/*- * BSD LICENSE * * Copyright (c) Intel Corporation. * 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. */ #include "spdk/stdinc.h" #include "ioat_internal.h" #include "spdk/env.h" #include "spdk/util.h" #include "spdk_internal/log.h" struct ioat_driver { pthread_mutex_t lock; TAILQ_HEAD(, spdk_ioat_chan) attached_chans; }; static struct ioat_driver g_ioat_driver = { .lock = PTHREAD_MUTEX_INITIALIZER, .attached_chans = TAILQ_HEAD_INITIALIZER(g_ioat_driver.attached_chans), }; static uint64_t ioat_get_chansts(struct spdk_ioat_chan *ioat) { return spdk_mmio_read_8(&ioat->regs->chansts); } static void ioat_write_chancmp(struct spdk_ioat_chan *ioat, uint64_t addr) { spdk_mmio_write_8(&ioat->regs->chancmp, addr); } static void ioat_write_chainaddr(struct spdk_ioat_chan *ioat, uint64_t addr) { spdk_mmio_write_8(&ioat->regs->chainaddr, addr); } static inline void ioat_suspend(struct spdk_ioat_chan *ioat) { ioat->regs->chancmd = SPDK_IOAT_CHANCMD_SUSPEND; } static inline void ioat_reset(struct spdk_ioat_chan *ioat) { ioat->regs->chancmd = SPDK_IOAT_CHANCMD_RESET; } static inline uint32_t ioat_reset_pending(struct spdk_ioat_chan *ioat) { uint8_t cmd; cmd = ioat->regs->chancmd; return (cmd & SPDK_IOAT_CHANCMD_RESET) == SPDK_IOAT_CHANCMD_RESET; } static int ioat_map_pci_bar(struct spdk_ioat_chan *ioat) { int regs_bar, rc; void *addr; uint64_t phys_addr, size; regs_bar = 0; rc = spdk_pci_device_map_bar(ioat->device, regs_bar, &addr, &phys_addr, &size); if (rc != 0 || addr == NULL) { SPDK_ERRLOG("pci_device_map_range failed with error code %d\n", rc); return -1; } ioat->regs = (volatile struct spdk_ioat_registers *)addr; return 0; } static int ioat_unmap_pci_bar(struct spdk_ioat_chan *ioat) { int rc = 0; void *addr = (void *)ioat->regs; if (addr) { rc = spdk_pci_device_unmap_bar(ioat->device, 0, addr); } return rc; } static inline uint32_t ioat_get_active(struct spdk_ioat_chan *ioat) { return (ioat->head - ioat->tail) & ((1 << ioat->ring_size_order) - 1); } static inline uint32_t ioat_get_ring_space(struct spdk_ioat_chan *ioat) { return (1 << ioat->ring_size_order) - ioat_get_active(ioat) - 1; } static uint32_t ioat_get_ring_index(struct spdk_ioat_chan *ioat, uint32_t index) { return index & ((1 << ioat->ring_size_order) - 1); } static void ioat_get_ring_entry(struct spdk_ioat_chan *ioat, uint32_t index, struct ioat_descriptor **desc, union spdk_ioat_hw_desc **hw_desc) { uint32_t i = ioat_get_ring_index(ioat, index); *desc = &ioat->ring[i]; *hw_desc = &ioat->hw_ring[i]; } static uint64_t ioat_get_desc_phys_addr(struct spdk_ioat_chan *ioat, uint32_t index) { return ioat->hw_ring_phys_addr + ioat_get_ring_index(ioat, index) * sizeof(union spdk_ioat_hw_desc); } static void ioat_submit_single(struct spdk_ioat_chan *ioat) { ioat->head++; } static void ioat_flush(struct spdk_ioat_chan *ioat) { ioat->regs->dmacount = (uint16_t)ioat->head; } static struct ioat_descriptor * ioat_prep_null(struct spdk_ioat_chan *ioat) { struct ioat_descriptor *desc; union spdk_ioat_hw_desc *hw_desc; if (ioat_get_ring_space(ioat) < 1) { return NULL; } ioat_get_ring_entry(ioat, ioat->head, &desc, &hw_desc); hw_desc->dma.u.control_raw = 0; hw_desc->dma.u.control.op = SPDK_IOAT_OP_COPY; hw_desc->dma.u.control.null = 1; hw_desc->dma.u.control.completion_update = 1; hw_desc->dma.size = 8; hw_desc->dma.src_addr = 0; hw_desc->dma.dest_addr = 0; desc->callback_fn = NULL; desc->callback_arg = NULL; ioat_submit_single(ioat); return desc; } static struct ioat_descriptor * ioat_prep_copy(struct spdk_ioat_chan *ioat, uint64_t dst, uint64_t src, uint32_t len) { struct ioat_descriptor *desc; union spdk_ioat_hw_desc *hw_desc; assert(len <= ioat->max_xfer_size); if (ioat_get_ring_space(ioat) < 1) { return NULL; } ioat_get_ring_entry(ioat, ioat->head, &desc, &hw_desc); hw_desc->dma.u.control_raw = 0; hw_desc->dma.u.control.op = SPDK_IOAT_OP_COPY; hw_desc->dma.u.control.completion_update = 1; hw_desc->dma.size = len; hw_desc->dma.src_addr = src; hw_desc->dma.dest_addr = dst; desc->callback_fn = NULL; desc->callback_arg = NULL; ioat_submit_single(ioat); return desc; } static struct ioat_descriptor * ioat_prep_fill(struct spdk_ioat_chan *ioat, uint64_t dst, uint64_t fill_pattern, uint32_t len) { struct ioat_descriptor *desc; union spdk_ioat_hw_desc *hw_desc; assert(len <= ioat->max_xfer_size); if (ioat_get_ring_space(ioat) < 1) { return NULL; } ioat_get_ring_entry(ioat, ioat->head, &desc, &hw_desc); hw_desc->fill.u.control_raw = 0; hw_desc->fill.u.control.op = SPDK_IOAT_OP_FILL; hw_desc->fill.u.control.completion_update = 1; hw_desc->fill.size = len; hw_desc->fill.src_data = fill_pattern; hw_desc->fill.dest_addr = dst; desc->callback_fn = NULL; desc->callback_arg = NULL; ioat_submit_single(ioat); return desc; } static int ioat_reset_hw(struct spdk_ioat_chan *ioat) { int timeout; uint64_t status; uint32_t chanerr; status = ioat_get_chansts(ioat); if (is_ioat_active(status) || is_ioat_idle(status)) { ioat_suspend(ioat); } timeout = 20; /* in milliseconds */ while (is_ioat_active(status) || is_ioat_idle(status)) { spdk_delay_us(1000); timeout--; if (timeout == 0) { SPDK_ERRLOG("timed out waiting for suspend\n"); return -1; } status = ioat_get_chansts(ioat); } /* * Clear any outstanding errors. * CHANERR is write-1-to-clear, so write the current CHANERR bits back to reset everything. */ chanerr = ioat->regs->chanerr; ioat->regs->chanerr = chanerr; ioat_reset(ioat); timeout = 20; while (ioat_reset_pending(ioat)) { spdk_delay_us(1000); timeout--; if (timeout == 0) { SPDK_ERRLOG("timed out waiting for reset\n"); return -1; } } return 0; } static int ioat_process_channel_events(struct spdk_ioat_chan *ioat) { struct ioat_descriptor *desc; uint64_t status, completed_descriptor, hw_desc_phys_addr; uint32_t tail; if (ioat->head == ioat->tail) { return 0; } status = *ioat->comp_update; completed_descriptor = status & SPDK_IOAT_CHANSTS_COMPLETED_DESCRIPTOR_MASK; if (is_ioat_halted(status)) { SPDK_ERRLOG("Channel halted (%x)\n", ioat->regs->chanerr); return -1; } if (completed_descriptor == ioat->last_seen) { return 0; } do { tail = ioat_get_ring_index(ioat, ioat->tail); desc = &ioat->ring[tail]; if (desc->callback_fn) { desc->callback_fn(desc->callback_arg); } hw_desc_phys_addr = ioat_get_desc_phys_addr(ioat, ioat->tail); ioat->tail++; } while (hw_desc_phys_addr != completed_descriptor); ioat->last_seen = hw_desc_phys_addr; return 0; } static int ioat_channel_destruct(struct spdk_ioat_chan *ioat) { ioat_unmap_pci_bar(ioat); if (ioat->ring) { free(ioat->ring); } if (ioat->hw_ring) { spdk_dma_free(ioat->hw_ring); } if (ioat->comp_update) { spdk_dma_free((void *)ioat->comp_update); ioat->comp_update = NULL; } return 0; } static int ioat_channel_start(struct spdk_ioat_chan *ioat) { uint8_t xfercap, version; uint64_t status; int i, num_descriptors; uint64_t comp_update_bus_addr = 0; if (ioat_map_pci_bar(ioat) != 0) { SPDK_ERRLOG("ioat_map_pci_bar() failed\n"); return -1; } version = ioat->regs->cbver; if (version < SPDK_IOAT_VER_3_0) { SPDK_ERRLOG(" unsupported IOAT version %u.%u\n", version >> 4, version & 0xF); return -1; } /* Always support DMA copy */ ioat->dma_capabilities = SPDK_IOAT_ENGINE_COPY_SUPPORTED; if (ioat->regs->dmacapability & SPDK_IOAT_DMACAP_BFILL) ioat->dma_capabilities |= SPDK_IOAT_ENGINE_FILL_SUPPORTED; xfercap = ioat->regs->xfercap; /* Only bits [4:0] are valid. */ xfercap &= 0x1f; if (xfercap == 0) { /* 0 means 4 GB max transfer size. */ ioat->max_xfer_size = 1ULL << 32; } else if (xfercap < 12) { /* XFCERCAP must be at least 12 (4 KB) according to the spec. */ SPDK_ERRLOG("invalid XFERCAP value %u\n", xfercap); return -1; } else { ioat->max_xfer_size = 1U << xfercap; } ioat->comp_update = spdk_dma_zmalloc(sizeof(*ioat->comp_update), SPDK_IOAT_CHANCMP_ALIGN, &comp_update_bus_addr); if (ioat->comp_update == NULL) { return -1; } ioat->ring_size_order = IOAT_DEFAULT_ORDER; num_descriptors = 1 << ioat->ring_size_order; ioat->ring = calloc(num_descriptors, sizeof(struct ioat_descriptor)); if (!ioat->ring) { return -1; } ioat->hw_ring = spdk_dma_zmalloc(num_descriptors * sizeof(union spdk_ioat_hw_desc), 64, &ioat->hw_ring_phys_addr); if (!ioat->hw_ring) { return -1; } for (i = 0; i < num_descriptors; i++) { ioat->hw_ring[i].generic.next = ioat_get_desc_phys_addr(ioat, i + 1); } ioat->head = 0; ioat->tail = 0; ioat->last_seen = 0; ioat_reset_hw(ioat); ioat->regs->chanctrl = SPDK_IOAT_CHANCTRL_ANY_ERR_ABORT_EN; ioat_write_chancmp(ioat, comp_update_bus_addr); ioat_write_chainaddr(ioat, ioat->hw_ring_phys_addr); ioat_prep_null(ioat); ioat_flush(ioat); i = 100; while (i-- > 0) { spdk_delay_us(100); status = ioat_get_chansts(ioat); if (is_ioat_idle(status)) break; } if (is_ioat_idle(status)) { ioat_process_channel_events(ioat); } else { SPDK_ERRLOG("could not start channel: status = %p\n error = %#x\n", (void *)status, ioat->regs->chanerr); return -1; } return 0; } /* Caller must hold g_ioat_driver.lock */ static struct spdk_ioat_chan * ioat_attach(void *device) { struct spdk_ioat_chan *ioat; uint32_t cmd_reg; ioat = calloc(1, sizeof(struct spdk_ioat_chan)); if (ioat == NULL) { return NULL; } /* Enable PCI busmaster. */ spdk_pci_device_cfg_read32(device, &cmd_reg, 4); cmd_reg |= 0x4; spdk_pci_device_cfg_write32(device, cmd_reg, 4); ioat->device = device; if (ioat_channel_start(ioat) != 0) { ioat_channel_destruct(ioat); free(ioat); return NULL; } return ioat; } struct ioat_enum_ctx { spdk_ioat_probe_cb probe_cb; spdk_ioat_attach_cb attach_cb; void *cb_ctx; }; /* This function must only be called while holding g_ioat_driver.lock */ static int ioat_enum_cb(void *ctx, struct spdk_pci_device *pci_dev) { struct ioat_enum_ctx *enum_ctx = ctx; struct spdk_ioat_chan *ioat; /* Verify that this device is not already attached */ TAILQ_FOREACH(ioat, &g_ioat_driver.attached_chans, tailq) { /* * NOTE: This assumes that the PCI abstraction layer will use the same device handle * across enumerations; we could compare by BDF instead if this is not true. */ if (pci_dev == ioat->device) { return 0; } } if (enum_ctx->probe_cb(enum_ctx->cb_ctx, pci_dev)) { /* * Since I/OAT init is relatively quick, just perform the full init during probing. * If this turns out to be a bottleneck later, this can be changed to work like * NVMe with a list of devices to initialize in parallel. */ ioat = ioat_attach(pci_dev); if (ioat == NULL) { SPDK_ERRLOG("ioat_attach() failed\n"); return -1; } TAILQ_INSERT_TAIL(&g_ioat_driver.attached_chans, ioat, tailq); enum_ctx->attach_cb(enum_ctx->cb_ctx, pci_dev, ioat); } return 0; } int spdk_ioat_probe(void *cb_ctx, spdk_ioat_probe_cb probe_cb, spdk_ioat_attach_cb attach_cb) { int rc; struct ioat_enum_ctx enum_ctx; pthread_mutex_lock(&g_ioat_driver.lock); enum_ctx.probe_cb = probe_cb; enum_ctx.attach_cb = attach_cb; enum_ctx.cb_ctx = cb_ctx; rc = spdk_pci_ioat_enumerate(ioat_enum_cb, &enum_ctx); pthread_mutex_unlock(&g_ioat_driver.lock); return rc; } int spdk_ioat_detach(struct spdk_ioat_chan *ioat) { struct ioat_driver *driver = &g_ioat_driver; /* ioat should be in the free list (not registered to a thread) * when calling ioat_detach(). */ pthread_mutex_lock(&driver->lock); TAILQ_REMOVE(&driver->attached_chans, ioat, tailq); pthread_mutex_unlock(&driver->lock); ioat_channel_destruct(ioat); free(ioat); return 0; } #define _2MB_PAGE(ptr) ((ptr) & ~(0x200000 - 1)) #define _2MB_OFFSET(ptr) ((ptr) & (0x200000 - 1)) int spdk_ioat_submit_copy(struct spdk_ioat_chan *ioat, void *cb_arg, spdk_ioat_req_cb cb_fn, void *dst, const void *src, uint64_t nbytes) { struct ioat_descriptor *last_desc; uint64_t remaining, op_size; uint64_t vdst, vsrc; uint64_t vdst_page, vsrc_page; uint64_t pdst_page, psrc_page; uint32_t orig_head; if (!ioat) { return -EINVAL; } orig_head = ioat->head; vdst = (uint64_t)dst; vsrc = (uint64_t)src; vdst_page = vsrc_page = 0; pdst_page = psrc_page = SPDK_VTOPHYS_ERROR; remaining = nbytes; while (remaining) { if (_2MB_PAGE(vsrc) != vsrc_page) { vsrc_page = _2MB_PAGE(vsrc); psrc_page = spdk_vtophys((void *)vsrc_page); } if (_2MB_PAGE(vdst) != vdst_page) { vdst_page = _2MB_PAGE(vdst); pdst_page = spdk_vtophys((void *)vdst_page); } op_size = remaining; op_size = spdk_min(op_size, (0x200000 - _2MB_OFFSET(vsrc))); op_size = spdk_min(op_size, (0x200000 - _2MB_OFFSET(vdst))); op_size = spdk_min(op_size, ioat->max_xfer_size); remaining -= op_size; last_desc = ioat_prep_copy(ioat, pdst_page + _2MB_OFFSET(vdst), psrc_page + _2MB_OFFSET(vsrc), op_size); if (remaining == 0 || last_desc == NULL) { break; } vsrc += op_size; vdst += op_size; } /* Issue null descriptor for null transfer */ if (nbytes == 0) { last_desc = ioat_prep_null(ioat); } if (last_desc) { last_desc->callback_fn = cb_fn; last_desc->callback_arg = cb_arg; } else { /* * Ran out of descriptors in the ring - reset head to leave things as they were * in case we managed to fill out any descriptors. */ ioat->head = orig_head; return -ENOMEM; } ioat_flush(ioat); return 0; } int spdk_ioat_submit_fill(struct spdk_ioat_chan *ioat, void *cb_arg, spdk_ioat_req_cb cb_fn, void *dst, uint64_t fill_pattern, uint64_t nbytes) { struct ioat_descriptor *last_desc = NULL; uint64_t remaining, op_size; uint64_t vdst; uint32_t orig_head; if (!ioat) { return -EINVAL; } if (!(ioat->dma_capabilities & SPDK_IOAT_ENGINE_FILL_SUPPORTED)) { SPDK_ERRLOG("Channel does not support memory fill\n"); return -1; } orig_head = ioat->head; vdst = (uint64_t)dst; remaining = nbytes; while (remaining) { op_size = remaining; op_size = spdk_min(op_size, ioat->max_xfer_size); remaining -= op_size; last_desc = ioat_prep_fill(ioat, spdk_vtophys((void *)vdst), fill_pattern, op_size); if (remaining == 0 || last_desc == NULL) { break; } vdst += op_size; } if (last_desc) { last_desc->callback_fn = cb_fn; last_desc->callback_arg = cb_arg; } else { /* * Ran out of descriptors in the ring - reset head to leave things as they were * in case we managed to fill out any descriptors. */ ioat->head = orig_head; return -ENOMEM; } ioat_flush(ioat); return 0; } uint32_t spdk_ioat_get_dma_capabilities(struct spdk_ioat_chan *ioat) { if (!ioat) { return 0; } return ioat->dma_capabilities; } int spdk_ioat_process_events(struct spdk_ioat_chan *ioat) { return ioat_process_channel_events(ioat); } SPDK_LOG_REGISTER_TRACE_FLAG("ioat", SPDK_TRACE_IOAT)