/* * Copyright 2024 Cypress Semiconductor Corporation (an Infineon company) or * an affiliate of Cypress Semiconductor Corporation * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT infineon_cat1_qspi_flash #define SOC_NV_FLASH_NODE DT_PARENT(DT_INST(0, fixed_partitions)) #define PAGE_LEN DT_PROP(SOC_NV_FLASH_NODE, erase_block_size) #include #include #include #include #include "cy_serial_flash_qspi.h" #include "cy_smif_memslot.h" LOG_MODULE_REGISTER(flash_infineon_cat1, CONFIG_FLASH_LOG_LEVEL); /* Device config structure */ struct ifx_cat1_flash_config { uint32_t base_addr; uint32_t max_addr; }; /* Data structure */ struct ifx_cat1_flash_data { cyhal_flash_t flash_obj; struct k_sem sem; }; static struct flash_parameters ifx_cat1_flash_parameters = { .write_block_size = DT_PROP(SOC_NV_FLASH_NODE, write_block_size), .erase_value = 0xFF, }; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_read_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_write_en_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_write_dis_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_erase_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_chip_erase_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_program_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_read_sts_reg_qe_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_read_sts_reg_wip_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_write_sts_reg_qe_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_read_sts_reg_oe_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_write_sts_reg_oe_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_read_latency_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_write_latency_cmd = {0}; cy_stc_smif_mem_cmd_t sfdp_slave_slot_0_read_sfdp_cmd = { /* The 8-bit command. 1 x I/O read command. */ .command = 0x5AU, /* The width of the command transfer. */ .cmdWidth = CY_SMIF_WIDTH_SINGLE, /* The width of the address transfer. */ .addrWidth = CY_SMIF_WIDTH_SINGLE, /* The 8-bit mode byte. This value is 0xFFFFFFFF when there is no mode present. */ .mode = 0xFFFFFFFFU, /* The width of the mode command transfer. */ .modeWidth = CY_SMIF_WIDTH_SINGLE, /* The number of dummy cycles. A zero value suggests no dummy cycles. */ .dummyCycles = 8U, /* The width of the data transfer. */ .dataWidth = CY_SMIF_WIDTH_SINGLE, }; cy_stc_smif_octal_ddr_en_seq_t oe_sequence_SFDP_SlaveSlot_0 = { .cmdSeq1Len = CY_SMIF_SFDP_ODDR_CMD_SEQ_MAX_LEN, .cmdSeq2Len = CY_SMIF_SFDP_ODDR_CMD_SEQ_MAX_LEN, .cmdSeq1 = {0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}, .cmdSeq2 = {0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}, }; /* Support for memories with hybrid regions is added in the version 1.50 * Please refer to the changelog in * https://iot-webserver.aus.cypress.com/projects/iot_release/ * ASSETS/repo/mtb-pdl-cat1/develop/Latest/deploy/docs/ * pdl_api_reference_manual/html/group__group__smif.html * for more details */ #if (CY_SMIF_DRV_VERSION_MAJOR > 1) && (CY_SMIF_DRV_VERSION_MINOR >= 50) static cy_stc_smif_hybrid_region_info_t sfdp_slave_slot_0_region_info_storage[16]; #define GENERATE_REGION_INFO_PTR(index, _) &sfdp_slave_slot_0_region_info_storage[index], static cy_stc_smif_hybrid_region_info_t *sfdp_slave_slot_0_region_info[16] = { LISTIFY(16, GENERATE_REGION_INFO_PTR, ())}; #endif cy_stc_smif_mem_device_cfg_t deviceCfg_SFDP_SlaveSlot_0 = { /* Specifies the number of address bytes used by the memory slave device. */ .numOfAddrBytes = 0x03U, /* The size of the memory. */ .memSize = 0x0000100U, /* Specifies the Read command. */ .readCmd = &sfdp_slave_slot_0_read_cmd, /* Specifies the Write Enable command. */ .writeEnCmd = &sfdp_slave_slot_0_write_en_cmd, /* Specifies the Write Disable command. */ .writeDisCmd = &sfdp_slave_slot_0_write_dis_cmd, /* Specifies the Erase command. */ .eraseCmd = &sfdp_slave_slot_0_erase_cmd, /* Specifies the sector size of each erase. */ .eraseSize = 0x0001000U, /* Specifies the Chip Erase command. */ .chipEraseCmd = &sfdp_slave_slot_0_chip_erase_cmd, /* Specifies the Program command. */ .programCmd = &sfdp_slave_slot_0_program_cmd, /* Specifies the page size for programming. */ .programSize = 0x0000100U, /* Specifies the command to read the QE-containing status register. */ .readStsRegQeCmd = &sfdp_slave_slot_0_read_sts_reg_qe_cmd, /* Specifies the command to read the WIP-containing status register. */ .readStsRegWipCmd = &sfdp_slave_slot_0_read_sts_reg_wip_cmd, /* Specifies the read SFDP command */ .readSfdpCmd = &sfdp_slave_slot_0_read_sfdp_cmd, /* Specifies the command to write into the QE-containing status register. */ .writeStsRegQeCmd = &sfdp_slave_slot_0_write_sts_reg_qe_cmd, /* The mask for the status register. */ .stsRegBusyMask = 0x00U, /* The mask for the status register. */ .stsRegQuadEnableMask = 0x00U, /* The max time for the erase type-1 cycle-time in ms. */ .eraseTime = 1U, /* The max time for the chip-erase cycle-time in ms. */ .chipEraseTime = 16U, /* The max time for the page-program cycle-time in us. */ .programTime = 8U, #if (CY_SMIF_DRV_VERSION_MAJOR > 1) && (CY_SMIF_DRV_VERSION_MINOR >= 50) /* Points to NULL or to structure with info about sectors for hybrid memory. */ .hybridRegionCount = 0U, .hybridRegionInfo = sfdp_slave_slot_0_region_info, #endif /* Specifies the command to read variable latency cycles configuration register */ .readLatencyCmd = &sfdp_slave_slot_0_read_latency_cmd, /* Specifies the command to write variable latency cycles configuration register */ .writeLatencyCmd = &sfdp_slave_slot_0_write_latency_cmd, /* Specifies the address for variable latency cycle address */ .latencyCyclesRegAddr = 0x00U, /* Specifies variable latency cycles Mask */ .latencyCyclesMask = 0x00U, /* Specifies data for memory with hybrid sectors */ .octalDDREnableSeq = &oe_sequence_SFDP_SlaveSlot_0, /* Specifies the command to read the OE-containing status register. */ .readStsRegOeCmd = &sfdp_slave_slot_0_read_sts_reg_oe_cmd, /* Specifies the command to write the OE-containing status register. */ .writeStsRegOeCmd = &sfdp_slave_slot_0_write_sts_reg_oe_cmd, /* QE mask for the status registers */ .stsRegOctalEnableMask = 0x00U, /* Octal enable register address */ .octalEnableRegAddr = 0x00U, /* Frequency of operation used in Octal mode */ .freq_of_operation = CY_SMIF_100MHZ_OPERATION, }; cy_stc_smif_mem_config_t sfdp_slave_slot_0 = { /* Determines the slot number where the memory device is placed. */ .slaveSelect = CY_SMIF_SLAVE_SELECT_0, /* Flags. */ .flags = CY_SMIF_FLAG_SMIF_REV_3 | CY_SMIF_FLAG_MEMORY_MAPPED | CY_SMIF_FLAG_WR_EN | CY_SMIF_FLAG_DETECT_SFDP | CY_SMIF_FLAG_MERGE_ENABLE, /* The data-line selection options for a slave device. */ .dataSelect = CY_SMIF_DATA_SEL0, /* The base address the memory slave * Valid when the memory-mapped mode is enabled. */ .baseAddress = 0x60000000U, /* The size allocated in the memory map, for the memory slave device. * The size is allocated from the base address. Valid when the memory mapped mode is * enabled. */ .memMappedSize = 0x100000U, /* If this memory device is one of the devices in the dual quad SPI configuration. * Valid when the memory mapped mode is enabled. */ .dualQuadSlots = 0, /* The configuration of the device. */ .deviceCfg = &deviceCfg_SFDP_SlaveSlot_0, /** Continuous transfer merge timeout. * After this period the memory device is deselected. A later transfer, even from a * continuous address, starts with the overhead phases (command, address, mode, dummy * cycles). This configuration parameter is available for CAT1B devices. */ .mergeTimeout = CY_SMIF_MERGE_TIMEOUT_1_CYCLE, }; static inline void flash_ifx_sem_take(const struct device *dev) { struct ifx_cat1_flash_data *data = dev->data; k_sem_take(&data->sem, K_FOREVER); } static inline void flash_ifx_sem_give(const struct device *dev) { struct ifx_cat1_flash_data *data = dev->data; k_sem_give(&data->sem); } static int ifx_cat1_flash_read(const struct device *dev, off_t offset, void *data, size_t data_len) { cy_rslt_t rslt = CY_RSLT_SUCCESS; int ret = 0; if (!data_len) { return 0; } flash_ifx_sem_take(dev); rslt = cy_serial_flash_qspi_read(offset, data_len, data); if (rslt != CY_RSLT_SUCCESS) { LOG_ERR("Error reading @ %lu (Err:0x%x)", offset, rslt); ret = -EIO; } flash_ifx_sem_give(dev); return ret; } static int ifx_cat1_flash_write(const struct device *dev, off_t offset, const void *data, size_t data_len) { cy_rslt_t rslt = CY_RSLT_SUCCESS; int ret = 0; if (data_len == 0) { return 0; } if (offset < 0) { return -EINVAL; } flash_ifx_sem_take(dev); rslt = cy_serial_flash_qspi_write(offset, data_len, data); if (rslt != CY_RSLT_SUCCESS) { LOG_ERR("Error in writing @ %lu (Err:0x%x)", offset, rslt); ret = -EIO; } flash_ifx_sem_give(dev); return ret; } static int ifx_cat1_flash_erase(const struct device *dev, off_t offset, size_t size) { cy_rslt_t rslt; int ret = 0; if (offset < 0) { return -EINVAL; } flash_ifx_sem_take(dev); rslt = cy_serial_flash_qspi_erase(offset, size); if (rslt != CY_RSLT_SUCCESS) { LOG_ERR("Error in erasing : 0x%x", rslt); ret = -EIO; } flash_ifx_sem_give(dev); return ret; } #if CONFIG_FLASH_PAGE_LAYOUT static const struct flash_pages_layout ifx_cat1_flash_pages_layout = { .pages_count = DT_REG_SIZE(SOC_NV_FLASH_NODE) / PAGE_LEN, .pages_size = PAGE_LEN, }; static void ifx_cat1_flash_page_layout(const struct device *dev, const struct flash_pages_layout **layout, size_t *layout_size) { *layout = &ifx_cat1_flash_pages_layout; /* * For flash memories which have uniform page sizes, this routine * returns an array of length 1, which specifies the page size and * number of pages in the memory. */ *layout_size = 1; } #endif /* CONFIG_FLASH_PAGE_LAYOUT */ static const struct flash_parameters *ifx_cat1_flash_get_parameters(const struct device *dev) { ARG_UNUSED(dev); return &ifx_cat1_flash_parameters; } static int ifx_cat1_flash_init(const struct device *dev) { struct ifx_cat1_flash_data *data = dev->data; cy_rslt_t rslt = CY_RSLT_SUCCESS; rslt = cy_serial_flash_qspi_init(&sfdp_slave_slot_0, NC, NC, NC, NC, NC, NC, NC, NC, NC, NC, 50000000lu); if (rslt != CY_RSLT_SUCCESS) { LOG_ERR("Serial Flash initialization failed [rslt: 0x%x]", rslt); } k_sem_init(&data->sem, 1, 1); return 0; } static DEVICE_API(flash, ifx_cat1_flash_driver_api) = { .read = ifx_cat1_flash_read, .write = ifx_cat1_flash_write, .erase = ifx_cat1_flash_erase, .get_parameters = ifx_cat1_flash_get_parameters, #ifdef CONFIG_FLASH_PAGE_LAYOUT .page_layout = ifx_cat1_flash_page_layout, #endif }; static struct ifx_cat1_flash_data flash_data; static const struct ifx_cat1_flash_config flash_config = { .base_addr = DT_REG_ADDR(SOC_NV_FLASH_NODE), .max_addr = DT_REG_ADDR(SOC_NV_FLASH_NODE) + DT_REG_SIZE(SOC_NV_FLASH_NODE)}; DEVICE_DT_INST_DEFINE(0, ifx_cat1_flash_init, NULL, &flash_data, &flash_config, POST_KERNEL, CONFIG_FLASH_INIT_PRIORITY, &ifx_cat1_flash_driver_api);