#include <rte_pci.h>
#include <rte_bus_pci.h>
#include <rte_byteorder.h>
+#ifdef RTE_BBDEV_OFFLOAD_COST
+#include <rte_cycles.h>
+#endif
#include <rte_bbdev.h>
#include <rte_bbdev_pmd.h>
#include "fpga_5gnr_fec.h"
+#include "rte_pmd_fpga_5gnr_fec.h"
/* 5GNR SW PMD logging ID */
static int fpga_5gnr_fec_logtype;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+
+/* Read Ring Control Register of FPGA 5GNR FEC device */
+static inline void
+print_ring_reg_debug_info(void *mmio_base, uint32_t offset)
+{
+ rte_bbdev_log_debug(
+ "FPGA MMIO base address @ %p | Ring Control Register @ offset = 0x%08"
+ PRIx32, mmio_base, offset);
+ rte_bbdev_log_debug(
+ "RING_BASE_ADDR = 0x%016"PRIx64,
+ fpga_reg_read_64(mmio_base, offset));
+ rte_bbdev_log_debug(
+ "RING_HEAD_ADDR = 0x%016"PRIx64,
+ fpga_reg_read_64(mmio_base, offset +
+ FPGA_5GNR_FEC_RING_HEAD_ADDR));
+ rte_bbdev_log_debug(
+ "RING_SIZE = 0x%04"PRIx16,
+ fpga_reg_read_16(mmio_base, offset +
+ FPGA_5GNR_FEC_RING_SIZE));
+ rte_bbdev_log_debug(
+ "RING_MISC = 0x%02"PRIx8,
+ fpga_reg_read_8(mmio_base, offset +
+ FPGA_5GNR_FEC_RING_MISC));
+ rte_bbdev_log_debug(
+ "RING_ENABLE = 0x%02"PRIx8,
+ fpga_reg_read_8(mmio_base, offset +
+ FPGA_5GNR_FEC_RING_ENABLE));
+ rte_bbdev_log_debug(
+ "RING_FLUSH_QUEUE_EN = 0x%02"PRIx8,
+ fpga_reg_read_8(mmio_base, offset +
+ FPGA_5GNR_FEC_RING_FLUSH_QUEUE_EN));
+ rte_bbdev_log_debug(
+ "RING_SHADOW_TAIL = 0x%04"PRIx16,
+ fpga_reg_read_16(mmio_base, offset +
+ FPGA_5GNR_FEC_RING_SHADOW_TAIL));
+ rte_bbdev_log_debug(
+ "RING_HEAD_POINT = 0x%04"PRIx16,
+ fpga_reg_read_16(mmio_base, offset +
+ FPGA_5GNR_FEC_RING_HEAD_POINT));
+}
+
+/* Read Static Register of FPGA 5GNR FEC device */
+static inline void
+print_static_reg_debug_info(void *mmio_base)
+{
+ uint16_t config = fpga_reg_read_16(mmio_base,
+ FPGA_5GNR_FEC_CONFIGURATION);
+ uint8_t qmap_done = fpga_reg_read_8(mmio_base,
+ FPGA_5GNR_FEC_QUEUE_PF_VF_MAP_DONE);
+ uint16_t lb_factor = fpga_reg_read_16(mmio_base,
+ FPGA_5GNR_FEC_LOAD_BALANCE_FACTOR);
+ uint16_t ring_desc_len = fpga_reg_read_16(mmio_base,
+ FPGA_5GNR_FEC_RING_DESC_LEN);
+ uint16_t flr_time_out = fpga_reg_read_16(mmio_base,
+ FPGA_5GNR_FEC_FLR_TIME_OUT);
+
+ rte_bbdev_log_debug("UL.DL Weights = %u.%u",
+ ((uint8_t)config), ((uint8_t)(config >> 8)));
+ rte_bbdev_log_debug("UL.DL Load Balance = %u.%u",
+ ((uint8_t)lb_factor), ((uint8_t)(lb_factor >> 8)));
+ rte_bbdev_log_debug("Queue-PF/VF Mapping Table = %s",
+ (qmap_done > 0) ? "READY" : "NOT-READY");
+ rte_bbdev_log_debug("Ring Descriptor Size = %u bytes",
+ ring_desc_len*FPGA_RING_DESC_LEN_UNIT_BYTES);
+ rte_bbdev_log_debug("FLR Timeout = %f usec",
+ (float)flr_time_out*FPGA_FLR_TIMEOUT_UNIT);
+}
+
+/* Print decode DMA Descriptor of FPGA 5GNR Decoder device */
+static void
+print_dma_dec_desc_debug_info(union fpga_dma_desc *desc)
+{
+ rte_bbdev_log_debug("DMA response desc %p\n"
+ "\t-- done(%"PRIu32") | iter(%"PRIu32") | et_pass(%"PRIu32")"
+ " | crcb_pass (%"PRIu32") | error(%"PRIu32")\n"
+ "\t-- qm_idx(%"PRIu32") | max_iter(%"PRIu32") | "
+ "bg_idx (%"PRIu32") | harqin_en(%"PRIu32") | zc(%"PRIu32")\n"
+ "\t-- hbstroe_offset(%"PRIu32") | num_null (%"PRIu32") "
+ "| irq_en(%"PRIu32")\n"
+ "\t-- ncb(%"PRIu32") | desc_idx (%"PRIu32") | "
+ "drop_crc24b(%"PRIu32") | RV (%"PRIu32")\n"
+ "\t-- crc24b_ind(%"PRIu32") | et_dis (%"PRIu32")\n"
+ "\t-- harq_input_length(%"PRIu32") | rm_e(%"PRIu32")\n"
+ "\t-- cbs_in_op(%"PRIu32") | in_add (0x%08"PRIx32"%08"PRIx32")"
+ "| out_add (0x%08"PRIx32"%08"PRIx32")",
+ desc,
+ (uint32_t)desc->dec_req.done,
+ (uint32_t)desc->dec_req.iter,
+ (uint32_t)desc->dec_req.et_pass,
+ (uint32_t)desc->dec_req.crcb_pass,
+ (uint32_t)desc->dec_req.error,
+ (uint32_t)desc->dec_req.qm_idx,
+ (uint32_t)desc->dec_req.max_iter,
+ (uint32_t)desc->dec_req.bg_idx,
+ (uint32_t)desc->dec_req.harqin_en,
+ (uint32_t)desc->dec_req.zc,
+ (uint32_t)desc->dec_req.hbstroe_offset,
+ (uint32_t)desc->dec_req.num_null,
+ (uint32_t)desc->dec_req.irq_en,
+ (uint32_t)desc->dec_req.ncb,
+ (uint32_t)desc->dec_req.desc_idx,
+ (uint32_t)desc->dec_req.drop_crc24b,
+ (uint32_t)desc->dec_req.rv,
+ (uint32_t)desc->dec_req.crc24b_ind,
+ (uint32_t)desc->dec_req.et_dis,
+ (uint32_t)desc->dec_req.harq_input_length,
+ (uint32_t)desc->dec_req.rm_e,
+ (uint32_t)desc->dec_req.cbs_in_op,
+ (uint32_t)desc->dec_req.in_addr_hi,
+ (uint32_t)desc->dec_req.in_addr_lw,
+ (uint32_t)desc->dec_req.out_addr_hi,
+ (uint32_t)desc->dec_req.out_addr_lw);
+ uint32_t *word = (uint32_t *) desc;
+ rte_bbdev_log_debug("%08"PRIx32"\n%08"PRIx32"\n%08"PRIx32"\n%08"PRIx32"\n"
+ "%08"PRIx32"\n%08"PRIx32"\n%08"PRIx32"\n%08"PRIx32"\n",
+ word[0], word[1], word[2], word[3],
+ word[4], word[5], word[6], word[7]);
+}
+
+/* Print decode DMA Descriptor of FPGA 5GNR encoder device */
+static void
+print_dma_enc_desc_debug_info(union fpga_dma_desc *desc)
+{
+ rte_bbdev_log_debug("DMA response desc %p\n"
+ "%"PRIu32" %"PRIu32"\n"
+ "K' %"PRIu32" E %"PRIu32" desc %"PRIu32" Z %"PRIu32"\n"
+ "BG %"PRIu32" Qm %"PRIu32" CRC %"PRIu32" IRQ %"PRIu32"\n"
+ "k0 %"PRIu32" Ncb %"PRIu32" F %"PRIu32"\n",
+ desc,
+ (uint32_t)desc->enc_req.done,
+ (uint32_t)desc->enc_req.error,
+
+ (uint32_t)desc->enc_req.k_,
+ (uint32_t)desc->enc_req.rm_e,
+ (uint32_t)desc->enc_req.desc_idx,
+ (uint32_t)desc->enc_req.zc,
+
+ (uint32_t)desc->enc_req.bg_idx,
+ (uint32_t)desc->enc_req.qm_idx,
+ (uint32_t)desc->enc_req.crc_en,
+ (uint32_t)desc->enc_req.irq_en,
+
+ (uint32_t)desc->enc_req.k0,
+ (uint32_t)desc->enc_req.ncb,
+ (uint32_t)desc->enc_req.num_null);
+ uint32_t *word = (uint32_t *) desc;
+ rte_bbdev_log_debug("%08"PRIx32"\n%08"PRIx32"\n%08"PRIx32"\n%08"PRIx32"\n"
+ "%08"PRIx32"\n%08"PRIx32"\n%08"PRIx32"\n%08"PRIx32"\n",
+ word[0], word[1], word[2], word[3],
+ word[4], word[5], word[6], word[7]);
+}
+
+#endif
+
static int
-fpga_dev_close(struct rte_bbdev *dev __rte_unused)
+fpga_setup_queues(struct rte_bbdev *dev, uint16_t num_queues, int socket_id)
{
+ /* Number of queues bound to a PF/VF */
+ uint32_t hw_q_num = 0;
+ uint32_t ring_size, payload, address, q_id, offset;
+ rte_iova_t phys_addr;
+ struct fpga_ring_ctrl_reg ring_reg;
+ struct fpga_5gnr_fec_device *fpga_dev = dev->data->dev_private;
+
+ address = FPGA_5GNR_FEC_QUEUE_PF_VF_MAP_DONE;
+ if (!(fpga_reg_read_32(fpga_dev->mmio_base, address) & 0x1)) {
+ rte_bbdev_log(ERR,
+ "Queue-PF/VF mapping is not set! Was PF configured for device (%s) ?",
+ dev->data->name);
+ return -EPERM;
+ }
+
+ /* Clear queue registers structure */
+ memset(&ring_reg, 0, sizeof(struct fpga_ring_ctrl_reg));
+
+ /* Scan queue map.
+ * If a queue is valid and mapped to a calling PF/VF the read value is
+ * replaced with a queue ID and if it's not then
+ * FPGA_INVALID_HW_QUEUE_ID is returned.
+ */
+ for (q_id = 0; q_id < FPGA_TOTAL_NUM_QUEUES; ++q_id) {
+ uint32_t hw_q_id = fpga_reg_read_32(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_QUEUE_MAP + (q_id << 2));
+
+ rte_bbdev_log_debug("%s: queue ID: %u, registry queue ID: %u",
+ dev->device->name, q_id, hw_q_id);
+
+ if (hw_q_id != FPGA_INVALID_HW_QUEUE_ID) {
+ fpga_dev->q_bound_bit_map |= (1ULL << q_id);
+ /* Clear queue register of found queue */
+ offset = FPGA_5GNR_FEC_RING_CTRL_REGS +
+ (sizeof(struct fpga_ring_ctrl_reg) * q_id);
+ fpga_ring_reg_write(fpga_dev->mmio_base,
+ offset, ring_reg);
+ ++hw_q_num;
+ }
+ }
+ if (hw_q_num == 0) {
+ rte_bbdev_log(ERR,
+ "No HW queues assigned to this device. Probably this is a VF configured for PF mode. Check device configuration!");
+ return -ENODEV;
+ }
+
+ if (num_queues > hw_q_num) {
+ rte_bbdev_log(ERR,
+ "Not enough queues for device %s! Requested: %u, available: %u",
+ dev->device->name, num_queues, hw_q_num);
+ return -EINVAL;
+ }
+
+ ring_size = FPGA_RING_MAX_SIZE * sizeof(struct fpga_dma_dec_desc);
+
+ /* Enforce 32 byte alignment */
+ RTE_BUILD_BUG_ON((RTE_CACHE_LINE_SIZE % 32) != 0);
+
+ /* Allocate memory for SW descriptor rings */
+ fpga_dev->sw_rings = rte_zmalloc_socket(dev->device->driver->name,
+ num_queues * ring_size, RTE_CACHE_LINE_SIZE,
+ socket_id);
+ if (fpga_dev->sw_rings == NULL) {
+ rte_bbdev_log(ERR,
+ "Failed to allocate memory for %s:%u sw_rings",
+ dev->device->driver->name, dev->data->dev_id);
+ return -ENOMEM;
+ }
+
+ fpga_dev->sw_rings_phys = rte_malloc_virt2iova(fpga_dev->sw_rings);
+ fpga_dev->sw_ring_size = ring_size;
+ fpga_dev->sw_ring_max_depth = FPGA_RING_MAX_SIZE;
+
+ /* Allocate memory for ring flush status */
+ fpga_dev->flush_queue_status = rte_zmalloc_socket(NULL,
+ sizeof(uint64_t), RTE_CACHE_LINE_SIZE, socket_id);
+ if (fpga_dev->flush_queue_status == NULL) {
+ rte_bbdev_log(ERR,
+ "Failed to allocate memory for %s:%u flush_queue_status",
+ dev->device->driver->name, dev->data->dev_id);
+ return -ENOMEM;
+ }
+
+ /* Set the flush status address registers */
+ phys_addr = rte_malloc_virt2iova(fpga_dev->flush_queue_status);
+
+ address = FPGA_5GNR_FEC_VFQ_FLUSH_STATUS_LW;
+ payload = (uint32_t)(phys_addr);
+ fpga_reg_write_32(fpga_dev->mmio_base, address, payload);
+
+ address = FPGA_5GNR_FEC_VFQ_FLUSH_STATUS_HI;
+ payload = (uint32_t)(phys_addr >> 32);
+ fpga_reg_write_32(fpga_dev->mmio_base, address, payload);
+
+ return 0;
+}
+
+static int
+fpga_dev_close(struct rte_bbdev *dev)
+{
+ struct fpga_5gnr_fec_device *fpga_dev = dev->data->dev_private;
+
+ rte_free(fpga_dev->sw_rings);
+ rte_free(fpga_dev->flush_queue_status);
+
return 0;
}
uint32_t q_id = 0;
static const struct rte_bbdev_op_cap bbdev_capabilities[] = {
+ {
+ .type = RTE_BBDEV_OP_LDPC_ENC,
+ .cap.ldpc_enc = {
+ .capability_flags =
+ RTE_BBDEV_LDPC_RATE_MATCH |
+ RTE_BBDEV_LDPC_ENC_INTERRUPTS |
+ RTE_BBDEV_LDPC_CRC_24B_ATTACH,
+ .num_buffers_src =
+ RTE_BBDEV_LDPC_MAX_CODE_BLOCKS,
+ .num_buffers_dst =
+ RTE_BBDEV_LDPC_MAX_CODE_BLOCKS,
+ }
+ },
+ {
+ .type = RTE_BBDEV_OP_LDPC_DEC,
+ .cap.ldpc_dec = {
+ .capability_flags =
+ RTE_BBDEV_LDPC_CRC_TYPE_24B_CHECK |
+ RTE_BBDEV_LDPC_CRC_TYPE_24B_DROP |
+ RTE_BBDEV_LDPC_HQ_COMBINE_IN_ENABLE |
+ RTE_BBDEV_LDPC_HQ_COMBINE_OUT_ENABLE |
+ RTE_BBDEV_LDPC_ITERATION_STOP_ENABLE |
+ RTE_BBDEV_LDPC_INTERNAL_HARQ_MEMORY_IN_ENABLE |
+ RTE_BBDEV_LDPC_INTERNAL_HARQ_MEMORY_OUT_ENABLE |
+ RTE_BBDEV_LDPC_INTERNAL_HARQ_MEMORY_LOOPBACK |
+ RTE_BBDEV_LDPC_DEC_INTERRUPTS |
+ RTE_BBDEV_LDPC_INTERNAL_HARQ_MEMORY_FILLERS,
+ .llr_size = 6,
+ .llr_decimals = 2,
+ .num_buffers_src =
+ RTE_BBDEV_LDPC_MAX_CODE_BLOCKS,
+ .num_buffers_hard_out =
+ RTE_BBDEV_LDPC_MAX_CODE_BLOCKS,
+ .num_buffers_soft_out = 0,
+ }
+ },
RTE_BBDEV_END_OF_CAPABILITIES_LIST()
};
}
}
+/**
+ * Find index of queue bound to current PF/VF which is unassigned. Return -1
+ * when there is no available queue
+ */
+static inline int
+fpga_find_free_queue_idx(struct rte_bbdev *dev,
+ const struct rte_bbdev_queue_conf *conf)
+{
+ struct fpga_5gnr_fec_device *d = dev->data->dev_private;
+ uint64_t q_idx;
+ uint8_t i = 0;
+ uint8_t range = FPGA_TOTAL_NUM_QUEUES >> 1;
+
+ if (conf->op_type == RTE_BBDEV_OP_LDPC_ENC) {
+ i = FPGA_NUM_DL_QUEUES;
+ range = FPGA_TOTAL_NUM_QUEUES;
+ }
+
+ for (; i < range; ++i) {
+ q_idx = 1ULL << i;
+ /* Check if index of queue is bound to current PF/VF */
+ if (d->q_bound_bit_map & q_idx)
+ /* Check if found queue was not already assigned */
+ if (!(d->q_assigned_bit_map & q_idx)) {
+ d->q_assigned_bit_map |= q_idx;
+ return i;
+ }
+ }
+
+ rte_bbdev_log(INFO, "Failed to find free queue on %s", dev->data->name);
+
+ return -1;
+}
+
+static int
+fpga_queue_setup(struct rte_bbdev *dev, uint16_t queue_id,
+ const struct rte_bbdev_queue_conf *conf)
+{
+ uint32_t address, ring_offset;
+ struct fpga_5gnr_fec_device *d = dev->data->dev_private;
+ struct fpga_queue *q;
+ int8_t q_idx;
+
+ /* Check if there is a free queue to assign */
+ q_idx = fpga_find_free_queue_idx(dev, conf);
+ if (q_idx == -1)
+ return -1;
+
+ /* Allocate the queue data structure. */
+ q = rte_zmalloc_socket(dev->device->driver->name, sizeof(*q),
+ RTE_CACHE_LINE_SIZE, conf->socket);
+ if (q == NULL) {
+ /* Mark queue as un-assigned */
+ d->q_assigned_bit_map &= (0xFFFFFFFF - (1ULL << q_idx));
+ rte_bbdev_log(ERR, "Failed to allocate queue memory");
+ return -ENOMEM;
+ }
+
+ q->d = d;
+ q->q_idx = q_idx;
+
+ /* Set ring_base_addr */
+ q->ring_addr = RTE_PTR_ADD(d->sw_rings, (d->sw_ring_size * queue_id));
+ q->ring_ctrl_reg.ring_base_addr = d->sw_rings_phys +
+ (d->sw_ring_size * queue_id);
+
+ /* Allocate memory for Completion Head variable*/
+ q->ring_head_addr = rte_zmalloc_socket(dev->device->driver->name,
+ sizeof(uint64_t), RTE_CACHE_LINE_SIZE, conf->socket);
+ if (q->ring_head_addr == NULL) {
+ /* Mark queue as un-assigned */
+ d->q_assigned_bit_map &= (0xFFFFFFFF - (1ULL << q_idx));
+ rte_free(q);
+ rte_bbdev_log(ERR,
+ "Failed to allocate memory for %s:%u completion_head",
+ dev->device->driver->name, dev->data->dev_id);
+ return -ENOMEM;
+ }
+ /* Set ring_head_addr */
+ q->ring_ctrl_reg.ring_head_addr =
+ rte_malloc_virt2iova(q->ring_head_addr);
+
+ /* Clear shadow_completion_head */
+ q->shadow_completion_head = 0;
+
+ /* Set ring_size */
+ if (conf->queue_size > FPGA_RING_MAX_SIZE) {
+ /* Mark queue as un-assigned */
+ d->q_assigned_bit_map &= (0xFFFFFFFF - (1ULL << q_idx));
+ rte_free(q->ring_head_addr);
+ rte_free(q);
+ rte_bbdev_log(ERR,
+ "Size of queue is too big %d (MAX: %d ) for %s:%u",
+ conf->queue_size, FPGA_RING_MAX_SIZE,
+ dev->device->driver->name, dev->data->dev_id);
+ return -EINVAL;
+ }
+ q->ring_ctrl_reg.ring_size = conf->queue_size;
+
+ /* Set Miscellaneous FPGA register*/
+ /* Max iteration number for TTI mitigation - todo */
+ q->ring_ctrl_reg.max_ul_dec = 0;
+ /* Enable max iteration number for TTI - todo */
+ q->ring_ctrl_reg.max_ul_dec_en = 0;
+
+ /* Enable the ring */
+ q->ring_ctrl_reg.enable = 1;
+
+ /* Set FPGA head_point and tail registers */
+ q->ring_ctrl_reg.head_point = q->tail = 0;
+
+ /* Set FPGA shadow_tail register */
+ q->ring_ctrl_reg.shadow_tail = q->tail;
+
+ /* Calculates the ring offset for found queue */
+ ring_offset = FPGA_5GNR_FEC_RING_CTRL_REGS +
+ (sizeof(struct fpga_ring_ctrl_reg) * q_idx);
+
+ /* Set FPGA Ring Control Registers */
+ fpga_ring_reg_write(d->mmio_base, ring_offset, q->ring_ctrl_reg);
+
+ /* Store MMIO register of shadow_tail */
+ address = ring_offset + FPGA_5GNR_FEC_RING_SHADOW_TAIL;
+ q->shadow_tail_addr = RTE_PTR_ADD(d->mmio_base, address);
+
+ q->head_free_desc = q->tail;
+
+ /* Set wrap mask */
+ q->sw_ring_wrap_mask = conf->queue_size - 1;
+
+ rte_bbdev_log_debug("Setup dev%u q%u: queue_idx=%u",
+ dev->data->dev_id, queue_id, q->q_idx);
+
+ dev->data->queues[queue_id].queue_private = q;
+
+ rte_bbdev_log_debug("BBDEV queue[%d] set up for FPGA queue[%d]",
+ queue_id, q_idx);
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Read FPGA Ring Control Registers after configuration*/
+ print_ring_reg_debug_info(d->mmio_base, ring_offset);
+#endif
+ return 0;
+}
+
+static int
+fpga_queue_release(struct rte_bbdev *dev, uint16_t queue_id)
+{
+ struct fpga_5gnr_fec_device *d = dev->data->dev_private;
+ struct fpga_queue *q = dev->data->queues[queue_id].queue_private;
+ struct fpga_ring_ctrl_reg ring_reg;
+ uint32_t offset;
+
+ rte_bbdev_log_debug("FPGA Queue[%d] released", queue_id);
+
+ if (q != NULL) {
+ memset(&ring_reg, 0, sizeof(struct fpga_ring_ctrl_reg));
+ offset = FPGA_5GNR_FEC_RING_CTRL_REGS +
+ (sizeof(struct fpga_ring_ctrl_reg) * q->q_idx);
+ /* Disable queue */
+ fpga_reg_write_8(d->mmio_base,
+ offset + FPGA_5GNR_FEC_RING_ENABLE, 0x00);
+ /* Clear queue registers */
+ fpga_ring_reg_write(d->mmio_base, offset, ring_reg);
+
+ /* Mark the Queue as un-assigned */
+ d->q_assigned_bit_map &= (0xFFFFFFFF - (1ULL << q->q_idx));
+ rte_free(q->ring_head_addr);
+ rte_free(q);
+ dev->data->queues[queue_id].queue_private = NULL;
+ }
+
+ return 0;
+}
+
+/* Function starts a device queue. */
+static int
+fpga_queue_start(struct rte_bbdev *dev, uint16_t queue_id)
+{
+ struct fpga_5gnr_fec_device *d = dev->data->dev_private;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ if (d == NULL) {
+ rte_bbdev_log(ERR, "Invalid device pointer");
+ return -1;
+ }
+#endif
+ struct fpga_queue *q = dev->data->queues[queue_id].queue_private;
+ uint32_t offset = FPGA_5GNR_FEC_RING_CTRL_REGS +
+ (sizeof(struct fpga_ring_ctrl_reg) * q->q_idx);
+ uint8_t enable = 0x01;
+ uint16_t zero = 0x0000;
+
+ /* Clear queue head and tail variables */
+ q->tail = q->head_free_desc = 0;
+
+ /* Clear FPGA head_point and tail registers */
+ fpga_reg_write_16(d->mmio_base, offset + FPGA_5GNR_FEC_RING_HEAD_POINT,
+ zero);
+ fpga_reg_write_16(d->mmio_base, offset + FPGA_5GNR_FEC_RING_SHADOW_TAIL,
+ zero);
+
+ /* Enable queue */
+ fpga_reg_write_8(d->mmio_base, offset + FPGA_5GNR_FEC_RING_ENABLE,
+ enable);
+
+ rte_bbdev_log_debug("FPGA Queue[%d] started", queue_id);
+ return 0;
+}
+
+/* Function stops a device queue. */
+static int
+fpga_queue_stop(struct rte_bbdev *dev, uint16_t queue_id)
+{
+ struct fpga_5gnr_fec_device *d = dev->data->dev_private;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ if (d == NULL) {
+ rte_bbdev_log(ERR, "Invalid device pointer");
+ return -1;
+ }
+#endif
+ struct fpga_queue *q = dev->data->queues[queue_id].queue_private;
+ uint32_t offset = FPGA_5GNR_FEC_RING_CTRL_REGS +
+ (sizeof(struct fpga_ring_ctrl_reg) * q->q_idx);
+ uint8_t payload = 0x01;
+ uint8_t counter = 0;
+ uint8_t timeout = FPGA_QUEUE_FLUSH_TIMEOUT_US /
+ FPGA_TIMEOUT_CHECK_INTERVAL;
+
+ /* Set flush_queue_en bit to trigger queue flushing */
+ fpga_reg_write_8(d->mmio_base,
+ offset + FPGA_5GNR_FEC_RING_FLUSH_QUEUE_EN, payload);
+
+ /** Check if queue flush is completed.
+ * FPGA will update the completion flag after queue flushing is
+ * completed. If completion flag is not updated within 1ms it is
+ * considered as a failure.
+ */
+ while (!(*((volatile uint8_t *)d->flush_queue_status + q->q_idx)
+ & payload)) {
+ if (counter > timeout) {
+ rte_bbdev_log(ERR, "FPGA Queue Flush failed for queue %d",
+ queue_id);
+ return -1;
+ }
+ usleep(FPGA_TIMEOUT_CHECK_INTERVAL);
+ counter++;
+ }
+
+ /* Disable queue */
+ payload = 0x00;
+ fpga_reg_write_8(d->mmio_base, offset + FPGA_5GNR_FEC_RING_ENABLE,
+ payload);
+
+ rte_bbdev_log_debug("FPGA Queue[%d] stopped", queue_id);
+ return 0;
+}
+
+static inline uint16_t
+get_queue_id(struct rte_bbdev_data *data, uint8_t q_idx)
+{
+ uint16_t queue_id;
+
+ for (queue_id = 0; queue_id < data->num_queues; ++queue_id) {
+ struct fpga_queue *q = data->queues[queue_id].queue_private;
+ if (q != NULL && q->q_idx == q_idx)
+ return queue_id;
+ }
+
+ return -1;
+}
+
+/* Interrupt handler triggered by FPGA dev for handling specific interrupt */
+static void
+fpga_dev_interrupt_handler(void *cb_arg)
+{
+ struct rte_bbdev *dev = cb_arg;
+ struct fpga_5gnr_fec_device *fpga_dev = dev->data->dev_private;
+ struct fpga_queue *q;
+ uint64_t ring_head;
+ uint64_t q_idx;
+ uint16_t queue_id;
+ uint8_t i;
+
+ /* Scan queue assigned to this device */
+ for (i = 0; i < FPGA_TOTAL_NUM_QUEUES; ++i) {
+ q_idx = 1ULL << i;
+ if (fpga_dev->q_bound_bit_map & q_idx) {
+ queue_id = get_queue_id(dev->data, i);
+ if (queue_id == (uint16_t) -1)
+ continue;
+
+ /* Check if completion head was changed */
+ q = dev->data->queues[queue_id].queue_private;
+ ring_head = *q->ring_head_addr;
+ if (q->shadow_completion_head != ring_head &&
+ q->irq_enable == 1) {
+ q->shadow_completion_head = ring_head;
+ rte_bbdev_pmd_callback_process(
+ dev,
+ RTE_BBDEV_EVENT_DEQUEUE,
+ &queue_id);
+ }
+ }
+ }
+}
+
+static int
+fpga_queue_intr_enable(struct rte_bbdev *dev, uint16_t queue_id)
+{
+ struct fpga_queue *q = dev->data->queues[queue_id].queue_private;
+
+ if (!rte_intr_cap_multiple(dev->intr_handle))
+ return -ENOTSUP;
+
+ q->irq_enable = 1;
+
+ return 0;
+}
+
+static int
+fpga_queue_intr_disable(struct rte_bbdev *dev, uint16_t queue_id)
+{
+ struct fpga_queue *q = dev->data->queues[queue_id].queue_private;
+ q->irq_enable = 0;
+
+ return 0;
+}
+
+static int
+fpga_intr_enable(struct rte_bbdev *dev)
+{
+ int ret;
+ uint8_t i;
+
+ if (!rte_intr_cap_multiple(dev->intr_handle)) {
+ rte_bbdev_log(ERR, "Multiple intr vector is not supported by FPGA (%s)",
+ dev->data->name);
+ return -ENOTSUP;
+ }
+
+ /* Create event file descriptors for each of 64 queue. Event fds will be
+ * mapped to FPGA IRQs in rte_intr_enable(). This is a 1:1 mapping where
+ * the IRQ number is a direct translation to the queue number.
+ *
+ * 63 (FPGA_NUM_INTR_VEC) event fds are created as rte_intr_enable()
+ * mapped the first IRQ to already created interrupt event file
+ * descriptor (intr_handle->fd).
+ */
+ if (rte_intr_efd_enable(dev->intr_handle, FPGA_NUM_INTR_VEC)) {
+ rte_bbdev_log(ERR, "Failed to create fds for %u queues",
+ dev->data->num_queues);
+ return -1;
+ }
+
+ /* TODO Each event file descriptor is overwritten by interrupt event
+ * file descriptor. That descriptor is added to epoll observed list.
+ * It ensures that callback function assigned to that descriptor will
+ * invoked when any FPGA queue issues interrupt.
+ */
+ for (i = 0; i < FPGA_NUM_INTR_VEC; ++i)
+ dev->intr_handle->efds[i] = dev->intr_handle->fd;
+
+ if (!dev->intr_handle->intr_vec) {
+ dev->intr_handle->intr_vec = rte_zmalloc("intr_vec",
+ dev->data->num_queues * sizeof(int), 0);
+ if (!dev->intr_handle->intr_vec) {
+ rte_bbdev_log(ERR, "Failed to allocate %u vectors",
+ dev->data->num_queues);
+ return -ENOMEM;
+ }
+ }
+
+ ret = rte_intr_enable(dev->intr_handle);
+ if (ret < 0) {
+ rte_bbdev_log(ERR,
+ "Couldn't enable interrupts for device: %s",
+ dev->data->name);
+ return ret;
+ }
+
+ ret = rte_intr_callback_register(dev->intr_handle,
+ fpga_dev_interrupt_handler, dev);
+ if (ret < 0) {
+ rte_bbdev_log(ERR,
+ "Couldn't register interrupt callback for device: %s",
+ dev->data->name);
+ return ret;
+ }
+
+ return 0;
+}
+
static const struct rte_bbdev_ops fpga_ops = {
+ .setup_queues = fpga_setup_queues,
+ .intr_enable = fpga_intr_enable,
.close = fpga_dev_close,
.info_get = fpga_dev_info_get,
+ .queue_setup = fpga_queue_setup,
+ .queue_stop = fpga_queue_stop,
+ .queue_start = fpga_queue_start,
+ .queue_release = fpga_queue_release,
+ .queue_intr_enable = fpga_queue_intr_enable,
+ .queue_intr_disable = fpga_queue_intr_disable
};
+static inline void
+fpga_dma_enqueue(struct fpga_queue *q, uint16_t num_desc,
+ struct rte_bbdev_stats *queue_stats)
+{
+#ifdef RTE_BBDEV_OFFLOAD_COST
+ uint64_t start_time = 0;
+ queue_stats->acc_offload_cycles = 0;
+#else
+ RTE_SET_USED(queue_stats);
+#endif
+
+ /* Update tail and shadow_tail register */
+ q->tail = (q->tail + num_desc) & q->sw_ring_wrap_mask;
+
+ rte_wmb();
+
+#ifdef RTE_BBDEV_OFFLOAD_COST
+ /* Start time measurement for enqueue function offload. */
+ start_time = rte_rdtsc_precise();
+#endif
+ mmio_write_16(q->shadow_tail_addr, q->tail);
+
+#ifdef RTE_BBDEV_OFFLOAD_COST
+ rte_wmb();
+ queue_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
+#endif
+}
+
+/* Read flag value 0/1/ from bitmap */
+static inline bool
+check_bit(uint32_t bitmap, uint32_t bitmask)
+{
+ return bitmap & bitmask;
+}
+
+/* Print an error if a descriptor error has occurred.
+ * Return 0 on success, 1 on failure
+ */
+static inline int
+check_desc_error(uint32_t error_code) {
+ switch (error_code) {
+ case DESC_ERR_NO_ERR:
+ return 0;
+ case DESC_ERR_K_P_OUT_OF_RANGE:
+ rte_bbdev_log(ERR, "Encode block size K' is out of range");
+ break;
+ case DESC_ERR_Z_C_NOT_LEGAL:
+ rte_bbdev_log(ERR, "Zc is illegal");
+ break;
+ case DESC_ERR_DESC_OFFSET_ERR:
+ rte_bbdev_log(ERR,
+ "Queue offset does not meet the expectation in the FPGA"
+ );
+ break;
+ case DESC_ERR_DESC_READ_FAIL:
+ rte_bbdev_log(ERR, "Unsuccessful completion for descriptor read");
+ break;
+ case DESC_ERR_DESC_READ_TIMEOUT:
+ rte_bbdev_log(ERR, "Descriptor read time-out");
+ break;
+ case DESC_ERR_DESC_READ_TLP_POISONED:
+ rte_bbdev_log(ERR, "Descriptor read TLP poisoned");
+ break;
+ case DESC_ERR_CB_READ_FAIL:
+ rte_bbdev_log(ERR, "Unsuccessful completion for code block");
+ break;
+ case DESC_ERR_CB_READ_TIMEOUT:
+ rte_bbdev_log(ERR, "Code block read time-out");
+ break;
+ case DESC_ERR_CB_READ_TLP_POISONED:
+ rte_bbdev_log(ERR, "Code block read TLP poisoned");
+ break;
+ case DESC_ERR_HBSTORE_ERR:
+ rte_bbdev_log(ERR, "Hbstroe exceeds HARQ buffer size.");
+ break;
+ default:
+ rte_bbdev_log(ERR, "Descriptor error unknown error code %u",
+ error_code);
+ break;
+ }
+ return 1;
+}
+
+/* Compute value of k0.
+ * Based on 3GPP 38.212 Table 5.4.2.1-2
+ * Starting position of different redundancy versions, k0
+ */
+static inline uint16_t
+get_k0(uint16_t n_cb, uint16_t z_c, uint8_t bg, uint8_t rv_index)
+{
+ if (rv_index == 0)
+ return 0;
+ uint16_t n = (bg == 1 ? N_ZC_1 : N_ZC_2) * z_c;
+ if (n_cb == n) {
+ if (rv_index == 1)
+ return (bg == 1 ? K0_1_1 : K0_1_2) * z_c;
+ else if (rv_index == 2)
+ return (bg == 1 ? K0_2_1 : K0_2_2) * z_c;
+ else
+ return (bg == 1 ? K0_3_1 : K0_3_2) * z_c;
+ }
+ /* LBRM case - includes a division by N */
+ if (rv_index == 1)
+ return (((bg == 1 ? K0_1_1 : K0_1_2) * n_cb)
+ / n) * z_c;
+ else if (rv_index == 2)
+ return (((bg == 1 ? K0_2_1 : K0_2_2) * n_cb)
+ / n) * z_c;
+ else
+ return (((bg == 1 ? K0_3_1 : K0_3_2) * n_cb)
+ / n) * z_c;
+}
+
+/**
+ * Set DMA descriptor for encode operation (1 Code Block)
+ *
+ * @param op
+ * Pointer to a single encode operation.
+ * @param desc
+ * Pointer to DMA descriptor.
+ * @param input
+ * Pointer to pointer to input data which will be decoded.
+ * @param e
+ * E value (length of output in bits).
+ * @param ncb
+ * Ncb value (size of the soft buffer).
+ * @param out_length
+ * Length of output buffer
+ * @param in_offset
+ * Input offset in rte_mbuf structure. It is used for calculating the point
+ * where data is starting.
+ * @param out_offset
+ * Output offset in rte_mbuf structure. It is used for calculating the point
+ * where hard output data will be stored.
+ * @param cbs_in_op
+ * Number of CBs contained in one operation.
+ */
+static inline int
+fpga_dma_desc_te_fill(struct rte_bbdev_enc_op *op,
+ struct fpga_dma_enc_desc *desc, struct rte_mbuf *input,
+ struct rte_mbuf *output, uint16_t k_, uint16_t e,
+ uint32_t in_offset, uint32_t out_offset, uint16_t desc_offset,
+ uint8_t cbs_in_op)
+{
+ /* reset */
+ desc->done = 0;
+ desc->error = 0;
+ desc->k_ = k_;
+ desc->rm_e = e;
+ desc->desc_idx = desc_offset;
+ desc->zc = op->ldpc_enc.z_c;
+ desc->bg_idx = op->ldpc_enc.basegraph - 1;
+ desc->qm_idx = op->ldpc_enc.q_m / 2;
+ desc->crc_en = check_bit(op->ldpc_enc.op_flags,
+ RTE_BBDEV_LDPC_CRC_24B_ATTACH);
+ desc->irq_en = 0;
+ desc->k0 = get_k0(op->ldpc_enc.n_cb, op->ldpc_enc.z_c,
+ op->ldpc_enc.basegraph, op->ldpc_enc.rv_index);
+ desc->ncb = op->ldpc_enc.n_cb;
+ desc->num_null = op->ldpc_enc.n_filler;
+ /* Set inbound data buffer address */
+ desc->in_addr_hi = (uint32_t)(
+ rte_pktmbuf_mtophys_offset(input, in_offset) >> 32);
+ desc->in_addr_lw = (uint32_t)(
+ rte_pktmbuf_mtophys_offset(input, in_offset));
+
+ desc->out_addr_hi = (uint32_t)(
+ rte_pktmbuf_mtophys_offset(output, out_offset) >> 32);
+ desc->out_addr_lw = (uint32_t)(
+ rte_pktmbuf_mtophys_offset(output, out_offset));
+ /* Save software context needed for dequeue */
+ desc->op_addr = op;
+ /* Set total number of CBs in an op */
+ desc->cbs_in_op = cbs_in_op;
+ return 0;
+}
+
+/**
+ * Set DMA descriptor for decode operation (1 Code Block)
+ *
+ * @param op
+ * Pointer to a single encode operation.
+ * @param desc
+ * Pointer to DMA descriptor.
+ * @param input
+ * Pointer to pointer to input data which will be decoded.
+ * @param in_offset
+ * Input offset in rte_mbuf structure. It is used for calculating the point
+ * where data is starting.
+ * @param out_offset
+ * Output offset in rte_mbuf structure. It is used for calculating the point
+ * where hard output data will be stored.
+ * @param cbs_in_op
+ * Number of CBs contained in one operation.
+ */
+static inline int
+fpga_dma_desc_ld_fill(struct rte_bbdev_dec_op *op,
+ struct fpga_dma_dec_desc *desc,
+ struct rte_mbuf *input, struct rte_mbuf *output,
+ uint16_t harq_in_length,
+ uint32_t in_offset, uint32_t out_offset,
+ uint32_t harq_offset,
+ uint16_t desc_offset,
+ uint8_t cbs_in_op)
+{
+ /* reset */
+ desc->done = 0;
+ desc->error = 0;
+ /* Set inbound data buffer address */
+ desc->in_addr_hi = (uint32_t)(
+ rte_pktmbuf_mtophys_offset(input, in_offset) >> 32);
+ desc->in_addr_lw = (uint32_t)(
+ rte_pktmbuf_mtophys_offset(input, in_offset));
+ desc->rm_e = op->ldpc_dec.cb_params.e;
+ desc->harq_input_length = harq_in_length;
+ desc->et_dis = !check_bit(op->ldpc_dec.op_flags,
+ RTE_BBDEV_LDPC_ITERATION_STOP_ENABLE);
+ desc->rv = op->ldpc_dec.rv_index;
+ desc->crc24b_ind = check_bit(op->ldpc_dec.op_flags,
+ RTE_BBDEV_LDPC_CRC_TYPE_24B_CHECK);
+ desc->drop_crc24b = check_bit(op->ldpc_dec.op_flags,
+ RTE_BBDEV_LDPC_CRC_TYPE_24B_DROP);
+ desc->desc_idx = desc_offset;
+ desc->ncb = op->ldpc_dec.n_cb;
+ desc->num_null = op->ldpc_dec.n_filler;
+ desc->hbstroe_offset = harq_offset >> 10;
+ desc->zc = op->ldpc_dec.z_c;
+ desc->harqin_en = check_bit(op->ldpc_dec.op_flags,
+ RTE_BBDEV_LDPC_HQ_COMBINE_IN_ENABLE);
+ desc->bg_idx = op->ldpc_dec.basegraph - 1;
+ desc->max_iter = op->ldpc_dec.iter_max;
+ desc->qm_idx = op->ldpc_dec.q_m / 2;
+ desc->out_addr_hi = (uint32_t)(
+ rte_pktmbuf_mtophys_offset(output, out_offset) >> 32);
+ desc->out_addr_lw = (uint32_t)(
+ rte_pktmbuf_mtophys_offset(output, out_offset));
+ /* Save software context needed for dequeue */
+ desc->op_addr = op;
+ /* Set total number of CBs in an op */
+ desc->cbs_in_op = cbs_in_op;
+
+ return 0;
+}
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+/* Validates LDPC encoder parameters */
+static int
+validate_enc_op(struct rte_bbdev_enc_op *op __rte_unused)
+{
+ struct rte_bbdev_op_ldpc_enc *ldpc_enc = &op->ldpc_enc;
+ struct rte_bbdev_op_enc_ldpc_cb_params *cb = NULL;
+ struct rte_bbdev_op_enc_ldpc_tb_params *tb = NULL;
+
+
+ if (ldpc_enc->input.length >
+ RTE_BBDEV_LDPC_MAX_CB_SIZE >> 3) {
+ rte_bbdev_log(ERR, "CB size (%u) is too big, max: %d",
+ ldpc_enc->input.length,
+ RTE_BBDEV_LDPC_MAX_CB_SIZE);
+ return -1;
+ }
+
+ if (op->mempool == NULL) {
+ rte_bbdev_log(ERR, "Invalid mempool pointer");
+ return -1;
+ }
+ if (ldpc_enc->input.data == NULL) {
+ rte_bbdev_log(ERR, "Invalid input pointer");
+ return -1;
+ }
+ if (ldpc_enc->output.data == NULL) {
+ rte_bbdev_log(ERR, "Invalid output pointer");
+ return -1;
+ }
+ if ((ldpc_enc->basegraph > 2) || (ldpc_enc->basegraph == 0)) {
+ rte_bbdev_log(ERR,
+ "basegraph (%u) is out of range 1 <= value <= 2",
+ ldpc_enc->basegraph);
+ return -1;
+ }
+ if (ldpc_enc->code_block_mode > 1) {
+ rte_bbdev_log(ERR,
+ "code_block_mode (%u) is out of range 0:Tb 1:CB",
+ ldpc_enc->code_block_mode);
+ return -1;
+ }
+
+ if (ldpc_enc->code_block_mode == 0) {
+ tb = &ldpc_enc->tb_params;
+ if (tb->c == 0) {
+ rte_bbdev_log(ERR,
+ "c (%u) is out of range 1 <= value <= %u",
+ tb->c, RTE_BBDEV_LDPC_MAX_CODE_BLOCKS);
+ return -1;
+ }
+ if (tb->cab > tb->c) {
+ rte_bbdev_log(ERR,
+ "cab (%u) is greater than c (%u)",
+ tb->cab, tb->c);
+ return -1;
+ }
+ if ((tb->ea < RTE_BBDEV_LDPC_MIN_CB_SIZE)
+ && tb->r < tb->cab) {
+ rte_bbdev_log(ERR,
+ "ea (%u) is less than %u or it is not even",
+ tb->ea, RTE_BBDEV_LDPC_MIN_CB_SIZE);
+ return -1;
+ }
+ if ((tb->eb < RTE_BBDEV_LDPC_MIN_CB_SIZE)
+ && tb->c > tb->cab) {
+ rte_bbdev_log(ERR,
+ "eb (%u) is less than %u",
+ tb->eb, RTE_BBDEV_LDPC_MIN_CB_SIZE);
+ return -1;
+ }
+ if (tb->r > (tb->c - 1)) {
+ rte_bbdev_log(ERR,
+ "r (%u) is greater than c - 1 (%u)",
+ tb->r, tb->c - 1);
+ return -1;
+ }
+ } else {
+ cb = &ldpc_enc->cb_params;
+ if (cb->e < RTE_BBDEV_LDPC_MIN_CB_SIZE) {
+ rte_bbdev_log(ERR,
+ "e (%u) is less than %u or it is not even",
+ cb->e, RTE_BBDEV_LDPC_MIN_CB_SIZE);
+ return -1;
+ }
+ }
+ return 0;
+}
+#endif
+
+static inline char *
+mbuf_append(struct rte_mbuf *m_head, struct rte_mbuf *m, uint16_t len)
+{
+ if (unlikely(len > rte_pktmbuf_tailroom(m)))
+ return NULL;
+
+ char *tail = (char *)m->buf_addr + m->data_off + m->data_len;
+ m->data_len = (uint16_t)(m->data_len + len);
+ m_head->pkt_len = (m_head->pkt_len + len);
+ return tail;
+}
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+/* Validates LDPC decoder parameters */
+static int
+validate_dec_op(struct rte_bbdev_dec_op *op __rte_unused)
+{
+ struct rte_bbdev_op_ldpc_dec *ldpc_dec = &op->ldpc_dec;
+ struct rte_bbdev_op_dec_ldpc_cb_params *cb = NULL;
+ struct rte_bbdev_op_dec_ldpc_tb_params *tb = NULL;
+
+ if (op->mempool == NULL) {
+ rte_bbdev_log(ERR, "Invalid mempool pointer");
+ return -1;
+ }
+ if (ldpc_dec->rv_index > 3) {
+ rte_bbdev_log(ERR,
+ "rv_index (%u) is out of range 0 <= value <= 3",
+ ldpc_dec->rv_index);
+ return -1;
+ }
+
+ if (ldpc_dec->iter_max == 0) {
+ rte_bbdev_log(ERR,
+ "iter_max (%u) is equal to 0",
+ ldpc_dec->iter_max);
+ return -1;
+ }
+
+ if (ldpc_dec->code_block_mode > 1) {
+ rte_bbdev_log(ERR,
+ "code_block_mode (%u) is out of range 0 <= value <= 1",
+ ldpc_dec->code_block_mode);
+ return -1;
+ }
+
+ if (ldpc_dec->code_block_mode == 0) {
+ tb = &ldpc_dec->tb_params;
+ if (tb->c < 1) {
+ rte_bbdev_log(ERR,
+ "c (%u) is out of range 1 <= value <= %u",
+ tb->c, RTE_BBDEV_LDPC_MAX_CODE_BLOCKS);
+ return -1;
+ }
+ if (tb->cab > tb->c) {
+ rte_bbdev_log(ERR,
+ "cab (%u) is greater than c (%u)",
+ tb->cab, tb->c);
+ return -1;
+ }
+ } else {
+ cb = &ldpc_dec->cb_params;
+ if (cb->e < RTE_BBDEV_LDPC_MIN_CB_SIZE) {
+ rte_bbdev_log(ERR,
+ "e (%u) is out of range %u <= value <= %u",
+ cb->e, RTE_BBDEV_LDPC_MIN_CB_SIZE,
+ RTE_BBDEV_LDPC_MAX_CB_SIZE);
+ return -1;
+ }
+ }
+
+ return 0;
+}
+#endif
+
+static inline int
+fpga_harq_write_loopback(struct fpga_5gnr_fec_device *fpga_dev,
+ struct rte_mbuf *harq_input, uint16_t harq_in_length,
+ uint32_t harq_in_offset, uint32_t harq_out_offset)
+{
+ uint32_t out_offset = harq_out_offset;
+ uint32_t in_offset = harq_in_offset;
+ uint32_t left_length = harq_in_length;
+ uint32_t reg_32, increment = 0;
+ uint64_t *input = NULL;
+ uint32_t last_transaction = left_length
+ % FPGA_5GNR_FEC_DDR_WR_DATA_LEN_IN_BYTES;
+ uint64_t last_word;
+
+ if (last_transaction > 0)
+ left_length -= last_transaction;
+
+ /*
+ * Get HARQ buffer size for each VF/PF: When 0x00, there is no
+ * available DDR space for the corresponding VF/PF.
+ */
+ reg_32 = fpga_reg_read_32(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_HARQ_BUF_SIZE_REGS);
+ if (reg_32 < harq_in_length) {
+ left_length = reg_32;
+ rte_bbdev_log(ERR, "HARQ in length > HARQ buffer size\n");
+ }
+
+ input = (uint64_t *)rte_pktmbuf_mtod_offset(harq_input,
+ uint8_t *, in_offset);
+
+ while (left_length > 0) {
+ if (fpga_reg_read_8(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_ADDR_RDY_REGS) == 1) {
+ fpga_reg_write_32(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_WR_ADDR_REGS,
+ out_offset);
+ fpga_reg_write_64(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_WR_DATA_REGS,
+ input[increment]);
+ left_length -= FPGA_5GNR_FEC_DDR_WR_DATA_LEN_IN_BYTES;
+ out_offset += FPGA_5GNR_FEC_DDR_WR_DATA_LEN_IN_BYTES;
+ increment++;
+ fpga_reg_write_8(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_WR_DONE_REGS, 1);
+ }
+ }
+ while (last_transaction > 0) {
+ if (fpga_reg_read_8(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_ADDR_RDY_REGS) == 1) {
+ fpga_reg_write_32(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_WR_ADDR_REGS,
+ out_offset);
+ last_word = input[increment];
+ last_word &= (uint64_t)(1 << (last_transaction * 4))
+ - 1;
+ fpga_reg_write_64(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_WR_DATA_REGS,
+ last_word);
+ fpga_reg_write_8(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_WR_DONE_REGS, 1);
+ last_transaction = 0;
+ }
+ }
+ return 1;
+}
+
+static inline int
+fpga_harq_read_loopback(struct fpga_5gnr_fec_device *fpga_dev,
+ struct rte_mbuf *harq_output, uint16_t harq_in_length,
+ uint32_t harq_in_offset, uint32_t harq_out_offset)
+{
+ uint32_t left_length, in_offset = harq_in_offset;
+ uint64_t reg;
+ uint32_t increment = 0;
+ uint64_t *input = NULL;
+ uint32_t last_transaction = harq_in_length
+ % FPGA_5GNR_FEC_DDR_WR_DATA_LEN_IN_BYTES;
+
+ if (last_transaction > 0)
+ harq_in_length += (8 - last_transaction);
+
+ reg = fpga_reg_read_32(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_HARQ_BUF_SIZE_REGS);
+ if (reg < harq_in_length) {
+ harq_in_length = reg;
+ rte_bbdev_log(ERR, "HARQ in length > HARQ buffer size\n");
+ }
+
+ if (!mbuf_append(harq_output, harq_output, harq_in_length)) {
+ rte_bbdev_log(ERR, "HARQ output buffer warning %d %d\n",
+ harq_output->buf_len -
+ rte_pktmbuf_headroom(harq_output),
+ harq_in_length);
+ harq_in_length = harq_output->buf_len -
+ rte_pktmbuf_headroom(harq_output);
+ if (!mbuf_append(harq_output, harq_output, harq_in_length)) {
+ rte_bbdev_log(ERR, "HARQ output buffer issue %d %d\n",
+ harq_output->buf_len, harq_in_length);
+ return -1;
+ }
+ }
+ left_length = harq_in_length;
+
+ input = (uint64_t *)rte_pktmbuf_mtod_offset(harq_output,
+ uint8_t *, harq_out_offset);
+
+ while (left_length > 0) {
+ fpga_reg_write_32(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_RD_ADDR_REGS, in_offset);
+ fpga_reg_write_8(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_RD_DONE_REGS, 1);
+ reg = fpga_reg_read_8(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_RD_RDY_REGS);
+ while (reg != 1) {
+ reg = fpga_reg_read_8(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_RD_RDY_REGS);
+ if (reg == FPGA_DDR_OVERFLOW) {
+ rte_bbdev_log(ERR,
+ "Read address is overflow!\n");
+ return -1;
+ }
+ }
+ input[increment] = fpga_reg_read_64(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_RD_DATA_REGS);
+ left_length -= FPGA_5GNR_FEC_DDR_RD_DATA_LEN_IN_BYTES;
+ in_offset += FPGA_5GNR_FEC_DDR_WR_DATA_LEN_IN_BYTES;
+ increment++;
+ fpga_reg_write_8(fpga_dev->mmio_base,
+ FPGA_5GNR_FEC_DDR4_RD_DONE_REGS, 0);
+ }
+ return 1;
+}
+
+static inline int
+enqueue_ldpc_enc_one_op_cb(struct fpga_queue *q, struct rte_bbdev_enc_op *op,
+ uint16_t desc_offset)
+{
+ union fpga_dma_desc *desc;
+ int ret;
+ uint8_t c, crc24_bits = 0;
+ struct rte_bbdev_op_ldpc_enc *enc = &op->ldpc_enc;
+ uint16_t in_offset = enc->input.offset;
+ uint16_t out_offset = enc->output.offset;
+ struct rte_mbuf *m_in = enc->input.data;
+ struct rte_mbuf *m_out = enc->output.data;
+ struct rte_mbuf *m_out_head = enc->output.data;
+ uint32_t in_length, out_length, e;
+ uint16_t total_left = enc->input.length;
+ uint16_t ring_offset;
+ uint16_t K, k_;
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ /* FIXME */
+ if (validate_enc_op(op) == -1) {
+ rte_bbdev_log(ERR, "LDPC encoder validation failed");
+ return -EINVAL;
+ }
+#endif
+
+ /* Clear op status */
+ op->status = 0;
+
+ if (m_in == NULL || m_out == NULL) {
+ rte_bbdev_log(ERR, "Invalid mbuf pointer");
+ op->status = 1 << RTE_BBDEV_DATA_ERROR;
+ return -EINVAL;
+ }
+
+ if (enc->op_flags & RTE_BBDEV_LDPC_CRC_24B_ATTACH)
+ crc24_bits = 24;
+
+ if (enc->code_block_mode == 0) {
+ /* For Transport Block mode */
+ /* FIXME */
+ c = enc->tb_params.c;
+ e = enc->tb_params.ea;
+ } else { /* For Code Block mode */
+ c = 1;
+ e = enc->cb_params.e;
+ }
+
+ /* Update total_left */
+ K = (enc->basegraph == 1 ? 22 : 10) * enc->z_c;
+ k_ = K - enc->n_filler;
+ in_length = (k_ - crc24_bits) >> 3;
+ out_length = (e + 7) >> 3;
+
+ total_left = rte_pktmbuf_data_len(m_in) - in_offset;
+
+ /* Update offsets */
+ if (total_left != in_length) {
+ op->status |= 1 << RTE_BBDEV_DATA_ERROR;
+ rte_bbdev_log(ERR,
+ "Mismatch between mbuf length and included CBs sizes %d",
+ total_left);
+ }
+
+ mbuf_append(m_out_head, m_out, out_length);
+
+ /* Offset into the ring */
+ ring_offset = ((q->tail + desc_offset) & q->sw_ring_wrap_mask);
+ /* Setup DMA Descriptor */
+ desc = q->ring_addr + ring_offset;
+
+ ret = fpga_dma_desc_te_fill(op, &desc->enc_req, m_in, m_out,
+ k_, e, in_offset, out_offset, ring_offset, c);
+ if (unlikely(ret < 0))
+ return ret;
+
+ /* Update lengths */
+ total_left -= in_length;
+ op->ldpc_enc.output.length += out_length;
+
+ if (total_left > 0) {
+ rte_bbdev_log(ERR,
+ "Mismatch between mbuf length and included CB sizes: mbuf len %u, cb len %u",
+ total_left, in_length);
+ return -1;
+ }
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ print_dma_enc_desc_debug_info(desc);
+#endif
+ return 1;
+}
+
+static inline int
+enqueue_ldpc_dec_one_op_cb(struct fpga_queue *q, struct rte_bbdev_dec_op *op,
+ uint16_t desc_offset)
+{
+ union fpga_dma_desc *desc;
+ int ret;
+ uint16_t ring_offset;
+ uint8_t c;
+ uint16_t e, in_length, out_length, k0, l, seg_total_left, sys_cols;
+ uint16_t K, parity_offset, harq_in_length = 0, harq_out_length = 0;
+ uint16_t crc24_overlap = 0;
+ struct rte_bbdev_op_ldpc_dec *dec = &op->ldpc_dec;
+ struct rte_mbuf *m_in = dec->input.data;
+ struct rte_mbuf *m_out = dec->hard_output.data;
+ struct rte_mbuf *m_out_head = dec->hard_output.data;
+ uint16_t in_offset = dec->input.offset;
+ uint16_t out_offset = dec->hard_output.offset;
+ uint32_t harq_offset = 0;
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ if (validate_dec_op(op) == -1) {
+ rte_bbdev_log(ERR, "LDPC decoder validation failed");
+ return -EINVAL;
+ }
+#endif
+
+ /* Clear op status */
+ op->status = 0;
+
+ /* Setup DMA Descriptor */
+ ring_offset = ((q->tail + desc_offset) & q->sw_ring_wrap_mask);
+ desc = q->ring_addr + ring_offset;
+
+ if (check_bit(dec->op_flags,
+ RTE_BBDEV_LDPC_INTERNAL_HARQ_MEMORY_LOOPBACK)) {
+ struct rte_mbuf *harq_in = dec->harq_combined_input.data;
+ struct rte_mbuf *harq_out = dec->harq_combined_output.data;
+ harq_in_length = dec->harq_combined_input.length;
+ uint32_t harq_in_offset = dec->harq_combined_input.offset;
+ uint32_t harq_out_offset = dec->harq_combined_output.offset;
+
+ if (check_bit(dec->op_flags,
+ RTE_BBDEV_LDPC_INTERNAL_HARQ_MEMORY_OUT_ENABLE
+ )) {
+ ret = fpga_harq_write_loopback(q->d, harq_in,
+ harq_in_length, harq_in_offset,
+ harq_out_offset);
+ } else if (check_bit(dec->op_flags,
+ RTE_BBDEV_LDPC_INTERNAL_HARQ_MEMORY_IN_ENABLE
+ )) {
+ ret = fpga_harq_read_loopback(q->d, harq_out,
+ harq_in_length, harq_in_offset,
+ harq_out_offset);
+ dec->harq_combined_output.length = harq_in_length;
+ } else {
+ rte_bbdev_log(ERR, "OP flag Err!");
+ ret = -1;
+ }
+ /* Set descriptor for dequeue */
+ desc->dec_req.done = 1;
+ desc->dec_req.error = 0;
+ desc->dec_req.op_addr = op;
+ desc->dec_req.cbs_in_op = 1;
+ /* Mark this dummy descriptor to be dropped by HW */
+ desc->dec_req.desc_idx = (ring_offset + 1)
+ & q->sw_ring_wrap_mask;
+ return ret; /* Error or number of CB */
+ }
+
+ if (m_in == NULL || m_out == NULL) {
+ rte_bbdev_log(ERR, "Invalid mbuf pointer");
+ op->status = 1 << RTE_BBDEV_DATA_ERROR;
+ return -1;
+ }
+
+ c = 1;
+ e = dec->cb_params.e;
+
+ if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_CRC_TYPE_24B_DROP))
+ crc24_overlap = 24;
+
+ sys_cols = (dec->basegraph == 1) ? 22 : 10;
+ K = sys_cols * dec->z_c;
+ parity_offset = K - 2 * dec->z_c;
+
+ out_length = ((K - crc24_overlap - dec->n_filler) >> 3);
+ in_length = e;
+ seg_total_left = dec->input.length;
+
+ if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_HQ_COMBINE_IN_ENABLE)) {
+ harq_in_length = RTE_MIN(dec->harq_combined_input.length,
+ (uint32_t)dec->n_cb);
+ }
+
+ if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_HQ_COMBINE_OUT_ENABLE)) {
+ k0 = get_k0(dec->n_cb, dec->z_c,
+ dec->basegraph, dec->rv_index);
+ if (k0 > parity_offset)
+ l = k0 + e;
+ else
+ l = k0 + e + dec->n_filler;
+ harq_out_length = RTE_MIN(RTE_MAX(harq_in_length, l),
+ dec->n_cb - dec->n_filler);
+ dec->harq_combined_output.length = harq_out_length;
+ }
+
+ mbuf_append(m_out_head, m_out, out_length);
+ if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_HQ_COMBINE_IN_ENABLE))
+ harq_offset = dec->harq_combined_input.offset;
+ else if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_HQ_COMBINE_OUT_ENABLE))
+ harq_offset = dec->harq_combined_output.offset;
+
+ if ((harq_offset & 0x3FF) > 0) {
+ rte_bbdev_log(ERR, "Invalid HARQ offset %d", harq_offset);
+ op->status = 1 << RTE_BBDEV_DATA_ERROR;
+ return -1;
+ }
+
+ ret = fpga_dma_desc_ld_fill(op, &desc->dec_req, m_in, m_out,
+ harq_in_length, in_offset, out_offset, harq_offset,
+ ring_offset, c);
+ if (unlikely(ret < 0))
+ return ret;
+ /* Update lengths */
+ seg_total_left -= in_length;
+ op->ldpc_dec.hard_output.length += out_length;
+ if (seg_total_left > 0) {
+ rte_bbdev_log(ERR,
+ "Mismatch between mbuf length and included CB sizes: mbuf len %u, cb len %u",
+ seg_total_left, in_length);
+ return -1;
+ }
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ print_dma_dec_desc_debug_info(desc);
+#endif
+
+ return 1;
+}
+
+static uint16_t
+fpga_enqueue_ldpc_enc(struct rte_bbdev_queue_data *q_data,
+ struct rte_bbdev_enc_op **ops, uint16_t num)
+{
+ uint16_t i, total_enqueued_cbs = 0;
+ int32_t avail;
+ int enqueued_cbs;
+ struct fpga_queue *q = q_data->queue_private;
+ union fpga_dma_desc *desc;
+
+ /* Check if queue is not full */
+ if (unlikely(((q->tail + 1) & q->sw_ring_wrap_mask) ==
+ q->head_free_desc))
+ return 0;
+
+ /* Calculates available space */
+ avail = (q->head_free_desc > q->tail) ?
+ q->head_free_desc - q->tail - 1 :
+ q->ring_ctrl_reg.ring_size + q->head_free_desc - q->tail - 1;
+
+ for (i = 0; i < num; ++i) {
+
+ /* Check if there is available space for further
+ * processing
+ */
+ if (unlikely(avail - 1 < 0))
+ break;
+ avail -= 1;
+ enqueued_cbs = enqueue_ldpc_enc_one_op_cb(q, ops[i],
+ total_enqueued_cbs);
+
+ if (enqueued_cbs < 0)
+ break;
+
+ total_enqueued_cbs += enqueued_cbs;
+
+ rte_bbdev_log_debug("enqueuing enc ops [%d/%d] | head %d | tail %d",
+ total_enqueued_cbs, num,
+ q->head_free_desc, q->tail);
+ }
+
+ /* Set interrupt bit for last CB in enqueued ops. FPGA issues interrupt
+ * only when all previous CBs were already processed.
+ */
+ desc = q->ring_addr + ((q->tail + total_enqueued_cbs - 1)
+ & q->sw_ring_wrap_mask);
+ desc->enc_req.irq_en = q->irq_enable;
+
+ fpga_dma_enqueue(q, total_enqueued_cbs, &q_data->queue_stats);
+
+ /* Update stats */
+ q_data->queue_stats.enqueued_count += i;
+ q_data->queue_stats.enqueue_err_count += num - i;
+
+ return i;
+}
+
+static uint16_t
+fpga_enqueue_ldpc_dec(struct rte_bbdev_queue_data *q_data,
+ struct rte_bbdev_dec_op **ops, uint16_t num)
+{
+ uint16_t i, total_enqueued_cbs = 0;
+ int32_t avail;
+ int enqueued_cbs;
+ struct fpga_queue *q = q_data->queue_private;
+ union fpga_dma_desc *desc;
+
+ /* Check if queue is not full */
+ if (unlikely(((q->tail + 1) & q->sw_ring_wrap_mask) ==
+ q->head_free_desc))
+ return 0;
+
+ /* Calculates available space */
+ avail = (q->head_free_desc > q->tail) ?
+ q->head_free_desc - q->tail - 1 :
+ q->ring_ctrl_reg.ring_size + q->head_free_desc - q->tail - 1;
+
+ for (i = 0; i < num; ++i) {
+
+ /* Check if there is available space for further
+ * processing
+ */
+ if (unlikely(avail - 1 < 0))
+ break;
+ avail -= 1;
+ enqueued_cbs = enqueue_ldpc_dec_one_op_cb(q, ops[i],
+ total_enqueued_cbs);
+
+ if (enqueued_cbs < 0)
+ break;
+
+ total_enqueued_cbs += enqueued_cbs;
+
+ rte_bbdev_log_debug("enqueuing dec ops [%d/%d] | head %d | tail %d",
+ total_enqueued_cbs, num,
+ q->head_free_desc, q->tail);
+ }
+
+ /* Update stats */
+ q_data->queue_stats.enqueued_count += i;
+ q_data->queue_stats.enqueue_err_count += num - i;
+
+ /* Set interrupt bit for last CB in enqueued ops. FPGA issues interrupt
+ * only when all previous CBs were already processed.
+ */
+ desc = q->ring_addr + ((q->tail + total_enqueued_cbs - 1)
+ & q->sw_ring_wrap_mask);
+ desc->enc_req.irq_en = q->irq_enable;
+ fpga_dma_enqueue(q, total_enqueued_cbs, &q_data->queue_stats);
+ return i;
+}
+
+
+static inline int
+dequeue_ldpc_enc_one_op_cb(struct fpga_queue *q,
+ struct rte_bbdev_enc_op **op,
+ uint16_t desc_offset)
+{
+ union fpga_dma_desc *desc;
+ int desc_error;
+ /* Set current desc */
+ desc = q->ring_addr + ((q->head_free_desc + desc_offset)
+ & q->sw_ring_wrap_mask);
+
+ /*check if done */
+ if (desc->enc_req.done == 0)
+ return -1;
+
+ /* make sure the response is read atomically */
+ rte_smp_rmb();
+
+ rte_bbdev_log_debug("DMA response desc %p", desc);
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ print_dma_enc_desc_debug_info(desc);
+#endif
+
+ *op = desc->enc_req.op_addr;
+ /* Check the descriptor error field, return 1 on error */
+ desc_error = check_desc_error(desc->enc_req.error);
+ (*op)->status = desc_error << RTE_BBDEV_DATA_ERROR;
+
+ return 1;
+}
+
+
+static inline int
+dequeue_ldpc_dec_one_op_cb(struct fpga_queue *q, struct rte_bbdev_dec_op **op,
+ uint16_t desc_offset)
+{
+ union fpga_dma_desc *desc;
+ int desc_error;
+ /* Set descriptor */
+ desc = q->ring_addr + ((q->head_free_desc + desc_offset)
+ & q->sw_ring_wrap_mask);
+
+ /* Verify done bit is set */
+ if (desc->dec_req.done == 0)
+ return -1;
+
+ /* make sure the response is read atomically */
+ rte_smp_rmb();
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ print_dma_dec_desc_debug_info(desc);
+#endif
+
+ *op = desc->dec_req.op_addr;
+
+ if (check_bit((*op)->ldpc_dec.op_flags,
+ RTE_BBDEV_LDPC_INTERNAL_HARQ_MEMORY_LOOPBACK)) {
+ (*op)->status = 0;
+ return 1;
+ }
+
+ /* FPGA reports iterations based on round-up minus 1 */
+ (*op)->ldpc_dec.iter_count = desc->dec_req.iter + 1;
+ /* CRC Check criteria */
+ if (desc->dec_req.crc24b_ind && !(desc->dec_req.crcb_pass))
+ (*op)->status = 1 << RTE_BBDEV_CRC_ERROR;
+ /* et_pass = 0 when decoder fails */
+ (*op)->status |= !(desc->dec_req.et_pass) << RTE_BBDEV_SYNDROME_ERROR;
+ /* Check the descriptor error field, return 1 on error */
+ desc_error = check_desc_error(desc->dec_req.error);
+ (*op)->status |= desc_error << RTE_BBDEV_DATA_ERROR;
+ return 1;
+}
+
+static uint16_t
+fpga_dequeue_ldpc_enc(struct rte_bbdev_queue_data *q_data,
+ struct rte_bbdev_enc_op **ops, uint16_t num)
+{
+ struct fpga_queue *q = q_data->queue_private;
+ uint32_t avail = (q->tail - q->head_free_desc) & q->sw_ring_wrap_mask;
+ uint16_t i;
+ uint16_t dequeued_cbs = 0;
+ int ret;
+
+ for (i = 0; (i < num) && (dequeued_cbs < avail); ++i) {
+ ret = dequeue_ldpc_enc_one_op_cb(q, &ops[i], dequeued_cbs);
+
+ if (ret < 0)
+ break;
+
+ dequeued_cbs += ret;
+
+ rte_bbdev_log_debug("dequeuing enc ops [%d/%d] | head %d | tail %d",
+ dequeued_cbs, num, q->head_free_desc, q->tail);
+ }
+
+ /* Update head */
+ q->head_free_desc = (q->head_free_desc + dequeued_cbs) &
+ q->sw_ring_wrap_mask;
+
+ /* Update stats */
+ q_data->queue_stats.dequeued_count += i;
+
+ return i;
+}
+
+static uint16_t
+fpga_dequeue_ldpc_dec(struct rte_bbdev_queue_data *q_data,
+ struct rte_bbdev_dec_op **ops, uint16_t num)
+{
+ struct fpga_queue *q = q_data->queue_private;
+ uint32_t avail = (q->tail - q->head_free_desc) & q->sw_ring_wrap_mask;
+ uint16_t i;
+ uint16_t dequeued_cbs = 0;
+ int ret;
+
+ for (i = 0; (i < num) && (dequeued_cbs < avail); ++i) {
+ ret = dequeue_ldpc_dec_one_op_cb(q, &ops[i], dequeued_cbs);
+
+ if (ret < 0)
+ break;
+
+ dequeued_cbs += ret;
+
+ rte_bbdev_log_debug("dequeuing dec ops [%d/%d] | head %d | tail %d",
+ dequeued_cbs, num, q->head_free_desc, q->tail);
+ }
+
+ /* Update head */
+ q->head_free_desc = (q->head_free_desc + dequeued_cbs) &
+ q->sw_ring_wrap_mask;
+
+ /* Update stats */
+ q_data->queue_stats.dequeued_count += i;
+
+ return i;
+}
+
+
/* Initialization Function */
static void
fpga_5gnr_fec_init(struct rte_bbdev *dev, struct rte_pci_driver *drv)
struct rte_pci_device *pci_dev = RTE_DEV_TO_PCI(dev->device);
dev->dev_ops = &fpga_ops;
+ dev->enqueue_ldpc_enc_ops = fpga_enqueue_ldpc_enc;
+ dev->enqueue_ldpc_dec_ops = fpga_enqueue_ldpc_dec;
+ dev->dequeue_ldpc_enc_ops = fpga_dequeue_ldpc_enc;
+ dev->dequeue_ldpc_dec_ops = fpga_dequeue_ldpc_dec;
((struct fpga_5gnr_fec_device *) dev->data->dev_private)->pf_device =
!strcmp(drv->driver.name,
rte_bbdev_log_debug("bbdev id = %u [%s]",
bbdev->data->dev_id, dev_name);
+ struct fpga_5gnr_fec_device *d = bbdev->data->dev_private;
+ uint32_t version_id = fpga_reg_read_32(d->mmio_base,
+ FPGA_5GNR_FEC_VERSION_ID);
+ rte_bbdev_log(INFO, "FEC FPGA RTL v%u.%u",
+ ((uint16_t)(version_id >> 16)), ((uint16_t)version_id));
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ if (!strcmp(bbdev->device->driver->name,
+ RTE_STR(FPGA_5GNR_FEC_PF_DRIVER_NAME)))
+ print_static_reg_debug_info(d->mmio_base);
+#endif
return 0;
}
return 0;
}
+static inline void
+set_default_fpga_conf(struct fpga_5gnr_fec_conf *def_conf)
+{
+ /* clear default configuration before initialization */
+ memset(def_conf, 0, sizeof(struct fpga_5gnr_fec_conf));
+ /* Set pf mode to true */
+ def_conf->pf_mode_en = true;
+
+ /* Set ratio between UL and DL to 1:1 (unit of weight is 3 CBs) */
+ def_conf->ul_bandwidth = 3;
+ def_conf->dl_bandwidth = 3;
+
+ /* Set Load Balance Factor to 64 */
+ def_conf->dl_load_balance = 64;
+ def_conf->ul_load_balance = 64;
+}
+
+/* Initial configuration of FPGA 5GNR FEC device */
+int
+fpga_5gnr_fec_configure(const char *dev_name,
+ const struct fpga_5gnr_fec_conf *conf)
+{
+ uint32_t payload_32, address;
+ uint16_t payload_16;
+ uint8_t payload_8;
+ uint16_t q_id, vf_id, total_q_id, total_ul_q_id, total_dl_q_id;
+ struct rte_bbdev *bbdev = rte_bbdev_get_named_dev(dev_name);
+ struct fpga_5gnr_fec_conf def_conf;
+
+ if (bbdev == NULL) {
+ rte_bbdev_log(ERR,
+ "Invalid dev_name (%s), or device is not yet initialised",
+ dev_name);
+ return -ENODEV;
+ }
+
+ struct fpga_5gnr_fec_device *d = bbdev->data->dev_private;
+
+ if (conf == NULL) {
+ rte_bbdev_log(ERR,
+ "FPGA Configuration was not provided. Default configuration will be loaded.");
+ set_default_fpga_conf(&def_conf);
+ conf = &def_conf;
+ }
+
+ /*
+ * Configure UL:DL ratio.
+ * [7:0]: UL weight
+ * [15:8]: DL weight
+ */
+ payload_16 = (conf->dl_bandwidth << 8) | conf->ul_bandwidth;
+ address = FPGA_5GNR_FEC_CONFIGURATION;
+ fpga_reg_write_16(d->mmio_base, address, payload_16);
+
+ /* Clear all queues registers */
+ payload_32 = FPGA_INVALID_HW_QUEUE_ID;
+ for (q_id = 0; q_id < FPGA_TOTAL_NUM_QUEUES; ++q_id) {
+ address = (q_id << 2) + FPGA_5GNR_FEC_QUEUE_MAP;
+ fpga_reg_write_32(d->mmio_base, address, payload_32);
+ }
+
+ /*
+ * If PF mode is enabled allocate all queues for PF only.
+ *
+ * For VF mode each VF can have different number of UL and DL queues.
+ * Total number of queues to configure cannot exceed FPGA
+ * capabilities - 64 queues - 32 queues for UL and 32 queues for DL.
+ * Queues mapping is done according to configuration:
+ *
+ * UL queues:
+ * | Q_ID | VF_ID |
+ * | 0 | 0 |
+ * | ... | 0 |
+ * | conf->vf_dl_queues_number[0] - 1 | 0 |
+ * | conf->vf_dl_queues_number[0] | 1 |
+ * | ... | 1 |
+ * | conf->vf_dl_queues_number[1] - 1 | 1 |
+ * | ... | ... |
+ * | conf->vf_dl_queues_number[7] - 1 | 7 |
+ *
+ * DL queues:
+ * | Q_ID | VF_ID |
+ * | 32 | 0 |
+ * | ... | 0 |
+ * | conf->vf_ul_queues_number[0] - 1 | 0 |
+ * | conf->vf_ul_queues_number[0] | 1 |
+ * | ... | 1 |
+ * | conf->vf_ul_queues_number[1] - 1 | 1 |
+ * | ... | ... |
+ * | conf->vf_ul_queues_number[7] - 1 | 7 |
+ *
+ * Example of configuration:
+ * conf->vf_ul_queues_number[0] = 4; -> 4 UL queues for VF0
+ * conf->vf_dl_queues_number[0] = 4; -> 4 DL queues for VF0
+ * conf->vf_ul_queues_number[1] = 2; -> 2 UL queues for VF1
+ * conf->vf_dl_queues_number[1] = 2; -> 2 DL queues for VF1
+ *
+ * UL:
+ * | Q_ID | VF_ID |
+ * | 0 | 0 |
+ * | 1 | 0 |
+ * | 2 | 0 |
+ * | 3 | 0 |
+ * | 4 | 1 |
+ * | 5 | 1 |
+ *
+ * DL:
+ * | Q_ID | VF_ID |
+ * | 32 | 0 |
+ * | 33 | 0 |
+ * | 34 | 0 |
+ * | 35 | 0 |
+ * | 36 | 1 |
+ * | 37 | 1 |
+ */
+ if (conf->pf_mode_en) {
+ payload_32 = 0x1;
+ for (q_id = 0; q_id < FPGA_TOTAL_NUM_QUEUES; ++q_id) {
+ address = (q_id << 2) + FPGA_5GNR_FEC_QUEUE_MAP;
+ fpga_reg_write_32(d->mmio_base, address, payload_32);
+ }
+ } else {
+ /* Calculate total number of UL and DL queues to configure */
+ total_ul_q_id = total_dl_q_id = 0;
+ for (vf_id = 0; vf_id < FPGA_5GNR_FEC_NUM_VFS; ++vf_id) {
+ total_ul_q_id += conf->vf_ul_queues_number[vf_id];
+ total_dl_q_id += conf->vf_dl_queues_number[vf_id];
+ }
+ total_q_id = total_dl_q_id + total_ul_q_id;
+ /*
+ * Check if total number of queues to configure does not exceed
+ * FPGA capabilities (64 queues - 32 UL and 32 DL queues)
+ */
+ if ((total_ul_q_id > FPGA_NUM_UL_QUEUES) ||
+ (total_dl_q_id > FPGA_NUM_DL_QUEUES) ||
+ (total_q_id > FPGA_TOTAL_NUM_QUEUES)) {
+ rte_bbdev_log(ERR,
+ "FPGA Configuration failed. Too many queues to configure: UL_Q %u, DL_Q %u, FPGA_Q %u",
+ total_ul_q_id, total_dl_q_id,
+ FPGA_TOTAL_NUM_QUEUES);
+ return -EINVAL;
+ }
+ total_ul_q_id = 0;
+ for (vf_id = 0; vf_id < FPGA_5GNR_FEC_NUM_VFS; ++vf_id) {
+ for (q_id = 0; q_id < conf->vf_ul_queues_number[vf_id];
+ ++q_id, ++total_ul_q_id) {
+ address = (total_ul_q_id << 2) +
+ FPGA_5GNR_FEC_QUEUE_MAP;
+ payload_32 = ((0x80 + vf_id) << 16) | 0x1;
+ fpga_reg_write_32(d->mmio_base, address,
+ payload_32);
+ }
+ }
+ total_dl_q_id = 0;
+ for (vf_id = 0; vf_id < FPGA_5GNR_FEC_NUM_VFS; ++vf_id) {
+ for (q_id = 0; q_id < conf->vf_dl_queues_number[vf_id];
+ ++q_id, ++total_dl_q_id) {
+ address = ((total_dl_q_id + FPGA_NUM_UL_QUEUES)
+ << 2) + FPGA_5GNR_FEC_QUEUE_MAP;
+ payload_32 = ((0x80 + vf_id) << 16) | 0x1;
+ fpga_reg_write_32(d->mmio_base, address,
+ payload_32);
+ }
+ }
+ }
+
+ /* Setting Load Balance Factor */
+ payload_16 = (conf->dl_load_balance << 8) | (conf->ul_load_balance);
+ address = FPGA_5GNR_FEC_LOAD_BALANCE_FACTOR;
+ fpga_reg_write_16(d->mmio_base, address, payload_16);
+
+ /* Setting length of ring descriptor entry */
+ payload_16 = FPGA_RING_DESC_ENTRY_LENGTH;
+ address = FPGA_5GNR_FEC_RING_DESC_LEN;
+ fpga_reg_write_16(d->mmio_base, address, payload_16);
+
+ /* Setting FLR timeout value */
+ payload_16 = conf->flr_time_out;
+ address = FPGA_5GNR_FEC_FLR_TIME_OUT;
+ fpga_reg_write_16(d->mmio_base, address, payload_16);
+
+ /* Queue PF/VF mapping table is ready */
+ payload_8 = 0x1;
+ address = FPGA_5GNR_FEC_QUEUE_PF_VF_MAP_DONE;
+ fpga_reg_write_8(d->mmio_base, address, payload_8);
+
+ rte_bbdev_log_debug("PF FPGA 5GNR FEC configuration complete for %s",
+ dev_name);
+
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ print_static_reg_debug_info(d->mmio_base);
+#endif
+ return 0;
+}
+
/* FPGA 5GNR FEC PCI PF address map */
static struct rte_pci_id pci_id_fpga_5gnr_fec_pf_map[] = {
{