// SPDX-License-Identifier: GPL-2.0+ /* * (C) 2017 Marvell International Ltd. * (C) 2021 Pali Rohár */ #include #include #include #include #include #include #define OTP_NB_REG_BASE ((void __iomem *)MVEBU_REGISTER(0x12600)) #define OTP_SB_REG_BASE ((void __iomem *)MVEBU_REGISTER(0x1A200)) #define OTP_CONTROL_OFF 0x00 #define OTP_MODE_BIT BIT(15) #define OTP_RPTR_RST_BIT BIT(14) #define OTP_POR_B_BIT BIT(13) #define OTP_PRDT_BIT BIT(3) #define OTP_READ_PORT_OFF 0x04 #define OTP_READ_POINTER_OFF 0x08 #define OTP_PTR_INC_BIT BIT(8) static void otp_read_parallel(void __iomem *base, u32 *data, u32 count) { u32 regval; /* 1. Clear OTP_MODE_NB to parallel mode */ regval = readl(base + OTP_CONTROL_OFF); regval &= ~OTP_MODE_BIT; writel(regval, base + OTP_CONTROL_OFF); /* 2. Set OTP_POR_B_NB enter normal operation */ regval = readl(base + OTP_CONTROL_OFF); regval |= OTP_POR_B_BIT; writel(regval, base + OTP_CONTROL_OFF); /* 3. Set OTP_PTR_INC_NB to auto-increment pointer after each read */ regval = readl(base + OTP_READ_POINTER_OFF); regval |= OTP_PTR_INC_BIT; writel(regval, base + OTP_READ_POINTER_OFF); /* 4. Set OTP_RPTR_RST_NB, then clear the same field */ regval = readl(base + OTP_CONTROL_OFF); regval |= OTP_RPTR_RST_BIT; writel(regval, base + OTP_CONTROL_OFF); regval = readl(base + OTP_CONTROL_OFF); regval &= ~OTP_RPTR_RST_BIT; writel(regval, base + OTP_CONTROL_OFF); /* 5. Toggle OTP_PRDT_NB * a. Set OTP_PRDT_NB to 1. * b. Clear OTP_PRDT_NB to 0. * c. Wait for a minimum of 100 ns. * d. Set OTP_PRDT_NB to 1 */ regval = readl(base + OTP_CONTROL_OFF); regval |= OTP_PRDT_BIT; writel(regval, base + OTP_CONTROL_OFF); regval = readl(base + OTP_CONTROL_OFF); regval &= ~OTP_PRDT_BIT; writel(regval, base + OTP_CONTROL_OFF); ndelay(100); regval = readl(base + OTP_CONTROL_OFF); regval |= OTP_PRDT_BIT; writel(regval, base + OTP_CONTROL_OFF); while (count-- > 0) { /* 6. Read the content of OTP 32-bits at a time */ ndelay(100000); *(data++) = readl(base + OTP_READ_PORT_OFF); } } static int rwtm_otp_read(u8 row, u32 word, u32 *data) { u32 out[3]; u32 in[2]; int res = -EINVAL; if (word < 2) { /* * MBOX_CMD_OTP_READ_32B command is supported by Marvell * fuse.bin firmware and also by new CZ.NIC wtmi firmware. * This command returns raw bits without ECC corrections. * It does not provide access to the lock bit. */ in[0] = row; in[1] = word * 32; res = mbox_do_cmd(MBOX_CMD_OTP_READ_32B, in, 2, out, 1); if (!res) *data = out[0]; } else if (word == 2) { /* * MBOX_CMD_OTP_READ command is supported only by new CZ.NIC * wtmi firmware and provides access to all bits, including * lock bit without doing ECC corrections. For compatibility * with Marvell fuse.bin firmware, use this command only for * accessing lock bit. */ in[0] = row; res = mbox_do_cmd(MBOX_CMD_OTP_READ, in, 1, out, 3); if (!res) *data = out[2]; } return res; } static int rwtm_otp_write(u8 row, u32 word, u32 data) { u32 in[4]; int res = -EINVAL; if (word < 2) { /* * MBOX_CMD_OTP_WRITE_32B command is supported by Marvell * fuse.bin firmware and also by new CZ.NIC wtmi firmware. * This command writes only selected bits to OTP and does * not calculate ECC bits. It does not allow to write the * lock bit. */ in[0] = row; in[1] = word * 32; in[2] = data; res = mbox_do_cmd(MBOX_CMD_OTP_WRITE_32B, in, 3, NULL, 0); } else if (word == 2 && !(data & ~0x1)) { /* * MBOX_CMD_OTP_WRITE command is supported only by new CZ.NIC * wtmi firmware and allows to write any bit to OTP, including * the lock bit. It does not calculate or write ECC bits too. * For compatibility with Marvell fuse.bin firmware, use this * command only for writing the lock bit. */ in[0] = row; in[1] = 0; in[2] = 0; in[3] = data; res = mbox_do_cmd(MBOX_CMD_OTP_WRITE, in, 4, NULL, 0); } return res; } /* * Banks 0-43 are used for accessing Security OTP (44 rows with 67 bits via 44 banks and words 0-2) * Bank 44 is used for accessing North Bridge OTP (69 bits via words 0-2) * Bank 45 is used for accessing South Bridge OTP (97 bits via words 0-3) */ #define RWTM_ROWS 44 #define RWTM_MAX_BANK (RWTM_ROWS - 1) #define RWTM_ROW_WORDS 3 #define OTP_NB_BANK RWTM_ROWS #define OTP_NB_WORDS 3 #define OTP_SB_BANK (RWTM_ROWS + 1) #define OTP_SB_WORDS 4 int fuse_read(u32 bank, u32 word, u32 *val) { if (bank <= RWTM_MAX_BANK) { if (word >= RWTM_ROW_WORDS) return -EINVAL; return rwtm_otp_read(bank, word, val); } else if (bank == OTP_NB_BANK) { u32 data[OTP_NB_WORDS]; if (word >= OTP_NB_WORDS) return -EINVAL; otp_read_parallel(OTP_NB_REG_BASE, data, OTP_NB_WORDS); *val = data[word]; return 0; } else if (bank == OTP_SB_BANK) { u32 data[OTP_SB_WORDS]; if (word >= OTP_SB_WORDS) return -EINVAL; otp_read_parallel(OTP_SB_REG_BASE, data, OTP_SB_WORDS); *val = data[word]; return 0; } else { return -EINVAL; } } int fuse_prog(u32 bank, u32 word, u32 val) { if (bank <= RWTM_MAX_BANK) { if (word >= RWTM_ROW_WORDS) return -EINVAL; return rwtm_otp_write(bank, word, val); } else if (bank == OTP_NB_BANK) { /* TODO: not implemented yet */ return -ENOSYS; } else if (bank == OTP_SB_BANK) { /* TODO: not implemented yet */ return -ENOSYS; } else { return -EINVAL; } } int fuse_sense(u32 bank, u32 word, u32 *val) { /* not supported */ return -ENOSYS; } int fuse_override(u32 bank, u32 word, u32 val) { /* not supported */ return -ENOSYS; }