/* Write a register of a ACC100 device */
static inline void
-acc100_reg_write(struct acc100_device *d, uint32_t offset, uint32_t payload)
+acc100_reg_write(struct acc100_device *d, uint32_t offset, uint32_t value)
{
void *reg_addr = RTE_PTR_ADD(d->mmio_base, offset);
- mmio_write(reg_addr, payload);
+ mmio_write(reg_addr, value);
usleep(ACC100_LONG_WAIT);
}
enum {UL_4G = 0, UL_5G, DL_4G, DL_5G, NUM_ACC};
+/* Return the accelerator enum for a Queue Group Index */
+static inline int
+accFromQgid(int qg_idx, const struct rte_acc100_conf *acc100_conf)
+{
+ int accQg[ACC100_NUM_QGRPS];
+ int NumQGroupsPerFn[NUM_ACC];
+ int acc, qgIdx, qgIndex = 0;
+ for (qgIdx = 0; qgIdx < ACC100_NUM_QGRPS; qgIdx++)
+ accQg[qgIdx] = 0;
+ NumQGroupsPerFn[UL_4G] = acc100_conf->q_ul_4g.num_qgroups;
+ NumQGroupsPerFn[UL_5G] = acc100_conf->q_ul_5g.num_qgroups;
+ NumQGroupsPerFn[DL_4G] = acc100_conf->q_dl_4g.num_qgroups;
+ NumQGroupsPerFn[DL_5G] = acc100_conf->q_dl_5g.num_qgroups;
+ for (acc = UL_4G; acc < NUM_ACC; acc++)
+ for (qgIdx = 0; qgIdx < NumQGroupsPerFn[acc]; qgIdx++)
+ accQg[qgIndex++] = acc;
+ acc = accQg[qg_idx];
+ return acc;
+}
+
/* Return the queue topology for a Queue Group Index */
static inline void
qtopFromAcc(struct rte_acc100_queue_topology **qtop, int acc_enum,
*qtop = p_qtop;
}
+/* Return the AQ depth for a Queue Group Index */
+static inline int
+aqDepth(int qg_idx, struct rte_acc100_conf *acc100_conf)
+{
+ struct rte_acc100_queue_topology *q_top = NULL;
+ int acc_enum = accFromQgid(qg_idx, acc100_conf);
+ qtopFromAcc(&q_top, acc_enum, acc100_conf);
+ if (unlikely(q_top == NULL))
+ return 0;
+ return q_top->aq_depth_log2;
+}
+
+/* Return the AQ depth for a Queue Group Index */
+static inline int
+aqNum(int qg_idx, struct rte_acc100_conf *acc100_conf)
+{
+ struct rte_acc100_queue_topology *q_top = NULL;
+ int acc_enum = accFromQgid(qg_idx, acc100_conf);
+ qtopFromAcc(&q_top, acc_enum, acc100_conf);
+ if (unlikely(q_top == NULL))
+ return 0;
+ return q_top->num_aqs_per_groups;
+}
+
static void
initQTop(struct rte_acc100_conf *acc100_conf)
{
free_base_addresses(base_addrs, i);
}
+/*
+ * Find queue_id of a device queue based on details from the Info Ring.
+ * If a queue isn't found UINT16_MAX is returned.
+ */
+static inline uint16_t
+get_queue_id_from_ring_info(struct rte_bbdev_data *data,
+ const union acc100_info_ring_data ring_data)
+{
+ uint16_t queue_id;
+
+ for (queue_id = 0; queue_id < data->num_queues; ++queue_id) {
+ struct acc100_queue *acc100_q =
+ data->queues[queue_id].queue_private;
+ if (acc100_q != NULL && acc100_q->aq_id == ring_data.aq_id &&
+ acc100_q->qgrp_id == ring_data.qg_id &&
+ acc100_q->vf_id == ring_data.vf_id)
+ return queue_id;
+ }
+
+ return UINT16_MAX;
+}
+
+/* Checks PF Info Ring to find the interrupt cause and handles it accordingly */
+static inline void
+acc100_check_ir(struct acc100_device *acc100_dev)
+{
+ volatile union acc100_info_ring_data *ring_data;
+ uint16_t info_ring_head = acc100_dev->info_ring_head;
+ if (acc100_dev->info_ring == NULL)
+ return;
+
+ ring_data = acc100_dev->info_ring + (acc100_dev->info_ring_head &
+ ACC100_INFO_RING_MASK);
+
+ while (ring_data->valid) {
+ if ((ring_data->int_nb < ACC100_PF_INT_DMA_DL_DESC_IRQ) || (
+ ring_data->int_nb >
+ ACC100_PF_INT_DMA_DL5G_DESC_IRQ))
+ rte_bbdev_log(WARNING, "InfoRing: ITR:%d Info:0x%x",
+ ring_data->int_nb, ring_data->detailed_info);
+ /* Initialize Info Ring entry and move forward */
+ ring_data->val = 0;
+ info_ring_head++;
+ ring_data = acc100_dev->info_ring +
+ (info_ring_head & ACC100_INFO_RING_MASK);
+ }
+}
+
+/* Checks PF Info Ring to find the interrupt cause and handles it accordingly */
+static inline void
+acc100_pf_interrupt_handler(struct rte_bbdev *dev)
+{
+ struct acc100_device *acc100_dev = dev->data->dev_private;
+ volatile union acc100_info_ring_data *ring_data;
+ struct acc100_deq_intr_details deq_intr_det;
+
+ ring_data = acc100_dev->info_ring + (acc100_dev->info_ring_head &
+ ACC100_INFO_RING_MASK);
+
+ while (ring_data->valid) {
+
+ rte_bbdev_log_debug(
+ "ACC100 PF Interrupt received, Info Ring data: 0x%x",
+ ring_data->val);
+
+ switch (ring_data->int_nb) {
+ case ACC100_PF_INT_DMA_DL_DESC_IRQ:
+ case ACC100_PF_INT_DMA_UL_DESC_IRQ:
+ case ACC100_PF_INT_DMA_UL5G_DESC_IRQ:
+ case ACC100_PF_INT_DMA_DL5G_DESC_IRQ:
+ deq_intr_det.queue_id = get_queue_id_from_ring_info(
+ dev->data, *ring_data);
+ if (deq_intr_det.queue_id == UINT16_MAX) {
+ rte_bbdev_log(ERR,
+ "Couldn't find queue: aq_id: %u, qg_id: %u, vf_id: %u",
+ ring_data->aq_id,
+ ring_data->qg_id,
+ ring_data->vf_id);
+ return;
+ }
+ rte_bbdev_pmd_callback_process(dev,
+ RTE_BBDEV_EVENT_DEQUEUE, &deq_intr_det);
+ break;
+ default:
+ rte_bbdev_pmd_callback_process(dev,
+ RTE_BBDEV_EVENT_ERROR, NULL);
+ break;
+ }
+
+ /* Initialize Info Ring entry and move forward */
+ ring_data->val = 0;
+ ++acc100_dev->info_ring_head;
+ ring_data = acc100_dev->info_ring +
+ (acc100_dev->info_ring_head &
+ ACC100_INFO_RING_MASK);
+ }
+}
+
+/* Checks VF Info Ring to find the interrupt cause and handles it accordingly */
+static inline void
+acc100_vf_interrupt_handler(struct rte_bbdev *dev)
+{
+ struct acc100_device *acc100_dev = dev->data->dev_private;
+ volatile union acc100_info_ring_data *ring_data;
+ struct acc100_deq_intr_details deq_intr_det;
+
+ ring_data = acc100_dev->info_ring + (acc100_dev->info_ring_head &
+ ACC100_INFO_RING_MASK);
+
+ while (ring_data->valid) {
+
+ rte_bbdev_log_debug(
+ "ACC100 VF Interrupt received, Info Ring data: 0x%x",
+ ring_data->val);
+
+ switch (ring_data->int_nb) {
+ case ACC100_VF_INT_DMA_DL_DESC_IRQ:
+ case ACC100_VF_INT_DMA_UL_DESC_IRQ:
+ case ACC100_VF_INT_DMA_UL5G_DESC_IRQ:
+ case ACC100_VF_INT_DMA_DL5G_DESC_IRQ:
+ /* VFs are not aware of their vf_id - it's set to 0 in
+ * queue structures.
+ */
+ ring_data->vf_id = 0;
+ deq_intr_det.queue_id = get_queue_id_from_ring_info(
+ dev->data, *ring_data);
+ if (deq_intr_det.queue_id == UINT16_MAX) {
+ rte_bbdev_log(ERR,
+ "Couldn't find queue: aq_id: %u, qg_id: %u",
+ ring_data->aq_id,
+ ring_data->qg_id);
+ return;
+ }
+ rte_bbdev_pmd_callback_process(dev,
+ RTE_BBDEV_EVENT_DEQUEUE, &deq_intr_det);
+ break;
+ default:
+ rte_bbdev_pmd_callback_process(dev,
+ RTE_BBDEV_EVENT_ERROR, NULL);
+ break;
+ }
+
+ /* Initialize Info Ring entry and move forward */
+ ring_data->valid = 0;
+ ++acc100_dev->info_ring_head;
+ ring_data = acc100_dev->info_ring + (acc100_dev->info_ring_head
+ & ACC100_INFO_RING_MASK);
+ }
+}
+
+/* Interrupt handler triggered by ACC100 dev for handling specific interrupt */
+static void
+acc100_dev_interrupt_handler(void *cb_arg)
+{
+ struct rte_bbdev *dev = cb_arg;
+ struct acc100_device *acc100_dev = dev->data->dev_private;
+
+ /* Read info ring */
+ if (acc100_dev->pf_device)
+ acc100_pf_interrupt_handler(dev);
+ else
+ acc100_vf_interrupt_handler(dev);
+}
+
+/* Allocate and setup inforing */
+static int
+allocate_info_ring(struct rte_bbdev *dev)
+{
+ struct acc100_device *d = dev->data->dev_private;
+ const struct acc100_registry_addr *reg_addr;
+ rte_iova_t info_ring_iova;
+ uint32_t phys_low, phys_high;
+
+ if (d->info_ring != NULL)
+ return 0; /* Already configured */
+
+ /* Choose correct registry addresses for the device type */
+ if (d->pf_device)
+ reg_addr = &pf_reg_addr;
+ else
+ reg_addr = &vf_reg_addr;
+ /* Allocate InfoRing */
+ d->info_ring = rte_zmalloc_socket("Info Ring",
+ ACC100_INFO_RING_NUM_ENTRIES *
+ sizeof(*d->info_ring), RTE_CACHE_LINE_SIZE,
+ dev->data->socket_id);
+ if (d->info_ring == NULL) {
+ rte_bbdev_log(ERR,
+ "Failed to allocate Info Ring for %s:%u",
+ dev->device->driver->name,
+ dev->data->dev_id);
+ return -ENOMEM;
+ }
+ info_ring_iova = rte_malloc_virt2iova(d->info_ring);
+
+ /* Setup Info Ring */
+ phys_high = (uint32_t)(info_ring_iova >> 32);
+ phys_low = (uint32_t)(info_ring_iova);
+ acc100_reg_write(d, reg_addr->info_ring_hi, phys_high);
+ acc100_reg_write(d, reg_addr->info_ring_lo, phys_low);
+ acc100_reg_write(d, reg_addr->info_ring_en, ACC100_REG_IRQ_EN_ALL);
+ d->info_ring_head = (acc100_reg_read(d, reg_addr->info_ring_ptr) &
+ 0xFFF) / sizeof(union acc100_info_ring_data);
+ return 0;
+}
+
+
/* Allocate 64MB memory used for all software rings */
static int
acc100_setup_queues(struct rte_bbdev *dev, uint16_t num_queues, int socket_id)
{
- uint32_t phys_low, phys_high, payload;
+ uint32_t phys_low, phys_high, value;
struct acc100_device *d = dev->data->dev_private;
const struct acc100_registry_addr *reg_addr;
+ int ret;
if (d->pf_device && !d->acc100_conf.pf_mode_en) {
rte_bbdev_log(NOTICE,
* Configure Ring Size to the max queue ring size
* (used for wrapping purpose)
*/
- payload = log2_basic(d->sw_ring_size / 64);
- acc100_reg_write(d, reg_addr->ring_size, payload);
+ value = log2_basic(d->sw_ring_size / 64);
+ acc100_reg_write(d, reg_addr->ring_size, value);
/* Configure tail pointer for use when SDONE enabled */
d->tail_ptrs = rte_zmalloc_socket(
acc100_reg_write(d, reg_addr->tail_ptrs_dl4g_hi, phys_high);
acc100_reg_write(d, reg_addr->tail_ptrs_dl4g_lo, phys_low);
+ ret = allocate_info_ring(dev);
+ if (ret < 0) {
+ rte_bbdev_log(ERR, "Failed to allocate info_ring for %s:%u",
+ dev->device->driver->name,
+ dev->data->dev_id);
+ /* Continue */
+ }
+
d->harq_layout = rte_zmalloc_socket("HARQ Layout",
ACC100_HARQ_LAYOUT * sizeof(*d->harq_layout),
RTE_CACHE_LINE_SIZE, dev->data->socket_id);
return 0;
}
+static int
+acc100_intr_enable(struct rte_bbdev *dev)
+{
+ int ret;
+ struct acc100_device *d = dev->data->dev_private;
+
+ /* Only MSI are currently supported */
+ if (dev->intr_handle->type == RTE_INTR_HANDLE_VFIO_MSI ||
+ dev->intr_handle->type == RTE_INTR_HANDLE_UIO) {
+
+ ret = allocate_info_ring(dev);
+ if (ret < 0) {
+ rte_bbdev_log(ERR,
+ "Couldn't allocate info ring for device: %s",
+ dev->data->name);
+ return ret;
+ }
+
+ ret = rte_intr_enable(dev->intr_handle);
+ if (ret < 0) {
+ rte_bbdev_log(ERR,
+ "Couldn't enable interrupts for device: %s",
+ dev->data->name);
+ rte_free(d->info_ring);
+ return ret;
+ }
+ ret = rte_intr_callback_register(dev->intr_handle,
+ acc100_dev_interrupt_handler, dev);
+ if (ret < 0) {
+ rte_bbdev_log(ERR,
+ "Couldn't register interrupt callback for device: %s",
+ dev->data->name);
+ rte_free(d->info_ring);
+ return ret;
+ }
+
+ return 0;
+ }
+
+ rte_bbdev_log(ERR, "ACC100 (%s) supports only VFIO MSI interrupts",
+ dev->data->name);
+ return -ENOTSUP;
+}
+
/* Free memory used for software rings */
static int
acc100_dev_close(struct rte_bbdev *dev)
{
struct acc100_device *d = dev->data->dev_private;
+ acc100_check_ir(d);
if (d->sw_rings_base != NULL) {
rte_free(d->tail_ptrs);
+ rte_free(d->info_ring);
rte_free(d->sw_rings_base);
d->sw_rings_base = NULL;
}
RTE_BBDEV_TURBO_CRC_TYPE_24B |
RTE_BBDEV_TURBO_HALF_ITERATION_EVEN |
RTE_BBDEV_TURBO_EARLY_TERMINATION |
+ RTE_BBDEV_TURBO_DEC_INTERRUPTS |
RTE_BBDEV_TURBO_NEG_LLR_1_BIT_IN |
RTE_BBDEV_TURBO_MAP_DEC |
RTE_BBDEV_TURBO_DEC_TB_CRC_24B_KEEP |
RTE_BBDEV_TURBO_CRC_24B_ATTACH |
RTE_BBDEV_TURBO_RV_INDEX_BYPASS |
RTE_BBDEV_TURBO_RATE_MATCH |
+ RTE_BBDEV_TURBO_ENC_INTERRUPTS |
RTE_BBDEV_TURBO_ENC_SCATTER_GATHER,
.num_buffers_src =
RTE_BBDEV_TURBO_MAX_CODE_BLOCKS,
.capability_flags =
RTE_BBDEV_LDPC_RATE_MATCH |
RTE_BBDEV_LDPC_CRC_24B_ATTACH |
- RTE_BBDEV_LDPC_INTERLEAVER_BYPASS,
+ RTE_BBDEV_LDPC_INTERLEAVER_BYPASS |
+ RTE_BBDEV_LDPC_ENC_INTERRUPTS,
.num_buffers_src =
RTE_BBDEV_LDPC_MAX_CODE_BLOCKS,
.num_buffers_dst =
RTE_BBDEV_LDPC_DECODE_BYPASS |
RTE_BBDEV_LDPC_DEC_SCATTER_GATHER |
RTE_BBDEV_LDPC_HARQ_6BIT_COMPRESSION |
- RTE_BBDEV_LDPC_LLR_COMPRESSION,
+ RTE_BBDEV_LDPC_LLR_COMPRESSION |
+ RTE_BBDEV_LDPC_DEC_INTERRUPTS,
.llr_size = 8,
.llr_decimals = 1,
.num_buffers_src =
#else
dev_info->harq_buffer_size = 0;
#endif
+ acc100_check_ir(d);
+}
+
+static int
+acc100_queue_intr_enable(struct rte_bbdev *dev, uint16_t queue_id)
+{
+ struct acc100_queue *q = dev->data->queues[queue_id].queue_private;
+
+ if (dev->intr_handle->type != RTE_INTR_HANDLE_VFIO_MSI &&
+ dev->intr_handle->type != RTE_INTR_HANDLE_UIO)
+ return -ENOTSUP;
+
+ q->irq_enable = 1;
+ return 0;
+}
+
+static int
+acc100_queue_intr_disable(struct rte_bbdev *dev, uint16_t queue_id)
+{
+ struct acc100_queue *q = dev->data->queues[queue_id].queue_private;
+
+ if (dev->intr_handle->type != RTE_INTR_HANDLE_VFIO_MSI &&
+ dev->intr_handle->type != RTE_INTR_HANDLE_UIO)
+ return -ENOTSUP;
+
+ q->irq_enable = 0;
+ return 0;
}
static const struct rte_bbdev_ops acc100_bbdev_ops = {
.setup_queues = acc100_setup_queues,
+ .intr_enable = acc100_intr_enable,
.close = acc100_dev_close,
.info_get = acc100_dev_info_get,
.queue_setup = acc100_queue_setup,
.queue_release = acc100_queue_release,
+ .queue_intr_enable = acc100_queue_intr_enable,
+ .queue_intr_disable = acc100_queue_intr_disable
};
/* ACC100 PCI PF address map */
}
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+/* Validates turbo encoder parameters */
+static inline int
+validate_enc_op(struct rte_bbdev_enc_op *op)
+{
+ struct rte_bbdev_op_turbo_enc *turbo_enc = &op->turbo_enc;
+ struct rte_bbdev_op_enc_turbo_cb_params *cb = NULL;
+ struct rte_bbdev_op_enc_turbo_tb_params *tb = NULL;
+ uint16_t kw, kw_neg, kw_pos;
+
+ if (op->mempool == NULL) {
+ rte_bbdev_log(ERR, "Invalid mempool pointer");
+ return -1;
+ }
+ if (turbo_enc->input.data == NULL) {
+ rte_bbdev_log(ERR, "Invalid input pointer");
+ return -1;
+ }
+ if (turbo_enc->output.data == NULL) {
+ rte_bbdev_log(ERR, "Invalid output pointer");
+ return -1;
+ }
+ if (turbo_enc->rv_index > 3) {
+ rte_bbdev_log(ERR,
+ "rv_index (%u) is out of range 0 <= value <= 3",
+ turbo_enc->rv_index);
+ return -1;
+ }
+ if (turbo_enc->code_block_mode != 0 &&
+ turbo_enc->code_block_mode != 1) {
+ rte_bbdev_log(ERR,
+ "code_block_mode (%u) is out of range 0 <= value <= 1",
+ turbo_enc->code_block_mode);
+ return -1;
+ }
+
+ if (turbo_enc->code_block_mode == 0) {
+ tb = &turbo_enc->tb_params;
+ if ((tb->k_neg < RTE_BBDEV_TURBO_MIN_CB_SIZE
+ || tb->k_neg > RTE_BBDEV_TURBO_MAX_CB_SIZE)
+ && tb->c_neg > 0) {
+ rte_bbdev_log(ERR,
+ "k_neg (%u) is out of range %u <= value <= %u",
+ tb->k_neg, RTE_BBDEV_TURBO_MIN_CB_SIZE,
+ RTE_BBDEV_TURBO_MAX_CB_SIZE);
+ return -1;
+ }
+ if (tb->k_pos < RTE_BBDEV_TURBO_MIN_CB_SIZE
+ || tb->k_pos > RTE_BBDEV_TURBO_MAX_CB_SIZE) {
+ rte_bbdev_log(ERR,
+ "k_pos (%u) is out of range %u <= value <= %u",
+ tb->k_pos, RTE_BBDEV_TURBO_MIN_CB_SIZE,
+ RTE_BBDEV_TURBO_MAX_CB_SIZE);
+ return -1;
+ }
+ if (tb->c_neg > (RTE_BBDEV_TURBO_MAX_CODE_BLOCKS - 1))
+ rte_bbdev_log(ERR,
+ "c_neg (%u) is out of range 0 <= value <= %u",
+ tb->c_neg,
+ RTE_BBDEV_TURBO_MAX_CODE_BLOCKS - 1);
+ if (tb->c < 1 || tb->c > RTE_BBDEV_TURBO_MAX_CODE_BLOCKS) {
+ rte_bbdev_log(ERR,
+ "c (%u) is out of range 1 <= value <= %u",
+ tb->c, RTE_BBDEV_TURBO_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_TURBO_MIN_CB_SIZE || (tb->ea % 2))
+ && tb->r < tb->cab) {
+ rte_bbdev_log(ERR,
+ "ea (%u) is less than %u or it is not even",
+ tb->ea, RTE_BBDEV_TURBO_MIN_CB_SIZE);
+ return -1;
+ }
+ if ((tb->eb < RTE_BBDEV_TURBO_MIN_CB_SIZE || (tb->eb % 2))
+ && tb->c > tb->cab) {
+ rte_bbdev_log(ERR,
+ "eb (%u) is less than %u or it is not even",
+ tb->eb, RTE_BBDEV_TURBO_MIN_CB_SIZE);
+ return -1;
+ }
+
+ kw_neg = 3 * RTE_ALIGN_CEIL(tb->k_neg + 4,
+ RTE_BBDEV_TURBO_C_SUBBLOCK);
+ if (tb->ncb_neg < tb->k_neg || tb->ncb_neg > kw_neg) {
+ rte_bbdev_log(ERR,
+ "ncb_neg (%u) is out of range (%u) k_neg <= value <= (%u) kw_neg",
+ tb->ncb_neg, tb->k_neg, kw_neg);
+ return -1;
+ }
+
+ kw_pos = 3 * RTE_ALIGN_CEIL(tb->k_pos + 4,
+ RTE_BBDEV_TURBO_C_SUBBLOCK);
+ if (tb->ncb_pos < tb->k_pos || tb->ncb_pos > kw_pos) {
+ rte_bbdev_log(ERR,
+ "ncb_pos (%u) is out of range (%u) k_pos <= value <= (%u) kw_pos",
+ tb->ncb_pos, tb->k_pos, kw_pos);
+ 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 = &turbo_enc->cb_params;
+ if (cb->k < RTE_BBDEV_TURBO_MIN_CB_SIZE
+ || cb->k > RTE_BBDEV_TURBO_MAX_CB_SIZE) {
+ rte_bbdev_log(ERR,
+ "k (%u) is out of range %u <= value <= %u",
+ cb->k, RTE_BBDEV_TURBO_MIN_CB_SIZE,
+ RTE_BBDEV_TURBO_MAX_CB_SIZE);
+ return -1;
+ }
+
+ if (cb->e < RTE_BBDEV_TURBO_MIN_CB_SIZE || (cb->e % 2)) {
+ rte_bbdev_log(ERR,
+ "e (%u) is less than %u or it is not even",
+ cb->e, RTE_BBDEV_TURBO_MIN_CB_SIZE);
+ return -1;
+ }
+
+ kw = RTE_ALIGN_CEIL(cb->k + 4, RTE_BBDEV_TURBO_C_SUBBLOCK) * 3;
+ if (cb->ncb < cb->k || cb->ncb > kw) {
+ rte_bbdev_log(ERR,
+ "ncb (%u) is out of range (%u) k <= value <= (%u) kw",
+ cb->ncb, cb->k, kw);
+ return -1;
+ }
+ }
+
+ return 0;
+}
+/* Validates LDPC encoder parameters */
+static inline int
+validate_ldpc_enc_op(struct rte_bbdev_enc_op *op)
+{
+ struct rte_bbdev_op_ldpc_enc *ldpc_enc = &op->ldpc_enc;
+
+ 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->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 ((ldpc_enc->basegraph > 2) || (ldpc_enc->basegraph == 0)) {
+ rte_bbdev_log(ERR,
+ "BG (%u) is out of range 1 <= value <= 2",
+ ldpc_enc->basegraph);
+ return -1;
+ }
+ if (ldpc_enc->rv_index > 3) {
+ rte_bbdev_log(ERR,
+ "rv_index (%u) is out of range 0 <= value <= 3",
+ ldpc_enc->rv_index);
+ return -1;
+ }
+ if (ldpc_enc->code_block_mode > 1) {
+ rte_bbdev_log(ERR,
+ "code_block_mode (%u) is out of range 0 <= value <= 1",
+ ldpc_enc->code_block_mode);
+ return -1;
+ }
+ int K = (ldpc_enc->basegraph == 1 ? 22 : 10) * ldpc_enc->z_c;
+ if (ldpc_enc->n_filler >= K) {
+ rte_bbdev_log(ERR,
+ "K and F are not compatible %u %u",
+ K, ldpc_enc->n_filler);
+ return -1;
+ }
+ return 0;
+}
+
+/* Validates LDPC decoder parameters */
+static inline int
+validate_ldpc_dec_op(struct rte_bbdev_dec_op *op)
+{
+ struct rte_bbdev_op_ldpc_dec *ldpc_dec = &op->ldpc_dec;
+
+ if (op->mempool == NULL) {
+ rte_bbdev_log(ERR, "Invalid mempool pointer");
+ return -1;
+ }
+ if ((ldpc_dec->basegraph > 2) || (ldpc_dec->basegraph == 0)) {
+ rte_bbdev_log(ERR,
+ "BG (%u) is out of range 1 <= value <= 2",
+ ldpc_dec->basegraph);
+ 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->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->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;
+ }
+ int K = (ldpc_dec->basegraph == 1 ? 22 : 10) * ldpc_dec->z_c;
+ if (ldpc_dec->n_filler >= K) {
+ rte_bbdev_log(ERR,
+ "K and F are not compatible %u %u",
+ K, ldpc_dec->n_filler);
+ return -1;
+ }
+ return 0;
+}
+#endif
+
/* Enqueue one encode operations for ACC100 device in CB mode */
static inline int
enqueue_enc_one_op_cb(struct acc100_queue *q, struct rte_bbdev_enc_op *op,
seg_total_left;
struct rte_mbuf *input, *output_head, *output;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ if (validate_enc_op(op) == -1) {
+ rte_bbdev_log(ERR, "Turbo encoder validation failed");
+ return -EINVAL;
+ }
+#endif
+
uint16_t desc_idx = ((q->sw_ring_head + total_enqueued_cbs)
& q->sw_ring_wrap_mask);
desc = q->ring_addr + desc_idx;
uint16_t in_length_in_bytes;
struct rte_bbdev_op_ldpc_enc *enc = &ops[0]->ldpc_enc;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ if (validate_ldpc_enc_op(ops[0]) == -1) {
+ rte_bbdev_log(ERR, "LDPC encoder validation failed");
+ return -EINVAL;
+ }
+#endif
+
uint16_t desc_idx = ((q->sw_ring_head + total_enqueued_cbs)
& q->sw_ring_wrap_mask);
desc = q->ring_addr + desc_idx;
seg_total_left;
struct rte_mbuf *input, *output_head, *output;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ if (validate_ldpc_enc_op(op) == -1) {
+ rte_bbdev_log(ERR, "LDPC encoder validation failed");
+ return -EINVAL;
+ }
+#endif
+
uint16_t desc_idx = ((q->sw_ring_head + total_enqueued_cbs)
& q->sw_ring_wrap_mask);
desc = q->ring_addr + desc_idx;
struct rte_mbuf *input, *output_head, *output;
uint16_t current_enqueued_cbs = 0;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ if (validate_enc_op(op) == -1) {
+ rte_bbdev_log(ERR, "Turbo encoder validation failed");
+ return -EINVAL;
+ }
+#endif
+
uint16_t desc_idx = ((q->sw_ring_head + total_enqueued_cbs)
& q->sw_ring_wrap_mask);
desc = q->ring_addr + desc_idx;
r++;
}
- if (unlikely(desc == NULL))
- return current_enqueued_cbs;
-
#ifdef RTE_LIBRTE_BBDEV_DEBUG
if (check_mbuf_total_left(mbuf_total_left) != 0)
return -EINVAL;
return current_enqueued_cbs;
}
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+/* Validates turbo decoder parameters */
+static inline int
+validate_dec_op(struct rte_bbdev_dec_op *op)
+{
+ struct rte_bbdev_op_turbo_dec *turbo_dec = &op->turbo_dec;
+ struct rte_bbdev_op_dec_turbo_cb_params *cb = NULL;
+ struct rte_bbdev_op_dec_turbo_tb_params *tb = NULL;
+
+ if (op->mempool == NULL) {
+ rte_bbdev_log(ERR, "Invalid mempool pointer");
+ return -1;
+ }
+ if (turbo_dec->input.data == NULL) {
+ rte_bbdev_log(ERR, "Invalid input pointer");
+ return -1;
+ }
+ if (turbo_dec->hard_output.data == NULL) {
+ rte_bbdev_log(ERR, "Invalid hard_output pointer");
+ return -1;
+ }
+ if (check_bit(turbo_dec->op_flags, RTE_BBDEV_TURBO_SOFT_OUTPUT) &&
+ turbo_dec->soft_output.data == NULL) {
+ rte_bbdev_log(ERR, "Invalid soft_output pointer");
+ return -1;
+ }
+ if (turbo_dec->rv_index > 3) {
+ rte_bbdev_log(ERR,
+ "rv_index (%u) is out of range 0 <= value <= 3",
+ turbo_dec->rv_index);
+ return -1;
+ }
+ if (turbo_dec->iter_min < 1) {
+ rte_bbdev_log(ERR,
+ "iter_min (%u) is less than 1",
+ turbo_dec->iter_min);
+ return -1;
+ }
+ if (turbo_dec->iter_max <= 2) {
+ rte_bbdev_log(ERR,
+ "iter_max (%u) is less than or equal to 2",
+ turbo_dec->iter_max);
+ return -1;
+ }
+ if (turbo_dec->iter_min > turbo_dec->iter_max) {
+ rte_bbdev_log(ERR,
+ "iter_min (%u) is greater than iter_max (%u)",
+ turbo_dec->iter_min, turbo_dec->iter_max);
+ return -1;
+ }
+ if (turbo_dec->code_block_mode != 0 &&
+ turbo_dec->code_block_mode != 1) {
+ rte_bbdev_log(ERR,
+ "code_block_mode (%u) is out of range 0 <= value <= 1",
+ turbo_dec->code_block_mode);
+ return -1;
+ }
+
+ if (turbo_dec->code_block_mode == 0) {
+ tb = &turbo_dec->tb_params;
+ if ((tb->k_neg < RTE_BBDEV_TURBO_MIN_CB_SIZE
+ || tb->k_neg > RTE_BBDEV_TURBO_MAX_CB_SIZE)
+ && tb->c_neg > 0) {
+ rte_bbdev_log(ERR,
+ "k_neg (%u) is out of range %u <= value <= %u",
+ tb->k_neg, RTE_BBDEV_TURBO_MIN_CB_SIZE,
+ RTE_BBDEV_TURBO_MAX_CB_SIZE);
+ return -1;
+ }
+ if ((tb->k_pos < RTE_BBDEV_TURBO_MIN_CB_SIZE
+ || tb->k_pos > RTE_BBDEV_TURBO_MAX_CB_SIZE)
+ && tb->c > tb->c_neg) {
+ rte_bbdev_log(ERR,
+ "k_pos (%u) is out of range %u <= value <= %u",
+ tb->k_pos, RTE_BBDEV_TURBO_MIN_CB_SIZE,
+ RTE_BBDEV_TURBO_MAX_CB_SIZE);
+ return -1;
+ }
+ if (tb->c_neg > (RTE_BBDEV_TURBO_MAX_CODE_BLOCKS - 1))
+ rte_bbdev_log(ERR,
+ "c_neg (%u) is out of range 0 <= value <= %u",
+ tb->c_neg,
+ RTE_BBDEV_TURBO_MAX_CODE_BLOCKS - 1);
+ if (tb->c < 1 || tb->c > RTE_BBDEV_TURBO_MAX_CODE_BLOCKS) {
+ rte_bbdev_log(ERR,
+ "c (%u) is out of range 1 <= value <= %u",
+ tb->c, RTE_BBDEV_TURBO_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 (check_bit(turbo_dec->op_flags, RTE_BBDEV_TURBO_EQUALIZER) &&
+ (tb->ea < RTE_BBDEV_TURBO_MIN_CB_SIZE
+ || (tb->ea % 2))
+ && tb->cab > 0) {
+ rte_bbdev_log(ERR,
+ "ea (%u) is less than %u or it is not even",
+ tb->ea, RTE_BBDEV_TURBO_MIN_CB_SIZE);
+ return -1;
+ }
+ if (check_bit(turbo_dec->op_flags, RTE_BBDEV_TURBO_EQUALIZER) &&
+ (tb->eb < RTE_BBDEV_TURBO_MIN_CB_SIZE
+ || (tb->eb % 2))
+ && tb->c > tb->cab) {
+ rte_bbdev_log(ERR,
+ "eb (%u) is less than %u or it is not even",
+ tb->eb, RTE_BBDEV_TURBO_MIN_CB_SIZE);
+ }
+ } else {
+ cb = &turbo_dec->cb_params;
+ if (cb->k < RTE_BBDEV_TURBO_MIN_CB_SIZE
+ || cb->k > RTE_BBDEV_TURBO_MAX_CB_SIZE) {
+ rte_bbdev_log(ERR,
+ "k (%u) is out of range %u <= value <= %u",
+ cb->k, RTE_BBDEV_TURBO_MIN_CB_SIZE,
+ RTE_BBDEV_TURBO_MAX_CB_SIZE);
+ return -1;
+ }
+ if (check_bit(turbo_dec->op_flags, RTE_BBDEV_TURBO_EQUALIZER) &&
+ (cb->e < RTE_BBDEV_TURBO_MIN_CB_SIZE ||
+ (cb->e % 2))) {
+ rte_bbdev_log(ERR,
+ "e (%u) is less than %u or it is not even",
+ cb->e, RTE_BBDEV_TURBO_MIN_CB_SIZE);
+ return -1;
+ }
+ }
+
+ return 0;
+}
+#endif
+
/** Enqueue one decode operations for ACC100 device in CB mode */
static inline int
enqueue_dec_one_op_cb(struct acc100_queue *q, struct rte_bbdev_dec_op *op,
struct rte_mbuf *input, *h_output_head, *h_output,
*s_output_head, *s_output;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ if (validate_dec_op(op) == -1) {
+ rte_bbdev_log(ERR, "Turbo decoder validation failed");
+ return -EINVAL;
+ }
+#endif
+
uint16_t desc_idx = ((q->sw_ring_head + total_enqueued_cbs)
& q->sw_ring_wrap_mask);
desc = q->ring_addr + desc_idx;
return ret;
}
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ if (validate_ldpc_dec_op(op) == -1) {
+ rte_bbdev_log(ERR, "LDPC decoder validation failed");
+ return -EINVAL;
+ }
+#endif
union acc100_dma_desc *desc;
uint16_t desc_idx = ((q->sw_ring_head + total_enqueued_cbs)
& q->sw_ring_wrap_mask);
struct rte_mbuf *input, *h_output_head, *h_output;
uint16_t current_enqueued_cbs = 0;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ if (validate_ldpc_dec_op(op) == -1) {
+ rte_bbdev_log(ERR, "LDPC decoder validation failed");
+ return -EINVAL;
+ }
+#endif
+
uint16_t desc_idx = ((q->sw_ring_head + total_enqueued_cbs)
& q->sw_ring_wrap_mask);
desc = q->ring_addr + desc_idx;
r++;
}
- if (unlikely(desc == NULL))
- return current_enqueued_cbs;
-
#ifdef RTE_LIBRTE_BBDEV_DEBUG
if (check_mbuf_total_left(mbuf_total_left) != 0)
return -EINVAL;
*s_output_head, *s_output;
uint16_t current_enqueued_cbs = 0;
+#ifdef RTE_LIBRTE_BBDEV_DEBUG
+ /* Validate op structure */
+ if (validate_dec_op(op) == -1) {
+ rte_bbdev_log(ERR, "Turbo decoder validation failed");
+ return -EINVAL;
+ }
+#endif
+
uint16_t desc_idx = ((q->sw_ring_head + total_enqueued_cbs)
& q->sw_ring_wrap_mask);
desc = q->ring_addr + desc_idx;
r++;
}
- if (unlikely(desc == NULL))
- return current_enqueued_cbs;
-
#ifdef RTE_LIBRTE_BBDEV_DEBUG
if (check_mbuf_total_left(mbuf_total_left) != 0)
return -EINVAL;
? (1 << RTE_BBDEV_DATA_ERROR) : 0);
op->status |= ((rsp.dma_err) ? (1 << RTE_BBDEV_DRV_ERROR) : 0);
op->status |= ((rsp.fcw_err) ? (1 << RTE_BBDEV_DRV_ERROR) : 0);
- if (op->status != 0)
+ if (op->status != 0) {
q_data->queue_stats.dequeue_err_count++;
+ acc100_check_ir(q->d);
+ }
/* CRC invalid if error exists */
if (!op->status)
op->status |= 1 << RTE_BBDEV_SYNDROME_ERROR;
op->ldpc_dec.iter_count = (uint8_t) rsp.iter_cnt;
+ if (op->status & (1 << RTE_BBDEV_DRV_ERROR))
+ acc100_check_ir(q->d);
+
/* Check if this is the last desc in batch (Atomic Queue) */
if (desc->req.last_desc_in_batch) {
(*aq_dequeued)++;
RTE_PMD_REGISTER_PCI_TABLE(ACC100PF_DRIVER_NAME, pci_id_acc100_pf_map);
RTE_PMD_REGISTER_PCI(ACC100VF_DRIVER_NAME, acc100_pci_vf_driver);
RTE_PMD_REGISTER_PCI_TABLE(ACC100VF_DRIVER_NAME, pci_id_acc100_vf_map);
+
+/*
+ * Workaround implementation to fix the power on status of some 5GUL engines
+ * This requires DMA permission if ported outside DPDK
+ * It consists in resolving the state of these engines by running a
+ * dummy operation and resetting the engines to ensure state are reliably
+ * defined.
+ */
+static void
+poweron_cleanup(struct rte_bbdev *bbdev, struct acc100_device *d,
+ struct rte_acc100_conf *conf)
+{
+ int i, template_idx, qg_idx;
+ uint32_t address, status, value;
+ printf("Need to clear power-on 5GUL status in internal memory\n");
+ /* Reset LDPC Cores */
+ for (i = 0; i < ACC100_ENGINES_MAX; i++)
+ acc100_reg_write(d, HWPfFecUl5gCntrlReg +
+ ACC100_ENGINE_OFFSET * i, ACC100_RESET_HI);
+ usleep(ACC100_LONG_WAIT);
+ for (i = 0; i < ACC100_ENGINES_MAX; i++)
+ acc100_reg_write(d, HWPfFecUl5gCntrlReg +
+ ACC100_ENGINE_OFFSET * i, ACC100_RESET_LO);
+ usleep(ACC100_LONG_WAIT);
+ /* Prepare dummy workload */
+ alloc_2x64mb_sw_rings_mem(bbdev, d, 0);
+ /* Set base addresses */
+ uint32_t phys_high = (uint32_t)(d->sw_rings_iova >> 32);
+ uint32_t phys_low = (uint32_t)(d->sw_rings_iova &
+ ~(ACC100_SIZE_64MBYTE-1));
+ acc100_reg_write(d, HWPfDmaFec5GulDescBaseHiRegVf, phys_high);
+ acc100_reg_write(d, HWPfDmaFec5GulDescBaseLoRegVf, phys_low);
+
+ /* Descriptor for a dummy 5GUL code block processing*/
+ union acc100_dma_desc *desc = NULL;
+ desc = d->sw_rings;
+ desc->req.data_ptrs[0].address = d->sw_rings_iova +
+ ACC100_DESC_FCW_OFFSET;
+ desc->req.data_ptrs[0].blen = ACC100_FCW_LD_BLEN;
+ desc->req.data_ptrs[0].blkid = ACC100_DMA_BLKID_FCW;
+ desc->req.data_ptrs[0].last = 0;
+ desc->req.data_ptrs[0].dma_ext = 0;
+ desc->req.data_ptrs[1].address = d->sw_rings_iova + 512;
+ desc->req.data_ptrs[1].blkid = ACC100_DMA_BLKID_IN;
+ desc->req.data_ptrs[1].last = 1;
+ desc->req.data_ptrs[1].dma_ext = 0;
+ desc->req.data_ptrs[1].blen = 44;
+ desc->req.data_ptrs[2].address = d->sw_rings_iova + 1024;
+ desc->req.data_ptrs[2].blkid = ACC100_DMA_BLKID_OUT_ENC;
+ desc->req.data_ptrs[2].last = 1;
+ desc->req.data_ptrs[2].dma_ext = 0;
+ desc->req.data_ptrs[2].blen = 5;
+ /* Dummy FCW */
+ desc->req.fcw_ld.FCWversion = ACC100_FCW_VER;
+ desc->req.fcw_ld.qm = 1;
+ desc->req.fcw_ld.nfiller = 30;
+ desc->req.fcw_ld.BG = 2 - 1;
+ desc->req.fcw_ld.Zc = 7;
+ desc->req.fcw_ld.ncb = 350;
+ desc->req.fcw_ld.rm_e = 4;
+ desc->req.fcw_ld.itmax = 10;
+ desc->req.fcw_ld.gain_i = 1;
+ desc->req.fcw_ld.gain_h = 1;
+
+ int engines_to_restart[ACC100_SIG_UL_5G_LAST + 1] = {0};
+ int num_failed_engine = 0;
+ /* Detect engines in undefined state */
+ for (template_idx = ACC100_SIG_UL_5G;
+ template_idx <= ACC100_SIG_UL_5G_LAST;
+ template_idx++) {
+ /* Check engine power-on status */
+ address = HwPfFecUl5gIbDebugReg +
+ ACC100_ENGINE_OFFSET * template_idx;
+ status = (acc100_reg_read(d, address) >> 4) & 0xF;
+ if (status == 0) {
+ engines_to_restart[num_failed_engine] = template_idx;
+ num_failed_engine++;
+ }
+ }
+
+ int numQqsAcc = conf->q_ul_5g.num_qgroups;
+ int numQgs = conf->q_ul_5g.num_qgroups;
+ value = 0;
+ for (qg_idx = numQqsAcc; qg_idx < (numQgs + numQqsAcc); qg_idx++)
+ value |= (1 << qg_idx);
+ /* Force each engine which is in unspecified state */
+ for (i = 0; i < num_failed_engine; i++) {
+ int failed_engine = engines_to_restart[i];
+ printf("Force engine %d\n", failed_engine);
+ for (template_idx = ACC100_SIG_UL_5G;
+ template_idx <= ACC100_SIG_UL_5G_LAST;
+ template_idx++) {
+ address = HWPfQmgrGrpTmplateReg4Indx
+ + ACC100_BYTES_IN_WORD * template_idx;
+ if (template_idx == failed_engine)
+ acc100_reg_write(d, address, value);
+ else
+ acc100_reg_write(d, address, 0);
+ }
+ /* Reset descriptor header */
+ desc->req.word0 = ACC100_DMA_DESC_TYPE;
+ desc->req.word1 = 0;
+ desc->req.word2 = 0;
+ desc->req.word3 = 0;
+ desc->req.numCBs = 1;
+ desc->req.m2dlen = 2;
+ desc->req.d2mlen = 1;
+ /* Enqueue the code block for processing */
+ union acc100_enqueue_reg_fmt enq_req;
+ enq_req.val = 0;
+ enq_req.addr_offset = ACC100_DESC_OFFSET;
+ enq_req.num_elem = 1;
+ enq_req.req_elem_addr = 0;
+ rte_wmb();
+ acc100_reg_write(d, HWPfQmgrIngressAq + 0x100, enq_req.val);
+ usleep(ACC100_LONG_WAIT * 100);
+ if (desc->req.word0 != 2)
+ printf("DMA Response %#"PRIx32"\n", desc->req.word0);
+ }
+
+ /* Reset LDPC Cores */
+ for (i = 0; i < ACC100_ENGINES_MAX; i++)
+ acc100_reg_write(d, HWPfFecUl5gCntrlReg +
+ ACC100_ENGINE_OFFSET * i,
+ ACC100_RESET_HI);
+ usleep(ACC100_LONG_WAIT);
+ for (i = 0; i < ACC100_ENGINES_MAX; i++)
+ acc100_reg_write(d, HWPfFecUl5gCntrlReg +
+ ACC100_ENGINE_OFFSET * i,
+ ACC100_RESET_LO);
+ usleep(ACC100_LONG_WAIT);
+ acc100_reg_write(d, HWPfHi5GHardResetReg, ACC100_RESET_HARD);
+ usleep(ACC100_LONG_WAIT);
+ int numEngines = 0;
+ /* Check engine power-on status again */
+ for (template_idx = ACC100_SIG_UL_5G;
+ template_idx <= ACC100_SIG_UL_5G_LAST;
+ template_idx++) {
+ address = HwPfFecUl5gIbDebugReg +
+ ACC100_ENGINE_OFFSET * template_idx;
+ status = (acc100_reg_read(d, address) >> 4) & 0xF;
+ address = HWPfQmgrGrpTmplateReg4Indx
+ + ACC100_BYTES_IN_WORD * template_idx;
+ if (status == 1) {
+ acc100_reg_write(d, address, value);
+ numEngines++;
+ } else
+ acc100_reg_write(d, address, 0);
+ }
+ printf("Number of 5GUL engines %d\n", numEngines);
+
+ if (d->sw_rings_base != NULL)
+ rte_free(d->sw_rings_base);
+ usleep(ACC100_LONG_WAIT);
+}
+
+/* Initial configuration of a ACC100 device prior to running configure() */
+int
+rte_acc100_configure(const char *dev_name, struct rte_acc100_conf *conf)
+{
+ rte_bbdev_log(INFO, "rte_acc100_configure");
+ uint32_t value, address, status;
+ int qg_idx, template_idx, vf_idx, acc, i;
+ struct rte_bbdev *bbdev = rte_bbdev_get_named_dev(dev_name);
+
+ /* Compile time checks */
+ RTE_BUILD_BUG_ON(sizeof(struct acc100_dma_req_desc) != 256);
+ RTE_BUILD_BUG_ON(sizeof(union acc100_dma_desc) != 256);
+ RTE_BUILD_BUG_ON(sizeof(struct acc100_fcw_td) != 24);
+ RTE_BUILD_BUG_ON(sizeof(struct acc100_fcw_te) != 32);
+
+ if (bbdev == NULL) {
+ rte_bbdev_log(ERR,
+ "Invalid dev_name (%s), or device is not yet initialised",
+ dev_name);
+ return -ENODEV;
+ }
+ struct acc100_device *d = bbdev->data->dev_private;
+
+ /* Store configuration */
+ rte_memcpy(&d->acc100_conf, conf, sizeof(d->acc100_conf));
+
+ /* PCIe Bridge configuration */
+ acc100_reg_write(d, HwPfPcieGpexBridgeControl, ACC100_CFG_PCI_BRIDGE);
+ for (i = 1; i < ACC100_GPEX_AXIMAP_NUM; i++)
+ acc100_reg_write(d,
+ HwPfPcieGpexAxiAddrMappingWindowPexBaseHigh
+ + i * 16, 0);
+
+ /* Prevent blocking AXI read on BRESP for AXI Write */
+ address = HwPfPcieGpexAxiPioControl;
+ value = ACC100_CFG_PCI_AXI;
+ acc100_reg_write(d, address, value);
+
+ /* 5GDL PLL phase shift */
+ acc100_reg_write(d, HWPfChaDl5gPllPhshft0, 0x1);
+
+ /* Explicitly releasing AXI as this may be stopped after PF FLR/BME */
+ address = HWPfDmaAxiControl;
+ value = 1;
+ acc100_reg_write(d, address, value);
+
+ /* DDR Configuration */
+ address = HWPfDdrBcTim6;
+ value = acc100_reg_read(d, address);
+ value &= 0xFFFFFFFB; /* Bit 2 */
+#ifdef ACC100_DDR_ECC_ENABLE
+ value |= 0x4;
+#endif
+ acc100_reg_write(d, address, value);
+ address = HWPfDdrPhyDqsCountNum;
+#ifdef ACC100_DDR_ECC_ENABLE
+ value = 9;
+#else
+ value = 8;
+#endif
+ acc100_reg_write(d, address, value);
+
+ /* Set default descriptor signature */
+ address = HWPfDmaDescriptorSignatuture;
+ value = 0;
+ acc100_reg_write(d, address, value);
+
+ /* Enable the Error Detection in DMA */
+ value = ACC100_CFG_DMA_ERROR;
+ address = HWPfDmaErrorDetectionEn;
+ acc100_reg_write(d, address, value);
+
+ /* AXI Cache configuration */
+ value = ACC100_CFG_AXI_CACHE;
+ address = HWPfDmaAxcacheReg;
+ acc100_reg_write(d, address, value);
+
+ /* Default DMA Configuration (Qmgr Enabled) */
+ address = HWPfDmaConfig0Reg;
+ value = 0;
+ acc100_reg_write(d, address, value);
+ address = HWPfDmaQmanen;
+ value = 0;
+ acc100_reg_write(d, address, value);
+
+ /* Default RLIM/ALEN configuration */
+ address = HWPfDmaConfig1Reg;
+ value = (1 << 31) + (23 << 8) + (1 << 6) + 7;
+ acc100_reg_write(d, address, value);
+
+ /* Configure DMA Qmanager addresses */
+ address = HWPfDmaQmgrAddrReg;
+ value = HWPfQmgrEgressQueuesTemplate;
+ acc100_reg_write(d, address, value);
+
+ /* ===== Qmgr Configuration ===== */
+ /* Configuration of the AQueue Depth QMGR_GRP_0_DEPTH_LOG2 for UL */
+ int totalQgs = conf->q_ul_4g.num_qgroups +
+ conf->q_ul_5g.num_qgroups +
+ conf->q_dl_4g.num_qgroups +
+ conf->q_dl_5g.num_qgroups;
+ for (qg_idx = 0; qg_idx < totalQgs; qg_idx++) {
+ address = HWPfQmgrDepthLog2Grp +
+ ACC100_BYTES_IN_WORD * qg_idx;
+ value = aqDepth(qg_idx, conf);
+ acc100_reg_write(d, address, value);
+ address = HWPfQmgrTholdGrp +
+ ACC100_BYTES_IN_WORD * qg_idx;
+ value = (1 << 16) + (1 << (aqDepth(qg_idx, conf) - 1));
+ acc100_reg_write(d, address, value);
+ }
+
+ /* Template Priority in incremental order */
+ for (template_idx = 0; template_idx < ACC100_NUM_TMPL;
+ template_idx++) {
+ address = HWPfQmgrGrpTmplateReg0Indx +
+ ACC100_BYTES_IN_WORD * (template_idx % 8);
+ value = ACC100_TMPL_PRI_0;
+ acc100_reg_write(d, address, value);
+ address = HWPfQmgrGrpTmplateReg1Indx +
+ ACC100_BYTES_IN_WORD * (template_idx % 8);
+ value = ACC100_TMPL_PRI_1;
+ acc100_reg_write(d, address, value);
+ address = HWPfQmgrGrpTmplateReg2indx +
+ ACC100_BYTES_IN_WORD * (template_idx % 8);
+ value = ACC100_TMPL_PRI_2;
+ acc100_reg_write(d, address, value);
+ address = HWPfQmgrGrpTmplateReg3Indx +
+ ACC100_BYTES_IN_WORD * (template_idx % 8);
+ value = ACC100_TMPL_PRI_3;
+ acc100_reg_write(d, address, value);
+ }
+
+ address = HWPfQmgrGrpPriority;
+ value = ACC100_CFG_QMGR_HI_P;
+ acc100_reg_write(d, address, value);
+
+ /* Template Configuration */
+ for (template_idx = 0; template_idx < ACC100_NUM_TMPL;
+ template_idx++) {
+ value = 0;
+ address = HWPfQmgrGrpTmplateReg4Indx
+ + ACC100_BYTES_IN_WORD * template_idx;
+ acc100_reg_write(d, address, value);
+ }
+ /* 4GUL */
+ int numQgs = conf->q_ul_4g.num_qgroups;
+ int numQqsAcc = 0;
+ value = 0;
+ for (qg_idx = numQqsAcc; qg_idx < (numQgs + numQqsAcc); qg_idx++)
+ value |= (1 << qg_idx);
+ for (template_idx = ACC100_SIG_UL_4G;
+ template_idx <= ACC100_SIG_UL_4G_LAST;
+ template_idx++) {
+ address = HWPfQmgrGrpTmplateReg4Indx
+ + ACC100_BYTES_IN_WORD * template_idx;
+ acc100_reg_write(d, address, value);
+ }
+ /* 5GUL */
+ numQqsAcc += numQgs;
+ numQgs = conf->q_ul_5g.num_qgroups;
+ value = 0;
+ int numEngines = 0;
+ for (qg_idx = numQqsAcc; qg_idx < (numQgs + numQqsAcc); qg_idx++)
+ value |= (1 << qg_idx);
+ for (template_idx = ACC100_SIG_UL_5G;
+ template_idx <= ACC100_SIG_UL_5G_LAST;
+ template_idx++) {
+ /* Check engine power-on status */
+ address = HwPfFecUl5gIbDebugReg +
+ ACC100_ENGINE_OFFSET * template_idx;
+ status = (acc100_reg_read(d, address) >> 4) & 0xF;
+ address = HWPfQmgrGrpTmplateReg4Indx
+ + ACC100_BYTES_IN_WORD * template_idx;
+ if (status == 1) {
+ acc100_reg_write(d, address, value);
+ numEngines++;
+ } else
+ acc100_reg_write(d, address, 0);
+#if RTE_ACC100_SINGLE_FEC == 1
+ value = 0;
+#endif
+ }
+ printf("Number of 5GUL engines %d\n", numEngines);
+ /* 4GDL */
+ numQqsAcc += numQgs;
+ numQgs = conf->q_dl_4g.num_qgroups;
+ value = 0;
+ for (qg_idx = numQqsAcc; qg_idx < (numQgs + numQqsAcc); qg_idx++)
+ value |= (1 << qg_idx);
+ for (template_idx = ACC100_SIG_DL_4G;
+ template_idx <= ACC100_SIG_DL_4G_LAST;
+ template_idx++) {
+ address = HWPfQmgrGrpTmplateReg4Indx
+ + ACC100_BYTES_IN_WORD * template_idx;
+ acc100_reg_write(d, address, value);
+#if RTE_ACC100_SINGLE_FEC == 1
+ value = 0;
+#endif
+ }
+ /* 5GDL */
+ numQqsAcc += numQgs;
+ numQgs = conf->q_dl_5g.num_qgroups;
+ value = 0;
+ for (qg_idx = numQqsAcc; qg_idx < (numQgs + numQqsAcc); qg_idx++)
+ value |= (1 << qg_idx);
+ for (template_idx = ACC100_SIG_DL_5G;
+ template_idx <= ACC100_SIG_DL_5G_LAST;
+ template_idx++) {
+ address = HWPfQmgrGrpTmplateReg4Indx
+ + ACC100_BYTES_IN_WORD * template_idx;
+ acc100_reg_write(d, address, value);
+#if RTE_ACC100_SINGLE_FEC == 1
+ value = 0;
+#endif
+ }
+
+ /* Queue Group Function mapping */
+ int qman_func_id[5] = {0, 2, 1, 3, 4};
+ address = HWPfQmgrGrpFunction0;
+ value = 0;
+ for (qg_idx = 0; qg_idx < 8; qg_idx++) {
+ acc = accFromQgid(qg_idx, conf);
+ value |= qman_func_id[acc]<<(qg_idx * 4);
+ }
+ acc100_reg_write(d, address, value);
+
+ /* Configuration of the Arbitration QGroup depth to 1 */
+ for (qg_idx = 0; qg_idx < totalQgs; qg_idx++) {
+ address = HWPfQmgrArbQDepthGrp +
+ ACC100_BYTES_IN_WORD * qg_idx;
+ value = 0;
+ acc100_reg_write(d, address, value);
+ }
+
+ /* Enabling AQueues through the Queue hierarchy*/
+ for (vf_idx = 0; vf_idx < ACC100_NUM_VFS; vf_idx++) {
+ for (qg_idx = 0; qg_idx < ACC100_NUM_QGRPS; qg_idx++) {
+ value = 0;
+ if (vf_idx < conf->num_vf_bundles &&
+ qg_idx < totalQgs)
+ value = (1 << aqNum(qg_idx, conf)) - 1;
+ address = HWPfQmgrAqEnableVf
+ + vf_idx * ACC100_BYTES_IN_WORD;
+ value += (qg_idx << 16);
+ acc100_reg_write(d, address, value);
+ }
+ }
+
+ /* This pointer to ARAM (256kB) is shifted by 2 (4B per register) */
+ uint32_t aram_address = 0;
+ for (qg_idx = 0; qg_idx < totalQgs; qg_idx++) {
+ for (vf_idx = 0; vf_idx < conf->num_vf_bundles; vf_idx++) {
+ address = HWPfQmgrVfBaseAddr + vf_idx
+ * ACC100_BYTES_IN_WORD + qg_idx
+ * ACC100_BYTES_IN_WORD * 64;
+ value = aram_address;
+ acc100_reg_write(d, address, value);
+ /* Offset ARAM Address for next memory bank
+ * - increment of 4B
+ */
+ aram_address += aqNum(qg_idx, conf) *
+ (1 << aqDepth(qg_idx, conf));
+ }
+ }
+
+ if (aram_address > ACC100_WORDS_IN_ARAM_SIZE) {
+ rte_bbdev_log(ERR, "ARAM Configuration not fitting %d %d\n",
+ aram_address, ACC100_WORDS_IN_ARAM_SIZE);
+ return -EINVAL;
+ }
+
+ /* ==== HI Configuration ==== */
+
+ /* Prevent Block on Transmit Error */
+ address = HWPfHiBlockTransmitOnErrorEn;
+ value = 0;
+ acc100_reg_write(d, address, value);
+ /* Prevents to drop MSI */
+ address = HWPfHiMsiDropEnableReg;
+ value = 0;
+ acc100_reg_write(d, address, value);
+ /* Set the PF Mode register */
+ address = HWPfHiPfMode;
+ value = (conf->pf_mode_en) ? ACC100_PF_VAL : 0;
+ acc100_reg_write(d, address, value);
+ /* Enable Error Detection in HW */
+ address = HWPfDmaErrorDetectionEn;
+ value = 0x3D7;
+ acc100_reg_write(d, address, value);
+
+ /* QoS overflow init */
+ value = 1;
+ address = HWPfQosmonAEvalOverflow0;
+ acc100_reg_write(d, address, value);
+ address = HWPfQosmonBEvalOverflow0;
+ acc100_reg_write(d, address, value);
+
+ /* HARQ DDR Configuration */
+ unsigned int ddrSizeInMb = 512; /* Fixed to 512 MB per VF for now */
+ for (vf_idx = 0; vf_idx < conf->num_vf_bundles; vf_idx++) {
+ address = HWPfDmaVfDdrBaseRw + vf_idx
+ * 0x10;
+ value = ((vf_idx * (ddrSizeInMb / 64)) << 16) +
+ (ddrSizeInMb - 1);
+ acc100_reg_write(d, address, value);
+ }
+ usleep(ACC100_LONG_WAIT);
+
+ /* Workaround in case some 5GUL engines are in an unexpected state */
+ if (numEngines < (ACC100_SIG_UL_5G_LAST + 1))
+ poweron_cleanup(bbdev, d, conf);
+
+ rte_bbdev_log_debug("PF Tip configuration complete for %s", dev_name);
+ return 0;
+}