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openmpi/ompi/mca/btl/tcp/btl_tcp.c
Brian Barrett 27cea44a9c Fix a number of issues with the ompi_ptr_t: 
* Make sure that the pval always writes to the correct portion of the
    lval.  This only matters on 32 bit big endian machines.
  * On 32 bit machines when assigning to pval, the other 4 bytes of lval
    weren't being written, which could lead to bogus data

We use macros so that there aren't casts all over the code and the pval
assignment can occur to the correct 4 bytes.  Refs trac:587

This commit was SVN r12974.

The following Trac tickets were found above:
  Ticket 587 --> https://svn.open-mpi.org/trac/ompi/ticket/587
2007-01-03 19:47:48 +00:00

503 строки
15 KiB
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Исходник Ответственный История

/*
* 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 (c) 2006 Los Alamos National Security, LLC. All rights
* reserved.
*
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*/
#include "ompi_config.h"
#include <string.h>
#include "opal/util/output.h"
#include "opal/util/if.h"
#include "ompi/mca/pml/pml.h"
#include "ompi/mca/btl/btl.h"
#include "btl_tcp.h"
#include "btl_tcp_frag.h"
#include "btl_tcp_proc.h"
#include "btl_tcp_endpoint.h"
#include "ompi/datatype/convertor.h"
#include "ompi/datatype/datatype.h"
#include "ompi/mca/mpool/base/base.h"
#include "ompi/mca/mpool/mpool.h"
#include "ompi/proc/proc.h"
mca_btl_tcp_module_t mca_btl_tcp_module = {
{
&mca_btl_tcp_component.super,
0, /* max size of first fragment */
0, /* min send fragment size */
0, /* max send fragment size */
0, /* min rdma fragment size */
0, /* max rdma fragment size */
0, /* exclusivity */
0, /* latency */
0, /* bandwidth */
0, /* flags */
mca_btl_tcp_add_procs,
mca_btl_tcp_del_procs,
mca_btl_tcp_register,
mca_btl_tcp_finalize,
mca_btl_tcp_alloc,
mca_btl_tcp_free,
mca_btl_tcp_prepare_src,
mca_btl_tcp_prepare_dst,
mca_btl_tcp_send,
mca_btl_tcp_put,
NULL, /* get */
mca_btl_base_dump,
NULL, /* mpool */
NULL /* register error */
}
};
/**
*
*/
int mca_btl_tcp_add_procs(
struct mca_btl_base_module_t* btl,
size_t nprocs,
struct ompi_proc_t **ompi_procs,
struct mca_btl_base_endpoint_t** peers,
ompi_bitmap_t* reachable)
{
mca_btl_tcp_module_t* tcp_btl = (mca_btl_tcp_module_t*)btl;
ompi_proc_t* my_proc; /* pointer to caller's proc structure */
int i, rc;
/* get pointer to my proc structure */
my_proc = ompi_proc_local();
if( NULL == my_proc ) {
return OMPI_ERR_OUT_OF_RESOURCE;
}
for(i = 0; i < (int) nprocs; i++) {
struct ompi_proc_t* ompi_proc = ompi_procs[i];
mca_btl_tcp_proc_t* tcp_proc;
mca_btl_base_endpoint_t* tcp_endpoint;
/* Do not create loopback TCP connections */
if( my_proc == ompi_proc ) continue;
if(NULL == (tcp_proc = mca_btl_tcp_proc_create(ompi_proc))) {
return OMPI_ERR_OUT_OF_RESOURCE;
}
/*
* Check to make sure that the peer has at least as many interface
* addresses exported as we are trying to use. If not, then
* don't bind this BTL instance to the proc.
*/
OPAL_THREAD_LOCK(&tcp_proc->proc_lock);
/* The btl_proc datastructure is shared by all TCP BTL
* instances that are trying to reach this destination.
* Cache the peer instance on the btl_proc.
*/
tcp_endpoint = OBJ_NEW(mca_btl_tcp_endpoint_t);
if(NULL == tcp_endpoint) {
OPAL_THREAD_UNLOCK(&tcp_proc->proc_lock);
return OMPI_ERR_OUT_OF_RESOURCE;
}
tcp_endpoint->endpoint_btl = tcp_btl;
rc = mca_btl_tcp_proc_insert(tcp_proc, tcp_endpoint);
if(rc != OMPI_SUCCESS) {
OBJ_RELEASE(tcp_endpoint);
OPAL_THREAD_UNLOCK(&tcp_proc->proc_lock);
continue;
}
ompi_bitmap_set_bit(reachable, i);
OPAL_THREAD_UNLOCK(&tcp_proc->proc_lock);
peers[i] = tcp_endpoint;
opal_list_append(&tcp_btl->tcp_endpoints, (opal_list_item_t*)tcp_endpoint);
/* we increase the count of MPI users of the event library
once per peer, so that we are used until we aren't
connected to a peer */
opal_progress_event_users_increment();
}
return OMPI_SUCCESS;
}
int mca_btl_tcp_del_procs(struct mca_btl_base_module_t* btl,
size_t nprocs,
struct ompi_proc_t **procs,
struct mca_btl_base_endpoint_t ** endpoints)
{
mca_btl_tcp_module_t* tcp_btl = (mca_btl_tcp_module_t*)btl;
size_t i;
for(i=0; i<nprocs; i++) {
mca_btl_tcp_endpoint_t* tcp_endpoint = endpoints[i];
if(tcp_endpoint->endpoint_proc != mca_btl_tcp_proc_local()) {
opal_list_remove_item(&tcp_btl->tcp_endpoints, (opal_list_item_t*)tcp_endpoint);
OBJ_RELEASE(tcp_endpoint);
}
opal_progress_event_users_decrement();
}
return OMPI_SUCCESS;
}
/**
* Register callback function to support send/recv semantics
*/
int mca_btl_tcp_register(
struct mca_btl_base_module_t* btl,
mca_btl_base_tag_t tag,
mca_btl_base_module_recv_cb_fn_t cbfunc,
void* cbdata)
{
mca_btl_tcp_module_t* tcp_btl = (mca_btl_tcp_module_t*) btl;
tcp_btl->tcp_reg[tag].cbfunc = cbfunc;
tcp_btl->tcp_reg[tag].cbdata = cbdata;
return OMPI_SUCCESS;
}
/**
* Allocate a segment.
*
* @param btl (IN) BTL module
* @param size (IN) Request segment size.
*/
mca_btl_base_descriptor_t* mca_btl_tcp_alloc(
struct mca_btl_base_module_t* btl,
size_t size)
{
mca_btl_tcp_frag_t* frag;
int rc;
if(size <= btl->btl_eager_limit) {
MCA_BTL_TCP_FRAG_ALLOC_EAGER(frag, rc);
frag->segments[0].seg_len = size;
} else if (size <= btl->btl_max_send_size) {
MCA_BTL_TCP_FRAG_ALLOC_MAX(frag, rc);
frag->segments[0].seg_len = size;
} else {
return NULL;
}
OMPI_PTR_SET_PVAL(frag->segments[0].seg_addr, frag+1);
frag->base.des_src = frag->segments;
frag->base.des_src_cnt = 1;
frag->base.des_dst = NULL;
frag->base.des_dst_cnt = 0;
frag->base.des_flags = 0;
frag->btl = (mca_btl_tcp_module_t*)btl;
return (mca_btl_base_descriptor_t*)frag;
}
/**
* Return a segment
*/
int mca_btl_tcp_free(
struct mca_btl_base_module_t* btl,
mca_btl_base_descriptor_t* des)
{
mca_btl_tcp_frag_t* frag = (mca_btl_tcp_frag_t*)des;
MCA_BTL_TCP_FRAG_RETURN(frag);
return OMPI_SUCCESS;
}
/**
* Pack data and return a descriptor that can be
* used for send/put.
*
* @param btl (IN) BTL module
* @param peer (IN) BTL peer addressing
*/
mca_btl_base_descriptor_t* mca_btl_tcp_prepare_src(
struct mca_btl_base_module_t* btl,
struct mca_btl_base_endpoint_t* endpoint,
struct mca_mpool_base_registration_t* registration,
struct ompi_convertor_t* convertor,
size_t reserve,
size_t* size)
{
mca_btl_tcp_frag_t* frag;
struct iovec iov;
uint32_t iov_count = 1;
size_t max_data = *size;
int rc;
/*
* if we aren't pinning the data and the requested size is less
* than the eager limit pack into a fragment from the eager pool
*/
if (max_data+reserve <= btl->btl_eager_limit) {
MCA_BTL_TCP_FRAG_ALLOC_EAGER(frag, rc);
}
/*
* otherwise pack as much data as we can into a fragment
* that is the max send size.
*/
else {
MCA_BTL_TCP_FRAG_ALLOC_MAX(frag, rc);
}
if(NULL == frag) {
return NULL;
}
if(max_data == 0) {
OMPI_PTR_SET_PVAL(frag->segments[0].seg_addr, (frag + 1));
frag->segments[0].seg_len = reserve;
frag->base.des_src_cnt = 1;
} else if(ompi_convertor_need_buffers(convertor)) {
if (max_data + reserve > frag->size) {
max_data = frag->size - reserve;
}
iov.iov_len = max_data;
iov.iov_base = (IOVBASE_TYPE*)(((unsigned char*)(frag+1)) + reserve);
rc = ompi_convertor_pack(convertor, &iov, &iov_count, &max_data );
if( rc < 0 ) {
mca_btl_tcp_free(btl, &frag->base);
return NULL;
}
OMPI_PTR_SET_PVAL(frag->segments[0].seg_addr, (frag + 1));
frag->segments[0].seg_len = max_data + reserve;
frag->base.des_src_cnt = 1;
} else {
iov.iov_len = max_data;
iov.iov_base = NULL;
rc = ompi_convertor_pack(convertor, &iov, &iov_count, &max_data );
if( rc < 0 ) {
mca_btl_tcp_free(btl, &frag->base);
return NULL;
}
OMPI_PTR_SET_PVAL(frag->segments[0].seg_addr, frag+1);
frag->segments[0].seg_len = reserve;
OMPI_PTR_SET_PVAL(frag->segments[1].seg_addr, iov.iov_base);
frag->segments[1].seg_len = max_data;
frag->base.des_src_cnt = 2;
}
frag->base.des_src = frag->segments;
frag->base.des_dst = NULL;
frag->base.des_dst_cnt = 0;
frag->base.des_flags = 0;
*size = max_data;
return &frag->base;
}
/**
* Prepare a descriptor for send/rdma using the supplied
* convertor. If the convertor references data that is contigous,
* the descriptor may simply point to the user buffer. Otherwise,
* this routine is responsible for allocating buffer space and
* packing if required.
*
* @param btl (IN) BTL module
* @param endpoint (IN) BTL peer addressing
* @param convertor (IN) Data type convertor
* @param reserve (IN) Additional bytes requested by upper layer to precede user data
* @param size (IN/OUT) Number of bytes to prepare (IN), number of bytes actually prepared (OUT)
*/
mca_btl_base_descriptor_t* mca_btl_tcp_prepare_dst(
struct mca_btl_base_module_t* btl,
struct mca_btl_base_endpoint_t* endpoint,
struct mca_mpool_base_registration_t* registration,
struct ompi_convertor_t* convertor,
size_t reserve,
size_t* size)
{
mca_btl_tcp_frag_t* frag;
ptrdiff_t lb;
int rc;
MCA_BTL_TCP_FRAG_ALLOC_USER(frag, rc);
if(NULL == frag) {
return NULL;
}
ompi_ddt_type_lb(convertor->pDesc, &lb);
frag->segments->seg_len = *size;
OMPI_PTR_SET_PVAL(frag->segments->seg_addr,
convertor->pBaseBuf + lb + convertor->bConverted);
frag->base.des_src = NULL;
frag->base.des_src_cnt = 0;
frag->base.des_dst = frag->segments;
frag->base.des_dst_cnt = 1;
frag->base.des_flags = 0;
return &frag->base;
}
/**
* Initiate an asynchronous send.
*
* @param btl (IN) BTL module
* @param endpoint (IN) BTL addressing information
* @param descriptor (IN) Description of the data to be transfered
* @param tag (IN) The tag value used to notify the peer.
*/
int mca_btl_tcp_send(
struct mca_btl_base_module_t* btl,
struct mca_btl_base_endpoint_t* endpoint,
struct mca_btl_base_descriptor_t* descriptor,
mca_btl_base_tag_t tag)
{
mca_btl_tcp_module_t* tcp_btl = (mca_btl_tcp_module_t*) btl;
mca_btl_tcp_frag_t* frag = (mca_btl_tcp_frag_t*)descriptor;
size_t i;
frag->btl = tcp_btl;
frag->endpoint = endpoint;
frag->rc = 0;
frag->iov_idx = 0;
frag->iov_cnt = 1;
frag->iov_ptr = frag->iov;
frag->iov[0].iov_base = (IOVBASE_TYPE*)&frag->hdr;
frag->iov[0].iov_len = sizeof(frag->hdr);
frag->hdr.size = 0;
for(i=0; i<frag->base.des_src_cnt; i++) {
frag->hdr.size += frag->segments[i].seg_len;
frag->iov[i+1].iov_len = frag->segments[i].seg_len;
frag->iov[i+1].iov_base = (IOVBASE_TYPE*) OMPI_PTR_GET_PVAL(frag->segments[i].seg_addr);
frag->iov_cnt++;
}
frag->hdr.base.tag = tag;
frag->hdr.type = MCA_BTL_TCP_HDR_TYPE_SEND;
frag->hdr.count = 0;
if (endpoint->endpoint_nbo) MCA_BTL_TCP_HDR_HTON(frag->hdr);
return mca_btl_tcp_endpoint_send(endpoint,frag);
}
/**
* Initiate an asynchronous put.
*
* @param btl (IN) BTL module
* @param endpoint (IN) BTL addressing information
* @param descriptor (IN) Description of the data to be transferred
*/
int mca_btl_tcp_put(
mca_btl_base_module_t* btl,
mca_btl_base_endpoint_t* endpoint,
mca_btl_base_descriptor_t* descriptor)
{
mca_btl_tcp_module_t* tcp_btl = (mca_btl_tcp_module_t*) btl;
mca_btl_tcp_frag_t* frag = (mca_btl_tcp_frag_t*)descriptor;
size_t i;
frag->btl = tcp_btl;
frag->endpoint = endpoint;
frag->rc = 0;
frag->iov_idx = 0;
frag->hdr.size = 0;
frag->iov_cnt = 2;
frag->iov_ptr = frag->iov;
frag->iov[0].iov_base = (IOVBASE_TYPE*)&frag->hdr;
frag->iov[0].iov_len = sizeof(frag->hdr);
frag->iov[1].iov_base = (IOVBASE_TYPE*)frag->base.des_dst;
frag->iov[1].iov_len = frag->base.des_dst_cnt * sizeof(mca_btl_base_segment_t);
for(i=0; i<frag->base.des_src_cnt; i++) {
frag->hdr.size += frag->segments[i].seg_len;
frag->iov[i+2].iov_len = frag->segments[i].seg_len;
frag->iov[i+2].iov_base = (IOVBASE_TYPE*) OMPI_PTR_GET_PVAL(frag->segments[i].seg_addr);
frag->iov_cnt++;
}
frag->hdr.base.tag = MCA_BTL_TAG_BTL;
frag->hdr.type = MCA_BTL_TCP_HDR_TYPE_PUT;
frag->hdr.count = frag->base.des_dst_cnt;
if (endpoint->endpoint_nbo) MCA_BTL_TCP_HDR_HTON(frag->hdr);
return mca_btl_tcp_endpoint_send(endpoint,frag);
}
/**
* Initiate an asynchronous get.
*
* @param btl (IN) BTL module
* @param endpoint (IN) BTL addressing information
* @param descriptor (IN) Description of the data to be transferred
*
*/
int mca_btl_tcp_get(
mca_btl_base_module_t* btl,
mca_btl_base_endpoint_t* endpoint,
mca_btl_base_descriptor_t* descriptor)
{
mca_btl_tcp_module_t* tcp_btl = (mca_btl_tcp_module_t*) btl;
mca_btl_tcp_frag_t* frag = (mca_btl_tcp_frag_t*)descriptor;
frag->btl = tcp_btl;
frag->endpoint = endpoint;
frag->rc = 0;
frag->iov_idx = 0;
frag->hdr.size = 0;
frag->iov_cnt = 2;
frag->iov_ptr = frag->iov;
frag->iov[0].iov_base = (IOVBASE_TYPE*)&frag->hdr;
frag->iov[0].iov_len = sizeof(frag->hdr);
frag->iov[1].iov_base = (IOVBASE_TYPE*)frag->base.des_src;
frag->iov[1].iov_len = frag->base.des_src_cnt * sizeof(mca_btl_base_segment_t);
frag->hdr.base.tag = MCA_BTL_TAG_BTL;
frag->hdr.type = MCA_BTL_TCP_HDR_TYPE_GET;
frag->hdr.count = frag->base.des_src_cnt;
if (endpoint->endpoint_nbo) MCA_BTL_TCP_HDR_HTON(frag->hdr);
return mca_btl_tcp_endpoint_send(endpoint,frag);
}
/*
* Cleanup/release module resources.
*/
int mca_btl_tcp_finalize(struct mca_btl_base_module_t* btl)
{
mca_btl_tcp_module_t* tcp_btl = (mca_btl_tcp_module_t*) btl;
opal_list_item_t* item;
for( item = opal_list_remove_first(&tcp_btl->tcp_endpoints);
item != NULL;
item = opal_list_remove_first(&tcp_btl->tcp_endpoints)) {
mca_btl_tcp_endpoint_t *endpoint = (mca_btl_tcp_endpoint_t*)item;
OBJ_RELEASE(endpoint);
opal_progress_event_users_decrement();
}
free(tcp_btl);
return OMPI_SUCCESS;
}
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