rt-thread/bsp/phytium/libraries/drivers/drv_sdif.c

532 lines
16 KiB
C

/*
* Copyright (c) 2006-2023, RT-Thread Development Team
*
* SPDX-License-Identifier: Apache-2.0
*
* Email: opensource_embedded@phytium.com.cn
*
* Change Logs:
* Date Author Notes
* 2023/7/11 liqiaozhong init SD card and mount file system
* 2023/11/8 zhugengyu add interrupt handling for dma waiting, unify function naming
*/
/***************************** Include Files *********************************/
#include"rtconfig.h"
#ifdef BSP_USING_SDIF
#include <rthw.h>
#include <rtdef.h>
#include <rtthread.h>
#include <rtdevice.h>
#include <rtdbg.h>
#include <drivers/mmcsd_core.h>
#ifdef RT_USING_SMART
#include "ioremap.h"
#endif
#include "mm_aspace.h"
#include "interrupt.h"
#define LOG_TAG "sdif_drv"
#include "drv_log.h"
#include "ftypes.h"
#include "fparameters.h"
#include "fcpu_info.h"
#include "fsdif_timing.h"
#include "fsdif.h"
#include "fsdif_hw.h"
#include "drv_sdif.h"
/************************** Constant Definitions *****************************/
#ifdef USING_SDIF0
#define SDIF_CONTROLLER_ID FSDIF0_ID
#elif defined (USING_SDIF1)
#define SDIF_CONTROLLER_ID FSDIF1_ID
#endif
#define SDIF_MALLOC_CAP_DESC 256U
#define SDIF_DMA_ALIGN 512U
#define SDIF_DMA_BLK_SZ 512U
#define SDIF_VALID_OCR 0x00FFFF80 /* supported voltage range is 1.65v-3.6v (VDD_165_195-VDD_35_36) */
#define SDIF_MAX_BLK_TRANS 20U
#ifndef CONFIG_SDCARD_OFFSET
#define CONFIG_SDCARD_OFFSET 0x0U
#endif
/* preserve pointer to host instance */
static struct rt_mmcsd_host *mmc_host[FSDIF_NUM] = {RT_NULL};
/**************************** Type Definitions *******************************/
typedef struct
{
FSdif *mmcsd_instance;
FSdifIDmaDesc *rw_desc;
rt_err_t (*transfer)(struct rt_mmcsd_host *host, struct rt_mmcsd_req *req, FSdifCmdData *cmd_data_p);
struct rt_event event;
#define SDIF_EVENT_CARD_DETECTED (1 << 0)
#define SDIF_EVENT_COMMAND_DONE (1 << 1)
#define SDIF_EVENT_DATA_DONE (1 << 2)
#define SDIF_EVENT_ERROR_OCCUR (1 << 3)
#define SDIF_EVENT_SDIO_IRQ (1 << 4)
} fsdif_info_t;
/************************** Variable Definitions *****************************/
/***************** Macros (Inline Functions) Definitions *********************/
void fsdif_change(void);
/*******************************Api Functions*********************************/
static void fsdif_host_relax(void)
{
rt_thread_mdelay(1);
}
static void fsdif_card_detect_callback(FSdif *const mmcsd_instance, void *args, u32 status, u32 dmac_status)
{
struct rt_mmcsd_host *host = (struct rt_mmcsd_host *)args;
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
rt_event_send(&private_data->event, SDIF_EVENT_CARD_DETECTED);
fsdif_change();
}
static void fsdif_command_done_callback(FSdif *const mmcsd_instance, void *args, u32 status, u32 dmac_status)
{
struct rt_mmcsd_host *host = (struct rt_mmcsd_host *)args;
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
rt_event_send(&private_data->event, SDIF_EVENT_COMMAND_DONE);
}
static void fsdif_data_done_callback(FSdif *const mmcsd_instance, void *args, u32 status, u32 dmac_status)
{
struct rt_mmcsd_host *host = (struct rt_mmcsd_host *)args;
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
rt_event_send(&private_data->event, SDIF_EVENT_DATA_DONE);
}
static void fsdif_sdio_irq_callback(FSdif *const mmcsd_instance, void *args, u32 status, u32 dmac_status)
{
struct rt_mmcsd_host *host = (struct rt_mmcsd_host *)args;
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
rt_event_send(&private_data->event, SDIF_EVENT_SDIO_IRQ);
}
static void fsdif_error_occur_callback(FSdif *const mmcsd_instance, void *args, u32 status, u32 dmac_status)
{
struct rt_mmcsd_host *host = (struct rt_mmcsd_host *)args;
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
rt_event_send(&private_data->event, SDIF_EVENT_ERROR_OCCUR);
}
static void fsdif_ctrl_setup_interrupt(struct rt_mmcsd_host *host)
{
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
FSdif *mmcsd_instance = private_data->mmcsd_instance;
FSdifConfig *config_p = &mmcsd_instance->config;
rt_uint32_t cpu_id = 0;
GetCpuId((u32 *)&cpu_id);
rt_hw_interrupt_set_target_cpus(config_p->irq_num, cpu_id);
rt_hw_interrupt_set_priority(config_p->irq_num, 0xd0);
/* register intr callback */
rt_hw_interrupt_install(config_p->irq_num,
FSdifInterruptHandler,
mmcsd_instance,
NULL);
/* enable irq */
rt_hw_interrupt_umask(config_p->irq_num);
FSdifRegisterEvtHandler(mmcsd_instance, FSDIF_EVT_CARD_DETECTED, fsdif_card_detect_callback, host);
FSdifRegisterEvtHandler(mmcsd_instance, FSDIF_EVT_ERR_OCCURE, fsdif_error_occur_callback, host);
FSdifRegisterEvtHandler(mmcsd_instance, FSDIF_EVT_CMD_DONE, fsdif_command_done_callback, host);
FSdifRegisterEvtHandler(mmcsd_instance, FSDIF_EVT_DATA_DONE, fsdif_data_done_callback, host);
FSdifRegisterEvtHandler(mmcsd_instance, FSDIF_EVT_SDIO_IRQ, fsdif_sdio_irq_callback, host);
return;
}
static rt_err_t fsdif_ctrl_init(struct rt_mmcsd_host *host)
{
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
FSdif *mmcsd_instance = RT_NULL;
const FSdifConfig *default_mmcsd_config = RT_NULL;
FSdifConfig mmcsd_config;
FSdifIDmaDesc *rw_desc = RT_NULL;
mmcsd_instance = rt_malloc(sizeof(FSdif));
if (!mmcsd_instance)
{
LOG_E("Malloc mmcsd_instance failed");
return -RT_ERROR;
}
rw_desc = rt_malloc_align(SDIF_MAX_BLK_TRANS * sizeof(FSdifIDmaDesc), SDIF_MALLOC_CAP_DESC);
if (!rw_desc)
{
LOG_E("Malloc rw_desc failed");
return -RT_ERROR;
}
rt_memset(mmcsd_instance, 0, sizeof(FSdif));
rt_memset(rw_desc, 0, SDIF_MAX_BLK_TRANS * sizeof(FSdifIDmaDesc));
/* SDIF controller init */
RT_ASSERT((default_mmcsd_config = FSdifLookupConfig(SDIF_CONTROLLER_ID)) != RT_NULL);
mmcsd_config = *default_mmcsd_config; /* load default config */
#ifdef RT_USING_SMART
mmcsd_config.base_addr = (uintptr)rt_ioremap((void *)mmcsd_config.base_addr, 0x1000);
#endif
mmcsd_config.trans_mode = FSDIF_IDMA_TRANS_MODE;
#ifdef USING_EMMC
mmcsd_config.non_removable = TRUE; /* eMMC is unremovable on board */
#else
mmcsd_config.non_removable = FALSE; /* TF card is removable on board */
#endif
mmcsd_config.get_tuning = FSdifGetTimingSetting;
if (FSDIF_SUCCESS != FSdifCfgInitialize(mmcsd_instance, &mmcsd_config))
{
LOG_E("SDIF controller init failed.");
return -RT_ERROR;
}
if (FSDIF_SUCCESS != FSdifSetIDMAList(mmcsd_instance, rw_desc, (uintptr)rw_desc + PV_OFFSET, SDIF_MAX_BLK_TRANS))
{
LOG_E("SDIF controller setup DMA failed.");
return -RT_ERROR;
}
mmcsd_instance->desc_list.first_desc_dma = (uintptr)rw_desc + PV_OFFSET;
FSdifRegisterRelaxHandler(mmcsd_instance, fsdif_host_relax); /* SDIF delay for a while */
private_data->mmcsd_instance = mmcsd_instance;
private_data->rw_desc = rw_desc;
fsdif_ctrl_setup_interrupt(host);
return RT_EOK;
}
rt_inline rt_err_t fsdif_dma_transfer(struct rt_mmcsd_host *host, struct rt_mmcsd_req *req, FSdifCmdData *req_cmd)
{
FError ret = FT_SUCCESS;
rt_uint32_t event = 0U;
rt_uint32_t wait_event = 0U;
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
FSdif *mmcsd_instance = private_data->mmcsd_instance;
if (req_cmd->data_p == RT_NULL)
{
wait_event = SDIF_EVENT_COMMAND_DONE;
}
else
{
wait_event = SDIF_EVENT_COMMAND_DONE | SDIF_EVENT_DATA_DONE;
}
ret = FSdifDMATransfer(mmcsd_instance, req_cmd);
if (ret != FT_SUCCESS)
{
LOG_E("FSdifDMATransfer() fail.");
return -RT_ERROR;
}
while (TRUE)
{
if (rt_event_recv(&private_data->event,
(wait_event),
(RT_EVENT_FLAG_AND | RT_EVENT_FLAG_CLEAR | RT_WAITING_NO),
rt_tick_from_millisecond(5000),
&event) == RT_EOK)
{
(void)FSdifGetCmdResponse(mmcsd_instance, req_cmd);
break;
}
else
{
if (rt_event_recv(&private_data->event,
(SDIF_EVENT_ERROR_OCCUR),
(RT_EVENT_FLAG_CLEAR | RT_WAITING_NO),
rt_tick_from_millisecond(5000),
&event) == RT_EOK)
{
LOG_E("Sdif DMA transfer endup with error !!!");
return -RT_EIO;
}
}
fsdif_host_relax();
}
if (resp_type(req->cmd) & RESP_MASK)
{
if (resp_type(req->cmd) == RESP_R2)
{
req->cmd->resp[3] = req_cmd->response[0];
req->cmd->resp[2] = req_cmd->response[1];
req->cmd->resp[1] = req_cmd->response[2];
req->cmd->resp[0] = req_cmd->response[3];
}
else
{
req->cmd->resp[0] = req_cmd->response[0];
}
}
return RT_EOK;
}
static void fsdif_request_send(struct rt_mmcsd_host *host, struct rt_mmcsd_req *req)
{
/* ignore some SDIF-ONIY cmd */
if ((req->cmd->cmd_code == SD_IO_SEND_OP_COND) || (req->cmd->cmd_code == SD_IO_RW_DIRECT))
{
req->cmd->err = -1;
goto skip_cmd;
}
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
FSdifCmdData req_cmd;
FSdifCmdData req_stop;
FSdifData req_data;
rt_uint32_t *data_buf_aligned = RT_NULL;
rt_uint32_t cmd_flag = resp_type(req->cmd);
rt_memset(&req_cmd, 0, sizeof(FSdifCmdData));
rt_memset(&req_stop, 0, sizeof(FSdifCmdData));
rt_memset(&req_data, 0, sizeof(FSdifData));
/* convert req into ft driver type */
if (req->cmd->cmd_code == GO_IDLE_STATE)
{
req_cmd.flag |= FSDIF_CMD_FLAG_NEED_INIT;
}
if (req->cmd->cmd_code == GO_INACTIVE_STATE)
{
req_cmd.flag |= FSDIF_CMD_FLAG_NEED_AUTO_STOP;
}
if ((cmd_flag != RESP_R3) && (cmd_flag != RESP_R4) && (cmd_flag != RESP_NONE))
{
req_cmd.flag |= FSDIF_CMD_FLAG_NEED_RESP_CRC;
}
if (cmd_flag & RESP_MASK)
{
req_cmd.flag |= FSDIF_CMD_FLAG_EXP_RESP;
if (cmd_flag == RESP_R2)
{
req_cmd.flag |= FSDIF_CMD_FLAG_EXP_LONG_RESP;
}
}
if (req->data) /* transfer command with data */
{
data_buf_aligned = rt_malloc_align(SDIF_DMA_BLK_SZ * req->data->blks, SDIF_DMA_ALIGN);
if (!data_buf_aligned)
{
LOG_E("Malloc data_buf_aligned failed");
return;
}
rt_memset(data_buf_aligned, 0, SDIF_DMA_BLK_SZ * req->data->blks);
req_cmd.flag |= FSDIF_CMD_FLAG_EXP_DATA;
req_data.blksz = req->data->blksize;
req_data.blkcnt = req->data->blks + CONFIG_SDCARD_OFFSET;
req_data.datalen = req->data->blksize * req->data->blks;
if ((uintptr)req->data->buf % SDIF_DMA_ALIGN) /* data buffer should be 512-aligned */
{
if (req->data->flags & DATA_DIR_WRITE)
{
rt_memcpy((void *)data_buf_aligned, (void *)req->data->buf, req_data.datalen);
}
req_data.buf = (rt_uint8_t *)data_buf_aligned;
req_data.buf_dma = (uintptr)data_buf_aligned + PV_OFFSET;
}
else
{
req_data.buf = (rt_uint8_t *)req->data->buf;
req_data.buf_dma = (uintptr)req->data->buf + PV_OFFSET;
}
req_cmd.data_p = &req_data;
if (req->data->flags & DATA_DIR_READ)
{
req_cmd.flag |= FSDIF_CMD_FLAG_READ_DATA;
}
else if (req->data->flags & DATA_DIR_WRITE)
{
req_cmd.flag |= FSDIF_CMD_FLAG_WRITE_DATA;
}
}
req_cmd.cmdidx = req->cmd->cmd_code;
req_cmd.cmdarg = req->cmd->arg;
/* do cmd and data transfer */
req->cmd->err = (private_data->transfer)(host, req, &req_cmd);
if (req->cmd->err != RT_EOK)
{
LOG_E("transfer failed in %s", __func__);
}
if (req->data && (req->data->flags & DATA_DIR_READ))
{
if ((uintptr)req->data->buf % SDIF_DMA_ALIGN) /* data buffer should be 512-aligned */
{
rt_memcpy((void *)req->data->buf, (void *)data_buf_aligned, req_data.datalen);
}
}
/* stop cmd */
if (req->stop)
{
req_stop.cmdidx = req->stop->cmd_code;
req_stop.cmdarg = req->stop->arg;
if (req->stop->flags & RESP_MASK)
{
req_stop.flag |= FSDIF_CMD_FLAG_READ_DATA;
if (resp_type(req->stop) == RESP_R2)
{
req_stop.flag |= FSDIF_CMD_FLAG_EXP_LONG_RESP;
}
}
req->stop->err = (private_data->transfer)(host, req, &req_stop);
}
if (data_buf_aligned)
{
rt_free_align(data_buf_aligned);
}
skip_cmd:
mmcsd_req_complete(host);
}
static void fsdif_set_iocfg(struct rt_mmcsd_host *host, struct rt_mmcsd_io_cfg *io_cfg)
{
FError ret = FT_SUCCESS;
fsdif_info_t *private_data = (fsdif_info_t *)host->private_data;
FSdif *mmcsd_instance = private_data->mmcsd_instance;
uintptr base_addr = mmcsd_instance->config.base_addr;
if (0 != io_cfg->clock)
{
ret = FSdifSetClkFreq(mmcsd_instance, io_cfg->clock);
if (ret != FT_SUCCESS)
{
LOG_E("FSdifSetClkFreq fail.");
}
}
switch (io_cfg->bus_width)
{
case MMCSD_BUS_WIDTH_1:
FSdifSetBusWidth(base_addr, 1U);
break;
case MMCSD_BUS_WIDTH_4:
FSdifSetBusWidth(base_addr, 4U);
break;
case MMCSD_BUS_WIDTH_8:
FSdifSetBusWidth(base_addr, 8U);
break;
default:
LOG_E("Invalid bus width %d", io_cfg->bus_width);
break;
}
}
static const struct rt_mmcsd_host_ops ops =
{
fsdif_request_send,
fsdif_set_iocfg,
RT_NULL,
RT_NULL,
RT_NULL,
};
void fsdif_change(void)
{
mmcsd_change(mmc_host[SDIF_CONTROLLER_ID]);
}
int rt_hw_fsdif_init(void)
{
/* variables init */
struct rt_mmcsd_host *host = RT_NULL;
fsdif_info_t *private_data = RT_NULL;
rt_err_t result = RT_EOK;
host = mmcsd_alloc_host();
if (!host)
{
LOG_E("Alloc host failed");
goto err_free;
}
private_data = rt_malloc(sizeof(fsdif_info_t));
if (!private_data)
{
LOG_E("Malloc private_data failed");
goto err_free;
}
rt_memset(private_data, 0, sizeof(fsdif_info_t));
private_data->transfer = fsdif_dma_transfer;
result = rt_event_init(&private_data->event, "sdif_event", RT_IPC_FLAG_FIFO);
RT_ASSERT(RT_EOK == result);
/* host data init */
host->ops = &ops;
host->freq_min = 400000;
host->freq_max = 50000000;
host->valid_ocr = SDIF_VALID_OCR; /* the voltage range supported is 1.65v-3.6v */
host->flags = MMCSD_MUTBLKWRITE | MMCSD_BUSWIDTH_4;
host->max_seg_size = SDIF_DMA_BLK_SZ; /* used in block_dev.c */
host->max_dma_segs = SDIF_MAX_BLK_TRANS; /* physical segment number */
host->max_blk_size = SDIF_DMA_BLK_SZ; /* all the 4 para limits size of one blk tran */
host->max_blk_count = SDIF_MAX_BLK_TRANS;
host->private_data = private_data;
mmc_host[SDIF_CONTROLLER_ID] = host;
if (RT_EOK != fsdif_ctrl_init(host))
{
LOG_E("fsdif_ctrl_init() failed");
goto err_free;
}
return RT_EOK;
err_free:
if (host)
{
rt_free(host);
}
if (private_data->mmcsd_instance)
{
rt_free(private_data->mmcsd_instance);
}
if (private_data->rw_desc)
{
rt_free_align(private_data->rw_desc);
}
if (private_data)
{
rt_free(private_data);
}
return -RT_EOK;
}
INIT_DEVICE_EXPORT(rt_hw_fsdif_init);
#endif // #ifdef RT_USING_SDIO