blob: dba4535494abdc28a5317e1b96ea3cb3b8e7a852 [file] [log] [blame]
/* SPDX-License-Identifier: GPL-2.0 or BSD-3-Clause */
/* Authors: Bernard Metzler <bmt@zurich.ibm.com> */
/* Copyright (c) 2008-2019, IBM Corporation */
#ifndef _SIW_H
#define _SIW_H
#include <rdma/ib_verbs.h>
#include <linux/socket.h>
#include <linux/skbuff.h>
#include <crypto/hash.h>
#include <linux/crc32.h>
#include <linux/crc32c.h>
#include <rdma/siw-abi.h>
#include "iwarp.h"
#define SIW_VENDOR_ID 0x626d74 /* ascii 'bmt' for now */
#define SIW_VENDORT_PART_ID 0
#define SIW_MAX_QP (1024 * 100)
#define SIW_MAX_QP_WR (1024 * 32)
#define SIW_MAX_ORD_QP 128
#define SIW_MAX_IRD_QP 128
#define SIW_MAX_SGE_PBL 256 /* max num sge's for PBL */
#define SIW_MAX_SGE_RD 1 /* iwarp limitation. we could relax */
#define SIW_MAX_CQ (1024 * 100)
#define SIW_MAX_CQE (SIW_MAX_QP_WR * 100)
#define SIW_MAX_MR (SIW_MAX_QP * 10)
#define SIW_MAX_PD SIW_MAX_QP
#define SIW_MAX_MW 0 /* to be set if MW's are supported */
#define SIW_MAX_FMR SIW_MAX_MR
#define SIW_MAX_SRQ SIW_MAX_QP
#define SIW_MAX_SRQ_WR (SIW_MAX_QP_WR * 10)
#define SIW_MAX_CONTEXT SIW_MAX_PD
/* Min number of bytes for using zero copy transmit */
#define SENDPAGE_THRESH PAGE_SIZE
/* Maximum number of frames which can be send in one SQ processing */
#define SQ_USER_MAXBURST 100
/* Maximum number of consecutive IRQ elements which get served
* if SQ has pending work. Prevents starving local SQ processing
* by serving peer Read Requests.
*/
#define SIW_IRQ_MAXBURST_SQ_ACTIVE 4
struct siw_dev_cap {
int max_qp;
int max_qp_wr;
int max_ord; /* max. outbound read queue depth */
int max_ird; /* max. inbound read queue depth */
int max_sge;
int max_sge_rd;
int max_cq;
int max_cqe;
int max_mr;
int max_pd;
int max_mw;
int max_fmr;
int max_srq;
int max_srq_wr;
int max_srq_sge;
};
struct siw_pd {
struct ib_pd base_pd;
};
struct siw_device {
struct ib_device base_dev;
struct net_device *netdev;
struct siw_dev_cap attrs;
u32 vendor_part_id;
int numa_node;
/* physical port state (only one port per device) */
enum ib_port_state state;
spinlock_t lock;
struct xarray qp_xa;
struct xarray mem_xa;
struct list_head cep_list;
struct list_head qp_list;
/* active objects statistics to enforce limits */
atomic_t num_qp;
atomic_t num_cq;
atomic_t num_pd;
atomic_t num_mr;
atomic_t num_srq;
atomic_t num_ctx;
struct work_struct netdev_down;
};
struct siw_uobj {
void *addr;
u32 size;
};
struct siw_ucontext {
struct ib_ucontext base_ucontext;
struct siw_device *sdev;
/* xarray of user mappable objects */
struct xarray xa;
u32 uobj_nextkey;
};
/*
* The RDMA core does not define LOCAL_READ access, which is always
* enabled implictely.
*/
#define IWARP_ACCESS_MASK \
(IB_ACCESS_LOCAL_WRITE | IB_ACCESS_REMOTE_WRITE | \
IB_ACCESS_REMOTE_READ)
/*
* siw presentation of user memory registered as source
* or target of RDMA operations.
*/
struct siw_page_chunk {
struct page **plist;
};
struct siw_umem {
struct siw_page_chunk *page_chunk;
int num_pages;
bool writable;
u64 fp_addr; /* First page base address */
struct mm_struct *owning_mm;
};
struct siw_pble {
dma_addr_t addr; /* Address of assigned buffer */
unsigned int size; /* Size of this entry */
unsigned long pbl_off; /* Total offset from start of PBL */
};
struct siw_pbl {
unsigned int num_buf;
unsigned int max_buf;
struct siw_pble pbe[1];
};
struct siw_mr;
/*
* Generic memory representation for registered siw memory.
* Memory lookup always via higher 24 bit of STag (STag index).
*/
struct siw_mem {
struct siw_device *sdev;
struct kref ref;
u64 va; /* VA of memory */
u64 len; /* length of the memory buffer in bytes */
u32 stag; /* iWarp memory access steering tag */
u8 stag_valid; /* VALID or INVALID */
u8 is_pbl; /* PBL or user space mem */
u8 is_mw; /* Memory Region or Memory Window */
enum ib_access_flags perms; /* local/remote READ & WRITE */
union {
struct siw_umem *umem;
struct siw_pbl *pbl;
void *mem_obj;
};
struct ib_pd *pd;
};
struct siw_mr {
struct ib_mr base_mr;
struct siw_mem *mem;
struct rcu_head rcu;
};
/*
* Error codes for local or remote
* access to registered memory
*/
enum siw_access_state {
E_ACCESS_OK,
E_STAG_INVALID,
E_BASE_BOUNDS,
E_ACCESS_PERM,
E_PD_MISMATCH
};
enum siw_wr_state {
SIW_WR_IDLE,
SIW_WR_QUEUED, /* processing has not started yet */
SIW_WR_INPROGRESS /* initiated processing of the WR */
};
/* The WQE currently being processed (RX or TX) */
struct siw_wqe {
/* Copy of applications SQE or RQE */
union {
struct siw_sqe sqe;
struct siw_rqe rqe;
};
struct siw_mem *mem[SIW_MAX_SGE]; /* per sge's resolved mem */
enum siw_wr_state wr_status;
enum siw_wc_status wc_status;
u32 bytes; /* total bytes to process */
u32 processed; /* bytes processed */
};
struct siw_cq {
struct ib_cq base_cq;
spinlock_t lock;
struct siw_cq_ctrl *notify;
struct siw_cqe *queue;
u32 cq_put;
u32 cq_get;
u32 num_cqe;
bool kernel_verbs;
u32 xa_cq_index; /* mmap information for CQE array */
u32 id; /* For debugging only */
};
enum siw_qp_state {
SIW_QP_STATE_IDLE,
SIW_QP_STATE_RTR,
SIW_QP_STATE_RTS,
SIW_QP_STATE_CLOSING,
SIW_QP_STATE_TERMINATE,
SIW_QP_STATE_ERROR,
SIW_QP_STATE_COUNT
};
enum siw_qp_flags {
SIW_RDMA_BIND_ENABLED = (1 << 0),
SIW_RDMA_WRITE_ENABLED = (1 << 1),
SIW_RDMA_READ_ENABLED = (1 << 2),
SIW_SIGNAL_ALL_WR = (1 << 3),
SIW_MPA_CRC = (1 << 4),
SIW_QP_IN_DESTROY = (1 << 5)
};
enum siw_qp_attr_mask {
SIW_QP_ATTR_STATE = (1 << 0),
SIW_QP_ATTR_ACCESS_FLAGS = (1 << 1),
SIW_QP_ATTR_LLP_HANDLE = (1 << 2),
SIW_QP_ATTR_ORD = (1 << 3),
SIW_QP_ATTR_IRD = (1 << 4),
SIW_QP_ATTR_SQ_SIZE = (1 << 5),
SIW_QP_ATTR_RQ_SIZE = (1 << 6),
SIW_QP_ATTR_MPA = (1 << 7)
};
struct siw_srq {
struct ib_srq base_srq;
spinlock_t lock;
u32 max_sge;
u32 limit; /* low watermark for async event */
struct siw_rqe *recvq;
u32 rq_put;
u32 rq_get;
u32 num_rqe; /* max # of wqe's allowed */
u32 xa_srq_index; /* mmap information for SRQ array */
char armed; /* inform user if limit hit */
char kernel_verbs; /* '1' if kernel client */
};
struct siw_qp_attrs {
enum siw_qp_state state;
u32 sq_size;
u32 rq_size;
u32 orq_size;
u32 irq_size;
u32 sq_max_sges;
u32 rq_max_sges;
enum siw_qp_flags flags;
struct socket *sk;
};
enum siw_tx_ctx {
SIW_SEND_HDR, /* start or continue sending HDR */
SIW_SEND_DATA, /* start or continue sending DDP payload */
SIW_SEND_TRAILER, /* start or continue sending TRAILER */
SIW_SEND_SHORT_FPDU/* send whole FPDU hdr|data|trailer at once */
};
enum siw_rx_state {
SIW_GET_HDR, /* await new hdr or within hdr */
SIW_GET_DATA_START, /* start of inbound DDP payload */
SIW_GET_DATA_MORE, /* continuation of (misaligned) DDP payload */
SIW_GET_TRAILER/* await new trailer or within trailer */
};
struct siw_rx_stream {
struct sk_buff *skb;
int skb_new; /* pending unread bytes in skb */
int skb_offset; /* offset in skb */
int skb_copied; /* processed bytes in skb */
union iwarp_hdr hdr;
struct mpa_trailer trailer;
enum siw_rx_state state;
/*
* For each FPDU, main RX loop runs through 3 stages:
* Receiving protocol headers, placing DDP payload and receiving
* trailer information (CRC + possibly padding).
* Next two variables keep state on receive status of the
* current FPDU part (hdr, data, trailer).
*/
int fpdu_part_rcvd; /* bytes in pkt part copied */
int fpdu_part_rem; /* bytes in pkt part not seen */
/*
* Next expected DDP MSN for each QN +
* expected steering tag +
* expected DDP tagget offset (all HBO)
*/
u32 ddp_msn[RDMAP_UNTAGGED_QN_COUNT];
u32 ddp_stag;
u64 ddp_to;
u32 inval_stag; /* Stag to be invalidated */
struct shash_desc *mpa_crc_hd;
u8 rx_suspend : 1;
u8 pad : 2; /* # of pad bytes expected */
u8 rdmap_op : 4; /* opcode of current frame */
};
struct siw_rx_fpdu {
/*
* Local destination memory of inbound RDMA operation.
* Valid, according to wqe->wr_status
*/
struct siw_wqe wqe_active;
unsigned int pbl_idx; /* Index into current PBL */
unsigned int sge_idx; /* current sge in rx */
unsigned int sge_off; /* already rcvd in curr. sge */
char first_ddp_seg; /* this is the first DDP seg */
char more_ddp_segs; /* more DDP segs expected */
u8 prev_rdmap_op : 4; /* opcode of prev frame */
};
/*
* Shorthands for short packets w/o payload
* to be transmitted more efficient.
*/
struct siw_send_pkt {
struct iwarp_send send;
__be32 crc;
};
struct siw_write_pkt {
struct iwarp_rdma_write write;
__be32 crc;
};
struct siw_rreq_pkt {
struct iwarp_rdma_rreq rreq;
__be32 crc;
};
struct siw_rresp_pkt {
struct iwarp_rdma_rresp rresp;
__be32 crc;
};
struct siw_iwarp_tx {
union {
union iwarp_hdr hdr;
/* Generic part of FPDU header */
struct iwarp_ctrl ctrl;
struct iwarp_ctrl_untagged c_untagged;
struct iwarp_ctrl_tagged c_tagged;
/* FPDU headers */
struct iwarp_rdma_write rwrite;
struct iwarp_rdma_rreq rreq;
struct iwarp_rdma_rresp rresp;
struct iwarp_terminate terminate;
struct iwarp_send send;
struct iwarp_send_inv send_inv;
/* complete short FPDUs */
struct siw_send_pkt send_pkt;
struct siw_write_pkt write_pkt;
struct siw_rreq_pkt rreq_pkt;
struct siw_rresp_pkt rresp_pkt;
} pkt;
struct mpa_trailer trailer;
/* DDP MSN for untagged messages */
u32 ddp_msn[RDMAP_UNTAGGED_QN_COUNT];
enum siw_tx_ctx state;
u16 ctrl_len; /* ddp+rdmap hdr */
u16 ctrl_sent;
int burst;
int bytes_unsent; /* ddp payload bytes */
struct shash_desc *mpa_crc_hd;
u8 do_crc : 1; /* do crc for segment */
u8 use_sendpage : 1; /* send w/o copy */
u8 tx_suspend : 1; /* stop sending DDP segs. */
u8 pad : 2; /* # pad in current fpdu */
u8 orq_fence : 1; /* ORQ full or Send fenced */
u8 in_syscall : 1; /* TX out of user context */
u8 zcopy_tx : 1; /* Use TCP_SENDPAGE if possible */
u8 gso_seg_limit; /* Maximum segments for GSO, 0 = unbound */
u16 fpdu_len; /* len of FPDU to tx */
unsigned int tcp_seglen; /* remaining tcp seg space */
struct siw_wqe wqe_active;
int pbl_idx; /* Index into current PBL */
int sge_idx; /* current sge in tx */
u32 sge_off; /* already sent in curr. sge */
};
struct siw_qp {
struct siw_device *sdev;
struct ib_qp *ib_qp;
struct kref ref;
u32 qp_num;
struct list_head devq;
int tx_cpu;
bool kernel_verbs;
struct siw_qp_attrs attrs;
struct siw_cep *cep;
struct rw_semaphore state_lock;
struct ib_pd *pd;
struct siw_cq *scq;
struct siw_cq *rcq;
struct siw_srq *srq;
struct siw_iwarp_tx tx_ctx; /* Transmit context */
spinlock_t sq_lock;
struct siw_sqe *sendq; /* send queue element array */
uint32_t sq_get; /* consumer index into sq array */
uint32_t sq_put; /* kernel prod. index into sq array */
struct llist_node tx_list;
struct siw_sqe *orq; /* outbound read queue element array */
spinlock_t orq_lock;
uint32_t orq_get; /* consumer index into orq array */
uint32_t orq_put; /* shared producer index for ORQ */
struct siw_rx_stream rx_stream;
struct siw_rx_fpdu *rx_fpdu;
struct siw_rx_fpdu rx_tagged;
struct siw_rx_fpdu rx_untagged;
spinlock_t rq_lock;
struct siw_rqe *recvq; /* recv queue element array */
uint32_t rq_get; /* consumer index into rq array */
uint32_t rq_put; /* kernel prod. index into rq array */
struct siw_sqe *irq; /* inbound read queue element array */
uint32_t irq_get; /* consumer index into irq array */
uint32_t irq_put; /* producer index into irq array */
int irq_burst;
struct { /* information to be carried in TERMINATE pkt, if valid */
u8 valid;
u8 in_tx;
u8 layer : 4, etype : 4;
u8 ecode;
} term_info;
u32 xa_sq_index; /* mmap information for SQE array */
u32 xa_rq_index; /* mmap information for RQE array */
struct rcu_head rcu;
};
struct siw_base_qp {
struct ib_qp base_qp;
struct siw_qp *qp;
};
/* helper macros */
#define rx_qp(rx) container_of(rx, struct siw_qp, rx_stream)
#define tx_qp(tx) container_of(tx, struct siw_qp, tx_ctx)
#define tx_wqe(qp) (&(qp)->tx_ctx.wqe_active)
#define rx_wqe(rctx) (&(rctx)->wqe_active)
#define rx_mem(rctx) ((rctx)->wqe_active.mem[0])
#define tx_type(wqe) ((wqe)->sqe.opcode)
#define rx_type(wqe) ((wqe)->rqe.opcode)
#define tx_flags(wqe) ((wqe)->sqe.flags)
struct iwarp_msg_info {
int hdr_len;
struct iwarp_ctrl ctrl;
int (*rx_data)(struct siw_qp *qp);
};
/* Global siw parameters. Currently set in siw_main.c */
extern const bool zcopy_tx;
extern const bool try_gso;
extern const bool loopback_enabled;
extern const bool mpa_crc_required;
extern const bool mpa_crc_strict;
extern const bool siw_tcp_nagle;
extern u_char mpa_version;
extern const bool peer_to_peer;
extern struct task_struct *siw_tx_thread[];
extern struct crypto_shash *siw_crypto_shash;
extern struct iwarp_msg_info iwarp_pktinfo[RDMAP_TERMINATE + 1];
/* QP general functions */
int siw_qp_modify(struct siw_qp *qp, struct siw_qp_attrs *attr,
enum siw_qp_attr_mask mask);
int siw_qp_mpa_rts(struct siw_qp *qp, enum mpa_v2_ctrl ctrl);
void siw_qp_llp_close(struct siw_qp *qp);
void siw_qp_cm_drop(struct siw_qp *qp, int schedule);
void siw_send_terminate(struct siw_qp *qp);
void siw_qp_get_ref(struct ib_qp *qp);
void siw_qp_put_ref(struct ib_qp *qp);
int siw_qp_add(struct siw_device *sdev, struct siw_qp *qp);
void siw_free_qp(struct kref *ref);
void siw_init_terminate(struct siw_qp *qp, enum term_elayer layer,
u8 etype, u8 ecode, int in_tx);
enum ddp_ecode siw_tagged_error(enum siw_access_state state);
enum rdmap_ecode siw_rdmap_error(enum siw_access_state state);
void siw_read_to_orq(struct siw_sqe *rreq, struct siw_sqe *sqe);
int siw_sqe_complete(struct siw_qp *qp, struct siw_sqe *sqe, u32 bytes,
enum siw_wc_status status);
int siw_rqe_complete(struct siw_qp *qp, struct siw_rqe *rqe, u32 bytes,
u32 inval_stag, enum siw_wc_status status);
void siw_qp_llp_data_ready(struct sock *sk);
void siw_qp_llp_write_space(struct sock *sk);
/* QP TX path functions */
int siw_run_sq(void *arg);
int siw_qp_sq_process(struct siw_qp *qp);
int siw_sq_start(struct siw_qp *qp);
int siw_activate_tx(struct siw_qp *qp);
void siw_stop_tx_thread(int nr_cpu);
int siw_get_tx_cpu(struct siw_device *sdev);
void siw_put_tx_cpu(int cpu);
/* QP RX path functions */
int siw_proc_send(struct siw_qp *qp);
int siw_proc_rreq(struct siw_qp *qp);
int siw_proc_rresp(struct siw_qp *qp);
int siw_proc_write(struct siw_qp *qp);
int siw_proc_terminate(struct siw_qp *qp);
int siw_tcp_rx_data(read_descriptor_t *rd_desc, struct sk_buff *skb,
unsigned int off, size_t len);
static inline void set_rx_fpdu_context(struct siw_qp *qp, u8 opcode)
{
if (opcode == RDMAP_RDMA_WRITE || opcode == RDMAP_RDMA_READ_RESP)
qp->rx_fpdu = &qp->rx_tagged;
else
qp->rx_fpdu = &qp->rx_untagged;
qp->rx_stream.rdmap_op = opcode;
}
static inline struct siw_ucontext *to_siw_ctx(struct ib_ucontext *base_ctx)
{
return container_of(base_ctx, struct siw_ucontext, base_ucontext);
}
static inline struct siw_base_qp *to_siw_base_qp(struct ib_qp *base_qp)
{
return container_of(base_qp, struct siw_base_qp, base_qp);
}
static inline struct siw_qp *to_siw_qp(struct ib_qp *base_qp)
{
return to_siw_base_qp(base_qp)->qp;
}
static inline struct siw_cq *to_siw_cq(struct ib_cq *base_cq)
{
return container_of(base_cq, struct siw_cq, base_cq);
}
static inline struct siw_srq *to_siw_srq(struct ib_srq *base_srq)
{
return container_of(base_srq, struct siw_srq, base_srq);
}
static inline struct siw_device *to_siw_dev(struct ib_device *base_dev)
{
return container_of(base_dev, struct siw_device, base_dev);
}
static inline struct siw_mr *to_siw_mr(struct ib_mr *base_mr)
{
return container_of(base_mr, struct siw_mr, base_mr);
}
static inline struct siw_qp *siw_qp_id2obj(struct siw_device *sdev, int id)
{
struct siw_qp *qp;
rcu_read_lock();
qp = xa_load(&sdev->qp_xa, id);
if (likely(qp && kref_get_unless_zero(&qp->ref))) {
rcu_read_unlock();
return qp;
}
rcu_read_unlock();
return NULL;
}
static inline u32 qp_id(struct siw_qp *qp)
{
return qp->qp_num;
}
static inline void siw_qp_get(struct siw_qp *qp)
{
kref_get(&qp->ref);
}
static inline void siw_qp_put(struct siw_qp *qp)
{
kref_put(&qp->ref, siw_free_qp);
}
static inline int siw_sq_empty(struct siw_qp *qp)
{
struct siw_sqe *sqe = &qp->sendq[qp->sq_get % qp->attrs.sq_size];
return READ_ONCE(sqe->flags) == 0;
}
static inline struct siw_sqe *sq_get_next(struct siw_qp *qp)
{
struct siw_sqe *sqe = &qp->sendq[qp->sq_get % qp->attrs.sq_size];
if (READ_ONCE(sqe->flags) & SIW_WQE_VALID)
return sqe;
return NULL;
}
static inline struct siw_sqe *orq_get_current(struct siw_qp *qp)
{
return &qp->orq[qp->orq_get % qp->attrs.orq_size];
}
static inline struct siw_sqe *orq_get_tail(struct siw_qp *qp)
{
return &qp->orq[qp->orq_put % qp->attrs.orq_size];
}
static inline struct siw_sqe *orq_get_free(struct siw_qp *qp)
{
struct siw_sqe *orq_e = orq_get_tail(qp);
if (orq_e && READ_ONCE(orq_e->flags) == 0)
return orq_e;
return NULL;
}
static inline int siw_orq_empty(struct siw_qp *qp)
{
return qp->orq[qp->orq_get % qp->attrs.orq_size].flags == 0 ? 1 : 0;
}
static inline struct siw_sqe *irq_alloc_free(struct siw_qp *qp)
{
struct siw_sqe *irq_e = &qp->irq[qp->irq_put % qp->attrs.irq_size];
if (READ_ONCE(irq_e->flags) == 0) {
qp->irq_put++;
return irq_e;
}
return NULL;
}
static inline __wsum siw_csum_update(const void *buff, int len, __wsum sum)
{
return (__force __wsum)crc32c((__force __u32)sum, buff, len);
}
static inline __wsum siw_csum_combine(__wsum csum, __wsum csum2, int offset,
int len)
{
return (__force __wsum)__crc32c_le_combine((__force __u32)csum,
(__force __u32)csum2, len);
}
static inline void siw_crc_skb(struct siw_rx_stream *srx, unsigned int len)
{
const struct skb_checksum_ops siw_cs_ops = {
.update = siw_csum_update,
.combine = siw_csum_combine,
};
__wsum crc = *(u32 *)shash_desc_ctx(srx->mpa_crc_hd);
crc = __skb_checksum(srx->skb, srx->skb_offset, len, crc,
&siw_cs_ops);
*(u32 *)shash_desc_ctx(srx->mpa_crc_hd) = crc;
}
#define siw_dbg(ibdev, fmt, ...) \
ibdev_dbg(ibdev, "%s: " fmt, __func__, ##__VA_ARGS__)
#define siw_dbg_qp(qp, fmt, ...) \
ibdev_dbg(&qp->sdev->base_dev, "QP[%u] %s: " fmt, qp_id(qp), __func__, \
##__VA_ARGS__)
#define siw_dbg_cq(cq, fmt, ...) \
ibdev_dbg(cq->base_cq.device, "CQ[%u] %s: " fmt, cq->id, __func__, \
##__VA_ARGS__)
#define siw_dbg_pd(pd, fmt, ...) \
ibdev_dbg(pd->device, "PD[%u] %s: " fmt, pd->res.id, __func__, \
##__VA_ARGS__)
#define siw_dbg_mem(mem, fmt, ...) \
ibdev_dbg(&mem->sdev->base_dev, \
"MEM[0x%08x] %s: " fmt, mem->stag, __func__, ##__VA_ARGS__)
#define siw_dbg_cep(cep, fmt, ...) \
ibdev_dbg(&cep->sdev->base_dev, "CEP[0x%pK] %s: " fmt, \
cep, __func__, ##__VA_ARGS__)
void siw_cq_flush(struct siw_cq *cq);
void siw_sq_flush(struct siw_qp *qp);
void siw_rq_flush(struct siw_qp *qp);
int siw_reap_cqe(struct siw_cq *cq, struct ib_wc *wc);
#endif