false; /* no attempt to overflow the queue */
/* set the tail */
fifo->tail=fifo->head;
/* return */
return error_code;
}
/**
* 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_fifo_write_to_head_same_base_addr(void *data,
ompi_fifo_t *fifo, mca_mpool_base_module_t *fifo_allocator)
{
int error_code;
size_t len_to_allocate;
ompi_cb_fifo_wrapper_t *next_ff;
/* attempt to write data to head ompi_fifo_cb_fifo_t */
error_code=ompi_cb_fifo_write_to_head_same_base_addr(data,
(ompi_cb_fifo_t *)&(fifo->head->cb_fifo));
/* If the queue is full, create a new circular buffer and put the
data in it. */
if( OMPI_CB_ERROR == error_code ) {
/* NOTE: This is the lock described in the top-level comment
in this file. There are corresponding uses of this lock in
both of the read routines. We need to protect this whole
section -- setting cb_overflow to true through setting the
next_fifo_wrapper to the next circular buffer. It is
likely possible to do this in a finer grain; indeed, it is
likely that we can get rid of this lock altogther, but it
will take some refactoring to make the data updates
safe. */
opal_atomic_lock(&(fifo->fifo_lock));
/* mark queue as overflown */
fifo->head->cb_overflow=true;
/* see if next queue is available - while the next queue
* has not been emptied, it will be marked as overflowen*/
next_ff=(ompi_cb_fifo_wrapper_t *)fifo->head->next_fifo_wrapper;
/* if next queue not available, allocate new queue */
if (next_ff->cb_overflow) {
/* allocate head ompi_cb_fifo_t structure */
len_to_allocate=sizeof(ompi_cb_fifo_wrapper_t);
next_ff = (ompi_cb_fifo_wrapper_t*)fifo_allocator->mpool_alloc
(fifo_allocator, len_to_allocate,CACHE_LINE_SIZE, 0, NULL);
if ( NULL == next_ff) {
opal_atomic_unlock(&(fifo->fifo_lock));
return OMPI_ERR_OUT_OF_RESOURCE;
}
/* initialize the circular buffer fifo head structure */
error_code=ompi_cb_fifo_init_same_base_addr(
fifo->head->cb_fifo.size,
fifo->head->cb_fifo.lazy_free_frequency,
fifo->head->cb_fifo.fifo_memory_locality_index,
fifo->head->cb_fifo.head_memory_locality_index,
fifo->head->cb_fifo.tail_memory_locality_index,
&(next_ff->cb_fifo),
fifo_allocator);
if ( OMPI_SUCCESS != error_code ) {
opal_atomic_unlock(&(fifo->fifo_lock));
return error_code;
}
/* finish new element initialization */
next_ff->next_fifo_wrapper=fifo->head->next_fifo_wrapper; /* only one element in the link list */
next_ff->cb_overflow=false; /* no attempt to overflow the queue */
fifo->head->next_fifo_wrapper=next_ff;
}
/* reset head pointer */
fifo->head=next_ff;
opal_atomic_unlock(&(fifo->fifo_lock));
/* write data to new head structure */
error_code=ompi_cb_fifo_write_to_head_same_base_addr(data,
(ompi_cb_fifo_t *)&(fifo->head->cb_fifo));
if( OMPI_CB_ERROR == error_code ) {
return error_code;
}
}
return error_code;
}
/**
* Try to read pointer from the tail of the queue
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @returncode Pointer - OMPI_CB_FREE indicates no data to read
*
*/
static inline
void *ompi_fifo_read_from_tail_same_base_addr( ompi_fifo_t *fifo)
{
/* local parameters */
void *return_value;
bool queue_empty, flush_entries_read;
ompi_cb_fifo_t *cb_fifo;
/* get next element */
cb_fifo=(ompi_cb_fifo_t *)&(fifo->tail->cb_fifo);
flush_entries_read=fifo->tail->cb_overflow;
return_value = ompi_cb_fifo_read_from_tail_same_base_addr( cb_fifo,
flush_entries_read,
&queue_empty);
/* check to see if need to move on to next cb_fifo in the link list */
if( queue_empty ) {
/* queue_emptied - move on to next element in fifo */
/* See the big comment at the top of this file about this
lock. */
opal_atomic_lock(&(fifo->fifo_lock));
fifo->tail->cb_overflow=false;
fifo->tail=fifo->tail->next_fifo_wrapper;
opal_atomic_unlock(&(fifo->fifo_lock));
}
return return_value;
}
/**
* Try to read pointer from the tail of the queue, and the base
* pointer is different so we must convert.
*
* @param fifo Pointer to data structure defining this fifo (IN)
*
* @param offset Offset relative to base of the memory segement (IN)
*
* @returncode Pointer - OMPI_CB_FREE indicates no data to read
*
*/
static inline void *ompi_fifo_read_from_tail(ompi_fifo_t *fifo,
ptrdiff_t offset)
{
/* local parameters */
void *return_value;
bool queue_empty;
volatile ompi_cb_fifo_wrapper_t *t_ptr;
t_ptr = (volatile ompi_cb_fifo_wrapper_t *)
(((char*) fifo->tail) + offset);
/* get next element */
return_value=ompi_cb_fifo_read_from_tail(
(ompi_cb_fifo_t *)&(t_ptr->cb_fifo),
t_ptr->cb_overflow, &queue_empty, offset);
/* check to see if need to move on to next cb_fifo in the link list */
if( queue_empty ) {
/* queue_emptied - move on to next element in fifo */
/* See the big comment at the top of this file about this
lock. */
opal_atomic_lock(&(fifo->fifo_lock));
t_ptr->cb_overflow = false;
fifo->tail = t_ptr->next_fifo_wrapper;
opal_atomic_unlock(&(fifo->fifo_lock));
}
/* return */
return return_value;
}
#endif /* !_OMPI_FIFO */