/* * Copyright 2020 NXP * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT nxp_imx_flexspi_nor #include #include #include #include "spi_nor.h" #include "memc_mcux_flexspi.h" #ifdef CONFIG_HAS_MCUX_CACHE #include #endif #define NOR_WRITE_SIZE 1 #define NOR_ERASE_VALUE 0xff #ifdef CONFIG_FLASH_MCUX_FLEXSPI_NOR_WRITE_BUFFER static uint8_t nor_write_buf[SPI_NOR_PAGE_SIZE]; #endif LOG_MODULE_REGISTER(flash_flexspi_nor, CONFIG_FLASH_LOG_LEVEL); enum { /* Instructions matching with XIP layout */ READ_FAST_QUAD_OUTPUT, READ_FAST_OUTPUT, READ_NORMAL_OUTPUT, READ_STATUS, WRITE_ENABLE, ERASE_SECTOR, PAGE_PROGRAM_INPUT, PAGE_PROGRAM_QUAD_INPUT, READ_ID, WRITE_STATUS_REG, ENTER_QPI, EXIT_QPI, READ_STATUS_REG, ERASE_CHIP, }; struct flash_flexspi_nor_config { char *controller_label; flexspi_port_t port; flexspi_device_config_t config; struct flash_pages_layout layout; struct flash_parameters flash_parameters; }; struct flash_flexspi_nor_data { const struct device *controller; }; static const uint32_t flash_flexspi_nor_lut[][4] = { [READ_ID] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, SPI_NOR_CMD_RDID, kFLEXSPI_Command_READ_SDR, kFLEXSPI_1PAD, 0x04), }, [READ_STATUS_REG] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, SPI_NOR_CMD_RDSR, kFLEXSPI_Command_READ_SDR, kFLEXSPI_1PAD, 0x04), }, [WRITE_STATUS_REG] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, SPI_NOR_CMD_WRSR, kFLEXSPI_Command_WRITE_SDR, kFLEXSPI_1PAD, 0x04), }, [WRITE_ENABLE] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, SPI_NOR_CMD_WREN, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0), }, [ERASE_SECTOR] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, SPI_NOR_CMD_SE, kFLEXSPI_Command_RADDR_SDR, kFLEXSPI_1PAD, 0x18), }, [ERASE_CHIP] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, SPI_NOR_CMD_CE, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0), }, [READ_FAST_QUAD_OUTPUT] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, 0x6B, kFLEXSPI_Command_RADDR_SDR, kFLEXSPI_1PAD, 0x18), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_DUMMY_SDR, kFLEXSPI_4PAD, 0x08, kFLEXSPI_Command_READ_SDR, kFLEXSPI_4PAD, 0x04), }, [READ_FAST_OUTPUT] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, 0x0B, kFLEXSPI_Command_RADDR_SDR, kFLEXSPI_1PAD, 0x18), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_DUMMY_SDR, kFLEXSPI_1PAD, 0x08, kFLEXSPI_Command_READ_SDR, kFLEXSPI_1PAD, 0x04), }, [READ_NORMAL_OUTPUT] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, SPI_NOR_CMD_READ, kFLEXSPI_Command_RADDR_SDR, kFLEXSPI_1PAD, 0x18), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_READ_SDR, kFLEXSPI_1PAD, 0x04, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0), }, [READ_STATUS] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, 0x81, kFLEXSPI_Command_READ_SDR, kFLEXSPI_1PAD, 0x04), }, [PAGE_PROGRAM_INPUT] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, SPI_NOR_CMD_PP, kFLEXSPI_Command_RADDR_SDR, kFLEXSPI_1PAD, 0x18), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_WRITE_SDR, kFLEXSPI_1PAD, 0x04, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0), }, [PAGE_PROGRAM_QUAD_INPUT] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, 0x32, kFLEXSPI_Command_RADDR_SDR, kFLEXSPI_1PAD, 0x18), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_WRITE_SDR, kFLEXSPI_4PAD, 0x04, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0), }, [ENTER_QPI] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_1PAD, 0x35, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0), }, [EXIT_QPI] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_SDR, kFLEXSPI_4PAD, 0xF5, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0), }, }; static int flash_flexspi_nor_get_vendor_id(const struct device *dev, uint8_t *vendor_id) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; uint32_t buffer = 0; int ret; flexspi_transfer_t transfer = { .deviceAddress = 0, .port = config->port, .cmdType = kFLEXSPI_Read, .SeqNumber = 1, .seqIndex = READ_ID, .data = &buffer, .dataSize = 1, }; LOG_DBG("Reading id"); ret = memc_flexspi_transfer(data->controller, &transfer); *vendor_id = buffer; return ret; } static int flash_flexspi_nor_read_status(const struct device *dev, uint32_t *status) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; flexspi_transfer_t transfer = { .deviceAddress = 0, .port = config->port, .cmdType = kFLEXSPI_Read, .SeqNumber = 1, .seqIndex = READ_STATUS_REG, .data = status, .dataSize = 1, }; LOG_DBG("Reading status register"); return memc_flexspi_transfer(data->controller, &transfer); } static int flash_flexspi_nor_write_status(const struct device *dev, uint32_t *status) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; flexspi_transfer_t transfer = { .deviceAddress = 0, .port = config->port, .cmdType = kFLEXSPI_Write, .SeqNumber = 1, .seqIndex = WRITE_STATUS_REG, .data = status, .dataSize = 1, }; LOG_DBG("Writing status register"); return memc_flexspi_transfer(data->controller, &transfer); } static int flash_flexspi_nor_write_enable(const struct device *dev) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; flexspi_transfer_t transfer = { .deviceAddress = 0, .port = config->port, .cmdType = kFLEXSPI_Command, .SeqNumber = 1, .seqIndex = WRITE_ENABLE, .data = NULL, .dataSize = 0, }; LOG_DBG("Enabling write"); return memc_flexspi_transfer(data->controller, &transfer); } static int flash_flexspi_nor_erase_sector(const struct device *dev, off_t offset) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; flexspi_transfer_t transfer = { .deviceAddress = offset, .port = config->port, .cmdType = kFLEXSPI_Command, .SeqNumber = 1, .seqIndex = ERASE_SECTOR, .data = NULL, .dataSize = 0, }; LOG_DBG("Erasing sector at 0x%08x", offset); return memc_flexspi_transfer(data->controller, &transfer); } static int flash_flexspi_nor_erase_chip(const struct device *dev) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; flexspi_transfer_t transfer = { .deviceAddress = 0, .port = config->port, .cmdType = kFLEXSPI_Command, .SeqNumber = 1, .seqIndex = ERASE_CHIP, .data = NULL, .dataSize = 0, }; LOG_DBG("Erasing chip"); return memc_flexspi_transfer(data->controller, &transfer); } static int flash_flexspi_nor_page_program(const struct device *dev, off_t offset, const void *buffer, size_t len) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; flexspi_transfer_t transfer = { .deviceAddress = offset, .port = config->port, .cmdType = kFLEXSPI_Write, .SeqNumber = 1, .seqIndex = PAGE_PROGRAM_QUAD_INPUT, .data = (uint32_t *) buffer, .dataSize = len, }; LOG_DBG("Page programming %d bytes to 0x%08x", len, offset); return memc_flexspi_transfer(data->controller, &transfer); } static int flash_flexspi_nor_wait_bus_busy(const struct device *dev) { uint32_t status = 0; int ret; do { ret = flash_flexspi_nor_read_status(dev, &status); LOG_DBG("status: 0x%x", status); if (ret) { LOG_ERR("Could not read status"); return ret; } } while (status & BIT(0)); return 0; } static int flash_flexspi_nor_enable_quad_mode(const struct device *dev) { struct flash_flexspi_nor_data *data = dev->data; uint32_t status = 0x40; flash_flexspi_nor_write_status(dev, &status); flash_flexspi_nor_wait_bus_busy(dev); memc_flexspi_reset(data->controller); return 0; } static int flash_flexspi_nor_read(const struct device *dev, off_t offset, void *buffer, size_t len) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; uint8_t *src = memc_flexspi_get_ahb_address(data->controller, config->port, offset); memcpy(buffer, src, len); return 0; } static int flash_flexspi_nor_write(const struct device *dev, off_t offset, const void *buffer, size_t len) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; size_t size = len; uint8_t *src = (uint8_t *) buffer; int i; unsigned int key = 0; uint8_t *dst = memc_flexspi_get_ahb_address(data->controller, config->port, offset); if (memc_flexspi_is_running_xip(data->controller)) { key = irq_lock(); } while (len) { /* If the offset isn't a multiple of the NOR page size, we first need * to write the remaining part that fits, otherwise the write could * be wrapped around within the same page */ i = MIN(SPI_NOR_PAGE_SIZE - (offset % SPI_NOR_PAGE_SIZE), len); #ifdef CONFIG_FLASH_MCUX_FLEXSPI_NOR_WRITE_BUFFER memcpy(nor_write_buf, src, i); #endif flash_flexspi_nor_write_enable(dev); #ifdef CONFIG_FLASH_MCUX_FLEXSPI_NOR_WRITE_BUFFER flash_flexspi_nor_page_program(dev, offset, nor_write_buf, i); #else flash_flexspi_nor_page_program(dev, offset, src, i); #endif flash_flexspi_nor_wait_bus_busy(dev); memc_flexspi_reset(data->controller); src += i; offset += i; len -= i; } if (memc_flexspi_is_running_xip(data->controller)) { irq_unlock(key); } #ifdef CONFIG_HAS_MCUX_CACHE DCACHE_InvalidateByRange((uint32_t) dst, size); #endif return 0; } static int flash_flexspi_nor_erase(const struct device *dev, off_t offset, size_t size) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; int num_sectors = size / SPI_NOR_SECTOR_SIZE; int i; unsigned int key = 0; uint8_t *dst = memc_flexspi_get_ahb_address(data->controller, config->port, offset); if (offset % SPI_NOR_SECTOR_SIZE) { LOG_ERR("Invalid offset"); return -EINVAL; } if (size % SPI_NOR_SECTOR_SIZE) { LOG_ERR("Invalid size"); return -EINVAL; } if (memc_flexspi_is_running_xip(data->controller)) { key = irq_lock(); } if ((offset == 0) && (size == config->config.flashSize * KB(1))) { flash_flexspi_nor_write_enable(dev); flash_flexspi_nor_erase_chip(dev); flash_flexspi_nor_wait_bus_busy(dev); memc_flexspi_reset(data->controller); } else { for (i = 0; i < num_sectors; i++) { flash_flexspi_nor_write_enable(dev); flash_flexspi_nor_erase_sector(dev, offset); flash_flexspi_nor_wait_bus_busy(dev); memc_flexspi_reset(data->controller); offset += SPI_NOR_SECTOR_SIZE; } } if (memc_flexspi_is_running_xip(data->controller)) { irq_unlock(key); } #ifdef CONFIG_HAS_MCUX_CACHE DCACHE_InvalidateByRange((uint32_t) dst, size); #endif return 0; } static const struct flash_parameters *flash_flexspi_nor_get_parameters( const struct device *dev) { const struct flash_flexspi_nor_config *config = dev->config; return &config->flash_parameters; } #if defined(CONFIG_FLASH_PAGE_LAYOUT) static void flash_flexspi_nor_pages_layout(const struct device *dev, const struct flash_pages_layout **layout, size_t *layout_size) { const struct flash_flexspi_nor_config *config = dev->config; *layout = &config->layout; *layout_size = 1; } #endif /* CONFIG_FLASH_PAGE_LAYOUT */ static int flash_flexspi_nor_init(const struct device *dev) { const struct flash_flexspi_nor_config *config = dev->config; struct flash_flexspi_nor_data *data = dev->data; uint8_t vendor_id; data->controller = device_get_binding(config->controller_label); if (data->controller == NULL) { LOG_ERR("Could not find controller"); return -EINVAL; } if (!memc_flexspi_is_running_xip(data->controller) && memc_flexspi_set_device_config(data->controller, &config->config, config->port)) { LOG_ERR("Could not set device configuration"); return -EINVAL; } if (memc_flexspi_update_lut(data->controller, 0, (const uint32_t *) flash_flexspi_nor_lut, sizeof(flash_flexspi_nor_lut) / 4)) { LOG_ERR("Could not update lut"); return -EINVAL; } memc_flexspi_reset(data->controller); if (flash_flexspi_nor_get_vendor_id(dev, &vendor_id)) { LOG_ERR("Could not read vendor id"); return -EIO; } LOG_DBG("Vendor id: 0x%0x", vendor_id); if (flash_flexspi_nor_enable_quad_mode(dev)) { LOG_ERR("Could not enable quad mode"); return -EIO; } return 0; } static const struct flash_driver_api flash_flexspi_nor_api = { .erase = flash_flexspi_nor_erase, .write = flash_flexspi_nor_write, .read = flash_flexspi_nor_read, .get_parameters = flash_flexspi_nor_get_parameters, #if defined(CONFIG_FLASH_PAGE_LAYOUT) .page_layout = flash_flexspi_nor_pages_layout, #endif }; #define CONCAT3(x, y, z) x ## y ## z #define CS_INTERVAL_UNIT(unit) \ CONCAT3(kFLEXSPI_CsIntervalUnit, unit, SckCycle) #define AHB_WRITE_WAIT_UNIT(unit) \ CONCAT3(kFLEXSPI_AhbWriteWaitUnit, unit, AhbCycle) #define FLASH_FLEXSPI_DEVICE_CONFIG(n) \ { \ .flexspiRootClk = MHZ(120), \ .flashSize = DT_INST_PROP(n, size) / 8 / KB(1), \ .CSIntervalUnit = \ CS_INTERVAL_UNIT( \ DT_INST_PROP(n, cs_interval_unit)), \ .CSInterval = DT_INST_PROP(n, cs_interval), \ .CSHoldTime = DT_INST_PROP(n, cs_hold_time), \ .CSSetupTime = DT_INST_PROP(n, cs_setup_time), \ .dataValidTime = DT_INST_PROP(n, data_valid_time), \ .columnspace = DT_INST_PROP(n, column_space), \ .enableWordAddress = DT_INST_PROP(n, word_addressable), \ .AWRSeqIndex = 0, \ .AWRSeqNumber = 0, \ .ARDSeqIndex = READ_FAST_QUAD_OUTPUT, \ .ARDSeqNumber = 1, \ .AHBWriteWaitUnit = \ AHB_WRITE_WAIT_UNIT( \ DT_INST_PROP(n, ahb_write_wait_unit)), \ .AHBWriteWaitInterval = \ DT_INST_PROP(n, ahb_write_wait_interval), \ } \ #define FLASH_FLEXSPI_NOR(n) \ static const struct flash_flexspi_nor_config \ flash_flexspi_nor_config_##n = { \ .controller_label = DT_INST_BUS_LABEL(n), \ .port = DT_INST_REG_ADDR(n), \ .config = FLASH_FLEXSPI_DEVICE_CONFIG(n), \ .layout = { \ .pages_count = DT_INST_PROP(n, size) / 8 \ / SPI_NOR_SECTOR_SIZE, \ .pages_size = SPI_NOR_SECTOR_SIZE, \ }, \ .flash_parameters = { \ .write_block_size = NOR_WRITE_SIZE, \ .erase_value = NOR_ERASE_VALUE, \ }, \ }; \ \ static struct flash_flexspi_nor_data \ flash_flexspi_nor_data_##n; \ \ DEVICE_DT_INST_DEFINE(n, \ flash_flexspi_nor_init, \ NULL, \ &flash_flexspi_nor_data_##n, \ &flash_flexspi_nor_config_##n, \ POST_KERNEL, \ CONFIG_KERNEL_INIT_PRIORITY_DEVICE, \ &flash_flexspi_nor_api); DT_INST_FOREACH_STATUS_OKAY(FLASH_FLEXSPI_NOR)