kunlun/dtest/mac_rx_test/hal/hal_rx.c

/****************************************************************************
 *
 * Copyright(c) 2019 by Aerospace C.Power (Chongqing) Microelectronics. ALL RIGHTS RESERVED.
 *
 * This Information is proprietary to Aerospace C.Power (Chongqing) Microelectronics and MAY NOT
 * be copied by any method or incorporated into another program without
 * the express written consent of Aerospace C.Power. This Information or any portion
 * thereof remains the property of Aerospace C.Power. The Information contained herein
 * is believed to be accurate and Aerospace C.Power assumes no responsibility or
 * liability for its use in any way and conveys no license or title under
 * any patent or copyright and makes no representation or warranty that this
 * Information is free from patent or copyright infringement.
 *
 * ****************************************************************************/
#include "hw_reg_api.h"
#include "tx_mpdu_start.h"
#include "rx_desc_reg_api.h"
#include "phy_bb.h"
#include "hw_rx.h"
#include "rx_entry.h"
#include "tx_entry.h"
#include "hal_rx.h"
#include "iot_bitops.h"
#include "iot_io.h"
#include "iot_led.h"
#include "mpdu_header.h"

plc_dt_ctxt_t g_plc_dt_ctxt = {{0, NULL, {{0}}, NULL, 4000}};

void dut_flag_set(bool_t flag_status)
{
    g_plc_dt_ctxt.indep.dut_flag = flag_status;
}

mac_rx_phy_info_t *phy_info_ptr_get()
{
    return g_plc_dt_ctxt.indep.phy_info;
}

/* support mode : ftm, module, dtest scan */
void rx_common_init(uint32_t band_idx)
{
    /* basic data struct init for bit ops */
    iot_bitops_init();

#if SUPPORT_SMART_GRID
    glb_cfg.m_type = PLC_PROTO_TYPE_SG;
#elif SUPPORT_SOUTHERN_POWER_GRID
    glb_cfg.m_type = PLC_PROTO_TYPE_SPG;
#endif
    mac_rx_init(band_idx);

    /* setup the rx ring */
    rx_ring_setup_hw(0, NULL);

    /* enable the rx ring */
    rx_ring_enable(0, true);
}

void mac_tmi_cnt_clr()
{
    for(uint32_t j = 0; j < MAX_TMI_NUM; j++)
    {
        g_plc_dt_ctxt.indep.tmi_beacon_cnt[j][0] = 0;
        g_plc_dt_ctxt.indep.tmi_beacon_cnt[j][1] = 0;
        g_plc_dt_ctxt.indep.tmi_beacon_cnt[j][2] = 0;
        g_plc_dt_ctxt.indep.tmi_beacon_cnt[j][3] = 0;
        g_plc_dt_ctxt.indep.tmi_sof_cnt[j][0] = 0;
        g_plc_dt_ctxt.indep.tmi_sof_cnt[j][1] = 0;
        g_plc_dt_ctxt.indep.tmi_sof_cnt[j][2] = 0;
        g_plc_dt_ctxt.indep.tmi_sof_cnt[j][3] = 0;
    }

    for(uint32_t k = 0; k < MAX_PB_NUM; k++)
    {
        g_plc_dt_ctxt.indep.tmi_sack_cnt[k] = 0;
        g_plc_dt_ctxt.indep.tmi_nncco_cnt[k] = 0;
    }
}

/* packets detail cnt printer */
void mac_pkt_info_cnt_print()
{
    uint8_t tmi = 0, tmp = 0, i = 0;
    uint32_t rate_idx = 0;
    iot_phy_sts_info_t total_sts = {0};
    iot_mac_sts_info_t mac_sts = {0};

    phy_sts_get(&total_sts);
    iot_printf("[CNT][mac]tx_ok:%d/4s\r\n", total_sts.mac_tx_ok_cnt);
    iot_printf("[CNT][phy]fc_ok:%d/4s, fc_err:%d/4s,", \
            total_sts.fc_crc_ok_cnt,total_sts.fc_crc_fail_cnt);
    iot_printf("pld_ok:%d/4s, pld_fail:%d/4s, sync_ok:%d/4s, "
            "rx_abort:%d/4s\r\n", \
            total_sts.pld_crc_ok_cnt, total_sts.pld_crc_fail_cnt, \
            total_sts.sync_ok_cnt, total_sts.phy_rx_abort_cnt);

    /*control IOT_PLC_RX_LED on the basis of pld_crc_ok_cnt*/
    if(total_sts.pld_crc_ok_cnt >= PHY_RX_CRC_RATE_LED_ON) {
        iot_led_on(IOT_PLC_RX_LED);
    } else if (total_sts.pld_crc_ok_cnt == PHY_RX_CRC_RATE_LED_OFF) {
        iot_led_off(IOT_PLC_RX_LED);
    } else {
        iot_led_off(IOT_PLC_RX_LED);
        iot_led_blink(IOT_PLC_RX_LED, 1);
    }

    /* Multi PB cnt */
    iot_printf("[MPB]pb_ok_1st:%d, 2nd:%d, 3rd:%d, 4th:%d\r\n", \
            g_plc_dt_ctxt.indep.fisrt_pb_crc_ok_cnt, \
            g_plc_dt_ctxt.indep.second_pb_crc_ok_cnt, \
            g_plc_dt_ctxt.indep.third_pb_crc_ok_cnt, \
            g_plc_dt_ctxt.indep.last_pb_crc_ok_cnt);
    /* reset cnt */
    g_plc_dt_ctxt.indep.fisrt_pb_crc_ok_cnt = 0;
    g_plc_dt_ctxt.indep.second_pb_crc_ok_cnt = 0;
    g_plc_dt_ctxt.indep.third_pb_crc_ok_cnt = 0;
    g_plc_dt_ctxt.indep.last_pb_crc_ok_cnt = 0;

    /* print tmi cnt */
    tmi = MAX_TMI_NUM;
    while(tmi--){
        for(i = 0; i < 4; i++)
        {
            /* beacon */
            if (g_plc_dt_ctxt.indep.tmi_beacon_cnt[tmi][i] != 0) {
                if (tmi < 15) {
                    iot_printf("[BCN][tmi-%d][pb-%d]:%d\r\n", \
                            tmi,i,g_plc_dt_ctxt.indep.tmi_beacon_cnt[tmi][i]);
                } else {
                    tmp = tmi - 15;/* skip optimization for next  */
                    iot_printf("[BCN][ext-tmi-%d][pb-%d]:%d\r\n", \
                            tmp,i,g_plc_dt_ctxt.indep.tmi_beacon_cnt[tmi][i]);
                }
                g_plc_dt_ctxt.indep.tmi_beacon_cnt[tmi][i] = 0;
            }
            /* sof */
            if (g_plc_dt_ctxt.indep.tmi_sof_cnt[tmi][i] != 0) {
                if (tmi < 15) {
                    iot_printf("[SOF][tmi-%d][pb-%d]:%d\r\n", \
                            tmi,i,g_plc_dt_ctxt.indep.tmi_sof_cnt[tmi][i]);
                } else {
                    tmp = tmi - 15;/* skip optimization for next  */
                    iot_printf("[SOF][ext-tmi-%d][pb-%d]:%d\r\n", \
                            tmp,i,g_plc_dt_ctxt.indep.tmi_sof_cnt[tmi][i]);
                }
                g_plc_dt_ctxt.indep.tmi_sof_cnt[tmi][i] = 0;
            }
        }
    }

    /* sack & nncco */
    for(i=0; i<4; i++)
    {
        if (g_plc_dt_ctxt.indep.tmi_sack_cnt[i] != 0) {
            iot_printf("[SACK][pb-%d]:%d\r\n", i, \
                g_plc_dt_ctxt.indep.tmi_sack_cnt[i]);
            g_plc_dt_ctxt.indep.tmi_sack_cnt[i] = 0;
        }
        if (g_plc_dt_ctxt.indep.tmi_nncco_cnt[i] != 0) {
            iot_printf("[NNCCO][pb-%d]:%d\r\n", i, \
                g_plc_dt_ctxt.indep.tmi_nncco_cnt[i]);
            g_plc_dt_ctxt.indep.tmi_nncco_cnt[i] = 0;
        }
    }

    /* band info */
    for(rate_idx=0; rate_idx<MAC_BB_MAX_RATE; rate_idx++)
    {
        for(i=0; i<MAX_HW_BAND; i++)
        {
            if (g_plc_dt_ctxt.indep.band_cnt_rx[rate_idx][i] != 0) {
                iot_printf("[RB][rate-%d][band-%d]:%d\r\n", \
                        rate_idx, i, g_plc_dt_ctxt.indep.band_cnt_rx[rate_idx][i]);
                g_plc_dt_ctxt.indep.band_cnt_rx[rate_idx][i] = 0;
            }
        }
    }
    /* mac rx cnt */
    mac_sts_get(&mac_sts);
    iot_printf("[MAC][rx-ring%d]:ring-%d, fc-%d, pkt-%d\n\n", 0, \
            mac_sts.mac_rx_ring0_dbg_cnt, \
            mac_sts.mac_rx_fc_dbg_cnt, \
            mac_sts.mac_rx_pkt_det_cnt);
}

void phy_granite_loopback(uint32_t band_idx)
{
    /* reset phy */
    phy_reset(PHY_RST_REASON_WARM);

    /* Must cfg start adn end tone */
    mac_rx_init(band_idx);

    phy_rx_loopback();
}

/* TODO: replace by mac_ppm_cal */
uint32_t mac_ntb_ppm_cali_start(rx_buf_hdr_t *pb_buf, uint32_t ppm_cnt)
{
    /* ppm calibration */
    volatile int64_t ppm = 0;
    volatile int64_t rx_span = 0, tx_span = 0, rx_ntb_span = 0;

    /* ppm cali */
    g_plc_dt_ctxt.indep.rx_ts_last = g_plc_dt_ctxt.indep.rx_ts_cur;
    g_plc_dt_ctxt.indep.rx_ts_cur = \
        mac_rx_mpdu_end_get_local_timestamp(&pb_buf->mpdu_ed);
    g_plc_dt_ctxt.indep.rx_ntb_ts_last = g_plc_dt_ctxt.indep.rx_ntb_ts_cur;
    g_plc_dt_ctxt.indep.rx_ntb_ts_cur = \
        mac_rx_mpdu_end_get_ntb_timestamp(&pb_buf->mpdu_ed);;
    g_plc_dt_ctxt.indep.tx_ts_last = g_plc_dt_ctxt.indep.tx_ts_cur;

    g_plc_dt_ctxt.indep.tx_ts_cur = \
        mac_get_bcn_st(PHY_PROTO_TYPE_GET(), \
            mac_rx_mpdu_st_get_fc_addr(&pb_buf->mpdu_st));

    rx_span = g_plc_dt_ctxt.indep.rx_ts_cur - \
        g_plc_dt_ctxt.indep.rx_ts_last;
    if (rx_span < 0) { // wrap around
        rx_span = (0x100000000LL) - \
            g_plc_dt_ctxt.indep.rx_ts_last + \
            g_plc_dt_ctxt.indep.rx_ts_cur;
    }

    rx_ntb_span = g_plc_dt_ctxt.indep.rx_ntb_ts_cur - \
        g_plc_dt_ctxt.indep.rx_ntb_ts_last;
    if (rx_ntb_span < 0) { // wrap around
        rx_ntb_span = (0x100000000LL) - \
            g_plc_dt_ctxt.indep.rx_ntb_ts_last + \
            g_plc_dt_ctxt.indep.rx_ntb_ts_cur;
    }

    tx_span = g_plc_dt_ctxt.indep.tx_ts_cur - \
        g_plc_dt_ctxt.indep.tx_ts_last;
    if (tx_span < 0) { // wrap around
        tx_span = (0x100000000LL) - \
            g_plc_dt_ctxt.indep.tx_ts_last + \
            g_plc_dt_ctxt.indep.tx_ts_cur;
    }

#if PHY_RX_DBG_EN
    iot_printf("[Debug]ntb ts0:%u, ts1:%u, ts_span:%u\r\n",  \
        g_plc_dt_ctxt.indep.rx_ntb_ts_last, \
        g_plc_dt_ctxt.indep.rx_ntb_ts_cur, \
        (uint32_t)rx_ntb_span);
    iot_printf("[Debug]rx0:%u,rx1:%u,tx0:%u,tx1:%u,\r\n", \
        g_plc_dt_ctxt.indep.rx_ts_last, \
        g_plc_dt_ctxt.indep.rx_ts_cur, \
        g_plc_dt_ctxt.indep.tx_ts_last, \
        g_plc_dt_ctxt.indep.tx_ts_cur);
    iot_printf("r1-r0:%u,t1-t0:%u, ppm_pkt:%d\r\n", \
        (uint32_t)rx_span, \
        (uint32_t)tx_span, pb_buf->mpdu_st.phy.est_ppm);
#endif

    if (rx_span > (ppm_cnt - (ppm_cnt >> 1)) && \
        rx_span < (ppm_cnt + (ppm_cnt >> 1))) {
        /* cal ppm */
        ppm = (rx_ntb_span - tx_span) * (1 << 20);
        ppm = ppm/tx_span;

        /* check ppm valid */
        if (ppm < 200 && ppm > -200) {
            phy_ppm_cal_and_update_hw(PHY_CAL_UNIT_1_1, \
                -ppm, IOT_SUPPORT_RATE_SR, BB_PPM_TXRX);
            iot_printf("[ppm cali] write ppm:%d successfully!\r\n", \
                (uint32_t)ppm);
        } else {
            iot_printf("[ppm cali] ppm:%d cal failed!\r\n",(uint32_t)ppm);
        }
    } else {
        iot_printf("[ppm cali] rx_span:%lld not valid!\r\n", rx_span);
    }

    return ERR_OK;
}