linux/drivers/infiniband/hw/hfi1/tid_rdma.c
Kaike Wan dc25b239eb IB/hfi1: Field not zero-ed when allocating TID flow memory
The field flow->resync_npkts is added for TID RDMA WRITE request and
zero-ed when a TID RDMA WRITE RESP packet is received by the requester.
This field is used to rewind a request during retry in the function
hfi1_tid_rdma_restart_req() shared by both TID RDMA WRITE and TID RDMA
READ requests. Therefore, when a TID RDMA READ request is retried, this
field may not be initialized at all, which causes the retry to start at an
incorrect psn, leading to the drop of the retry request by the responder.

This patch fixes the problem by zeroing out the field when the flow memory
is allocated.

Fixes: 838b6fd2d9 ("IB/hfi1: TID RDMA RcvArray programming and TID allocation")
Cc: <stable@vger.kernel.org>
Link: https://lore.kernel.org/r/20190715164534.74174.6177.stgit@awfm-01.aw.intel.com
Reviewed-by: Mike Marciniszyn <mike.marciniszyn@intel.com>
Signed-off-by: Kaike Wan <kaike.wan@intel.com>
Signed-off-by: Mike Marciniszyn <mike.marciniszyn@intel.com>
Signed-off-by: Jason Gunthorpe <jgg@mellanox.com>
2019-07-22 14:57:55 -03:00

5560 lines
158 KiB
C

// SPDX-License-Identifier: (GPL-2.0 OR BSD-3-Clause)
/*
* Copyright(c) 2018 Intel Corporation.
*
*/
#include "hfi.h"
#include "qp.h"
#include "rc.h"
#include "verbs.h"
#include "tid_rdma.h"
#include "exp_rcv.h"
#include "trace.h"
/**
* DOC: TID RDMA READ protocol
*
* This is an end-to-end protocol at the hfi1 level between two nodes that
* improves performance by avoiding data copy on the requester side. It
* converts a qualified RDMA READ request into a TID RDMA READ request on
* the requester side and thereafter handles the request and response
* differently. To be qualified, the RDMA READ request should meet the
* following:
* -- The total data length should be greater than 256K;
* -- The total data length should be a multiple of 4K page size;
* -- Each local scatter-gather entry should be 4K page aligned;
* -- Each local scatter-gather entry should be a multiple of 4K page size;
*/
#define RCV_TID_FLOW_TABLE_CTRL_FLOW_VALID_SMASK BIT_ULL(32)
#define RCV_TID_FLOW_TABLE_CTRL_HDR_SUPP_EN_SMASK BIT_ULL(33)
#define RCV_TID_FLOW_TABLE_CTRL_KEEP_AFTER_SEQ_ERR_SMASK BIT_ULL(34)
#define RCV_TID_FLOW_TABLE_CTRL_KEEP_ON_GEN_ERR_SMASK BIT_ULL(35)
#define RCV_TID_FLOW_TABLE_STATUS_SEQ_MISMATCH_SMASK BIT_ULL(37)
#define RCV_TID_FLOW_TABLE_STATUS_GEN_MISMATCH_SMASK BIT_ULL(38)
/* Maximum number of packets within a flow generation. */
#define MAX_TID_FLOW_PSN BIT(HFI1_KDETH_BTH_SEQ_SHIFT)
#define GENERATION_MASK 0xFFFFF
static u32 mask_generation(u32 a)
{
return a & GENERATION_MASK;
}
/* Reserved generation value to set to unused flows for kernel contexts */
#define KERN_GENERATION_RESERVED mask_generation(U32_MAX)
/*
* J_KEY for kernel contexts when TID RDMA is used.
* See generate_jkey() in hfi.h for more information.
*/
#define TID_RDMA_JKEY 32
#define HFI1_KERNEL_MIN_JKEY HFI1_ADMIN_JKEY_RANGE
#define HFI1_KERNEL_MAX_JKEY (2 * HFI1_ADMIN_JKEY_RANGE - 1)
/* Maximum number of segments in flight per QP request. */
#define TID_RDMA_MAX_READ_SEGS_PER_REQ 6
#define TID_RDMA_MAX_WRITE_SEGS_PER_REQ 4
#define MAX_REQ max_t(u16, TID_RDMA_MAX_READ_SEGS_PER_REQ, \
TID_RDMA_MAX_WRITE_SEGS_PER_REQ)
#define MAX_FLOWS roundup_pow_of_two(MAX_REQ + 1)
#define MAX_EXPECTED_PAGES (MAX_EXPECTED_BUFFER / PAGE_SIZE)
#define TID_RDMA_DESTQP_FLOW_SHIFT 11
#define TID_RDMA_DESTQP_FLOW_MASK 0x1f
#define TID_OPFN_QP_CTXT_MASK 0xff
#define TID_OPFN_QP_CTXT_SHIFT 56
#define TID_OPFN_QP_KDETH_MASK 0xff
#define TID_OPFN_QP_KDETH_SHIFT 48
#define TID_OPFN_MAX_LEN_MASK 0x7ff
#define TID_OPFN_MAX_LEN_SHIFT 37
#define TID_OPFN_TIMEOUT_MASK 0x1f
#define TID_OPFN_TIMEOUT_SHIFT 32
#define TID_OPFN_RESERVED_MASK 0x3f
#define TID_OPFN_RESERVED_SHIFT 26
#define TID_OPFN_URG_MASK 0x1
#define TID_OPFN_URG_SHIFT 25
#define TID_OPFN_VER_MASK 0x7
#define TID_OPFN_VER_SHIFT 22
#define TID_OPFN_JKEY_MASK 0x3f
#define TID_OPFN_JKEY_SHIFT 16
#define TID_OPFN_MAX_READ_MASK 0x3f
#define TID_OPFN_MAX_READ_SHIFT 10
#define TID_OPFN_MAX_WRITE_MASK 0x3f
#define TID_OPFN_MAX_WRITE_SHIFT 4
/*
* OPFN TID layout
*
* 63 47 31 15
* NNNNNNNNKKKKKKKK MMMMMMMMMMMTTTTT DDDDDDUVVVJJJJJJ RRRRRRWWWWWWCCCC
* 3210987654321098 7654321098765432 1098765432109876 5432109876543210
* N - the context Number
* K - the Kdeth_qp
* M - Max_len
* T - Timeout
* D - reserveD
* V - version
* U - Urg capable
* J - Jkey
* R - max_Read
* W - max_Write
* C - Capcode
*/
static u32 tid_rdma_flow_wt;
static void tid_rdma_trigger_resume(struct work_struct *work);
static void hfi1_kern_exp_rcv_free_flows(struct tid_rdma_request *req);
static int hfi1_kern_exp_rcv_alloc_flows(struct tid_rdma_request *req,
gfp_t gfp);
static void hfi1_init_trdma_req(struct rvt_qp *qp,
struct tid_rdma_request *req);
static void hfi1_tid_write_alloc_resources(struct rvt_qp *qp, bool intr_ctx);
static void hfi1_tid_timeout(struct timer_list *t);
static void hfi1_add_tid_reap_timer(struct rvt_qp *qp);
static void hfi1_mod_tid_reap_timer(struct rvt_qp *qp);
static void hfi1_mod_tid_retry_timer(struct rvt_qp *qp);
static int hfi1_stop_tid_retry_timer(struct rvt_qp *qp);
static void hfi1_tid_retry_timeout(struct timer_list *t);
static int make_tid_rdma_ack(struct rvt_qp *qp,
struct ib_other_headers *ohdr,
struct hfi1_pkt_state *ps);
static void hfi1_do_tid_send(struct rvt_qp *qp);
static u32 read_r_next_psn(struct hfi1_devdata *dd, u8 ctxt, u8 fidx);
static void tid_rdma_rcv_err(struct hfi1_packet *packet,
struct ib_other_headers *ohdr,
struct rvt_qp *qp, u32 psn, int diff, bool fecn);
static void update_r_next_psn_fecn(struct hfi1_packet *packet,
struct hfi1_qp_priv *priv,
struct hfi1_ctxtdata *rcd,
struct tid_rdma_flow *flow,
bool fecn);
static u64 tid_rdma_opfn_encode(struct tid_rdma_params *p)
{
return
(((u64)p->qp & TID_OPFN_QP_CTXT_MASK) <<
TID_OPFN_QP_CTXT_SHIFT) |
((((u64)p->qp >> 16) & TID_OPFN_QP_KDETH_MASK) <<
TID_OPFN_QP_KDETH_SHIFT) |
(((u64)((p->max_len >> PAGE_SHIFT) - 1) &
TID_OPFN_MAX_LEN_MASK) << TID_OPFN_MAX_LEN_SHIFT) |
(((u64)p->timeout & TID_OPFN_TIMEOUT_MASK) <<
TID_OPFN_TIMEOUT_SHIFT) |
(((u64)p->urg & TID_OPFN_URG_MASK) << TID_OPFN_URG_SHIFT) |
(((u64)p->jkey & TID_OPFN_JKEY_MASK) << TID_OPFN_JKEY_SHIFT) |
(((u64)p->max_read & TID_OPFN_MAX_READ_MASK) <<
TID_OPFN_MAX_READ_SHIFT) |
(((u64)p->max_write & TID_OPFN_MAX_WRITE_MASK) <<
TID_OPFN_MAX_WRITE_SHIFT);
}
static void tid_rdma_opfn_decode(struct tid_rdma_params *p, u64 data)
{
p->max_len = (((data >> TID_OPFN_MAX_LEN_SHIFT) &
TID_OPFN_MAX_LEN_MASK) + 1) << PAGE_SHIFT;
p->jkey = (data >> TID_OPFN_JKEY_SHIFT) & TID_OPFN_JKEY_MASK;
p->max_write = (data >> TID_OPFN_MAX_WRITE_SHIFT) &
TID_OPFN_MAX_WRITE_MASK;
p->max_read = (data >> TID_OPFN_MAX_READ_SHIFT) &
TID_OPFN_MAX_READ_MASK;
p->qp =
((((data >> TID_OPFN_QP_KDETH_SHIFT) & TID_OPFN_QP_KDETH_MASK)
<< 16) |
((data >> TID_OPFN_QP_CTXT_SHIFT) & TID_OPFN_QP_CTXT_MASK));
p->urg = (data >> TID_OPFN_URG_SHIFT) & TID_OPFN_URG_MASK;
p->timeout = (data >> TID_OPFN_TIMEOUT_SHIFT) & TID_OPFN_TIMEOUT_MASK;
}
void tid_rdma_opfn_init(struct rvt_qp *qp, struct tid_rdma_params *p)
{
struct hfi1_qp_priv *priv = qp->priv;
p->qp = (kdeth_qp << 16) | priv->rcd->ctxt;
p->max_len = TID_RDMA_MAX_SEGMENT_SIZE;
p->jkey = priv->rcd->jkey;
p->max_read = TID_RDMA_MAX_READ_SEGS_PER_REQ;
p->max_write = TID_RDMA_MAX_WRITE_SEGS_PER_REQ;
p->timeout = qp->timeout;
p->urg = is_urg_masked(priv->rcd);
}
bool tid_rdma_conn_req(struct rvt_qp *qp, u64 *data)
{
struct hfi1_qp_priv *priv = qp->priv;
*data = tid_rdma_opfn_encode(&priv->tid_rdma.local);
return true;
}
bool tid_rdma_conn_reply(struct rvt_qp *qp, u64 data)
{
struct hfi1_qp_priv *priv = qp->priv;
struct tid_rdma_params *remote, *old;
bool ret = true;
old = rcu_dereference_protected(priv->tid_rdma.remote,
lockdep_is_held(&priv->opfn.lock));
data &= ~0xfULL;
/*
* If data passed in is zero, return true so as not to continue the
* negotiation process
*/
if (!data || !HFI1_CAP_IS_KSET(TID_RDMA))
goto null;
/*
* If kzalloc fails, return false. This will result in:
* * at the requester a new OPFN request being generated to retry
* the negotiation
* * at the responder, 0 being returned to the requester so as to
* disable TID RDMA at both the requester and the responder
*/
remote = kzalloc(sizeof(*remote), GFP_ATOMIC);
if (!remote) {
ret = false;
goto null;
}
tid_rdma_opfn_decode(remote, data);
priv->tid_timer_timeout_jiffies =
usecs_to_jiffies((((4096UL * (1UL << remote->timeout)) /
1000UL) << 3) * 7);
trace_hfi1_opfn_param(qp, 0, &priv->tid_rdma.local);
trace_hfi1_opfn_param(qp, 1, remote);
rcu_assign_pointer(priv->tid_rdma.remote, remote);
/*
* A TID RDMA READ request's segment size is not equal to
* remote->max_len only when the request's data length is smaller
* than remote->max_len. In that case, there will be only one segment.
* Therefore, when priv->pkts_ps is used to calculate req->cur_seg
* during retry, it will lead to req->cur_seg = 0, which is exactly
* what is expected.
*/
priv->pkts_ps = (u16)rvt_div_mtu(qp, remote->max_len);
priv->timeout_shift = ilog2(priv->pkts_ps - 1) + 1;
goto free;
null:
RCU_INIT_POINTER(priv->tid_rdma.remote, NULL);
priv->timeout_shift = 0;
free:
if (old)
kfree_rcu(old, rcu_head);
return ret;
}
bool tid_rdma_conn_resp(struct rvt_qp *qp, u64 *data)
{
bool ret;
ret = tid_rdma_conn_reply(qp, *data);
*data = 0;
/*
* If tid_rdma_conn_reply() returns error, set *data as 0 to indicate
* TID RDMA could not be enabled. This will result in TID RDMA being
* disabled at the requester too.
*/
if (ret)
(void)tid_rdma_conn_req(qp, data);
return ret;
}
void tid_rdma_conn_error(struct rvt_qp *qp)
{
struct hfi1_qp_priv *priv = qp->priv;
struct tid_rdma_params *old;
old = rcu_dereference_protected(priv->tid_rdma.remote,
lockdep_is_held(&priv->opfn.lock));
RCU_INIT_POINTER(priv->tid_rdma.remote, NULL);
if (old)
kfree_rcu(old, rcu_head);
}
/* This is called at context initialization time */
int hfi1_kern_exp_rcv_init(struct hfi1_ctxtdata *rcd, int reinit)
{
if (reinit)
return 0;
BUILD_BUG_ON(TID_RDMA_JKEY < HFI1_KERNEL_MIN_JKEY);
BUILD_BUG_ON(TID_RDMA_JKEY > HFI1_KERNEL_MAX_JKEY);
rcd->jkey = TID_RDMA_JKEY;
hfi1_set_ctxt_jkey(rcd->dd, rcd, rcd->jkey);
return hfi1_alloc_ctxt_rcv_groups(rcd);
}
/**
* qp_to_rcd - determine the receive context used by a qp
* @qp - the qp
*
* This routine returns the receive context associated
* with a a qp's qpn.
*
* Returns the context.
*/
static struct hfi1_ctxtdata *qp_to_rcd(struct rvt_dev_info *rdi,
struct rvt_qp *qp)
{
struct hfi1_ibdev *verbs_dev = container_of(rdi,
struct hfi1_ibdev,
rdi);
struct hfi1_devdata *dd = container_of(verbs_dev,
struct hfi1_devdata,
verbs_dev);
unsigned int ctxt;
if (qp->ibqp.qp_num == 0)
ctxt = 0;
else
ctxt = hfi1_get_qp_map(dd, qp->ibqp.qp_num >> dd->qos_shift);
return dd->rcd[ctxt];
}
int hfi1_qp_priv_init(struct rvt_dev_info *rdi, struct rvt_qp *qp,
struct ib_qp_init_attr *init_attr)
{
struct hfi1_qp_priv *qpriv = qp->priv;
int i, ret;
qpriv->rcd = qp_to_rcd(rdi, qp);
spin_lock_init(&qpriv->opfn.lock);
INIT_WORK(&qpriv->opfn.opfn_work, opfn_send_conn_request);
INIT_WORK(&qpriv->tid_rdma.trigger_work, tid_rdma_trigger_resume);
qpriv->flow_state.psn = 0;
qpriv->flow_state.index = RXE_NUM_TID_FLOWS;
qpriv->flow_state.last_index = RXE_NUM_TID_FLOWS;
qpriv->flow_state.generation = KERN_GENERATION_RESERVED;
qpriv->s_state = TID_OP(WRITE_RESP);
qpriv->s_tid_cur = HFI1_QP_WQE_INVALID;
qpriv->s_tid_head = HFI1_QP_WQE_INVALID;
qpriv->s_tid_tail = HFI1_QP_WQE_INVALID;
qpriv->rnr_nak_state = TID_RNR_NAK_INIT;
qpriv->r_tid_head = HFI1_QP_WQE_INVALID;
qpriv->r_tid_tail = HFI1_QP_WQE_INVALID;
qpriv->r_tid_ack = HFI1_QP_WQE_INVALID;
qpriv->r_tid_alloc = HFI1_QP_WQE_INVALID;
atomic_set(&qpriv->n_requests, 0);
atomic_set(&qpriv->n_tid_requests, 0);
timer_setup(&qpriv->s_tid_timer, hfi1_tid_timeout, 0);
timer_setup(&qpriv->s_tid_retry_timer, hfi1_tid_retry_timeout, 0);
INIT_LIST_HEAD(&qpriv->tid_wait);
if (init_attr->qp_type == IB_QPT_RC && HFI1_CAP_IS_KSET(TID_RDMA)) {
struct hfi1_devdata *dd = qpriv->rcd->dd;
qpriv->pages = kzalloc_node(TID_RDMA_MAX_PAGES *
sizeof(*qpriv->pages),
GFP_KERNEL, dd->node);
if (!qpriv->pages)
return -ENOMEM;
for (i = 0; i < qp->s_size; i++) {
struct hfi1_swqe_priv *priv;
struct rvt_swqe *wqe = rvt_get_swqe_ptr(qp, i);
priv = kzalloc_node(sizeof(*priv), GFP_KERNEL,
dd->node);
if (!priv)
return -ENOMEM;
hfi1_init_trdma_req(qp, &priv->tid_req);
priv->tid_req.e.swqe = wqe;
wqe->priv = priv;
}
for (i = 0; i < rvt_max_atomic(rdi); i++) {
struct hfi1_ack_priv *priv;
priv = kzalloc_node(sizeof(*priv), GFP_KERNEL,
dd->node);
if (!priv)
return -ENOMEM;
hfi1_init_trdma_req(qp, &priv->tid_req);
priv->tid_req.e.ack = &qp->s_ack_queue[i];
ret = hfi1_kern_exp_rcv_alloc_flows(&priv->tid_req,
GFP_KERNEL);
if (ret) {
kfree(priv);
return ret;
}
qp->s_ack_queue[i].priv = priv;
}
}
return 0;
}
void hfi1_qp_priv_tid_free(struct rvt_dev_info *rdi, struct rvt_qp *qp)
{
struct hfi1_qp_priv *qpriv = qp->priv;
struct rvt_swqe *wqe;
u32 i;
if (qp->ibqp.qp_type == IB_QPT_RC && HFI1_CAP_IS_KSET(TID_RDMA)) {
for (i = 0; i < qp->s_size; i++) {
wqe = rvt_get_swqe_ptr(qp, i);
kfree(wqe->priv);
wqe->priv = NULL;
}
for (i = 0; i < rvt_max_atomic(rdi); i++) {
struct hfi1_ack_priv *priv = qp->s_ack_queue[i].priv;
if (priv)
hfi1_kern_exp_rcv_free_flows(&priv->tid_req);
kfree(priv);
qp->s_ack_queue[i].priv = NULL;
}
cancel_work_sync(&qpriv->opfn.opfn_work);
kfree(qpriv->pages);
qpriv->pages = NULL;
}
}
/* Flow and tid waiter functions */
/**
* DOC: lock ordering
*
* There are two locks involved with the queuing
* routines: the qp s_lock and the exp_lock.
*
* Since the tid space allocation is called from
* the send engine, the qp s_lock is already held.
*
* The allocation routines will get the exp_lock.
*
* The first_qp() call is provided to allow the head of
* the rcd wait queue to be fetched under the exp_lock and
* followed by a drop of the exp_lock.
*
* Any qp in the wait list will have the qp reference count held
* to hold the qp in memory.
*/
/*
* return head of rcd wait list
*
* Must hold the exp_lock.
*
* Get a reference to the QP to hold the QP in memory.
*
* The caller must release the reference when the local
* is no longer being used.
*/
static struct rvt_qp *first_qp(struct hfi1_ctxtdata *rcd,
struct tid_queue *queue)
__must_hold(&rcd->exp_lock)
{
struct hfi1_qp_priv *priv;
lockdep_assert_held(&rcd->exp_lock);
priv = list_first_entry_or_null(&queue->queue_head,
struct hfi1_qp_priv,
tid_wait);
if (!priv)
return NULL;
rvt_get_qp(priv->owner);
return priv->owner;
}
/**
* kernel_tid_waiters - determine rcd wait
* @rcd: the receive context
* @qp: the head of the qp being processed
*
* This routine will return false IFF
* the list is NULL or the head of the
* list is the indicated qp.
*
* Must hold the qp s_lock and the exp_lock.
*
* Return:
* false if either of the conditions below are satisfied:
* 1. The list is empty or
* 2. The indicated qp is at the head of the list and the
* HFI1_S_WAIT_TID_SPACE bit is set in qp->s_flags.
* true is returned otherwise.
*/
static bool kernel_tid_waiters(struct hfi1_ctxtdata *rcd,
struct tid_queue *queue, struct rvt_qp *qp)
__must_hold(&rcd->exp_lock) __must_hold(&qp->s_lock)
{
struct rvt_qp *fqp;
bool ret = true;
lockdep_assert_held(&qp->s_lock);
lockdep_assert_held(&rcd->exp_lock);
fqp = first_qp(rcd, queue);
if (!fqp || (fqp == qp && (qp->s_flags & HFI1_S_WAIT_TID_SPACE)))
ret = false;
rvt_put_qp(fqp);
return ret;
}
/**
* dequeue_tid_waiter - dequeue the qp from the list
* @qp - the qp to remove the wait list
*
* This routine removes the indicated qp from the
* wait list if it is there.
*
* This should be done after the hardware flow and
* tid array resources have been allocated.
*
* Must hold the qp s_lock and the rcd exp_lock.
*
* It assumes the s_lock to protect the s_flags
* field and to reliably test the HFI1_S_WAIT_TID_SPACE flag.
*/
static void dequeue_tid_waiter(struct hfi1_ctxtdata *rcd,
struct tid_queue *queue, struct rvt_qp *qp)
__must_hold(&rcd->exp_lock) __must_hold(&qp->s_lock)
{
struct hfi1_qp_priv *priv = qp->priv;
lockdep_assert_held(&qp->s_lock);
lockdep_assert_held(&rcd->exp_lock);
if (list_empty(&priv->tid_wait))
return;
list_del_init(&priv->tid_wait);
qp->s_flags &= ~HFI1_S_WAIT_TID_SPACE;
queue->dequeue++;
rvt_put_qp(qp);
}
/**
* queue_qp_for_tid_wait - suspend QP on tid space
* @rcd: the receive context
* @qp: the qp
*
* The qp is inserted at the tail of the rcd
* wait queue and the HFI1_S_WAIT_TID_SPACE s_flag is set.
*
* Must hold the qp s_lock and the exp_lock.
*/
static void queue_qp_for_tid_wait(struct hfi1_ctxtdata *rcd,
struct tid_queue *queue, struct rvt_qp *qp)
__must_hold(&rcd->exp_lock) __must_hold(&qp->s_lock)
{
struct hfi1_qp_priv *priv = qp->priv;
lockdep_assert_held(&qp->s_lock);
lockdep_assert_held(&rcd->exp_lock);
if (list_empty(&priv->tid_wait)) {
qp->s_flags |= HFI1_S_WAIT_TID_SPACE;
list_add_tail(&priv->tid_wait, &queue->queue_head);
priv->tid_enqueue = ++queue->enqueue;
rcd->dd->verbs_dev.n_tidwait++;
trace_hfi1_qpsleep(qp, HFI1_S_WAIT_TID_SPACE);
rvt_get_qp(qp);
}
}
/**
* __trigger_tid_waiter - trigger tid waiter
* @qp: the qp
*
* This is a private entrance to schedule the qp
* assuming the caller is holding the qp->s_lock.
*/
static void __trigger_tid_waiter(struct rvt_qp *qp)
__must_hold(&qp->s_lock)
{
lockdep_assert_held(&qp->s_lock);
if (!(qp->s_flags & HFI1_S_WAIT_TID_SPACE))
return;
trace_hfi1_qpwakeup(qp, HFI1_S_WAIT_TID_SPACE);
hfi1_schedule_send(qp);
}
/**
* tid_rdma_schedule_tid_wakeup - schedule wakeup for a qp
* @qp - the qp
*
* trigger a schedule or a waiting qp in a deadlock
* safe manner. The qp reference is held prior
* to this call via first_qp().
*
* If the qp trigger was already scheduled (!rval)
* the the reference is dropped, otherwise the resume
* or the destroy cancel will dispatch the reference.
*/
static void tid_rdma_schedule_tid_wakeup(struct rvt_qp *qp)
{
struct hfi1_qp_priv *priv;
struct hfi1_ibport *ibp;
struct hfi1_pportdata *ppd;
struct hfi1_devdata *dd;
bool rval;
if (!qp)
return;
priv = qp->priv;
ibp = to_iport(qp->ibqp.device, qp->port_num);
ppd = ppd_from_ibp(ibp);
dd = dd_from_ibdev(qp->ibqp.device);
rval = queue_work_on(priv->s_sde ?
priv->s_sde->cpu :
cpumask_first(cpumask_of_node(dd->node)),
ppd->hfi1_wq,
&priv->tid_rdma.trigger_work);
if (!rval)
rvt_put_qp(qp);
}
/**
* tid_rdma_trigger_resume - field a trigger work request
* @work - the work item
*
* Complete the off qp trigger processing by directly
* calling the progress routine.
*/
static void tid_rdma_trigger_resume(struct work_struct *work)
{
struct tid_rdma_qp_params *tr;
struct hfi1_qp_priv *priv;
struct rvt_qp *qp;
tr = container_of(work, struct tid_rdma_qp_params, trigger_work);
priv = container_of(tr, struct hfi1_qp_priv, tid_rdma);
qp = priv->owner;
spin_lock_irq(&qp->s_lock);
if (qp->s_flags & HFI1_S_WAIT_TID_SPACE) {
spin_unlock_irq(&qp->s_lock);
hfi1_do_send(priv->owner, true);
} else {
spin_unlock_irq(&qp->s_lock);
}
rvt_put_qp(qp);
}
/**
* tid_rdma_flush_wait - unwind any tid space wait
*
* This is called when resetting a qp to
* allow a destroy or reset to get rid
* of any tid space linkage and reference counts.
*/
static void _tid_rdma_flush_wait(struct rvt_qp *qp, struct tid_queue *queue)
__must_hold(&qp->s_lock)
{
struct hfi1_qp_priv *priv;
if (!qp)
return;
lockdep_assert_held(&qp->s_lock);
priv = qp->priv;
qp->s_flags &= ~HFI1_S_WAIT_TID_SPACE;
spin_lock(&priv->rcd->exp_lock);
if (!list_empty(&priv->tid_wait)) {
list_del_init(&priv->tid_wait);
qp->s_flags &= ~HFI1_S_WAIT_TID_SPACE;
queue->dequeue++;
rvt_put_qp(qp);
}
spin_unlock(&priv->rcd->exp_lock);
}
void hfi1_tid_rdma_flush_wait(struct rvt_qp *qp)
__must_hold(&qp->s_lock)
{
struct hfi1_qp_priv *priv = qp->priv;
_tid_rdma_flush_wait(qp, &priv->rcd->flow_queue);
_tid_rdma_flush_wait(qp, &priv->rcd->rarr_queue);
}
/* Flow functions */
/**
* kern_reserve_flow - allocate a hardware flow
* @rcd - the context to use for allocation
* @last - the index of the preferred flow. Use RXE_NUM_TID_FLOWS to
* signify "don't care".
*
* Use a bit mask based allocation to reserve a hardware
* flow for use in receiving KDETH data packets. If a preferred flow is
* specified the function will attempt to reserve that flow again, if
* available.
*
* The exp_lock must be held.
*
* Return:
* On success: a value postive value between 0 and RXE_NUM_TID_FLOWS - 1
* On failure: -EAGAIN
*/
static int kern_reserve_flow(struct hfi1_ctxtdata *rcd, int last)
__must_hold(&rcd->exp_lock)
{
int nr;
/* Attempt to reserve the preferred flow index */
if (last >= 0 && last < RXE_NUM_TID_FLOWS &&
!test_and_set_bit(last, &rcd->flow_mask))
return last;
nr = ffz(rcd->flow_mask);
BUILD_BUG_ON(RXE_NUM_TID_FLOWS >=
(sizeof(rcd->flow_mask) * BITS_PER_BYTE));
if (nr > (RXE_NUM_TID_FLOWS - 1))
return -EAGAIN;
set_bit(nr, &rcd->flow_mask);
return nr;
}
static void kern_set_hw_flow(struct hfi1_ctxtdata *rcd, u32 generation,
u32 flow_idx)
{
u64 reg;
reg = ((u64)generation << HFI1_KDETH_BTH_SEQ_SHIFT) |
RCV_TID_FLOW_TABLE_CTRL_FLOW_VALID_SMASK |
RCV_TID_FLOW_TABLE_CTRL_KEEP_AFTER_SEQ_ERR_SMASK |
RCV_TID_FLOW_TABLE_CTRL_KEEP_ON_GEN_ERR_SMASK |
RCV_TID_FLOW_TABLE_STATUS_SEQ_MISMATCH_SMASK |
RCV_TID_FLOW_TABLE_STATUS_GEN_MISMATCH_SMASK;
if (generation != KERN_GENERATION_RESERVED)
reg |= RCV_TID_FLOW_TABLE_CTRL_HDR_SUPP_EN_SMASK;
write_uctxt_csr(rcd->dd, rcd->ctxt,
RCV_TID_FLOW_TABLE + 8 * flow_idx, reg);
}
static u32 kern_setup_hw_flow(struct hfi1_ctxtdata *rcd, u32 flow_idx)
__must_hold(&rcd->exp_lock)
{
u32 generation = rcd->flows[flow_idx].generation;
kern_set_hw_flow(rcd, generation, flow_idx);
return generation;
}
static u32 kern_flow_generation_next(u32 gen)
{
u32 generation = mask_generation(gen + 1);
if (generation == KERN_GENERATION_RESERVED)
generation = mask_generation(generation + 1);
return generation;
}
static void kern_clear_hw_flow(struct hfi1_ctxtdata *rcd, u32 flow_idx)
__must_hold(&rcd->exp_lock)
{
rcd->flows[flow_idx].generation =
kern_flow_generation_next(rcd->flows[flow_idx].generation);
kern_set_hw_flow(rcd, KERN_GENERATION_RESERVED, flow_idx);
}
int hfi1_kern_setup_hw_flow(struct hfi1_ctxtdata *rcd, struct rvt_qp *qp)
{
struct hfi1_qp_priv *qpriv = (struct hfi1_qp_priv *)qp->priv;
struct tid_flow_state *fs = &qpriv->flow_state;
struct rvt_qp *fqp;
unsigned long flags;
int ret = 0;
/* The QP already has an allocated flow */
if (fs->index != RXE_NUM_TID_FLOWS)
return ret;
spin_lock_irqsave(&rcd->exp_lock, flags);
if (kernel_tid_waiters(rcd, &rcd->flow_queue, qp))
goto queue;
ret = kern_reserve_flow(rcd, fs->last_index);
if (ret < 0)
goto queue;
fs->index = ret;
fs->last_index = fs->index;
/* Generation received in a RESYNC overrides default flow generation */
if (fs->generation != KERN_GENERATION_RESERVED)
rcd->flows[fs->index].generation = fs->generation;
fs->generation = kern_setup_hw_flow(rcd, fs->index);
fs->psn = 0;
dequeue_tid_waiter(rcd, &rcd->flow_queue, qp);
/* get head before dropping lock */
fqp = first_qp(rcd, &rcd->flow_queue);
spin_unlock_irqrestore(&rcd->exp_lock, flags);
tid_rdma_schedule_tid_wakeup(fqp);
return 0;
queue:
queue_qp_for_tid_wait(rcd, &rcd->flow_queue, qp);
spin_unlock_irqrestore(&rcd->exp_lock, flags);
return -EAGAIN;
}
void hfi1_kern_clear_hw_flow(struct hfi1_ctxtdata *rcd, struct rvt_qp *qp)
{
struct hfi1_qp_priv *qpriv = (struct hfi1_qp_priv *)qp->priv;
struct tid_flow_state *fs = &qpriv->flow_state;
struct rvt_qp *fqp;
unsigned long flags;
if (fs->index >= RXE_NUM_TID_FLOWS)
return;
spin_lock_irqsave(&rcd->exp_lock, flags);
kern_clear_hw_flow(rcd, fs->index);
clear_bit(fs->index, &rcd->flow_mask);
fs->index = RXE_NUM_TID_FLOWS;
fs->psn = 0;
fs->generation = KERN_GENERATION_RESERVED;
/* get head before dropping lock */
fqp = first_qp(rcd, &rcd->flow_queue);
spin_unlock_irqrestore(&rcd->exp_lock, flags);
if (fqp == qp) {
__trigger_tid_waiter(fqp);
rvt_put_qp(fqp);
} else {
tid_rdma_schedule_tid_wakeup(fqp);
}
}
void hfi1_kern_init_ctxt_generations(struct hfi1_ctxtdata *rcd)
{
int i;
for (i = 0; i < RXE_NUM_TID_FLOWS; i++) {
rcd->flows[i].generation = mask_generation(prandom_u32());
kern_set_hw_flow(rcd, KERN_GENERATION_RESERVED, i);
}
}
/* TID allocation functions */
static u8 trdma_pset_order(struct tid_rdma_pageset *s)
{
u8 count = s->count;
return ilog2(count) + 1;
}
/**
* tid_rdma_find_phys_blocks_4k - get groups base on mr info
* @npages - number of pages
* @pages - pointer to an array of page structs
* @list - page set array to return
*
* This routine returns the number of groups associated with
* the current sge information. This implementation is based
* on the expected receive find_phys_blocks() adjusted to
* use the MR information vs. the pfn.
*
* Return:
* the number of RcvArray entries
*/
static u32 tid_rdma_find_phys_blocks_4k(struct tid_rdma_flow *flow,
struct page **pages,
u32 npages,
struct tid_rdma_pageset *list)
{
u32 pagecount, pageidx, setcount = 0, i;
void *vaddr, *this_vaddr;
if (!npages)
return 0;
/*
* Look for sets of physically contiguous pages in the user buffer.
* This will allow us to optimize Expected RcvArray entry usage by
* using the bigger supported sizes.
*/
vaddr = page_address(pages[0]);
trace_hfi1_tid_flow_page(flow->req->qp, flow, 0, 0, 0, vaddr);
for (pageidx = 0, pagecount = 1, i = 1; i <= npages; i++) {
this_vaddr = i < npages ? page_address(pages[i]) : NULL;
trace_hfi1_tid_flow_page(flow->req->qp, flow, i, 0, 0,
this_vaddr);
/*
* If the vaddr's are not sequential, pages are not physically
* contiguous.
*/
if (this_vaddr != (vaddr + PAGE_SIZE)) {
/*
* At this point we have to loop over the set of
* physically contiguous pages and break them down it
* sizes supported by the HW.
* There are two main constraints:
* 1. The max buffer size is MAX_EXPECTED_BUFFER.
* If the total set size is bigger than that
* program only a MAX_EXPECTED_BUFFER chunk.
* 2. The buffer size has to be a power of two. If
* it is not, round down to the closes power of
* 2 and program that size.
*/
while (pagecount) {
int maxpages = pagecount;
u32 bufsize = pagecount * PAGE_SIZE;
if (bufsize > MAX_EXPECTED_BUFFER)
maxpages =
MAX_EXPECTED_BUFFER >>
PAGE_SHIFT;
else if (!is_power_of_2(bufsize))
maxpages =
rounddown_pow_of_two(bufsize) >>
PAGE_SHIFT;
list[setcount].idx = pageidx;
list[setcount].count = maxpages;
trace_hfi1_tid_pageset(flow->req->qp, setcount,
list[setcount].idx,
list[setcount].count);
pagecount -= maxpages;
pageidx += maxpages;
setcount++;
}
pageidx = i;
pagecount = 1;
vaddr = this_vaddr;
} else {
vaddr += PAGE_SIZE;
pagecount++;
}
}
/* insure we always return an even number of sets */
if (setcount & 1)
list[setcount++].count = 0;
return setcount;
}
/**
* tid_flush_pages - dump out pages into pagesets
* @list - list of pagesets
* @idx - pointer to current page index
* @pages - number of pages to dump
* @sets - current number of pagesset
*
* This routine flushes out accumuated pages.
*
* To insure an even number of sets the
* code may add a filler.
*
* This can happen with when pages is not
* a power of 2 or pages is a power of 2
* less than the maximum pages.
*
* Return:
* The new number of sets
*/
static u32 tid_flush_pages(struct tid_rdma_pageset *list,
u32 *idx, u32 pages, u32 sets)
{
while (pages) {
u32 maxpages = pages;
if (maxpages > MAX_EXPECTED_PAGES)
maxpages = MAX_EXPECTED_PAGES;
else if (!is_power_of_2(maxpages))
maxpages = rounddown_pow_of_two(maxpages);
list[sets].idx = *idx;
list[sets++].count = maxpages;
*idx += maxpages;
pages -= maxpages;
}
/* might need a filler */
if (sets & 1)
list[sets++].count = 0;
return sets;
}
/**
* tid_rdma_find_phys_blocks_8k - get groups base on mr info
* @pages - pointer to an array of page structs
* @npages - number of pages
* @list - page set array to return
*
* This routine parses an array of pages to compute pagesets
* in an 8k compatible way.
*
* pages are tested two at a time, i, i + 1 for contiguous
* pages and i - 1 and i contiguous pages.
*
* If any condition is false, any accumlated pages are flushed and
* v0,v1 are emitted as separate PAGE_SIZE pagesets
*
* Otherwise, the current 8k is totaled for a future flush.
*
* Return:
* The number of pagesets
* list set with the returned number of pagesets
*
*/
static u32 tid_rdma_find_phys_blocks_8k(struct tid_rdma_flow *flow,
struct page **pages,
u32 npages,
struct tid_rdma_pageset *list)
{
u32 idx, sets = 0, i;
u32 pagecnt = 0;
void *v0, *v1, *vm1;
if (!npages)
return 0;
for (idx = 0, i = 0, vm1 = NULL; i < npages; i += 2) {
/* get a new v0 */
v0 = page_address(pages[i]);
trace_hfi1_tid_flow_page(flow->req->qp, flow, i, 1, 0, v0);
v1 = i + 1 < npages ?
page_address(pages[i + 1]) : NULL;
trace_hfi1_tid_flow_page(flow->req->qp, flow, i, 1, 1, v1);
/* compare i, i + 1 vaddr */
if (v1 != (v0 + PAGE_SIZE)) {
/* flush out pages */
sets = tid_flush_pages(list, &idx, pagecnt, sets);
/* output v0,v1 as two pagesets */
list[sets].idx = idx++;
list[sets++].count = 1;
if (v1) {
list[sets].count = 1;
list[sets++].idx = idx++;
} else {
list[sets++].count = 0;
}
vm1 = NULL;
pagecnt = 0;
continue;
}
/* i,i+1 consecutive, look at i-1,i */
if (vm1 && v0 != (vm1 + PAGE_SIZE)) {
/* flush out pages */
sets = tid_flush_pages(list, &idx, pagecnt, sets);
pagecnt = 0;
}
/* pages will always be a multiple of 8k */
pagecnt += 2;
/* save i-1 */
vm1 = v1;
/* move to next pair */
}
/* dump residual pages at end */
sets = tid_flush_pages(list, &idx, npages - idx, sets);
/* by design cannot be odd sets */
WARN_ON(sets & 1);
return sets;
}
/**
* Find pages for one segment of a sge array represented by @ss. The function
* does not check the sge, the sge must have been checked for alignment with a
* prior call to hfi1_kern_trdma_ok. Other sge checking is done as part of
* rvt_lkey_ok and rvt_rkey_ok. Also, the function only modifies the local sge
* copy maintained in @ss->sge, the original sge is not modified.
*
* Unlike IB RDMA WRITE, we can't decrement ss->num_sge here because we are not
* releasing the MR reference count at the same time. Otherwise, we'll "leak"
* references to the MR. This difference requires that we keep track of progress
* into the sg_list. This is done by the cur_seg cursor in the tid_rdma_request
* structure.
*/
static u32 kern_find_pages(struct tid_rdma_flow *flow,
struct page **pages,
struct rvt_sge_state *ss, bool *last)
{
struct tid_rdma_request *req = flow->req;
struct rvt_sge *sge = &ss->sge;
u32 length = flow->req->seg_len;
u32 len = PAGE_SIZE;
u32 i = 0;
while (length && req->isge < ss->num_sge) {
pages[i++] = virt_to_page(sge->vaddr);
sge->vaddr += len;
sge->length -= len;
sge->sge_length -= len;
if (!sge->sge_length) {
if (++req->isge < ss->num_sge)
*sge = ss->sg_list[req->isge - 1];
} else if (sge->length == 0 && sge->mr->lkey) {
if (++sge->n >= RVT_SEGSZ) {
++sge->m;
sge->n = 0;
}
sge->vaddr = sge->mr->map[sge->m]->segs[sge->n].vaddr;
sge->length = sge->mr->map[sge->m]->segs[sge->n].length;
}
length -= len;
}
flow->length = flow->req->seg_len - length;
*last = req->isge == ss->num_sge ? false : true;
return i;
}
static void dma_unmap_flow(struct tid_rdma_flow *flow)
{
struct hfi1_devdata *dd;
int i;
struct tid_rdma_pageset *pset;
dd = flow->req->rcd->dd;
for (i = 0, pset = &flow->pagesets[0]; i < flow->npagesets;
i++, pset++) {
if (pset->count && pset->addr) {
dma_unmap_page(&dd->pcidev->dev,
pset->addr,
PAGE_SIZE * pset->count,
DMA_FROM_DEVICE);
pset->mapped = 0;
}
}
}
static int dma_map_flow(struct tid_rdma_flow *flow, struct page **pages)
{
int i;
struct hfi1_devdata *dd = flow->req->rcd->dd;
struct tid_rdma_pageset *pset;
for (i = 0, pset = &flow->pagesets[0]; i < flow->npagesets;
i++, pset++) {
if (pset->count) {
pset->addr = dma_map_page(&dd->pcidev->dev,
pages[pset->idx],
0,
PAGE_SIZE * pset->count,
DMA_FROM_DEVICE);
if (dma_mapping_error(&dd->pcidev->dev, pset->addr)) {
dma_unmap_flow(flow);
return -ENOMEM;
}
pset->mapped = 1;
}
}
return 0;
}
static inline bool dma_mapped(struct tid_rdma_flow *flow)
{
return !!flow->pagesets[0].mapped;
}
/*
* Get pages pointers and identify contiguous physical memory chunks for a
* segment. All segments are of length flow->req->seg_len.
*/
static int kern_get_phys_blocks(struct tid_rdma_flow *flow,
struct page **pages,
struct rvt_sge_state *ss, bool *last)
{
u8 npages;
/* Reuse previously computed pagesets, if any */
if (flow->npagesets) {
trace_hfi1_tid_flow_alloc(flow->req->qp, flow->req->setup_head,
flow);
if (!dma_mapped(flow))
return dma_map_flow(flow, pages);
return 0;
}
npages = kern_find_pages(flow, pages, ss, last);
if (flow->req->qp->pmtu == enum_to_mtu(OPA_MTU_4096))
flow->npagesets =
tid_rdma_find_phys_blocks_4k(flow, pages, npages,
flow->pagesets);
else
flow->npagesets =
tid_rdma_find_phys_blocks_8k(flow, pages, npages,
flow->pagesets);
return dma_map_flow(flow, pages);
}
static inline void kern_add_tid_node(struct tid_rdma_flow *flow,
struct hfi1_ctxtdata *rcd, char *s,
struct tid_group *grp, u8 cnt)
{
struct kern_tid_node *node = &flow->tnode[flow->tnode_cnt++];
WARN_ON_ONCE(flow->tnode_cnt >=
(TID_RDMA_MAX_SEGMENT_SIZE >> PAGE_SHIFT));
if (WARN_ON_ONCE(cnt & 1))
dd_dev_err(rcd->dd,
"unexpected odd allocation cnt %u map 0x%x used %u",
cnt, grp->map, grp->used);
node->grp = grp;
node->map = grp->map;
node->cnt = cnt;
trace_hfi1_tid_node_add(flow->req->qp, s, flow->tnode_cnt - 1,
grp->base, grp->map, grp->used, cnt);
}
/*
* Try to allocate pageset_count TID's from TID groups for a context
*
* This function allocates TID's without moving groups between lists or
* modifying grp->map. This is done as follows, being cogizant of the lists
* between which the TID groups will move:
* 1. First allocate complete groups of 8 TID's since this is more efficient,
* these groups will move from group->full without affecting used
* 2. If more TID's are needed allocate from used (will move from used->full or
* stay in used)
* 3. If we still don't have the required number of TID's go back and look again
* at a complete group (will move from group->used)
*/
static int kern_alloc_tids(struct tid_rdma_flow *flow)
{
struct hfi1_ctxtdata *rcd = flow->req->rcd;
struct hfi1_devdata *dd = rcd->dd;
u32 ngroups, pageidx = 0;
struct tid_group *group = NULL, *used;
u8 use;
flow->tnode_cnt = 0;
ngroups = flow->npagesets / dd->rcv_entries.group_size;
if (!ngroups)
goto used_list;
/* First look at complete groups */
list_for_each_entry(group, &rcd->tid_group_list.list, list) {
kern_add_tid_node(flow, rcd, "complete groups", group,
group->size);
pageidx += group->size;
if (!--ngroups)
break;
}
if (pageidx >= flow->npagesets)
goto ok;
used_list:
/* Now look at partially used groups */
list_for_each_entry(used, &rcd->tid_used_list.list, list) {
use = min_t(u32, flow->npagesets - pageidx,
used->size - used->used);
kern_add_tid_node(flow, rcd, "used groups", used, use);
pageidx += use;
if (pageidx >= flow->npagesets)
goto ok;
}
/*
* Look again at a complete group, continuing from where we left.
* However, if we are at the head, we have reached the end of the
* complete groups list from the first loop above
*/
if (group && &group->list == &rcd->tid_group_list.list)
goto bail_eagain;
group = list_prepare_entry(group, &rcd->tid_group_list.list,
list);
if (list_is_last(&group->list, &rcd->tid_group_list.list))
goto bail_eagain;
group = list_next_entry(group, list);
use = min_t(u32, flow->npagesets - pageidx, group->size);
kern_add_tid_node(flow, rcd, "complete continue", group, use);
pageidx += use;
if (pageidx >= flow->npagesets)
goto ok;
bail_eagain:
trace_hfi1_msg_alloc_tids(flow->req->qp, " insufficient tids: needed ",
(u64)flow->npagesets);
return -EAGAIN;
ok:
return 0;
}
static void kern_program_rcv_group(struct tid_rdma_flow *flow, int grp_num,
u32 *pset_idx)
{
struct hfi1_ctxtdata *rcd = flow->req->rcd;
struct hfi1_devdata *dd = rcd->dd;
struct kern_tid_node *node = &flow->tnode[grp_num];
struct tid_group *grp = node->grp;
struct tid_rdma_pageset *pset;
u32 pmtu_pg = flow->req->qp->pmtu >> PAGE_SHIFT;
u32 rcventry, npages = 0, pair = 0, tidctrl;
u8 i, cnt = 0;
for (i = 0; i < grp->size; i++) {
rcventry = grp->base + i;
if (node->map & BIT(i) || cnt >= node->cnt) {
rcv_array_wc_fill(dd, rcventry);
continue;
}
pset = &flow->pagesets[(*pset_idx)++];
if (pset->count) {
hfi1_put_tid(dd, rcventry, PT_EXPECTED,
pset->addr, trdma_pset_order(pset));
} else {
hfi1_put_tid(dd, rcventry, PT_INVALID, 0, 0);
}
npages += pset->count;
rcventry -= rcd->expected_base;
tidctrl = pair ? 0x3 : rcventry & 0x1 ? 0x2 : 0x1;
/*
* A single TID entry will be used to use a rcvarr pair (with
* tidctrl 0x3), if ALL these are true (a) the bit pos is even
* (b) the group map shows current and the next bits as free
* indicating two consecutive rcvarry entries are available (c)
* we actually need 2 more entries
*/
pair = !(i & 0x1) && !((node->map >> i) & 0x3) &&
node->cnt >= cnt + 2;
if (!pair) {
if (!pset->count)
tidctrl = 0x1;
flow->tid_entry[flow->tidcnt++] =
EXP_TID_SET(IDX, rcventry >> 1) |
EXP_TID_SET(CTRL, tidctrl) |
EXP_TID_SET(LEN, npages);
trace_hfi1_tid_entry_alloc(/* entry */
flow->req->qp, flow->tidcnt - 1,
flow->tid_entry[flow->tidcnt - 1]);
/* Efficient DIV_ROUND_UP(npages, pmtu_pg) */
flow->npkts += (npages + pmtu_pg - 1) >> ilog2(pmtu_pg);
npages = 0;
}
if (grp->used == grp->size - 1)
tid_group_move(grp, &rcd->tid_used_list,
&rcd->tid_full_list);
else if (!grp->used)
tid_group_move(grp, &rcd->tid_group_list,
&rcd->tid_used_list);
grp->used++;
grp->map |= BIT(i);
cnt++;
}
}
static void kern_unprogram_rcv_group(struct tid_rdma_flow *flow, int grp_num)
{
struct hfi1_ctxtdata *rcd = flow->req->rcd;
struct hfi1_devdata *dd = rcd->dd;
struct kern_tid_node *node = &flow->tnode[grp_num];
struct tid_group *grp = node->grp;
u32 rcventry;
u8 i, cnt = 0;
for (i = 0; i < grp->size; i++) {
rcventry = grp->base + i;
if (node->map & BIT(i) || cnt >= node->cnt) {
rcv_array_wc_fill(dd, rcventry);
continue;
}
hfi1_put_tid(dd, rcventry, PT_INVALID, 0, 0);
grp->used--;
grp->map &= ~BIT(i);
cnt++;
if (grp->used == grp->size - 1)
tid_group_move(grp, &rcd->tid_full_list,
&rcd->tid_used_list);
else if (!grp->used)
tid_group_move(grp, &rcd->tid_used_list,
&rcd->tid_group_list);
}
if (WARN_ON_ONCE(cnt & 1)) {
struct hfi1_ctxtdata *rcd = flow->req->rcd;
struct hfi1_devdata *dd = rcd->dd;
dd_dev_err(dd, "unexpected odd free cnt %u map 0x%x used %u",
cnt, grp->map, grp->used);
}
}
static void kern_program_rcvarray(struct tid_rdma_flow *flow)
{
u32 pset_idx = 0;
int i;
flow->npkts = 0;
flow->tidcnt = 0;
for (i = 0; i < flow->tnode_cnt; i++)
kern_program_rcv_group(flow, i, &pset_idx);
trace_hfi1_tid_flow_alloc(flow->req->qp, flow->req->setup_head, flow);
}
/**
* hfi1_kern_exp_rcv_setup() - setup TID's and flow for one segment of a
* TID RDMA request
*
* @req: TID RDMA request for which the segment/flow is being set up
* @ss: sge state, maintains state across successive segments of a sge
* @last: set to true after the last sge segment has been processed
*
* This function
* (1) finds a free flow entry in the flow circular buffer
* (2) finds pages and continuous physical chunks constituing one segment
* of an sge
* (3) allocates TID group entries for those chunks
* (4) programs rcvarray entries in the hardware corresponding to those
* TID's
* (5) computes a tidarray with formatted TID entries which can be sent
* to the sender
* (6) Reserves and programs HW flows.
* (7) It also manages queing the QP when TID/flow resources are not
* available.
*
* @req points to struct tid_rdma_request of which the segments are a part. The
* function uses qp, rcd and seg_len members of @req. In the absence of errors,
* req->flow_idx is the index of the flow which has been prepared in this
* invocation of function call. With flow = &req->flows[req->flow_idx],
* flow->tid_entry contains the TID array which the sender can use for TID RDMA
* sends and flow->npkts contains number of packets required to send the
* segment.
*
* hfi1_check_sge_align should be called prior to calling this function and if
* it signals error TID RDMA cannot be used for this sge and this function
* should not be called.
*
* For the queuing, caller must hold the flow->req->qp s_lock from the send
* engine and the function will procure the exp_lock.
*
* Return:
* The function returns -EAGAIN if sufficient number of TID/flow resources to
* map the segment could not be allocated. In this case the function should be
* called again with previous arguments to retry the TID allocation. There are
* no other error returns. The function returns 0 on success.
*/
int hfi1_kern_exp_rcv_setup(struct tid_rdma_request *req,
struct rvt_sge_state *ss, bool *last)
__must_hold(&req->qp->s_lock)
{
struct tid_rdma_flow *flow = &req->flows[req->setup_head];
struct hfi1_ctxtdata *rcd = req->rcd;
struct hfi1_qp_priv *qpriv = req->qp->priv;
unsigned long flags;
struct rvt_qp *fqp;
u16 clear_tail = req->clear_tail;
lockdep_assert_held(&req->qp->s_lock);
/*
* We return error if either (a) we don't have space in the flow
* circular buffer, or (b) we already have max entries in the buffer.
* Max entries depend on the type of request we are processing and the
* negotiated TID RDMA parameters.
*/
if (!CIRC_SPACE(req->setup_head, clear_tail, MAX_FLOWS) ||
CIRC_CNT(req->setup_head, clear_tail, MAX_FLOWS) >=
req->n_flows)
return -EINVAL;
/*
* Get pages, identify contiguous physical memory chunks for the segment
* If we can not determine a DMA address mapping we will treat it just
* like if we ran out of space above.
*/
if (kern_get_phys_blocks(flow, qpriv->pages, ss, last)) {
hfi1_wait_kmem(flow->req->qp);
return -ENOMEM;
}
spin_lock_irqsave(&rcd->exp_lock, flags);
if (kernel_tid_waiters(rcd, &rcd->rarr_queue, flow->req->qp))
goto queue;
/*
* At this point we know the number of pagesets and hence the number of
* TID's to map the segment. Allocate the TID's from the TID groups. If
* we cannot allocate the required number we exit and try again later
*/
if (kern_alloc_tids(flow))
goto queue;
/*
* Finally program the TID entries with the pagesets, compute the
* tidarray and enable the HW flow
*/
kern_program_rcvarray(flow);
/*
* Setup the flow state with relevant information.
* This information is used for tracking the sequence of data packets
* for the segment.
* The flow is setup here as this is the most accurate time and place
* to do so. Doing at a later time runs the risk of the flow data in
* qpriv getting out of sync.
*/
memset(&flow->flow_state, 0x0, sizeof(flow->flow_state));
flow->idx = qpriv->flow_state.index;
flow->flow_state.generation = qpriv->flow_state.generation;
flow->flow_state.spsn = qpriv->flow_state.psn;
flow->flow_state.lpsn = flow->flow_state.spsn + flow->npkts - 1;
flow->flow_state.r_next_psn =
full_flow_psn(flow, flow->flow_state.spsn);
qpriv->flow_state.psn += flow->npkts;
dequeue_tid_waiter(rcd, &rcd->rarr_queue, flow->req->qp);
/* get head before dropping lock */
fqp = first_qp(rcd, &rcd->rarr_queue);
spin_unlock_irqrestore(&rcd->exp_lock, flags);
tid_rdma_schedule_tid_wakeup(fqp);
req->setup_head = (req->setup_head + 1) & (MAX_FLOWS - 1);
return 0;
queue:
queue_qp_for_tid_wait(rcd, &rcd->rarr_queue, flow->req->qp);
spin_unlock_irqrestore(&rcd->exp_lock, flags);
return -EAGAIN;
}
static void hfi1_tid_rdma_reset_flow(struct tid_rdma_flow *flow)
{
flow->npagesets = 0;
}
/*
* This function is called after one segment has been successfully sent to
* release the flow and TID HW/SW resources for that segment. The segments for a
* TID RDMA request are setup and cleared in FIFO order which is managed using a
* circular buffer.
*/
int hfi1_kern_exp_rcv_clear(struct tid_rdma_request *req)
__must_hold(&req->qp->s_lock)
{
struct tid_rdma_flow *flow = &req->flows[req->clear_tail];
struct hfi1_ctxtdata *rcd = req->rcd;
unsigned long flags;
int i;
struct rvt_qp *fqp;
lockdep_assert_held(&req->qp->s_lock);
/* Exit if we have nothing in the flow circular buffer */
if (!CIRC_CNT(req->setup_head, req->clear_tail, MAX_FLOWS))
return -EINVAL;
spin_lock_irqsave(&rcd->exp_lock, flags);
for (i = 0; i < flow->tnode_cnt; i++)
kern_unprogram_rcv_group(flow, i);
/* To prevent double unprogramming */
flow->tnode_cnt = 0;
/* get head before dropping lock */
fqp = first_qp(rcd, &rcd->rarr_queue);
spin_unlock_irqrestore(&rcd->exp_lock, flags);
dma_unmap_flow(flow);
hfi1_tid_rdma_reset_flow(flow);
req->clear_tail = (req->clear_tail + 1) & (MAX_FLOWS - 1);
if (fqp == req->qp) {
__trigger_tid_waiter(fqp);
rvt_put_qp(fqp);
} else {
tid_rdma_schedule_tid_wakeup(fqp);
}
return 0;
}
/*
* This function is called to release all the tid entries for
* a request.
*/
void hfi1_kern_exp_rcv_clear_all(struct tid_rdma_request *req)
__must_hold(&req->qp->s_lock)
{
/* Use memory barrier for proper ordering */
while (CIRC_CNT(req->setup_head, req->clear_tail, MAX_FLOWS)) {
if (hfi1_kern_exp_rcv_clear(req))
break;
}
}
/**
* hfi1_kern_exp_rcv_free_flows - free priviously allocated flow information
* @req - the tid rdma request to be cleaned
*/
static void hfi1_kern_exp_rcv_free_flows(struct tid_rdma_request *req)
{
kfree(req->flows);
req->flows = NULL;
}
/**
* __trdma_clean_swqe - clean up for large sized QPs
* @qp: the queue patch
* @wqe: the send wqe
*/
void __trdma_clean_swqe(struct rvt_qp *qp, struct rvt_swqe *wqe)
{
struct hfi1_swqe_priv *p = wqe->priv;
hfi1_kern_exp_rcv_free_flows(&p->tid_req);
}
/*
* This can be called at QP create time or in the data path.
*/
static int hfi1_kern_exp_rcv_alloc_flows(struct tid_rdma_request *req,
gfp_t gfp)
{
struct tid_rdma_flow *flows;
int i;
if (likely(req->flows))
return 0;
flows = kmalloc_node(MAX_FLOWS * sizeof(*flows), gfp,
req->rcd->numa_id);
if (!flows)
return -ENOMEM;
/* mini init */
for (i = 0; i < MAX_FLOWS; i++) {
flows[i].req = req;
flows[i].npagesets = 0;
flows[i].pagesets[0].mapped = 0;
flows[i].resync_npkts = 0;
}
req->flows = flows;
return 0;
}
static void hfi1_init_trdma_req(struct rvt_qp *qp,
struct tid_rdma_request *req)
{
struct hfi1_qp_priv *qpriv = qp->priv;
/*
* Initialize various TID RDMA request variables.
* These variables are "static", which is why they
* can be pre-initialized here before the WRs has
* even been submitted.
* However, non-NULL values for these variables do not
* imply that this WQE has been enabled for TID RDMA.
* Drivers should check the WQE's opcode to determine
* if a request is a TID RDMA one or not.
*/
req->qp = qp;
req->rcd = qpriv->rcd;
}
u64 hfi1_access_sw_tid_wait(const struct cntr_entry *entry,
void *context, int vl, int mode, u64 data)
{
struct hfi1_devdata *dd = context;
return dd->verbs_dev.n_tidwait;
}
static struct tid_rdma_flow *find_flow_ib(struct tid_rdma_request *req,
u32 psn, u16 *fidx)
{
u16 head, tail;
struct tid_rdma_flow *flow;
head = req->setup_head;
tail = req->clear_tail;
for ( ; CIRC_CNT(head, tail, MAX_FLOWS);
tail = CIRC_NEXT(tail, MAX_FLOWS)) {
flow = &req->flows[tail];
if (cmp_psn(psn, flow->flow_state.ib_spsn) >= 0 &&
cmp_psn(psn, flow->flow_state.ib_lpsn) <= 0) {
if (fidx)
*fidx = tail;
return flow;
}
}
return NULL;
}
static struct tid_rdma_flow *
__find_flow_ranged(struct tid_rdma_request *req, u16 head, u16 tail,
u32 psn, u16 *fidx)
{
for ( ; CIRC_CNT(head, tail, MAX_FLOWS);
tail = CIRC_NEXT(tail, MAX_FLOWS)) {
struct tid_rdma_flow *flow = &req->flows[tail];
u32 spsn, lpsn;
spsn = full_flow_psn(flow, flow->flow_state.spsn);
lpsn = full_flow_psn(flow, flow->flow_state.lpsn);
if (cmp_psn(psn, spsn) >= 0 && cmp_psn(psn, lpsn) <= 0) {
if (fidx)
*fidx = tail;
return flow;
}
}
return NULL;
}
static struct tid_rdma_flow *find_flow(struct tid_rdma_request *req,
u32 psn, u16 *fidx)
{
return __find_flow_ranged(req, req->setup_head, req->clear_tail, psn,
fidx);
}
/* TID RDMA READ functions */
u32 hfi1_build_tid_rdma_read_packet(struct rvt_swqe *wqe,
struct ib_other_headers *ohdr, u32 *bth1,
u32 *bth2, u32 *len)
{
struct tid_rdma_request *req = wqe_to_tid_req(wqe);
struct tid_rdma_flow *flow = &req->flows[req->flow_idx];
struct rvt_qp *qp = req->qp;
struct hfi1_qp_priv *qpriv = qp->priv;
struct hfi1_swqe_priv *wpriv = wqe->priv;
struct tid_rdma_read_req *rreq = &ohdr->u.tid_rdma.r_req;
struct tid_rdma_params *remote;
u32 req_len = 0;
void *req_addr = NULL;
/* This is the IB psn used to send the request */
*bth2 = mask_psn(flow->flow_state.ib_spsn + flow->pkt);
trace_hfi1_tid_flow_build_read_pkt(qp, req->flow_idx, flow);
/* TID Entries for TID RDMA READ payload */
req_addr = &flow->tid_entry[flow->tid_idx];
req_len = sizeof(*flow->tid_entry) *
(flow->tidcnt - flow->tid_idx);
memset(&ohdr->u.tid_rdma.r_req, 0, sizeof(ohdr->u.tid_rdma.r_req));
wpriv->ss.sge.vaddr = req_addr;
wpriv->ss.sge.sge_length = req_len;
wpriv->ss.sge.length = wpriv->ss.sge.sge_length;
/*
* We can safely zero these out. Since the first SGE covers the
* entire packet, nothing else should even look at the MR.
*/
wpriv->ss.sge.mr = NULL;
wpriv->ss.sge.m = 0;
wpriv->ss.sge.n = 0;
wpriv->ss.sg_list = NULL;
wpriv->ss.total_len = wpriv->ss.sge.sge_length;
wpriv->ss.num_sge = 1;
/* Construct the TID RDMA READ REQ packet header */
rcu_read_lock();
remote = rcu_dereference(qpriv->tid_rdma.remote);
KDETH_RESET(rreq->kdeth0, KVER, 0x1);
KDETH_RESET(rreq->kdeth1, JKEY, remote->jkey);
rreq->reth.vaddr = cpu_to_be64(wqe->rdma_wr.remote_addr +
req->cur_seg * req->seg_len + flow->sent);
rreq->reth.rkey = cpu_to_be32(wqe->rdma_wr.rkey);
rreq->reth.length = cpu_to_be32(*len);
rreq->tid_flow_psn =
cpu_to_be32((flow->flow_state.generation <<
HFI1_KDETH_BTH_SEQ_SHIFT) |
((flow->flow_state.spsn + flow->pkt) &
HFI1_KDETH_BTH_SEQ_MASK));
rreq->tid_flow_qp =
cpu_to_be32(qpriv->tid_rdma.local.qp |
((flow->idx & TID_RDMA_DESTQP_FLOW_MASK) <<
TID_RDMA_DESTQP_FLOW_SHIFT) |
qpriv->rcd->ctxt);
rreq->verbs_qp = cpu_to_be32(qp->remote_qpn);
*bth1 &= ~RVT_QPN_MASK;
*bth1 |= remote->qp;
*bth2 |= IB_BTH_REQ_ACK;
rcu_read_unlock();
/* We are done with this segment */
flow->sent += *len;
req->cur_seg++;
qp->s_state = TID_OP(READ_REQ);
req->ack_pending++;
req->flow_idx = (req->flow_idx + 1) & (MAX_FLOWS - 1);
qpriv->pending_tid_r_segs++;
qp->s_num_rd_atomic++;
/* Set the TID RDMA READ request payload size */
*len = req_len;
return sizeof(ohdr->u.tid_rdma.r_req) / sizeof(u32);
}
/*
* @len: contains the data length to read upon entry and the read request
* payload length upon exit.
*/
u32 hfi1_build_tid_rdma_read_req(struct rvt_qp *qp, struct rvt_swqe *wqe,
struct ib_other_headers *ohdr, u32 *bth1,
u32 *bth2, u32 *len)
__must_hold(&qp->s_lock)
{
struct hfi1_qp_priv *qpriv = qp->priv;
struct tid_rdma_request *req = wqe_to_tid_req(wqe);
struct tid_rdma_flow *flow = NULL;
u32 hdwords = 0;
bool last;
bool retry = true;
u32 npkts = rvt_div_round_up_mtu(qp, *len);
trace_hfi1_tid_req_build_read_req(qp, 0, wqe->wr.opcode, wqe->psn,
wqe->lpsn, req);
/*
* Check sync conditions. Make sure that there are no pending
* segments before freeing the flow.
*/
sync_check:
if (req->state == TID_REQUEST_SYNC) {
if (qpriv->pending_tid_r_segs)
goto done;
hfi1_kern_clear_hw_flow(req->rcd, qp);
qpriv->s_flags &= ~HFI1_R_TID_SW_PSN;
req->state = TID_REQUEST_ACTIVE;
}
/*
* If the request for this segment is resent, the tid resources should
* have been allocated before. In this case, req->flow_idx should
* fall behind req->setup_head.
*/
if (req->flow_idx == req->setup_head) {
retry = false;
if (req->state == TID_REQUEST_RESEND) {
/*
* This is the first new segment for a request whose
* earlier segments have been re-sent. We need to
* set up the sge pointer correctly.
*/
restart_sge(&qp->s_sge, wqe, req->s_next_psn,
qp->pmtu);
req->isge = 0;
req->state = TID_REQUEST_ACTIVE;
}
/*
* Check sync. The last PSN of each generation is reserved for
* RESYNC.
*/
if ((qpriv->flow_state.psn + npkts) > MAX_TID_FLOW_PSN - 1) {
req->state = TID_REQUEST_SYNC;
goto sync_check;
}
/* Allocate the flow if not yet */
if (hfi1_kern_setup_hw_flow(qpriv->rcd, qp))
goto done;
/*
* The following call will advance req->setup_head after
* allocating the tid entries.
*/
if (hfi1_kern_exp_rcv_setup(req, &qp->s_sge, &last)) {
req->state = TID_REQUEST_QUEUED;
/*
* We don't have resources for this segment. The QP has
* already been queued.
*/
goto done;
}
}
/* req->flow_idx should only be one slot behind req->setup_head */
flow = &req->flows[req->flow_idx];
flow->pkt = 0;
flow->tid_idx = 0;
flow->sent = 0;
if (!retry) {
/* Set the first and last IB PSN for the flow in use.*/
flow->flow_state.ib_spsn = req->s_next_psn;
flow->flow_state.ib_lpsn =
flow->flow_state.ib_spsn + flow->npkts - 1;
}
/* Calculate the next segment start psn.*/
req->s_next_psn += flow->npkts;
/* Build the packet header */
hdwords = hfi1_build_tid_rdma_read_packet(wqe, ohdr, bth1, bth2, len);
done:
return hdwords;
}
/*
* Validate and accept the TID RDMA READ request parameters.
* Return 0 if the request is accepted successfully;
* Return 1 otherwise.
*/
static int tid_rdma_rcv_read_request(struct rvt_qp *qp,
struct rvt_ack_entry *e,
struct hfi1_packet *packet,
struct ib_other_headers *ohdr,
u32 bth0, u32 psn, u64 vaddr, u32 len)
{
struct hfi1_qp_priv *qpriv = qp->priv;
struct tid_rdma_request *req;
struct tid_rdma_flow *flow;
u32 flow_psn, i, tidlen = 0, pktlen, tlen;
req = ack_to_tid_req(e);
/* Validate the payload first */
flow = &req->flows[req->setup_head];
/* payload length = packet length - (header length + ICRC length) */
pktlen = packet->tlen - (packet->hlen + 4);
if (pktlen > sizeof(flow->tid_entry))
return 1;
memcpy(flow->tid_entry, packet->ebuf, pktlen);
flow->tidcnt = pktlen / sizeof(*flow->tid_entry);
/*
* Walk the TID_ENTRY list to make sure we have enough space for a
* complete segment. Also calculate the number of required packets.
*/
flow->npkts = rvt_div_round_up_mtu(qp, len);
for (i = 0; i < flow->tidcnt; i++) {
trace_hfi1_tid_entry_rcv_read_req(qp, i,
flow->tid_entry[i]);
tlen = EXP_TID_GET(flow->tid_entry[i], LEN);
if (!tlen)
return 1;
/*
* For tid pair (tidctr == 3), the buffer size of the pair
* should be the sum of the buffer size described by each
* tid entry. However, only the first entry needs to be
* specified in the request (see WFR HAS Section 8.5.7.1).
*/
tidlen += tlen;
}
if (tidlen * PAGE_SIZE < len)
return 1;
/* Empty the flow array */
req->clear_tail = req->setup_head;
flow->pkt = 0;
flow->tid_idx = 0;
flow->tid_offset = 0;
flow->sent = 0;
flow->tid_qpn = be32_to_cpu(ohdr->u.tid_rdma.r_req.tid_flow_qp);
flow->idx = (flow->tid_qpn >> TID_RDMA_DESTQP_FLOW_SHIFT) &
TID_RDMA_DESTQP_FLOW_MASK;
flow_psn = mask_psn(be32_to_cpu(ohdr->u.tid_rdma.r_req.tid_flow_psn));
flow->flow_state.generation = flow_psn >> HFI1_KDETH_BTH_SEQ_SHIFT;
flow->flow_state.spsn = flow_psn & HFI1_KDETH_BTH_SEQ_MASK;
flow->length = len;
flow->flow_state.lpsn = flow->flow_state.spsn +
flow->npkts - 1;
flow->flow_state.ib_spsn = psn;
flow->flow_state.ib_lpsn = flow->flow_state.ib_spsn + flow->npkts - 1;
trace_hfi1_tid_flow_rcv_read_req(qp, req->setup_head, flow);
/* Set the initial flow index to the current flow. */
req->flow_idx = req->setup_head;
/* advance circular buffer head */
req->setup_head = (req->setup_head + 1) & (MAX_FLOWS - 1);
/*
* Compute last PSN for request.
*/
e->opcode = (bth0 >> 24) & 0xff;
e->psn = psn;
e->lpsn = psn + flow->npkts - 1;
e->sent = 0;
req->n_flows = qpriv->tid_rdma.local.max_read;
req->state = TID_REQUEST_ACTIVE;
req->cur_seg = 0;
req->comp_seg = 0;
req->ack_seg = 0;
req->isge = 0;
req->seg_len = qpriv->tid_rdma.local.max_len;
req->total_len = len;
req->total_segs = 1;
req->r_flow_psn = e->psn;
trace_hfi1_tid_req_rcv_read_req(qp, 0, e->opcode, e->psn, e->lpsn,
req);
return 0;
}
static int tid_rdma_rcv_error(struct hfi1_packet *packet,
struct ib_other_headers *ohdr,
struct rvt_qp *qp, u32 psn, int diff)
{
struct hfi1_ibport *ibp = to_iport(qp->ibqp.device, qp->port_num);
struct hfi1_ctxtdata *rcd = ((struct hfi1_qp_priv *)qp->priv)->rcd;
struct hfi1_ibdev *dev = to_idev(qp->ibqp.device);
struct hfi1_qp_priv *qpriv = qp->priv;
struct rvt_ack_entry *e;
struct tid_rdma_request *req;
unsigned long flags;
u8 prev;
bool old_req;
trace_hfi1_rsp_tid_rcv_error(qp, psn);
trace_hfi1_tid_rdma_rcv_err(qp, 0, psn, diff);
if (diff > 0) {
/* sequence error */
if (!qp->r_nak_state) {
ibp->rvp.n_rc_seqnak++;
qp->r_nak_state = IB_NAK_PSN_ERROR;
qp->r_ack_psn = qp->r_psn;
rc_defered_ack(rcd, qp);
}
goto done;
}
ibp->rvp.n_rc_dupreq++;
spin_lock_irqsave(&qp->s_lock, flags);
e = find_prev_entry(qp, psn, &prev, NULL, &old_req);
if (!e || (e->opcode != TID_OP(READ_REQ) &&
e->opcode != TID_OP(WRITE_REQ)))
goto unlock;
req = ack_to_tid_req(e);
req->r_flow_psn = psn;
trace_hfi1_tid_req_rcv_err(qp, 0, e->opcode, e->psn, e->lpsn, req);
if (e->opcode == TID_OP(READ_REQ)) {
struct ib_reth *reth;
u32 len;
u32 rkey;
u64 vaddr;
int ok;
u32 bth0;
reth = &ohdr->u.tid_rdma.r_req.reth;
/*
* The requester always restarts from the start of the original
* request.
*/
len = be32_to_cpu(reth->length);
if (psn != e->psn || len != req->total_len)
goto unlock;
release_rdma_sge_mr(e);
rkey = be32_to_cpu(reth->rkey);
vaddr = get_ib_reth_vaddr(reth);
qp->r_len = len;
ok = rvt_rkey_ok(qp, &e->rdma_sge, len, vaddr, rkey,
IB_ACCESS_REMOTE_READ);
if (unlikely(!ok))
goto unlock;
/*
* If all the response packets for the current request have
* been sent out and this request is complete (old_request
* == false) and the TID flow may be unusable (the
* req->clear_tail is advanced). However, when an earlier
* request is received, this request will not be complete any
* more (qp->s_tail_ack_queue is moved back, see below).
* Consequently, we need to update the TID flow info everytime
* a duplicate request is received.
*/
bth0 = be32_to_cpu(ohdr->bth[0]);
if (tid_rdma_rcv_read_request(qp, e, packet, ohdr, bth0, psn,
vaddr, len))
goto unlock;
/*
* True if the request is already scheduled (between
* qp->s_tail_ack_queue and qp->r_head_ack_queue);
*/
if (old_req)
goto unlock;
} else {
struct flow_state *fstate;
bool schedule = false;
u8 i;
if (req->state == TID_REQUEST_RESEND) {
req->state = TID_REQUEST_RESEND_ACTIVE;
} else if (req->state == TID_REQUEST_INIT_RESEND) {
req->state = TID_REQUEST_INIT;
schedule = true;
}
/*
* True if the request is already scheduled (between
* qp->s_tail_ack_queue and qp->r_head_ack_queue).
* Also, don't change requests, which are at the SYNC
* point and haven't generated any responses yet.
* There is nothing to retransmit for them yet.
*/
if (old_req || req->state == TID_REQUEST_INIT ||
(req->state == TID_REQUEST_SYNC && !req->cur_seg)) {
for (i = prev + 1; ; i++) {
if (i > rvt_size_atomic(&dev->rdi))
i = 0;
if (i == qp->r_head_ack_queue)
break;
e = &qp->s_ack_queue[i];
req = ack_to_tid_req(e);
if (e->opcode == TID_OP(WRITE_REQ) &&
req->state == TID_REQUEST_INIT)
req->state = TID_REQUEST_INIT_RESEND;
}
/*
* If the state of the request has been changed,
* the first leg needs to get scheduled in order to
* pick up the change. Otherwise, normal response
* processing should take care of it.
*/
if (!schedule)
goto unlock;
}
/*
* If there is no more allocated segment, just schedule the qp
* without changing any state.
*/
if (req->clear_tail == req->setup_head)
goto schedule;
/*
* If this request has sent responses for segments, which have
* not received data yet (flow_idx != clear_tail), the flow_idx
* pointer needs to be adjusted so the same responses can be
* re-sent.
*/
if (CIRC_CNT(req->flow_idx, req->clear_tail, MAX_FLOWS)) {
fstate = &req->flows[req->clear_tail].flow_state;
qpriv->pending_tid_w_segs -=
CIRC_CNT(req->flow_idx, req->clear_tail,
MAX_FLOWS);
req->flow_idx =
CIRC_ADD(req->clear_tail,
delta_psn(psn, fstate->resp_ib_psn),
MAX_FLOWS);
qpriv->pending_tid_w_segs +=
delta_psn(psn, fstate->resp_ib_psn);
/*
* When flow_idx == setup_head, we've gotten a duplicate
* request for a segment, which has not been allocated
* yet. In that case, don't adjust this request.
* However, we still want to go through the loop below
* to adjust all subsequent requests.
*/
if (CIRC_CNT(req->setup_head, req->flow_idx,
MAX_FLOWS)) {
req->cur_seg = delta_psn(psn, e->psn);
req->state = TID_REQUEST_RESEND_ACTIVE;
}
}
for (i = prev + 1; ; i++) {
/*
* Look at everything up to and including
* s_tail_ack_queue
*/
if (i > rvt_size_atomic(&dev->rdi))
i = 0;
if (i == qp->r_head_ack_queue)
break;
e = &qp->s_ack_queue[i];
req = ack_to_tid_req(e);
trace_hfi1_tid_req_rcv_err(qp, 0, e->opcode, e->psn,
e->lpsn, req);
if (e->opcode != TID_OP(WRITE_REQ) ||
req->cur_seg == req->comp_seg ||
req->state == TID_REQUEST_INIT ||
req->state == TID_REQUEST_INIT_RESEND) {
if (req->state == TID_REQUEST_INIT)
req->state = TID_REQUEST_INIT_RESEND;
continue;
}
qpriv->pending_tid_w_segs -=
CIRC_CNT(req->flow_idx,
req->clear_tail,
MAX_FLOWS);
req->flow_idx = req->clear_tail;
req->state = TID_REQUEST_RESEND;
req->cur_seg = req->comp_seg;
}
qpriv->s_flags &= ~HFI1_R_TID_WAIT_INTERLCK;
}
/* Re-process old requests.*/
if (qp->s_acked_ack_queue == qp->s_tail_ack_queue)
qp->s_acked_ack_queue = prev;
qp->s_tail_ack_queue = prev;
/*
* Since the qp->s_tail_ack_queue is modified, the
* qp->s_ack_state must be changed to re-initialize
* qp->s_ack_rdma_sge; Otherwise, we will end up in
* wrong memory region.
*/
qp->s_ack_state = OP(ACKNOWLEDGE);
schedule:
/*
* It's possible to receive a retry psn that is earlier than an RNRNAK
* psn. In this case, the rnrnak state should be cleared.
*/
if (qpriv->rnr_nak_state) {
qp->s_nak_state = 0;
qpriv->rnr_nak_state = TID_RNR_NAK_INIT;
qp->r_psn = e->lpsn + 1;
hfi1_tid_write_alloc_resources(qp, true);
}
qp->r_state = e->opcode;
qp->r_nak_state = 0;
qp->s_flags |= RVT_S_RESP_PENDING;
hfi1_schedule_send(qp);
unlock:
spin_unlock_irqrestore(&qp->s_lock, flags);
done:
return 1;
}
void hfi1_rc_rcv_tid_rdma_read_req(struct hfi1_packet *packet)
{
/* HANDLER FOR TID RDMA READ REQUEST packet (Responder side)*/
/*
* 1. Verify TID RDMA READ REQ as per IB_OPCODE_RC_RDMA_READ
* (see hfi1_rc_rcv())
* 2. Put TID RDMA READ REQ into the response queueu (s_ack_queue)
* - Setup struct tid_rdma_req with request info
* - Initialize struct tid_rdma_flow info;
* - Copy TID entries;
* 3. Set the qp->s_ack_state.
* 4. Set RVT_S_RESP_PENDING in s_flags.
* 5. Kick the send engine (hfi1_schedule_send())
*/
struct hfi1_ctxtdata *rcd = packet->rcd;
struct rvt_qp *qp = packet->qp;
struct hfi1_ibport *ibp = to_iport(qp->ibqp.device, qp->port_num);
struct ib_other_headers *ohdr = packet->ohdr;
struct rvt_ack_entry *e;
unsigned long flags;
struct ib_reth *reth;
struct hfi1_qp_priv *qpriv = qp->priv;
u32 bth0, psn, len, rkey;
bool fecn;
u8 next;
u64 vaddr;
int diff;
u8 nack_state = IB_NAK_INVALID_REQUEST;
bth0 = be32_to_cpu(ohdr->bth[0]);
if (hfi1_ruc_check_hdr(ibp, packet))
return;
fecn = process_ecn(qp, packet);
psn = mask_psn(be32_to_cpu(ohdr->bth[2]));
trace_hfi1_rsp_rcv_tid_read_req(qp, psn);
if (qp->state == IB_QPS_RTR && !(qp->r_flags & RVT_R_COMM_EST))
rvt_comm_est(qp);
if (unlikely(!(qp->qp_access_flags & IB_ACCESS_REMOTE_READ)))
goto nack_inv;
reth = &ohdr->u.tid_rdma.r_req.reth;
vaddr = be64_to_cpu(reth->vaddr);
len = be32_to_cpu(reth->length);
/* The length needs to be in multiples of PAGE_SIZE */
if (!len || len & ~PAGE_MASK || len > qpriv->tid_rdma.local.max_len)
goto nack_inv;
diff = delta_psn(psn, qp->r_psn);
if (unlikely(diff)) {
tid_rdma_rcv_err(packet, ohdr, qp, psn, diff, fecn);
return;
}
/* We've verified the request, insert it into the ack queue. */
next = qp->r_head_ack_queue + 1;
if (next > rvt_size_atomic(ib_to_rvt(qp->ibqp.device)))
next = 0;
spin_lock_irqsave(&qp->s_lock, flags);
if (unlikely(next == qp->s_tail_ack_queue)) {
if (!qp->s_ack_queue[next].sent) {
nack_state = IB_NAK_REMOTE_OPERATIONAL_ERROR;
goto nack_inv_unlock;
}
update_ack_queue(qp, next);
}
e = &qp->s_ack_queue[qp->r_head_ack_queue];
release_rdma_sge_mr(e);
rkey = be32_to_cpu(reth->rkey);
qp->r_len = len;
if (unlikely(!rvt_rkey_ok(qp, &e->rdma_sge, qp->r_len, vaddr,
rkey, IB_ACCESS_REMOTE_READ)))
goto nack_acc;
/* Accept the request parameters */
if (tid_rdma_rcv_read_request(qp, e, packet, ohdr, bth0, psn, vaddr,
len))
goto nack_inv_unlock;
qp->r_state = e->opcode;
qp->r_nak_state = 0;
/*
* We need to increment the MSN here instead of when we
* finish sending the result since a duplicate request would
* increment it more than once.
*/
qp->r_msn++;
qp->r_psn += e->lpsn - e->psn + 1;
qp->r_head_ack_queue = next;
/*
* For all requests other than TID WRITE which are added to the ack
* queue, qpriv->r_tid_alloc follows qp->r_head_ack_queue. It is ok to
* do this because of interlocks between these and TID WRITE
* requests. The same change has also been made in hfi1_rc_rcv().
*/
qpriv->r_tid_alloc = qp->r_head_ack_queue;
/* Schedule the send tasklet. */
qp->s_flags |= RVT_S_RESP_PENDING;
if (fecn)
qp->s_flags |= RVT_S_ECN;
hfi1_schedule_send(qp);
spin_unlock_irqrestore(&qp->s_lock, flags);
return;
nack_inv_unlock:
spin_unlock_irqrestore(&qp->s_lock, flags);
nack_inv:
rvt_rc_error(qp, IB_WC_LOC_QP_OP_ERR);
qp->r_nak_state = nack_state;
qp->r_ack_psn = qp->r_psn;
/* Queue NAK for later */
rc_defered_ack(rcd, qp);
return;
nack_acc:
spin_unlock_irqrestore(&qp->s_lock, flags);
rvt_rc_error(qp, IB_WC_LOC_PROT_ERR);
qp->r_nak_state = IB_NAK_REMOTE_ACCESS_ERROR;
qp->r_ack_psn = qp->r_psn;
}
u32 hfi1_build_tid_rdma_read_resp(struct rvt_qp *qp, struct rvt_ack_entry *e,
struct ib_other_headers *ohdr, u32 *bth0,
u32 *bth1, u32 *bth2, u32 *len, bool *last)
{
struct hfi1_ack_priv *epriv = e->priv;
struct tid_rdma_request *req = &epriv->tid_req;
struct hfi1_qp_priv *qpriv = qp->priv;
struct tid_rdma_flow *flow = &req->flows[req->clear_tail];
u32 tidentry = flow->tid_entry[flow->tid_idx];
u32 tidlen = EXP_TID_GET(tidentry, LEN) << PAGE_SHIFT;
struct tid_rdma_read_resp *resp = &ohdr->u.tid_rdma.r_rsp;
u32 next_offset, om = KDETH_OM_LARGE;
bool last_pkt;
u32 hdwords = 0;
struct tid_rdma_params *remote;
*len = min_t(u32, qp->pmtu, tidlen - flow->tid_offset);
flow->sent += *len;
next_offset = flow->tid_offset + *len;
last_pkt = (flow->sent >= flow->length);
trace_hfi1_tid_entry_build_read_resp(qp, flow->tid_idx, tidentry);
trace_hfi1_tid_flow_build_read_resp(qp, req->clear_tail, flow);
rcu_read_lock();
remote = rcu_dereference(qpriv->tid_rdma.remote);
if (!remote) {
rcu_read_unlock();
goto done;
}
KDETH_RESET(resp->kdeth0, KVER, 0x1);
KDETH_SET(resp->kdeth0, SH, !last_pkt);
KDETH_SET(resp->kdeth0, INTR, !!(!last_pkt && remote->urg));
KDETH_SET(resp->kdeth0, TIDCTRL, EXP_TID_GET(tidentry, CTRL));
KDETH_SET(resp->kdeth0, TID, EXP_TID_GET(tidentry, IDX));
KDETH_SET(resp->kdeth0, OM, om == KDETH_OM_LARGE);
KDETH_SET(resp->kdeth0, OFFSET, flow->tid_offset / om);
KDETH_RESET(resp->kdeth1, JKEY, remote->jkey);
resp->verbs_qp = cpu_to_be32(qp->remote_qpn);
rcu_read_unlock();
resp->aeth = rvt_compute_aeth(qp);
resp->verbs_psn = cpu_to_be32(mask_psn(flow->flow_state.ib_spsn +
flow->pkt));
*bth0 = TID_OP(READ_RESP) << 24;
*bth1 = flow->tid_qpn;
*bth2 = mask_psn(((flow->flow_state.spsn + flow->pkt++) &
HFI1_KDETH_BTH_SEQ_MASK) |
(flow->flow_state.generation <<
HFI1_KDETH_BTH_SEQ_SHIFT));
*last = last_pkt;
if (last_pkt)
/* Advance to next flow */
req->clear_tail = (req->clear_tail + 1) &
(MAX_FLOWS - 1);
if (next_offset >= tidlen) {
flow->tid_offset = 0;
flow->tid_idx++;
} else {
flow->tid_offset = next_offset;
}
hdwords = sizeof(ohdr->u.tid_rdma.r_rsp) / sizeof(u32);
done:
return hdwords;
}
static inline struct tid_rdma_request *
find_tid_request(struct rvt_qp *qp, u32 psn, enum ib_wr_opcode opcode)
__must_hold(&qp->s_lock)
{
struct rvt_swqe *wqe;
struct tid_rdma_request *req = NULL;
u32 i, end;
end = qp->s_cur + 1;
if (end == qp->s_size)
end = 0;
for (i = qp->s_acked; i != end;) {
wqe = rvt_get_swqe_ptr(qp, i);
if (cmp_psn(psn, wqe->psn) >= 0 &&
cmp_psn(psn, wqe->lpsn) <= 0) {
if (wqe->wr.opcode == opcode)
req = wqe_to_tid_req(wqe);
break;
}
if (++i == qp->s_size)
i = 0;
}
return req;
}
void hfi1_rc_rcv_tid_rdma_read_resp(struct hfi1_packet *packet)
{
/* HANDLER FOR TID RDMA READ RESPONSE packet (Requestor side */
/*
* 1. Find matching SWQE
* 2. Check that the entire segment has been read.
* 3. Remove HFI1_S_WAIT_TID_RESP from s_flags.
* 4. Free the TID flow resources.
* 5. Kick the send engine (hfi1_schedule_send())
*/
struct ib_other_headers *ohdr = packet->ohdr;
struct rvt_qp *qp = packet->qp;
struct hfi1_qp_priv *priv = qp->priv;
struct hfi1_ctxtdata *rcd = packet->rcd;
struct tid_rdma_request *req;
struct tid_rdma_flow *flow;
u32 opcode, aeth;
bool fecn;
unsigned long flags;
u32 kpsn, ipsn;
trace_hfi1_sender_rcv_tid_read_resp(qp);
fecn = process_ecn(qp, packet);
kpsn = mask_psn(be32_to_cpu(ohdr->bth[2]));
aeth = be32_to_cpu(ohdr->u.tid_rdma.r_rsp.aeth);
opcode = (be32_to_cpu(ohdr->bth[0]) >> 24) & 0xff;
spin_lock_irqsave(&qp->s_lock, flags);
ipsn = mask_psn(be32_to_cpu(ohdr->u.tid_rdma.r_rsp.verbs_psn));
req = find_tid_request(qp, ipsn, IB_WR_TID_RDMA_READ);
if (unlikely(!req))
goto ack_op_err;
flow = &req->flows[req->clear_tail];
/* When header suppression is disabled */
if (cmp_psn(ipsn, flow->flow_state.ib_lpsn)) {
update_r_next_psn_fecn(packet, priv, rcd, flow, fecn);
if (cmp_psn(kpsn, flow->flow_state.r_next_psn))
goto ack_done;
flow->flow_state.r_next_psn = mask_psn(kpsn + 1);
/*
* Copy the payload to destination buffer if this packet is
* delivered as an eager packet due to RSM rule and FECN.
* The RSM rule selects FECN bit in BTH and SH bit in
* KDETH header and therefore will not match the last
* packet of each segment that has SH bit cleared.
*/
if (fecn && packet->etype == RHF_RCV_TYPE_EAGER) {
struct rvt_sge_state ss;
u32 len;
u32 tlen = packet->tlen;
u16 hdrsize = packet->hlen;
u8 pad = packet->pad;
u8 extra_bytes = pad + packet->extra_byte +
(SIZE_OF_CRC << 2);
u32 pmtu = qp->pmtu;
if (unlikely(tlen != (hdrsize + pmtu + extra_bytes)))
goto ack_op_err;
len = restart_sge(&ss, req->e.swqe, ipsn, pmtu);
if (unlikely(len < pmtu))
goto ack_op_err;
rvt_copy_sge(qp, &ss, packet->payload, pmtu, false,
false);
/* Raise the sw sequence check flag for next packet */
priv->s_flags |= HFI1_R_TID_SW_PSN;
}
goto ack_done;
}
flow->flow_state.r_next_psn = mask_psn(kpsn + 1);
req->ack_pending--;
priv->pending_tid_r_segs--;
qp->s_num_rd_atomic--;
if ((qp->s_flags & RVT_S_WAIT_FENCE) &&
!qp->s_num_rd_atomic) {
qp->s_flags &= ~(RVT_S_WAIT_FENCE |
RVT_S_WAIT_ACK);
hfi1_schedule_send(qp);
}
if (qp->s_flags & RVT_S_WAIT_RDMAR) {
qp->s_flags &= ~(RVT_S_WAIT_RDMAR | RVT_S_WAIT_ACK);
hfi1_schedule_send(qp);
}
trace_hfi1_ack(qp, ipsn);
trace_hfi1_tid_req_rcv_read_resp(qp, 0, req->e.swqe->wr.opcode,
req->e.swqe->psn, req->e.swqe->lpsn,
req);
trace_hfi1_tid_flow_rcv_read_resp(qp, req->clear_tail, flow);
/* Release the tid resources */
hfi1_kern_exp_rcv_clear(req);
if (!do_rc_ack(qp, aeth, ipsn, opcode, 0, rcd))
goto ack_done;
/* If not done yet, build next read request */
if (++req->comp_seg >= req->total_segs) {
priv->tid_r_comp++;
req->state = TID_REQUEST_COMPLETE;
}
/*
* Clear the hw flow under two conditions:
* 1. This request is a sync point and it is complete;
* 2. Current request is completed and there are no more requests.
*/
if ((req->state == TID_REQUEST_SYNC &&
req->comp_seg == req->cur_seg) ||
priv->tid_r_comp == priv->tid_r_reqs) {
hfi1_kern_clear_hw_flow(priv->rcd, qp);
priv->s_flags &= ~HFI1_R_TID_SW_PSN;
if (req->state == TID_REQUEST_SYNC)
req->state = TID_REQUEST_ACTIVE;
}
hfi1_schedule_send(qp);
goto ack_done;
ack_op_err:
/*
* The test indicates that the send engine has finished its cleanup
* after sending the request and it's now safe to put the QP into error
* state. However, if the wqe queue is empty (qp->s_acked == qp->s_tail
* == qp->s_head), it would be unsafe to complete the wqe pointed by
* qp->s_acked here. Putting the qp into error state will safely flush
* all remaining requests.
*/
if (qp->s_last == qp->s_acked)
rvt_error_qp(qp, IB_WC_WR_FLUSH_ERR);
ack_done:
spin_unlock_irqrestore(&qp->s_lock, flags);
}
void hfi1_kern_read_tid_flow_free(struct rvt_qp *qp)
__must_hold(&qp->s_lock)
{
u32 n = qp->s_acked;
struct rvt_swqe *wqe;
struct tid_rdma_request *req;
struct hfi1_qp_priv *priv = qp->priv;
lockdep_assert_held(&qp->s_lock);
/* Free any TID entries */
while (n != qp->s_tail) {
wqe = rvt_get_swqe_ptr(qp, n);
if (wqe->wr.opcode == IB_WR_TID_RDMA_READ) {
req = wqe_to_tid_req(wqe);
hfi1_kern_exp_rcv_clear_all(req);
}
if (++n == qp->s_size)
n = 0;
}
/* Free flow */
hfi1_kern_clear_hw_flow(priv->rcd, qp);
}
static bool tid_rdma_tid_err(struct hfi1_ctxtdata *rcd,
struct hfi1_packet *packet, u8 rcv_type,
u8 opcode)
{
struct rvt_qp *qp = packet->qp;
struct hfi1_qp_priv *qpriv = qp->priv;
u32 ipsn;
struct ib_other_headers *ohdr = packet->ohdr;
struct rvt_ack_entry *e;
struct tid_rdma_request *req;
struct rvt_dev_info *rdi = ib_to_rvt(qp->ibqp.device);
u32 i;
if (rcv_type >= RHF_RCV_TYPE_IB)
goto done;
spin_lock(&qp->s_lock);
/*
* We've ran out of space in the eager buffer.
* Eagerly received KDETH packets which require space in the
* Eager buffer (packet that have payload) are TID RDMA WRITE
* response packets. In this case, we have to re-transmit the
* TID RDMA WRITE request.
*/
if (rcv_type == RHF_RCV_TYPE_EAGER) {
hfi1_restart_rc(qp, qp->s_last_psn + 1, 1);
hfi1_schedule_send(qp);
goto done_unlock;
}
/*
* For TID READ response, error out QP after freeing the tid
* resources.
*/
if (opcode == TID_OP(READ_RESP)) {
ipsn = mask_psn(be32_to_cpu(ohdr->u.tid_rdma.r_rsp.verbs_psn));
if (cmp_psn(ipsn, qp->s_last_psn) > 0 &&
cmp_psn(ipsn, qp->s_psn) < 0) {
hfi1_kern_read_tid_flow_free(qp);
spin_unlock(&qp->s_lock);
rvt_rc_error(qp, IB_WC_LOC_QP_OP_ERR);
goto done;
}
goto done_unlock;
}
/*
* Error out the qp for TID RDMA WRITE
*/
hfi1_kern_clear_hw_flow(qpriv->rcd, qp);
for (i = 0; i < rvt_max_atomic(rdi); i++) {
e = &qp->s_ack_queue[i];
if (e->opcode == TID_OP(WRITE_REQ)) {
req = ack_to_tid_req(e);
hfi1_kern_exp_rcv_clear_all(req);
}
}
spin_unlock(&qp->s_lock);
rvt_rc_error(qp, IB_WC_LOC_LEN_ERR);
goto done;
done_unlock:
spin_unlock(&qp->s_lock);
done:
return true;
}
static void restart_tid_rdma_read_req(struct hfi1_ctxtdata *rcd,
struct rvt_qp *qp, struct rvt_swqe *wqe)
{
struct tid_rdma_request *req;
struct tid_rdma_flow *flow;
/* Start from the right segment */
qp->r_flags |= RVT_R_RDMAR_SEQ;
req = wqe_to_tid_req(wqe);
flow = &req->flows[req->clear_tail];
hfi1_restart_rc(qp, flow->flow_state.ib_spsn, 0);
if (list_empty(&qp->rspwait)) {
qp->r_flags |= RVT_R_RSP_SEND;
rvt_get_qp(qp);
list_add_tail(&qp->rspwait, &rcd->qp_wait_list);
}
}
/*
* Handle the KDETH eflags for TID RDMA READ response.
*
* Return true if the last packet for a segment has been received and it is
* time to process the response normally; otherwise, return true.
*
* The caller must hold the packet->qp->r_lock and the rcu_read_lock.
*/
static bool handle_read_kdeth_eflags(struct hfi1_ctxtdata *rcd,
struct hfi1_packet *packet, u8 rcv_type,
u8 rte, u32 psn, u32 ibpsn)
__must_hold(&packet->qp->r_lock) __must_hold(RCU)
{
struct hfi1_pportdata *ppd = rcd->ppd;
struct hfi1_devdata *dd = ppd->dd;
struct hfi1_ibport *ibp;
struct rvt_swqe *wqe;
struct tid_rdma_request *req;
struct tid_rdma_flow *flow;
u32 ack_psn;
struct rvt_qp *qp = packet->qp;
struct hfi1_qp_priv *priv = qp->priv;
bool ret = true;
int diff = 0;
u32 fpsn;
lockdep_assert_held(&qp->r_lock);
/* If the psn is out of valid range, drop the packet */
if (cmp_psn(ibpsn, qp->s_last_psn) < 0 ||
cmp_psn(ibpsn, qp->s_psn) > 0)
return ret;
spin_lock(&qp->s_lock);
/*
* Note that NAKs implicitly ACK outstanding SEND and RDMA write
* requests and implicitly NAK RDMA read and atomic requests issued
* before the NAK'ed request.
*/
ack_psn = ibpsn - 1;
wqe = rvt_get_swqe_ptr(qp, qp->s_acked);
ibp = to_iport(qp->ibqp.device, qp->port_num);
/* Complete WQEs that the PSN finishes. */
while ((int)delta_psn(ack_psn, wqe->lpsn) >= 0) {
/*
* If this request is a RDMA read or atomic, and the NACK is
* for a later operation, this NACK NAKs the RDMA read or
* atomic.
*/
if (wqe->wr.opcode == IB_WR_RDMA_READ ||
wqe->wr.opcode == IB_WR_TID_RDMA_READ ||
wqe->wr.opcode == IB_WR_ATOMIC_CMP_AND_SWP ||
wqe->wr.opcode == IB_WR_ATOMIC_FETCH_AND_ADD) {
/* Retry this request. */
if (!(qp->r_flags & RVT_R_RDMAR_SEQ)) {
qp->r_flags |= RVT_R_RDMAR_SEQ;
if (wqe->wr.opcode == IB_WR_TID_RDMA_READ) {
restart_tid_rdma_read_req(rcd, qp,
wqe);
} else {
hfi1_restart_rc(qp, qp->s_last_psn + 1,
0);
if (list_empty(&qp->rspwait)) {
qp->r_flags |= RVT_R_RSP_SEND;
rvt_get_qp(qp);
list_add_tail(/* wait */
&qp->rspwait,
&rcd->qp_wait_list);
}
}
}
/*
* No need to process the NAK since we are
* restarting an earlier request.
*/
break;
}
wqe = do_rc_completion(qp, wqe, ibp);
if (qp->s_acked == qp->s_tail)
break;
}
/* Handle the eflags for the request */
if (wqe->wr.opcode != IB_WR_TID_RDMA_READ)
goto s_unlock;
req = wqe_to_tid_req(wqe);
switch (rcv_type) {
case RHF_RCV_TYPE_EXPECTED:
switch (rte) {
case RHF_RTE_EXPECTED_FLOW_SEQ_ERR:
/*
* On the first occurrence of a Flow Sequence error,
* the flag TID_FLOW_SW_PSN is set.
*
* After that, the flow is *not* reprogrammed and the
* protocol falls back to SW PSN checking. This is done
* to prevent continuous Flow Sequence errors for any
* packets that could be still in the fabric.
*/
flow = find_flow(req, psn, NULL);
if (!flow) {
/*
* We can't find the IB PSN matching the
* received KDETH PSN. The only thing we can
* do at this point is report the error to
* the QP.
*/
hfi1_kern_read_tid_flow_free(qp);
spin_unlock(&qp->s_lock);
rvt_rc_error(qp, IB_WC_LOC_QP_OP_ERR);
return ret;
}
if (priv->s_flags & HFI1_R_TID_SW_PSN) {
diff = cmp_psn(psn,
flow->flow_state.r_next_psn);
if (diff > 0) {
if (!(qp->r_flags & RVT_R_RDMAR_SEQ))
restart_tid_rdma_read_req(rcd,
qp,
wqe);
/* Drop the packet.*/
goto s_unlock;
} else if (diff < 0) {
/*
* If a response packet for a restarted
* request has come back, reset the
* restart flag.
*/
if (qp->r_flags & RVT_R_RDMAR_SEQ)
qp->r_flags &=
~RVT_R_RDMAR_SEQ;
/* Drop the packet.*/
goto s_unlock;
}
/*
* If SW PSN verification is successful and
* this is the last packet in the segment, tell
* the caller to process it as a normal packet.
*/
fpsn = full_flow_psn(flow,
flow->flow_state.lpsn);
if (cmp_psn(fpsn, psn) == 0) {
ret = false;
if (qp->r_flags & RVT_R_RDMAR_SEQ)
qp->r_flags &=
~RVT_R_RDMAR_SEQ;
}
flow->flow_state.r_next_psn =
mask_psn(psn + 1);
} else {
u32 last_psn;
last_psn = read_r_next_psn(dd, rcd->ctxt,
flow->idx);
flow->flow_state.r_next_psn = last_psn;
priv->s_flags |= HFI1_R_TID_SW_PSN;
/*
* If no request has been restarted yet,
* restart the current one.
*/
if (!(qp->r_flags & RVT_R_RDMAR_SEQ))
restart_tid_rdma_read_req(rcd, qp,
wqe);
}
break;
case RHF_RTE_EXPECTED_FLOW_GEN_ERR:
/*
* Since the TID flow is able to ride through
* generation mismatch, drop this stale packet.
*/
break;
default:
break;
}
break;
case RHF_RCV_TYPE_ERROR:
switch (rte) {
case RHF_RTE_ERROR_OP_CODE_ERR:
case RHF_RTE_ERROR_KHDR_MIN_LEN_ERR:
case RHF_RTE_ERROR_KHDR_HCRC_ERR:
case RHF_RTE_ERROR_KHDR_KVER_ERR:
case RHF_RTE_ERROR_CONTEXT_ERR:
case RHF_RTE_ERROR_KHDR_TID_ERR:
default:
break;
}
default:
break;
}
s_unlock:
spin_unlock(&qp->s_lock);
return ret;
}
bool hfi1_handle_kdeth_eflags(struct hfi1_ctxtdata *rcd,
struct hfi1_pportdata *ppd,
struct hfi1_packet *packet)
{
struct hfi1_ibport *ibp = &ppd->ibport_data;
struct hfi1_devdata *dd = ppd->dd;
struct rvt_dev_info *rdi = &dd->verbs_dev.rdi;
u8 rcv_type = rhf_rcv_type(packet->rhf);
u8 rte = rhf_rcv_type_err(packet->rhf);
struct ib_header *hdr = packet->hdr;
struct ib_other_headers *ohdr = NULL;
int lnh = be16_to_cpu(hdr->lrh[0]) & 3;
u16 lid = be16_to_cpu(hdr->lrh[1]);
u8 opcode;
u32 qp_num, psn, ibpsn;
struct rvt_qp *qp;
struct hfi1_qp_priv *qpriv;
unsigned long flags;
bool ret = true;
struct rvt_ack_entry *e;
struct tid_rdma_request *req;
struct tid_rdma_flow *flow;
int diff = 0;
trace_hfi1_msg_handle_kdeth_eflags(NULL, "Kdeth error: rhf ",
packet->rhf);
if (packet->rhf & RHF_ICRC_ERR)
return ret;
packet->ohdr = &hdr->u.oth;
ohdr = packet->ohdr;
trace_input_ibhdr(rcd->dd, packet, !!(rhf_dc_info(packet->rhf)));
/* Get the destination QP number. */
qp_num = be32_to_cpu(ohdr->u.tid_rdma.r_rsp.verbs_qp) &
RVT_QPN_MASK;
if (lid >= be16_to_cpu(IB_MULTICAST_LID_BASE))
goto drop;
psn = mask_psn(be32_to_cpu(ohdr->bth[2]));
opcode = (be32_to_cpu(ohdr->bth[0]) >> 24) & 0xff;
rcu_read_lock();
qp = rvt_lookup_qpn(rdi, &ibp->rvp, qp_num);
if (!qp)
goto rcu_unlock;
packet->qp = qp;
/* Check for valid receive state. */
spin_lock_irqsave(&qp->r_lock, flags);
if (!(ib_rvt_state_ops[qp->state] & RVT_PROCESS_RECV_OK)) {
ibp->rvp.n_pkt_drops++;
goto r_unlock;
}
if (packet->rhf & RHF_TID_ERR) {
/* For TIDERR and RC QPs preemptively schedule a NAK */
u32 tlen = rhf_pkt_len(packet->rhf); /* in bytes */
/* Sanity check packet */
if (tlen < 24)
goto r_unlock;
/*
* Check for GRH. We should never get packets with GRH in this
* path.
*/
if (lnh == HFI1_LRH_GRH)
goto r_unlock;
if (tid_rdma_tid_err(rcd, packet, rcv_type, opcode))
goto r_unlock;
}
/* handle TID RDMA READ */
if (opcode == TID_OP(READ_RESP)) {
ibpsn = be32_to_cpu(ohdr->u.tid_rdma.r_rsp.verbs_psn);
ibpsn = mask_psn(ibpsn);
ret = handle_read_kdeth_eflags(rcd, packet, rcv_type, rte, psn,
ibpsn);
goto r_unlock;
}
/*
* qp->s_tail_ack_queue points to the rvt_ack_entry currently being
* processed. These a completed sequentially so we can be sure that
* the pointer will not change until the entire request has completed.
*/
spin_lock(&qp->s_lock);
qpriv = qp->priv;
e = &qp->s_ack_queue[qpriv->r_tid_tail];
req = ack_to_tid_req(e);
flow = &req->flows[req->clear_tail];
trace_hfi1_eflags_err_write(qp, rcv_type, rte, psn);
trace_hfi1_rsp_handle_kdeth_eflags(qp, psn);
trace_hfi1_tid_write_rsp_handle_kdeth_eflags(qp);
trace_hfi1_tid_req_handle_kdeth_eflags(qp, 0, e->opcode, e->psn,
e->lpsn, req);
trace_hfi1_tid_flow_handle_kdeth_eflags(qp, req->clear_tail, flow);
switch (rcv_type) {
case RHF_RCV_TYPE_EXPECTED:
switch (rte) {
case RHF_RTE_EXPECTED_FLOW_SEQ_ERR:
if (!(qpriv->s_flags & HFI1_R_TID_SW_PSN)) {
qpriv->s_flags |= HFI1_R_TID_SW_PSN;
flow->flow_state.r_next_psn =
read_r_next_psn(dd, rcd->ctxt,
flow->idx);
qpriv->r_next_psn_kdeth =
flow->flow_state.r_next_psn;
goto nak_psn;
} else {
/*
* If the received PSN does not match the next
* expected PSN, NAK the packet.
* However, only do that if we know that the a
* NAK has already been sent. Otherwise, this
* mismatch could be due to packets that were
* already in flight.
*/
diff = cmp_psn(psn,
flow->flow_state.r_next_psn);
if (diff > 0)
goto nak_psn;
else if (diff < 0)
break;
qpriv->s_nak_state = 0;
/*
* If SW PSN verification is successful and this
* is the last packet in the segment, tell the
* caller to process it as a normal packet.
*/
if (psn == full_flow_psn(flow,
flow->flow_state.lpsn))
ret = false;
flow->flow_state.r_next_psn =
mask_psn(psn + 1);
qpriv->r_next_psn_kdeth =
flow->flow_state.r_next_psn;
}
break;
case RHF_RTE_EXPECTED_FLOW_GEN_ERR:
goto nak_psn;
default:
break;
}
break;
case RHF_RCV_TYPE_ERROR:
switch (rte) {
case RHF_RTE_ERROR_OP_CODE_ERR:
case RHF_RTE_ERROR_KHDR_MIN_LEN_ERR:
case RHF_RTE_ERROR_KHDR_HCRC_ERR:
case RHF_RTE_ERROR_KHDR_KVER_ERR:
case RHF_RTE_ERROR_CONTEXT_ERR:
case RHF_RTE_ERROR_KHDR_TID_ERR:
default:
break;
}
default:
break;
}
unlock:
spin_unlock(&qp->s_lock);
r_unlock:
spin_unlock_irqrestore(&qp->r_lock, flags);
rcu_unlock:
rcu_read_unlock();
drop:
return ret;
nak_psn:
ibp->rvp.n_rc_seqnak++;
if (!qpriv->s_nak_state) {
qpriv->s_nak_state = IB_NAK_PSN_ERROR;
/* We are NAK'ing the next expected PSN */
qpriv->s_nak_psn = mask_psn(flow->flow_state.r_next_psn);
qpriv->s_flags |= RVT_S_ACK_PENDING;
if (qpriv->r_tid_ack == HFI1_QP_WQE_INVALID)
qpriv->r_tid_ack = qpriv->r_tid_tail;
hfi1_schedule_tid_send(qp);
}
goto unlock;
}
/*
* "Rewind" the TID request information.
* This means that we reset the state back to ACTIVE,
* find the proper flow, set the flow index to that flow,
* and reset the flow information.
*/
void hfi1_tid_rdma_restart_req(struct rvt_qp *qp, struct rvt_swqe *wqe,
u32 *bth2)
{
struct tid_rdma_request *req = wqe_to_tid_req(wqe);
struct tid_rdma_flow *flow;
struct hfi1_qp_priv *qpriv = qp->priv;
int diff, delta_pkts;
u32 tididx = 0, i;
u16 fidx;
if (wqe->wr.opcode == IB_WR_TID_RDMA_READ) {
*bth2 = mask_psn(qp->s_psn);
flow = find_flow_ib(req, *bth2, &fidx);
if (!flow) {
trace_hfi1_msg_tid_restart_req(/* msg */
qp, "!!!!!! Could not find flow to restart: bth2 ",
(u64)*bth2);
trace_hfi1_tid_req_restart_req(qp, 0, wqe->wr.opcode,
wqe->psn, wqe->lpsn,
req);
return;
}
} else {
fidx = req->acked_tail;
flow = &req->flows[fidx];
*bth2 = mask_psn(req->r_ack_psn);
}
if (wqe->wr.opcode == IB_WR_TID_RDMA_READ)
delta_pkts = delta_psn(*bth2, flow->flow_state.ib_spsn);
else
delta_pkts = delta_psn(*bth2,
full_flow_psn(flow,
flow->flow_state.spsn));
trace_hfi1_tid_flow_restart_req(qp, fidx, flow);
diff = delta_pkts + flow->resync_npkts;
flow->sent = 0;
flow->pkt = 0;
flow->tid_idx = 0;
flow->tid_offset = 0;
if (diff) {
for (tididx = 0; tididx < flow->tidcnt; tididx++) {
u32 tidentry = flow->tid_entry[tididx], tidlen,
tidnpkts, npkts;
flow->tid_offset = 0;
tidlen = EXP_TID_GET(tidentry, LEN) * PAGE_SIZE;
tidnpkts = rvt_div_round_up_mtu(qp, tidlen);
npkts = min_t(u32, diff, tidnpkts);
flow->pkt += npkts;
flow->sent += (npkts == tidnpkts ? tidlen :
npkts * qp->pmtu);
flow->tid_offset += npkts * qp->pmtu;
diff -= npkts;
if (!diff)
break;
}
}
if (wqe->wr.opcode == IB_WR_TID_RDMA_WRITE) {
rvt_skip_sge(&qpriv->tid_ss, (req->cur_seg * req->seg_len) +
flow->sent, 0);
/*
* Packet PSN is based on flow_state.spsn + flow->pkt. However,
* during a RESYNC, the generation is incremented and the
* sequence is reset to 0. Since we've adjusted the npkts in the
* flow and the SGE has been sufficiently advanced, we have to
* adjust flow->pkt in order to calculate the correct PSN.
*/
flow->pkt -= flow->resync_npkts;
}
if (flow->tid_offset ==
EXP_TID_GET(flow->tid_entry[tididx], LEN) * PAGE_SIZE) {
tididx++;
flow->tid_offset = 0;
}
flow->tid_idx = tididx;
if (wqe->wr.opcode == IB_WR_TID_RDMA_READ)
/* Move flow_idx to correct index */
req->flow_idx = fidx;
else
req->clear_tail = fidx;
trace_hfi1_tid_flow_restart_req(qp, fidx, flow);
trace_hfi1_tid_req_restart_req(qp, 0, wqe->wr.opcode, wqe->psn,
wqe->lpsn, req);
req->state = TID_REQUEST_ACTIVE;
if (wqe->wr.opcode == IB_WR_TID_RDMA_WRITE) {
/* Reset all the flows that we are going to resend */
fidx = CIRC_NEXT(fidx, MAX_FLOWS);
i = qpriv->s_tid_tail;
do {
for (; CIRC_CNT(req->setup_head, fidx, MAX_FLOWS);
fidx = CIRC_NEXT(fidx, MAX_FLOWS)) {
req->flows[fidx].sent = 0;
req->flows[fidx].pkt = 0;
req->flows[fidx].tid_idx = 0;
req->flows[fidx].tid_offset = 0;
req->flows[fidx].resync_npkts = 0;
}
if (i == qpriv->s_tid_cur)
break;
do {
i = (++i == qp->s_size ? 0 : i);
wqe = rvt_get_swqe_ptr(qp, i);
} while (wqe->wr.opcode != IB_WR_TID_RDMA_WRITE);
req = wqe_to_tid_req(wqe);
req->cur_seg = req->ack_seg;
fidx = req->acked_tail;
/* Pull req->clear_tail back */
req->clear_tail = fidx;
} while (1);
}
}
void hfi1_qp_kern_exp_rcv_clear_all(struct rvt_qp *qp)
{
int i, ret;
struct hfi1_qp_priv *qpriv = qp->priv;
struct tid_flow_state *fs;
if (qp->ibqp.qp_type != IB_QPT_RC || !HFI1_CAP_IS_KSET(TID_RDMA))
return;
/*
* First, clear the flow to help prevent any delayed packets from
* being delivered.
*/
fs = &qpriv->flow_state;
if (fs->index != RXE_NUM_TID_FLOWS)
hfi1_kern_clear_hw_flow(qpriv->rcd, qp);
for (i = qp->s_acked; i != qp->s_head;) {
struct rvt_swqe *wqe = rvt_get_swqe_ptr(qp, i);
if (++i == qp->s_size)
i = 0;
/* Free only locally allocated TID entries */
if (wqe->wr.opcode != IB_WR_TID_RDMA_READ)
continue;
do {
struct hfi1_swqe_priv *priv = wqe->priv;
ret = hfi1_kern_exp_rcv_clear(&priv->tid_req);
} while (!ret);
}
for (i = qp->s_acked_ack_queue; i != qp->r_head_ack_queue;) {
struct rvt_ack_entry *e = &qp->s_ack_queue[i];
if (++i == rvt_max_atomic(ib_to_rvt(qp->ibqp.device)))
i = 0;
/* Free only locally allocated TID entries */
if (e->opcode != TID_OP(WRITE_REQ))
continue;
do {
struct hfi1_ack_priv *priv = e->priv;
ret = hfi1_kern_exp_rcv_clear(&priv->tid_req);
} while (!ret);
}
}
bool hfi1_tid_rdma_wqe_interlock(struct rvt_qp *qp, struct rvt_swqe *wqe)
{
struct rvt_swqe *prev;
struct hfi1_qp_priv *priv = qp->priv;
u32 s_prev;
struct tid_rdma_request *req;
s_prev = (qp->s_cur == 0 ? qp->s_size : qp->s_cur) - 1;
prev = rvt_get_swqe_ptr(qp, s_prev);
switch (wqe->wr.opcode) {
case IB_WR_SEND:
case IB_WR_SEND_WITH_IMM:
case IB_WR_SEND_WITH_INV:
case IB_WR_ATOMIC_CMP_AND_SWP:
case IB_WR_ATOMIC_FETCH_AND_ADD:
case IB_WR_RDMA_WRITE:
switch (prev->wr.opcode) {
case IB_WR_TID_RDMA_WRITE:
req = wqe_to_tid_req(prev);
if (req->ack_seg != req->total_segs)
goto interlock;
default:
break;
}
break;
case IB_WR_RDMA_READ:
if (prev->wr.opcode != IB_WR_TID_RDMA_WRITE)
break;
/* fall through */
case IB_WR_TID_RDMA_READ:
switch (prev->wr.opcode) {
case IB_WR_RDMA_READ:
if (qp->s_acked != qp->s_cur)
goto interlock;
break;
case IB_WR_TID_RDMA_WRITE:
req = wqe_to_tid_req(prev);
if (req->ack_seg != req->total_segs)
goto interlock;
default:
break;
}
default:
break;
}
return false;
interlock:
priv->s_flags |= HFI1_S_TID_WAIT_INTERLCK;
return true;
}
/* Does @sge meet the alignment requirements for tid rdma? */
static inline bool hfi1_check_sge_align(struct rvt_qp *qp,
struct rvt_sge *sge, int num_sge)
{
int i;
for (i = 0; i < num_sge; i++, sge++) {
trace_hfi1_sge_check_align(qp, i, sge);
if ((u64)sge->vaddr & ~PAGE_MASK ||
sge->sge_length & ~PAGE_MASK)
return false;
}
return true;
}
void setup_tid_rdma_wqe(struct rvt_qp *qp, struct rvt_swqe *wqe)
{
struct hfi1_qp_priv *qpriv = (struct hfi1_qp_priv *)qp->priv;
struct hfi1_swqe_priv *priv = wqe->priv;
struct tid_rdma_params *remote;
enum ib_wr_opcode new_opcode;
bool do_tid_rdma = false;
struct hfi1_pportdata *ppd = qpriv->rcd->ppd;
if ((rdma_ah_get_dlid(&qp->remote_ah_attr) & ~((1 << ppd->lmc) - 1)) ==
ppd->lid)
return;
if (qpriv->hdr_type != HFI1_PKT_TYPE_9B)
return;
rcu_read_lock();
remote = rcu_dereference(qpriv->tid_rdma.remote);
/*
* If TID RDMA is disabled by the negotiation, don't
* use it.
*/
if (!remote)
goto exit;
if (wqe->wr.opcode == IB_WR_RDMA_READ) {
if (hfi1_check_sge_align(qp, &wqe->sg_list[0],
wqe->wr.num_sge)) {
new_opcode = IB_WR_TID_RDMA_READ;
do_tid_rdma = true;
}
} else if (wqe->wr.opcode == IB_WR_RDMA_WRITE) {
/*
* TID RDMA is enabled for this RDMA WRITE request iff:
* 1. The remote address is page-aligned,
* 2. The length is larger than the minimum segment size,
* 3. The length is page-multiple.
*/
if (!(wqe->rdma_wr.remote_addr & ~PAGE_MASK) &&
!(wqe->length & ~PAGE_MASK)) {
new_opcode = IB_WR_TID_RDMA_WRITE;
do_tid_rdma = true;
}
}
if (do_tid_rdma) {
if (hfi1_kern_exp_rcv_alloc_flows(&priv->tid_req, GFP_ATOMIC))
goto exit;
wqe->wr.opcode = new_opcode;
priv->tid_req.seg_len =
min_t(u32, remote->max_len, wqe->length);
priv->tid_req.total_segs =
DIV_ROUND_UP(wqe->length, priv->tid_req.seg_len);
/* Compute the last PSN of the request */
wqe->lpsn = wqe->psn;
if (wqe->wr.opcode == IB_WR_TID_RDMA_READ) {
priv->tid_req.n_flows = remote->max_read;
qpriv->tid_r_reqs++;
wqe->lpsn += rvt_div_round_up_mtu(qp, wqe->length) - 1;
} else {
wqe->lpsn += priv->tid_req.total_segs - 1;
atomic_inc(&qpriv->n_requests);
}
priv->tid_req.cur_seg = 0;
priv->tid_req.comp_seg = 0;
priv->tid_req.ack_seg = 0;
priv->tid_req.state = TID_REQUEST_INACTIVE;
/*
* Reset acked_tail.
* TID RDMA READ does not have ACKs so it does not
* update the pointer. We have to reset it so TID RDMA
* WRITE does not get confused.
*/
priv->tid_req.acked_tail = priv->tid_req.setup_head;
trace_hfi1_tid_req_setup_tid_wqe(qp, 1, wqe->wr.opcode,
wqe->psn, wqe->lpsn,
&priv->tid_req);
}
exit:
rcu_read_unlock();
}
/* TID RDMA WRITE functions */
u32 hfi1_build_tid_rdma_write_req(struct rvt_qp *qp, struct rvt_swqe *wqe,
struct ib_other_headers *ohdr,
u32 *bth1, u32 *bth2, u32 *len)
{
struct hfi1_qp_priv *qpriv = qp->priv;
struct tid_rdma_request *req = wqe_to_tid_req(wqe);
struct tid_rdma_params *remote;
rcu_read_lock();
remote = rcu_dereference(qpriv->tid_rdma.remote);
/*
* Set the number of flow to be used based on negotiated
* parameters.
*/
req->n_flows = remote->max_write;
req->state = TID_REQUEST_ACTIVE;
KDETH_RESET(ohdr->u.tid_rdma.w_req.kdeth0, KVER, 0x1);
KDETH_RESET(ohdr->u.tid_rdma.w_req.kdeth1, JKEY, remote->jkey);
ohdr->u.tid_rdma.w_req.reth.vaddr =
cpu_to_be64(wqe->rdma_wr.remote_addr + (wqe->length - *len));
ohdr->u.tid_rdma.w_req.reth.rkey =
cpu_to_be32(wqe->rdma_wr.rkey);
ohdr->u.tid_rdma.w_req.reth.length = cpu_to_be32(*len);
ohdr->u.tid_rdma.w_req.verbs_qp = cpu_to_be32(qp->remote_qpn);
*bth1 &= ~RVT_QPN_MASK;
*bth1 |= remote->qp;
qp->s_state = TID_OP(WRITE_REQ);
qp->s_flags |= HFI1_S_WAIT_TID_RESP;
*bth2 |= IB_BTH_REQ_ACK;
*len = 0;
rcu_read_unlock();
return sizeof(ohdr->u.tid_rdma.w_req) / sizeof(u32);
}
void hfi1_compute_tid_rdma_flow_wt(void)
{
/*
* Heuristic for computing the RNR timeout when waiting on the flow
* queue. Rather than a computationaly expensive exact estimate of when
* a flow will be available, we assume that if a QP is at position N in
* the flow queue it has to wait approximately (N + 1) * (number of
* segments between two sync points), assuming PMTU of 4K. The rationale
* for this is that flows are released and recycled at each sync point.
*/
tid_rdma_flow_wt = MAX_TID_FLOW_PSN * enum_to_mtu(OPA_MTU_4096) /
TID_RDMA_MAX_SEGMENT_SIZE;
}
static u32 position_in_queue(struct hfi1_qp_priv *qpriv,
struct tid_queue *queue)
{
return qpriv->tid_enqueue - queue->dequeue;
}
/*
* @qp: points to rvt_qp context.
* @to_seg: desired RNR timeout in segments.
* Return: index of the next highest timeout in the ib_hfi1_rnr_table[]
*/
static u32 hfi1_compute_tid_rnr_timeout(struct rvt_qp *qp, u32 to_seg)
{
struct hfi1_qp_priv *qpriv = qp->priv;
u64 timeout;
u32 bytes_per_us;
u8 i;
bytes_per_us = active_egress_rate(qpriv->rcd->ppd) / 8;
timeout = (to_seg * TID_RDMA_MAX_SEGMENT_SIZE) / bytes_per_us;
/*
* Find the next highest value in the RNR table to the required
* timeout. This gives the responder some padding.
*/
for (i = 1; i <= IB_AETH_CREDIT_MASK; i++)
if (rvt_rnr_tbl_to_usec(i) >= timeout)
return i;
return 0;
}
/**
* Central place for resource allocation at TID write responder,
* is called from write_req and write_data interrupt handlers as
* well as the send thread when a queued QP is scheduled for
* resource allocation.
*
* Iterates over (a) segments of a request and then (b) queued requests
* themselves to allocate resources for up to local->max_write
* segments across multiple requests. Stop allocating when we
* hit a sync point, resume allocating after data packets at
* sync point have been received.
*
* Resource allocation and sending of responses is decoupled. The
* request/segment which are being allocated and sent are as follows.
* Resources are allocated for:
* [request: qpriv->r_tid_alloc, segment: req->alloc_seg]
* The send thread sends:
* [request: qp->s_tail_ack_queue, segment:req->cur_seg]
*/
static void hfi1_tid_write_alloc_resources(struct rvt_qp *qp, bool intr_ctx)
{
struct tid_rdma_request *req;
struct hfi1_qp_priv *qpriv = qp->priv;
struct hfi1_ctxtdata *rcd = qpriv->rcd;
struct tid_rdma_params *local = &qpriv->tid_rdma.local;
struct rvt_ack_entry *e;
u32 npkts, to_seg;
bool last;
int ret = 0;
lockdep_assert_held(&qp->s_lock);
while (1) {
trace_hfi1_rsp_tid_write_alloc_res(qp, 0);
trace_hfi1_tid_write_rsp_alloc_res(qp);
/*
* Don't allocate more segments if a RNR NAK has already been
* scheduled to avoid messing up qp->r_psn: the RNR NAK will
* be sent only when all allocated segments have been sent.
* However, if more segments are allocated before that, TID RDMA
* WRITE RESP packets will be sent out for these new segments
* before the RNR NAK packet. When the requester receives the
* RNR NAK packet, it will restart with qp->s_last_psn + 1,
* which does not match qp->r_psn and will be dropped.
* Consequently, the requester will exhaust its retries and
* put the qp into error state.
*/
if (qpriv->rnr_nak_state == TID_RNR_NAK_SEND)
break;
/* No requests left to process */
if (qpriv->r_tid_alloc == qpriv->r_tid_head) {
/* If all data has been received, clear the flow */
if (qpriv->flow_state.index < RXE_NUM_TID_FLOWS &&
!qpriv->alloc_w_segs) {
hfi1_kern_clear_hw_flow(rcd, qp);
qpriv->s_flags &= ~HFI1_R_TID_SW_PSN;
}
break;
}
e = &qp->s_ack_queue[qpriv->r_tid_alloc];
if (e->opcode != TID_OP(WRITE_REQ))
goto next_req;
req = ack_to_tid_req(e);
trace_hfi1_tid_req_write_alloc_res(qp, 0, e->opcode, e->psn,
e->lpsn, req);
/* Finished allocating for all segments of this request */
if (req->alloc_seg >= req->total_segs)
goto next_req;
/* Can allocate only a maximum of local->max_write for a QP */
if (qpriv->alloc_w_segs >= local->max_write)
break;
/* Don't allocate at a sync point with data packets pending */
if (qpriv->sync_pt && qpriv->alloc_w_segs)
break;
/* All data received at the sync point, continue */
if (qpriv->sync_pt && !qpriv->alloc_w_segs) {
hfi1_kern_clear_hw_flow(rcd, qp);
qpriv->sync_pt = false;
qpriv->s_flags &= ~HFI1_R_TID_SW_PSN;
}
/* Allocate flow if we don't have one */
if (qpriv->flow_state.index >= RXE_NUM_TID_FLOWS) {
ret = hfi1_kern_setup_hw_flow(qpriv->rcd, qp);
if (ret) {
to_seg = tid_rdma_flow_wt *
position_in_queue(qpriv,
&rcd->flow_queue);
break;
}
}
npkts = rvt_div_round_up_mtu(qp, req->seg_len);
/*
* We are at a sync point if we run out of KDETH PSN space.
* Last PSN of every generation is reserved for RESYNC.
*/
if (qpriv->flow_state.psn + npkts > MAX_TID_FLOW_PSN - 1) {
qpriv->sync_pt = true;
break;
}
/*
* If overtaking req->acked_tail, send an RNR NAK. Because the
* QP is not queued in this case, and the issue can only be
* caused due a delay in scheduling the second leg which we
* cannot estimate, we use a rather arbitrary RNR timeout of
* (MAX_FLOWS / 2) segments
*/
if (!CIRC_SPACE(req->setup_head, req->acked_tail,
MAX_FLOWS)) {
ret = -EAGAIN;
to_seg = MAX_FLOWS >> 1;
qpriv->s_flags |= RVT_S_ACK_PENDING;
hfi1_schedule_tid_send(qp);
break;
}
/* Try to allocate rcv array / TID entries */
ret = hfi1_kern_exp_rcv_setup(req, &req->ss, &last);
if (ret == -EAGAIN)
to_seg = position_in_queue(qpriv, &rcd->rarr_queue);
if (ret)
break;
qpriv->alloc_w_segs++;
req->alloc_seg++;
continue;
next_req:
/* Begin processing the next request */
if (++qpriv->r_tid_alloc >
rvt_size_atomic(ib_to_rvt(qp->ibqp.device)))
qpriv->r_tid_alloc = 0;
}
/*
* Schedule an RNR NAK to be sent if (a) flow or rcv array allocation
* has failed (b) we are called from the rcv handler interrupt context
* (c) an RNR NAK has not already been scheduled
*/
if (ret == -EAGAIN && intr_ctx && !qp->r_nak_state)
goto send_rnr_nak;
return;
send_rnr_nak:
lockdep_assert_held(&qp->r_lock);
/* Set r_nak_state to prevent unrelated events from generating NAK's */
qp->r_nak_state = hfi1_compute_tid_rnr_timeout(qp, to_seg) | IB_RNR_NAK;
/* Pull back r_psn to the segment being RNR NAK'd */
qp->r_psn = e->psn + req->alloc_seg;
qp->r_ack_psn = qp->r_psn;
/*
* Pull back r_head_ack_queue to the ack entry following the request
* being RNR NAK'd. This allows resources to be allocated to the request
* if the queued QP is scheduled.
*/
qp->r_head_ack_queue = qpriv->r_tid_alloc + 1;
if (qp->r_head_ack_queue > rvt_size_atomic(ib_to_rvt(qp->ibqp.device)))
qp->r_head_ack_queue = 0;
qpriv->r_tid_head = qp->r_head_ack_queue;
/*
* These send side fields are used in make_rc_ack(). They are set in
* hfi1_send_rc_ack() but must be set here before dropping qp->s_lock
* for consistency
*/
qp->s_nak_state = qp->r_nak_state;
qp->s_ack_psn = qp->r_ack_psn;
/*
* Clear the ACK PENDING flag to prevent unwanted ACK because we
* have modified qp->s_ack_psn here.
*/
qp->s_flags &= ~(RVT_S_ACK_PENDING);
trace_hfi1_rsp_tid_write_alloc_res(qp, qp->r_psn);
/*
* qpriv->rnr_nak_state is used to determine when the scheduled RNR NAK
* has actually been sent. qp->s_flags RVT_S_ACK_PENDING bit cannot be
* used for this because qp->s_lock is dropped before calling
* hfi1_send_rc_ack() leading to inconsistency between the receive
* interrupt handlers and the send thread in make_rc_ack()
*/
qpriv->rnr_nak_state = TID_RNR_NAK_SEND;
/*
* Schedule RNR NAK to be sent. RNR NAK's are scheduled from the receive
* interrupt handlers but will be sent from the send engine behind any
* previous responses that may have been scheduled
*/
rc_defered_ack(rcd, qp);
}
void hfi1_rc_rcv_tid_rdma_write_req(struct hfi1_packet *packet)
{
/* HANDLER FOR TID RDMA WRITE REQUEST packet (Responder side)*/
/*
* 1. Verify TID RDMA WRITE REQ as per IB_OPCODE_RC_RDMA_WRITE_FIRST
* (see hfi1_rc_rcv())
* - Don't allow 0-length requests.
* 2. Put TID RDMA WRITE REQ into the response queueu (s_ack_queue)
* - Setup struct tid_rdma_req with request info
* - Prepare struct tid_rdma_flow array?
* 3. Set the qp->s_ack_state as state diagram in design doc.
* 4. Set RVT_S_RESP_PENDING in s_flags.
* 5. Kick the send engine (hfi1_schedule_send())
*/
struct hfi1_ctxtdata *rcd = packet->rcd;
struct rvt_qp *qp = packet->qp;
struct hfi1_ibport *ibp = to_iport(qp->ibqp.device, qp->port_num);
struct ib_other_headers *ohdr = packet->ohdr;
struct rvt_ack_entry *e;
unsigned long flags;
struct ib_reth *reth;
struct hfi1_qp_priv *qpriv = qp->priv;
struct tid_rdma_request *req;
u32 bth0, psn, len, rkey, num_segs;
bool fecn;
u8 next;
u64 vaddr;
int diff;
bth0 = be32_to_cpu(ohdr->bth[0]);
if (hfi1_ruc_check_hdr(ibp, packet))
return;
fecn = process_ecn(qp, packet);
psn = mask_psn(be32_to_cpu(ohdr->bth[2]));
trace_hfi1_rsp_rcv_tid_write_req(qp, psn);
if (qp->state == IB_QPS_RTR && !(qp->r_flags & RVT_R_COMM_EST))
rvt_comm_est(qp);
if (unlikely(!(qp->qp_access_flags & IB_ACCESS_REMOTE_WRITE)))
goto nack_inv;
reth = &ohdr->u.tid_rdma.w_req.reth;
vaddr = be64_to_cpu(reth->vaddr);
len = be32_to_cpu(reth->length);
num_segs = DIV_ROUND_UP(len, qpriv->tid_rdma.local.max_len);
diff = delta_psn(psn, qp->r_psn);
if (unlikely(diff)) {
tid_rdma_rcv_err(packet, ohdr, qp, psn, diff, fecn);
return;
}
/*
* The resent request which was previously RNR NAK'd is inserted at the
* location of the original request, which is one entry behind
* r_head_ack_queue
*/
if (qpriv->rnr_nak_state)
qp->r_head_ack_queue = qp->r_head_ack_queue ?
qp->r_head_ack_queue - 1 :
rvt_size_atomic(ib_to_rvt(qp->ibqp.device));
/* We've verified the request, insert it into the ack queue. */
next = qp->r_head_ack_queue + 1;
if (next > rvt_size_atomic(ib_to_rvt(qp->ibqp.device)))
next = 0;
spin_lock_irqsave(&qp->s_lock, flags);
if (unlikely(next == qp->s_acked_ack_queue)) {
if (!qp->s_ack_queue[next].sent)
goto nack_inv_unlock;
update_ack_queue(qp, next);
}
e = &qp->s_ack_queue[qp->r_head_ack_queue];
req = ack_to_tid_req(e);
/* Bring previously RNR NAK'd request back to life */
if (qpriv->rnr_nak_state) {
qp->r_nak_state = 0;
qp->s_nak_state = 0;
qpriv->rnr_nak_state = TID_RNR_NAK_INIT;
qp->r_psn = e->lpsn + 1;
req->state = TID_REQUEST_INIT;
goto update_head;
}
release_rdma_sge_mr(e);
/* The length needs to be in multiples of PAGE_SIZE */
if (!len || len & ~PAGE_MASK)
goto nack_inv_unlock;
rkey = be32_to_cpu(reth->rkey);
qp->r_len = len;
if (e->opcode == TID_OP(WRITE_REQ) &&
(req->setup_head != req->clear_tail ||
req->clear_tail != req->acked_tail))
goto nack_inv_unlock;
if (unlikely(!rvt_rkey_ok(qp, &e->rdma_sge, qp->r_len, vaddr,
rkey, IB_ACCESS_REMOTE_WRITE)))
goto nack_acc;
qp->r_psn += num_segs - 1;
e->opcode = (bth0 >> 24) & 0xff;
e->psn = psn;
e->lpsn = qp->r_psn;
e->sent = 0;
req->n_flows = min_t(u16, num_segs, qpriv->tid_rdma.local.max_write);
req->state = TID_REQUEST_INIT;
req->cur_seg = 0;
req->comp_seg = 0;
req->ack_seg = 0;
req->alloc_seg = 0;
req->isge = 0;
req->seg_len = qpriv->tid_rdma.local.max_len;
req->total_len = len;
req->total_segs = num_segs;
req->r_flow_psn = e->psn;
req->ss.sge = e->rdma_sge;
req->ss.num_sge = 1;
req->flow_idx = req->setup_head;
req->clear_tail = req->setup_head;
req->acked_tail = req->setup_head;
qp->r_state = e->opcode;
qp->r_nak_state = 0;
/*
* We need to increment the MSN here instead of when we
* finish sending the result since a duplicate request would
* increment it more than once.
*/
qp->r_msn++;
qp->r_psn++;
trace_hfi1_tid_req_rcv_write_req(qp, 0, e->opcode, e->psn, e->lpsn,
req);
if (qpriv->r_tid_tail == HFI1_QP_WQE_INVALID) {
qpriv->r_tid_tail = qp->r_head_ack_queue;
} else if (qpriv->r_tid_tail == qpriv->r_tid_head) {
struct tid_rdma_request *ptr;
e = &qp->s_ack_queue[qpriv->r_tid_tail];
ptr = ack_to_tid_req(e);
if (e->opcode != TID_OP(WRITE_REQ) ||
ptr->comp_seg == ptr->total_segs) {
if (qpriv->r_tid_tail == qpriv->r_tid_ack)
qpriv->r_tid_ack = qp->r_head_ack_queue;
qpriv->r_tid_tail = qp->r_head_ack_queue;
}
}
update_head:
qp->r_head_ack_queue = next;
qpriv->r_tid_head = qp->r_head_ack_queue;
hfi1_tid_write_alloc_resources(qp, true);
trace_hfi1_tid_write_rsp_rcv_req(qp);
/* Schedule the send tasklet. */
qp->s_flags |= RVT_S_RESP_PENDING;
if (fecn)
qp->s_flags |= RVT_S_ECN;
hfi1_schedule_send(qp);
spin_unlock_irqrestore(&qp->s_lock, flags);
return;
nack_inv_unlock:
spin_unlock_irqrestore(&qp->s_lock, flags);
nack_inv:
rvt_rc_error(qp, IB_WC_LOC_QP_OP_ERR);
qp->r_nak_state = IB_NAK_INVALID_REQUEST;
qp->r_ack_psn = qp->r_psn;
/* Queue NAK for later */
rc_defered_ack(rcd, qp);
return;
nack_acc:
spin_unlock_irqrestore(&qp->s_lock, flags);
rvt_rc_error(qp, IB_WC_LOC_PROT_ERR);
qp->r_nak_state = IB_NAK_REMOTE_ACCESS_ERROR;
qp->r_ack_psn = qp->r_psn;
}
u32 hfi1_build_tid_rdma_write_resp(struct rvt_qp *qp, struct rvt_ack_entry *e,
struct ib_other_headers *ohdr, u32 *bth1,
u32 bth2, u32 *len,
struct rvt_sge_state **ss)
{
struct hfi1_ack_priv *epriv = e->priv;
struct tid_rdma_request *req = &epriv->tid_req;
struct hfi1_qp_priv *qpriv = qp->priv;
struct tid_rdma_flow *flow = NULL;
u32 resp_len = 0, hdwords = 0;
void *resp_addr = NULL;
struct tid_rdma_params *remote;
trace_hfi1_tid_req_build_write_resp(qp, 0, e->opcode, e->psn, e->lpsn,
req);
trace_hfi1_tid_write_rsp_build_resp(qp);
trace_hfi1_rsp_build_tid_write_resp(qp, bth2);
flow = &req->flows[req->flow_idx];
switch (req->state) {
default:
/*
* Try to allocate resources here in case QP was queued and was
* later scheduled when resources became available
*/
hfi1_tid_write_alloc_resources(qp, false);
/* We've already sent everything which is ready */
if (req->cur_seg >= req->alloc_seg)
goto done;
/*
* Resources can be assigned but responses cannot be sent in
* rnr_nak state, till the resent request is received
*/
if (qpriv->rnr_nak_state == TID_RNR_NAK_SENT)
goto done;
req->state = TID_REQUEST_ACTIVE;
trace_hfi1_tid_flow_build_write_resp(qp, req->flow_idx, flow);
req->flow_idx = CIRC_NEXT(req->flow_idx, MAX_FLOWS);
hfi1_add_tid_reap_timer(qp);
break;
case TID_REQUEST_RESEND_ACTIVE:
case TID_REQUEST_RESEND:
trace_hfi1_tid_flow_build_write_resp(qp, req->flow_idx, flow);
req->flow_idx = CIRC_NEXT(req->flow_idx, MAX_FLOWS);
if (!CIRC_CNT(req->setup_head, req->flow_idx, MAX_FLOWS))
req->state = TID_REQUEST_ACTIVE;
hfi1_mod_tid_reap_timer(qp);
break;
}
flow->flow_state.resp_ib_psn = bth2;
resp_addr = (void *)flow->tid_entry;
resp_len = sizeof(*flow->tid_entry) * flow->tidcnt;
req->cur_seg++;
memset(&ohdr->u.tid_rdma.w_rsp, 0, sizeof(ohdr->u.tid_rdma.w_rsp));
epriv->ss.sge.vaddr = resp_addr;
epriv->ss.sge.sge_length = resp_len;
epriv->ss.sge.length = epriv->ss.sge.sge_length;
/*
* We can safely zero these out. Since the first SGE covers the
* entire packet, nothing else should even look at the MR.
*/
epriv->ss.sge.mr = NULL;
epriv->ss.sge.m = 0;
epriv->ss.sge.n = 0;
epriv->ss.sg_list = NULL;
epriv->ss.total_len = epriv->ss.sge.sge_length;
epriv->ss.num_sge = 1;
*ss = &epriv->ss;
*len = epriv->ss.total_len;
/* Construct the TID RDMA WRITE RESP packet header */
rcu_read_lock();
remote = rcu_dereference(qpriv->tid_rdma.remote);
KDETH_RESET(ohdr->u.tid_rdma.w_rsp.kdeth0, KVER, 0x1);
KDETH_RESET(ohdr->u.tid_rdma.w_rsp.kdeth1, JKEY, remote->jkey);
ohdr->u.tid_rdma.w_rsp.aeth = rvt_compute_aeth(qp);
ohdr->u.tid_rdma.w_rsp.tid_flow_psn =
cpu_to_be32((flow->flow_state.generation <<
HFI1_KDETH_BTH_SEQ_SHIFT) |
(flow->flow_state.spsn &
HFI1_KDETH_BTH_SEQ_MASK));
ohdr->u.tid_rdma.w_rsp.tid_flow_qp =
cpu_to_be32(qpriv->tid_rdma.local.qp |
((flow->idx & TID_RDMA_DESTQP_FLOW_MASK) <<
TID_RDMA_DESTQP_FLOW_SHIFT) |
qpriv->rcd->ctxt);
ohdr->u.tid_rdma.w_rsp.verbs_qp = cpu_to_be32(qp->remote_qpn);
*bth1 = remote->qp;
rcu_read_unlock();
hdwords = sizeof(ohdr->u.tid_rdma.w_rsp) / sizeof(u32);
qpriv->pending_tid_w_segs++;
done:
return hdwords;
}
static void hfi1_add_tid_reap_timer(struct rvt_qp *qp)
{
struct hfi1_qp_priv *qpriv = qp->priv;
lockdep_assert_held(&qp->s_lock);
if (!(qpriv->s_flags & HFI1_R_TID_RSC_TIMER)) {
qpriv->s_flags |= HFI1_R_TID_RSC_TIMER;
qpriv->s_tid_timer.expires = jiffies +
qpriv->tid_timer_timeout_jiffies;
add_timer(&qpriv->s_tid_timer);
}
}
static void hfi1_mod_tid_reap_timer(struct rvt_qp *qp)
{
struct hfi1_qp_priv *qpriv = qp->priv;
lockdep_assert_held(&qp->s_lock);
qpriv->s_flags |= HFI1_R_TID_RSC_TIMER;
mod_timer(&qpriv->s_tid_timer, jiffies +
qpriv->tid_timer_timeout_jiffies);
}
static int hfi1_stop_tid_reap_timer(struct rvt_qp *qp)
{
struct hfi1_qp_priv *qpriv = qp->priv;
int rval = 0;
lockdep_assert_held(&qp->s_lock);
if (qpriv->s_flags & HFI1_R_TID_RSC_TIMER) {
rval = del_timer(&qpriv->s_tid_timer);
qpriv->s_flags &= ~HFI1_R_TID_RSC_TIMER;
}
return rval;
}
void hfi1_del_tid_reap_timer(struct rvt_qp *qp)
{
struct hfi1_qp_priv *qpriv = qp->priv;
del_timer_sync(&qpriv->s_tid_timer);
qpriv->s_flags &= ~HFI1_R_TID_RSC_TIMER;
}
static void hfi1_tid_timeout(struct timer_list *t)
{
struct hfi1_qp_priv *qpriv = from_timer(qpriv, t, s_tid_timer);
struct rvt_qp *qp = qpriv->owner;
struct rvt_dev_info *rdi = ib_to_rvt(qp->ibqp.device);
unsigned long flags;
u32 i;
spin_lock_irqsave(&qp->r_lock, flags);
spin_lock(&qp->s_lock);
if (qpriv->s_flags & HFI1_R_TID_RSC_TIMER) {
dd_dev_warn(dd_from_ibdev(qp->ibqp.device), "[QP%u] %s %d\n",
qp->ibqp.qp_num, __func__, __LINE__);
trace_hfi1_msg_tid_timeout(/* msg */
qp, "resource timeout = ",
(u64)qpriv->tid_timer_timeout_jiffies);
hfi1_stop_tid_reap_timer(qp);
/*
* Go though the entire ack queue and clear any outstanding
* HW flow and RcvArray resources.
*/
hfi1_kern_clear_hw_flow(qpriv->rcd, qp);
for (i = 0; i < rvt_max_atomic(rdi); i++) {
struct tid_rdma_request *req =
ack_to_tid_req(&qp->s_ack_queue[i]);
hfi1_kern_exp_rcv_clear_all(req);
}
spin_unlock(&qp->s_lock);
if (qp->ibqp.event_handler) {
struct ib_event ev;
ev.device = qp->ibqp.device;
ev.element.qp = &qp->ibqp;
ev.event = IB_EVENT_QP_FATAL;
qp->ibqp.event_handler(&ev, qp->ibqp.qp_context);
}
rvt_rc_error(qp, IB_WC_RESP_TIMEOUT_ERR);
goto unlock_r_lock;
}
spin_unlock(&qp->s_lock);
unlock_r_lock:
spin_unlock_irqrestore(&qp->r_lock, flags);
}
void hfi1_rc_rcv_tid_rdma_write_resp(struct hfi1_packet *packet)
{
/* HANDLER FOR TID RDMA WRITE RESPONSE packet (Requestor side */
/*
* 1. Find matching SWQE
* 2. Check that TIDENTRY array has enough space for a complete
* segment. If not, put QP in error state.
* 3. Save response data in struct tid_rdma_req and struct tid_rdma_flow
* 4. Remove HFI1_S_WAIT_TID_RESP from s_flags.
* 5. Set qp->s_state
* 6. Kick the send engine (hfi1_schedule_send())
*/
struct ib_other_headers *ohdr = packet->ohdr;
struct rvt_qp *qp = packet->qp;
struct hfi1_qp_priv *qpriv = qp->priv;
struct hfi1_ctxtdata *rcd = packet->rcd;
struct rvt_swqe *wqe;
struct tid_rdma_request *req;
struct tid_rdma_flow *flow;
enum ib_wc_status status;
u32 opcode, aeth, psn, flow_psn, i, tidlen = 0, pktlen;
bool fecn;
unsigned long flags;
fecn = process_ecn(qp, packet);
psn = mask_psn(be32_to_cpu(ohdr->bth[2]));
aeth = be32_to_cpu(ohdr->u.tid_rdma.w_rsp.aeth);
opcode = (be32_to_cpu(ohdr->bth[0]) >> 24) & 0xff;
spin_lock_irqsave(&qp->s_lock, flags);
/* Ignore invalid responses */
if (cmp_psn(psn, qp->s_next_psn) >= 0)
goto ack_done;
/* Ignore duplicate responses. */
if (unlikely(cmp_psn(psn, qp->s_last_psn) <= 0))
goto ack_done;
if (unlikely(qp->s_acked == qp->s_tail))
goto ack_done;
/*
* If we are waiting for a particular packet sequence number
* due to a request being resent, check for it. Otherwise,
* ensure that we haven't missed anything.
*/
if (qp->r_flags & RVT_R_RDMAR_SEQ) {
if (cmp_psn(psn, qp->s_last_psn + 1) != 0)
goto ack_done;
qp->r_flags &= ~RVT_R_RDMAR_SEQ;
}
wqe = rvt_get_swqe_ptr(qp, qpriv->s_tid_cur);
if (unlikely(wqe->wr.opcode != IB_WR_TID_RDMA_WRITE))
goto ack_op_err;
req = wqe_to_tid_req(wqe);
/*
* If we've lost ACKs and our acked_tail pointer is too far
* behind, don't overwrite segments. Just drop the packet and
* let the reliability protocol take care of it.
*/
if (!CIRC_SPACE(req->setup_head, req->acked_tail, MAX_FLOWS))
goto ack_done;
/*
* The call to do_rc_ack() should be last in the chain of
* packet checks because it will end up updating the QP state.
* Therefore, anything that would prevent the packet from
* being accepted as a successful response should be prior
* to it.
*/
if (!do_rc_ack(qp, aeth, psn, opcode, 0, rcd))
goto ack_done;
trace_hfi1_ack(qp, psn);
flow = &req->flows[req->setup_head];
flow->pkt = 0;
flow->tid_idx = 0;
flow->tid_offset = 0;
flow->sent = 0;
flow->resync_npkts = 0;
flow->tid_qpn = be32_to_cpu(ohdr->u.tid_rdma.w_rsp.tid_flow_qp);
flow->idx = (flow->tid_qpn >> TID_RDMA_DESTQP_FLOW_SHIFT) &
TID_RDMA_DESTQP_FLOW_MASK;
flow_psn = mask_psn(be32_to_cpu(ohdr->u.tid_rdma.w_rsp.tid_flow_psn));
flow->flow_state.generation = flow_psn >> HFI1_KDETH_BTH_SEQ_SHIFT;
flow->flow_state.spsn = flow_psn & HFI1_KDETH_BTH_SEQ_MASK;
flow->flow_state.resp_ib_psn = psn;
flow->length = min_t(u32, req->seg_len,
(wqe->length - (req->comp_seg * req->seg_len)));
flow->npkts = rvt_div_round_up_mtu(qp, flow->length);
flow->flow_state.lpsn = flow->flow_state.spsn +
flow->npkts - 1;
/* payload length = packet length - (header length + ICRC length) */
pktlen = packet->tlen - (packet->hlen + 4);
if (pktlen > sizeof(flow->tid_entry)) {
status = IB_WC_LOC_LEN_ERR;
goto ack_err;
}
memcpy(flow->tid_entry, packet->ebuf, pktlen);
flow->tidcnt = pktlen / sizeof(*flow->tid_entry);
trace_hfi1_tid_flow_rcv_write_resp(qp, req->setup_head, flow);
req->comp_seg++;
trace_hfi1_tid_write_sender_rcv_resp(qp, 0);
/*
* Walk the TID_ENTRY list to make sure we have enough space for a
* complete segment.
*/
for (i = 0; i < flow->tidcnt; i++) {
trace_hfi1_tid_entry_rcv_write_resp(/* entry */
qp, i, flow->tid_entry[i]);
if (!EXP_TID_GET(flow->tid_entry[i], LEN)) {
status = IB_WC_LOC_LEN_ERR;
goto ack_err;
}
tidlen += EXP_TID_GET(flow->tid_entry[i], LEN);
}
if (tidlen * PAGE_SIZE < flow->length) {
status = IB_WC_LOC_LEN_ERR;
goto ack_err;
}
trace_hfi1_tid_req_rcv_write_resp(qp, 0, wqe->wr.opcode, wqe->psn,
wqe->lpsn, req);
/*
* If this is the first response for this request, set the initial
* flow index to the current flow.
*/
if (!cmp_psn(psn, wqe->psn)) {
req->r_last_acked = mask_psn(wqe->psn - 1);
/* Set acked flow index to head index */
req->acked_tail = req->setup_head;
}
/* advance circular buffer head */
req->setup_head = CIRC_NEXT(req->setup_head, MAX_FLOWS);
req->state = TID_REQUEST_ACTIVE;
/*
* If all responses for this TID RDMA WRITE request have been received
* advance the pointer to the next one.
* Since TID RDMA requests could be mixed in with regular IB requests,
* they might not appear sequentially in the queue. Therefore, the
* next request needs to be "found".
*/
if (qpriv->s_tid_cur != qpriv->s_tid_head &&
req->comp_seg == req->total_segs) {
for (i = qpriv->s_tid_cur + 1; ; i++) {
if (i == qp->s_size)
i = 0;
wqe = rvt_get_swqe_ptr(qp, i);
if (i == qpriv->s_tid_head)
break;
if (wqe->wr.opcode == IB_WR_TID_RDMA_WRITE)
break;
}
qpriv->s_tid_cur = i;
}
qp->s_flags &= ~HFI1_S_WAIT_TID_RESP;
hfi1_schedule_tid_send(qp);
goto ack_done;
ack_op_err:
status = IB_WC_LOC_QP_OP_ERR;
ack_err:
rvt_error_qp(qp, status);
ack_done:
if (fecn)
qp->s_flags |= RVT_S_ECN;
spin_unlock_irqrestore(&qp->s_lock, flags);
}
bool hfi1_build_tid_rdma_packet(struct rvt_swqe *wqe,
struct ib_other_headers *ohdr,
u32 *bth1, u32 *bth2, u32 *len)
{
struct tid_rdma_request *req = wqe_to_tid_req(wqe);
struct tid_rdma_flow *flow = &req->flows[req->clear_tail];
struct tid_rdma_params *remote;
struct rvt_qp *qp = req->qp;
struct hfi1_qp_priv *qpriv = qp->priv;
u32 tidentry = flow->tid_entry[flow->tid_idx];
u32 tidlen = EXP_TID_GET(tidentry, LEN) << PAGE_SHIFT;
struct tid_rdma_write_data *wd = &ohdr->u.tid_rdma.w_data;
u32 next_offset, om = KDETH_OM_LARGE;
bool last_pkt;
if (!tidlen) {
hfi1_trdma_send_complete(qp, wqe, IB_WC_REM_INV_RD_REQ_ERR);
rvt_error_qp(qp, IB_WC_REM_INV_RD_REQ_ERR);
}
*len = min_t(u32, qp->pmtu, tidlen - flow->tid_offset);
flow->sent += *len;
next_offset = flow->tid_offset + *len;
last_pkt = (flow->tid_idx == (flow->tidcnt - 1) &&
next_offset >= tidlen) || (flow->sent >= flow->length);
trace_hfi1_tid_entry_build_write_data(qp, flow->tid_idx, tidentry);
trace_hfi1_tid_flow_build_write_data(qp, req->clear_tail, flow);
rcu_read_lock();
remote = rcu_dereference(qpriv->tid_rdma.remote);
KDETH_RESET(wd->kdeth0, KVER, 0x1);
KDETH_SET(wd->kdeth0, SH, !last_pkt);
KDETH_SET(wd->kdeth0, INTR, !!(!last_pkt && remote->urg));
KDETH_SET(wd->kdeth0, TIDCTRL, EXP_TID_GET(tidentry, CTRL));
KDETH_SET(wd->kdeth0, TID, EXP_TID_GET(tidentry, IDX));
KDETH_SET(wd->kdeth0, OM, om == KDETH_OM_LARGE);
KDETH_SET(wd->kdeth0, OFFSET, flow->tid_offset / om);
KDETH_RESET(wd->kdeth1, JKEY, remote->jkey);
wd->verbs_qp = cpu_to_be32(qp->remote_qpn);
rcu_read_unlock();
*bth1 = flow->tid_qpn;
*bth2 = mask_psn(((flow->flow_state.spsn + flow->pkt++) &
HFI1_KDETH_BTH_SEQ_MASK) |
(flow->flow_state.generation <<
HFI1_KDETH_BTH_SEQ_SHIFT));
if (last_pkt) {
/* PSNs are zero-based, so +1 to count number of packets */
if (flow->flow_state.lpsn + 1 +
rvt_div_round_up_mtu(qp, req->seg_len) >
MAX_TID_FLOW_PSN)
req->state = TID_REQUEST_SYNC;
*bth2 |= IB_BTH_REQ_ACK;
}
if (next_offset >= tidlen) {
flow->tid_offset = 0;
flow->tid_idx++;
} else {
flow->tid_offset = next_offset;
}
return last_pkt;
}
void hfi1_rc_rcv_tid_rdma_write_data(struct hfi1_packet *packet)
{
struct rvt_qp *qp = packet->qp;
struct hfi1_qp_priv *priv = qp->priv;
struct hfi1_ctxtdata *rcd = priv->rcd;
struct ib_other_headers *ohdr = packet->ohdr;
struct rvt_ack_entry *e;
struct tid_rdma_request *req;
struct tid_rdma_flow *flow;
struct hfi1_ibdev *dev = to_idev(qp->ibqp.device);
unsigned long flags;
u32 psn, next;
u8 opcode;
bool fecn;
fecn = process_ecn(qp, packet);
psn = mask_psn(be32_to_cpu(ohdr->bth[2]));
opcode = (be32_to_cpu(ohdr->bth[0]) >> 24) & 0xff;
/*
* All error handling should be done by now. If we are here, the packet
* is either good or been accepted by the error handler.
*/
spin_lock_irqsave(&qp->s_lock, flags);
e = &qp->s_ack_queue[priv->r_tid_tail];
req = ack_to_tid_req(e);
flow = &req->flows[req->clear_tail];
if (cmp_psn(psn, full_flow_psn(flow, flow->flow_state.lpsn))) {
update_r_next_psn_fecn(packet, priv, rcd, flow, fecn);
if (cmp_psn(psn, flow->flow_state.r_next_psn))
goto send_nak;
flow->flow_state.r_next_psn = mask_psn(psn + 1);
/*
* Copy the payload to destination buffer if this packet is
* delivered as an eager packet due to RSM rule and FECN.
* The RSM rule selects FECN bit in BTH and SH bit in
* KDETH header and therefore will not match the last
* packet of each segment that has SH bit cleared.
*/
if (fecn && packet->etype == RHF_RCV_TYPE_EAGER) {
struct rvt_sge_state ss;
u32 len;
u32 tlen = packet->tlen;
u16 hdrsize = packet->hlen;
u8 pad = packet->pad;
u8 extra_bytes = pad + packet->extra_byte +
(SIZE_OF_CRC << 2);
u32 pmtu = qp->pmtu;
if (unlikely(tlen != (hdrsize + pmtu + extra_bytes)))
goto send_nak;
len = req->comp_seg * req->seg_len;
len += delta_psn(psn,
full_flow_psn(flow, flow->flow_state.spsn)) *
pmtu;
if (unlikely(req->total_len - len < pmtu))
goto send_nak;
/*
* The e->rdma_sge field is set when TID RDMA WRITE REQ
* is first received and is never modified thereafter.
*/
ss.sge = e->rdma_sge;
ss.sg_list = NULL;
ss.num_sge = 1;
ss.total_len = req->total_len;
rvt_skip_sge(&ss, len, false);
rvt_copy_sge(qp, &ss, packet->payload, pmtu, false,
false);
/* Raise the sw sequence check flag for next packet */
priv->r_next_psn_kdeth = mask_psn(psn + 1);
priv->s_flags |= HFI1_R_TID_SW_PSN;
}
goto exit;
}
flow->flow_state.r_next_psn = mask_psn(psn + 1);
hfi1_kern_exp_rcv_clear(req);
priv->alloc_w_segs--;
rcd->flows[flow->idx].psn = psn & HFI1_KDETH_BTH_SEQ_MASK;
req->comp_seg++;
priv->s_nak_state = 0;
/*
* Release the flow if one of the following conditions has been met:
* - The request has reached a sync point AND all outstanding
* segments have been completed, or
* - The entire request is complete and there are no more requests
* (of any kind) in the queue.
*/
trace_hfi1_rsp_rcv_tid_write_data(qp, psn);
trace_hfi1_tid_req_rcv_write_data(qp, 0, e->opcode, e->psn, e->lpsn,
req);
trace_hfi1_tid_write_rsp_rcv_data(qp);
if (priv->r_tid_ack == HFI1_QP_WQE_INVALID)
priv->r_tid_ack = priv->r_tid_tail;
if (opcode == TID_OP(WRITE_DATA_LAST)) {
release_rdma_sge_mr(e);
for (next = priv->r_tid_tail + 1; ; next++) {
if (next > rvt_size_atomic(&dev->rdi))
next = 0;
if (next == priv->r_tid_head)
break;
e = &qp->s_ack_queue[next];
if (e->opcode == TID_OP(WRITE_REQ))
break;
}
priv->r_tid_tail = next;
if (++qp->s_acked_ack_queue > rvt_size_atomic(&dev->rdi))
qp->s_acked_ack_queue = 0;
}
hfi1_tid_write_alloc_resources(qp, true);
/*
* If we need to generate more responses, schedule the
* send engine.
*/
if (req->cur_seg < req->total_segs ||
qp->s_tail_ack_queue != qp->r_head_ack_queue) {
qp->s_flags |= RVT_S_RESP_PENDING;
hfi1_schedule_send(qp);
}
priv->pending_tid_w_segs--;
if (priv->s_flags & HFI1_R_TID_RSC_TIMER) {
if (priv->pending_tid_w_segs)
hfi1_mod_tid_reap_timer(req->qp);
else
hfi1_stop_tid_reap_timer(req->qp);
}
done:
priv->s_flags |= RVT_S_ACK_PENDING;
hfi1_schedule_tid_send(qp);
exit:
priv->r_next_psn_kdeth = flow->flow_state.r_next_psn;
if (fecn)
qp->s_flags |= RVT_S_ECN;
spin_unlock_irqrestore(&qp->s_lock, flags);
return;
send_nak:
if (!priv->s_nak_state) {
priv->s_nak_state = IB_NAK_PSN_ERROR;
priv->s_nak_psn = flow->flow_state.r_next_psn;
priv->s_flags |= RVT_S_ACK_PENDING;
if (priv->r_tid_ack == HFI1_QP_WQE_INVALID)
priv->r_tid_ack = priv->r_tid_tail;
hfi1_schedule_tid_send(qp);
}
goto done;
}
static bool hfi1_tid_rdma_is_resync_psn(u32 psn)
{
return (bool)((psn & HFI1_KDETH_BTH_SEQ_MASK) ==
HFI1_KDETH_BTH_SEQ_MASK);
}
u32 hfi1_build_tid_rdma_write_ack(struct rvt_qp *qp, struct rvt_ack_entry *e,
struct ib_other_headers *ohdr, u16 iflow,
u32 *bth1, u32 *bth2)
{
struct hfi1_qp_priv *qpriv = qp->priv;
struct tid_flow_state *fs = &qpriv->flow_state;
struct tid_rdma_request *req = ack_to_tid_req(e);
struct tid_rdma_flow *flow = &req->flows[iflow];
struct tid_rdma_params *remote;
rcu_read_lock();
remote = rcu_dereference(qpriv->tid_rdma.remote);
KDETH_RESET(ohdr->u.tid_rdma.ack.kdeth1, JKEY, remote->jkey);
ohdr->u.tid_rdma.ack.verbs_qp = cpu_to_be32(qp->remote_qpn);
*bth1 = remote->qp;
rcu_read_unlock();
if (qpriv->resync) {
*bth2 = mask_psn((fs->generation <<
HFI1_KDETH_BTH_SEQ_SHIFT) - 1);
ohdr->u.tid_rdma.ack.aeth = rvt_compute_aeth(qp);
} else if (qpriv->s_nak_state) {
*bth2 = mask_psn(qpriv->s_nak_psn);
ohdr->u.tid_rdma.ack.aeth =
cpu_to_be32((qp->r_msn & IB_MSN_MASK) |
(qpriv->s_nak_state <<
IB_AETH_CREDIT_SHIFT));
} else {
*bth2 = full_flow_psn(flow, flow->flow_state.lpsn);
ohdr->u.tid_rdma.ack.aeth = rvt_compute_aeth(qp);
}
KDETH_RESET(ohdr->u.tid_rdma.ack.kdeth0, KVER, 0x1);
ohdr->u.tid_rdma.ack.tid_flow_qp =
cpu_to_be32(qpriv->tid_rdma.local.qp |
((flow->idx & TID_RDMA_DESTQP_FLOW_MASK) <<
TID_RDMA_DESTQP_FLOW_SHIFT) |
qpriv->rcd->ctxt);
ohdr->u.tid_rdma.ack.tid_flow_psn = 0;
ohdr->u.tid_rdma.ack.verbs_psn =
cpu_to_be32(flow->flow_state.resp_ib_psn);
if (qpriv->resync) {
/*
* If the PSN before the current expect KDETH PSN is the
* RESYNC PSN, then we never received a good TID RDMA WRITE
* DATA packet after a previous RESYNC.
* In this case, the next expected KDETH PSN stays the same.
*/
if (hfi1_tid_rdma_is_resync_psn(qpriv->r_next_psn_kdeth - 1)) {
ohdr->u.tid_rdma.ack.tid_flow_psn =
cpu_to_be32(qpriv->r_next_psn_kdeth_save);
} else {
/*
* Because the KDETH PSNs jump during a RESYNC, it's
* not possible to infer (or compute) the previous value
* of r_next_psn_kdeth in the case of back-to-back
* RESYNC packets. Therefore, we save it.
*/
qpriv->r_next_psn_kdeth_save =
qpriv->r_next_psn_kdeth - 1;
ohdr->u.tid_rdma.ack.tid_flow_psn =
cpu_to_be32(qpriv->r_next_psn_kdeth_save);
qpriv->r_next_psn_kdeth = mask_psn(*bth2 + 1);
}
qpriv->resync = false;
}
return sizeof(ohdr->u.tid_rdma.ack) / sizeof(u32);
}
void hfi1_rc_rcv_tid_rdma_ack(struct hfi1_packet *packet)
{
struct ib_other_headers *ohdr = packet->ohdr;
struct rvt_qp *qp = packet->qp;
struct hfi1_qp_priv *qpriv = qp->priv;
struct rvt_swqe *wqe;
struct tid_rdma_request *req;
struct tid_rdma_flow *flow;
u32 aeth, psn, req_psn, ack_psn, resync_psn, ack_kpsn;
unsigned long flags;
u16 fidx;
trace_hfi1_tid_write_sender_rcv_tid_ack(qp, 0);
process_ecn(qp, packet);
psn = mask_psn(be32_to_cpu(ohdr->bth[2]));
aeth = be32_to_cpu(ohdr->u.tid_rdma.ack.aeth);
req_psn = mask_psn(be32_to_cpu(ohdr->u.tid_rdma.ack.verbs_psn));
resync_psn = mask_psn(be32_to_cpu(ohdr->u.tid_rdma.ack.tid_flow_psn));
spin_lock_irqsave(&qp->s_lock, flags);
trace_hfi1_rcv_tid_ack(qp, aeth, psn, req_psn, resync_psn);
/* If we are waiting for an ACK to RESYNC, drop any other packets */
if ((qp->s_flags & HFI1_S_WAIT_HALT) &&
cmp_psn(psn, qpriv->s_resync_psn))
goto ack_op_err;
ack_psn = req_psn;
if (hfi1_tid_rdma_is_resync_psn(psn))
ack_kpsn = resync_psn;
else
ack_kpsn = psn;
if (aeth >> 29) {
ack_psn--;
ack_kpsn--;
}
wqe = rvt_get_swqe_ptr(qp, qp->s_acked);
if (wqe->wr.opcode != IB_WR_TID_RDMA_WRITE)
goto ack_op_err;
req = wqe_to_tid_req(wqe);
trace_hfi1_tid_req_rcv_tid_ack(qp, 0, wqe->wr.opcode, wqe->psn,
wqe->lpsn, req);
flow = &req->flows[req->acked_tail];
trace_hfi1_tid_flow_rcv_tid_ack(qp, req->acked_tail, flow);
/* Drop stale ACK/NAK */
if (cmp_psn(psn, full_flow_psn(flow, flow->flow_state.spsn)) < 0)
goto ack_op_err;
while (cmp_psn(ack_kpsn,
full_flow_psn(flow, flow->flow_state.lpsn)) >= 0 &&
req->ack_seg < req->cur_seg) {
req->ack_seg++;
/* advance acked segment pointer */
req->acked_tail = CIRC_NEXT(req->acked_tail, MAX_FLOWS);
req->r_last_acked = flow->flow_state.resp_ib_psn;
trace_hfi1_tid_req_rcv_tid_ack(qp, 0, wqe->wr.opcode, wqe->psn,
wqe->lpsn, req);
if (req->ack_seg == req->total_segs) {
req->state = TID_REQUEST_COMPLETE;
wqe = do_rc_completion(qp, wqe,
to_iport(qp->ibqp.device,
qp->port_num));
trace_hfi1_sender_rcv_tid_ack(qp);
atomic_dec(&qpriv->n_tid_requests);
if (qp->s_acked == qp->s_tail)
break;
if (wqe->wr.opcode != IB_WR_TID_RDMA_WRITE)
break;
req = wqe_to_tid_req(wqe);
}
flow = &req->flows[req->acked_tail];
trace_hfi1_tid_flow_rcv_tid_ack(qp, req->acked_tail, flow);
}
trace_hfi1_tid_req_rcv_tid_ack(qp, 0, wqe->wr.opcode, wqe->psn,
wqe->lpsn, req);
switch (aeth >> 29) {
case 0: /* ACK */
if (qpriv->s_flags & RVT_S_WAIT_ACK)
qpriv->s_flags &= ~RVT_S_WAIT_ACK;
if (!hfi1_tid_rdma_is_resync_psn(psn)) {
/* Check if there is any pending TID ACK */
if (wqe->wr.opcode == IB_WR_TID_RDMA_WRITE &&
req->ack_seg < req->cur_seg)
hfi1_mod_tid_retry_timer(qp);
else
hfi1_stop_tid_retry_timer(qp);
hfi1_schedule_send(qp);
} else {
u32 spsn, fpsn, last_acked, generation;
struct tid_rdma_request *rptr;
/* ACK(RESYNC) */
hfi1_stop_tid_retry_timer(qp);
/* Allow new requests (see hfi1_make_tid_rdma_pkt) */
qp->s_flags &= ~HFI1_S_WAIT_HALT;
/*
* Clear RVT_S_SEND_ONE flag in case that the TID RDMA
* ACK is received after the TID retry timer is fired
* again. In this case, do not send any more TID
* RESYNC request or wait for any more TID ACK packet.
*/
qpriv->s_flags &= ~RVT_S_SEND_ONE;
hfi1_schedule_send(qp);
if ((qp->s_acked == qpriv->s_tid_tail &&
req->ack_seg == req->total_segs) ||
qp->s_acked == qp->s_tail) {
qpriv->s_state = TID_OP(WRITE_DATA_LAST);
goto done;
}
if (req->ack_seg == req->comp_seg) {
qpriv->s_state = TID_OP(WRITE_DATA);
goto done;
}
/*
* The PSN to start with is the next PSN after the
* RESYNC PSN.
*/
psn = mask_psn(psn + 1);
generation = psn >> HFI1_KDETH_BTH_SEQ_SHIFT;
spsn = 0;
/*
* Update to the correct WQE when we get an ACK(RESYNC)
* in the middle of a request.
*/
if (delta_psn(ack_psn, wqe->lpsn))
wqe = rvt_get_swqe_ptr(qp, qp->s_acked);
req = wqe_to_tid_req(wqe);
flow = &req->flows[req->acked_tail];
/*
* RESYNC re-numbers the PSN ranges of all remaining
* segments. Also, PSN's start from 0 in the middle of a
* segment and the first segment size is less than the
* default number of packets. flow->resync_npkts is used
* to track the number of packets from the start of the
* real segment to the point of 0 PSN after the RESYNC
* in order to later correctly rewind the SGE.
*/
fpsn = full_flow_psn(flow, flow->flow_state.spsn);
req->r_ack_psn = psn;
flow->resync_npkts +=
delta_psn(mask_psn(resync_psn + 1), fpsn);
/*
* Renumber all packet sequence number ranges
* based on the new generation.
*/
last_acked = qp->s_acked;
rptr = req;
while (1) {
/* start from last acked segment */
for (fidx = rptr->acked_tail;
CIRC_CNT(rptr->setup_head, fidx,
MAX_FLOWS);
fidx = CIRC_NEXT(fidx, MAX_FLOWS)) {
u32 lpsn;
u32 gen;
flow = &rptr->flows[fidx];
gen = flow->flow_state.generation;
if (WARN_ON(gen == generation &&
flow->flow_state.spsn !=
spsn))
continue;
lpsn = flow->flow_state.lpsn;
lpsn = full_flow_psn(flow, lpsn);
flow->npkts =
delta_psn(lpsn,
mask_psn(resync_psn)
);
flow->flow_state.generation =
generation;
flow->flow_state.spsn = spsn;
flow->flow_state.lpsn =
flow->flow_state.spsn +
flow->npkts - 1;
flow->pkt = 0;
spsn += flow->npkts;
resync_psn += flow->npkts;
trace_hfi1_tid_flow_rcv_tid_ack(qp,
fidx,
flow);
}
if (++last_acked == qpriv->s_tid_cur + 1)
break;
if (last_acked == qp->s_size)
last_acked = 0;
wqe = rvt_get_swqe_ptr(qp, last_acked);
rptr = wqe_to_tid_req(wqe);
}
req->cur_seg = req->ack_seg;
qpriv->s_tid_tail = qp->s_acked;
qpriv->s_state = TID_OP(WRITE_REQ);
hfi1_schedule_tid_send(qp);
}
done:
qpriv->s_retry = qp->s_retry_cnt;
break;
case 3: /* NAK */
hfi1_stop_tid_retry_timer(qp);
switch ((aeth >> IB_AETH_CREDIT_SHIFT) &
IB_AETH_CREDIT_MASK) {
case 0: /* PSN sequence error */
flow = &req->flows[req->acked_tail];
trace_hfi1_tid_flow_rcv_tid_ack(qp, req->acked_tail,
flow);
req->r_ack_psn = mask_psn(be32_to_cpu(ohdr->bth[2]));
req->cur_seg = req->ack_seg;
qpriv->s_tid_tail = qp->s_acked;
qpriv->s_state = TID_OP(WRITE_REQ);
qpriv->s_retry = qp->s_retry_cnt;
hfi1_schedule_tid_send(qp);
break;
default:
break;
}
break;
default:
break;
}
ack_op_err:
spin_unlock_irqrestore(&qp->s_lock, flags);
}
void hfi1_add_tid_retry_timer(struct rvt_qp *qp)
{
struct hfi1_qp_priv *priv = qp->priv;
struct ib_qp *ibqp = &qp->ibqp;
struct rvt_dev_info *rdi = ib_to_rvt(ibqp->device);
lockdep_assert_held(&qp->s_lock);
if (!(priv->s_flags & HFI1_S_TID_RETRY_TIMER)) {
priv->s_flags |= HFI1_S_TID_RETRY_TIMER;
priv->s_tid_retry_timer.expires = jiffies +
priv->tid_retry_timeout_jiffies + rdi->busy_jiffies;
add_timer(&priv->s_tid_retry_timer);
}
}
static void hfi1_mod_tid_retry_timer(struct rvt_qp *qp)
{
struct hfi1_qp_priv *priv = qp->priv;
struct ib_qp *ibqp = &qp->ibqp;
struct rvt_dev_info *rdi = ib_to_rvt(ibqp->device);
lockdep_assert_held(&qp->s_lock);
priv->s_flags |= HFI1_S_TID_RETRY_TIMER;
mod_timer(&priv->s_tid_retry_timer, jiffies +
priv->tid_retry_timeout_jiffies + rdi->busy_jiffies);
}
static int hfi1_stop_tid_retry_timer(struct rvt_qp *qp)
{
struct hfi1_qp_priv *priv = qp->priv;
int rval = 0;
lockdep_assert_held(&qp->s_lock);
if (priv->s_flags & HFI1_S_TID_RETRY_TIMER) {
rval = del_timer(&priv->s_tid_retry_timer);
priv->s_flags &= ~HFI1_S_TID_RETRY_TIMER;
}
return rval;
}
void hfi1_del_tid_retry_timer(struct rvt_qp *qp)
{
struct hfi1_qp_priv *priv = qp->priv;
del_timer_sync(&priv->s_tid_retry_timer);
priv->s_flags &= ~HFI1_S_TID_RETRY_TIMER;
}
static void hfi1_tid_retry_timeout(struct timer_list *t)
{
struct hfi1_qp_priv *priv = from_timer(priv, t, s_tid_retry_timer);
struct rvt_qp *qp = priv->owner;
struct rvt_swqe *wqe;
unsigned long flags;
struct tid_rdma_request *req;
spin_lock_irqsave(&qp->r_lock, flags);
spin_lock(&qp->s_lock);
trace_hfi1_tid_write_sender_retry_timeout(qp, 0);
if (priv->s_flags & HFI1_S_TID_RETRY_TIMER) {
hfi1_stop_tid_retry_timer(qp);
if (!priv->s_retry) {
trace_hfi1_msg_tid_retry_timeout(/* msg */
qp,
"Exhausted retries. Tid retry timeout = ",
(u64)priv->tid_retry_timeout_jiffies);
wqe = rvt_get_swqe_ptr(qp, qp->s_acked);
hfi1_trdma_send_complete(qp, wqe, IB_WC_RETRY_EXC_ERR);
rvt_error_qp(qp, IB_WC_WR_FLUSH_ERR);
} else {
wqe = rvt_get_swqe_ptr(qp, qp->s_acked);
req = wqe_to_tid_req(wqe);
trace_hfi1_tid_req_tid_retry_timeout(/* req */
qp, 0, wqe->wr.opcode, wqe->psn, wqe->lpsn, req);
priv->s_flags &= ~RVT_S_WAIT_ACK;
/* Only send one packet (the RESYNC) */
priv->s_flags |= RVT_S_SEND_ONE;
/*
* No additional request shall be made by this QP until
* the RESYNC has been complete.
*/
qp->s_flags |= HFI1_S_WAIT_HALT;
priv->s_state = TID_OP(RESYNC);
priv->s_retry--;
hfi1_schedule_tid_send(qp);
}
}
spin_unlock(&qp->s_lock);
spin_unlock_irqrestore(&qp->r_lock, flags);
}
u32 hfi1_build_tid_rdma_resync(struct rvt_qp *qp, struct rvt_swqe *wqe,
struct ib_other_headers *ohdr, u32 *bth1,
u32 *bth2, u16 fidx)
{
struct hfi1_qp_priv *qpriv = qp->priv;
struct tid_rdma_params *remote;
struct tid_rdma_request *req = wqe_to_tid_req(wqe);
struct tid_rdma_flow *flow = &req->flows[fidx];
u32 generation;
rcu_read_lock();
remote = rcu_dereference(qpriv->tid_rdma.remote);
KDETH_RESET(ohdr->u.tid_rdma.ack.kdeth1, JKEY, remote->jkey);
ohdr->u.tid_rdma.ack.verbs_qp = cpu_to_be32(qp->remote_qpn);
*bth1 = remote->qp;
rcu_read_unlock();
generation = kern_flow_generation_next(flow->flow_state.generation);
*bth2 = mask_psn((generation << HFI1_KDETH_BTH_SEQ_SHIFT) - 1);
qpriv->s_resync_psn = *bth2;
*bth2 |= IB_BTH_REQ_ACK;
KDETH_RESET(ohdr->u.tid_rdma.ack.kdeth0, KVER, 0x1);
return sizeof(ohdr->u.tid_rdma.resync) / sizeof(u32);
}
void hfi1_rc_rcv_tid_rdma_resync(struct hfi1_packet *packet)
{
struct ib_other_headers *ohdr = packet->ohdr;
struct rvt_qp *qp = packet->qp;
struct hfi1_qp_priv *qpriv = qp->priv;
struct hfi1_ctxtdata *rcd = qpriv->rcd;
struct hfi1_ibdev *dev = to_idev(qp->ibqp.device);
struct rvt_ack_entry *e;
struct tid_rdma_request *req;
struct tid_rdma_flow *flow;
struct tid_flow_state *fs = &qpriv->flow_state;
u32 psn, generation, idx, gen_next;
bool fecn;
unsigned long flags;
fecn = process_ecn(qp, packet);
psn = mask_psn(be32_to_cpu(ohdr->bth[2]));
generation = mask_psn(psn + 1) >> HFI1_KDETH_BTH_SEQ_SHIFT;
spin_lock_irqsave(&qp->s_lock, flags);
gen_next = (fs->generation == KERN_GENERATION_RESERVED) ?
generation : kern_flow_generation_next(fs->generation);
/*
* RESYNC packet contains the "next" generation and can only be
* from the current or previous generations
*/
if (generation != mask_generation(gen_next - 1) &&
generation != gen_next)
goto bail;
/* Already processing a resync */
if (qpriv->resync)
goto bail;
spin_lock(&rcd->exp_lock);
if (fs->index >= RXE_NUM_TID_FLOWS) {
/*
* If we don't have a flow, save the generation so it can be
* applied when a new flow is allocated
*/
fs->generation = generation;
} else {
/* Reprogram the QP flow with new generation */
rcd->flows[fs->index].generation = generation;
fs->generation = kern_setup_hw_flow(rcd, fs->index);
}
fs->psn = 0;
/*
* Disable SW PSN checking since a RESYNC is equivalent to a
* sync point and the flow has/will be reprogrammed
*/
qpriv->s_flags &= ~HFI1_R_TID_SW_PSN;
trace_hfi1_tid_write_rsp_rcv_resync(qp);
/*
* Reset all TID flow information with the new generation.
* This is done for all requests and segments after the
* last received segment
*/
for (idx = qpriv->r_tid_tail; ; idx++) {
u16 flow_idx;
if (idx > rvt_size_atomic(&dev->rdi))
idx = 0;
e = &qp->s_ack_queue[idx];
if (e->opcode == TID_OP(WRITE_REQ)) {
req = ack_to_tid_req(e);
trace_hfi1_tid_req_rcv_resync(qp, 0, e->opcode, e->psn,
e->lpsn, req);
/* start from last unacked segment */
for (flow_idx = req->clear_tail;
CIRC_CNT(req->setup_head, flow_idx,
MAX_FLOWS);
flow_idx = CIRC_NEXT(flow_idx, MAX_FLOWS)) {
u32 lpsn;
u32 next;
flow = &req->flows[flow_idx];
lpsn = full_flow_psn(flow,
flow->flow_state.lpsn);
next = flow->flow_state.r_next_psn;
flow->npkts = delta_psn(lpsn, next - 1);
flow->flow_state.generation = fs->generation;
flow->flow_state.spsn = fs->psn;
flow->flow_state.lpsn =
flow->flow_state.spsn + flow->npkts - 1;
flow->flow_state.r_next_psn =
full_flow_psn(flow,
flow->flow_state.spsn);
fs->psn += flow->npkts;
trace_hfi1_tid_flow_rcv_resync(qp, flow_idx,
flow);
}
}
if (idx == qp->s_tail_ack_queue)
break;
}
spin_unlock(&rcd->exp_lock);
qpriv->resync = true;
/* RESYNC request always gets a TID RDMA ACK. */
qpriv->s_nak_state = 0;
qpriv->s_flags |= RVT_S_ACK_PENDING;
hfi1_schedule_tid_send(qp);
bail:
if (fecn)
qp->s_flags |= RVT_S_ECN;
spin_unlock_irqrestore(&qp->s_lock, flags);
}
/*
* Call this function when the last TID RDMA WRITE DATA packet for a request
* is built.
*/
static void update_tid_tail(struct rvt_qp *qp)
__must_hold(&qp->s_lock)
{
struct hfi1_qp_priv *priv = qp->priv;
u32 i;
struct rvt_swqe *wqe;
lockdep_assert_held(&qp->s_lock);
/* Can't move beyond s_tid_cur */
if (priv->s_tid_tail == priv->s_tid_cur)
return;
for (i = priv->s_tid_tail + 1; ; i++) {
if (i == qp->s_size)
i = 0;
if (i == priv->s_tid_cur)
break;
wqe = rvt_get_swqe_ptr(qp, i);
if (wqe->wr.opcode == IB_WR_TID_RDMA_WRITE)
break;
}
priv->s_tid_tail = i;
priv->s_state = TID_OP(WRITE_RESP);
}
int hfi1_make_tid_rdma_pkt(struct rvt_qp *qp, struct hfi1_pkt_state *ps)
__must_hold(&qp->s_lock)
{
struct hfi1_qp_priv *priv = qp->priv;
struct rvt_swqe *wqe;
u32 bth1 = 0, bth2 = 0, hwords = 5, len, middle = 0;
struct ib_other_headers *ohdr;
struct rvt_sge_state *ss = &qp->s_sge;
struct rvt_ack_entry *e = &qp->s_ack_queue[qp->s_tail_ack_queue];
struct tid_rdma_request *req = ack_to_tid_req(e);
bool last = false;
u8 opcode = TID_OP(WRITE_DATA);
lockdep_assert_held(&qp->s_lock);
trace_hfi1_tid_write_sender_make_tid_pkt(qp, 0);
/*
* Prioritize the sending of the requests and responses over the
* sending of the TID RDMA data packets.
*/
if (((atomic_read(&priv->n_tid_requests) < HFI1_TID_RDMA_WRITE_CNT) &&
atomic_read(&priv->n_requests) &&
!(qp->s_flags & (RVT_S_BUSY | RVT_S_WAIT_ACK |
HFI1_S_ANY_WAIT_IO))) ||
(e->opcode == TID_OP(WRITE_REQ) && req->cur_seg < req->alloc_seg &&
!(qp->s_flags & (RVT_S_BUSY | HFI1_S_ANY_WAIT_IO)))) {
struct iowait_work *iowork;
iowork = iowait_get_ib_work(&priv->s_iowait);
ps->s_txreq = get_waiting_verbs_txreq(iowork);
if (ps->s_txreq || hfi1_make_rc_req(qp, ps)) {
priv->s_flags |= HFI1_S_TID_BUSY_SET;
return 1;
}
}
ps->s_txreq = get_txreq(ps->dev, qp);
if (!ps->s_txreq)
goto bail_no_tx;
ohdr = &ps->s_txreq->phdr.hdr.ibh.u.oth;
if ((priv->s_flags & RVT_S_ACK_PENDING) &&
make_tid_rdma_ack(qp, ohdr, ps))
return 1;
/*
* Bail out if we can't send data.
* Be reminded that this check must been done after the call to
* make_tid_rdma_ack() because the responding QP could be in
* RTR state where it can send TID RDMA ACK, not TID RDMA WRITE DATA.
*/
if (!(ib_rvt_state_ops[qp->state] & RVT_PROCESS_SEND_OK))
goto bail;
if (priv->s_flags & RVT_S_WAIT_ACK)
goto bail;
/* Check whether there is anything to do. */
if (priv->s_tid_tail == HFI1_QP_WQE_INVALID)
goto bail;
wqe = rvt_get_swqe_ptr(qp, priv->s_tid_tail);
req = wqe_to_tid_req(wqe);
trace_hfi1_tid_req_make_tid_pkt(qp, 0, wqe->wr.opcode, wqe->psn,
wqe->lpsn, req);
switch (priv->s_state) {
case TID_OP(WRITE_REQ):
case TID_OP(WRITE_RESP):
priv->tid_ss.sge = wqe->sg_list[0];
priv->tid_ss.sg_list = wqe->sg_list + 1;
priv->tid_ss.num_sge = wqe->wr.num_sge;
priv->tid_ss.total_len = wqe->length;
if (priv->s_state == TID_OP(WRITE_REQ))
hfi1_tid_rdma_restart_req(qp, wqe, &bth2);
priv->s_state = TID_OP(WRITE_DATA);
/* fall through */
case TID_OP(WRITE_DATA):
/*
* 1. Check whether TID RDMA WRITE RESP available.
* 2. If no:
* 2.1 If have more segments and no TID RDMA WRITE RESP,
* set HFI1_S_WAIT_TID_RESP
* 2.2 Return indicating no progress made.
* 3. If yes:
* 3.1 Build TID RDMA WRITE DATA packet.
* 3.2 If last packet in segment:
* 3.2.1 Change KDETH header bits
* 3.2.2 Advance RESP pointers.
* 3.3 Return indicating progress made.
*/
trace_hfi1_sender_make_tid_pkt(qp);
trace_hfi1_tid_write_sender_make_tid_pkt(qp, 0);
wqe = rvt_get_swqe_ptr(qp, priv->s_tid_tail);
req = wqe_to_tid_req(wqe);
len = wqe->length;
if (!req->comp_seg || req->cur_seg == req->comp_seg)
goto bail;
trace_hfi1_tid_req_make_tid_pkt(qp, 0, wqe->wr.opcode,
wqe->psn, wqe->lpsn, req);
last = hfi1_build_tid_rdma_packet(wqe, ohdr, &bth1, &bth2,
&len);
if (last) {
/* move pointer to next flow */
req->clear_tail = CIRC_NEXT(req->clear_tail,
MAX_FLOWS);
if (++req->cur_seg < req->total_segs) {
if (!CIRC_CNT(req->setup_head, req->clear_tail,
MAX_FLOWS))
qp->s_flags |= HFI1_S_WAIT_TID_RESP;
} else {
priv->s_state = TID_OP(WRITE_DATA_LAST);
opcode = TID_OP(WRITE_DATA_LAST);
/* Advance the s_tid_tail now */
update_tid_tail(qp);
}
}
hwords += sizeof(ohdr->u.tid_rdma.w_data) / sizeof(u32);
ss = &priv->tid_ss;
break;
case TID_OP(RESYNC):
trace_hfi1_sender_make_tid_pkt(qp);
/* Use generation from the most recently received response */
wqe = rvt_get_swqe_ptr(qp, priv->s_tid_cur);
req = wqe_to_tid_req(wqe);
/* If no responses for this WQE look at the previous one */
if (!req->comp_seg) {
wqe = rvt_get_swqe_ptr(qp,
(!priv->s_tid_cur ? qp->s_size :
priv->s_tid_cur) - 1);
req = wqe_to_tid_req(wqe);
}
hwords += hfi1_build_tid_rdma_resync(qp, wqe, ohdr, &bth1,
&bth2,
CIRC_PREV(req->setup_head,
MAX_FLOWS));
ss = NULL;
len = 0;
opcode = TID_OP(RESYNC);
break;
default:
goto bail;
}
if (priv->s_flags & RVT_S_SEND_ONE) {
priv->s_flags &= ~RVT_S_SEND_ONE;
priv->s_flags |= RVT_S_WAIT_ACK;
bth2 |= IB_BTH_REQ_ACK;
}
qp->s_len -= len;
ps->s_txreq->hdr_dwords = hwords;
ps->s_txreq->sde = priv->s_sde;
ps->s_txreq->ss = ss;
ps->s_txreq->s_cur_size = len;
hfi1_make_ruc_header(qp, ohdr, (opcode << 24), bth1, bth2,
middle, ps);
return 1;
bail:
hfi1_put_txreq(ps->s_txreq);
bail_no_tx:
ps->s_txreq = NULL;
priv->s_flags &= ~RVT_S_BUSY;
/*
* If we didn't get a txreq, the QP will be woken up later to try
* again, set the flags to the the wake up which work item to wake
* up.
* (A better algorithm should be found to do this and generalize the
* sleep/wakeup flags.)
*/
iowait_set_flag(&priv->s_iowait, IOWAIT_PENDING_TID);
return 0;
}
static int make_tid_rdma_ack(struct rvt_qp *qp,
struct ib_other_headers *ohdr,
struct hfi1_pkt_state *ps)
{
struct rvt_ack_entry *e;
struct hfi1_qp_priv *qpriv = qp->priv;
struct hfi1_ibdev *dev = to_idev(qp->ibqp.device);
u32 hwords, next;
u32 len = 0;
u32 bth1 = 0, bth2 = 0;
int middle = 0;
u16 flow;
struct tid_rdma_request *req, *nreq;
trace_hfi1_tid_write_rsp_make_tid_ack(qp);
/* Don't send an ACK if we aren't supposed to. */
if (!(ib_rvt_state_ops[qp->state] & RVT_PROCESS_RECV_OK))
goto bail;
/* header size in 32-bit words LRH+BTH = (8+12)/4. */
hwords = 5;
e = &qp->s_ack_queue[qpriv->r_tid_ack];
req = ack_to_tid_req(e);
/*
* In the RESYNC case, we are exactly one segment past the
* previously sent ack or at the previously sent NAK. So to send
* the resync ack, we go back one segment (which might be part of
* the previous request) and let the do-while loop execute again.
* The advantage of executing the do-while loop is that any data
* received after the previous ack is automatically acked in the
* RESYNC ack. It turns out that for the do-while loop we only need
* to pull back qpriv->r_tid_ack, not the segment
* indices/counters. The scheme works even if the previous request
* was not a TID WRITE request.
*/
if (qpriv->resync) {
if (!req->ack_seg || req->ack_seg == req->total_segs)
qpriv->r_tid_ack = !qpriv->r_tid_ack ?
rvt_size_atomic(&dev->rdi) :
qpriv->r_tid_ack - 1;
e = &qp->s_ack_queue[qpriv->r_tid_ack];
req = ack_to_tid_req(e);
}
trace_hfi1_rsp_make_tid_ack(qp, e->psn);
trace_hfi1_tid_req_make_tid_ack(qp, 0, e->opcode, e->psn, e->lpsn,
req);
/*
* If we've sent all the ACKs that we can, we are done
* until we get more segments...
*/
if (!qpriv->s_nak_state && !qpriv->resync &&
req->ack_seg == req->comp_seg)
goto bail;
do {
/*
* To deal with coalesced ACKs, the acked_tail pointer
* into the flow array is used. The distance between it
* and the clear_tail is the number of flows that are
* being ACK'ed.
*/
req->ack_seg +=
/* Get up-to-date value */
CIRC_CNT(req->clear_tail, req->acked_tail,
MAX_FLOWS);
/* Advance acked index */
req->acked_tail = req->clear_tail;
/*
* req->clear_tail points to the segment currently being
* received. So, when sending an ACK, the previous
* segment is being ACK'ed.
*/
flow = CIRC_PREV(req->acked_tail, MAX_FLOWS);
if (req->ack_seg != req->total_segs)
break;
req->state = TID_REQUEST_COMPLETE;
next = qpriv->r_tid_ack + 1;
if (next > rvt_size_atomic(&dev->rdi))
next = 0;
qpriv->r_tid_ack = next;
if (qp->s_ack_queue[next].opcode != TID_OP(WRITE_REQ))
break;
nreq = ack_to_tid_req(&qp->s_ack_queue[next]);
if (!nreq->comp_seg || nreq->ack_seg == nreq->comp_seg)
break;
/* Move to the next ack entry now */
e = &qp->s_ack_queue[qpriv->r_tid_ack];
req = ack_to_tid_req(e);
} while (1);
/*
* At this point qpriv->r_tid_ack == qpriv->r_tid_tail but e and
* req could be pointing at the previous ack queue entry
*/
if (qpriv->s_nak_state ||
(qpriv->resync &&
!hfi1_tid_rdma_is_resync_psn(qpriv->r_next_psn_kdeth - 1) &&
(cmp_psn(qpriv->r_next_psn_kdeth - 1,
full_flow_psn(&req->flows[flow],
req->flows[flow].flow_state.lpsn)) > 0))) {
/*
* A NAK will implicitly acknowledge all previous TID RDMA
* requests. Therefore, we NAK with the req->acked_tail
* segment for the request at qpriv->r_tid_ack (same at
* this point as the req->clear_tail segment for the
* qpriv->r_tid_tail request)
*/
e = &qp->s_ack_queue[qpriv->r_tid_ack];
req = ack_to_tid_req(e);
flow = req->acked_tail;
} else if (req->ack_seg == req->total_segs &&
qpriv->s_flags & HFI1_R_TID_WAIT_INTERLCK)
qpriv->s_flags &= ~HFI1_R_TID_WAIT_INTERLCK;
trace_hfi1_tid_write_rsp_make_tid_ack(qp);
trace_hfi1_tid_req_make_tid_ack(qp, 0, e->opcode, e->psn, e->lpsn,
req);
hwords += hfi1_build_tid_rdma_write_ack(qp, e, ohdr, flow, &bth1,
&bth2);
len = 0;
qpriv->s_flags &= ~RVT_S_ACK_PENDING;
ps->s_txreq->hdr_dwords = hwords;
ps->s_txreq->sde = qpriv->s_sde;
ps->s_txreq->s_cur_size = len;
ps->s_txreq->ss = NULL;
hfi1_make_ruc_header(qp, ohdr, (TID_OP(ACK) << 24), bth1, bth2, middle,
ps);
ps->s_txreq->txreq.flags |= SDMA_TXREQ_F_VIP;
return 1;
bail:
/*
* Ensure s_rdma_ack_cnt changes are committed prior to resetting
* RVT_S_RESP_PENDING
*/
smp_wmb();
qpriv->s_flags &= ~RVT_S_ACK_PENDING;
return 0;
}
static int hfi1_send_tid_ok(struct rvt_qp *qp)
{
struct hfi1_qp_priv *priv = qp->priv;
return !(priv->s_flags & RVT_S_BUSY ||
qp->s_flags & HFI1_S_ANY_WAIT_IO) &&
(verbs_txreq_queued(iowait_get_tid_work(&priv->s_iowait)) ||
(priv->s_flags & RVT_S_RESP_PENDING) ||
!(qp->s_flags & HFI1_S_ANY_TID_WAIT_SEND));
}
void _hfi1_do_tid_send(struct work_struct *work)
{
struct iowait_work *w = container_of(work, struct iowait_work, iowork);
struct rvt_qp *qp = iowait_to_qp(w->iow);
hfi1_do_tid_send(qp);
}
static void hfi1_do_tid_send(struct rvt_qp *qp)
{
struct hfi1_pkt_state ps;
struct hfi1_qp_priv *priv = qp->priv;
ps.dev = to_idev(qp->ibqp.device);
ps.ibp = to_iport(qp->ibqp.device, qp->port_num);
ps.ppd = ppd_from_ibp(ps.ibp);
ps.wait = iowait_get_tid_work(&priv->s_iowait);
ps.in_thread = false;
ps.timeout_int = qp->timeout_jiffies / 8;
trace_hfi1_rc_do_tid_send(qp, false);
spin_lock_irqsave(&qp->s_lock, ps.flags);
/* Return if we are already busy processing a work request. */
if (!hfi1_send_tid_ok(qp)) {
if (qp->s_flags & HFI1_S_ANY_WAIT_IO)
iowait_set_flag(&priv->s_iowait, IOWAIT_PENDING_TID);
spin_unlock_irqrestore(&qp->s_lock, ps.flags);
return;
}
priv->s_flags |= RVT_S_BUSY;
ps.timeout = jiffies + ps.timeout_int;
ps.cpu = priv->s_sde ? priv->s_sde->cpu :
cpumask_first(cpumask_of_node(ps.ppd->dd->node));
ps.pkts_sent = false;
/* insure a pre-built packet is handled */
ps.s_txreq = get_waiting_verbs_txreq(ps.wait);
do {
/* Check for a constructed packet to be sent. */
if (ps.s_txreq) {
if (priv->s_flags & HFI1_S_TID_BUSY_SET) {
qp->s_flags |= RVT_S_BUSY;
ps.wait = iowait_get_ib_work(&priv->s_iowait);
}
spin_unlock_irqrestore(&qp->s_lock, ps.flags);
/*
* If the packet cannot be sent now, return and
* the send tasklet will be woken up later.
*/
if (hfi1_verbs_send(qp, &ps))
return;
/* allow other tasks to run */
if (hfi1_schedule_send_yield(qp, &ps, true))
return;
spin_lock_irqsave(&qp->s_lock, ps.flags);
if (priv->s_flags & HFI1_S_TID_BUSY_SET) {
qp->s_flags &= ~RVT_S_BUSY;
priv->s_flags &= ~HFI1_S_TID_BUSY_SET;
ps.wait = iowait_get_tid_work(&priv->s_iowait);
if (iowait_flag_set(&priv->s_iowait,
IOWAIT_PENDING_IB))
hfi1_schedule_send(qp);
}
}
} while (hfi1_make_tid_rdma_pkt(qp, &ps));
iowait_starve_clear(ps.pkts_sent, &priv->s_iowait);
spin_unlock_irqrestore(&qp->s_lock, ps.flags);
}
static bool _hfi1_schedule_tid_send(struct rvt_qp *qp)
{
struct hfi1_qp_priv *priv = qp->priv;
struct hfi1_ibport *ibp =
to_iport(qp->ibqp.device, qp->port_num);
struct hfi1_pportdata *ppd = ppd_from_ibp(ibp);
struct hfi1_devdata *dd = dd_from_ibdev(qp->ibqp.device);
return iowait_tid_schedule(&priv->s_iowait, ppd->hfi1_wq,
priv->s_sde ?
priv->s_sde->cpu :
cpumask_first(cpumask_of_node(dd->node)));
}
/**
* hfi1_schedule_tid_send - schedule progress on TID RDMA state machine
* @qp: the QP
*
* This schedules qp progress on the TID RDMA state machine. Caller
* should hold the s_lock.
* Unlike hfi1_schedule_send(), this cannot use hfi1_send_ok() because
* the two state machines can step on each other with respect to the
* RVT_S_BUSY flag.
* Therefore, a modified test is used.
* @return true if the second leg is scheduled;
* false if the second leg is not scheduled.
*/
bool hfi1_schedule_tid_send(struct rvt_qp *qp)
{
lockdep_assert_held(&qp->s_lock);
if (hfi1_send_tid_ok(qp)) {
/*
* The following call returns true if the qp is not on the
* queue and false if the qp is already on the queue before
* this call. Either way, the qp will be on the queue when the
* call returns.
*/
_hfi1_schedule_tid_send(qp);
return true;
}
if (qp->s_flags & HFI1_S_ANY_WAIT_IO)
iowait_set_flag(&((struct hfi1_qp_priv *)qp->priv)->s_iowait,
IOWAIT_PENDING_TID);
return false;
}
bool hfi1_tid_rdma_ack_interlock(struct rvt_qp *qp, struct rvt_ack_entry *e)
{
struct rvt_ack_entry *prev;
struct tid_rdma_request *req;
struct hfi1_ibdev *dev = to_idev(qp->ibqp.device);
struct hfi1_qp_priv *priv = qp->priv;
u32 s_prev;
s_prev = qp->s_tail_ack_queue == 0 ? rvt_size_atomic(&dev->rdi) :
(qp->s_tail_ack_queue - 1);
prev = &qp->s_ack_queue[s_prev];
if ((e->opcode == TID_OP(READ_REQ) ||
e->opcode == OP(RDMA_READ_REQUEST)) &&
prev->opcode == TID_OP(WRITE_REQ)) {
req = ack_to_tid_req(prev);
if (req->ack_seg != req->total_segs) {
priv->s_flags |= HFI1_R_TID_WAIT_INTERLCK;
return true;
}
}
return false;
}
static u32 read_r_next_psn(struct hfi1_devdata *dd, u8 ctxt, u8 fidx)
{
u64 reg;
/*
* The only sane way to get the amount of
* progress is to read the HW flow state.
*/
reg = read_uctxt_csr(dd, ctxt, RCV_TID_FLOW_TABLE + (8 * fidx));
return mask_psn(reg);
}
static void tid_rdma_rcv_err(struct hfi1_packet *packet,
struct ib_other_headers *ohdr,
struct rvt_qp *qp, u32 psn, int diff, bool fecn)
{
unsigned long flags;
tid_rdma_rcv_error(packet, ohdr, qp, psn, diff);
if (fecn) {
spin_lock_irqsave(&qp->s_lock, flags);
qp->s_flags |= RVT_S_ECN;
spin_unlock_irqrestore(&qp->s_lock, flags);
}
}
static void update_r_next_psn_fecn(struct hfi1_packet *packet,
struct hfi1_qp_priv *priv,
struct hfi1_ctxtdata *rcd,
struct tid_rdma_flow *flow,
bool fecn)
{
/*
* If a start/middle packet is delivered here due to
* RSM rule and FECN, we need to update the r_next_psn.
*/
if (fecn && packet->etype == RHF_RCV_TYPE_EAGER &&
!(priv->s_flags & HFI1_R_TID_SW_PSN)) {
struct hfi1_devdata *dd = rcd->dd;
flow->flow_state.r_next_psn =
read_r_next_psn(dd, rcd->ctxt, flow->idx);
}
}