Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Kumaravel Thiagarajan | 2120 | 99.16% | 2 | 66.67% |
Dan Carpenter | 18 | 0.84% | 1 | 33.33% |
Total | 2138 | 3 |
// SPDX-License-Identifier: GPL-2.0 // Copyright (C) 2022-2023 Microchip Technology Inc. // PCI1xxxx OTP/EEPROM driver #include <linux/auxiliary_bus.h> #include <linux/device.h> #include <linux/iopoll.h> #include <linux/module.h> #include <linux/nvmem-provider.h> #include "mchp_pci1xxxx_gp.h" #define AUX_DRIVER_NAME "PCI1xxxxOTPE2P" #define EEPROM_NAME "pci1xxxx_eeprom" #define OTP_NAME "pci1xxxx_otp" #define PERI_PF3_SYSTEM_REG_ADDR_BASE 0x2000 #define PERI_PF3_SYSTEM_REG_LENGTH 0x4000 #define EEPROM_SIZE_BYTES 8192 #define OTP_SIZE_BYTES 8192 #define CONFIG_REG_ADDR_BASE 0 #define EEPROM_REG_ADDR_BASE 0x0E00 #define OTP_REG_ADDR_BASE 0x1000 #define MMAP_OTP_OFFSET(x) (OTP_REG_ADDR_BASE + (x)) #define MMAP_EEPROM_OFFSET(x) (EEPROM_REG_ADDR_BASE + (x)) #define MMAP_CFG_OFFSET(x) (CONFIG_REG_ADDR_BASE + (x)) #define EEPROM_CMD_REG 0x00 #define EEPROM_DATA_REG 0x04 #define EEPROM_CMD_EPC_WRITE (BIT(29) | BIT(28)) #define EEPROM_CMD_EPC_TIMEOUT_BIT BIT(17) #define EEPROM_CMD_EPC_BUSY_BIT BIT(31) #define STATUS_READ_DELAY_US 1 #define STATUS_READ_TIMEOUT_US 20000 #define OTP_ADDR_HIGH_OFFSET 0x04 #define OTP_ADDR_LOW_OFFSET 0x08 #define OTP_PRGM_DATA_OFFSET 0x10 #define OTP_PRGM_MODE_OFFSET 0x14 #define OTP_RD_DATA_OFFSET 0x18 #define OTP_FUNC_CMD_OFFSET 0x20 #define OTP_CMD_GO_OFFSET 0x28 #define OTP_PASS_FAIL_OFFSET 0x2C #define OTP_STATUS_OFFSET 0x30 #define OTP_FUNC_RD_BIT BIT(0) #define OTP_FUNC_PGM_BIT BIT(1) #define OTP_CMD_GO_BIT BIT(0) #define OTP_STATUS_BUSY_BIT BIT(0) #define OTP_PGM_MODE_BYTE_BIT BIT(0) #define OTP_FAIL_BIT BIT(0) #define OTP_PWR_DN_BIT BIT(0) #define OTP_PWR_DN_OFFSET 0x00 #define CFG_SYS_LOCK_OFFSET 0xA0 #define CFG_SYS_LOCK_PF3 BIT(5) #define BYTE_LOW (GENMASK(7, 0)) #define BYTE_HIGH (GENMASK(12, 8)) struct pci1xxxx_otp_eeprom_device { struct auxiliary_device *pdev; void __iomem *reg_base; struct nvmem_config nvmem_config_eeprom; struct nvmem_device *nvmem_eeprom; struct nvmem_config nvmem_config_otp; struct nvmem_device *nvmem_otp; }; static int set_sys_lock(struct pci1xxxx_otp_eeprom_device *priv) { void __iomem *sys_lock = priv->reg_base + MMAP_CFG_OFFSET(CFG_SYS_LOCK_OFFSET); u8 data; writel(CFG_SYS_LOCK_PF3, sys_lock); data = readl(sys_lock); if (data != CFG_SYS_LOCK_PF3) return -EPERM; return 0; } static void release_sys_lock(struct pci1xxxx_otp_eeprom_device *priv) { void __iomem *sys_lock = priv->reg_base + MMAP_CFG_OFFSET(CFG_SYS_LOCK_OFFSET); writel(0, sys_lock); } static bool is_eeprom_responsive(struct pci1xxxx_otp_eeprom_device *priv) { void __iomem *rb = priv->reg_base; u32 regval; int ret; writel(EEPROM_CMD_EPC_TIMEOUT_BIT, rb + MMAP_EEPROM_OFFSET(EEPROM_CMD_REG)); writel(EEPROM_CMD_EPC_BUSY_BIT, rb + MMAP_EEPROM_OFFSET(EEPROM_CMD_REG)); /* Wait for the EPC_BUSY bit to get cleared or timeout bit to get set*/ ret = read_poll_timeout(readl, regval, !(regval & EEPROM_CMD_EPC_BUSY_BIT), STATUS_READ_DELAY_US, STATUS_READ_TIMEOUT_US, true, rb + MMAP_EEPROM_OFFSET(EEPROM_CMD_REG)); /* Return failure if either of software or hardware timeouts happen */ if (ret < 0 || (!ret && (regval & EEPROM_CMD_EPC_TIMEOUT_BIT))) return false; return true; } static int pci1xxxx_eeprom_read(void *priv_t, unsigned int off, void *buf_t, size_t count) { struct pci1xxxx_otp_eeprom_device *priv = priv_t; void __iomem *rb = priv->reg_base; char *buf = buf_t; u32 regval; u32 byte; int ret; if (off >= priv->nvmem_config_eeprom.size) return -EFAULT; if ((off + count) > priv->nvmem_config_eeprom.size) count = priv->nvmem_config_eeprom.size - off; ret = set_sys_lock(priv); if (ret) return ret; for (byte = 0; byte < count; byte++) { writel(EEPROM_CMD_EPC_BUSY_BIT | (off + byte), rb + MMAP_EEPROM_OFFSET(EEPROM_CMD_REG)); ret = read_poll_timeout(readl, regval, !(regval & EEPROM_CMD_EPC_BUSY_BIT), STATUS_READ_DELAY_US, STATUS_READ_TIMEOUT_US, true, rb + MMAP_EEPROM_OFFSET(EEPROM_CMD_REG)); if (ret < 0 || (!ret && (regval & EEPROM_CMD_EPC_TIMEOUT_BIT))) { ret = -EIO; goto error; } buf[byte] = readl(rb + MMAP_EEPROM_OFFSET(EEPROM_DATA_REG)); } error: release_sys_lock(priv); return ret; } static int pci1xxxx_eeprom_write(void *priv_t, unsigned int off, void *value_t, size_t count) { struct pci1xxxx_otp_eeprom_device *priv = priv_t; void __iomem *rb = priv->reg_base; char *value = value_t; u32 regval; u32 byte; int ret; if (off >= priv->nvmem_config_eeprom.size) return -EFAULT; if ((off + count) > priv->nvmem_config_eeprom.size) count = priv->nvmem_config_eeprom.size - off; ret = set_sys_lock(priv); if (ret) return ret; for (byte = 0; byte < count; byte++) { writel(*(value + byte), rb + MMAP_EEPROM_OFFSET(EEPROM_DATA_REG)); regval = EEPROM_CMD_EPC_TIMEOUT_BIT | EEPROM_CMD_EPC_WRITE | (off + byte); writel(regval, rb + MMAP_EEPROM_OFFSET(EEPROM_CMD_REG)); writel(EEPROM_CMD_EPC_BUSY_BIT | regval, rb + MMAP_EEPROM_OFFSET(EEPROM_CMD_REG)); ret = read_poll_timeout(readl, regval, !(regval & EEPROM_CMD_EPC_BUSY_BIT), STATUS_READ_DELAY_US, STATUS_READ_TIMEOUT_US, true, rb + MMAP_EEPROM_OFFSET(EEPROM_CMD_REG)); if (ret < 0 || (!ret && (regval & EEPROM_CMD_EPC_TIMEOUT_BIT))) { ret = -EIO; goto error; } } error: release_sys_lock(priv); return ret; } static void otp_device_set_address(struct pci1xxxx_otp_eeprom_device *priv, u16 address) { u16 lo, hi; lo = address & BYTE_LOW; hi = (address & BYTE_HIGH) >> 8; writew(lo, priv->reg_base + MMAP_OTP_OFFSET(OTP_ADDR_LOW_OFFSET)); writew(hi, priv->reg_base + MMAP_OTP_OFFSET(OTP_ADDR_HIGH_OFFSET)); } static int pci1xxxx_otp_read(void *priv_t, unsigned int off, void *buf_t, size_t count) { struct pci1xxxx_otp_eeprom_device *priv = priv_t; void __iomem *rb = priv->reg_base; char *buf = buf_t; u32 regval; u32 byte; int ret; u8 data; if (off >= priv->nvmem_config_otp.size) return -EFAULT; if ((off + count) > priv->nvmem_config_otp.size) count = priv->nvmem_config_otp.size - off; ret = set_sys_lock(priv); if (ret) return ret; for (byte = 0; byte < count; byte++) { otp_device_set_address(priv, (u16)(off + byte)); data = readl(rb + MMAP_OTP_OFFSET(OTP_FUNC_CMD_OFFSET)); writel(data | OTP_FUNC_RD_BIT, rb + MMAP_OTP_OFFSET(OTP_FUNC_CMD_OFFSET)); data = readl(rb + MMAP_OTP_OFFSET(OTP_CMD_GO_OFFSET)); writel(data | OTP_CMD_GO_BIT, rb + MMAP_OTP_OFFSET(OTP_CMD_GO_OFFSET)); ret = read_poll_timeout(readl, regval, !(regval & OTP_STATUS_BUSY_BIT), STATUS_READ_DELAY_US, STATUS_READ_TIMEOUT_US, true, rb + MMAP_OTP_OFFSET(OTP_STATUS_OFFSET)); data = readl(rb + MMAP_OTP_OFFSET(OTP_PASS_FAIL_OFFSET)); if (ret < 0 || data & OTP_FAIL_BIT) { ret = -EIO; goto error; } buf[byte] = readl(rb + MMAP_OTP_OFFSET(OTP_RD_DATA_OFFSET)); } error: release_sys_lock(priv); return ret; } static int pci1xxxx_otp_write(void *priv_t, unsigned int off, void *value_t, size_t count) { struct pci1xxxx_otp_eeprom_device *priv = priv_t; void __iomem *rb = priv->reg_base; char *value = value_t; u32 regval; u32 byte; int ret; u8 data; if (off >= priv->nvmem_config_otp.size) return -EFAULT; if ((off + count) > priv->nvmem_config_otp.size) count = priv->nvmem_config_otp.size - off; ret = set_sys_lock(priv); if (ret) return ret; for (byte = 0; byte < count; byte++) { otp_device_set_address(priv, (u16)(off + byte)); /* * Set OTP_PGM_MODE_BYTE command bit in OTP_PRGM_MODE register * to enable Byte programming */ data = readl(rb + MMAP_OTP_OFFSET(OTP_PRGM_MODE_OFFSET)); writel(data | OTP_PGM_MODE_BYTE_BIT, rb + MMAP_OTP_OFFSET(OTP_PRGM_MODE_OFFSET)); writel(*(value + byte), rb + MMAP_OTP_OFFSET(OTP_PRGM_DATA_OFFSET)); data = readl(rb + MMAP_OTP_OFFSET(OTP_FUNC_CMD_OFFSET)); writel(data | OTP_FUNC_PGM_BIT, rb + MMAP_OTP_OFFSET(OTP_FUNC_CMD_OFFSET)); data = readl(rb + MMAP_OTP_OFFSET(OTP_CMD_GO_OFFSET)); writel(data | OTP_CMD_GO_BIT, rb + MMAP_OTP_OFFSET(OTP_CMD_GO_OFFSET)); ret = read_poll_timeout(readl, regval, !(regval & OTP_STATUS_BUSY_BIT), STATUS_READ_DELAY_US, STATUS_READ_TIMEOUT_US, true, rb + MMAP_OTP_OFFSET(OTP_STATUS_OFFSET)); data = readl(rb + MMAP_OTP_OFFSET(OTP_PASS_FAIL_OFFSET)); if (ret < 0 || data & OTP_FAIL_BIT) { ret = -EIO; goto error; } } error: release_sys_lock(priv); return ret; } static int pci1xxxx_otp_eeprom_probe(struct auxiliary_device *aux_dev, const struct auxiliary_device_id *id) { struct auxiliary_device_wrapper *aux_dev_wrapper; struct pci1xxxx_otp_eeprom_device *priv; struct gp_aux_data_type *pdata; int ret; u8 data; aux_dev_wrapper = container_of(aux_dev, struct auxiliary_device_wrapper, aux_dev); pdata = &aux_dev_wrapper->gp_aux_data; if (!pdata) return -EINVAL; priv = devm_kzalloc(&aux_dev->dev, sizeof(*priv), GFP_KERNEL); if (!priv) return -ENOMEM; priv->pdev = aux_dev; if (!devm_request_mem_region(&aux_dev->dev, pdata->region_start + PERI_PF3_SYSTEM_REG_ADDR_BASE, PERI_PF3_SYSTEM_REG_LENGTH, aux_dev->name)) return -ENOMEM; priv->reg_base = devm_ioremap(&aux_dev->dev, pdata->region_start + PERI_PF3_SYSTEM_REG_ADDR_BASE, PERI_PF3_SYSTEM_REG_LENGTH); if (!priv->reg_base) return -ENOMEM; ret = set_sys_lock(priv); if (ret) return ret; /* Set OTP_PWR_DN to 0 to make OTP Operational */ data = readl(priv->reg_base + MMAP_OTP_OFFSET(OTP_PWR_DN_OFFSET)); writel(data & ~OTP_PWR_DN_BIT, priv->reg_base + MMAP_OTP_OFFSET(OTP_PWR_DN_OFFSET)); dev_set_drvdata(&aux_dev->dev, priv); if (is_eeprom_responsive(priv)) { priv->nvmem_config_eeprom.type = NVMEM_TYPE_EEPROM; priv->nvmem_config_eeprom.name = EEPROM_NAME; priv->nvmem_config_eeprom.dev = &aux_dev->dev; priv->nvmem_config_eeprom.owner = THIS_MODULE; priv->nvmem_config_eeprom.reg_read = pci1xxxx_eeprom_read; priv->nvmem_config_eeprom.reg_write = pci1xxxx_eeprom_write; priv->nvmem_config_eeprom.priv = priv; priv->nvmem_config_eeprom.stride = 1; priv->nvmem_config_eeprom.word_size = 1; priv->nvmem_config_eeprom.size = EEPROM_SIZE_BYTES; priv->nvmem_eeprom = devm_nvmem_register(&aux_dev->dev, &priv->nvmem_config_eeprom); if (IS_ERR(priv->nvmem_eeprom)) return PTR_ERR(priv->nvmem_eeprom); } release_sys_lock(priv); priv->nvmem_config_otp.type = NVMEM_TYPE_OTP; priv->nvmem_config_otp.name = OTP_NAME; priv->nvmem_config_otp.dev = &aux_dev->dev; priv->nvmem_config_otp.owner = THIS_MODULE; priv->nvmem_config_otp.reg_read = pci1xxxx_otp_read; priv->nvmem_config_otp.reg_write = pci1xxxx_otp_write; priv->nvmem_config_otp.priv = priv; priv->nvmem_config_otp.stride = 1; priv->nvmem_config_otp.word_size = 1; priv->nvmem_config_otp.size = OTP_SIZE_BYTES; priv->nvmem_otp = devm_nvmem_register(&aux_dev->dev, &priv->nvmem_config_otp); if (IS_ERR(priv->nvmem_otp)) return PTR_ERR(priv->nvmem_otp); return ret; } static void pci1xxxx_otp_eeprom_remove(struct auxiliary_device *aux_dev) { struct pci1xxxx_otp_eeprom_device *priv; void __iomem *sys_lock; priv = dev_get_drvdata(&aux_dev->dev); sys_lock = priv->reg_base + MMAP_CFG_OFFSET(CFG_SYS_LOCK_OFFSET); writel(CFG_SYS_LOCK_PF3, sys_lock); /* Shut down OTP */ writel(OTP_PWR_DN_BIT, priv->reg_base + MMAP_OTP_OFFSET(OTP_PWR_DN_OFFSET)); writel(0, sys_lock); } static const struct auxiliary_device_id pci1xxxx_otp_eeprom_auxiliary_id_table[] = { {.name = "mchp_pci1xxxx_gp.gp_otp_e2p"}, {}, }; MODULE_DEVICE_TABLE(auxiliary, pci1xxxx_otp_eeprom_auxiliary_id_table); static struct auxiliary_driver pci1xxxx_otp_eeprom_driver = { .driver = { .name = AUX_DRIVER_NAME, }, .probe = pci1xxxx_otp_eeprom_probe, .remove = pci1xxxx_otp_eeprom_remove, .id_table = pci1xxxx_otp_eeprom_auxiliary_id_table }; module_auxiliary_driver(pci1xxxx_otp_eeprom_driver); MODULE_LICENSE("GPL"); MODULE_AUTHOR("Kumaravel Thiagarajan <kumaravel.thiagarajan@microchip.com>"); MODULE_AUTHOR("Tharun Kumar P <tharunkumar.pasumarthi@microchip.com>"); MODULE_AUTHOR("Vaibhaav Ram T.L <vaibhaavram.tl@microchip.com>"); MODULE_DESCRIPTION("Microchip Technology Inc. PCI1xxxx OTP EEPROM Programmer");
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