numam-spdk/lib/nvme/nvme_pcie.c
Changpeng Liu 760c98651e nvme: check metadata dword alignment
PSDT 00b also need to check the metadta alignment.

Change-Id: I117f524c61bc4c712b46c91e4d51549825d06f6c
Signed-off-by: Changpeng Liu <changpeng.liu@intel.com>
Reviewed-on: https://review.spdk.io/gerrit/c/spdk/spdk/+/1353
Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
Reviewed-by: Aleksey Marchuk <alexeymar@mellanox.com>
Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com>
2020-03-25 07:54:40 +00:00

2387 lines
64 KiB
C

/*-
* BSD LICENSE
*
* Copyright (c) Intel Corporation. All rights reserved.
* Copyright (c) 2017, IBM Corporation. All rights reserved.
* Copyright (c) 2019, 2020 Mellanox Technologies LTD. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Intel Corporation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/*
* NVMe over PCIe transport
*/
#include "spdk/stdinc.h"
#include "spdk/env.h"
#include "spdk/likely.h"
#include "spdk/string.h"
#include "nvme_internal.h"
#include "nvme_uevent.h"
/*
* Number of completion queue entries to process before ringing the
* completion queue doorbell.
*/
#define NVME_MIN_COMPLETIONS (1)
#define NVME_MAX_COMPLETIONS (128)
/*
* NVME_MAX_SGL_DESCRIPTORS defines the maximum number of descriptors in one SGL
* segment.
*/
#define NVME_MAX_SGL_DESCRIPTORS (251)
#define NVME_MAX_PRP_LIST_ENTRIES (505)
struct nvme_pcie_enum_ctx {
struct spdk_nvme_probe_ctx *probe_ctx;
struct spdk_pci_addr pci_addr;
bool has_pci_addr;
};
/* PCIe transport extensions for spdk_nvme_ctrlr */
struct nvme_pcie_ctrlr {
struct spdk_nvme_ctrlr ctrlr;
/** NVMe MMIO register space */
volatile struct spdk_nvme_registers *regs;
/** NVMe MMIO register size */
uint64_t regs_size;
struct {
/* BAR mapping address which contains controller memory buffer */
void *bar_va;
/* BAR physical address which contains controller memory buffer */
uint64_t bar_pa;
/* Controller memory buffer size in Bytes */
uint64_t size;
/* Current offset of controller memory buffer, relative to start of BAR virt addr */
uint64_t current_offset;
/* Last valid offset into CMB, this differs if CMB memory registration occurs or not */
uint64_t end;
void *mem_register_addr;
size_t mem_register_size;
bool io_data_supported;
} cmb;
/** stride in uint32_t units between doorbell registers (1 = 4 bytes, 2 = 8 bytes, ...) */
uint32_t doorbell_stride_u32;
/* Opaque handle to associated PCI device. */
struct spdk_pci_device *devhandle;
/* Flag to indicate the MMIO register has been remapped */
bool is_remapped;
};
struct nvme_tracker {
TAILQ_ENTRY(nvme_tracker) tq_list;
struct nvme_request *req;
uint16_t cid;
uint16_t rsvd0;
uint32_t rsvd1;
spdk_nvme_cmd_cb cb_fn;
void *cb_arg;
uint64_t prp_sgl_bus_addr;
union {
uint64_t prp[NVME_MAX_PRP_LIST_ENTRIES];
struct spdk_nvme_sgl_descriptor sgl[NVME_MAX_SGL_DESCRIPTORS];
} u;
};
/*
* struct nvme_tracker must be exactly 4K so that the prp[] array does not cross a page boundary
* and so that there is no padding required to meet alignment requirements.
*/
SPDK_STATIC_ASSERT(sizeof(struct nvme_tracker) == 4096, "nvme_tracker is not 4K");
SPDK_STATIC_ASSERT((offsetof(struct nvme_tracker, u.sgl) & 7) == 0, "SGL must be Qword aligned");
/* PCIe transport extensions for spdk_nvme_qpair */
struct nvme_pcie_qpair {
/* Submission queue tail doorbell */
volatile uint32_t *sq_tdbl;
/* Completion queue head doorbell */
volatile uint32_t *cq_hdbl;
/* Submission queue */
struct spdk_nvme_cmd *cmd;
/* Completion queue */
struct spdk_nvme_cpl *cpl;
TAILQ_HEAD(, nvme_tracker) free_tr;
TAILQ_HEAD(nvme_outstanding_tr_head, nvme_tracker) outstanding_tr;
/* Array of trackers indexed by command ID. */
struct nvme_tracker *tr;
uint16_t num_entries;
uint8_t retry_count;
uint16_t max_completions_cap;
uint16_t last_sq_tail;
uint16_t sq_tail;
uint16_t cq_head;
uint16_t sq_head;
struct {
uint8_t phase : 1;
uint8_t delay_cmd_submit : 1;
uint8_t has_shadow_doorbell : 1;
} flags;
/*
* Base qpair structure.
* This is located after the hot data in this structure so that the important parts of
* nvme_pcie_qpair are in the same cache line.
*/
struct spdk_nvme_qpair qpair;
struct {
/* Submission queue shadow tail doorbell */
volatile uint32_t *sq_tdbl;
/* Completion queue shadow head doorbell */
volatile uint32_t *cq_hdbl;
/* Submission queue event index */
volatile uint32_t *sq_eventidx;
/* Completion queue event index */
volatile uint32_t *cq_eventidx;
} shadow_doorbell;
/*
* Fields below this point should not be touched on the normal I/O path.
*/
bool sq_in_cmb;
uint64_t cmd_bus_addr;
uint64_t cpl_bus_addr;
struct spdk_nvme_cmd *sq_vaddr;
struct spdk_nvme_cpl *cq_vaddr;
};
static int nvme_pcie_ctrlr_attach(struct spdk_nvme_probe_ctx *probe_ctx,
struct spdk_pci_addr *pci_addr);
static int nvme_pcie_qpair_construct(struct spdk_nvme_qpair *qpair,
const struct spdk_nvme_io_qpair_opts *opts);
static int nvme_pcie_qpair_destroy(struct spdk_nvme_qpair *qpair);
__thread struct nvme_pcie_ctrlr *g_thread_mmio_ctrlr = NULL;
static uint16_t g_signal_lock;
static bool g_sigset = false;
static int g_hotplug_fd = -1;
static void
nvme_sigbus_fault_sighandler(int signum, siginfo_t *info, void *ctx)
{
void *map_address;
uint16_t flag = 0;
if (!__atomic_compare_exchange_n(&g_signal_lock, &flag, 1, false, __ATOMIC_ACQUIRE,
__ATOMIC_RELAXED)) {
SPDK_DEBUGLOG(SPDK_LOG_NVME, "request g_signal_lock failed\n");
return;
}
assert(g_thread_mmio_ctrlr != NULL);
if (!g_thread_mmio_ctrlr->is_remapped) {
map_address = mmap((void *)g_thread_mmio_ctrlr->regs, g_thread_mmio_ctrlr->regs_size,
PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANONYMOUS | MAP_FIXED, -1, 0);
if (map_address == MAP_FAILED) {
SPDK_ERRLOG("mmap failed\n");
__atomic_store_n(&g_signal_lock, 0, __ATOMIC_RELEASE);
return;
}
memset(map_address, 0xFF, sizeof(struct spdk_nvme_registers));
g_thread_mmio_ctrlr->regs = (volatile struct spdk_nvme_registers *)map_address;
g_thread_mmio_ctrlr->is_remapped = true;
}
__atomic_store_n(&g_signal_lock, 0, __ATOMIC_RELEASE);
}
static void
nvme_pcie_ctrlr_setup_signal(void)
{
struct sigaction sa;
sa.sa_sigaction = nvme_sigbus_fault_sighandler;
sigemptyset(&sa.sa_mask);
sa.sa_flags = SA_SIGINFO;
sigaction(SIGBUS, &sa, NULL);
}
static inline struct nvme_pcie_ctrlr *
nvme_pcie_ctrlr(struct spdk_nvme_ctrlr *ctrlr)
{
assert(ctrlr->trid.trtype == SPDK_NVME_TRANSPORT_PCIE);
return SPDK_CONTAINEROF(ctrlr, struct nvme_pcie_ctrlr, ctrlr);
}
static int
_nvme_pcie_hotplug_monitor(struct spdk_nvme_probe_ctx *probe_ctx)
{
struct spdk_nvme_ctrlr *ctrlr, *tmp;
struct spdk_uevent event;
struct spdk_pci_addr pci_addr;
union spdk_nvme_csts_register csts;
struct spdk_nvme_ctrlr_process *proc;
while (spdk_get_uevent(g_hotplug_fd, &event) > 0) {
if (event.subsystem == SPDK_NVME_UEVENT_SUBSYSTEM_UIO ||
event.subsystem == SPDK_NVME_UEVENT_SUBSYSTEM_VFIO) {
if (event.action == SPDK_NVME_UEVENT_ADD) {
SPDK_DEBUGLOG(SPDK_LOG_NVME, "add nvme address: %s\n",
event.traddr);
if (spdk_process_is_primary()) {
if (!spdk_pci_addr_parse(&pci_addr, event.traddr)) {
nvme_pcie_ctrlr_attach(probe_ctx, &pci_addr);
}
}
} else if (event.action == SPDK_NVME_UEVENT_REMOVE) {
struct spdk_nvme_transport_id trid;
memset(&trid, 0, sizeof(trid));
spdk_nvme_trid_populate_transport(&trid, SPDK_NVME_TRANSPORT_PCIE);
snprintf(trid.traddr, sizeof(trid.traddr), "%s", event.traddr);
ctrlr = spdk_nvme_get_ctrlr_by_trid_unsafe(&trid);
if (ctrlr == NULL) {
return 0;
}
SPDK_DEBUGLOG(SPDK_LOG_NVME, "remove nvme address: %s\n",
event.traddr);
nvme_ctrlr_fail(ctrlr, true);
/* get the user app to clean up and stop I/O */
if (ctrlr->remove_cb) {
nvme_robust_mutex_unlock(&g_spdk_nvme_driver->lock);
ctrlr->remove_cb(probe_ctx->cb_ctx, ctrlr);
nvme_robust_mutex_lock(&g_spdk_nvme_driver->lock);
}
}
}
}
/* This is a work around for vfio-attached device hot remove detection. */
TAILQ_FOREACH_SAFE(ctrlr, &g_spdk_nvme_driver->shared_attached_ctrlrs, tailq, tmp) {
bool do_remove = false;
if (ctrlr->trid.trtype == SPDK_NVME_TRANSPORT_PCIE) {
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
if (spdk_pci_device_is_removed(pctrlr->devhandle)) {
do_remove = true;
}
}
/* NVMe controller BAR must be mapped in the current process before any access. */
proc = spdk_nvme_ctrlr_get_current_process(ctrlr);
if (proc) {
csts = spdk_nvme_ctrlr_get_regs_csts(ctrlr);
if (csts.raw == 0xffffffffU) {
do_remove = true;
}
}
if (do_remove) {
nvme_ctrlr_fail(ctrlr, true);
if (ctrlr->remove_cb) {
nvme_robust_mutex_unlock(&g_spdk_nvme_driver->lock);
ctrlr->remove_cb(probe_ctx->cb_ctx, ctrlr);
nvme_robust_mutex_lock(&g_spdk_nvme_driver->lock);
}
}
}
return 0;
}
static inline struct nvme_pcie_qpair *
nvme_pcie_qpair(struct spdk_nvme_qpair *qpair)
{
assert(qpair->trtype == SPDK_NVME_TRANSPORT_PCIE);
return SPDK_CONTAINEROF(qpair, struct nvme_pcie_qpair, qpair);
}
static volatile void *
nvme_pcie_reg_addr(struct spdk_nvme_ctrlr *ctrlr, uint32_t offset)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
return (volatile void *)((uintptr_t)pctrlr->regs + offset);
}
static int
nvme_pcie_ctrlr_set_reg_4(struct spdk_nvme_ctrlr *ctrlr, uint32_t offset, uint32_t value)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
assert(offset <= sizeof(struct spdk_nvme_registers) - 4);
g_thread_mmio_ctrlr = pctrlr;
spdk_mmio_write_4(nvme_pcie_reg_addr(ctrlr, offset), value);
g_thread_mmio_ctrlr = NULL;
return 0;
}
static int
nvme_pcie_ctrlr_set_reg_8(struct spdk_nvme_ctrlr *ctrlr, uint32_t offset, uint64_t value)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
assert(offset <= sizeof(struct spdk_nvme_registers) - 8);
g_thread_mmio_ctrlr = pctrlr;
spdk_mmio_write_8(nvme_pcie_reg_addr(ctrlr, offset), value);
g_thread_mmio_ctrlr = NULL;
return 0;
}
static int
nvme_pcie_ctrlr_get_reg_4(struct spdk_nvme_ctrlr *ctrlr, uint32_t offset, uint32_t *value)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
assert(offset <= sizeof(struct spdk_nvme_registers) - 4);
assert(value != NULL);
g_thread_mmio_ctrlr = pctrlr;
*value = spdk_mmio_read_4(nvme_pcie_reg_addr(ctrlr, offset));
g_thread_mmio_ctrlr = NULL;
if (~(*value) == 0) {
return -1;
}
return 0;
}
static int
nvme_pcie_ctrlr_get_reg_8(struct spdk_nvme_ctrlr *ctrlr, uint32_t offset, uint64_t *value)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
assert(offset <= sizeof(struct spdk_nvme_registers) - 8);
assert(value != NULL);
g_thread_mmio_ctrlr = pctrlr;
*value = spdk_mmio_read_8(nvme_pcie_reg_addr(ctrlr, offset));
g_thread_mmio_ctrlr = NULL;
if (~(*value) == 0) {
return -1;
}
return 0;
}
static int
nvme_pcie_ctrlr_set_asq(struct nvme_pcie_ctrlr *pctrlr, uint64_t value)
{
return nvme_pcie_ctrlr_set_reg_8(&pctrlr->ctrlr, offsetof(struct spdk_nvme_registers, asq),
value);
}
static int
nvme_pcie_ctrlr_set_acq(struct nvme_pcie_ctrlr *pctrlr, uint64_t value)
{
return nvme_pcie_ctrlr_set_reg_8(&pctrlr->ctrlr, offsetof(struct spdk_nvme_registers, acq),
value);
}
static int
nvme_pcie_ctrlr_set_aqa(struct nvme_pcie_ctrlr *pctrlr, const union spdk_nvme_aqa_register *aqa)
{
return nvme_pcie_ctrlr_set_reg_4(&pctrlr->ctrlr, offsetof(struct spdk_nvme_registers, aqa.raw),
aqa->raw);
}
static int
nvme_pcie_ctrlr_get_cmbloc(struct nvme_pcie_ctrlr *pctrlr, union spdk_nvme_cmbloc_register *cmbloc)
{
return nvme_pcie_ctrlr_get_reg_4(&pctrlr->ctrlr, offsetof(struct spdk_nvme_registers, cmbloc.raw),
&cmbloc->raw);
}
static int
nvme_pcie_ctrlr_get_cmbsz(struct nvme_pcie_ctrlr *pctrlr, union spdk_nvme_cmbsz_register *cmbsz)
{
return nvme_pcie_ctrlr_get_reg_4(&pctrlr->ctrlr, offsetof(struct spdk_nvme_registers, cmbsz.raw),
&cmbsz->raw);
}
static uint32_t
nvme_pcie_ctrlr_get_max_xfer_size(struct spdk_nvme_ctrlr *ctrlr)
{
/*
* For commands requiring more than 2 PRP entries, one PRP will be
* embedded in the command (prp1), and the rest of the PRP entries
* will be in a list pointed to by the command (prp2). This means
* that real max number of PRP entries we support is 506+1, which
* results in a max xfer size of 506*ctrlr->page_size.
*/
return NVME_MAX_PRP_LIST_ENTRIES * ctrlr->page_size;
}
static uint16_t
nvme_pcie_ctrlr_get_max_sges(struct spdk_nvme_ctrlr *ctrlr)
{
return NVME_MAX_SGL_DESCRIPTORS;
}
static void
nvme_pcie_ctrlr_map_cmb(struct nvme_pcie_ctrlr *pctrlr)
{
int rc;
void *addr;
uint32_t bir;
union spdk_nvme_cmbsz_register cmbsz;
union spdk_nvme_cmbloc_register cmbloc;
uint64_t size, unit_size, offset, bar_size, bar_phys_addr;
uint64_t mem_register_start, mem_register_end;
if (nvme_pcie_ctrlr_get_cmbsz(pctrlr, &cmbsz) ||
nvme_pcie_ctrlr_get_cmbloc(pctrlr, &cmbloc)) {
SPDK_ERRLOG("get registers failed\n");
goto exit;
}
if (!cmbsz.bits.sz) {
goto exit;
}
bir = cmbloc.bits.bir;
/* Values 0 2 3 4 5 are valid for BAR */
if (bir > 5 || bir == 1) {
goto exit;
}
/* unit size for 4KB/64KB/1MB/16MB/256MB/4GB/64GB */
unit_size = (uint64_t)1 << (12 + 4 * cmbsz.bits.szu);
/* controller memory buffer size in Bytes */
size = unit_size * cmbsz.bits.sz;
/* controller memory buffer offset from BAR in Bytes */
offset = unit_size * cmbloc.bits.ofst;
rc = spdk_pci_device_map_bar(pctrlr->devhandle, bir, &addr,
&bar_phys_addr, &bar_size);
if ((rc != 0) || addr == NULL) {
goto exit;
}
if (offset > bar_size) {
goto exit;
}
if (size > bar_size - offset) {
goto exit;
}
pctrlr->cmb.bar_va = addr;
pctrlr->cmb.bar_pa = bar_phys_addr;
pctrlr->cmb.size = size;
pctrlr->cmb.current_offset = offset;
pctrlr->cmb.end = offset + size;
if (!cmbsz.bits.sqs) {
pctrlr->ctrlr.opts.use_cmb_sqs = false;
}
/* If only SQS is supported use legacy mapping */
if (cmbsz.bits.sqs && !(cmbsz.bits.wds || cmbsz.bits.rds)) {
return;
}
/* If CMB is less than 4MiB in size then abort CMB mapping */
if (pctrlr->cmb.size < (1ULL << 22)) {
goto exit;
}
mem_register_start = _2MB_PAGE((uintptr_t)pctrlr->cmb.bar_va + offset + VALUE_2MB - 1);
mem_register_end = _2MB_PAGE((uintptr_t)pctrlr->cmb.bar_va + offset + pctrlr->cmb.size);
pctrlr->cmb.mem_register_addr = (void *)mem_register_start;
pctrlr->cmb.mem_register_size = mem_register_end - mem_register_start;
rc = spdk_mem_register(pctrlr->cmb.mem_register_addr, pctrlr->cmb.mem_register_size);
if (rc) {
SPDK_ERRLOG("spdk_mem_register() failed\n");
goto exit;
}
pctrlr->cmb.current_offset = mem_register_start - ((uint64_t)pctrlr->cmb.bar_va);
pctrlr->cmb.end = mem_register_end - ((uint64_t)pctrlr->cmb.bar_va);
pctrlr->cmb.io_data_supported = true;
return;
exit:
pctrlr->cmb.bar_va = NULL;
pctrlr->ctrlr.opts.use_cmb_sqs = false;
return;
}
static int
nvme_pcie_ctrlr_unmap_cmb(struct nvme_pcie_ctrlr *pctrlr)
{
int rc = 0;
union spdk_nvme_cmbloc_register cmbloc;
void *addr = pctrlr->cmb.bar_va;
if (addr) {
if (pctrlr->cmb.mem_register_addr) {
spdk_mem_unregister(pctrlr->cmb.mem_register_addr, pctrlr->cmb.mem_register_size);
}
if (nvme_pcie_ctrlr_get_cmbloc(pctrlr, &cmbloc)) {
SPDK_ERRLOG("get_cmbloc() failed\n");
return -EIO;
}
rc = spdk_pci_device_unmap_bar(pctrlr->devhandle, cmbloc.bits.bir, addr);
}
return rc;
}
static void *
nvme_pcie_ctrlr_alloc_cmb_io_buffer(struct spdk_nvme_ctrlr *ctrlr, size_t size)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
uint64_t offset;
if (pctrlr->cmb.bar_va == NULL) {
SPDK_DEBUGLOG(SPDK_LOG_NVME, "CMB not available\n");
return NULL;
}
if (!pctrlr->cmb.io_data_supported) {
SPDK_DEBUGLOG(SPDK_LOG_NVME, "CMB doesn't support I/O data\n");
return NULL;
}
if (ctrlr->opts.use_cmb_sqs) {
SPDK_ERRLOG("CMB is already in use for submission queues.\n");
return NULL;
}
offset = (pctrlr->cmb.current_offset + (3)) & ~(3);
/* CMB may only consume part of the BAR, calculate accordingly */
if (offset + size > pctrlr->cmb.end) {
SPDK_ERRLOG("Tried to allocate past valid CMB range!\n");
return NULL;
}
pctrlr->cmb.current_offset = offset + size;
return pctrlr->cmb.bar_va + offset;
}
static int
nvme_pcie_ctrlr_free_cmb_io_buffer(struct spdk_nvme_ctrlr *ctrlr, void *buf, size_t size)
{
/*
* Do nothing for now.
* TODO: Track free space so buffers may be reused.
*/
SPDK_ERRLOG("no deallocation for CMB buffers yet!\n");
return 0;
}
static int
nvme_pcie_ctrlr_allocate_bars(struct nvme_pcie_ctrlr *pctrlr)
{
int rc;
void *addr;
uint64_t phys_addr, size;
rc = spdk_pci_device_map_bar(pctrlr->devhandle, 0, &addr,
&phys_addr, &size);
pctrlr->regs = (volatile struct spdk_nvme_registers *)addr;
if ((pctrlr->regs == NULL) || (rc != 0)) {
SPDK_ERRLOG("nvme_pcicfg_map_bar failed with rc %d or bar %p\n",
rc, pctrlr->regs);
return -1;
}
pctrlr->regs_size = size;
nvme_pcie_ctrlr_map_cmb(pctrlr);
return 0;
}
static int
nvme_pcie_ctrlr_free_bars(struct nvme_pcie_ctrlr *pctrlr)
{
int rc = 0;
void *addr = (void *)pctrlr->regs;
if (pctrlr->ctrlr.is_removed) {
return rc;
}
rc = nvme_pcie_ctrlr_unmap_cmb(pctrlr);
if (rc != 0) {
SPDK_ERRLOG("nvme_ctrlr_unmap_cmb failed with error code %d\n", rc);
return -1;
}
if (addr) {
/* NOTE: addr may have been remapped here. We're relying on DPDK to call
* munmap internally.
*/
rc = spdk_pci_device_unmap_bar(pctrlr->devhandle, 0, addr);
}
return rc;
}
static int
nvme_pcie_ctrlr_construct_admin_qpair(struct spdk_nvme_ctrlr *ctrlr, uint16_t num_entries)
{
struct nvme_pcie_qpair *pqpair;
int rc;
pqpair = spdk_zmalloc(sizeof(*pqpair), 64, NULL, SPDK_ENV_SOCKET_ID_ANY, SPDK_MALLOC_SHARE);
if (pqpair == NULL) {
return -ENOMEM;
}
pqpair->num_entries = num_entries;
pqpair->flags.delay_cmd_submit = 0;
ctrlr->adminq = &pqpair->qpair;
rc = nvme_qpair_init(ctrlr->adminq,
0, /* qpair ID */
ctrlr,
SPDK_NVME_QPRIO_URGENT,
num_entries);
if (rc != 0) {
return rc;
}
return nvme_pcie_qpair_construct(ctrlr->adminq, NULL);
}
/* This function must only be called while holding g_spdk_nvme_driver->lock */
static int
pcie_nvme_enum_cb(void *ctx, struct spdk_pci_device *pci_dev)
{
struct spdk_nvme_transport_id trid = {};
struct nvme_pcie_enum_ctx *enum_ctx = ctx;
struct spdk_nvme_ctrlr *ctrlr;
struct spdk_pci_addr pci_addr;
pci_addr = spdk_pci_device_get_addr(pci_dev);
spdk_nvme_trid_populate_transport(&trid, SPDK_NVME_TRANSPORT_PCIE);
spdk_pci_addr_fmt(trid.traddr, sizeof(trid.traddr), &pci_addr);
ctrlr = spdk_nvme_get_ctrlr_by_trid_unsafe(&trid);
if (!spdk_process_is_primary()) {
if (!ctrlr) {
SPDK_ERRLOG("Controller must be constructed in the primary process first.\n");
return -1;
}
return nvme_ctrlr_add_process(ctrlr, pci_dev);
}
/* check whether user passes the pci_addr */
if (enum_ctx->has_pci_addr &&
(spdk_pci_addr_compare(&pci_addr, &enum_ctx->pci_addr) != 0)) {
return 1;
}
return nvme_ctrlr_probe(&trid, enum_ctx->probe_ctx, pci_dev);
}
static int
nvme_pcie_ctrlr_scan(struct spdk_nvme_probe_ctx *probe_ctx,
bool direct_connect)
{
struct nvme_pcie_enum_ctx enum_ctx = {};
enum_ctx.probe_ctx = probe_ctx;
if (strlen(probe_ctx->trid.traddr) != 0) {
if (spdk_pci_addr_parse(&enum_ctx.pci_addr, probe_ctx->trid.traddr)) {
return -1;
}
enum_ctx.has_pci_addr = true;
}
/* Only the primary process can monitor hotplug. */
if (spdk_process_is_primary()) {
if (g_hotplug_fd < 0) {
g_hotplug_fd = spdk_uevent_connect();
if (g_hotplug_fd < 0) {
SPDK_DEBUGLOG(SPDK_LOG_NVME, "Failed to open uevent netlink socket\n");
}
} else {
_nvme_pcie_hotplug_monitor(probe_ctx);
}
}
if (enum_ctx.has_pci_addr == false) {
return spdk_pci_enumerate(spdk_pci_nvme_get_driver(),
pcie_nvme_enum_cb, &enum_ctx);
} else {
return spdk_pci_device_attach(spdk_pci_nvme_get_driver(),
pcie_nvme_enum_cb, &enum_ctx, &enum_ctx.pci_addr);
}
}
static int
nvme_pcie_ctrlr_attach(struct spdk_nvme_probe_ctx *probe_ctx, struct spdk_pci_addr *pci_addr)
{
struct nvme_pcie_enum_ctx enum_ctx;
enum_ctx.probe_ctx = probe_ctx;
enum_ctx.has_pci_addr = true;
enum_ctx.pci_addr = *pci_addr;
return spdk_pci_enumerate(spdk_pci_nvme_get_driver(), pcie_nvme_enum_cb, &enum_ctx);
}
static struct spdk_nvme_ctrlr *nvme_pcie_ctrlr_construct(const struct spdk_nvme_transport_id *trid,
const struct spdk_nvme_ctrlr_opts *opts,
void *devhandle)
{
struct spdk_pci_device *pci_dev = devhandle;
struct nvme_pcie_ctrlr *pctrlr;
union spdk_nvme_cap_register cap;
union spdk_nvme_vs_register vs;
uint32_t cmd_reg;
int rc;
struct spdk_pci_id pci_id;
rc = spdk_pci_device_claim(pci_dev);
if (rc < 0) {
SPDK_ERRLOG("could not claim device %s (%s)\n",
trid->traddr, spdk_strerror(-rc));
return NULL;
}
pctrlr = spdk_zmalloc(sizeof(struct nvme_pcie_ctrlr), 64, NULL,
SPDK_ENV_SOCKET_ID_ANY, SPDK_MALLOC_SHARE);
if (pctrlr == NULL) {
spdk_pci_device_unclaim(pci_dev);
SPDK_ERRLOG("could not allocate ctrlr\n");
return NULL;
}
pctrlr->is_remapped = false;
pctrlr->ctrlr.is_removed = false;
pctrlr->devhandle = devhandle;
pctrlr->ctrlr.opts = *opts;
pctrlr->ctrlr.trid = *trid;
rc = nvme_ctrlr_construct(&pctrlr->ctrlr);
if (rc != 0) {
spdk_pci_device_unclaim(pci_dev);
spdk_free(pctrlr);
return NULL;
}
rc = nvme_pcie_ctrlr_allocate_bars(pctrlr);
if (rc != 0) {
spdk_pci_device_unclaim(pci_dev);
spdk_free(pctrlr);
return NULL;
}
/* Enable PCI busmaster and disable INTx */
spdk_pci_device_cfg_read32(pci_dev, &cmd_reg, 4);
cmd_reg |= 0x404;
spdk_pci_device_cfg_write32(pci_dev, cmd_reg, 4);
if (nvme_ctrlr_get_cap(&pctrlr->ctrlr, &cap)) {
SPDK_ERRLOG("get_cap() failed\n");
spdk_pci_device_unclaim(pci_dev);
spdk_free(pctrlr);
return NULL;
}
if (nvme_ctrlr_get_vs(&pctrlr->ctrlr, &vs)) {
SPDK_ERRLOG("get_vs() failed\n");
spdk_pci_device_unclaim(pci_dev);
spdk_free(pctrlr);
return NULL;
}
nvme_ctrlr_init_cap(&pctrlr->ctrlr, &cap, &vs);
/* Doorbell stride is 2 ^ (dstrd + 2),
* but we want multiples of 4, so drop the + 2 */
pctrlr->doorbell_stride_u32 = 1 << cap.bits.dstrd;
pci_id = spdk_pci_device_get_id(pci_dev);
pctrlr->ctrlr.quirks = nvme_get_quirks(&pci_id);
rc = nvme_pcie_ctrlr_construct_admin_qpair(&pctrlr->ctrlr, pctrlr->ctrlr.opts.admin_queue_size);
if (rc != 0) {
nvme_ctrlr_destruct(&pctrlr->ctrlr);
return NULL;
}
/* Construct the primary process properties */
rc = nvme_ctrlr_add_process(&pctrlr->ctrlr, pci_dev);
if (rc != 0) {
nvme_ctrlr_destruct(&pctrlr->ctrlr);
return NULL;
}
if (g_sigset != true) {
nvme_pcie_ctrlr_setup_signal();
g_sigset = true;
}
return &pctrlr->ctrlr;
}
static int
nvme_pcie_ctrlr_enable(struct spdk_nvme_ctrlr *ctrlr)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
struct nvme_pcie_qpair *padminq = nvme_pcie_qpair(ctrlr->adminq);
union spdk_nvme_aqa_register aqa;
if (nvme_pcie_ctrlr_set_asq(pctrlr, padminq->cmd_bus_addr)) {
SPDK_ERRLOG("set_asq() failed\n");
return -EIO;
}
if (nvme_pcie_ctrlr_set_acq(pctrlr, padminq->cpl_bus_addr)) {
SPDK_ERRLOG("set_acq() failed\n");
return -EIO;
}
aqa.raw = 0;
/* acqs and asqs are 0-based. */
aqa.bits.acqs = nvme_pcie_qpair(ctrlr->adminq)->num_entries - 1;
aqa.bits.asqs = nvme_pcie_qpair(ctrlr->adminq)->num_entries - 1;
if (nvme_pcie_ctrlr_set_aqa(pctrlr, &aqa)) {
SPDK_ERRLOG("set_aqa() failed\n");
return -EIO;
}
return 0;
}
static int
nvme_pcie_ctrlr_destruct(struct spdk_nvme_ctrlr *ctrlr)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
struct spdk_pci_device *devhandle = nvme_ctrlr_proc_get_devhandle(ctrlr);
if (ctrlr->adminq) {
nvme_pcie_qpair_destroy(ctrlr->adminq);
}
nvme_ctrlr_destruct_finish(ctrlr);
nvme_ctrlr_free_processes(ctrlr);
nvme_pcie_ctrlr_free_bars(pctrlr);
if (devhandle) {
spdk_pci_device_unclaim(devhandle);
spdk_pci_device_detach(devhandle);
}
spdk_free(pctrlr);
return 0;
}
static void
nvme_qpair_construct_tracker(struct nvme_tracker *tr, uint16_t cid, uint64_t phys_addr)
{
tr->prp_sgl_bus_addr = phys_addr + offsetof(struct nvme_tracker, u.prp);
tr->cid = cid;
tr->req = NULL;
}
static int
nvme_pcie_qpair_reset(struct spdk_nvme_qpair *qpair)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
/* all head/tail vals are set to 0 */
pqpair->last_sq_tail = pqpair->sq_tail = pqpair->sq_head = pqpair->cq_head = 0;
/*
* First time through the completion queue, HW will set phase
* bit on completions to 1. So set this to 1 here, indicating
* we're looking for a 1 to know which entries have completed.
* we'll toggle the bit each time when the completion queue
* rolls over.
*/
pqpair->flags.phase = 1;
memset(pqpair->cmd, 0,
pqpair->num_entries * sizeof(struct spdk_nvme_cmd));
memset(pqpair->cpl, 0,
pqpair->num_entries * sizeof(struct spdk_nvme_cpl));
return 0;
}
static int
nvme_pcie_ctrlr_alloc_cmb(struct spdk_nvme_ctrlr *ctrlr, uint64_t length, uint64_t aligned,
uint64_t *offset)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
uint64_t round_offset;
round_offset = pctrlr->cmb.current_offset;
round_offset = (round_offset + (aligned - 1)) & ~(aligned - 1);
/* CMB may only consume part of the BAR, calculate accordingly */
if (round_offset + length > pctrlr->cmb.end) {
SPDK_ERRLOG("Tried to allocate past valid CMB range!\n");
return -1;
}
*offset = round_offset;
pctrlr->cmb.current_offset = round_offset + length;
return 0;
}
static int
nvme_pcie_qpair_construct(struct spdk_nvme_qpair *qpair,
const struct spdk_nvme_io_qpair_opts *opts)
{
struct spdk_nvme_ctrlr *ctrlr = qpair->ctrlr;
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
struct nvme_tracker *tr;
uint16_t i;
volatile uint32_t *doorbell_base;
uint64_t offset;
uint16_t num_trackers;
size_t page_align = VALUE_2MB;
uint32_t flags = SPDK_MALLOC_DMA;
uint64_t sq_paddr = 0;
uint64_t cq_paddr = 0;
if (opts) {
pqpair->sq_vaddr = opts->sq.vaddr;
pqpair->cq_vaddr = opts->cq.vaddr;
sq_paddr = opts->sq.paddr;
cq_paddr = opts->cq.paddr;
}
pqpair->retry_count = ctrlr->opts.transport_retry_count;
/*
* Limit the maximum number of completions to return per call to prevent wraparound,
* and calculate how many trackers can be submitted at once without overflowing the
* completion queue.
*/
pqpair->max_completions_cap = pqpair->num_entries / 4;
pqpair->max_completions_cap = spdk_max(pqpair->max_completions_cap, NVME_MIN_COMPLETIONS);
pqpair->max_completions_cap = spdk_min(pqpair->max_completions_cap, NVME_MAX_COMPLETIONS);
num_trackers = pqpair->num_entries - pqpair->max_completions_cap;
SPDK_INFOLOG(SPDK_LOG_NVME, "max_completions_cap = %" PRIu16 " num_trackers = %" PRIu16 "\n",
pqpair->max_completions_cap, num_trackers);
assert(num_trackers != 0);
pqpair->sq_in_cmb = false;
if (nvme_qpair_is_admin_queue(&pqpair->qpair)) {
flags |= SPDK_MALLOC_SHARE;
}
/* cmd and cpl rings must be aligned on page size boundaries. */
if (ctrlr->opts.use_cmb_sqs) {
if (nvme_pcie_ctrlr_alloc_cmb(ctrlr, pqpair->num_entries * sizeof(struct spdk_nvme_cmd),
sysconf(_SC_PAGESIZE), &offset) == 0) {
pqpair->cmd = pctrlr->cmb.bar_va + offset;
pqpair->cmd_bus_addr = pctrlr->cmb.bar_pa + offset;
pqpair->sq_in_cmb = true;
}
}
if (pqpair->sq_in_cmb == false) {
if (pqpair->sq_vaddr) {
pqpair->cmd = pqpair->sq_vaddr;
} else {
/* To ensure physical address contiguity we make each ring occupy
* a single hugepage only. See MAX_IO_QUEUE_ENTRIES.
*/
pqpair->cmd = spdk_zmalloc(pqpair->num_entries * sizeof(struct spdk_nvme_cmd),
page_align, NULL,
SPDK_ENV_SOCKET_ID_ANY, flags);
if (pqpair->cmd == NULL) {
SPDK_ERRLOG("alloc qpair_cmd failed\n");
return -ENOMEM;
}
}
if (sq_paddr) {
assert(pqpair->sq_vaddr != NULL);
pqpair->cmd_bus_addr = sq_paddr;
} else {
pqpair->cmd_bus_addr = spdk_vtophys(pqpair->cmd, NULL);
if (pqpair->cmd_bus_addr == SPDK_VTOPHYS_ERROR) {
SPDK_ERRLOG("spdk_vtophys(pqpair->cmd) failed\n");
return -EFAULT;
}
}
}
if (pqpair->cq_vaddr) {
pqpair->cpl = pqpair->cq_vaddr;
} else {
pqpair->cpl = spdk_zmalloc(pqpair->num_entries * sizeof(struct spdk_nvme_cpl),
page_align, NULL,
SPDK_ENV_SOCKET_ID_ANY, flags);
if (pqpair->cpl == NULL) {
SPDK_ERRLOG("alloc qpair_cpl failed\n");
return -ENOMEM;
}
}
if (cq_paddr) {
assert(pqpair->cq_vaddr != NULL);
pqpair->cpl_bus_addr = cq_paddr;
} else {
pqpair->cpl_bus_addr = spdk_vtophys(pqpair->cpl, NULL);
if (pqpair->cpl_bus_addr == SPDK_VTOPHYS_ERROR) {
SPDK_ERRLOG("spdk_vtophys(pqpair->cpl) failed\n");
return -EFAULT;
}
}
doorbell_base = &pctrlr->regs->doorbell[0].sq_tdbl;
pqpair->sq_tdbl = doorbell_base + (2 * qpair->id + 0) * pctrlr->doorbell_stride_u32;
pqpair->cq_hdbl = doorbell_base + (2 * qpair->id + 1) * pctrlr->doorbell_stride_u32;
/*
* Reserve space for all of the trackers in a single allocation.
* struct nvme_tracker must be padded so that its size is already a power of 2.
* This ensures the PRP list embedded in the nvme_tracker object will not span a
* 4KB boundary, while allowing access to trackers in tr[] via normal array indexing.
*/
pqpair->tr = spdk_zmalloc(num_trackers * sizeof(*tr), sizeof(*tr), NULL,
SPDK_ENV_SOCKET_ID_ANY, SPDK_MALLOC_SHARE);
if (pqpair->tr == NULL) {
SPDK_ERRLOG("nvme_tr failed\n");
return -ENOMEM;
}
TAILQ_INIT(&pqpair->free_tr);
TAILQ_INIT(&pqpair->outstanding_tr);
for (i = 0; i < num_trackers; i++) {
tr = &pqpair->tr[i];
nvme_qpair_construct_tracker(tr, i, spdk_vtophys(tr, NULL));
TAILQ_INSERT_HEAD(&pqpair->free_tr, tr, tq_list);
}
nvme_pcie_qpair_reset(qpair);
return 0;
}
static inline void
nvme_pcie_copy_command(struct spdk_nvme_cmd *dst, const struct spdk_nvme_cmd *src)
{
/* dst and src are known to be non-overlapping and 64-byte aligned. */
#if defined(__SSE2__)
__m128i *d128 = (__m128i *)dst;
const __m128i *s128 = (const __m128i *)src;
_mm_stream_si128(&d128[0], _mm_load_si128(&s128[0]));
_mm_stream_si128(&d128[1], _mm_load_si128(&s128[1]));
_mm_stream_si128(&d128[2], _mm_load_si128(&s128[2]));
_mm_stream_si128(&d128[3], _mm_load_si128(&s128[3]));
#else
*dst = *src;
#endif
}
/**
* Note: the ctrlr_lock must be held when calling this function.
*/
static void
nvme_pcie_qpair_insert_pending_admin_request(struct spdk_nvme_qpair *qpair,
struct nvme_request *req, struct spdk_nvme_cpl *cpl)
{
struct spdk_nvme_ctrlr *ctrlr = qpair->ctrlr;
struct nvme_request *active_req = req;
struct spdk_nvme_ctrlr_process *active_proc;
/*
* The admin request is from another process. Move to the per
* process list for that process to handle it later.
*/
assert(nvme_qpair_is_admin_queue(qpair));
assert(active_req->pid != getpid());
active_proc = spdk_nvme_ctrlr_get_process(ctrlr, active_req->pid);
if (active_proc) {
/* Save the original completion information */
memcpy(&active_req->cpl, cpl, sizeof(*cpl));
STAILQ_INSERT_TAIL(&active_proc->active_reqs, active_req, stailq);
} else {
SPDK_ERRLOG("The owning process (pid %d) is not found. Dropping the request.\n",
active_req->pid);
nvme_free_request(active_req);
}
}
/**
* Note: the ctrlr_lock must be held when calling this function.
*/
static void
nvme_pcie_qpair_complete_pending_admin_request(struct spdk_nvme_qpair *qpair)
{
struct spdk_nvme_ctrlr *ctrlr = qpair->ctrlr;
struct nvme_request *req, *tmp_req;
pid_t pid = getpid();
struct spdk_nvme_ctrlr_process *proc;
/*
* Check whether there is any pending admin request from
* other active processes.
*/
assert(nvme_qpair_is_admin_queue(qpair));
proc = spdk_nvme_ctrlr_get_current_process(ctrlr);
if (!proc) {
SPDK_ERRLOG("the active process (pid %d) is not found for this controller.\n", pid);
assert(proc);
return;
}
STAILQ_FOREACH_SAFE(req, &proc->active_reqs, stailq, tmp_req) {
STAILQ_REMOVE(&proc->active_reqs, req, nvme_request, stailq);
assert(req->pid == pid);
nvme_complete_request(req->cb_fn, req->cb_arg, qpair, req, &req->cpl);
nvme_free_request(req);
}
}
static inline int
nvme_pcie_qpair_need_event(uint16_t event_idx, uint16_t new_idx, uint16_t old)
{
return (uint16_t)(new_idx - event_idx) <= (uint16_t)(new_idx - old);
}
static bool
nvme_pcie_qpair_update_mmio_required(struct spdk_nvme_qpair *qpair, uint16_t value,
volatile uint32_t *shadow_db,
volatile uint32_t *eventidx)
{
uint16_t old;
if (!shadow_db) {
return true;
}
old = *shadow_db;
*shadow_db = value;
/*
* Ensure that the doorbell is updated before reading the EventIdx from
* memory
*/
spdk_mb();
if (!nvme_pcie_qpair_need_event(*eventidx, value, old)) {
return false;
}
return true;
}
static inline void
nvme_pcie_qpair_ring_sq_doorbell(struct spdk_nvme_qpair *qpair)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(qpair->ctrlr);
bool need_mmio = true;
if (qpair->first_fused_submitted) {
/* This is first cmd of two fused commands - don't ring doorbell */
qpair->first_fused_submitted = 0;
return;
}
if (spdk_unlikely(pqpair->flags.has_shadow_doorbell)) {
need_mmio = nvme_pcie_qpair_update_mmio_required(qpair,
pqpair->sq_tail,
pqpair->shadow_doorbell.sq_tdbl,
pqpair->shadow_doorbell.sq_eventidx);
}
if (spdk_likely(need_mmio)) {
spdk_wmb();
g_thread_mmio_ctrlr = pctrlr;
spdk_mmio_write_4(pqpair->sq_tdbl, pqpair->sq_tail);
g_thread_mmio_ctrlr = NULL;
}
}
static inline void
nvme_pcie_qpair_ring_cq_doorbell(struct spdk_nvme_qpair *qpair)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(qpair->ctrlr);
bool need_mmio = true;
if (spdk_unlikely(pqpair->flags.has_shadow_doorbell)) {
need_mmio = nvme_pcie_qpair_update_mmio_required(qpair,
pqpair->cq_head,
pqpair->shadow_doorbell.cq_hdbl,
pqpair->shadow_doorbell.cq_eventidx);
}
if (spdk_likely(need_mmio)) {
g_thread_mmio_ctrlr = pctrlr;
spdk_mmio_write_4(pqpair->cq_hdbl, pqpair->cq_head);
g_thread_mmio_ctrlr = NULL;
}
}
static void
nvme_pcie_qpair_submit_tracker(struct spdk_nvme_qpair *qpair, struct nvme_tracker *tr)
{
struct nvme_request *req;
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
req = tr->req;
assert(req != NULL);
if (req->cmd.fuse == SPDK_NVME_IO_FLAGS_FUSE_FIRST) {
/* This is first cmd of two fused commands - don't ring doorbell */
qpair->first_fused_submitted = 1;
}
/* Copy the command from the tracker to the submission queue. */
nvme_pcie_copy_command(&pqpair->cmd[pqpair->sq_tail], &req->cmd);
if (spdk_unlikely(++pqpair->sq_tail == pqpair->num_entries)) {
pqpair->sq_tail = 0;
}
if (spdk_unlikely(pqpair->sq_tail == pqpair->sq_head)) {
SPDK_ERRLOG("sq_tail is passing sq_head!\n");
}
if (!pqpair->flags.delay_cmd_submit) {
nvme_pcie_qpair_ring_sq_doorbell(qpair);
}
}
static void
nvme_pcie_qpair_complete_tracker(struct spdk_nvme_qpair *qpair, struct nvme_tracker *tr,
struct spdk_nvme_cpl *cpl, bool print_on_error)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
struct nvme_request *req;
bool retry, error;
bool req_from_current_proc = true;
req = tr->req;
assert(req != NULL);
error = spdk_nvme_cpl_is_error(cpl);
retry = error && nvme_completion_is_retry(cpl) &&
req->retries < pqpair->retry_count;
if (error && print_on_error && !qpair->ctrlr->opts.disable_error_logging) {
spdk_nvme_qpair_print_command(qpair, &req->cmd);
spdk_nvme_qpair_print_completion(qpair, cpl);
}
assert(cpl->cid == req->cmd.cid);
if (retry) {
req->retries++;
nvme_pcie_qpair_submit_tracker(qpair, tr);
} else {
/* Only check admin requests from different processes. */
if (nvme_qpair_is_admin_queue(qpair) && req->pid != getpid()) {
req_from_current_proc = false;
nvme_pcie_qpair_insert_pending_admin_request(qpair, req, cpl);
} else {
nvme_complete_request(tr->cb_fn, tr->cb_arg, qpair, req, cpl);
}
if (req_from_current_proc == true) {
nvme_qpair_free_request(qpair, req);
}
tr->req = NULL;
TAILQ_REMOVE(&pqpair->outstanding_tr, tr, tq_list);
TAILQ_INSERT_HEAD(&pqpair->free_tr, tr, tq_list);
}
}
static void
nvme_pcie_qpair_manual_complete_tracker(struct spdk_nvme_qpair *qpair,
struct nvme_tracker *tr, uint32_t sct, uint32_t sc, uint32_t dnr,
bool print_on_error)
{
struct spdk_nvme_cpl cpl;
memset(&cpl, 0, sizeof(cpl));
cpl.sqid = qpair->id;
cpl.cid = tr->cid;
cpl.status.sct = sct;
cpl.status.sc = sc;
cpl.status.dnr = dnr;
nvme_pcie_qpair_complete_tracker(qpair, tr, &cpl, print_on_error);
}
static void
nvme_pcie_qpair_abort_trackers(struct spdk_nvme_qpair *qpair, uint32_t dnr)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
struct nvme_tracker *tr, *temp, *last;
last = TAILQ_LAST(&pqpair->outstanding_tr, nvme_outstanding_tr_head);
/* Abort previously submitted (outstanding) trs */
TAILQ_FOREACH_SAFE(tr, &pqpair->outstanding_tr, tq_list, temp) {
if (!qpair->ctrlr->opts.disable_error_logging) {
SPDK_ERRLOG("aborting outstanding command\n");
}
nvme_pcie_qpair_manual_complete_tracker(qpair, tr, SPDK_NVME_SCT_GENERIC,
SPDK_NVME_SC_ABORTED_BY_REQUEST, dnr, true);
if (tr == last) {
break;
}
}
}
static void
nvme_pcie_admin_qpair_abort_aers(struct spdk_nvme_qpair *qpair)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
struct nvme_tracker *tr;
tr = TAILQ_FIRST(&pqpair->outstanding_tr);
while (tr != NULL) {
assert(tr->req != NULL);
if (tr->req->cmd.opc == SPDK_NVME_OPC_ASYNC_EVENT_REQUEST) {
nvme_pcie_qpair_manual_complete_tracker(qpair, tr,
SPDK_NVME_SCT_GENERIC, SPDK_NVME_SC_ABORTED_SQ_DELETION, 0,
false);
tr = TAILQ_FIRST(&pqpair->outstanding_tr);
} else {
tr = TAILQ_NEXT(tr, tq_list);
}
}
}
static void
nvme_pcie_admin_qpair_destroy(struct spdk_nvme_qpair *qpair)
{
nvme_pcie_admin_qpair_abort_aers(qpair);
}
static int
nvme_pcie_qpair_destroy(struct spdk_nvme_qpair *qpair)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
if (nvme_qpair_is_admin_queue(qpair)) {
nvme_pcie_admin_qpair_destroy(qpair);
}
/*
* We check sq_vaddr and cq_vaddr to see if the user specified the memory
* buffers when creating the I/O queue.
* If the user specified them, we cannot free that memory.
* Nor do we free it if it's in the CMB.
*/
if (!pqpair->sq_vaddr && pqpair->cmd && !pqpair->sq_in_cmb) {
spdk_free(pqpair->cmd);
}
if (!pqpair->cq_vaddr && pqpair->cpl) {
spdk_free(pqpair->cpl);
}
if (pqpair->tr) {
spdk_free(pqpair->tr);
}
nvme_qpair_deinit(qpair);
spdk_free(pqpair);
return 0;
}
static void
nvme_pcie_qpair_abort_reqs(struct spdk_nvme_qpair *qpair, uint32_t dnr)
{
nvme_pcie_qpair_abort_trackers(qpair, dnr);
}
static int
nvme_pcie_ctrlr_cmd_create_io_cq(struct spdk_nvme_ctrlr *ctrlr,
struct spdk_nvme_qpair *io_que, spdk_nvme_cmd_cb cb_fn,
void *cb_arg)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(io_que);
struct nvme_request *req;
struct spdk_nvme_cmd *cmd;
req = nvme_allocate_request_null(ctrlr->adminq, cb_fn, cb_arg);
if (req == NULL) {
return -ENOMEM;
}
cmd = &req->cmd;
cmd->opc = SPDK_NVME_OPC_CREATE_IO_CQ;
cmd->cdw10_bits.create_io_q.qid = io_que->id;
cmd->cdw10_bits.create_io_q.qsize = pqpair->num_entries - 1;
cmd->cdw11_bits.create_io_cq.pc = 1;
cmd->dptr.prp.prp1 = pqpair->cpl_bus_addr;
return nvme_ctrlr_submit_admin_request(ctrlr, req);
}
static int
nvme_pcie_ctrlr_cmd_create_io_sq(struct spdk_nvme_ctrlr *ctrlr,
struct spdk_nvme_qpair *io_que, spdk_nvme_cmd_cb cb_fn, void *cb_arg)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(io_que);
struct nvme_request *req;
struct spdk_nvme_cmd *cmd;
req = nvme_allocate_request_null(ctrlr->adminq, cb_fn, cb_arg);
if (req == NULL) {
return -ENOMEM;
}
cmd = &req->cmd;
cmd->opc = SPDK_NVME_OPC_CREATE_IO_SQ;
cmd->cdw10_bits.create_io_q.qid = io_que->id;
cmd->cdw10_bits.create_io_q.qsize = pqpair->num_entries - 1;
cmd->cdw11_bits.create_io_sq.pc = 1;
cmd->cdw11_bits.create_io_sq.qprio = io_que->qprio;
cmd->cdw11_bits.create_io_sq.cqid = io_que->id;
cmd->dptr.prp.prp1 = pqpair->cmd_bus_addr;
return nvme_ctrlr_submit_admin_request(ctrlr, req);
}
static int
nvme_pcie_ctrlr_cmd_delete_io_cq(struct spdk_nvme_ctrlr *ctrlr, struct spdk_nvme_qpair *qpair,
spdk_nvme_cmd_cb cb_fn, void *cb_arg)
{
struct nvme_request *req;
struct spdk_nvme_cmd *cmd;
req = nvme_allocate_request_null(ctrlr->adminq, cb_fn, cb_arg);
if (req == NULL) {
return -ENOMEM;
}
cmd = &req->cmd;
cmd->opc = SPDK_NVME_OPC_DELETE_IO_CQ;
cmd->cdw10_bits.delete_io_q.qid = qpair->id;
return nvme_ctrlr_submit_admin_request(ctrlr, req);
}
static int
nvme_pcie_ctrlr_cmd_delete_io_sq(struct spdk_nvme_ctrlr *ctrlr, struct spdk_nvme_qpair *qpair,
spdk_nvme_cmd_cb cb_fn, void *cb_arg)
{
struct nvme_request *req;
struct spdk_nvme_cmd *cmd;
req = nvme_allocate_request_null(ctrlr->adminq, cb_fn, cb_arg);
if (req == NULL) {
return -ENOMEM;
}
cmd = &req->cmd;
cmd->opc = SPDK_NVME_OPC_DELETE_IO_SQ;
cmd->cdw10_bits.delete_io_q.qid = qpair->id;
return nvme_ctrlr_submit_admin_request(ctrlr, req);
}
static int
_nvme_pcie_ctrlr_create_io_qpair(struct spdk_nvme_ctrlr *ctrlr, struct spdk_nvme_qpair *qpair,
uint16_t qid)
{
struct nvme_pcie_ctrlr *pctrlr = nvme_pcie_ctrlr(ctrlr);
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
struct nvme_completion_poll_status *status;
int rc;
status = malloc(sizeof(*status));
if (!status) {
SPDK_ERRLOG("Failed to allocate status tracker\n");
return -ENOMEM;
}
rc = nvme_pcie_ctrlr_cmd_create_io_cq(ctrlr, qpair, nvme_completion_poll_cb, status);
if (rc != 0) {
free(status);
return rc;
}
if (spdk_nvme_wait_for_completion(ctrlr->adminq, status)) {
SPDK_ERRLOG("nvme_create_io_cq failed!\n");
if (!status->timed_out) {
free(status);
}
return -1;
}
rc = nvme_pcie_ctrlr_cmd_create_io_sq(qpair->ctrlr, qpair, nvme_completion_poll_cb, status);
if (rc != 0) {
free(status);
return rc;
}
if (spdk_nvme_wait_for_completion(ctrlr->adminq, status)) {
SPDK_ERRLOG("nvme_create_io_sq failed!\n");
if (status->timed_out) {
/* Request is still queued, the memory will be freed in a completion callback.
allocate a new request */
status = malloc(sizeof(*status));
if (!status) {
SPDK_ERRLOG("Failed to allocate status tracker\n");
return -ENOMEM;
}
}
/* Attempt to delete the completion queue */
rc = nvme_pcie_ctrlr_cmd_delete_io_cq(qpair->ctrlr, qpair, nvme_completion_poll_cb, status);
if (rc != 0) {
/* The originall or newly allocated status structure can be freed since
* the corresponding request has been completed of failed to submit */
free(status);
return -1;
}
spdk_nvme_wait_for_completion(ctrlr->adminq, status);
if (!status->timed_out) {
/* status can be freed regardless of spdk_nvme_wait_for_completion return value */
free(status);
}
return -1;
}
if (ctrlr->shadow_doorbell) {
pqpair->shadow_doorbell.sq_tdbl = ctrlr->shadow_doorbell + (2 * qpair->id + 0) *
pctrlr->doorbell_stride_u32;
pqpair->shadow_doorbell.cq_hdbl = ctrlr->shadow_doorbell + (2 * qpair->id + 1) *
pctrlr->doorbell_stride_u32;
pqpair->shadow_doorbell.sq_eventidx = ctrlr->eventidx + (2 * qpair->id + 0) *
pctrlr->doorbell_stride_u32;
pqpair->shadow_doorbell.cq_eventidx = ctrlr->eventidx + (2 * qpair->id + 1) *
pctrlr->doorbell_stride_u32;
pqpair->flags.has_shadow_doorbell = 1;
} else {
pqpair->flags.has_shadow_doorbell = 0;
}
nvme_pcie_qpair_reset(qpair);
free(status);
return 0;
}
static struct spdk_nvme_qpair *
nvme_pcie_ctrlr_create_io_qpair(struct spdk_nvme_ctrlr *ctrlr, uint16_t qid,
const struct spdk_nvme_io_qpair_opts *opts)
{
struct nvme_pcie_qpair *pqpair;
struct spdk_nvme_qpair *qpair;
int rc;
assert(ctrlr != NULL);
pqpair = spdk_zmalloc(sizeof(*pqpair), 64, NULL,
SPDK_ENV_SOCKET_ID_ANY, SPDK_MALLOC_SHARE);
if (pqpair == NULL) {
return NULL;
}
pqpair->num_entries = opts->io_queue_size;
pqpair->flags.delay_cmd_submit = opts->delay_cmd_submit;
qpair = &pqpair->qpair;
rc = nvme_qpair_init(qpair, qid, ctrlr, opts->qprio, opts->io_queue_requests);
if (rc != 0) {
nvme_pcie_qpair_destroy(qpair);
return NULL;
}
rc = nvme_pcie_qpair_construct(qpair, opts);
if (rc != 0) {
nvme_pcie_qpair_destroy(qpair);
return NULL;
}
return qpair;
}
static int
nvme_pcie_ctrlr_connect_qpair(struct spdk_nvme_ctrlr *ctrlr, struct spdk_nvme_qpair *qpair)
{
if (nvme_qpair_is_admin_queue(qpair)) {
return 0;
} else {
return _nvme_pcie_ctrlr_create_io_qpair(ctrlr, qpair, qpair->id);
}
}
static void
nvme_pcie_ctrlr_disconnect_qpair(struct spdk_nvme_ctrlr *ctrlr, struct spdk_nvme_qpair *qpair)
{
}
static int
nvme_pcie_ctrlr_delete_io_qpair(struct spdk_nvme_ctrlr *ctrlr, struct spdk_nvme_qpair *qpair)
{
struct nvme_completion_poll_status *status;
int rc;
assert(ctrlr != NULL);
if (ctrlr->is_removed) {
goto free;
}
status = malloc(sizeof(*status));
if (!status) {
SPDK_ERRLOG("Failed to allocate status tracker\n");
return -ENOMEM;
}
/* Delete the I/O submission queue */
rc = nvme_pcie_ctrlr_cmd_delete_io_sq(ctrlr, qpair, nvme_completion_poll_cb, status);
if (rc != 0) {
SPDK_ERRLOG("Failed to send request to delete_io_sq with rc=%d\n", rc);
free(status);
return rc;
}
if (spdk_nvme_wait_for_completion(ctrlr->adminq, status)) {
if (!status->timed_out) {
free(status);
}
return -1;
}
/* Delete the completion queue */
rc = nvme_pcie_ctrlr_cmd_delete_io_cq(ctrlr, qpair, nvme_completion_poll_cb, status);
if (rc != 0) {
SPDK_ERRLOG("Failed to send request to delete_io_cq with rc=%d\n", rc);
free(status);
return rc;
}
if (spdk_nvme_wait_for_completion(ctrlr->adminq, status)) {
if (!status->timed_out) {
free(status);
}
return -1;
}
free(status);
free:
if (qpair->no_deletion_notification_needed == 0) {
/* Abort the rest of the I/O */
nvme_pcie_qpair_abort_trackers(qpair, 1);
}
nvme_pcie_qpair_destroy(qpair);
return 0;
}
static void
nvme_pcie_fail_request_bad_vtophys(struct spdk_nvme_qpair *qpair, struct nvme_tracker *tr)
{
/*
* Bad vtophys translation, so abort this request and return
* immediately.
*/
nvme_pcie_qpair_manual_complete_tracker(qpair, tr, SPDK_NVME_SCT_GENERIC,
SPDK_NVME_SC_INVALID_FIELD,
1 /* do not retry */, true);
}
/*
* Append PRP list entries to describe a virtually contiguous buffer starting at virt_addr of len bytes.
*
* *prp_index will be updated to account for the number of PRP entries used.
*/
static inline int
nvme_pcie_prp_list_append(struct nvme_tracker *tr, uint32_t *prp_index, void *virt_addr, size_t len,
uint32_t page_size)
{
struct spdk_nvme_cmd *cmd = &tr->req->cmd;
uintptr_t page_mask = page_size - 1;
uint64_t phys_addr;
uint32_t i;
SPDK_DEBUGLOG(SPDK_LOG_NVME, "prp_index:%u virt_addr:%p len:%u\n",
*prp_index, virt_addr, (uint32_t)len);
if (spdk_unlikely(((uintptr_t)virt_addr & 3) != 0)) {
SPDK_ERRLOG("virt_addr %p not dword aligned\n", virt_addr);
return -EFAULT;
}
i = *prp_index;
while (len) {
uint32_t seg_len;
/*
* prp_index 0 is stored in prp1, and the rest are stored in the prp[] array,
* so prp_index == count is valid.
*/
if (spdk_unlikely(i > SPDK_COUNTOF(tr->u.prp))) {
SPDK_ERRLOG("out of PRP entries\n");
return -EFAULT;
}
phys_addr = spdk_vtophys(virt_addr, NULL);
if (spdk_unlikely(phys_addr == SPDK_VTOPHYS_ERROR)) {
SPDK_ERRLOG("vtophys(%p) failed\n", virt_addr);
return -EFAULT;
}
if (i == 0) {
SPDK_DEBUGLOG(SPDK_LOG_NVME, "prp1 = %p\n", (void *)phys_addr);
cmd->dptr.prp.prp1 = phys_addr;
seg_len = page_size - ((uintptr_t)virt_addr & page_mask);
} else {
if ((phys_addr & page_mask) != 0) {
SPDK_ERRLOG("PRP %u not page aligned (%p)\n", i, virt_addr);
return -EFAULT;
}
SPDK_DEBUGLOG(SPDK_LOG_NVME, "prp[%u] = %p\n", i - 1, (void *)phys_addr);
tr->u.prp[i - 1] = phys_addr;
seg_len = page_size;
}
seg_len = spdk_min(seg_len, len);
virt_addr += seg_len;
len -= seg_len;
i++;
}
cmd->psdt = SPDK_NVME_PSDT_PRP;
if (i <= 1) {
cmd->dptr.prp.prp2 = 0;
} else if (i == 2) {
cmd->dptr.prp.prp2 = tr->u.prp[0];
SPDK_DEBUGLOG(SPDK_LOG_NVME, "prp2 = %p\n", (void *)cmd->dptr.prp.prp2);
} else {
cmd->dptr.prp.prp2 = tr->prp_sgl_bus_addr;
SPDK_DEBUGLOG(SPDK_LOG_NVME, "prp2 = %p (PRP list)\n", (void *)cmd->dptr.prp.prp2);
}
*prp_index = i;
return 0;
}
static int
nvme_pcie_qpair_build_request_invalid(struct spdk_nvme_qpair *qpair,
struct nvme_request *req, struct nvme_tracker *tr, bool dword_aligned)
{
assert(0);
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
return -EINVAL;
}
/**
* Build PRP list describing physically contiguous payload buffer.
*/
static int
nvme_pcie_qpair_build_contig_request(struct spdk_nvme_qpair *qpair, struct nvme_request *req,
struct nvme_tracker *tr, bool dword_aligned)
{
uint32_t prp_index = 0;
int rc;
rc = nvme_pcie_prp_list_append(tr, &prp_index, req->payload.contig_or_cb_arg + req->payload_offset,
req->payload_size, qpair->ctrlr->page_size);
if (rc) {
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
}
return rc;
}
/**
* Build an SGL describing a physically contiguous payload buffer.
*
* This is more efficient than using PRP because large buffers can be
* described this way.
*/
static int
nvme_pcie_qpair_build_contig_hw_sgl_request(struct spdk_nvme_qpair *qpair, struct nvme_request *req,
struct nvme_tracker *tr, bool dword_aligned)
{
void *virt_addr;
uint64_t phys_addr, mapping_length;
uint32_t length;
struct spdk_nvme_sgl_descriptor *sgl;
uint32_t nseg = 0;
assert(req->payload_size != 0);
assert(nvme_payload_type(&req->payload) == NVME_PAYLOAD_TYPE_CONTIG);
sgl = tr->u.sgl;
req->cmd.psdt = SPDK_NVME_PSDT_SGL_MPTR_CONTIG;
req->cmd.dptr.sgl1.unkeyed.subtype = 0;
length = req->payload_size;
virt_addr = req->payload.contig_or_cb_arg + req->payload_offset;
mapping_length = length;
while (length > 0) {
if (nseg >= NVME_MAX_SGL_DESCRIPTORS) {
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
return -EFAULT;
}
if (dword_aligned && ((uintptr_t)virt_addr & 3)) {
SPDK_ERRLOG("virt_addr %p not dword aligned\n", virt_addr);
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
return -EFAULT;
}
phys_addr = spdk_vtophys(virt_addr, &mapping_length);
if (phys_addr == SPDK_VTOPHYS_ERROR) {
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
return -EFAULT;
}
mapping_length = spdk_min(length, mapping_length);
length -= mapping_length;
virt_addr += mapping_length;
sgl->unkeyed.type = SPDK_NVME_SGL_TYPE_DATA_BLOCK;
sgl->unkeyed.length = mapping_length;
sgl->address = phys_addr;
sgl->unkeyed.subtype = 0;
sgl++;
nseg++;
}
if (nseg == 1) {
/*
* The whole transfer can be described by a single SGL descriptor.
* Use the special case described by the spec where SGL1's type is Data Block.
* This means the SGL in the tracker is not used at all, so copy the first (and only)
* SGL element into SGL1.
*/
req->cmd.dptr.sgl1.unkeyed.type = SPDK_NVME_SGL_TYPE_DATA_BLOCK;
req->cmd.dptr.sgl1.address = tr->u.sgl[0].address;
req->cmd.dptr.sgl1.unkeyed.length = tr->u.sgl[0].unkeyed.length;
} else {
/* SPDK NVMe driver supports only 1 SGL segment for now, it is enough because
* NVME_MAX_SGL_DESCRIPTORS * 16 is less than one page.
*/
req->cmd.dptr.sgl1.unkeyed.type = SPDK_NVME_SGL_TYPE_LAST_SEGMENT;
req->cmd.dptr.sgl1.address = tr->prp_sgl_bus_addr;
req->cmd.dptr.sgl1.unkeyed.length = nseg * sizeof(struct spdk_nvme_sgl_descriptor);
}
return 0;
}
/**
* Build SGL list describing scattered payload buffer.
*/
static int
nvme_pcie_qpair_build_hw_sgl_request(struct spdk_nvme_qpair *qpair, struct nvme_request *req,
struct nvme_tracker *tr, bool dword_aligned)
{
int rc;
void *virt_addr;
uint64_t phys_addr;
uint32_t remaining_transfer_len, remaining_user_sge_len, length;
struct spdk_nvme_sgl_descriptor *sgl;
uint32_t nseg = 0;
/*
* Build scattered payloads.
*/
assert(req->payload_size != 0);
assert(nvme_payload_type(&req->payload) == NVME_PAYLOAD_TYPE_SGL);
assert(req->payload.reset_sgl_fn != NULL);
assert(req->payload.next_sge_fn != NULL);
req->payload.reset_sgl_fn(req->payload.contig_or_cb_arg, req->payload_offset);
sgl = tr->u.sgl;
req->cmd.psdt = SPDK_NVME_PSDT_SGL_MPTR_CONTIG;
req->cmd.dptr.sgl1.unkeyed.subtype = 0;
remaining_transfer_len = req->payload_size;
while (remaining_transfer_len > 0) {
rc = req->payload.next_sge_fn(req->payload.contig_or_cb_arg,
&virt_addr, &remaining_user_sge_len);
if (rc) {
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
return -EFAULT;
}
remaining_user_sge_len = spdk_min(remaining_user_sge_len, remaining_transfer_len);
remaining_transfer_len -= remaining_user_sge_len;
while (remaining_user_sge_len > 0) {
if (nseg >= NVME_MAX_SGL_DESCRIPTORS) {
SPDK_ERRLOG("Too many SGL entries\n");
goto exit;
}
if (dword_aligned && ((uintptr_t)virt_addr & 3)) {
SPDK_ERRLOG("virt_addr %p not dword aligned\n", virt_addr);
goto exit;
}
phys_addr = spdk_vtophys(virt_addr, NULL);
if (phys_addr == SPDK_VTOPHYS_ERROR) {
goto exit;
}
length = spdk_min(remaining_user_sge_len, VALUE_2MB - _2MB_OFFSET(virt_addr));
remaining_user_sge_len -= length;
virt_addr += length;
if (nseg > 0 && phys_addr ==
(*(sgl - 1)).address + (*(sgl - 1)).unkeyed.length) {
/* extend previous entry */
(*(sgl - 1)).unkeyed.length += length;
continue;
}
sgl->unkeyed.type = SPDK_NVME_SGL_TYPE_DATA_BLOCK;
sgl->unkeyed.length = length;
sgl->address = phys_addr;
sgl->unkeyed.subtype = 0;
sgl++;
nseg++;
}
}
if (nseg == 1) {
/*
* The whole transfer can be described by a single SGL descriptor.
* Use the special case described by the spec where SGL1's type is Data Block.
* This means the SGL in the tracker is not used at all, so copy the first (and only)
* SGL element into SGL1.
*/
req->cmd.dptr.sgl1.unkeyed.type = SPDK_NVME_SGL_TYPE_DATA_BLOCK;
req->cmd.dptr.sgl1.address = tr->u.sgl[0].address;
req->cmd.dptr.sgl1.unkeyed.length = tr->u.sgl[0].unkeyed.length;
} else {
/* SPDK NVMe driver supports only 1 SGL segment for now, it is enough because
* NVME_MAX_SGL_DESCRIPTORS * 16 is less than one page.
*/
req->cmd.dptr.sgl1.unkeyed.type = SPDK_NVME_SGL_TYPE_LAST_SEGMENT;
req->cmd.dptr.sgl1.address = tr->prp_sgl_bus_addr;
req->cmd.dptr.sgl1.unkeyed.length = nseg * sizeof(struct spdk_nvme_sgl_descriptor);
}
return 0;
exit:
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
return -EFAULT;
}
/**
* Build PRP list describing scattered payload buffer.
*/
static int
nvme_pcie_qpair_build_prps_sgl_request(struct spdk_nvme_qpair *qpair, struct nvme_request *req,
struct nvme_tracker *tr, bool dword_aligned)
{
int rc;
void *virt_addr;
uint32_t remaining_transfer_len, length;
uint32_t prp_index = 0;
uint32_t page_size = qpair->ctrlr->page_size;
/*
* Build scattered payloads.
*/
assert(nvme_payload_type(&req->payload) == NVME_PAYLOAD_TYPE_SGL);
assert(req->payload.reset_sgl_fn != NULL);
req->payload.reset_sgl_fn(req->payload.contig_or_cb_arg, req->payload_offset);
remaining_transfer_len = req->payload_size;
while (remaining_transfer_len > 0) {
assert(req->payload.next_sge_fn != NULL);
rc = req->payload.next_sge_fn(req->payload.contig_or_cb_arg, &virt_addr, &length);
if (rc) {
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
return -EFAULT;
}
length = spdk_min(remaining_transfer_len, length);
/*
* Any incompatible sges should have been handled up in the splitting routine,
* but assert here as an additional check.
*
* All SGEs except last must end on a page boundary.
*/
assert((length == remaining_transfer_len) ||
_is_page_aligned((uintptr_t)virt_addr + length, page_size));
rc = nvme_pcie_prp_list_append(tr, &prp_index, virt_addr, length, page_size);
if (rc) {
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
return rc;
}
remaining_transfer_len -= length;
}
return 0;
}
typedef int(*build_req_fn)(struct spdk_nvme_qpair *, struct nvme_request *, struct nvme_tracker *,
bool);
static build_req_fn const g_nvme_pcie_build_req_table[][2] = {
[NVME_PAYLOAD_TYPE_INVALID] = {
nvme_pcie_qpair_build_request_invalid, /* PRP */
nvme_pcie_qpair_build_request_invalid /* SGL */
},
[NVME_PAYLOAD_TYPE_CONTIG] = {
nvme_pcie_qpair_build_contig_request, /* PRP */
nvme_pcie_qpair_build_contig_hw_sgl_request /* SGL */
},
[NVME_PAYLOAD_TYPE_SGL] = {
nvme_pcie_qpair_build_prps_sgl_request, /* PRP */
nvme_pcie_qpair_build_hw_sgl_request /* SGL */
}
};
static int
nvme_pcie_qpair_build_metadata(struct spdk_nvme_qpair *qpair, struct nvme_tracker *tr,
bool dword_aligned)
{
void *md_payload;
struct nvme_request *req = tr->req;
if (req->payload.md) {
md_payload = req->payload.md + req->md_offset;
if (dword_aligned && ((uintptr_t)md_payload & 3)) {
SPDK_ERRLOG("virt_addr %p not dword aligned\n", md_payload);
goto exit;
}
tr->req->cmd.mptr = spdk_vtophys(md_payload, NULL);
if (tr->req->cmd.mptr == SPDK_VTOPHYS_ERROR) {
goto exit;
}
}
return 0;
exit:
nvme_pcie_fail_request_bad_vtophys(qpair, tr);
return -EINVAL;
}
static int
nvme_pcie_qpair_submit_request(struct spdk_nvme_qpair *qpair, struct nvme_request *req)
{
struct nvme_tracker *tr;
int rc = 0;
struct spdk_nvme_ctrlr *ctrlr = qpair->ctrlr;
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
enum nvme_payload_type payload_type;
bool sgl_supported;
bool dword_aligned = true;
if (spdk_unlikely(nvme_qpair_is_admin_queue(qpair))) {
nvme_robust_mutex_lock(&ctrlr->ctrlr_lock);
}
tr = TAILQ_FIRST(&pqpair->free_tr);
if (tr == NULL) {
/* Inform the upper layer to try again later. */
rc = -EAGAIN;
goto exit;
}
TAILQ_REMOVE(&pqpair->free_tr, tr, tq_list); /* remove tr from free_tr */
TAILQ_INSERT_TAIL(&pqpair->outstanding_tr, tr, tq_list);
tr->req = req;
tr->cb_fn = req->cb_fn;
tr->cb_arg = req->cb_arg;
req->cmd.cid = tr->cid;
if (req->payload_size != 0) {
payload_type = nvme_payload_type(&req->payload);
/* According to the specification, PRPs shall be used for all
* Admin commands for NVMe over PCIe implementations.
*/
sgl_supported = (ctrlr->flags & SPDK_NVME_CTRLR_SGL_SUPPORTED) != 0 &&
!nvme_qpair_is_admin_queue(qpair);
if (sgl_supported && !(ctrlr->flags & SPDK_NVME_CTRLR_SGL_REQUIRES_DWORD_ALIGNMENT)) {
dword_aligned = false;
}
rc = g_nvme_pcie_build_req_table[payload_type][sgl_supported](qpair, req, tr, dword_aligned);
if (rc < 0) {
goto exit;
}
rc = nvme_pcie_qpair_build_metadata(qpair, tr, dword_aligned);
if (rc < 0) {
goto exit;
}
}
nvme_pcie_qpair_submit_tracker(qpair, tr);
exit:
if (spdk_unlikely(nvme_qpair_is_admin_queue(qpair))) {
nvme_robust_mutex_unlock(&ctrlr->ctrlr_lock);
}
return rc;
}
static void
nvme_pcie_qpair_check_timeout(struct spdk_nvme_qpair *qpair)
{
uint64_t t02;
struct nvme_tracker *tr, *tmp;
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
struct spdk_nvme_ctrlr *ctrlr = qpair->ctrlr;
struct spdk_nvme_ctrlr_process *active_proc;
/* Don't check timeouts during controller initialization. */
if (ctrlr->state != NVME_CTRLR_STATE_READY) {
return;
}
if (nvme_qpair_is_admin_queue(qpair)) {
active_proc = spdk_nvme_ctrlr_get_current_process(ctrlr);
} else {
active_proc = qpair->active_proc;
}
/* Only check timeouts if the current process has a timeout callback. */
if (active_proc == NULL || active_proc->timeout_cb_fn == NULL) {
return;
}
t02 = spdk_get_ticks();
TAILQ_FOREACH_SAFE(tr, &pqpair->outstanding_tr, tq_list, tmp) {
assert(tr->req != NULL);
if (nvme_request_check_timeout(tr->req, tr->cid, active_proc, t02)) {
/*
* The requests are in order, so as soon as one has not timed out,
* stop iterating.
*/
break;
}
}
}
static int32_t
nvme_pcie_qpair_process_completions(struct spdk_nvme_qpair *qpair, uint32_t max_completions)
{
struct nvme_pcie_qpair *pqpair = nvme_pcie_qpair(qpair);
struct nvme_tracker *tr;
struct spdk_nvme_cpl *cpl, *next_cpl;
uint32_t num_completions = 0;
struct spdk_nvme_ctrlr *ctrlr = qpair->ctrlr;
uint16_t next_cq_head;
uint8_t next_phase;
bool next_is_valid = false;
if (spdk_unlikely(nvme_qpair_is_admin_queue(qpair))) {
nvme_robust_mutex_lock(&ctrlr->ctrlr_lock);
}
if (max_completions == 0 || max_completions > pqpair->max_completions_cap) {
/*
* max_completions == 0 means unlimited, but complete at most
* max_completions_cap batch of I/O at a time so that the completion
* queue doorbells don't wrap around.
*/
max_completions = pqpair->max_completions_cap;
}
while (1) {
cpl = &pqpair->cpl[pqpair->cq_head];
if (!next_is_valid && cpl->status.p != pqpair->flags.phase) {
break;
}
if (spdk_likely(pqpair->cq_head + 1 != pqpair->num_entries)) {
next_cq_head = pqpair->cq_head + 1;
next_phase = pqpair->flags.phase;
} else {
next_cq_head = 0;
next_phase = !pqpair->flags.phase;
}
next_cpl = &pqpair->cpl[next_cq_head];
next_is_valid = (next_cpl->status.p == next_phase);
if (next_is_valid) {
__builtin_prefetch(&pqpair->tr[next_cpl->cid]);
}
#ifdef __PPC64__
/*
* This memory barrier prevents reordering of:
* - load after store from/to tr
* - load after load cpl phase and cpl cid
*/
spdk_mb();
#elif defined(__aarch64__)
__asm volatile("dmb oshld" ::: "memory");
#endif
if (spdk_unlikely(++pqpair->cq_head == pqpair->num_entries)) {
pqpair->cq_head = 0;
pqpair->flags.phase = !pqpair->flags.phase;
}
tr = &pqpair->tr[cpl->cid];
/* Prefetch the req's STAILQ_ENTRY since we'll need to access it
* as part of putting the req back on the qpair's free list.
*/
__builtin_prefetch(&tr->req->stailq);
pqpair->sq_head = cpl->sqhd;
if (tr->req) {
nvme_pcie_qpair_complete_tracker(qpair, tr, cpl, true);
} else {
SPDK_ERRLOG("cpl does not map to outstanding cmd\n");
spdk_nvme_qpair_print_completion(qpair, cpl);
assert(0);
}
if (++num_completions == max_completions) {
break;
}
}
if (num_completions > 0) {
nvme_pcie_qpair_ring_cq_doorbell(qpair);
}
if (pqpair->flags.delay_cmd_submit) {
if (pqpair->last_sq_tail != pqpair->sq_tail) {
nvme_pcie_qpair_ring_sq_doorbell(qpair);
pqpair->last_sq_tail = pqpair->sq_tail;
}
}
if (spdk_unlikely(ctrlr->timeout_enabled)) {
/*
* User registered for timeout callback
*/
nvme_pcie_qpair_check_timeout(qpair);
}
/* Before returning, complete any pending admin request. */
if (spdk_unlikely(nvme_qpair_is_admin_queue(qpair))) {
nvme_pcie_qpair_complete_pending_admin_request(qpair);
nvme_robust_mutex_unlock(&ctrlr->ctrlr_lock);
}
return num_completions;
}
const struct spdk_nvme_transport_ops pcie_ops = {
.name = "PCIE",
.type = SPDK_NVME_TRANSPORT_PCIE,
.ctrlr_construct = nvme_pcie_ctrlr_construct,
.ctrlr_scan = nvme_pcie_ctrlr_scan,
.ctrlr_destruct = nvme_pcie_ctrlr_destruct,
.ctrlr_enable = nvme_pcie_ctrlr_enable,
.ctrlr_set_reg_4 = nvme_pcie_ctrlr_set_reg_4,
.ctrlr_set_reg_8 = nvme_pcie_ctrlr_set_reg_8,
.ctrlr_get_reg_4 = nvme_pcie_ctrlr_get_reg_4,
.ctrlr_get_reg_8 = nvme_pcie_ctrlr_get_reg_8,
.ctrlr_get_max_xfer_size = nvme_pcie_ctrlr_get_max_xfer_size,
.ctrlr_get_max_sges = nvme_pcie_ctrlr_get_max_sges,
.ctrlr_alloc_cmb_io_buffer = nvme_pcie_ctrlr_alloc_cmb_io_buffer,
.ctrlr_free_cmb_io_buffer = nvme_pcie_ctrlr_free_cmb_io_buffer,
.ctrlr_create_io_qpair = nvme_pcie_ctrlr_create_io_qpair,
.ctrlr_delete_io_qpair = nvme_pcie_ctrlr_delete_io_qpair,
.ctrlr_connect_qpair = nvme_pcie_ctrlr_connect_qpair,
.ctrlr_disconnect_qpair = nvme_pcie_ctrlr_disconnect_qpair,
.qpair_abort_reqs = nvme_pcie_qpair_abort_reqs,
.qpair_reset = nvme_pcie_qpair_reset,
.qpair_submit_request = nvme_pcie_qpair_submit_request,
.qpair_process_completions = nvme_pcie_qpair_process_completions,
.admin_qpair_abort_aers = nvme_pcie_admin_qpair_abort_aers,
};
SPDK_NVME_TRANSPORT_REGISTER(pcie, &pcie_ops);