/**
* display a synchro entry file information
*/
char *geocli_display_one_file_info(char *p,geo_fid_entry_t *info_p)
{
uint8_t * pFid;
int idx;
uint8_t rozofs_safe = rozofs_get_rozofs_safe(info_p->layout);
pFid = (uint8_t *) info_p->fid;
p+=sprintf(p," %d |",info_p->layout);
/*
** display the fid
*/
p += sprintf(p,"%2.2x%2.2x%2.2x%2.2x-%2.2x%2.2x-%2.2x%2.2x-%2.2x%2.2x-%2.2x%2.2x%2.2x%2.2x%2.2x%2.2x |",
pFid[0],pFid[1],pFid[2],pFid[3],pFid[4],pFid[5],pFid[6],pFid[7],
pFid[8],pFid[9],pFid[10],pFid[11],pFid[12],pFid[13],pFid[14],pFid[15]);
/*
** offset start and end
*/
p +=sprintf(p,"%10"PRIu64" |",info_p->off_start);
p +=sprintf(p,"%10"PRIu64" |",info_p->off_end);
/*
** File only
*/
p+=sprintf(p,"%3d |",info_p->cid);
p += sprintf(p, "%3.3d", info_p->sids[0]);
for (idx = 1; idx < rozofs_safe; idx++) {
p += sprintf(p,"-%3.3d", info_p->sids[idx]);
}
p += sprintf(p,"\n");
return p;
}
/**
* The purpose of that function is to return TRUE if there are enough delete response received for
rebuilding a projection for future reading
@param layout : layout association with the file
@param prj_cxt_p: pointer to the projection context (working array)
@param *errcode: pointer to global error code to return
@retval 1 if there are enough received projection
@retval 0 when there is enough projection
*/
static inline int rozofs_storcli_all_prj_delete_check(uint8_t layout,rozofs_storcli_projection_ctx_t *prj_cxt_p,int *errcode_p)
{
/*
** Get the rozofs_safe value for the layout
*/
uint8_t rozofs_safe = rozofs_get_rozofs_safe(layout);
int i;
int received = 0;
*errcode_p = 0;
for (i = 0; i <rozofs_safe; i++,prj_cxt_p++)
{
if (prj_cxt_p->prj_state == ROZOFS_PRJ_WR_DONE)
{
received++;
continue;
}
if (prj_cxt_p->prj_state == ROZOFS_PRJ_WR_ERROR)
{
*errcode_p = prj_cxt_p->errcode;
received++;
continue;
}
}
if (received == rozofs_safe) return 1;
return 0;
}
char *storage_map_distribution(storage_t * st, uint8_t layout,
sid_t dist_set[ROZOFS_SAFE_MAX], uint8_t spare, char *path) {
int i = 0;
char build_path[FILENAME_MAX];
DEBUG_FUNCTION;
strncpy(path, st->root, FILENAME_MAX);
strcat(path, "/");
sprintf(build_path, "layout_%u/spare_%u/", layout, spare);
strcat(path, build_path);
uint8_t rozofs_safe = rozofs_get_rozofs_safe(layout);
for (i = 0; i < rozofs_safe; i++) {
char build_path_2[FILENAME_MAX];
sprintf(build_path_2, "%.3u", dist_set[i]);
strcat(path, build_path_2);
if (i != (rozofs_safe - 1))
strcat(path, "-");
}
strcat(path, "/");
return path;
}
void rozofs_storcli_truncate_projection_retry(rozofs_storcli_ctx_t *working_ctx_p,uint8_t projection_id,int same_storage_retry_acceptable)
{
uint8_t rozofs_safe;
uint8_t rozofs_forward;
uint8_t layout;
storcli_truncate_arg_t *storcli_truncate_rq_p = (storcli_truncate_arg_t*)&working_ctx_p->storcli_truncate_arg;
int error=0;
int storage_idx;
rozofs_storcli_projection_ctx_t *prj_cxt_p = working_ctx_p->prj_ctx;
rozofs_storcli_lbg_prj_assoc_t *lbg_assoc_p = working_ctx_p->lbg_assoc_tb;
layout = storcli_truncate_rq_p->layout;
rozofs_safe = rozofs_get_rozofs_safe(layout);
rozofs_forward = rozofs_get_rozofs_forward(layout);
/*
** Now update the state of each load balancing group since it might be possible
** that some experience a state change
*/
for (storage_idx = 0; storage_idx < rozofs_safe; storage_idx++)
{
/*
** Check the state of the load Balancing group
*/
rozofs_storcli_lbg_prj_insert_lbg_state(lbg_assoc_p,
storage_idx,
NORTH_LBG_GET_STATE(lbg_assoc_p[storage_idx].lbg_id));
}
/**
* attempt to select a new storage
*/
if (rozofs_storcli_select_storage_idx_for_write (working_ctx_p,rozofs_forward,rozofs_safe,projection_id) < 0)
{
/*
** Cannot select a new storage: OK so now double check if the retry on the same storage is
** acceptable.When it is the case, check if the max retry has not been yet reached
** Otherwise, we are in deep shit-> reject the read request
*/
if (same_storage_retry_acceptable == 0)
{
error = EIO;
prj_cxt_p[projection_id].errcode = error;
goto reject;
}
if (++prj_cxt_p[projection_id].retry_cpt >= ROZOFS_STORCLI_MAX_RETRY)
{
error = EIO;
prj_cxt_p[projection_id].errcode = error;
goto reject;
}
}
/*
** we are lucky since either a get a new storage or the retry counter is not exhausted
*/
sp_truncate_arg_no_bins_t *request;
sp_truncate_arg_no_bins_t truncate_prj_args;
void *xmit_buf;
int ret;
xmit_buf = prj_cxt_p[projection_id].prj_buf;
if (xmit_buf == NULL)
{
/*
** fatal error since the ressource control already took place
*/
error = EFAULT;
prj_cxt_p[projection_id].errcode = error;
goto fatal;
}
/*
** fill partially the common header
*/
retry:
request = &truncate_prj_args;
request->cid = storcli_truncate_rq_p->cid;
request->sid = (uint8_t) rozofs_storcli_lbg_prj_get_sid(working_ctx_p->lbg_assoc_tb,prj_cxt_p[projection_id].stor_idx);
request->layout = layout;
if (prj_cxt_p[projection_id].stor_idx >= rozofs_forward) request->spare = 1;
else request->spare = 0;
memcpy(request->dist_set, storcli_truncate_rq_p->dist_set, ROZOFS_SAFE_MAX*sizeof (uint8_t));
memcpy(request->fid, storcli_truncate_rq_p->fid, sizeof (sp_uuid_t));
request->proj_id = projection_id;
request->bid = storcli_truncate_rq_p->bid;
request->last_seg = storcli_truncate_rq_p->last_seg;
request->last_timestamp = working_ctx_p->timestamp;
/*
** Bins len has been saved in the working context
*/
request->len = working_ctx_p->truncate_bins_len;
uint32_t lbg_id = rozofs_storcli_lbg_prj_get_lbg(working_ctx_p->lbg_assoc_tb,prj_cxt_p[projection_id].stor_idx);
/*
** increment the lock since it might be possible that this procedure is called after a synchronous transaction failu failure
** while the system is still in the initial procedure that triggers the writing of the projection. So it might be possible that
** the lock is already asserted
** as for the initial case, we need to anticipate the xmit state of the projection since the ERROR status might be set
** on a synchronous transaction failure. If that state is set after a positive submission towards the lbg, we might
** overwrite the ERROR state with the IN_PRG state.
*/
working_ctx_p->write_ctx_lock++;
prj_cxt_p[projection_id].prj_state = ROZOFS_PRJ_WR_IN_PRG;
STORCLI_START_NORTH_PROF((&working_ctx_p->prj_ctx[projection_id]),truncate_prj,0);
ret = rozofs_sorcli_send_rq_common(lbg_id,ROZOFS_TMR_GET(TMR_STORAGE_PROGRAM),STORAGE_PROGRAM,STORAGE_VERSION,SP_TRUNCATE,
(xdrproc_t) xdr_sp_truncate_arg_no_bins_t, (caddr_t) request,
xmit_buf,
working_ctx_p->read_seqnum,
(uint32_t) projection_id,
working_ctx_p->truncate_bins_len,
rozofs_storcli_truncate_req_processing_cbk,
(void*)working_ctx_p);
working_ctx_p->write_ctx_lock--;
if (ret < 0)
{
/*
** the communication with the storage seems to be wrong (more than TCP connection temporary down
** attempt to select a new storage
**
*/
STORCLI_STOP_NORTH_PROF((&working_ctx_p->prj_ctx[projection_id]),truncate_prj,0);
if (rozofs_storcli_select_storage_idx_for_write (working_ctx_p,rozofs_forward,rozofs_safe,projection_id) < 0)
{
/*
** Out of storage !!-> too many storages are down
*/
goto fatal;
}
/*
** retry for that projection with a new storage index: WARNING: we assume that xmit buffer has not been released !!!
*/
goto retry;
}
/*
** OK, the buffer has been accepted by the load balancing group, check if there was a direct failure for
** that transaction
*/
if ( prj_cxt_p[projection_id].prj_state == ROZOFS_PRJ_WR_ERROR)
{
error = prj_cxt_p[projection_id].errcode;
goto fatal;
}
return;
/*
**_____________________________________________
** Exception cases
**_____________________________________________
*/
reject:
if (working_ctx_p->write_ctx_lock != 0) return;
/*
** we fall in that case when we run out of storage
*/
rozofs_storcli_write_reply_error(working_ctx_p,error);
/*
** release the root transaction context
*/
STORCLI_STOP_NORTH_PROF(working_ctx_p,truncate,0);
rozofs_storcli_release_context(working_ctx_p);
return;
fatal:
/*
** caution -> reply error is only generated if the ctx_lock is 0
*/
if (working_ctx_p->write_ctx_lock != 0) return;
/*
** we fall in that case when we run out of resource-> that case is a BUG !!
*/
rozofs_storcli_write_reply_error(working_ctx_p,error);
/*
** release the root transaction context
*/
STORCLI_STOP_NORTH_PROF(working_ctx_p,truncate,0);
rozofs_storcli_release_context(working_ctx_p);
return;
}
/*
** That function is called when all the projection are ready to be sent
@param working_ctx_p: pointer to the root context associated with the top level write request
@param data : pointer to the data of the last block to truncate
*/
void rozofs_storcli_truncate_req_processing_exec(rozofs_storcli_ctx_t *working_ctx_p, char * data)
{
storcli_truncate_arg_t *storcli_truncate_rq_p = (storcli_truncate_arg_t*)&working_ctx_p->storcli_truncate_arg;
uint8_t layout = storcli_truncate_rq_p->layout;
uint8_t rozofs_forward;
uint8_t rozofs_safe;
uint8_t projection_id;
int storage_idx;
int error=0;
rozofs_storcli_lbg_prj_assoc_t *lbg_assoc_p = working_ctx_p->lbg_assoc_tb;
rozofs_storcli_projection_ctx_t *prj_cxt_p = working_ctx_p->prj_ctx;
rozofs_forward = rozofs_get_rozofs_forward(layout);
rozofs_safe = rozofs_get_rozofs_safe(layout);
/*
** set the current state of each load balancing group belonging to the rozofs_safe group
*/
for (storage_idx = 0; storage_idx < rozofs_safe; storage_idx++)
{
/*
** Check the state of the load Balancing group
*/
rozofs_storcli_lbg_prj_insert_lbg_state(lbg_assoc_p,
storage_idx,
NORTH_LBG_GET_STATE(lbg_assoc_p[storage_idx].lbg_id));
}
/*
** Now find out a selectable lbg_id for each projection
*/
for (projection_id = 0; projection_id < rozofs_forward; projection_id++)
{
if (rozofs_storcli_select_storage_idx_for_write ( working_ctx_p,rozofs_forward, rozofs_safe,projection_id) < 0)
{
/*
** there is no enough valid storage !!
*/
error = EIO;
goto fail;
}
}
/*
** Let's transform the data to write
*/
working_ctx_p->truncate_bins_len = 0;
if (data != NULL) {
STORCLI_START_KPI(storcli_kpi_transform_forward);
rozofs_storcli_transform_forward(working_ctx_p->prj_ctx,
layout,
0,
1,
working_ctx_p->timestamp,
storcli_truncate_rq_p->last_seg,
data);
STORCLI_STOP_KPI(storcli_kpi_transform_forward,0);
working_ctx_p->truncate_bins_len = rozofs_get_max_psize(layout)*sizeof(bin_t) + sizeof(rozofs_stor_bins_hdr_t);
}
/*
** We have enough storage, so initiate the transaction towards the storage for each
** projection
*/
for (projection_id = 0; projection_id < rozofs_forward; projection_id++)
{
sp_truncate_arg_no_bins_t *request;
sp_truncate_arg_no_bins_t truncate_prj_args;
void *xmit_buf;
int ret;
xmit_buf = prj_cxt_p[projection_id].prj_buf;
if (xmit_buf == NULL)
{
/*
** fatal error since the ressource control already took place
*/
error = EIO;
goto fatal;
}
/*
** fill partially the common header
*/
retry:
request = &truncate_prj_args;
request->cid = storcli_truncate_rq_p->cid;
request->sid = (uint8_t) rozofs_storcli_lbg_prj_get_sid(working_ctx_p->lbg_assoc_tb,prj_cxt_p[projection_id].stor_idx);
request->layout = layout;
if (prj_cxt_p[projection_id].stor_idx >= rozofs_forward) request->spare = 1;
else request->spare = 0;
memcpy(request->dist_set, storcli_truncate_rq_p->dist_set, ROZOFS_SAFE_MAX*sizeof (uint8_t));
memcpy(request->fid, storcli_truncate_rq_p->fid, sizeof (sp_uuid_t));
request->proj_id = projection_id;
request->bid = storcli_truncate_rq_p->bid;
request->last_seg = storcli_truncate_rq_p->last_seg;
request->last_timestamp = working_ctx_p->timestamp;
request->len = working_ctx_p->truncate_bins_len;
uint32_t lbg_id = rozofs_storcli_lbg_prj_get_lbg(working_ctx_p->lbg_assoc_tb,prj_cxt_p[projection_id].stor_idx);
STORCLI_START_NORTH_PROF((&working_ctx_p->prj_ctx[projection_id]),truncate_prj,0);
/*
** caution we might have a direct reply if there is a direct error at load balancing group while
** ateempting to send the RPC message-> typically a disconnection of the TCP connection
** As a consequence the response fct 'rozofs_storcli_truncate_req_processing_cbk) can be called
** prior returning from rozofs_sorcli_send_rq_common')
** anticipate the status of the xmit state of the projection and lock the section to
** avoid a reply error before returning from rozofs_sorcli_send_rq_common()
** --> need to take care because the write context is released after the reply error sent to rozofsmount
*/
working_ctx_p->write_ctx_lock = 1;
prj_cxt_p[projection_id].prj_state = ROZOFS_PRJ_WR_IN_PRG;
ret = rozofs_sorcli_send_rq_common(lbg_id,ROZOFS_TMR_GET(TMR_STORAGE_PROGRAM),STORAGE_PROGRAM,STORAGE_VERSION,SP_TRUNCATE,
(xdrproc_t) xdr_sp_truncate_arg_no_bins_t, (caddr_t) request,
xmit_buf,
working_ctx_p->read_seqnum,
(uint32_t) projection_id,
working_ctx_p->truncate_bins_len,
rozofs_storcli_truncate_req_processing_cbk,
(void*)working_ctx_p);
working_ctx_p->write_ctx_lock = 0;
if (ret < 0)
{
/*
** the communication with the storage seems to be wrong (more than TCP connection temporary down
** attempt to select a new storage
**
*/
if (rozofs_storcli_select_storage_idx_for_write (working_ctx_p,rozofs_forward,rozofs_safe,projection_id) < 0)
{
/*
** Out of storage !!-> too many storages are down
*/
goto fatal;
}
/*
** retry for that projection with a new storage index: WARNING: we assume that xmit buffer has not been released !!!
*/
//#warning: it is assumed that xmit buffer has not been release, need to double check!!
goto retry;
}
else
{
/*
** check if the state has not been changed: -> it might be possible to get a direct error
*/
if (prj_cxt_p[projection_id].prj_state == ROZOFS_PRJ_WR_ERROR)
{
error = prj_cxt_p[projection_id].errcode;
goto fatal;
}
}
}
return;
fail:
/*
** we fall in that case when we run out of resource-> that case is a BUG !!
*/
rozofs_storcli_write_reply_error(working_ctx_p,error);
/*
** release the root transaction context
*/
STORCLI_STOP_NORTH_PROF(working_ctx_p,truncate,0);
rozofs_storcli_release_context(working_ctx_p);
return;
fatal:
/*
** we fall in that case when we run out of resource-> that case is a BUG !!
*/
rozofs_storcli_write_reply_error(working_ctx_p,error);
/*
** release the root transaction context
*/
STORCLI_STOP_NORTH_PROF(working_ctx_p,truncate,0);
rozofs_storcli_release_context(working_ctx_p);
return;
}
/**
Initial truncate request
@param socket_ctx_p: pointer to the af unix socket
@param socketId: reference of the socket (not used)
@param rozofs_storcli_remote_rsp_cbk: callback for sending out the response
@retval : TRUE-> xmit ready event expected
@retval : FALSE-> xmit ready event not expected
*/
void rozofs_storcli_truncate_req_init(uint32_t socket_ctx_idx, void *recv_buf,rozofs_storcli_resp_pf_t rozofs_storcli_remote_rsp_cbk)
{
rozofs_rpc_call_hdr_with_sz_t *com_hdr_p;
rozofs_storcli_ctx_t *working_ctx_p = NULL;
int i;
uint32_t msg_len; /* length of the rpc messsage including the header length */
storcli_truncate_arg_t *storcli_truncate_rq_p = NULL;
rozofs_rpc_call_hdr_t hdr; /* structure that contains the rpc header in host format */
int len; /* effective length of application message */
uint8_t *pmsg; /* pointer to the first available byte in the application message */
uint32_t header_len;
XDR xdrs;
int errcode = EINVAL;
/*
** allocate a context for the duration of the write
*/
working_ctx_p = rozofs_storcli_alloc_context();
if (working_ctx_p == NULL)
{
/*
** that situation MUST not occur since there the same number of receive buffer and working context!!
*/
severe("out of working read/write saved context");
goto failure;
}
storcli_truncate_rq_p = &working_ctx_p->storcli_truncate_arg;
STORCLI_START_NORTH_PROF(working_ctx_p,truncate,0);
/*
** Get the full length of the message and adjust it the the length of the applicative part (RPC header+application msg)
*/
msg_len = ruc_buf_getPayloadLen(recv_buf);
msg_len -=sizeof(uint32_t);
/*
** save the reference of the received socket since it will be needed for sending back the
** response
*/
working_ctx_p->socketRef = socket_ctx_idx;
working_ctx_p->user_param = NULL;
working_ctx_p->recv_buf = recv_buf;
working_ctx_p->response_cbk = rozofs_storcli_remote_rsp_cbk;
/*
** Get the payload of the receive buffer and set the pointer to the array that describes the write request
*/
com_hdr_p = (rozofs_rpc_call_hdr_with_sz_t*) ruc_buf_getPayload(recv_buf);
memcpy(&hdr,&com_hdr_p->hdr,sizeof(rozofs_rpc_call_hdr_t));
/*
** swap the rpc header
*/
scv_call_hdr_ntoh(&hdr);
pmsg = rozofs_storcli_set_ptr_on_nfs_call_msg((char*)&com_hdr_p->hdr,&header_len);
if (pmsg == NULL)
{
errcode = EFAULT;
goto failure;
}
/*
** map the memory on the first applicative RPC byte available and prepare to decode:
** notice that we will not call XDR_FREE since the application MUST
** provide a pointer for storing the file handle
*/
len = msg_len - header_len;
xdrmem_create(&xdrs,(char*)pmsg,len,XDR_DECODE);
/*
** store the source transaction id needed for the reply
*/
working_ctx_p->src_transaction_id = hdr.hdr.xid;
/*
** decode the RPC message of the truncate request
*/
if (xdr_storcli_truncate_arg_t(&xdrs,storcli_truncate_rq_p) == FALSE)
{
/*
** decoding error
*/
errcode = EFAULT;
severe("rpc trucnate request decoding error");
goto failure;
}
/*
** init of the load balancing group/ projection association table:
** That table is ordered: the first corresponds to the storage associated with projection 0, second with 1, etc..
** When build that table, we MUST consider the value of the base which is associated with the distribution
*/
uint8_t rozofs_safe = rozofs_get_rozofs_safe(storcli_truncate_rq_p->layout);
int lbg_in_distribution = 0;
for (i = 0; i <rozofs_safe ; i ++)
{
/*
** Get the load balancing group associated with the sid
*/
int lbg_id = rozofs_storcli_get_lbg_for_sid(storcli_truncate_rq_p->cid,storcli_truncate_rq_p->dist_set[i]);
if (lbg_id < 0)
{
/*
** there is no associated between the sid and the lbg. It is typically the case
** when a new cluster has been added to the configuration and the client does not
** know yet the configuration change
*/
severe("sid is unknown !! %d\n",storcli_truncate_rq_p->dist_set[i]);
continue;
}
rozofs_storcli_lbg_prj_insert_lbg_and_sid(working_ctx_p->lbg_assoc_tb,lbg_in_distribution,
lbg_id,
storcli_truncate_rq_p->dist_set[i]);
rozofs_storcli_lbg_prj_insert_lbg_state(working_ctx_p->lbg_assoc_tb,
lbg_in_distribution,
NORTH_LBG_GET_STATE(working_ctx_p->lbg_assoc_tb[lbg_in_distribution].lbg_id));
lbg_in_distribution++;
if (lbg_in_distribution == rozofs_safe) break;
}
/*
** allocate a small buffer that will be used for sending the response to the truncate request
*/
working_ctx_p->xmitBuf = ruc_buf_getBuffer(ROZOFS_STORCLI_NORTH_SMALL_POOL);
if (working_ctx_p == NULL)
{
/*
** that situation MUST not occur since there the same number of receive buffer and working context!!
*/
errcode = ENOMEM;
severe("out of small buffer");
goto failure;
}
/*
** allocate a sequence number for the working context (same aas for read)
*/
working_ctx_p->read_seqnum = rozofs_storcli_allocate_read_seqnum();
/*
** set now the working variable specific for handling the truncate
** we re-use the structure used for writing even if nothing is written
*/
uint8_t forward_projection = rozofs_get_rozofs_forward(storcli_truncate_rq_p->layout);
for (i = 0; i < forward_projection; i++)
{
working_ctx_p->prj_ctx[i].prj_state = ROZOFS_PRJ_READ_IDLE;
working_ctx_p->prj_ctx[i].prj_buf = ruc_buf_getBuffer(ROZOFS_STORCLI_SOUTH_LARGE_POOL);
if (working_ctx_p->prj_ctx[i].prj_buf == NULL)
{
/*
** that situation MUST not occur since there the same number of receive buffer and working context!!
*/
errcode = ENOMEM;
severe("out of large buffer");
goto failure;
}
/*
** increment inuse counter on each buffer since we might need to re-use that packet in case
** of retransmission
*/
working_ctx_p->prj_ctx[i].inuse_valid = 1;
ruc_buf_inuse_increment(working_ctx_p->prj_ctx[i].prj_buf);
/*
** set the pointer to the bins
*/
int position = rozofs_storcli_get_position_of_first_byte2write_in_truncate();
uint8_t *pbuf = (uint8_t*)ruc_buf_getPayload(working_ctx_p->prj_ctx[i].prj_buf);
working_ctx_p->prj_ctx[i].bins = (bin_t*)(pbuf+position);
}
/*
** Prepare for request serialization
*/
memcpy(working_ctx_p->fid_key, storcli_truncate_rq_p->fid, sizeof (sp_uuid_t));
working_ctx_p->opcode_key = STORCLI_TRUNCATE;
{
/**
* lock all the file for a truncate
*/
uint64_t nb_blocks = 0;
nb_blocks--;
int ret;
ret = stc_rng_insert((void*)working_ctx_p,
STORCLI_READ,working_ctx_p->fid_key,
0,nb_blocks,
&working_ctx_p->sched_idx);
if (ret == 0)
{
/*
** there is a current request that is processed with the same fid and there is a collision
*/
return;
}
/*
** no request pending with that fid, so we can process it right away
*/
return rozofs_storcli_truncate_req_processing(working_ctx_p);
}
/*
**_____________________________________________
** Exception cases
**_____________________________________________
*/
/*
** there was a failure while attempting to allocate a memory ressource.
*/
failure:
/*
** send back the response with the appropriated error code.
** note: The received buffer (rev_buf) is
** intended to be released by this service in case of error or the TCP transmitter
** once it has been passed to the TCP stack.
*/
rozofs_storcli_reply_error_with_recv_buf(socket_ctx_idx,recv_buf,NULL,rozofs_storcli_remote_rsp_cbk,errcode);
/*
** check if the root context was allocated. Free it if is exist
*/
if (working_ctx_p != NULL)
{
/*
** remove the reference to the recvbuf to avoid releasing it twice
*/
STORCLI_STOP_NORTH_PROF(working_ctx_p,truncate,0);
working_ctx_p->recv_buf = NULL;
rozofs_storcli_release_context(working_ctx_p);
}
return;
}
/**
Apply the transform to a buffer starting at "data". That buffer MUST be ROZOFS_BSIZE
aligned.
The first_block_idx is the index of a ROZOFS_BSIZE array in the output buffer
The number_of_blocks is the number of ROZOFS_BSIZE that must be transform
Notice that the first_block_idx offset applies to the output transform buffer only
not to the input buffer pointed by "data".
*
* @param *prj_ctx_p: pointer to the working array of the projection
* @param first_block_idx: index of the first block to transform
* @param number_of_blocks: number of blocks to write
* @param *data: pointer to the source data that must be transformed
@param *number_of_blocks_p: pointer to the array where the function returns number of blocks on which the transform was applied
@param *rozofs_storcli_prj_idx_table: pointer to the array used for storing the projections index for inverse process
*
* @return: the length written on success, -1 otherwise (errno is set)
*/
int rozofs_storcli_transform_inverse(rozofs_storcli_projection_ctx_t *prj_ctx_p,
uint8_t layout, uint32_t bsize,
uint32_t first_block_idx,
uint32_t number_of_blocks,
rozofs_storcli_inverse_block_t *block_ctx_p,
char *data,
uint32_t *number_of_blocks_p,
uint8_t *rozofs_storcli_prj_idx_table)
{
int block_idx;
uint16_t projection_id = 0;
int prj_ctx_idx;
*number_of_blocks_p = 0;
uint8_t rozofs_inverse = rozofs_get_rozofs_inverse(layout);
uint8_t rozofs_forward = rozofs_get_rozofs_forward(layout);
uint8_t rozofs_safe = rozofs_get_rozofs_safe(layout);
uint32_t bbytes = ROZOFS_BSIZE_BYTES(bsize);
int prj_size_in_msg = rozofs_get_max_psize_in_msg(layout,bsize);
/*
** Proceed the inverse data transform for the nb_projections2read blocks.
*/
for (block_idx = 0; block_idx < number_of_blocks; block_idx++) {
if (block_ctx_p[block_idx].state == ROZOFS_BLK_TRANSFORM_DONE)
{
/*
** transformation has already been done for that block of ROZOFS_BSIZE siz
** check the next one
*/
continue;
}
/*
** Check the case of the file that has no data (there is a hole in the file), this is indicated by
** reporting a timestamp of 0
*/
if ((block_ctx_p[block_idx].timestamp == 0) && (block_ctx_p[block_idx].effective_length == bbytes ))
{
/*
** clear the memory
*/
ROZOFS_STORCLI_STATS(ROZOFS_STORCLI_EMPTY_READ);
memset( data + (bbytes * (first_block_idx + block_idx)),0,bbytes);
block_ctx_p[block_idx].state = ROZOFS_BLK_TRANSFORM_DONE;
continue;
}
if ((block_ctx_p[block_idx].timestamp == 0) && (block_ctx_p[block_idx].effective_length == 0 ))
{
/*
** we have reached end of file
*/
block_ctx_p[block_idx].state = ROZOFS_BLK_TRANSFORM_DONE;
*number_of_blocks_p = (block_idx++);
return 0;
}
/*
** Here we have to take care, since the index of the projection_id use to address
** prj_ctx_p is NOT the real projection_id. The projection ID is found in the header of
** each bins, so for a set of projections pointed by bins, we might have a different
** projection id in the header of the projections contains in the bins array that has
** been read!!
*/
transform_inverse_proc(&rozofs_storcli_prj_idx_table[ROZOFS_SAFE_MAX_STORCLI*block_idx],
prj_ctx_p,
prj_size_in_msg,
layout,
bbytes,
first_block_idx,
block_idx,
data);
/*
** indicate that transform has been done for the projection
*/
block_ctx_p[block_idx].state = ROZOFS_BLK_TRANSFORM_DONE;
/*
** check the case of a block that is not full: need to zero's that part
*/
if (block_ctx_p[block_idx].effective_length < bbytes)
{
/*
** clear the memory
*/
char *raz_p = data + (bbytes * (first_block_idx + block_idx)) + block_ctx_p[block_idx].effective_length;
memset( raz_p,0,(bbytes-block_ctx_p[block_idx].effective_length) );
}
}
/*
** now the inverse transform is finished, release the allocated ressources used for
** rebuild
*/
*number_of_blocks_p = number_of_blocks;
/*
** Check whether a block should be repaired
*/
rozofs_storcli_check_block_2_repair(prj_ctx_p, rozofs_inverse, rozofs_forward, rozofs_safe, prj_size_in_msg, number_of_blocks, block_ctx_p);
return 0;
}
inline int rozofs_storcli_transform_inverse_check(rozofs_storcli_projection_ctx_t *prj_ctx_p,
uint8_t layout,
uint32_t block_idx,
uint8_t *prj_idx_tb_p,
uint64_t *timestamp_p,
uint16_t *effective_len_p)
{
uint8_t prj_ctx_idx;
uint8_t nb_projection_with_same_timestamp = 0;
uint8_t rozofs_inverse = rozofs_get_rozofs_inverse(layout);
uint8_t rozofs_safe = rozofs_get_rozofs_safe(layout);
int ret;
int eof = 1;
*timestamp_p = 0;
*effective_len_p = 0;
rozofs_storcli_timestamp_ctx_t ref_ctx;
rozofs_storcli_timestamp_ctx_t *ref_ctx_p = &ref_ctx;
rozofs_storcli_timestamp_ctx_t rozofs_storcli_timestamp_tb[ROZOFS_SAFE_MAX];
uint8_t rozofs_storcli_timestamp_next_free_idx=0;
ref_ctx_p->count = 0;
/*
** clean data used for tracking projection to rebuild
*/
rozofs_storcli_timestamp_ctx_t *p = &rozofs_storcli_timestamp_tb[rozofs_storcli_timestamp_next_free_idx];
p->timestamp = 0;
p->count = 0;
for (prj_ctx_idx = 0; prj_ctx_idx < rozofs_safe; prj_ctx_idx++)
{
if (prj_ctx_p[prj_ctx_idx].prj_state != ROZOFS_PRJ_READ_DONE)
{
/*
** that projection context does not contain valid data, so skip it
*/
continue;
}
/*
** Get the pointer to the projection header
*/
rozofs_stor_bins_hdr_t *rozofs_bins_hdr_p = (rozofs_stor_bins_hdr_t*)&prj_ctx_p[prj_ctx_idx].block_hdr_tab[block_idx];
/*
** skip the invalid blocks
*/
if ((rozofs_bins_hdr_p->s.timestamp == 0) && (rozofs_bins_hdr_p->s.effective_length==0)) continue;
if (ref_ctx_p->count == 0)
{
/*
** first projection found
*/
eof = 0;
ref_ctx_p->timestamp = rozofs_bins_hdr_p->s.timestamp;
ref_ctx_p->effective_length = rozofs_bins_hdr_p->s.effective_length;
ref_ctx_p->count++;
prj_idx_tb_p[nb_projection_with_same_timestamp++] = prj_ctx_idx;
continue;
}
/*
** the entry is not empty check if the timestamp and the effective length of the block belonging to
** projection prj_ctx_idx matches
*/
if ((rozofs_bins_hdr_p->s.timestamp == ref_ctx_p->timestamp) &&(rozofs_bins_hdr_p->s.effective_length == ref_ctx_p->effective_length))
{
/*
** there is a match, store the projection index and check if we have reach rozofs_inverse blocks with the
** same timestamp and length
*/
ref_ctx_p->count++;
prj_idx_tb_p[nb_projection_with_same_timestamp++] = prj_ctx_idx;
if (nb_projection_with_same_timestamp == rozofs_inverse)
{
/*
** ok we have found all the projection for the best case
*/
*timestamp_p = ref_ctx_p->timestamp;
*effective_len_p = ref_ctx_p->effective_length;
/*
** Mark the projection that MUST be rebuilt
*/
if (rozofs_storcli_timestamp_next_free_idx)
{
rozofs_storcli_mark_projection2rebuild(prj_ctx_p,
rozofs_storcli_timestamp_tb,
rozofs_storcli_timestamp_next_free_idx+1,
rozofs_storcli_timestamp_next_free_idx);
}
return (int)rozofs_inverse;
}
continue;
}
/*
** Either the length of the timestamp does not match
** log the reference of the projection index in order to address a potential rebuild of the
** projection
*/
p->prj_idx_tb[p->count]= prj_ctx_idx;
p->count++;
if (rozofs_storcli_timestamp_next_free_idx == 0)
{
rozofs_storcli_timestamp_next_free_idx = 1;
}
}
/*
** check th eof case
*/
if (eof) return 0;
/*
** unlucky, we did not find rozof_inverse projections with the same timestamp
** so we have to find out the projection(s) that are out of sequence
*/
ret = rozofs_storcli_transform_inverse_check_timestamp_tb( prj_ctx_p,
layout,
block_idx,
prj_idx_tb_p,
timestamp_p,
effective_len_p);
return ret;
}
inline int rozofs_storcli_transform_inverse_check_timestamp_tb(rozofs_storcli_projection_ctx_t *prj_ctx_p,
uint8_t layout,
uint32_t block_idx,
uint8_t *prj_idx_tb_p,
uint64_t *timestamp_p,
uint16_t *effective_len_p)
{
uint8_t prj_ctx_idx;
uint8_t timestamp_entry;
*timestamp_p = 0;
uint8_t rozofs_inverse = rozofs_get_rozofs_inverse(layout);
uint8_t rozofs_safe = rozofs_get_rozofs_safe(layout);
rozofs_storcli_timestamp_ctx_t *p;
int eof = 1;
rozofs_storcli_timestamp_ctx_t rozofs_storcli_timestamp_tb[ROZOFS_SAFE_MAX];
uint8_t rozofs_storcli_timestamp_next_free_idx=0;
for (prj_ctx_idx = 0; prj_ctx_idx < rozofs_safe; prj_ctx_idx++)
{
if (prj_ctx_p[prj_ctx_idx].prj_state != ROZOFS_PRJ_READ_DONE)
{
/*
** that projection context does not contain valid data, so skip it
*/
continue;
}
/*
** Get the pointer to the projection header
*/
rozofs_stor_bins_hdr_t *rozofs_bins_hdr_p = (rozofs_stor_bins_hdr_t*)&prj_ctx_p[prj_ctx_idx].block_hdr_tab[block_idx];
/*
** check if the current block of the projection contains valid data. The block is invalid when the timestamp and the
** effective length are 0. That situation can occur when a storage was in fault at the writing time, so we can face
** the situation where the projections read on the different storages do not return the same number of block.
*/
if ((rozofs_bins_hdr_p->s.timestamp == 0)&&(rozofs_bins_hdr_p->s.effective_length == 0)) continue;
if (rozofs_storcli_timestamp_next_free_idx == 0)
{
/*
** first entry
*/
eof = 0;
p = &rozofs_storcli_timestamp_tb[rozofs_storcli_timestamp_next_free_idx];
p->timestamp = rozofs_bins_hdr_p->s.timestamp;
p->effective_length = rozofs_bins_hdr_p->s.effective_length;
p->count = 0;
p->prj_idx_tb[p->count]= prj_ctx_idx;
p->count++;
rozofs_storcli_timestamp_next_free_idx++;
continue;
}
/*
** more than 1 entry in the timestamp table
*/
for(timestamp_entry = 0; timestamp_entry < rozofs_storcli_timestamp_next_free_idx;timestamp_entry++)
{
p = &rozofs_storcli_timestamp_tb[timestamp_entry];
if ((rozofs_bins_hdr_p->s.timestamp != p->timestamp) || (rozofs_bins_hdr_p->s.effective_length != p->effective_length)) continue;
/*
** same timestamp and length: register the projection index and check if we have reached rozofs_inverse projections
** to stop the search
*/
p->prj_idx_tb[p->count]= prj_ctx_idx;
p->count++;
if (p->count == rozofs_inverse)
{
/*
** OK we have the right number of projection so we can leave
*/
memcpy(prj_idx_tb_p,p->prj_idx_tb,rozofs_inverse);
/*
** assert the timestamp that is common to all projections used to rebuild that block
*/
*timestamp_p = p->timestamp;
*effective_len_p = p->effective_length;
/*
** Mark the projection that MUST be rebuilt
*/
rozofs_storcli_mark_projection2rebuild(prj_ctx_p,rozofs_storcli_timestamp_tb,timestamp_entry,rozofs_storcli_timestamp_next_free_idx);
return 1;
}
/*
** try next
*/
}
/*
** that timestamp does not exist, so create an entry for it
*/
p = &rozofs_storcli_timestamp_tb[rozofs_storcli_timestamp_next_free_idx];
p->timestamp = rozofs_bins_hdr_p->s.timestamp;
p->effective_length = rozofs_bins_hdr_p->s.effective_length;
p->count = 0;
p->prj_idx_tb[p->count]= prj_ctx_idx;
p->count++;
rozofs_storcli_timestamp_next_free_idx++;
}
/*
** take care of the case where we try to read after the end of file
*/
if (eof) return 0;
/*
** unlucky, we did not find rozof_inverse projections with the same timestamp
** we need to read one more projection unless we already attempt to read rozofs_safe
** projection or we run out of storage that are up among the set of rozofs_safe storage
*/
return -1;
}
