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numam-dpdk/drivers/baseband/turbo_sw/bbdev_turbo_software.c
Nicolas Chautru 973320514f drivers/baseband: expose per operation type queues 
Add support in existing bbdev PMDs for the explicit number of queues
and priority for each operation type configured on the device.

Signed-off-by: Nicolas Chautru <nicolas.chautru@intel.com>
Acked-by: Maxime Coquelin <maxime.coquelin@redhat.com>
Acked-by: Hemant Agrawal <hemant.agrawal@nxp.com>
Acked-by: Akhil Goyal <gakhil@marvell.com>
2022-10-07 08:44:58 +02:00

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/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2017 Intel Corporation
*/
#include <stdlib.h>
#include <string.h>
#include <rte_common.h>
#include <bus_vdev_driver.h>
#include <rte_malloc.h>
#include <rte_ring.h>
#include <rte_kvargs.h>
#include <rte_cycles.h>
#include <rte_errno.h>
#include <rte_bbdev.h>
#include <rte_bbdev_pmd.h>
#include <rte_hexdump.h>
#include <rte_log.h>
#ifdef RTE_BBDEV_SDK_AVX2
#include <ipp.h>
#include <ipps.h>
#include <phy_turbo.h>
#include <phy_crc.h>
#include <phy_rate_match.h>
#endif
#ifdef RTE_BBDEV_SDK_AVX512
#include <bit_reverse.h>
#include <phy_ldpc_encoder_5gnr.h>
#include <phy_ldpc_decoder_5gnr.h>
#include <phy_LDPC_ratematch_5gnr.h>
#include <phy_rate_dematching_5gnr.h>
#endif
#define DRIVER_NAME baseband_turbo_sw
RTE_LOG_REGISTER_DEFAULT(bbdev_turbo_sw_logtype, NOTICE);
/* Helper macro for logging */
#define rte_bbdev_log(level, fmt, ...) \
rte_log(RTE_LOG_ ## level, bbdev_turbo_sw_logtype, fmt "\n", \
##__VA_ARGS__)
#define rte_bbdev_log_debug(fmt, ...) \
rte_bbdev_log(DEBUG, RTE_STR(__LINE__) ":%s() " fmt, __func__, \
##__VA_ARGS__)
#define DEINT_INPUT_BUF_SIZE (((RTE_BBDEV_TURBO_MAX_CB_SIZE >> 3) + 1) * 48)
#define DEINT_OUTPUT_BUF_SIZE (DEINT_INPUT_BUF_SIZE * 6)
#define ADAPTER_OUTPUT_BUF_SIZE ((RTE_BBDEV_TURBO_MAX_CB_SIZE + 4) * 48)
/* private data structure */
struct bbdev_private {
unsigned int max_nb_queues; /**< Max number of queues */
};
/* Initialisation params structure that can be used by Turbo SW driver */
struct turbo_sw_params {
int socket_id; /*< Turbo SW device socket */
uint16_t queues_num; /*< Turbo SW device queues number */
};
/* Acceptable params for Turbo SW devices */
#define TURBO_SW_MAX_NB_QUEUES_ARG "max_nb_queues"
#define TURBO_SW_SOCKET_ID_ARG "socket_id"
static const char * const turbo_sw_valid_params[] = {
TURBO_SW_MAX_NB_QUEUES_ARG,
TURBO_SW_SOCKET_ID_ARG
};
/* queue */
struct turbo_sw_queue {
/* Ring for processed (encoded/decoded) operations which are ready to
* be dequeued.
*/
struct rte_ring *processed_pkts;
/* Stores input for turbo encoder (used when CRC attachment is
* performed
*/
uint8_t *enc_in;
/* Stores output from turbo encoder */
uint8_t *enc_out;
/* Alpha gamma buf for bblib_turbo_decoder() function */
int8_t *ag;
/* Temp buf for bblib_turbo_decoder() function */
uint16_t *code_block;
/* Input buf for bblib_rate_dematching_lte() function */
uint8_t *deint_input;
/* Output buf for bblib_rate_dematching_lte() function */
uint8_t *deint_output;
/* Output buf for bblib_turbodec_adapter_lte() function */
uint8_t *adapter_output;
/* Operation type of this queue */
enum rte_bbdev_op_type type;
} __rte_cache_aligned;
#ifdef RTE_BBDEV_SDK_AVX2
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;
}
/* Calculate index based on Table 5.1.3-3 from TS34.212 */
static inline int32_t
compute_idx(uint16_t k)
{
int32_t result = 0;
if (k < RTE_BBDEV_TURBO_MIN_CB_SIZE || k > RTE_BBDEV_TURBO_MAX_CB_SIZE)
return -1;
if (k > 2048) {
if ((k - 2048) % 64 != 0)
result = -1;
result = 124 + (k - 2048) / 64;
} else if (k <= 512) {
if ((k - 40) % 8 != 0)
result = -1;
result = (k - 40) / 8 + 1;
} else if (k <= 1024) {
if ((k - 512) % 16 != 0)
result = -1;
result = 60 + (k - 512) / 16;
} else { /* 1024 < k <= 2048 */
if ((k - 1024) % 32 != 0)
result = -1;
result = 92 + (k - 1024) / 32;
}
return result;
}
#endif
/* Read flag value 0/1 from bitmap */
static inline bool
check_bit(uint32_t bitmap, uint32_t bitmask)
{
return bitmap & bitmask;
}
/* Get device info */
static void
info_get(struct rte_bbdev *dev, struct rte_bbdev_driver_info *dev_info)
{
struct bbdev_private *internals = dev->data->dev_private;
const struct rte_bbdev_op_cap *op_cap;
int num_op_type = 0;
static const struct rte_bbdev_op_cap bbdev_capabilities[] = {
#ifdef RTE_BBDEV_SDK_AVX2
{
.type = RTE_BBDEV_OP_TURBO_DEC,
.cap.turbo_dec = {
.capability_flags =
RTE_BBDEV_TURBO_SUBBLOCK_DEINTERLEAVE |
RTE_BBDEV_TURBO_POS_LLR_1_BIT_IN |
RTE_BBDEV_TURBO_NEG_LLR_1_BIT_IN |
RTE_BBDEV_TURBO_CRC_TYPE_24B |
RTE_BBDEV_TURBO_DEC_TB_CRC_24B_KEEP |
RTE_BBDEV_TURBO_EARLY_TERMINATION,
.max_llr_modulus = 16,
.num_buffers_src =
RTE_BBDEV_TURBO_MAX_CODE_BLOCKS,
.num_buffers_hard_out =
RTE_BBDEV_TURBO_MAX_CODE_BLOCKS,
.num_buffers_soft_out = 0,
}
},
{
.type = RTE_BBDEV_OP_TURBO_ENC,
.cap.turbo_enc = {
.capability_flags =
RTE_BBDEV_TURBO_CRC_24B_ATTACH |
RTE_BBDEV_TURBO_CRC_24A_ATTACH |
RTE_BBDEV_TURBO_RATE_MATCH |
RTE_BBDEV_TURBO_RV_INDEX_BYPASS,
.num_buffers_src =
RTE_BBDEV_TURBO_MAX_CODE_BLOCKS,
.num_buffers_dst =
RTE_BBDEV_TURBO_MAX_CODE_BLOCKS,
}
},
#endif
#ifdef RTE_BBDEV_SDK_AVX512
{
.type = RTE_BBDEV_OP_LDPC_ENC,
.cap.ldpc_enc = {
.capability_flags =
RTE_BBDEV_LDPC_RATE_MATCH |
RTE_BBDEV_LDPC_CRC_16_ATTACH |
RTE_BBDEV_LDPC_CRC_24A_ATTACH |
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_16_CHECK |
RTE_BBDEV_LDPC_CRC_TYPE_24B_CHECK |
RTE_BBDEV_LDPC_CRC_TYPE_24A_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,
.llr_size = 8,
.llr_decimals = 4,
.num_buffers_src =
RTE_BBDEV_LDPC_MAX_CODE_BLOCKS,
.num_buffers_hard_out =
RTE_BBDEV_LDPC_MAX_CODE_BLOCKS,
.num_buffers_soft_out = 0,
}
},
#endif
RTE_BBDEV_END_OF_CAPABILITIES_LIST()
};
static struct rte_bbdev_queue_conf default_queue_conf = {
.queue_size = RTE_BBDEV_QUEUE_SIZE_LIMIT,
};
#ifdef RTE_BBDEV_SDK_AVX2
static const enum rte_cpu_flag_t cpu_flag = RTE_CPUFLAG_SSE4_2;
dev_info->cpu_flag_reqs = &cpu_flag;
#else
dev_info->cpu_flag_reqs = NULL;
#endif
default_queue_conf.socket = dev->data->socket_id;
dev_info->driver_name = RTE_STR(DRIVER_NAME);
dev_info->max_num_queues = internals->max_nb_queues;
dev_info->queue_size_lim = RTE_BBDEV_QUEUE_SIZE_LIMIT;
dev_info->hardware_accelerated = false;
dev_info->max_dl_queue_priority = 0;
dev_info->max_ul_queue_priority = 0;
dev_info->default_queue_conf = default_queue_conf;
dev_info->capabilities = bbdev_capabilities;
dev_info->min_alignment = 64;
dev_info->harq_buffer_size = 0;
dev_info->data_endianness = RTE_LITTLE_ENDIAN;
dev_info->device_status = RTE_BBDEV_DEV_NOT_SUPPORTED;
op_cap = bbdev_capabilities;
for (; op_cap->type != RTE_BBDEV_OP_NONE; ++op_cap)
num_op_type++;
op_cap = bbdev_capabilities;
if (num_op_type > 0) {
int num_queue_per_type = dev_info->max_num_queues / num_op_type;
for (; op_cap->type != RTE_BBDEV_OP_NONE; ++op_cap)
dev_info->num_queues[op_cap->type] = num_queue_per_type;
}
rte_bbdev_log_debug("got device info from %u\n", dev->data->dev_id);
}
/* Release queue */
static int
q_release(struct rte_bbdev *dev, uint16_t q_id)
{
struct turbo_sw_queue *q = dev->data->queues[q_id].queue_private;
if (q != NULL) {
rte_ring_free(q->processed_pkts);
rte_free(q->enc_out);
rte_free(q->enc_in);
rte_free(q->ag);
rte_free(q->code_block);
rte_free(q->deint_input);
rte_free(q->deint_output);
rte_free(q->adapter_output);
rte_free(q);
dev->data->queues[q_id].queue_private = NULL;
}
rte_bbdev_log_debug("released device queue %u:%u",
dev->data->dev_id, q_id);
return 0;
}
/* Setup a queue */
static int
q_setup(struct rte_bbdev *dev, uint16_t q_id,
const struct rte_bbdev_queue_conf *queue_conf)
{
int ret;
struct turbo_sw_queue *q;
char name[RTE_RING_NAMESIZE];
/* Allocate the queue data structure. */
q = rte_zmalloc_socket(RTE_STR(DRIVER_NAME), sizeof(*q),
RTE_CACHE_LINE_SIZE, queue_conf->socket);
if (q == NULL) {
rte_bbdev_log(ERR, "Failed to allocate queue memory");
return -ENOMEM;
}
/* Allocate memory for encoder output. */
ret = snprintf(name, RTE_RING_NAMESIZE, RTE_STR(DRIVER_NAME)"_enc_o%u:%u",
dev->data->dev_id, q_id);
if ((ret < 0) || (ret >= (int)RTE_RING_NAMESIZE)) {
rte_bbdev_log(ERR,
"Creating queue name for device %u queue %u failed",
dev->data->dev_id, q_id);
ret = -ENAMETOOLONG;
goto free_q;
}
q->enc_out = rte_zmalloc_socket(name,
((RTE_BBDEV_TURBO_MAX_TB_SIZE >> 3) + 3) *
sizeof(*q->enc_out) * 3,
RTE_CACHE_LINE_SIZE, queue_conf->socket);
if (q->enc_out == NULL) {
rte_bbdev_log(ERR,
"Failed to allocate queue memory for %s", name);
ret = -ENOMEM;
goto free_q;
}
/* Allocate memory for rate matching output. */
ret = snprintf(name, RTE_RING_NAMESIZE,
RTE_STR(DRIVER_NAME)"_enc_i%u:%u", dev->data->dev_id,
q_id);
if ((ret < 0) || (ret >= (int)RTE_RING_NAMESIZE)) {
rte_bbdev_log(ERR,
"Creating queue name for device %u queue %u failed",
dev->data->dev_id, q_id);
ret = -ENAMETOOLONG;
goto free_q;
}
q->enc_in = rte_zmalloc_socket(name,
(RTE_BBDEV_LDPC_MAX_CB_SIZE >> 3) * sizeof(*q->enc_in),
RTE_CACHE_LINE_SIZE, queue_conf->socket);
if (q->enc_in == NULL) {
rte_bbdev_log(ERR,
"Failed to allocate queue memory for %s", name);
ret = -ENOMEM;
goto free_q;
}
/* Allocate memory for Alpha Gamma temp buffer. */
ret = snprintf(name, RTE_RING_NAMESIZE, RTE_STR(DRIVER_NAME)"_ag%u:%u",
dev->data->dev_id, q_id);
if ((ret < 0) || (ret >= (int)RTE_RING_NAMESIZE)) {
rte_bbdev_log(ERR,
"Creating queue name for device %u queue %u failed",
dev->data->dev_id, q_id);
ret = -ENAMETOOLONG;
goto free_q;
}
q->ag = rte_zmalloc_socket(name,
RTE_BBDEV_TURBO_MAX_CB_SIZE * 10 * sizeof(*q->ag),
RTE_CACHE_LINE_SIZE, queue_conf->socket);
if (q->ag == NULL) {
rte_bbdev_log(ERR,
"Failed to allocate queue memory for %s", name);
ret = -ENOMEM;
goto free_q;
}
/* Allocate memory for code block temp buffer. */
ret = snprintf(name, RTE_RING_NAMESIZE, RTE_STR(DRIVER_NAME)"_cb%u:%u",
dev->data->dev_id, q_id);
if ((ret < 0) || (ret >= (int)RTE_RING_NAMESIZE)) {
rte_bbdev_log(ERR,
"Creating queue name for device %u queue %u failed",
dev->data->dev_id, q_id);
ret = -ENAMETOOLONG;
goto free_q;
}
q->code_block = rte_zmalloc_socket(name,
RTE_BBDEV_TURBO_MAX_CB_SIZE * sizeof(*q->code_block),
RTE_CACHE_LINE_SIZE, queue_conf->socket);
if (q->code_block == NULL) {
rte_bbdev_log(ERR,
"Failed to allocate queue memory for %s", name);
ret = -ENOMEM;
goto free_q;
}
/* Allocate memory for Deinterleaver input. */
ret = snprintf(name, RTE_RING_NAMESIZE,
RTE_STR(DRIVER_NAME)"_de_i%u:%u",
dev->data->dev_id, q_id);
if ((ret < 0) || (ret >= (int)RTE_RING_NAMESIZE)) {
rte_bbdev_log(ERR,
"Creating queue name for device %u queue %u failed",
dev->data->dev_id, q_id);
ret = -ENAMETOOLONG;
goto free_q;
}
q->deint_input = rte_zmalloc_socket(name,
DEINT_INPUT_BUF_SIZE * sizeof(*q->deint_input),
RTE_CACHE_LINE_SIZE, queue_conf->socket);
if (q->deint_input == NULL) {
rte_bbdev_log(ERR,
"Failed to allocate queue memory for %s", name);
ret = -ENOMEM;
goto free_q;
}
/* Allocate memory for Deinterleaver output. */
ret = snprintf(name, RTE_RING_NAMESIZE,
RTE_STR(DRIVER_NAME)"_de_o%u:%u",
dev->data->dev_id, q_id);
if ((ret < 0) || (ret >= (int)RTE_RING_NAMESIZE)) {
rte_bbdev_log(ERR,
"Creating queue name for device %u queue %u failed",
dev->data->dev_id, q_id);
ret = -ENAMETOOLONG;
goto free_q;
}
q->deint_output = rte_zmalloc_socket(NULL,
DEINT_OUTPUT_BUF_SIZE * sizeof(*q->deint_output),
RTE_CACHE_LINE_SIZE, queue_conf->socket);
if (q->deint_output == NULL) {
rte_bbdev_log(ERR,
"Failed to allocate queue memory for %s", name);
ret = -ENOMEM;
goto free_q;
}
/* Allocate memory for Adapter output. */
ret = snprintf(name, RTE_RING_NAMESIZE,
RTE_STR(DRIVER_NAME)"_ada_o%u:%u",
dev->data->dev_id, q_id);
if ((ret < 0) || (ret >= (int)RTE_RING_NAMESIZE)) {
rte_bbdev_log(ERR,
"Creating queue name for device %u queue %u failed",
dev->data->dev_id, q_id);
ret = -ENAMETOOLONG;
goto free_q;
}
q->adapter_output = rte_zmalloc_socket(NULL,
ADAPTER_OUTPUT_BUF_SIZE * sizeof(*q->adapter_output),
RTE_CACHE_LINE_SIZE, queue_conf->socket);
if (q->adapter_output == NULL) {
rte_bbdev_log(ERR,
"Failed to allocate queue memory for %s", name);
ret = -ENOMEM;
goto free_q;
}
/* Create ring for packets awaiting to be dequeued. */
ret = snprintf(name, RTE_RING_NAMESIZE, RTE_STR(DRIVER_NAME)"%u:%u",
dev->data->dev_id, q_id);
if ((ret < 0) || (ret >= (int)RTE_RING_NAMESIZE)) {
rte_bbdev_log(ERR,
"Creating queue name for device %u queue %u failed",
dev->data->dev_id, q_id);
ret = -ENAMETOOLONG;
goto free_q;
}
q->processed_pkts = rte_ring_create(name, queue_conf->queue_size,
queue_conf->socket, RING_F_SP_ENQ | RING_F_SC_DEQ);
if (q->processed_pkts == NULL) {
rte_bbdev_log(ERR, "Failed to create ring for %s", name);
ret = -rte_errno;
goto free_q;
}
q->type = queue_conf->op_type;
dev->data->queues[q_id].queue_private = q;
rte_bbdev_log_debug("setup device queue %s", name);
return 0;
free_q:
rte_ring_free(q->processed_pkts);
rte_free(q->enc_out);
rte_free(q->enc_in);
rte_free(q->ag);
rte_free(q->code_block);
rte_free(q->deint_input);
rte_free(q->deint_output);
rte_free(q->adapter_output);
rte_free(q);
return ret;
}
static const struct rte_bbdev_ops pmd_ops = {
.info_get = info_get,
.queue_setup = q_setup,
.queue_release = q_release
};
#ifdef RTE_BBDEV_SDK_AVX2
#ifdef RTE_LIBRTE_BBDEV_DEBUG
/* Checks if the encoder input buffer is correct.
* Returns 0 if it's valid, -1 otherwise.
*/
static inline int
is_enc_input_valid(const uint16_t k, const int32_t k_idx,
const uint16_t in_length)
{
if (k_idx < 0) {
rte_bbdev_log(ERR, "K Index is invalid");
return -1;
}
if (in_length - (k >> 3) < 0) {
rte_bbdev_log(ERR,
"Mismatch between input length (%u bytes) and K (%u bits)",
in_length, k);
return -1;
}
if (k > RTE_BBDEV_TURBO_MAX_CB_SIZE) {
rte_bbdev_log(ERR, "CB size (%u) is too big, max: %d",
k, RTE_BBDEV_TURBO_MAX_CB_SIZE);
return -1;
}
return 0;
}
/* Checks if the decoder input buffer is correct.
* Returns 0 if it's valid, -1 otherwise.
*/
static inline int
is_dec_input_valid(int32_t k_idx, int16_t kw, int16_t in_length)
{
if (k_idx < 0) {
rte_bbdev_log(ERR, "K index is invalid");
return -1;
}
if (in_length < kw) {
rte_bbdev_log(ERR,
"Mismatch between input length (%u) and kw (%u)",
in_length, kw);
return -1;
}
if (kw > RTE_BBDEV_TURBO_MAX_KW) {
rte_bbdev_log(ERR, "Input length (%u) is too big, max: %d",
kw, RTE_BBDEV_TURBO_MAX_KW);
return -1;
}
return 0;
}
#endif
#endif
static inline void
process_enc_cb(struct turbo_sw_queue *q, struct rte_bbdev_enc_op *op,
uint8_t r, uint8_t c, uint16_t k, uint16_t ncb,
uint32_t e, struct rte_mbuf *m_in, struct rte_mbuf *m_out_head,
struct rte_mbuf *m_out, uint16_t in_offset, uint16_t out_offset,
uint16_t in_length, struct rte_bbdev_stats *q_stats)
{
#ifdef RTE_BBDEV_SDK_AVX2
#ifdef RTE_LIBRTE_BBDEV_DEBUG
int ret;
#else
RTE_SET_USED(in_length);
#endif
int16_t k_idx;
uint16_t m;
uint8_t *in, *out0, *out1, *out2, *tmp_out, *rm_out;
uint64_t first_3_bytes = 0;
struct rte_bbdev_op_turbo_enc *enc = &op->turbo_enc;
struct bblib_crc_request crc_req;
struct bblib_crc_response crc_resp;
struct bblib_turbo_encoder_request turbo_req;
struct bblib_turbo_encoder_response turbo_resp;
struct bblib_rate_match_dl_request rm_req;
struct bblib_rate_match_dl_response rm_resp;
#ifdef RTE_BBDEV_OFFLOAD_COST
uint64_t start_time;
#else
RTE_SET_USED(q_stats);
#endif
k_idx = compute_idx(k);
in = rte_pktmbuf_mtod_offset(m_in, uint8_t *, in_offset);
/* CRC24A (for TB) */
if ((enc->op_flags & RTE_BBDEV_TURBO_CRC_24A_ATTACH) &&
(enc->code_block_mode == RTE_BBDEV_CODE_BLOCK)) {
#ifdef RTE_LIBRTE_BBDEV_DEBUG
ret = is_enc_input_valid(k - 24, k_idx, in_length);
if (ret != 0) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
return;
}
#endif
crc_req.data = in;
crc_req.len = k - 24;
/* Check if there is a room for CRC bits if not use
* the temporary buffer.
*/
if (mbuf_append(m_in, m_in, 3) == NULL) {
rte_memcpy(q->enc_in, in, (k - 24) >> 3);
in = q->enc_in;
} else {
/* Store 3 first bytes of next CB as they will be
* overwritten by CRC bytes. If it is the last CB then
* there is no point to store 3 next bytes and this
* if..else branch will be omitted.
*/
first_3_bytes = *((uint64_t *)&in[(k - 32) >> 3]);
}
crc_resp.data = in;
#ifdef RTE_BBDEV_OFFLOAD_COST
start_time = rte_rdtsc_precise();
#endif
/* CRC24A generation */
bblib_lte_crc24a_gen(&crc_req, &crc_resp);
#ifdef RTE_BBDEV_OFFLOAD_COST
q_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
#endif
} else if (enc->op_flags & RTE_BBDEV_TURBO_CRC_24B_ATTACH) {
/* CRC24B */
#ifdef RTE_LIBRTE_BBDEV_DEBUG
ret = is_enc_input_valid(k - 24, k_idx, in_length);
if (ret != 0) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
return;
}
#endif
crc_req.data = in;
crc_req.len = k - 24;
/* Check if there is a room for CRC bits if this is the last
* CB in TB. If not use temporary buffer.
*/
if ((c - r == 1) && (mbuf_append(m_in, m_in, 3) == NULL)) {
rte_memcpy(q->enc_in, in, (k - 24) >> 3);
in = q->enc_in;
} else if (c - r > 1) {
/* Store 3 first bytes of next CB as they will be
* overwritten by CRC bytes. If it is the last CB then
* there is no point to store 3 next bytes and this
* if..else branch will be omitted.
*/
first_3_bytes = *((uint64_t *)&in[(k - 32) >> 3]);
}
crc_resp.data = in;
#ifdef RTE_BBDEV_OFFLOAD_COST
start_time = rte_rdtsc_precise();
#endif
/* CRC24B generation */
bblib_lte_crc24b_gen(&crc_req, &crc_resp);
#ifdef RTE_BBDEV_OFFLOAD_COST
q_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
#endif
}
#ifdef RTE_LIBRTE_BBDEV_DEBUG
else {
ret = is_enc_input_valid(k, k_idx, in_length);
if (ret != 0) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
return;
}
}
#endif
/* Turbo encoder */
/* Each bit layer output from turbo encoder is (k+4) bits long, i.e.
* input length + 4 tail bits. That's (k/8) + 1 bytes after rounding up.
* So dst_data's length should be 3*(k/8) + 3 bytes.
* In Rate-matching bypass case outputs pointers passed to encoder
* (out0, out1 and out2) can directly point to addresses of output from
* turbo_enc entity.
*/
if (enc->op_flags & RTE_BBDEV_TURBO_RATE_MATCH) {
out0 = q->enc_out;
out1 = RTE_PTR_ADD(out0, (k >> 3) + 1);
out2 = RTE_PTR_ADD(out1, (k >> 3) + 1);
} else {
out0 = (uint8_t *)mbuf_append(m_out_head, m_out,
(k >> 3) * 3 + 2);
if (out0 == NULL) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR,
"Too little space in output mbuf");
return;
}
enc->output.length += (k >> 3) * 3 + 2;
/* rte_bbdev_op_data.offset can be different than the
* offset of the appended bytes
*/
out0 = rte_pktmbuf_mtod_offset(m_out, uint8_t *, out_offset);
out1 = rte_pktmbuf_mtod_offset(m_out, uint8_t *,
out_offset + (k >> 3) + 1);
out2 = rte_pktmbuf_mtod_offset(m_out, uint8_t *,
out_offset + 2 * ((k >> 3) + 1));
}
turbo_req.case_id = k_idx;
turbo_req.input_win = in;
turbo_req.length = k >> 3;
turbo_resp.output_win_0 = out0;
turbo_resp.output_win_1 = out1;
turbo_resp.output_win_2 = out2;
#ifdef RTE_BBDEV_OFFLOAD_COST
start_time = rte_rdtsc_precise();
#endif
/* Turbo encoding */
if (bblib_turbo_encoder(&turbo_req, &turbo_resp) != 0) {
op->status |= 1 << RTE_BBDEV_DRV_ERROR;
rte_bbdev_log(ERR, "Turbo Encoder failed");
return;
}
#ifdef RTE_BBDEV_OFFLOAD_COST
q_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
#endif
/* Restore 3 first bytes of next CB if they were overwritten by CRC*/
if (first_3_bytes != 0)
*((uint64_t *)&in[(k - 32) >> 3]) = first_3_bytes;
/* Rate-matching */
if (enc->op_flags & RTE_BBDEV_TURBO_RATE_MATCH) {
uint8_t mask_id;
/* Integer round up division by 8 */
uint16_t out_len = (e + 7) >> 3;
/* The mask array is indexed using E%8. E is an even number so
* there are only 4 possible values.
*/
const uint8_t mask_out[] = {0xFF, 0xC0, 0xF0, 0xFC};
/* get output data starting address */
rm_out = (uint8_t *)mbuf_append(m_out_head, m_out, out_len);
if (rm_out == NULL) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR,
"Too little space in output mbuf");
return;
}
/* rte_bbdev_op_data.offset can be different than the offset
* of the appended bytes
*/
rm_out = rte_pktmbuf_mtod_offset(m_out, uint8_t *, out_offset);
/* index of current code block */
rm_req.r = r;
/* total number of code block */
rm_req.C = c;
/* For DL - 1, UL - 0 */
rm_req.direction = 1;
/* According to 3ggp 36.212 Spec 5.1.4.1.2 section Nsoft, KMIMO
* and MDL_HARQ are used for Ncb calculation. As Ncb is already
* known we can adjust those parameters
*/
rm_req.Nsoft = ncb * rm_req.C;
rm_req.KMIMO = 1;
rm_req.MDL_HARQ = 1;
/* According to 3ggp 36.212 Spec 5.1.4.1.2 section Nl, Qm and G
* are used for E calculation. As E is already known we can
* adjust those parameters
*/
rm_req.NL = e;
rm_req.Qm = 1;
rm_req.G = rm_req.NL * rm_req.Qm * rm_req.C;
rm_req.rvidx = enc->rv_index;
rm_req.Kidx = k_idx - 1;
rm_req.nLen = k + 4;
rm_req.tin0 = out0;
rm_req.tin1 = out1;
rm_req.tin2 = out2;
rm_resp.output = rm_out;
rm_resp.OutputLen = out_len;
if (enc->op_flags & RTE_BBDEV_TURBO_RV_INDEX_BYPASS)
rm_req.bypass_rvidx = 1;
else
rm_req.bypass_rvidx = 0;
#ifdef RTE_BBDEV_OFFLOAD_COST
start_time = rte_rdtsc_precise();
#endif
/* Rate-Matching */
if (bblib_rate_match_dl(&rm_req, &rm_resp) != 0) {
op->status |= 1 << RTE_BBDEV_DRV_ERROR;
rte_bbdev_log(ERR, "Rate matching failed");
return;
}
#ifdef RTE_BBDEV_OFFLOAD_COST
q_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
#endif
/* SW fills an entire last byte even if E%8 != 0. Clear the
* superfluous data bits for consistency with HW device.
*/
mask_id = (e & 7) >> 1;
rm_out[out_len - 1] &= mask_out[mask_id];
enc->output.length += rm_resp.OutputLen;
} else {
/* Rate matching is bypassed */
/* Completing last byte of out0 (where 4 tail bits are stored)
* by moving first 4 bits from out1
*/
tmp_out = (uint8_t *) --out1;
*tmp_out = *tmp_out | ((*(tmp_out + 1) & 0xF0) >> 4);
tmp_out++;
/* Shifting out1 data by 4 bits to the left */
for (m = 0; m < k >> 3; ++m) {
uint8_t *first = tmp_out;
uint8_t second = *(tmp_out + 1);
*first = (*first << 4) | ((second & 0xF0) >> 4);
tmp_out++;
}
/* Shifting out2 data by 8 bits to the left */
for (m = 0; m < (k >> 3) + 1; ++m) {
*tmp_out = *(tmp_out + 1);
tmp_out++;
}
*tmp_out = 0;
}
#else
RTE_SET_USED(q);
RTE_SET_USED(op);
RTE_SET_USED(r);
RTE_SET_USED(c);
RTE_SET_USED(k);
RTE_SET_USED(ncb);
RTE_SET_USED(e);
RTE_SET_USED(m_in);
RTE_SET_USED(m_out_head);
RTE_SET_USED(m_out);
RTE_SET_USED(in_offset);
RTE_SET_USED(out_offset);
RTE_SET_USED(in_length);
RTE_SET_USED(q_stats);
#endif
}
static inline void
process_ldpc_enc_cb(struct turbo_sw_queue *q, struct rte_bbdev_enc_op *op,
uint32_t e, struct rte_mbuf *m_in, struct rte_mbuf *m_out_head,
struct rte_mbuf *m_out, uint16_t in_offset, uint16_t out_offset,
uint16_t seg_total_left, struct rte_bbdev_stats *q_stats)
{
#ifdef RTE_BBDEV_SDK_AVX512
RTE_SET_USED(seg_total_left);
uint8_t *in, *rm_out;
struct rte_bbdev_op_ldpc_enc *enc = &op->ldpc_enc;
struct bblib_ldpc_encoder_5gnr_request ldpc_req;
struct bblib_ldpc_encoder_5gnr_response ldpc_resp;
struct bblib_LDPC_ratematch_5gnr_request rm_req;
struct bblib_LDPC_ratematch_5gnr_response rm_resp;
struct bblib_crc_request crc_req;
struct bblib_crc_response crc_resp;
uint16_t msgLen, puntBits, parity_offset, out_len;
uint16_t K = (enc->basegraph == 1 ? 22 : 10) * enc->z_c;
uint16_t in_length_in_bits = K - enc->n_filler;
uint16_t in_length_in_bytes = (in_length_in_bits + 7) >> 3;
#ifdef RTE_BBDEV_OFFLOAD_COST
uint64_t start_time = rte_rdtsc_precise();
#else
RTE_SET_USED(q_stats);
#endif
in = rte_pktmbuf_mtod_offset(m_in, uint8_t *, in_offset);
/* Masking the Filler bits explicitly */
memset(q->enc_in + (in_length_in_bytes - 3), 0,
((K + 7) >> 3) - (in_length_in_bytes - 3));
/* CRC Generation */
if (enc->op_flags & RTE_BBDEV_LDPC_CRC_24A_ATTACH) {
rte_memcpy(q->enc_in, in, in_length_in_bytes - 3);
crc_req.data = in;
crc_req.len = in_length_in_bits - 24;
crc_resp.data = q->enc_in;
bblib_lte_crc24a_gen(&crc_req, &crc_resp);
} else if (enc->op_flags & RTE_BBDEV_LDPC_CRC_24B_ATTACH) {
rte_memcpy(q->enc_in, in, in_length_in_bytes - 3);
crc_req.data = in;
crc_req.len = in_length_in_bits - 24;
crc_resp.data = q->enc_in;
bblib_lte_crc24b_gen(&crc_req, &crc_resp);
} else if (enc->op_flags & RTE_BBDEV_LDPC_CRC_16_ATTACH) {
rte_memcpy(q->enc_in, in, in_length_in_bytes - 2);
crc_req.data = in;
crc_req.len = in_length_in_bits - 16;
crc_resp.data = q->enc_in;
bblib_lte_crc16_gen(&crc_req, &crc_resp);
} else
rte_memcpy(q->enc_in, in, in_length_in_bytes);
/* LDPC Encoding */
ldpc_req.Zc = enc->z_c;
ldpc_req.baseGraph = enc->basegraph;
/* Number of rows set to maximum */
ldpc_req.nRows = ldpc_req.baseGraph == 1 ? 46 : 42;
ldpc_req.numberCodeblocks = 1;
ldpc_req.input[0] = (int8_t *) q->enc_in;
ldpc_resp.output[0] = (int8_t *) q->enc_out;
bblib_bit_reverse(ldpc_req.input[0], in_length_in_bytes << 3);
if (bblib_ldpc_encoder_5gnr(&ldpc_req, &ldpc_resp) != 0) {
op->status |= 1 << RTE_BBDEV_DRV_ERROR;
rte_bbdev_log(ERR, "LDPC Encoder failed");
return;
}
/*
* Systematic + Parity : Recreating stream with filler bits, ideally
* the bit select could handle this in the RM SDK
*/
msgLen = (ldpc_req.baseGraph == 1 ? 22 : 10) * ldpc_req.Zc;
puntBits = 2 * ldpc_req.Zc;
parity_offset = msgLen - puntBits;
ippsCopyBE_1u(((uint8_t *) ldpc_req.input[0]) + (puntBits / 8),
puntBits%8, q->adapter_output, 0, parity_offset);
ippsCopyBE_1u(q->enc_out, 0, q->adapter_output + (parity_offset / 8),
parity_offset % 8, ldpc_req.nRows * ldpc_req.Zc);
out_len = (e + 7) >> 3;
/* get output data starting address */
rm_out = (uint8_t *)mbuf_append(m_out_head, m_out, out_len);
if (rm_out == NULL) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR,
"Too little space in output mbuf");
return;
}
/*
* rte_bbdev_op_data.offset can be different than the offset
* of the appended bytes
*/
rm_out = rte_pktmbuf_mtod_offset(m_out, uint8_t *, out_offset);
/* Rate-Matching */
rm_req.E = e;
rm_req.Ncb = enc->n_cb;
rm_req.Qm = enc->q_m;
rm_req.Zc = enc->z_c;
rm_req.baseGraph = enc->basegraph;
rm_req.input = q->adapter_output;
rm_req.nLen = enc->n_filler;
rm_req.nullIndex = parity_offset - enc->n_filler;
rm_req.rvidx = enc->rv_index;
rm_resp.output = q->deint_output;
if (bblib_LDPC_ratematch_5gnr(&rm_req, &rm_resp) != 0) {
op->status |= 1 << RTE_BBDEV_DRV_ERROR;
rte_bbdev_log(ERR, "Rate matching failed");
return;
}
/* RM SDK may provide non zero bits on last byte */
if ((e % 8) != 0)
q->deint_output[out_len-1] &= (1 << (e % 8)) - 1;
bblib_bit_reverse((int8_t *) q->deint_output, out_len << 3);
rte_memcpy(rm_out, q->deint_output, out_len);
enc->output.length += out_len;
#ifdef RTE_BBDEV_OFFLOAD_COST
q_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
#endif
#else
RTE_SET_USED(q);
RTE_SET_USED(op);
RTE_SET_USED(e);
RTE_SET_USED(m_in);
RTE_SET_USED(m_out_head);
RTE_SET_USED(m_out);
RTE_SET_USED(in_offset);
RTE_SET_USED(out_offset);
RTE_SET_USED(seg_total_left);
RTE_SET_USED(q_stats);
#endif
}
static inline void
enqueue_enc_one_op(struct turbo_sw_queue *q, struct rte_bbdev_enc_op *op,
struct rte_bbdev_stats *queue_stats)
{
uint8_t c, r, crc24_bits = 0;
uint16_t k, ncb;
uint32_t e;
struct rte_bbdev_op_turbo_enc *enc = &op->turbo_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, mbuf_total_left = enc->input.length;
uint16_t seg_total_left;
/* Clear op status */
op->status = 0;
if (mbuf_total_left > RTE_BBDEV_TURBO_MAX_TB_SIZE >> 3) {
rte_bbdev_log(ERR, "TB size (%u) is too big, max: %d",
mbuf_total_left, RTE_BBDEV_TURBO_MAX_TB_SIZE);
op->status = 1 << RTE_BBDEV_DATA_ERROR;
return;
}
if (m_in == NULL || m_out == NULL) {
rte_bbdev_log(ERR, "Invalid mbuf pointer");
op->status = 1 << RTE_BBDEV_DATA_ERROR;
return;
}
if ((enc->op_flags & RTE_BBDEV_TURBO_CRC_24B_ATTACH) ||
(enc->op_flags & RTE_BBDEV_TURBO_CRC_24A_ATTACH))
crc24_bits = 24;
if (enc->code_block_mode == RTE_BBDEV_TRANSPORT_BLOCK) {
c = enc->tb_params.c;
r = enc->tb_params.r;
} else {/* For Code Block mode */
c = 1;
r = 0;
}
while (mbuf_total_left > 0 && r < c) {
seg_total_left = rte_pktmbuf_data_len(m_in) - in_offset;
if (enc->code_block_mode == RTE_BBDEV_TRANSPORT_BLOCK) {
k = (r < enc->tb_params.c_neg) ?
enc->tb_params.k_neg : enc->tb_params.k_pos;
ncb = (r < enc->tb_params.c_neg) ?
enc->tb_params.ncb_neg : enc->tb_params.ncb_pos;
e = (r < enc->tb_params.cab) ?
enc->tb_params.ea : enc->tb_params.eb;
} else {
k = enc->cb_params.k;
ncb = enc->cb_params.ncb;
e = enc->cb_params.e;
}
process_enc_cb(q, op, r, c, k, ncb, e, m_in, m_out_head,
m_out, in_offset, out_offset, seg_total_left,
queue_stats);
/* Update total_left */
in_length = ((k - crc24_bits) >> 3);
mbuf_total_left -= in_length;
/* Update offsets for next CBs (if exist) */
in_offset += (k - crc24_bits) >> 3;
if (enc->op_flags & RTE_BBDEV_TURBO_RATE_MATCH)
out_offset += e >> 3;
else
out_offset += (k >> 3) * 3 + 2;
/* Update offsets */
if (seg_total_left == in_length) {
/* Go to the next mbuf */
m_in = m_in->next;
m_out = m_out->next;
in_offset = 0;
out_offset = 0;
}
r++;
}
/* check if all input data was processed */
if (mbuf_total_left != 0) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR,
"Mismatch between mbuf length and included CBs sizes");
}
}
static inline void
enqueue_ldpc_enc_one_op(struct turbo_sw_queue *q, struct rte_bbdev_enc_op *op,
struct rte_bbdev_stats *queue_stats)
{
uint8_t c, r, crc24_bits = 0;
uint32_t e;
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, mbuf_total_left = enc->input.length;
uint16_t seg_total_left;
/* Clear op status */
op->status = 0;
if (mbuf_total_left > RTE_BBDEV_TURBO_MAX_TB_SIZE >> 3) {
rte_bbdev_log(ERR, "TB size (%u) is too big, max: %d",
mbuf_total_left, RTE_BBDEV_TURBO_MAX_TB_SIZE);
op->status = 1 << RTE_BBDEV_DATA_ERROR;
return;
}
if (m_in == NULL || m_out == NULL) {
rte_bbdev_log(ERR, "Invalid mbuf pointer");
op->status = 1 << RTE_BBDEV_DATA_ERROR;
return;
}
if ((enc->op_flags & RTE_BBDEV_TURBO_CRC_24B_ATTACH) ||
(enc->op_flags & RTE_BBDEV_TURBO_CRC_24A_ATTACH))
crc24_bits = 24;
if (enc->code_block_mode == RTE_BBDEV_TRANSPORT_BLOCK) {
c = enc->tb_params.c;
r = enc->tb_params.r;
} else { /* For Code Block mode */
c = 1;
r = 0;
}
while (mbuf_total_left > 0 && r < c) {
seg_total_left = rte_pktmbuf_data_len(m_in) - in_offset;
if (enc->code_block_mode == RTE_BBDEV_TRANSPORT_BLOCK) {
e = (r < enc->tb_params.cab) ?
enc->tb_params.ea : enc->tb_params.eb;
} else {
e = enc->cb_params.e;
}
process_ldpc_enc_cb(q, op, e, m_in, m_out_head,
m_out, in_offset, out_offset, seg_total_left,
queue_stats);
/* Update total_left */
in_length = (enc->basegraph == 1 ? 22 : 10) * enc->z_c;
in_length = ((in_length - crc24_bits - enc->n_filler) >> 3);
mbuf_total_left -= in_length;
/* Update offsets for next CBs (if exist) */
in_offset += in_length;
out_offset += (e + 7) >> 3;
/* Update offsets */
if (seg_total_left == in_length) {
/* Go to the next mbuf */
m_in = m_in->next;
m_out = m_out->next;
in_offset = 0;
out_offset = 0;
}
r++;
}
/* check if all input data was processed */
if (mbuf_total_left != 0) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR,
"Mismatch between mbuf length and included CBs sizes %d",
mbuf_total_left);
}
}
static inline uint16_t
enqueue_enc_all_ops(struct turbo_sw_queue *q, struct rte_bbdev_enc_op **ops,
uint16_t nb_ops, struct rte_bbdev_stats *queue_stats)
{
uint16_t i;
#ifdef RTE_BBDEV_OFFLOAD_COST
queue_stats->acc_offload_cycles = 0;
#endif
for (i = 0; i < nb_ops; ++i)
enqueue_enc_one_op(q, ops[i], queue_stats);
return rte_ring_enqueue_burst(q->processed_pkts, (void **)ops, nb_ops,
NULL);
}
static inline uint16_t
enqueue_ldpc_enc_all_ops(struct turbo_sw_queue *q,
struct rte_bbdev_enc_op **ops,
uint16_t nb_ops, struct rte_bbdev_stats *queue_stats)
{
uint16_t i;
#ifdef RTE_BBDEV_OFFLOAD_COST
queue_stats->acc_offload_cycles = 0;
#endif
for (i = 0; i < nb_ops; ++i)
enqueue_ldpc_enc_one_op(q, ops[i], queue_stats);
return rte_ring_enqueue_burst(q->processed_pkts, (void **)ops, nb_ops,
NULL);
}
#ifdef RTE_BBDEV_SDK_AVX2
static inline void
move_padding_bytes(const uint8_t *in, uint8_t *out, uint16_t k,
uint16_t ncb)
{
uint16_t d = k + 4;
uint16_t kpi = ncb / 3;
uint16_t nd = kpi - d;
rte_memcpy(&out[nd], in, d);
rte_memcpy(&out[nd + kpi + 64], &in[kpi], d);
rte_memcpy(&out[(nd - 1) + 2 * (kpi + 64)], &in[2 * kpi], d);
}
#endif
static inline void
process_dec_cb(struct turbo_sw_queue *q, struct rte_bbdev_dec_op *op,
uint8_t c, uint16_t k, uint16_t kw, struct rte_mbuf *m_in,
struct rte_mbuf *m_out_head, struct rte_mbuf *m_out,
uint16_t in_offset, uint16_t out_offset, bool check_crc_24b,
uint16_t crc24_overlap, uint16_t in_length,
struct rte_bbdev_stats *q_stats)
{
#ifdef RTE_BBDEV_SDK_AVX2
#ifdef RTE_LIBRTE_BBDEV_DEBUG
int ret;
#else
RTE_SET_USED(in_length);
#endif
int32_t k_idx;
int32_t iter_cnt;
uint8_t *in, *out, *adapter_input;
int32_t ncb, ncb_without_null;
struct bblib_turbo_adapter_ul_response adapter_resp;
struct bblib_turbo_adapter_ul_request adapter_req;
struct bblib_turbo_decoder_request turbo_req;
struct bblib_turbo_decoder_response turbo_resp;
struct rte_bbdev_op_turbo_dec *dec = &op->turbo_dec;
#ifdef RTE_BBDEV_OFFLOAD_COST
uint64_t start_time;
#else
RTE_SET_USED(q_stats);
#endif
k_idx = compute_idx(k);
#ifdef RTE_LIBRTE_BBDEV_DEBUG
ret = is_dec_input_valid(k_idx, kw, in_length);
if (ret != 0) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
return;
}
#endif
in = rte_pktmbuf_mtod_offset(m_in, uint8_t *, in_offset);
ncb = kw;
ncb_without_null = (k + 4) * 3;
if (check_bit(dec->op_flags, RTE_BBDEV_TURBO_SUBBLOCK_DEINTERLEAVE)) {
struct bblib_deinterleave_ul_request deint_req;
struct bblib_deinterleave_ul_response deint_resp;
deint_req.circ_buffer = BBLIB_FULL_CIRCULAR_BUFFER;
deint_req.pharqbuffer = in;
deint_req.ncb = ncb;
deint_resp.pinteleavebuffer = q->deint_output;
#ifdef RTE_BBDEV_OFFLOAD_COST
start_time = rte_rdtsc_precise();
#endif
/* Sub-block De-Interleaving */
bblib_deinterleave_ul(&deint_req, &deint_resp);
#ifdef RTE_BBDEV_OFFLOAD_COST
q_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
#endif
} else
move_padding_bytes(in, q->deint_output, k, ncb);
adapter_input = q->deint_output;
if (dec->op_flags & RTE_BBDEV_TURBO_POS_LLR_1_BIT_IN)
adapter_req.isinverted = 1;
else if (dec->op_flags & RTE_BBDEV_TURBO_NEG_LLR_1_BIT_IN)
adapter_req.isinverted = 0;
else {
op->status |= 1 << RTE_BBDEV_DRV_ERROR;
rte_bbdev_log(ERR, "LLR format wasn't specified");
return;
}
adapter_req.ncb = ncb_without_null;
adapter_req.pinteleavebuffer = adapter_input;
adapter_resp.pharqout = q->adapter_output;
#ifdef RTE_BBDEV_OFFLOAD_COST
start_time = rte_rdtsc_precise();
#endif
/* Turbo decode adaptation */
bblib_turbo_adapter_ul(&adapter_req, &adapter_resp);
#ifdef RTE_BBDEV_OFFLOAD_COST
q_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
#endif
out = (uint8_t *)mbuf_append(m_out_head, m_out,
((k - crc24_overlap) >> 3));
if (out == NULL) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR, "Too little space in output mbuf");
return;
}
/* rte_bbdev_op_data.offset can be different than the offset of the
* appended bytes
*/
out = rte_pktmbuf_mtod_offset(m_out, uint8_t *, out_offset);
if (check_crc_24b)
turbo_req.c = c + 1;
else
turbo_req.c = c;
turbo_req.input = (int8_t *)q->adapter_output;
turbo_req.k = k;
turbo_req.k_idx = k_idx;
turbo_req.max_iter_num = dec->iter_max;
turbo_req.early_term_disable = !check_bit(dec->op_flags,
RTE_BBDEV_TURBO_EARLY_TERMINATION);
turbo_resp.ag_buf = q->ag;
turbo_resp.cb_buf = q->code_block;
turbo_resp.output = out;
#ifdef RTE_BBDEV_OFFLOAD_COST
start_time = rte_rdtsc_precise();
#endif
/* Turbo decode */
iter_cnt = bblib_turbo_decoder(&turbo_req, &turbo_resp);
#ifdef RTE_BBDEV_OFFLOAD_COST
q_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
#endif
dec->hard_output.length += (k >> 3);
if (iter_cnt > 0) {
/* Temporary solution for returned iter_count from SDK */
iter_cnt = (iter_cnt - 1) >> 1;
dec->iter_count = RTE_MAX(iter_cnt, dec->iter_count);
} else {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR, "Turbo Decoder failed");
return;
}
#else
RTE_SET_USED(q);
RTE_SET_USED(op);
RTE_SET_USED(c);
RTE_SET_USED(k);
RTE_SET_USED(kw);
RTE_SET_USED(m_in);
RTE_SET_USED(m_out_head);
RTE_SET_USED(m_out);
RTE_SET_USED(in_offset);
RTE_SET_USED(out_offset);
RTE_SET_USED(check_crc_24b);
RTE_SET_USED(crc24_overlap);
RTE_SET_USED(in_length);
RTE_SET_USED(q_stats);
#endif
}
static inline void
process_ldpc_dec_cb(struct turbo_sw_queue *q, struct rte_bbdev_dec_op *op,
uint8_t c, uint16_t out_length, uint32_t e,
struct rte_mbuf *m_in,
struct rte_mbuf *m_out_head, struct rte_mbuf *m_out,
struct rte_mbuf *m_harq_in,
struct rte_mbuf *m_harq_out_head, struct rte_mbuf *m_harq_out,
uint16_t in_offset, uint16_t out_offset,
uint16_t harq_in_offset, uint16_t harq_out_offset,
bool check_crc_24b,
uint16_t crc24_overlap, uint16_t in_length,
struct rte_bbdev_stats *q_stats)
{
#ifdef RTE_BBDEV_SDK_AVX512
RTE_SET_USED(in_length);
RTE_SET_USED(c);
uint8_t *in, *out, *harq_in, *harq_out, *adapter_input;
struct bblib_rate_dematching_5gnr_request derm_req;
struct bblib_rate_dematching_5gnr_response derm_resp;
struct bblib_ldpc_decoder_5gnr_request dec_req;
struct bblib_ldpc_decoder_5gnr_response dec_resp;
struct bblib_crc_request crc_req;
struct bblib_crc_response crc_resp;
struct rte_bbdev_op_ldpc_dec *dec = &op->ldpc_dec;
uint16_t K, parity_offset, sys_cols, outLenWithCrc;
int16_t deRmOutSize, numRows;
/* Compute some LDPC BG lengths */
outLenWithCrc = out_length + (crc24_overlap >> 3);
sys_cols = (dec->basegraph == 1) ? 22 : 10;
K = sys_cols * dec->z_c;
parity_offset = K - 2 * dec->z_c;
#ifdef RTE_BBDEV_OFFLOAD_COST
uint64_t start_time = rte_rdtsc_precise();
#else
RTE_SET_USED(q_stats);
#endif
in = rte_pktmbuf_mtod_offset(m_in, uint8_t *, in_offset);
if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_HQ_COMBINE_IN_ENABLE)) {
/**
* Single contiguous block from the first LLR of the
* circular buffer.
*/
harq_in = NULL;
if (m_harq_in != NULL)
harq_in = rte_pktmbuf_mtod_offset(m_harq_in,
uint8_t *, harq_in_offset);
if (harq_in == NULL) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR, "No space in harq input mbuf");
return;
}
uint16_t harq_in_length = RTE_MIN(
dec->harq_combined_input.length,
(uint32_t) dec->n_cb);
memset(q->ag + harq_in_length, 0,
dec->n_cb - harq_in_length);
rte_memcpy(q->ag, harq_in, harq_in_length);
}
derm_req.p_in = (int8_t *) in;
derm_req.p_harq = q->ag; /* This doesn't include the filler bits */
derm_req.base_graph = dec->basegraph;
derm_req.zc = dec->z_c;
derm_req.ncb = dec->n_cb;
derm_req.e = e;
derm_req.k0 = 0; /* Actual output from SDK */
derm_req.isretx = check_bit(dec->op_flags,
RTE_BBDEV_LDPC_HQ_COMBINE_IN_ENABLE);
derm_req.rvid = dec->rv_index;
derm_req.modulation_order = dec->q_m;
derm_req.start_null_index = parity_offset - dec->n_filler;
derm_req.num_of_null = dec->n_filler;
bblib_rate_dematching_5gnr(&derm_req, &derm_resp);
/* Compute RM out size and number of rows */
deRmOutSize = RTE_MIN(
derm_req.k0 + derm_req.e -
((derm_req.k0 < derm_req.start_null_index) ?
0 : dec->n_filler),
dec->n_cb - dec->n_filler);
if (m_harq_in != NULL)
deRmOutSize = RTE_MAX(deRmOutSize,
RTE_MIN(dec->n_cb - dec->n_filler,
m_harq_in->data_len));
numRows = ((deRmOutSize + dec->n_filler + dec->z_c - 1) / dec->z_c)
- sys_cols + 2;
numRows = RTE_MAX(4, numRows);
/* get output data starting address */
out = (uint8_t *)mbuf_append(m_out_head, m_out, out_length);
if (out == NULL) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR,
"Too little space in LDPC decoder output mbuf");
return;
}
/* rte_bbdev_op_data.offset can be different than the offset
* of the appended bytes
*/
out = rte_pktmbuf_mtod_offset(m_out, uint8_t *, out_offset);
adapter_input = q->enc_out;
dec_req.Zc = dec->z_c;
dec_req.baseGraph = dec->basegraph;
dec_req.nRows = numRows;
dec_req.numChannelLlrs = deRmOutSize;
dec_req.varNodes = derm_req.p_harq;
dec_req.numFillerBits = dec->n_filler;
dec_req.maxIterations = dec->iter_max;
dec_req.enableEarlyTermination = check_bit(dec->op_flags,
RTE_BBDEV_LDPC_ITERATION_STOP_ENABLE);
dec_resp.varNodes = (int16_t *) q->adapter_output;
dec_resp.compactedMessageBytes = q->enc_out;
bblib_ldpc_decoder_5gnr(&dec_req, &dec_resp);
dec->iter_count = RTE_MAX(dec_resp.iterationAtTermination,
dec->iter_count);
if (!dec_resp.parityPassedAtTermination)
op->status |= 1 << RTE_BBDEV_SYNDROME_ERROR;
bblib_bit_reverse((int8_t *) q->enc_out, outLenWithCrc << 3);
if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_CRC_TYPE_24A_CHECK) ||
check_bit(dec->op_flags,
RTE_BBDEV_LDPC_CRC_TYPE_24B_CHECK)) {
crc_req.data = adapter_input;
crc_req.len = K - dec->n_filler - 24;
crc_resp.check_passed = false;
crc_resp.data = adapter_input;
if (check_crc_24b)
bblib_lte_crc24b_check(&crc_req, &crc_resp);
else
bblib_lte_crc24a_check(&crc_req, &crc_resp);
if (!crc_resp.check_passed)
op->status |= 1 << RTE_BBDEV_CRC_ERROR;
} else if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_CRC_TYPE_16_CHECK)) {
crc_req.data = adapter_input;
crc_req.len = K - dec->n_filler - 16;
crc_resp.check_passed = false;
crc_resp.data = adapter_input;
bblib_lte_crc16_check(&crc_req, &crc_resp);
if (!crc_resp.check_passed)
op->status |= 1 << RTE_BBDEV_CRC_ERROR;
}
#ifdef RTE_BBDEV_OFFLOAD_COST
q_stats->acc_offload_cycles += rte_rdtsc_precise() - start_time;
#endif
if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_HQ_COMBINE_OUT_ENABLE)) {
harq_out = NULL;
if (m_harq_out != NULL) {
/* Initialize HARQ data length since we overwrite */
m_harq_out->data_len = 0;
/* Check there is enough space
* in the HARQ outbound buffer
*/
harq_out = (uint8_t *)mbuf_append(m_harq_out_head,
m_harq_out, deRmOutSize);
}
if (harq_out == NULL) {
op->status |= 1 << RTE_BBDEV_DATA_ERROR;
rte_bbdev_log(ERR, "No space in HARQ output mbuf");
return;
}
/* get output data starting address and overwrite the data */
harq_out = rte_pktmbuf_mtod_offset(m_harq_out, uint8_t *,
harq_out_offset);
rte_memcpy(harq_out, derm_req.p_harq, deRmOutSize);
dec->harq_combined_output.length += deRmOutSize;
}
rte_memcpy(out, adapter_input, out_length);
dec->hard_output.length += out_length;
#else
RTE_SET_USED(q);
RTE_SET_USED(op);
RTE_SET_USED(c);
RTE_SET_USED(out_length);
RTE_SET_USED(e);
RTE_SET_USED(m_in);
RTE_SET_USED(m_out_head);
RTE_SET_USED(m_out);
RTE_SET_USED(m_harq_in);
RTE_SET_USED(m_harq_out_head);
RTE_SET_USED(m_harq_out);
RTE_SET_USED(harq_in_offset);
RTE_SET_USED(harq_out_offset);
RTE_SET_USED(in_offset);
RTE_SET_USED(out_offset);
RTE_SET_USED(check_crc_24b);
RTE_SET_USED(crc24_overlap);
RTE_SET_USED(in_length);
RTE_SET_USED(q_stats);
#endif
}
static inline void
enqueue_dec_one_op(struct turbo_sw_queue *q, struct rte_bbdev_dec_op *op,
struct rte_bbdev_stats *queue_stats)
{
uint8_t c, r = 0;
uint16_t kw, k = 0;
uint16_t crc24_overlap = 0;
struct rte_bbdev_op_turbo_dec *dec = &op->turbo_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 mbuf_total_left = dec->input.length;
uint16_t seg_total_left;
/* 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;
}
if (dec->code_block_mode == RTE_BBDEV_TRANSPORT_BLOCK) {
c = dec->tb_params.c;
} else { /* For Code Block mode */
k = dec->cb_params.k;
c = 1;
}
if ((c > 1) && !check_bit(dec->op_flags,
RTE_BBDEV_TURBO_DEC_TB_CRC_24B_KEEP))
crc24_overlap = 24;
while (mbuf_total_left > 0) {
if (dec->code_block_mode == RTE_BBDEV_TRANSPORT_BLOCK)
k = (r < dec->tb_params.c_neg) ?
dec->tb_params.k_neg : dec->tb_params.k_pos;
seg_total_left = rte_pktmbuf_data_len(m_in) - in_offset;
/* Calculates circular buffer size (Kw).
* According to 3gpp 36.212 section 5.1.4.2
* Kw = 3 * Kpi,
* where:
* Kpi = nCol * nRow
* where nCol is 32 and nRow can be calculated from:
* D =< nCol * nRow
* where D is the size of each output from turbo encoder block
* (k + 4).
*/
kw = RTE_ALIGN_CEIL(k + 4, RTE_BBDEV_TURBO_C_SUBBLOCK) * 3;
process_dec_cb(q, op, c, k, kw, m_in, m_out_head, m_out,
in_offset, out_offset, check_bit(dec->op_flags,
RTE_BBDEV_TURBO_CRC_TYPE_24B), crc24_overlap,
seg_total_left, queue_stats);
/* To keep CRC24 attached to end of Code block, use
* RTE_BBDEV_TURBO_DEC_TB_CRC_24B_KEEP flag as it
* removed by default once verified.
*/
mbuf_total_left -= kw;
/* Update offsets */
if (seg_total_left == kw) {
/* Go to the next mbuf */
m_in = m_in->next;
m_out = m_out->next;
in_offset = 0;
out_offset = 0;
} else {
/* Update offsets for next CBs (if exist) */
in_offset += kw;
out_offset += ((k - crc24_overlap) >> 3);
}
r++;
}
}
static inline void
enqueue_ldpc_dec_one_op(struct turbo_sw_queue *q, struct rte_bbdev_dec_op *op,
struct rte_bbdev_stats *queue_stats)
{
uint8_t c, r = 0;
uint32_t e;
uint16_t out_length, 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_harq_in = dec->harq_combined_input.data;
struct rte_mbuf *m_harq_out = dec->harq_combined_output.data;
struct rte_mbuf *m_harq_out_head = dec->harq_combined_output.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 harq_in_offset = dec->harq_combined_input.offset;
uint16_t harq_out_offset = dec->harq_combined_output.offset;
uint16_t out_offset = dec->hard_output.offset;
uint32_t mbuf_total_left = dec->input.length;
uint16_t seg_total_left;
/* 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;
}
if (dec->code_block_mode == RTE_BBDEV_TRANSPORT_BLOCK) {
c = dec->tb_params.c;
e = dec->tb_params.ea;
} else { /* For Code Block mode */
c = 1;
e = dec->cb_params.e;
}
if (check_bit(dec->op_flags, RTE_BBDEV_LDPC_CRC_TYPE_24B_DROP))
crc24_overlap = 24;
out_length = (dec->basegraph == 1 ? 22 : 10) * dec->z_c; /* K */
out_length = ((out_length - crc24_overlap - dec->n_filler) >> 3);
while (mbuf_total_left > 0) {
if (dec->code_block_mode == RTE_BBDEV_TRANSPORT_BLOCK)
e = (r < dec->tb_params.cab) ?
dec->tb_params.ea : dec->tb_params.eb;
/* Special case handling when overusing mbuf */
if (e < RTE_BBDEV_LDPC_E_MAX_MBUF)
seg_total_left = rte_pktmbuf_data_len(m_in) - in_offset;
else
seg_total_left = e;
process_ldpc_dec_cb(q, op, c, out_length, e,
m_in, m_out_head, m_out,
m_harq_in, m_harq_out_head, m_harq_out,
in_offset, out_offset, harq_in_offset,
harq_out_offset,
check_bit(dec->op_flags,
RTE_BBDEV_LDPC_CRC_TYPE_24B_CHECK),
crc24_overlap,
seg_total_left, queue_stats);
/* To keep CRC24 attached to end of Code block, use
* RTE_BBDEV_LDPC_DEC_TB_CRC_24B_KEEP flag as it
* removed by default once verified.
*/
mbuf_total_left -= e;
/* Update offsets */
if (seg_total_left == e) {
/* Go to the next mbuf */
m_in = m_in->next;
m_out = m_out->next;
if (m_harq_in != NULL)
m_harq_in = m_harq_in->next;
if (m_harq_out != NULL)
m_harq_out = m_harq_out->next;
in_offset = 0;
out_offset = 0;
harq_in_offset = 0;
harq_out_offset = 0;
} else {
/* Update offsets for next CBs (if exist) */
in_offset += e;
out_offset += out_length;
}
r++;
}
}
static inline uint16_t
enqueue_dec_all_ops(struct turbo_sw_queue *q, struct rte_bbdev_dec_op **ops,
uint16_t nb_ops, struct rte_bbdev_stats *queue_stats)
{
uint16_t i;
#ifdef RTE_BBDEV_OFFLOAD_COST
queue_stats->acc_offload_cycles = 0;
#endif
for (i = 0; i < nb_ops; ++i)
enqueue_dec_one_op(q, ops[i], queue_stats);
return rte_ring_enqueue_burst(q->processed_pkts, (void **)ops, nb_ops,
NULL);
}
static inline uint16_t
enqueue_ldpc_dec_all_ops(struct turbo_sw_queue *q,
struct rte_bbdev_dec_op **ops,
uint16_t nb_ops, struct rte_bbdev_stats *queue_stats)
{
uint16_t i;
#ifdef RTE_BBDEV_OFFLOAD_COST
queue_stats->acc_offload_cycles = 0;
#endif
for (i = 0; i < nb_ops; ++i)
enqueue_ldpc_dec_one_op(q, ops[i], queue_stats);
return rte_ring_enqueue_burst(q->processed_pkts, (void **)ops, nb_ops,
NULL);
}
/* Enqueue burst */
static uint16_t
enqueue_enc_ops(struct rte_bbdev_queue_data *q_data,
struct rte_bbdev_enc_op **ops, uint16_t nb_ops)
{
void *queue = q_data->queue_private;
struct turbo_sw_queue *q = queue;
uint16_t nb_enqueued = 0;
nb_enqueued = enqueue_enc_all_ops(q, ops, nb_ops, &q_data->queue_stats);
q_data->queue_stats.enqueue_err_count += nb_ops - nb_enqueued;
q_data->queue_stats.enqueued_count += nb_enqueued;
return nb_enqueued;
}
/* Enqueue burst */
static uint16_t
enqueue_ldpc_enc_ops(struct rte_bbdev_queue_data *q_data,
struct rte_bbdev_enc_op **ops, uint16_t nb_ops)
{
void *queue = q_data->queue_private;
struct turbo_sw_queue *q = queue;
uint16_t nb_enqueued = 0;
nb_enqueued = enqueue_ldpc_enc_all_ops(
q, ops, nb_ops, &q_data->queue_stats);
q_data->queue_stats.enqueue_err_count += nb_ops - nb_enqueued;
q_data->queue_stats.enqueued_count += nb_enqueued;
return nb_enqueued;
}
/* Enqueue burst */
static uint16_t
enqueue_dec_ops(struct rte_bbdev_queue_data *q_data,
struct rte_bbdev_dec_op **ops, uint16_t nb_ops)
{
void *queue = q_data->queue_private;
struct turbo_sw_queue *q = queue;
uint16_t nb_enqueued = 0;
nb_enqueued = enqueue_dec_all_ops(q, ops, nb_ops, &q_data->queue_stats);
q_data->queue_stats.enqueue_err_count += nb_ops - nb_enqueued;
q_data->queue_stats.enqueued_count += nb_enqueued;
return nb_enqueued;
}
/* Enqueue burst */
static uint16_t
enqueue_ldpc_dec_ops(struct rte_bbdev_queue_data *q_data,
struct rte_bbdev_dec_op **ops, uint16_t nb_ops)
{
void *queue = q_data->queue_private;
struct turbo_sw_queue *q = queue;
uint16_t nb_enqueued = 0;
nb_enqueued = enqueue_ldpc_dec_all_ops(q, ops, nb_ops,
&q_data->queue_stats);
q_data->queue_stats.enqueue_err_count += nb_ops - nb_enqueued;
q_data->queue_stats.enqueued_count += nb_enqueued;
return nb_enqueued;
}
/* Dequeue decode burst */
static uint16_t
dequeue_dec_ops(struct rte_bbdev_queue_data *q_data,
struct rte_bbdev_dec_op **ops, uint16_t nb_ops)
{
struct turbo_sw_queue *q = q_data->queue_private;
uint16_t nb_dequeued = rte_ring_dequeue_burst(q->processed_pkts,
(void **)ops, nb_ops, NULL);
q_data->queue_stats.dequeued_count += nb_dequeued;
return nb_dequeued;
}
/* Dequeue encode burst */
static uint16_t
dequeue_enc_ops(struct rte_bbdev_queue_data *q_data,
struct rte_bbdev_enc_op **ops, uint16_t nb_ops)
{
struct turbo_sw_queue *q = q_data->queue_private;
uint16_t nb_dequeued = rte_ring_dequeue_burst(q->processed_pkts,
(void **)ops, nb_ops, NULL);
q_data->queue_stats.dequeued_count += nb_dequeued;
return nb_dequeued;
}
/* Parse 16bit integer from string argument */
static inline int
parse_u16_arg(const char *key, const char *value, void *extra_args)
{
uint16_t *u16 = extra_args;
unsigned int long result;
if ((value == NULL) || (extra_args == NULL))
return -EINVAL;
errno = 0;
result = strtoul(value, NULL, 0);
if ((result >= (1 << 16)) || (errno != 0)) {
rte_bbdev_log(ERR, "Invalid value %lu for %s", result, key);
return -ERANGE;
}
*u16 = (uint16_t)result;
return 0;
}
/* Parse parameters used to create device */
static int
parse_turbo_sw_params(struct turbo_sw_params *params, const char *input_args)
{
struct rte_kvargs *kvlist = NULL;
int ret = 0;
if (params == NULL)
return -EINVAL;
if (input_args) {
kvlist = rte_kvargs_parse(input_args, turbo_sw_valid_params);
if (kvlist == NULL)
return -EFAULT;
ret = rte_kvargs_process(kvlist, turbo_sw_valid_params[0],
&parse_u16_arg, &params->queues_num);
if (ret < 0)
goto exit;
ret = rte_kvargs_process(kvlist, turbo_sw_valid_params[1],
&parse_u16_arg, &params->socket_id);
if (ret < 0)
goto exit;
if (params->socket_id >= RTE_MAX_NUMA_NODES) {
rte_bbdev_log(ERR, "Invalid socket, must be < %u",
RTE_MAX_NUMA_NODES);
goto exit;
}
}
exit:
rte_kvargs_free(kvlist);
return ret;
}
/* Create device */
static int
turbo_sw_bbdev_create(struct rte_vdev_device *vdev,
struct turbo_sw_params *init_params)
{
struct rte_bbdev *bbdev;
const char *name = rte_vdev_device_name(vdev);
bbdev = rte_bbdev_allocate(name);
if (bbdev == NULL)
return -ENODEV;
bbdev->data->dev_private = rte_zmalloc_socket(name,
sizeof(struct bbdev_private), RTE_CACHE_LINE_SIZE,
init_params->socket_id);
if (bbdev->data->dev_private == NULL) {
rte_bbdev_release(bbdev);
return -ENOMEM;
}
bbdev->dev_ops = &pmd_ops;
bbdev->device = &vdev->device;
bbdev->data->socket_id = init_params->socket_id;
bbdev->intr_handle = NULL;
/* register rx/tx burst functions for data path */
bbdev->dequeue_enc_ops = dequeue_enc_ops;
bbdev->dequeue_dec_ops = dequeue_dec_ops;
bbdev->enqueue_enc_ops = enqueue_enc_ops;
bbdev->enqueue_dec_ops = enqueue_dec_ops;
bbdev->dequeue_ldpc_enc_ops = dequeue_enc_ops;
bbdev->dequeue_ldpc_dec_ops = dequeue_dec_ops;
bbdev->enqueue_ldpc_enc_ops = enqueue_ldpc_enc_ops;
bbdev->enqueue_ldpc_dec_ops = enqueue_ldpc_dec_ops;
((struct bbdev_private *) bbdev->data->dev_private)->max_nb_queues =
init_params->queues_num;
return 0;
}
/* Initialise device */
static int
turbo_sw_bbdev_probe(struct rte_vdev_device *vdev)
{
struct turbo_sw_params init_params = {
rte_socket_id(),
RTE_BBDEV_DEFAULT_MAX_NB_QUEUES
};
const char *name;
const char *input_args;
if (vdev == NULL)
return -EINVAL;
name = rte_vdev_device_name(vdev);
if (name == NULL)
return -EINVAL;
input_args = rte_vdev_device_args(vdev);
parse_turbo_sw_params(&init_params, input_args);
rte_bbdev_log_debug(
"Initialising %s on NUMA node %d with max queues: %d\n",
name, init_params.socket_id, init_params.queues_num);
return turbo_sw_bbdev_create(vdev, &init_params);
}
/* Uninitialise device */
static int
turbo_sw_bbdev_remove(struct rte_vdev_device *vdev)
{
struct rte_bbdev *bbdev;
const char *name;
if (vdev == NULL)
return -EINVAL;
name = rte_vdev_device_name(vdev);
if (name == NULL)
return -EINVAL;
bbdev = rte_bbdev_get_named_dev(name);
if (bbdev == NULL)
return -EINVAL;
rte_free(bbdev->data->dev_private);
return rte_bbdev_release(bbdev);
}
static struct rte_vdev_driver bbdev_turbo_sw_pmd_drv = {
.probe = turbo_sw_bbdev_probe,
.remove = turbo_sw_bbdev_remove
};
RTE_PMD_REGISTER_VDEV(DRIVER_NAME, bbdev_turbo_sw_pmd_drv);
RTE_PMD_REGISTER_PARAM_STRING(DRIVER_NAME,
TURBO_SW_MAX_NB_QUEUES_ARG"=<int> "
TURBO_SW_SOCKET_ID_ARG"=<int>");
RTE_PMD_REGISTER_ALIAS(DRIVER_NAME, turbo_sw);
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