/* * Copyright 2021 Basalte bv * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT nxp_imx_flexspi_hyperram #include #include #include "memc_mcux_flexspi.h" /* * NOTE: If CONFIG_FLASH_MCUX_FLEXSPI_XIP is selected, Any external functions * called while interacting with the flexspi MUST be relocated to SRAM or ITCM * at runtime, so that the chip does not access the flexspi to read program * instructions while it is being written to */ #if defined(CONFIG_FLASH_MCUX_FLEXSPI_XIP) && (CONFIG_MEMC_LOG_LEVEL > 0) #warning "Enabling memc driver logging and XIP mode simultaneously can cause \ read-while-write hazards. This configuration is not recommended." #endif LOG_MODULE_REGISTER(memc_flexspi_hyperram, CONFIG_MEMC_LOG_LEVEL); enum { READ_DATA, WRITE_DATA, READ_REG, WRITE_REG, }; struct memc_flexspi_hyperram_config { flexspi_port_t port; flexspi_device_config_t config; }; /* Device variables used in critical sections should be in this structure */ struct memc_flexspi_hyperram_data { const struct device *controller; }; static const uint32_t memc_flexspi_hyperram_lut[][4] = { /* Read Data */ [READ_DATA] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_DDR, kFLEXSPI_8PAD, 0xA0, kFLEXSPI_Command_RADDR_DDR, kFLEXSPI_8PAD, 0x18), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_CADDR_DDR, kFLEXSPI_8PAD, 0x10, kFLEXSPI_Command_DUMMY_RWDS_DDR, kFLEXSPI_8PAD, 0x06), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_READ_DDR, kFLEXSPI_8PAD, 0x04, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0x00), }, /* Write Data */ [WRITE_DATA] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_DDR, kFLEXSPI_8PAD, 0x20, kFLEXSPI_Command_RADDR_DDR, kFLEXSPI_8PAD, 0x18), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_CADDR_DDR, kFLEXSPI_8PAD, 0x10, kFLEXSPI_Command_DUMMY_RWDS_DDR, kFLEXSPI_8PAD, 0x06), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_WRITE_DDR, kFLEXSPI_8PAD, 0x04, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0x00), }, /* Read Register */ [READ_REG] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_DDR, kFLEXSPI_8PAD, 0xE0, kFLEXSPI_Command_RADDR_DDR, kFLEXSPI_8PAD, 0x18), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_CADDR_DDR, kFLEXSPI_8PAD, 0x10, kFLEXSPI_Command_DUMMY_RWDS_DDR, kFLEXSPI_8PAD, 0x06), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_READ_DDR, kFLEXSPI_8PAD, 0x04, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0x00), }, /* Write Register */ [WRITE_REG] = { FLEXSPI_LUT_SEQ(kFLEXSPI_Command_DDR, kFLEXSPI_8PAD, 0x60, kFLEXSPI_Command_RADDR_DDR, kFLEXSPI_8PAD, 0x18), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_CADDR_DDR, kFLEXSPI_8PAD, 0x10, kFLEXSPI_Command_DUMMY_RWDS_DDR, kFLEXSPI_8PAD, 0x06), FLEXSPI_LUT_SEQ(kFLEXSPI_Command_WRITE_DDR, kFLEXSPI_8PAD, 0x04, kFLEXSPI_Command_STOP, kFLEXSPI_1PAD, 0x00), }, }; static int memc_flexspi_hyperram_get_vendor_id(const struct device *dev, uint16_t *vendor_id) { const struct memc_flexspi_hyperram_config *config = dev->config; struct memc_flexspi_hyperram_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_REG, .data = &buffer, .dataSize = 4, }; LOG_DBG("Reading id"); ret = memc_flexspi_transfer(data->controller, &transfer); *vendor_id = buffer & 0xffff; return ret; } static int memc_flexspi_hyperram_init(const struct device *dev) { const struct memc_flexspi_hyperram_config *config = dev->config; struct memc_flexspi_hyperram_data *data = dev->data; uint16_t vendor_id; if (!device_is_ready(data->controller)) { LOG_ERR("Controller device not ready"); return -ENODEV; } if (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 *) memc_flexspi_hyperram_lut, sizeof(memc_flexspi_hyperram_lut) / 4)) { LOG_ERR("Could not update lut"); return -EINVAL; } memc_flexspi_reset(data->controller); if (memc_flexspi_hyperram_get_vendor_id(dev, &vendor_id)) { LOG_ERR("Could not read vendor id"); return -EIO; } LOG_DBG("Vendor id: 0x%0x", vendor_id); return 0; } #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 MEMC_FLEXSPI_DEVICE_CONFIG(n) \ { \ .flexspiRootClk = MHZ(332), \ .isSck2Enabled = false, \ .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 = WRITE_DATA, \ .AWRSeqNumber = 1, \ .ARDSeqIndex = READ_DATA, \ .ARDSeqNumber = 1, \ .AHBWriteWaitUnit = \ AHB_WRITE_WAIT_UNIT( \ DT_INST_PROP(n, ahb_write_wait_unit)), \ .AHBWriteWaitInterval = \ DT_INST_PROP(n, ahb_write_wait_interval), \ .enableWriteMask = true, \ } \ #define MEMC_FLEXSPI_HYPERRAM(n) \ static const struct memc_flexspi_hyperram_config \ memc_flexspi_hyperram_config_##n = { \ .port = DT_INST_REG_ADDR(n), \ .config = MEMC_FLEXSPI_DEVICE_CONFIG(n), \ }; \ \ static struct memc_flexspi_hyperram_data \ memc_flexspi_hyperram_data_##n = { \ .controller = DEVICE_DT_GET(DT_INST_BUS(n)), \ }; \ \ DEVICE_DT_INST_DEFINE(n, \ memc_flexspi_hyperram_init, \ NULL, \ &memc_flexspi_hyperram_data_##n, \ &memc_flexspi_hyperram_config_##n, \ POST_KERNEL, \ CONFIG_KERNEL_INIT_PRIORITY_DEVICE, \ NULL); DT_INST_FOREACH_STATUS_OKAY(MEMC_FLEXSPI_HYPERRAM)