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luban-lite-t3e-pro/bsp/artinchip/drv_bare/spinor/sfud_port.c
刘可亮 7bbc029dae v1.0.0
2023-08-30 16:21:18 +08:00

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11 KiB
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/*
* Copyright (c) 2023, Artinchip Technology Co., Ltd
*
* SPDX-License-Identifier: Apache-2.0
*
* Wu Dehuang <dehuang.wu@artinchip.com>
*/
#include <rtconfig.h>
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <string.h>
#include <sfud.h>
#include <aic_common.h>
#include <aic_core.h>
#include <aic_soc.h>
#include <aic_log.h>
#include <aic_hal.h>
#include <hal_qspi.h>
#include <hal_dma.h>
#include <aic_dma_id.h>
#include <aic_clk_id.h>
#include <mtd.h>
#include <aic_osal.h>
#include <partition_table.h>
#ifdef IMAGE_CFG_JSON_PARTS_MTD
#define NOR_MTD_PARTS IMAGE_CFG_JSON_PARTS_MTD
#else
#define NOR_MTD_PARTS ""
#endif
#define SFUD_READ_SFDP_FREQ 50000000
#define QSPI_MAX_CNT 4
struct aic_qspi_bus
{
char *name;
u32 idx;
u32 clk_id;
u32 clk_in_hz;
u32 bus_hz;
u32 dma_port_id;
u32 irq_num;
qspi_master_handle handle;
int probe_flag;
sfud_flash attached_flash;
};
static struct aic_qspi_bus qspi_bus_arr[] = {
#if defined(AIC_USING_QSPI0)
{
.name = "qspi0",
.idx = 0,
.clk_id = CLK_QSPI0,
.clk_in_hz = AIC_DEV_QSPI0_MAX_SRC_FREQ_HZ,
.bus_hz = AIC_QSPI0_DEVICE_SPINOR_FREQ,
.dma_port_id = DMA_ID_SPI0,
.irq_num = QSPI0_IRQn,
},
#endif
#if defined(AIC_USING_QSPI1)
{
.name = "qspi1",
.idx = 1,
.clk_id = CLK_QSPI1,
.clk_in_hz = AIC_DEV_QSPI1_MAX_SRC_FREQ_HZ,
.bus_hz = AIC_QSPI1_DEVICE_SPINOR_FREQ,
.dma_port_id = DMA_ID_SPI1,
.irq_num = QSPI1_IRQn,
},
#endif
#if defined(AIC_USING_QSPI2)
{
.name = "qspi2",
.idx = 2,
.clk_id = CLK_QSPI2,
.clk_in_hz = AIC_DEV_QSPI2_MAX_SRC_FREQ_HZ,
.bus_hz = AIC_QSPI2_DEVICE_SPINOR_FREQ,
.dma_port_id = DMA_ID_SPI2,
.irq_num = QSPI2_IRQn,
},
#endif
#if defined(AIC_USING_QSPI3)
{
.name = "qspi3",
.idx = 3,
.clk_id = CLK_QSPI3,
.clk_in_hz = AIC_DEV_QSPI3_MAX_SRC_FREQ_HZ,
.bus_hz = AIC_QSPI3_DEVICE_SPINOR_FREQ,
.dma_port_id = DMA_ID_SPI3,
.irq_num = QSPI3_IRQn,
},
#endif
};
static void retry_delay_100us(void)
{
aicos_udelay(100);
}
static struct aic_qspi_bus *get_qspi_by_index(u32 idx)
{
struct aic_qspi_bus *qspi;
u32 i;
qspi = NULL;
for (i = 0; i < ARRAY_SIZE(qspi_bus_arr); i++) {
if (i == idx) {
qspi = &qspi_bus_arr[i];
break;
}
}
return qspi;
}
static u32 address_copy(u32 addr, u32 size, uint8_t *dst)
{
u32 i;
i = 0;
while (size) {
dst[i++] = (addr >> (8 * (size - 1))) & 0xFF;
size--;
}
return i;
}
#ifdef SFUD_USING_QSPI
static sfud_err qspi_read(const struct __sfud_spi *spi, u32 addr,
sfud_qspi_read_cmd_format *rd_fmt, uint8_t *read_buf,
size_t read_size)
{
struct aic_qspi_bus *qspi;
struct qspi_transfer t;
uint8_t cmdbuf1[16];
uint8_t cmdbuf2[16];
u32 addrsiz;
int ret, single_cnt, rest_cnt, dummy_cnt, rest_buswidth;
qspi = (struct aic_qspi_bus *)spi->user_data;
single_cnt = 0;
rest_cnt = 0;
rest_buswidth = HAL_QSPI_BUS_WIDTH_SINGLE;
dummy_cnt = (rd_fmt->address_lines * rd_fmt->dummy_cycles / 8);
if (rd_fmt->instruction_lines == 1) {
cmdbuf1[single_cnt] = rd_fmt->instruction;
single_cnt++;
} else if (rd_fmt->instruction_lines > 1) {
cmdbuf2[rest_cnt] = rd_fmt->instruction;
rest_cnt++;
if (rd_fmt->instruction_lines > rest_buswidth)
rest_buswidth = rd_fmt->instruction_lines;
}
addrsiz = rd_fmt->address_size / 8;
if (rd_fmt->address_lines == 1) {
single_cnt += address_copy(addr, addrsiz, &cmdbuf1[single_cnt]);
memset(&cmdbuf1[single_cnt], 0, dummy_cnt);
single_cnt += dummy_cnt;
} else if (rd_fmt->address_lines > 1) {
rest_cnt += address_copy(addr, addrsiz, &cmdbuf2[rest_cnt]);
memset(&cmdbuf2[rest_cnt], 0, dummy_cnt);
rest_cnt += dummy_cnt;
if (rd_fmt->address_lines > rest_buswidth)
rest_buswidth = rd_fmt->address_lines;
}
hal_qspi_master_set_cs(&qspi->handle, 0, true);
/* Command phase */
if (single_cnt) {
hal_qspi_master_set_bus_width(&qspi->handle, HAL_QSPI_BUS_WIDTH_SINGLE);
t.rx_data = NULL;
t.tx_data = cmdbuf1;
t.data_len = single_cnt;
ret = hal_qspi_master_transfer_sync(&qspi->handle, &t);
if (ret)
goto out;
}
if (rest_cnt) {
hal_qspi_master_set_bus_width(&qspi->handle, rest_buswidth);
t.rx_data = NULL;
t.tx_data = cmdbuf2;
t.data_len = rest_cnt;
ret = hal_qspi_master_transfer_sync(&qspi->handle, &t);
if (ret)
goto out;
}
/* Read data phase */
hal_qspi_master_set_bus_width(&qspi->handle, rd_fmt->data_lines);
t.rx_data = read_buf;
t.tx_data = NULL;
t.data_len = read_size;
ret = hal_qspi_master_transfer_sync(&qspi->handle, &t);
out:
hal_qspi_master_set_cs(&qspi->handle, 0, false);
return ret;
}
#endif
static sfud_err spi_set_speed(const struct __sfud_spi *spi, uint32_t bus_hz)
{
struct aic_qspi_bus *qspi;
qspi = (struct aic_qspi_bus *)spi->user_data;
if (qspi == NULL)
return SFUD_ERR_NOT_FOUND;
hal_qspi_master_set_bus_freq(&qspi->handle, bus_hz);
return SFUD_SUCCESS;
}
static sfud_err spi_write_read(const struct __sfud_spi *spi,
const uint8_t *write_buf, size_t write_size,
uint8_t *read_buf, size_t read_size)
{
struct aic_qspi_bus *qspi;
struct qspi_transfer t;
int ret = 0;
qspi = (struct aic_qspi_bus *)spi->user_data;
hal_qspi_master_set_bus_width(&qspi->handle, HAL_QSPI_BUS_WIDTH_SINGLE);
hal_qspi_master_set_cs(&qspi->handle, 0, true);
if (write_size) {
t.rx_data = NULL;
t.tx_data = (uint8_t *)write_buf;
t.data_len = write_size;
ret = hal_qspi_master_transfer_sync(&qspi->handle, &t);
if (ret < 0)
goto out;
}
if (read_size) {
t.rx_data = read_buf;
t.tx_data = NULL;
t.data_len = read_size;
ret = hal_qspi_master_transfer_sync(&qspi->handle, &t);
}
out:
hal_qspi_master_set_cs(&qspi->handle, 0, false);
return ret;
}
sfud_err sfud_spi_port_init(sfud_flash *flash)
{
sfud_err result = SFUD_SUCCESS;
/* port SPI device interface */
flash->spi.wr = spi_write_read;
flash->spi.set_speed = spi_set_speed;
#ifdef SFUD_USING_QSPI
flash->spi.qspi_read = (void *)qspi_read;
#endif
flash->spi.lock = NULL;
flash->spi.unlock = NULL;
flash->spi.user_data = flash->user_data;
/* 100 microsecond delay */
flash->retry.delay = retry_delay_100us;
/* 60 seconds timeout */
flash->retry.times = 60 * 10000;
return result;
}
static int sfud_mtd_read(struct mtd_dev *mtd, u32 offset, uint8_t *data,
u32 len)
{
sfud_flash *flash;
u32 start, dolen;
if ((!mtd) || (!mtd->priv))
return -1;
start = mtd->start + offset;
dolen = len;
if ((mtd->size - offset) < dolen)
dolen = mtd->size - offset;
flash = mtd->priv;
return sfud_read(flash, start, dolen, data);
}
static int sfud_mtd_erase(struct mtd_dev *mtd, u32 offset, u32 len)
{
sfud_flash *flash;
u32 start, dolen;
if ((!mtd) || (!mtd->priv))
return -1;
start = mtd->start + offset;
dolen = len;
if ((mtd->size - offset) < dolen)
dolen = mtd->size - offset;
flash = mtd->priv;
return sfud_erase(flash, start, dolen);
}
static int sfud_mtd_write(struct mtd_dev *mtd, u32 offset, uint8_t *data,
u32 len)
{
sfud_flash *flash;
u32 start, dolen;
if ((!mtd) || (!mtd->priv))
return -1;
start = mtd->start + offset;
dolen = len;
if ((mtd->size - offset) < dolen)
dolen = mtd->size - offset;
flash = mtd->priv;
return sfud_write(flash, start, dolen, data);
}
static char *get_part_str(u32 spi_bus)
{
char name[8] = {0};
strcpy(name, "spi0");
name[3] += spi_bus;
if (strncmp(name, NOR_MTD_PARTS, 4) == 0)
return NOR_MTD_PARTS;
return NULL;
}
sfud_flash *sfud_probe(u32 spi_bus)
{
sfud_err result = SFUD_SUCCESS;
struct aic_qspi_bus *qspi;
struct mtd_dev *mtd;
struct mtd_partition *part, *p;
int ret;
struct qspi_master_config cfg;
char *partstr;
qspi = get_qspi_by_index(spi_bus);
if (!qspi) {
pr_err("spi bus is invalid: %d\n", spi_bus);
return NULL;
}
if ((qspi->probe_flag) && (qspi->attached_flash.init_ok))
return &qspi->attached_flash;
memset(&cfg, 0, sizeof(cfg));
cfg.idx = qspi->idx;
cfg.clk_in_hz = qspi->clk_in_hz;
cfg.clk_id = qspi->clk_id;
cfg.cpol = HAL_QSPI_CPOL_ACTIVE_HIGH;
cfg.cpha = HAL_QSPI_CPHA_FIRST_EDGE;
cfg.cs_polarity = HAL_QSPI_CS_POL_VALID_LOW;
ret = hal_qspi_master_init(&qspi->handle, &cfg);
if (ret) {
pr_err("hal_qspi_master_init failed. ret %d\n", ret);
return NULL;
}
#ifdef AIC_DMA_DRV
struct qspi_master_dma_config dmacfg;
memset(&dmacfg, 0, sizeof(dmacfg));
dmacfg.port_id = qspi->dma_port_id;
dmacfg.tx_bus_width = DMA_SLAVE_BUSWIDTH_1_BYTE;
dmacfg.rx_bus_width = DMA_SLAVE_BUSWIDTH_4_BYTES;
dmacfg.tx_max_burst = 1;
dmacfg.rx_max_burst = 8;
ret = hal_qspi_master_dma_config(&qspi->handle, &dmacfg);
if (ret) {
pr_err("qspi dma config failed.\n");
return NULL;
}
#endif
qspi->attached_flash.user_data = (void *)qspi;
qspi->attached_flash.init_hz = SFUD_READ_SFDP_FREQ;
qspi->attached_flash.bus_hz = AIC_QSPI0_DEVICE_SPINOR_FREQ;
result = sfud_device_init(&qspi->attached_flash);
if (result != SFUD_SUCCESS) {
pr_err("sfud_device_init failed: ret %d\n", result);
return NULL;
}
#ifdef SFUD_USING_QSPI
sfud_qspi_fast_read_enable(&qspi->attached_flash, 4);
#endif
mtd = malloc(sizeof(*mtd));
mtd->name = strdup("nor0");
mtd->name[3] += spi_bus;
mtd->start = 0;
mtd->size = qspi->attached_flash.chip.capacity;
mtd->erasesize = qspi->attached_flash.chip.erase_gran;
mtd->ops.erase = sfud_mtd_erase;
mtd->ops.read = sfud_mtd_read;
mtd->ops.write = sfud_mtd_write;
mtd->priv = &qspi->attached_flash;
mtd_add_device(mtd);
partstr = get_part_str(spi_bus);
part = mtd_parts_parse(partstr);
p = part;
while (p) {
mtd = malloc(sizeof(*mtd));
mtd->name = strdup(p->name);
mtd->start = p->start;
mtd->size = p->size;
mtd->erasesize = qspi->attached_flash.chip.erase_gran;
if (p->size == 0)
mtd->size = qspi->attached_flash.chip.capacity - p->start;
mtd->ops.erase = sfud_mtd_erase;
mtd->ops.read = sfud_mtd_read;
mtd->ops.write = sfud_mtd_write;
mtd->priv = &qspi->attached_flash;
mtd_add_device(mtd);
p = p->next;
}
if (part)
mtd_parts_free(part);
return &qspi->attached_flash;
}
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