luban-lite-t3e-pro/bsp/artinchip/hal/qspi/hal_qspi_v2x.c

/*
 * Copyright (c) 2022-2024, ArtInChip Technology Co., Ltd
 *
 * SPDX-License-Identifier: Apache-2.0
 */

#include <rtconfig.h>
#include <stdbool.h>
#include <string.h>
#include <stdint.h>
#include <aic_common.h>
#include <aic_core.h>
#include <aic_hal.h>
#include <hal_dma.h>
#include <hal_qspi.h>
#include "qspi_internal.h"

#include "qspi_hw_v2.0.h"

void hal_qspi_master_bit_mode_init(u32 base)
{
#if AIC_SUPPORT_SPI_X_WIRE_IN_BIT_MODE  == 4
    qspi_hw_set_work_mode(base, BMTC_BIT_WM_BIT_STD);
#else
    qspi_hw_set_work_mode(base, BMTC_BIT_WM_BIT_3WIRE);
#endif

    /* set chip select number */
    qspi_hw_bit_mode_set_cs_pol(base, false);
    qspi_hw_bit_mode_set_ss_owner(base, true);
}

int hal_qspi_master_transfer_bit_mode(qspi_master_handle *h, struct qspi_bm_transfer *t)
{
    struct qspi_master_state *qspi;
    u32 base;
    int ret = 0;

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    if ((t->tx_data == NULL) && (t->rx_data == NULL))
        return -EINVAL;

    if (!t->rx_bits_len && !t->tx_bits_len)
        return -EINVAL;

    qspi_hw_reset_fifo(base);
    if (t->tx_data && t->rx_data) {
        ret = qspi_hw_bit_mode_send_then_recv(base, t->tx_data, t->tx_bits_len,
                                              t->rx_data, t->rx_bits_len);
    } else {
        if (t->tx_data) {
            ret = qspi_hw_bit_mode_write(base, t->tx_data, t->tx_bits_len);
        }
        if (t->rx_data) {
            ret = qspi_hw_bit_mode_read(base, t->rx_data, t->rx_bits_len);
        }
    }

    return ret; /* In progress */
}

int hal_qspi_master_init(qspi_master_handle *h, struct qspi_master_config *cfg)
{
    struct qspi_master_state *qspi;
    u32 base, sclk;
    int ret;

    CHECK_PARAM(h, -EINVAL);
    CHECK_PARAM(cfg, -EINVAL);

    qspi = (struct qspi_master_state *)h;

    base = qspi_hw_index_to_base(cfg->idx);
    if (base == QSPI_INVALID_BASE) {
        hal_log_err("invalid spi controller index %d\n", cfg->idx);
        return -ENODEV;
    }

    sclk = cfg->clk_in_hz;
    if (sclk > HAL_QSPI_MAX_FREQ_HZ)
        sclk = HAL_QSPI_MAX_FREQ_HZ;
    else if (sclk < HAL_QSPI_MIN_FREQ_HZ)
        sclk = HAL_QSPI_MIN_FREQ_HZ;
    qspi->idx = cfg->idx;

    show_freq("freq (input)", qspi->idx, sclk);
    hal_clk_set_freq(cfg->clk_id, sclk);
    ret = hal_clk_enable(cfg->clk_id);
    if (ret < 0) {
        hal_log_err("QSPI %d clk enable failed!\n", cfg->idx);
        return -EFAULT;
    }

    ret = hal_clk_enable_deassertrst(cfg->clk_id);
    if (ret < 0) {
        hal_log_err("QSPI %d reset deassert failed!\n", cfg->idx);
        return -EFAULT;
    }

    qspi_hw_init_default(base);
    qspi_hw_set_ctrl_mode(base, QSPI_CTRL_MODE_MASTER);
    qspi_hw_set_tx_delay_mode(base, cfg->tx_dlymode);
    qspi_hw_set_rx_delay_mode(base, cfg->rx_dlymode);
    qspi_hw_interrupt_disable(base, ICR_BIT_ALL_MSK);
    qspi_hw_set_cpol(base, cfg->cpol);
    qspi_hw_set_cpha(base, cfg->cpha);
    qspi_hw_set_cs_polarity(base, cfg->cs_polarity);
    if (cfg->cs_polarity == QSPI_CS_POL_VALID_LOW)
        qspi_hw_set_cs_level(base, QSPI_CS_LEVEL_HIGH);
    else
        qspi_hw_set_cs_level(base, QSPI_CS_LEVEL_LOW);
    if (cfg->cs_auto)
        qspi_hw_set_cs_owner(base, QSPI_CS_CTL_BY_HW);
    else
        qspi_hw_set_cs_owner(base, QSPI_CS_CTL_BY_SW);
    qspi_hw_drop_invalid_data(base, QSPI_DROP_INVALID_DATA);
    qspi_hw_reset_fifo(base);
    qspi_hw_set_fifo_watermark(base, QSPI_TX_WATERMARK, QSPI_RX_WATERMARK);

    qspi->clk_id = cfg->clk_id;
    qspi->cb = NULL;
    qspi->cb_priv = NULL;

    if (h->bit_mode) {
        hal_qspi_master_bit_mode_init(base);
    }

    return 0;
}

void hal_qspi_fifo_reset(u32 base, u32 fifo)
{
    if (fifo == HAL_QSPI_RX_FIFO) {
        qspi_hw_reset_rx_fifo(base);
    }
    if (fifo == HAL_QSPI_TX_FIFO) {
        qspi_hw_reset_tx_fifo(base);
    }
}

void hal_qspi_master_fifo_reset(qspi_master_handle *h, u32 fifo)
{
    struct qspi_master_state *qspi;
    u32 base;

    CHECK_PARAM_RET(h);
    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);
    hal_qspi_fifo_reset(base, fifo);
}

int hal_qspi_master_deinit(qspi_master_handle *h)
{
    struct qspi_master_state *qspi;

    CHECK_PARAM(h, -EINVAL);

    qspi = (struct qspi_master_state *)h;
#ifdef AIC_DMA_DRV
    if (qspi->dma_rx) {
        hal_release_dma_chan(qspi->dma_rx);
        qspi->dma_rx = NULL;
    }
    if (qspi->dma_tx) {
        hal_release_dma_chan(qspi->dma_tx);
        qspi->dma_tx = NULL;
    }
#endif
    qspi->cb = NULL;
    qspi->cb_priv = NULL;
    qspi->async_tx = NULL;
    qspi->async_rx = NULL;
    qspi->async_tx_remain = 0;
    qspi->async_rx_remain = 0;
    return 0;
}

#ifdef AIC_DMA_DRV
int hal_qspi_master_dma_config(qspi_master_handle *h,
                               struct qspi_master_dma_config *cfg)
{
    struct qspi_master_state *qspi;
    struct aic_dma_chan *rx_chan, *tx_chan;

    CHECK_PARAM(h, -EINVAL);
    CHECK_PARAM(cfg, -EINVAL);

    qspi = (struct qspi_master_state *)h;
    if (qspi->dma_rx || qspi->dma_tx) {
        hal_log_err("DMA already init for QSPI.\n");
        return -EINVAL;
    }

    rx_chan = hal_request_dma_chan();
    if (!rx_chan) {
        hal_log_err("Request dma chan error.\n");
        goto err;
    }

    tx_chan = hal_request_dma_chan();
    if (!tx_chan) {
        hal_log_err("Request dma chan error.\n");
        goto err;
    }

    qspi->dma_rx = rx_chan;
    qspi->dma_tx = tx_chan;
    qspi->dma_cfg = *cfg;

    qspi->dma_cfg.dev_max_burst = HAL_QSPI_DMA_DEV_MAXBURST;
    qspi->dma_cfg.dev_bus_width = DMA_SLAVE_BUSWIDTH_4_BYTES;
    qspi->dma_cfg.mem_max_burst = HAL_QSPI_DMA_MEM_MAXBURST;
    qspi->dma_cfg.mem_bus_width = DMA_SLAVE_BUSWIDTH_UNDEFINED;

    return 0;
err:
    return -ENODEV;
}
#endif

int hal_qspi_master_set_cs(qspi_master_handle *h, u32 cs_num, bool enable)
{
    struct qspi_master_state *qspi;
    u32 base, pol, level;

    CHECK_PARAM(h, -EINVAL);
    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    if (h->bit_mode) {
        pol = qspi_hw_bit_mode_get_cs_pol(base);

        if (enable)
            level = (pol == QSPI_CS_POL_VALID_LOW) ? QSPI_CS_LEVEL_LOW :
                                                     QSPI_CS_LEVEL_HIGH;
        else
            level = (pol == QSPI_CS_POL_VALID_LOW) ? QSPI_CS_LEVEL_HIGH :
                                                     QSPI_CS_LEVEL_LOW;

        qspi_hw_bit_mode_set_cs_num(cs_num, base);
        qspi_hw_bit_mode_set_cs_level(base, level);
        return 0;
    }

    pol = qspi_hw_get_cs_polarity(base);
    if (enable)
        level = (pol == QSPI_CS_POL_VALID_LOW) ? QSPI_CS_LEVEL_LOW :
                                                 QSPI_CS_LEVEL_HIGH;
    else
        level = (pol == QSPI_CS_POL_VALID_LOW) ? QSPI_CS_LEVEL_HIGH :
                                                 QSPI_CS_LEVEL_LOW;
    qspi_hw_select_cs_num(base, cs_num);
    qspi_hw_set_cs_level(base, level);

    return 0;
}

int hal_qspi_master_set_bus_freq(qspi_master_handle *h, u32 bus_hz)
{
    u32 base, sclk, divider, div;
    struct qspi_master_state *qspi;

    CHECK_PARAM(h, -EINVAL);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);
    sclk = hal_clk_get_freq(qspi->clk_id);

    /* The source clock is divided into two halves by spi controller. */
    sclk = sclk / 2;

    if (bus_hz > HAL_QSPI_FPGA_MAX_FREQ_HZ)
        bus_hz = HAL_QSPI_FPGA_MAX_FREQ_HZ;
    else if (bus_hz < HAL_QSPI_MIN_FREQ_HZ)
        bus_hz = HAL_QSPI_MIN_FREQ_HZ;

    show_freq("freq ( bus )", qspi->idx, bus_hz);

    if (h->bit_mode) {
        qspi_hw_bit_mode_set_clk(bus_hz, sclk, base);
    }

    divider = qspi_master_get_best_div_param(sclk, bus_hz, &div);

    qspi_hw_set_clk_div(base, divider, div);
    if (divider == 0 && div == 0) {
        u32 rx_delay, tx_delay;
        tx_delay = qspi_hw_get_tx_delay_mode(base);
        rx_delay = qspi_hw_get_rx_delay_mode(base);
        qspi_hw_set_delay_mode_normal(base);
        qspi_hw_set_tx_delay_normal(base, tx_delay);
        qspi_hw_set_rx_delay_normal(base, rx_delay);
    }
    qspi->bus_hz = bus_hz;

    return 0;
}

int hal_qspi_master_set_bus_width(qspi_master_handle *h, u32 bus_width)
{
    struct qspi_master_state *qspi;
    u32 base;

    CHECK_PARAM(h, -EINVAL);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    qspi_hw_set_bus_width(base, bus_width);
    qspi->bus_width = bus_width;
    if (qspi->bus_width == 0)
        qspi->bus_width = QSPI_BUS_WIDTH_SINGLE;

    return 0;
}

int qspi_wait_transfer_done(u32 base, u32 tmo)
{
    u32 cnt = 0;

    while (qspi_hw_check_transfer_done(base) == false) {
        aic_udelay(HAL_QSPI_WAIT_DELAY_US);
        cnt++;
        if (cnt > tmo)
            return -ETIMEDOUT;
    }
    return 0;
}

#ifdef AIC_DMA_DRV
int qspi_wait_gpdma_tx_done(u32 base, u32 tmo)
{
    u32 cnt = 0;

    while (qspi_hw_check_gpdma_tx_done(base) == false) {
        aic_udelay(HAL_QSPI_WAIT_DELAY_US);
        cnt++;
        if (cnt > tmo)
            return -ETIMEDOUT;
    }
    return 0;
}

int qspi_wait_gpdma_rx_done(u32 base, u32 tmo)
{
    u32 cnt = 0;

    while (qspi_hw_check_gpdma_rx_done(base) == false) {
        aic_udelay(HAL_QSPI_WAIT_DELAY_US);
        cnt++;
        if (cnt > tmo)
            return -ETIMEDOUT;
    }
    return 0;
}
#endif

int qspi_fifo_write_read(u32 base, u8 *tx, u8 *rx, u32 len, u32 tmo)
{
    u32 free_len, dolen, cnt = 0;

    while (len) {
        free_len = QSPI_FIFO_DEPTH - qspi_hw_get_tx_fifo_cnt(base);
        while (free_len <= (QSPI_FIFO_DEPTH >> 3)) {
            aic_udelay(HAL_QSPI_WAIT_DELAY_US);
            free_len = QSPI_FIFO_DEPTH - qspi_hw_get_tx_fifo_cnt(base);
            cnt++;
            if (cnt > tmo)
                return -ETIMEDOUT;
            continue;
        }
        dolen = min(free_len, len);
        qspi_hw_write_fifo(base, tx, dolen);
        while (qspi_hw_get_rx_fifo_cnt(base) != dolen) {
            aic_udelay(HAL_QSPI_WAIT_DELAY_US);
            cnt++;
            if (cnt > tmo)
                return -ETIMEDOUT;
        }
        qspi_hw_read_fifo(base, rx, dolen);
        tx += dolen;
        rx += dolen;
        len -= dolen;
    }

    /* Data are written to FIFO, waiting all data are sent out */
    while (qspi_hw_get_tx_fifo_cnt(base)) {
        aic_udelay(HAL_QSPI_WAIT_DELAY_US);
        cnt++;
        if (cnt > tmo)
            return -ETIMEDOUT;
    }
    return 0;
}

int qspi_fifo_write_data(u32 base, u8 *data, u32 len, u32 tmo)
{
    u32 dolen, free_len, cnt = 0;

    while (len) {
        free_len = QSPI_FIFO_DEPTH - qspi_hw_get_tx_fifo_cnt(base);
        if (free_len <= (QSPI_FIFO_DEPTH >> 3)) {
            aic_udelay(HAL_QSPI_WAIT_DELAY_US);
            cnt++;
            if (cnt > tmo)
                return -ETIMEDOUT;
            continue;
        }
        dolen = min(free_len, len);
        qspi_hw_write_fifo(base, data, dolen);
        data += dolen;
        len -= dolen;
        aic_udelay(HAL_QSPI_WAIT_DELAY_US);
        cnt++;
    }

    /* Data are written to FIFO, waiting all data are sent out */
    while (qspi_hw_get_tx_fifo_cnt(base)) {
        aic_udelay(HAL_QSPI_WAIT_DELAY_US);
        cnt++;
        if (cnt > tmo)
            return -ETIMEDOUT;
    }
    return 0;
}

int qspi_fifo_read_data(u32 base, u8 *data, u32 len, u32 tmo)
{
    u32 dolen, cnt = 0;

    while (len) {
        dolen = qspi_hw_get_rx_fifo_cnt(base);
        if (dolen == 0) {
            aic_udelay(HAL_QSPI_WAIT_DELAY_US);
            cnt++;
            if (cnt > tmo)
                return -ETIMEDOUT;
            continue;
        } else if (dolen > len) {
            dolen = len;
        }
        qspi_hw_read_fifo(base, data, dolen);
        data += dolen;
        len -= dolen;
        aic_udelay(HAL_QSPI_WAIT_DELAY_US);
        cnt++;
    }

    return 0;
}

static int qspi_master_transfer_cpu_sync(qspi_master_handle *h,
                                         struct qspi_transfer *t)
{
    u32 base, tmo_cnt, txlen, tx_1line_cnt, rxlen, sts;
    struct qspi_master_state *qspi;
    int ret = 0;

    CHECK_PARAM(h, -EINVAL);
    CHECK_PARAM(t, -EINVAL);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    if ((t->tx_data == NULL) && (t->rx_data == NULL))
        return -EINVAL;
    if (t->data_len == 0)
        return -EINVAL;

    tmo_cnt = qspi_calc_timeout(qspi->bus_hz, t->data_len);
    /* CPU mode, spend more time */
    tmo_cnt *= 10;
    qspi_hw_reset_fifo(base);

    if (t->tx_data && t->rx_data) {
        if (qspi_hw_get_bus_width(base) != QSPI_BUS_WIDTH_SINGLE) {
            hal_log_err("Full duplex mode did not support.\n");
            goto out;
        }
        qspi->work_mode = QSPI_WORK_MODE_SYNC_DUPLEX_CPU;
        qspi_hw_set_transfer_cnt(base, t->data_len, t->data_len, 0, 0);
        qspi_hw_drop_invalid_data(base, QSPI_RECV_ALL_INPUT_DATA);
        qspi_hw_start_transfer(base);
        ret = qspi_fifo_write_read(base, t->tx_data, t->rx_data, t->data_len, tmo_cnt);
        if (ret < 0) {
            hal_log_err("read write fifo failure.\n");
            goto out;
        }
    } else if (t->tx_data) {
        txlen = t->data_len;
        tx_1line_cnt = 0;
        if (qspi_hw_get_bus_width(base) == QSPI_BUS_WIDTH_SINGLE)
            tx_1line_cnt = txlen;
        qspi->work_mode = QSPI_WORK_MODE_SYNC_TX_CPU;
        qspi_hw_set_transfer_cnt(base, txlen, tx_1line_cnt, 0, 0);
        qspi_hw_start_transfer(base);
        ret = qspi_fifo_write_data(base, t->tx_data, txlen, tmo_cnt);
        if (ret < 0) {
            hal_log_err("TX write fifo failure.\n");
            goto out;
        }
    } else if (t->rx_data) {
        rxlen = t->data_len;
        qspi->work_mode = QSPI_WORK_MODE_SYNC_RX_CPU;
        qspi_hw_set_transfer_cnt(base, 0, 0, rxlen, 0);
        qspi_hw_start_transfer(base);
        ret = qspi_fifo_read_data(base, t->rx_data, rxlen, tmo_cnt);
        if (ret < 0) {
            hal_log_err("RX read fifo failure: rxlen %d, tmo_cnt %d.\n", rxlen,
                        tmo_cnt);
            goto out;
        }
    }
    ret = qspi_wait_transfer_done(base, tmo_cnt);
    if (ret < 0) {
        hal_log_err("Wait transfer done timeout.\n");
        goto out;
    }
out:
    qspi_hw_get_interrupt_status(base, &sts);
    qspi_hw_clear_interrupt_status(base, sts);
    return ret;
}

#ifdef AIC_DMA_DRV
static int qspi_master_wait_dma_done(struct aic_dma_chan *ch, u32 tmo)
{
    u32 left, cnt = 0;

    while (hal_dma_chan_tx_status(ch, &left) != DMA_COMPLETE && left) {
        aic_udelay(HAL_QSPI_WAIT_DELAY_US);
        cnt++;
        if (cnt > tmo) {
            return -ETIMEDOUT;
        }
    }
    return 0;
}

static int qspi_txrx_dma_sync(qspi_master_handle *h,
                                         struct qspi_transfer *t, u32 tmo_cnt)
{
    struct qspi_master_state *qspi;
    struct dma_slave_config dmacfg;
    u32 base;
    int ret;

    CHECK_PARAM(h, -EINVAL);
    CHECK_PARAM(t, -EINVAL);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    if (qspi_hw_get_bus_width(base) != QSPI_BUS_WIDTH_SINGLE) {
            hal_log_err("Full duplex mode did not support.\n");
            return -1;
    }
    qspi->work_mode = QSPI_WORK_MODE_SYNC_DUPLEX_DMA;
    qspi_hw_tx_dma_enable(base);
    qspi_hw_rx_dma_enable(base);
    qspi_hw_set_transfer_cnt(base, t->data_len, t->data_len, 0, 0);
    qspi_hw_drop_invalid_data(base, QSPI_RECV_ALL_INPUT_DATA);

    /* config tx DMA channel */
    dmacfg.direction = DMA_MEM_TO_DEV;
    dmacfg.slave_id = qspi->dma_cfg.port_id;
    dmacfg.src_addr = (unsigned long)t->tx_data;
    dmacfg.dst_addr = (unsigned long)QSPI_REG_TXD(base);

    dmacfg.src_addr_width = qspi->dma_cfg.mem_bus_width;
    dmacfg.src_maxburst = qspi->dma_cfg.mem_max_burst;
    if (!(t->data_len % HAL_QSPI_DMA_4BYTES_LINE))
        dmacfg.dst_addr_width = qspi->dma_cfg.dev_bus_width;
    else
        dmacfg.dst_addr_width = DMA_SLAVE_BUSWIDTH_1_BYTE;
    dmacfg.dst_maxburst = qspi->dma_cfg.dev_max_burst;

    ret = hal_dma_chan_config(qspi->dma_tx, &dmacfg);
    if (ret < 0) {
        hal_log_err("TX dma chan config failure.\n");
        return -1;
    }
    ret = hal_dma_prep_mode_device(qspi->dma_tx, PTR2U32(QSPI_REG_TXD(base)),
                                       PTR2U32(t->tx_data), t->data_len,
                                       DMA_MEM_TO_DEV, TYPE_IO_FAST);
    if (ret < 0) {
        hal_log_err("TX dma chan prepare failure.\n");
        return -1;
    }

    ret = hal_dma_chan_start(qspi->dma_tx);
    if (ret < 0) {
        hal_log_err("TX dma chan start failure.\n");
        return -1;
    }

    /* config rx DMA channel */
    dmacfg.direction = DMA_DEV_TO_MEM;
    dmacfg.slave_id = qspi->dma_cfg.port_id;
    dmacfg.src_addr = (unsigned long)QSPI_REG_RXD(base);
    dmacfg.dst_addr = (unsigned long)t->rx_data;

    if (!(t->data_len % HAL_QSPI_DMA_4BYTES_LINE))
        dmacfg.src_addr_width = qspi->dma_cfg.dev_bus_width;
    else
        dmacfg.src_addr_width = DMA_SLAVE_BUSWIDTH_1_BYTE;
    dmacfg.src_maxburst = qspi->dma_cfg.mem_max_burst;
    dmacfg.dst_addr_width = qspi->dma_cfg.dev_bus_width;
    dmacfg.dst_maxburst = qspi->dma_cfg.dev_max_burst;

    ret = hal_dma_chan_config(qspi->dma_rx, &dmacfg);
    if (ret < 0) {
        hal_log_err("RX dma chan config failure.\n");
        return -1;
    }
    ret = hal_dma_prep_mode_device(qspi->dma_rx, PTR2U32(t->rx_data),
                                    PTR2U32(QSPI_REG_RXD(base)), t->data_len,
                                    DMA_DEV_TO_MEM, TYPE_IO_FAST);
    if (ret < 0) {
        hal_log_err("RX dma chan prepare failure.\n");
        return -1;
    }
    ret = hal_dma_chan_start(qspi->dma_rx);
    if (ret < 0) {
        hal_log_err("RX dma chan start failure.\n");
        return -1;
    }

    qspi_hw_start_transfer(base);
    ret = qspi_wait_transfer_done(base, tmo_cnt);
    if (ret < 0) {
        hal_log_err("Wait transfer done timeout.\n");
    }
    ret = qspi_master_wait_dma_done(qspi->dma_rx, tmo_cnt);
    if (ret < 0) {
        hal_log_err("RX wait dma done timeout.\n");
    }

    qspi_hw_drop_invalid_data(base, QSPI_DROP_INVALID_DATA);
    qspi_hw_rx_dma_disable(base);
    qspi_hw_tx_dma_disable(base);
    hal_dma_chan_stop(qspi->dma_rx);
    hal_dma_chan_stop(qspi->dma_tx);

    return ret;
}


static int qspi_master_transfer_dma_sync(qspi_master_handle *h,
                                         struct qspi_transfer *t)
{
    u32 base, tmo_cnt, txlen, tx_1line_cnt, rxlen, sts;
    struct qspi_master_state *qspi;
    struct aic_dma_chan *dma_rx, *dma_tx;
    struct dma_slave_config dmacfg;
    int ret = 0;

    CHECK_PARAM(h, -EINVAL);
    CHECK_PARAM(t, -EINVAL);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);
    memset(&dmacfg, 0, sizeof(dmacfg));

    if ((t->tx_data == NULL) && (t->rx_data == NULL))
        return -EINVAL;
    if (t->data_len == 0)
        return -EINVAL;

    tmo_cnt = qspi_calc_timeout(qspi->bus_hz, t->data_len);
    qspi_hw_reset_fifo(base);

    if (t->tx_data && t->rx_data) {
        ret = qspi_txrx_dma_sync(h, t, tmo_cnt);
    } else if (t->tx_data) {
        txlen = t->data_len;
        tx_1line_cnt = 0;
        if (qspi_hw_get_bus_width(base) == QSPI_BUS_WIDTH_SINGLE)
            tx_1line_cnt = txlen;
        qspi->work_mode = QSPI_WORK_MODE_SYNC_TX_CPU;
        qspi_hw_tx_dma_enable(base);
        qspi_hw_set_transfer_cnt(base, txlen, tx_1line_cnt, 0, 0);
        dma_tx = qspi->dma_tx;

        dmacfg.direction = DMA_MEM_TO_DEV;
        dmacfg.slave_id = qspi->dma_cfg.port_id;
        dmacfg.src_addr = (unsigned long)t->tx_data;
        dmacfg.dst_addr = (unsigned long)QSPI_REG_TXD(base);

        dmacfg.src_addr_width = qspi->dma_cfg.mem_bus_width;
        dmacfg.src_maxburst = qspi->dma_cfg.mem_max_burst;
        if (!(txlen % HAL_QSPI_DMA_4BYTES_LINE))
            dmacfg.dst_addr_width = qspi->dma_cfg.dev_bus_width;
        else
            dmacfg.dst_addr_width = DMA_SLAVE_BUSWIDTH_1_BYTE;
        dmacfg.dst_maxburst = qspi->dma_cfg.dev_max_burst;

        ret = hal_dma_chan_config(dma_tx, &dmacfg);
        if (ret < 0) {
            hal_log_err("TX dma chan config failure.\n");
            goto out;
        }
        ret = hal_dma_prep_mode_device(dma_tx, PTR2U32(QSPI_REG_TXD(base)),
                                       PTR2U32(t->tx_data), txlen,
                                       DMA_MEM_TO_DEV, TYPE_IO_FAST);
        if (ret < 0) {
            hal_log_err("TX dma chan prepare failure.\n");
            goto out;
        }
        ret = hal_dma_chan_start(dma_tx);
        if (ret < 0) {
            hal_log_err("TX dma chan start failure.\n");
            goto out;
        }
        qspi_hw_start_transfer(base);
        ret = qspi_master_wait_dma_done(dma_tx, tmo_cnt);
        if (ret < 0) {
            hal_log_err("TX wait dma done timeout.\n");
            goto tx_stop;
        }
        ret = qspi_wait_transfer_done(base, tmo_cnt);
        if (ret < 0) {
            hal_log_err("TX wait transfer done timeout.\n");
            goto tx_stop;
        }
    tx_stop:
        qspi_hw_tx_dma_disable(base);
        hal_dma_chan_stop(dma_tx);
    } else if (t->rx_data) {
        rxlen = t->data_len;
        qspi->work_mode = QSPI_WORK_MODE_SYNC_RX_CPU;
        qspi_hw_rx_dma_enable(base);
        qspi_hw_set_transfer_cnt(base, 0, 0, rxlen, 0);
        dma_rx = qspi->dma_rx;
        dmacfg.direction = DMA_DEV_TO_MEM;
        dmacfg.slave_id = qspi->dma_cfg.port_id;
        dmacfg.src_addr = (unsigned long)QSPI_REG_RXD(base);
        dmacfg.dst_addr = (unsigned long)t->rx_data;

        if (!(rxlen % HAL_QSPI_DMA_4BYTES_LINE))
            dmacfg.src_addr_width = qspi->dma_cfg.dev_bus_width;
        else
            dmacfg.src_addr_width = DMA_SLAVE_BUSWIDTH_1_BYTE;
        dmacfg.src_maxburst = qspi->dma_cfg.dev_max_burst;
        dmacfg.dst_addr_width = qspi->dma_cfg.mem_bus_width;
        dmacfg.dst_maxburst = qspi->dma_cfg.mem_max_burst;

        ret = hal_dma_chan_config(dma_rx, &dmacfg);
        if (ret < 0) {
            hal_log_err("RX dma chan config failure.\n");
            goto out;
        }
        if (dmacfg.src_addr_width % HAL_QSPI_DMA_4BYTES_LINE)
            qspi_hw_dma_word_enable(base, false);
        else
            qspi_hw_dma_word_enable(base, true);
        ret = hal_dma_prep_mode_device(dma_rx, PTR2U32(t->rx_data),
                                       PTR2U32(QSPI_REG_RXD(base)), rxlen,
                                       DMA_DEV_TO_MEM, TYPE_IO_FAST);
        if (ret < 0) {
            hal_log_err("RX dma chan prepare failure.\n");
            goto out;
        }
        ret = hal_dma_chan_start(dma_rx);
        if (ret < 0) {
            hal_log_err("RX dma chan start failure.\n");
            goto out;
        }
        qspi_hw_start_transfer(base);
        ret = qspi_wait_transfer_done(base, tmo_cnt);
        if (ret < 0) {
            hal_log_err("RX wait transfer done timeout.\n");
            goto rx_stop;
        }
        ret = qspi_master_wait_dma_done(dma_rx, tmo_cnt);
        if (ret < 0) {
            hal_log_err("RX wait dma done timeout.\n");
            goto rx_stop;
        }
    rx_stop:
        qspi_hw_rx_dma_disable(base);
        hal_dma_chan_stop(dma_rx);
    }
out:
    qspi_hw_get_interrupt_status(base, &sts);
    qspi_hw_clear_interrupt_status(base, sts);
    return ret;
}

static int qspi_master_can_dma(struct qspi_master_state *qspi,
                               struct qspi_transfer *t)
{
    if (qspi->dma_rx == NULL || qspi->dma_tx == NULL)
        return 0;
    if (t->data_len <= QSPI_FIFO_DEPTH)
        return 0;
    if (t->tx_data) {
        /* Meet DMA's address align requirement */
        if (((unsigned long)t->tx_data) & (AIC_DMA_ALIGN_SIZE - 1))
            return 0;
    }
    if (t->rx_data) {
        /* Meet DMA's address align requirement */
        if (((unsigned long)t->rx_data) & (AIC_DMA_ALIGN_SIZE - 1))
            return 0;
    }

    return 1;
}
#endif

int hal_qspi_master_transfer_sync(qspi_master_handle *h,
                                  struct qspi_transfer *t)
{
    struct qspi_master_state *qspi;

    CHECK_PARAM(h, -EINVAL);
    CHECK_PARAM(t, -EINVAL);

    qspi = (struct qspi_master_state *)h;
#ifdef AIC_DMA_DRV
    if (qspi_master_can_dma(qspi, t))
        return qspi_master_transfer_dma_sync(qspi, t);
#endif
    return qspi_master_transfer_cpu_sync(qspi, t);
}

int hal_qspi_master_register_cb(qspi_master_handle *h, qspi_master_async_cb cb,
                                void *priv)
{
    struct qspi_master_state *qspi;

    CHECK_PARAM(h, -EINVAL);
    CHECK_PARAM(cb, -EINVAL);

    qspi = (struct qspi_master_state *)h;
    qspi->cb = cb;
    qspi->cb_priv = priv;

    return 0;
}

static int qspi_master_transfer_cpu_async(struct qspi_master_state *qspi,
                                          struct qspi_transfer *t)
{
    u32 base, txlen, tx_1line_cnt, rxlen;
    int ret = 0;

    base = qspi_hw_index_to_base(qspi->idx);

    if ((t->tx_data == NULL) && (t->rx_data == NULL))
        return -EINVAL;
    if (t->data_len == 0)
        return -EINVAL;

    qspi_hw_reset_fifo(base);
    qspi_hw_interrupt_disable(base, ICR_BIT_CPU_MSK);
    qspi->status = HAL_QSPI_STATUS_IN_PROGRESS;
    if (t->tx_data) {
        txlen = t->data_len;
        tx_1line_cnt = 0;
        if (qspi_hw_get_bus_width(base) == QSPI_BUS_WIDTH_SINGLE)
            tx_1line_cnt = txlen;
        qspi->work_mode = QSPI_WORK_MODE_ASYNC_TX_CPU;
        qspi->done_mask = HAL_QSPI_STATUS_ASYNC_TDONE;
        qspi->async_rx = NULL;
        qspi->async_rx_remain = 0;
        qspi->async_tx = t->tx_data;
        qspi->async_tx_remain = txlen;
        qspi_hw_set_transfer_cnt(base, txlen, tx_1line_cnt, 0, 0);
        qspi_hw_start_transfer(base);
    } else if (t->rx_data) {
        rxlen = t->data_len;
        qspi->work_mode = QSPI_WORK_MODE_ASYNC_RX_CPU;
        qspi->done_mask = HAL_QSPI_STATUS_ASYNC_TDONE;
        qspi->async_tx = NULL;
        qspi->async_tx_remain = 0;
        qspi->async_rx = t->rx_data;
        qspi->async_rx_remain = rxlen;
        qspi_hw_set_transfer_cnt(base, 0, 0, rxlen, 0);
        qspi_hw_start_transfer(base);
    }
    qspi_hw_interrupt_enable(base, ICR_BIT_CPU_MSK);

    return ret;
}

#ifdef AIC_DMA_DRV
static void qspi_master_dma_tx_callback(void *h)
{
    struct qspi_master_state *qspi = h;
    struct aic_dma_chan *dma_tx = qspi->dma_tx;
    u32 base;

    qspi->status |= HAL_QSPI_STATUS_ASYNC_DMA_DONE;
    if (QSPI_IS_ASYNC_ALL_DONE(qspi->status, qspi->done_mask)) {
        base = qspi_hw_index_to_base(qspi->idx);
        qspi_hw_tx_dma_disable(base);
        hal_dma_chan_stop(dma_tx);
        if (qspi->cb)
            qspi->cb(h, qspi->cb_priv);
    }
}

static void qspi_master_dma_rx_callback(void *h)
{
    struct qspi_master_state *qspi = h;
    struct aic_dma_chan *dma_rx = qspi->dma_rx;
    u32 base;

    qspi->status |= HAL_QSPI_STATUS_ASYNC_DMA_DONE;
    if (QSPI_IS_ASYNC_ALL_DONE(qspi->status, qspi->done_mask)) {
        base = qspi_hw_index_to_base(qspi->idx);
        qspi_hw_rx_dma_disable(base);
        hal_dma_chan_stop(dma_rx);
        if (qspi->cb)
            qspi->cb(h, qspi->cb_priv);
    }
}

static int qspi_master_transfer_dma_async(struct qspi_master_state *qspi,
                                          struct qspi_transfer *t)
{
    u32 base, txlen, tx_1line_cnt, rxlen;
    struct aic_dma_chan *dma_rx, *dma_tx;
    struct dma_slave_config dmacfg;
    int ret = 0;

    base = qspi_hw_index_to_base(qspi->idx);

    if ((t->tx_data == NULL) && (t->rx_data == NULL))
        return -EINVAL;
    if (t->data_len == 0)
        return -EINVAL;

    qspi_hw_reset_fifo(base);
    qspi_hw_interrupt_disable(base, ICR_BIT_DMA_MSK);
    qspi->status = HAL_QSPI_STATUS_IN_PROGRESS;
    if (t->tx_data) {
        txlen = t->data_len;
        tx_1line_cnt = 0;
        if (qspi_hw_get_bus_width(base) == QSPI_BUS_WIDTH_SINGLE)
            tx_1line_cnt = txlen;
        qspi_hw_tx_dma_enable(base);
        qspi->work_mode = QSPI_WORK_MODE_ASYNC_TX_DMA;
        qspi->done_mask = HAL_QSPI_STATUS_ASYNC_ALL_DONE;
        qspi_hw_set_transfer_cnt(base, txlen, tx_1line_cnt, 0, 0);
        dma_tx = qspi->dma_tx;
        dmacfg.direction = DMA_MEM_TO_DEV;
        dmacfg.src_addr = (unsigned long)t->tx_data;
        dmacfg.dst_addr = (unsigned long)QSPI_REG_TXD(base);

        dmacfg.src_addr_width = DMA_SLAVE_BUSWIDTH_16_BYTES;
        dmacfg.src_maxburst = 16;
        dmacfg.dst_addr_width = DMA_SLAVE_BUSWIDTH_4_BYTES;
        dmacfg.dst_maxburst = 1;

        dmacfg.slave_id = qspi->dma_cfg.port_id;
        ret = hal_dma_chan_config(dma_tx, &dmacfg);
        if (ret)
            goto out;
        hal_dma_chan_register_cb(dma_tx, qspi_master_dma_tx_callback, qspi);
        ret = hal_dma_prep_mode_device(dma_tx, PTR2U32(QSPI_REG_TXD(base)),
                                       PTR2U32(t->tx_data), txlen,
                                       DMA_MEM_TO_DEV, TYPE_IO_FAST);
        if (ret)
            goto out;
        ret = hal_dma_chan_start(dma_tx);
        if (ret)
            goto out;
        qspi_hw_start_transfer(base);
    } else if (t->rx_data) {
        rxlen = t->data_len;
        qspi_hw_rx_dma_enable(base);
        qspi->work_mode = QSPI_WORK_MODE_ASYNC_RX_DMA;
        qspi->done_mask = HAL_QSPI_STATUS_ASYNC_ALL_DONE;
        qspi_hw_set_transfer_cnt(base, 0, 0, rxlen, 0);
        dma_rx = qspi->dma_rx;
        dmacfg.direction = DMA_DEV_TO_MEM;
        dmacfg.src_addr = (unsigned long)QSPI_REG_RXD(base);

        dmacfg.dst_addr = (unsigned long)t->rx_data;

        dmacfg.src_addr_width = DMA_SLAVE_BUSWIDTH_4_BYTES;
        dmacfg.src_maxburst = 1;
        dmacfg.dst_addr_width = DMA_SLAVE_BUSWIDTH_16_BYTES;
        dmacfg.dst_maxburst = 16;

        dmacfg.slave_id = qspi->dma_cfg.port_id;
        ret = hal_dma_chan_config(dma_rx, &dmacfg);
        if (ret)
            goto out;
        if (dmacfg.src_addr_width % HAL_QSPI_DMA_4BYTES_LINE)
            qspi_hw_dma_word_enable(base, false);
        else
            qspi_hw_dma_word_enable(base, true);
        hal_dma_chan_register_cb(dma_rx, qspi_master_dma_rx_callback, qspi);
        ret = hal_dma_prep_mode_device(dma_rx, PTR2U32(t->rx_data),
                                       PTR2U32(QSPI_REG_RXD(base)), rxlen,
                                       DMA_DEV_TO_MEM, TYPE_IO_FAST);
        if (ret)
            goto out;
        ret = hal_dma_chan_start(dma_rx);
        if (ret)
            goto out;
        qspi_hw_start_transfer(base);
    }
    qspi_hw_interrupt_enable(base, ICR_BIT_DMA_MSK);
out:
    return ret;
}
#endif

int hal_qspi_master_transfer_async(qspi_master_handle *h,
                                   struct qspi_transfer *t)
{
    struct qspi_master_state *qspi;

    CHECK_PARAM(h, -EINVAL);
    CHECK_PARAM(t, -EINVAL);

    qspi = (struct qspi_master_state *)h;
#ifdef AIC_DMA_DRV
    if (qspi_master_can_dma(qspi, t))
        return qspi_master_transfer_dma_async(qspi, t);
#endif
    return qspi_master_transfer_cpu_async(qspi, t);
}

void hal_qspi_master_irq_handler(qspi_master_handle *h)
{
    struct qspi_master_state *qspi;
    u32 base, sts;

    CHECK_PARAM_RET(h);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);
    qspi_hw_get_interrupt_status(base, &sts);
    if (sts & ISTS_BIT_TF_UDR)
        qspi->status |= HAL_QSPI_STATUS_TX_UNDER_RUN;
    if (sts & ISTS_BIT_TF_OVF)
        qspi->status |= HAL_QSPI_STATUS_TX_OVER_FLOW;

    if ((sts & ISTS_BIT_TF_EMP) || (sts & ISTS_BIT_TF_RDY)) {
        u32 dolen, free_len;
        if ((qspi->work_mode == QSPI_WORK_MODE_ASYNC_TX_CPU) &&
            qspi->async_tx && qspi->async_tx_remain) {
            free_len = QSPI_FIFO_DEPTH - qspi_hw_get_tx_fifo_cnt(base);
            dolen = min(free_len, qspi->async_tx_remain);
            qspi_hw_write_fifo(base, qspi->async_tx, dolen);
            qspi->async_tx += dolen;
            qspi->async_tx_remain -= dolen;
        }
    }

    if (sts & ISTS_BIT_RF_UDR)
        qspi->status |= HAL_QSPI_STATUS_RX_UNDER_RUN;
    if (sts & ISTS_BIT_RF_OVF)
        qspi->status |= HAL_QSPI_STATUS_RX_OVER_FLOW;
    if ((sts & ISTS_BIT_RF_FUL) || (sts & ISTS_BIT_RF_RDY) ||
        (sts & ISTS_BIT_TDONE)) {
        u32 dolen;
        if ((qspi->work_mode == QSPI_WORK_MODE_ASYNC_RX_CPU) &&
            qspi->async_rx && qspi->async_rx_remain) {
            dolen = qspi_hw_get_rx_fifo_cnt(base);
            if (dolen > qspi->async_rx_remain)
                dolen = qspi->async_rx_remain;
            qspi_hw_read_fifo(base, qspi->async_rx, dolen);
            qspi->async_rx += dolen;
            qspi->async_rx_remain -= dolen;
        }
    }
    if (sts & ISTS_BIT_TDONE) {
        if (qspi->status == HAL_QSPI_STATUS_IN_PROGRESS)
            qspi->status = HAL_QSPI_STATUS_OK;
        else
            qspi->status &= ~HAL_QSPI_STATUS_IN_PROGRESS;
        qspi_hw_interrupt_disable(base, ICR_BIT_ALL_MSK);
        qspi->async_rx = NULL;
        qspi->async_rx_remain = 0;
        qspi->async_tx = NULL;
        qspi->async_tx_remain = 0;
        qspi->status |= HAL_QSPI_STATUS_ASYNC_TDONE;
        if (QSPI_IS_ASYNC_ALL_DONE(qspi->status, qspi->done_mask)) {
#ifdef AIC_DMA_DRV
            if (qspi->work_mode == QSPI_WORK_MODE_ASYNC_TX_DMA)
                hal_dma_chan_stop(qspi->dma_tx);
            if (qspi->work_mode == QSPI_WORK_MODE_ASYNC_RX_DMA)
                hal_dma_chan_stop(qspi->dma_rx);
#endif
            if (qspi->cb)
                qspi->cb(h, qspi->cb_priv);
        }
    }
    qspi_hw_clear_interrupt_status(base, sts);
}

int hal_qspi_master_get_status(qspi_master_handle *h)
{
    struct qspi_master_state *qspi;

    CHECK_PARAM(h, -EINVAL);
    qspi = (struct qspi_master_state *)h;
    return (qspi->status) & (~HAL_QSPI_STATUS_INTERNAL_MSK);
}

#ifdef AIC_QSPI_DRV_V11
int hal_qspi_master_set_qio_mode(qspi_master_handle *h)
{
    struct qspi_master_state *qspi;
    u32 base;

    CHECK_PARAM(h, -EINVAL);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    qspi_hw_set_bus_width(base, 4);
    qspi_hw_set_qio_mode(base);

    return 0;
}

void hal_qspi_master_set_cs_owner(qspi_master_handle *h, u8 soft_hw)
{
    struct qspi_master_state *qspi;
    u32 base;

    CHECK_PARAM_RET(h);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    if (soft_hw == QSPI_CS_CTL_BY_SW) {
        qspi_hw_set_cs_owner(base, QSPI_CS_CTL_BY_SW);
    } else {
        qspi_hw_set_cs_owner(base, QSPI_CS_CTL_BY_HW);
    }
}

void hal_qspi_master_set_xip_burst_cfg(qspi_master_handle *h,
                                       struct qspi_xip_burst_cfg *cfg)
{
    struct qspi_master_state *qspi;
    u32 base;

    CHECK_PARAM_RET(h);
    CHECK_PARAM_RET(cfg);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    qspi_hw_set_wrap_len(base, cfg->wrap.auto_wl8, cfg->wrap.auto_wl16,
                         cfg->wrap.auto_wl32, cfg->wrap.auto_wl64);

    qspi_hw_set_btr_cmd_index(base, cfg->cmd_set_burst);
    qspi_hw_set_btr_dummy_byte(base, cfg->cmd_dummy_byte);
    if (cfg->cmd_bits_width)
        qspi_hw_set_btr_width(base, 1);
    if (cfg->wrap_en == HAL_XIP_BURST_WRAPPED_WITH_FIXED_LEN)
        qspi_hw_set_btr_wrap_en(base, 1);
    if (cfg->wrap_en == HAL_XIP_BURST_WRAPPED_WITH_AUTO_SEL_LEN) {
        qspi_hw_set_btr_wrap_en(base, 1);
        qspi_hw_set_btr_auto_wrap_len_en(base, 1);
    }
    qspi_hw_set_btr_burst_wrap(base, cfg->wrap.fixed_len);
    qspi_hw_set_btr_burst_linear(base, cfg->wrap.disable);
}

void hal_qspi_master_set_xip_read_cfg(qspi_master_handle *h,
                                      struct qspi_xip_read_cfg *cfg)
{
    struct qspi_master_state *qspi;
    u32 base;

    CHECK_PARAM_RET(h);
    CHECK_PARAM_RET(cfg);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    qspi_hw_set_rcm_cmd_index(base, cfg->read_cmd);
    qspi_hw_set_rcm_dummy_byte(base, cfg->dummy_byte);
    if (cfg->addr_mode)
        qspi_hw_set_rcm_addr_4byte_en(base, 1);
    qspi_hw_set_rcm_rdmode_byte_en(base, 1);
    if (cfg->read_cmd_bypass_en)
        qspi_hw_set_rcm_rdcmd_bypass_en(base, 1);

    qspi_hw_set_rcm_rdcmd_bypass_code(base, cfg->mode.bypass);
    qspi_hw_set_rcm_rdcmd_normal_code(base, cfg->mode.normal);
}

void hal_qspi_master_xip_enable(qspi_master_handle *h, bool enable)
{
    struct qspi_master_state *qspi;
    u32 base;

    CHECK_PARAM_RET(h);

    qspi = (struct qspi_master_state *)h;
    base = qspi_hw_index_to_base(qspi->idx);

    qspi_hw_set_xip_en(base, enable);
}

#endif /* AIC_QSPI_DRV_V11 */