/* * Copyright (c) 2016-2020, Broadcom * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #ifdef USE_SOFT_SOTP extern uint64_t soft_sotp[]; #endif #define SOTP_PROG_CONTROL (SOTP_REGS_OTP_BASE + 0x0000) #define SOTP_PROG_CONTROL__OTP_CPU_MODE_EN 15 #define SOTP_PROG_CONTROL__OTP_DISABLE_ECC 9 #define SOTP_PROG_CONTROL__OTP_ECC_WREN 8 #define SOTP_WRDATA_0 (SOTP_REGS_OTP_BASE + 0x0004) #define SOTP_WRDATA_1 (SOTP_REGS_OTP_BASE + 0x0008) #define SOTP_ADDR (SOTP_REGS_OTP_BASE + 0x000c) #define SOTP_ADDR__OTP_ROW_ADDR_R 6 #define SOTP_ADDR_MASK 0x3FF #define SOTP_CTRL_0 (SOTP_REGS_OTP_BASE + 0x0010) #define SOTP_CTRL_0__START 0 #define SOTP_CTRL_0__OTP_CMD 1 #define SOTP_STATUS_0 (SOTP_REGS_OTP_BASE + 0x0018) #define SOTP_STATUS__FDONE 3 #define SOTP_STATUS_1 (SOTP_REGS_OTP_BASE + 0x001c) #define SOTP_STATUS_1__CMD_DONE 1 #define SOTP_STATUS_1__ECC_DET 17 #define SOTP_RDDATA_0 (SOTP_REGS_OTP_BASE + 0x0020) #define SOTP_RDDATA_1 (SOTP_REGS_OTP_BASE + 0x0024) #define SOTP_READ 0 #define SOTP_PROG_WORD 10 #define SOTP_STATUS__PROGOK 2 #define SOTP_PROG_ENABLE 2 #define SOTP_ROW_DATA_MASK 0xffffffff #define SOTP_ECC_ERR_BITS_MASK 0x1ff00000000 #define SOTP_CHIP_CTRL_SW_OVERRIDE_CHIP_STATES 4 #define SOTP_CHIP_CTRL_SW_MANU_PROG 5 #define SOTP_CHIP_CTRL_SW_CID_PROG 6 #define SOTP_CHIP_CTRL_SW_AB_DEVICE 8 #define SOTP_CHIP_CTRL_SW_AB_DEV_MODE 9 #define CHIP_STATE_UNPROGRAMMED 0x1 #define CHIP_STATE_UNASSIGNED 0x2 uint64_t sotp_mem_read(uint32_t offset, uint32_t sotp_add_ecc) { #ifdef USE_SOFT_SOTP (void)sotp_add_ecc; return soft_sotp[offset]; #else uint64_t read_data = 0; uint64_t read_data1 = 0; uint64_t read_data2 = 0; /* Check for FDONE status */ while ((mmio_read_32(SOTP_STATUS_0) & BIT(SOTP_STATUS__FDONE)) != BIT(SOTP_STATUS__FDONE)) ; /* Enable OTP access by CPU */ mmio_setbits_32(SOTP_PROG_CONTROL, BIT(SOTP_PROG_CONTROL__OTP_CPU_MODE_EN)); if (sotp_add_ecc == 1) { mmio_clrbits_32(SOTP_PROG_CONTROL, BIT(SOTP_PROG_CONTROL__OTP_DISABLE_ECC)); } if (sotp_add_ecc == 0) { mmio_setbits_32(SOTP_PROG_CONTROL, BIT(SOTP_PROG_CONTROL__OTP_DISABLE_ECC)); } mmio_write_32(SOTP_ADDR, ((offset & SOTP_ADDR_MASK) << SOTP_ADDR__OTP_ROW_ADDR_R)); mmio_write_32(SOTP_CTRL_0, (SOTP_READ << SOTP_CTRL_0__OTP_CMD)); /* Start bit to tell SOTP to send command to the OTP controller */ mmio_setbits_32(SOTP_CTRL_0, BIT(SOTP_CTRL_0__START)); /* Wait for SOTP command done to be set */ while ((mmio_read_32(SOTP_STATUS_1) & BIT(SOTP_STATUS_1__CMD_DONE)) != BIT(SOTP_STATUS_1__CMD_DONE)) ; /* Clr Start bit after command done */ mmio_clrbits_32(SOTP_CTRL_0, BIT(SOTP_CTRL_0__START)); if ((offset > SOTP_DEVICE_SECURE_CFG3_ROW) && (mmio_read_32(SOTP_STATUS_1) & BIT(SOTP_STATUS_1__ECC_DET))) { ERROR("SOTP ECC ERROR Detected row offset %d\n", offset); read_data = SOTP_ECC_ERR_DETECT; } else { read_data1 = (uint64_t)mmio_read_32(SOTP_RDDATA_0); read_data1 = read_data1 & 0xFFFFFFFF; read_data2 = (uint64_t)mmio_read_32(SOTP_RDDATA_1); read_data2 = (read_data2 & 0x1ff) << 32; read_data = read_data1 | read_data2; } /* Command done is cleared */ mmio_setbits_32(SOTP_STATUS_1, BIT(SOTP_STATUS_1__CMD_DONE)); /* disable OTP access by CPU */ mmio_clrbits_32(SOTP_PROG_CONTROL, BIT(SOTP_PROG_CONTROL__OTP_CPU_MODE_EN)); return read_data; #endif } void sotp_mem_write(uint32_t addr, uint32_t sotp_add_ecc, uint64_t wdata) { #ifdef USE_SOFT_SOTP (void)sotp_add_ecc; soft_sotp[addr] = wdata; #else uint32_t loop; uint8_t prog_array[4] = { 0x0F, 0x04, 0x08, 0x0D }; uint32_t chip_state_default = (CHIP_STATE_UNASSIGNED|CHIP_STATE_UNPROGRAMMED); uint32_t chip_state = mmio_read_32(SOTP_REGS_SOTP_CHIP_STATES); uint32_t chip_ctrl_default = 0; /* * The override settings is required to allow the customer to program * the application specific keys into SOTP, before the conversion to * one of the AB modes. * At the end of write operation, the chip ctrl settings will restored * to the state prior to write call */ if (chip_state & chip_state_default) { uint32_t chip_ctrl; chip_ctrl_default = mmio_read_32(SOTP_CHIP_CTRL); INFO("SOTP: enable special prog mode\n"); chip_ctrl = BIT(SOTP_CHIP_CTRL_SW_OVERRIDE_CHIP_STATES) | BIT(SOTP_CHIP_CTRL_SW_MANU_PROG) | BIT(SOTP_CHIP_CTRL_SW_CID_PROG) | BIT(SOTP_CHIP_CTRL_SW_AB_DEVICE); mmio_write_32(SOTP_CHIP_CTRL, chip_ctrl); } /* Check for FDONE status */ while ((mmio_read_32(SOTP_STATUS_0) & BIT(SOTP_STATUS__FDONE)) != BIT(SOTP_STATUS__FDONE)) ; /* Enable OTP access by CPU */ mmio_setbits_32(SOTP_PROG_CONTROL, BIT(SOTP_PROG_CONTROL__OTP_CPU_MODE_EN)); if (addr > SOTP_DEVICE_SECURE_CFG3_ROW) { if (sotp_add_ecc == 0) { mmio_clrbits_32(SOTP_PROG_CONTROL, BIT(SOTP_PROG_CONTROL__OTP_ECC_WREN)); } if (sotp_add_ecc == 1) { mmio_setbits_32(SOTP_PROG_CONTROL, BIT(SOTP_PROG_CONTROL__OTP_ECC_WREN)); } } else { mmio_clrbits_32(SOTP_PROG_CONTROL, BIT(SOTP_PROG_CONTROL__OTP_ECC_WREN)); } mmio_write_32(SOTP_CTRL_0, (SOTP_PROG_ENABLE << 1)); /* * In order to avoid unintentional writes / programming of the OTP * array, the OTP Controller must be put into programming mode before * it will accept program commands. This is done by writing 0xF, 0x4, * 0x8, 0xD with program commands prior to starting the actual * programming sequence */ for (loop = 0; loop < 4; loop++) { mmio_write_32(SOTP_WRDATA_0, prog_array[loop]); /* * Start bit to tell SOTP to send command to the OTP controller */ mmio_setbits_32(SOTP_CTRL_0, BIT(SOTP_CTRL_0__START)); /* Wait for SOTP command done to <-- be set */ while ((mmio_read_32(SOTP_STATUS_1) & BIT(SOTP_STATUS_1__CMD_DONE)) != BIT(SOTP_STATUS_1__CMD_DONE)) ; /* Command done is cleared w1c */ mmio_setbits_32(SOTP_STATUS_1, BIT(SOTP_STATUS_1__CMD_DONE)); /* Clr Start bit after command done */ mmio_clrbits_32(SOTP_CTRL_0, BIT(SOTP_CTRL_0__START)); } /* Check for PROGOK */ while ((mmio_read_32(SOTP_STATUS_0) & 0x4) != BIT(SOTP_STATUS__PROGOK)) ; /* Set 10 bit row address */ mmio_write_32(SOTP_ADDR, ((addr & SOTP_ADDR_MASK) << SOTP_ADDR__OTP_ROW_ADDR_R)); /* Set SOTP Row data */ mmio_write_32(SOTP_WRDATA_0, (wdata & SOTP_ROW_DATA_MASK)); /* Set SOTP ECC and error bits */ mmio_write_32(SOTP_WRDATA_1, ((wdata & SOTP_ECC_ERR_BITS_MASK) >> 32)); /* Set prog_word command */ mmio_write_32(SOTP_CTRL_0, (SOTP_PROG_WORD << 1)); /* Start bit to tell SOTP to send command to the OTP controller */ mmio_setbits_32(SOTP_CTRL_0, BIT(SOTP_CTRL_0__START)); /* Wait for SOTP command done to be set */ while ((mmio_read_32(SOTP_STATUS_1) & BIT(SOTP_STATUS_1__CMD_DONE)) != BIT(SOTP_STATUS_1__CMD_DONE)) ; /* Command done is cleared w1c */ mmio_setbits_32(SOTP_STATUS_1, BIT(SOTP_STATUS_1__CMD_DONE)); /* disable OTP access by CPU */ mmio_clrbits_32(SOTP_PROG_CONTROL, BIT(SOTP_PROG_CONTROL__OTP_CPU_MODE_EN)); /* Clr Start bit after command done */ mmio_clrbits_32(SOTP_CTRL_0, BIT(SOTP_CTRL_0__START)); if (chip_state & chip_state_default) mmio_write_32(SOTP_CHIP_CTRL, chip_ctrl_default); #endif } int sotp_read_key(uint8_t *key, size_t keysize, int start_row, int end_row) { int row; uint32_t status = 0; uint32_t status2 = 0xFFFFFFFF; uint64_t row_data; uint32_t data; uint32_t *temp_key = (uint32_t *)key; row = start_row; while ((keysize > 0) && (row <= end_row)) { row_data = sotp_mem_read(row, SOTP_ROW_ECC); if (!(row_data & (SOTP_ECC_ERR_DETECT | SOTP_FAIL_BITS))) { memcpy(temp_key++, &row_data, sizeof(uint32_t)); keysize -= sizeof(uint32_t); data = (uint32_t)(row_data & SOTP_ROW_DATA_MASK); status |= data; status2 &= data; } row++; } if ((status2 == 0xFFFFFFFF) || (status == 0) || (row > end_row)) return -1; return 0; } int sotp_key_erased(void) { uint64_t row_data; int status = 0; row_data = sotp_mem_read(SOTP_DEVICE_SECURE_CFG0_ROW, 0); if (row_data & SOTP_DEVICE_SECURE_CFG0_OTP_ERASED_MASK) status = 1; else if (mmio_read_32(SOTP_REGS_SOTP_CHIP_STATES) & SOTP_REGS_SOTP_CHIP_STATES_OTP_ERASED_MASK) status = 1; return status; } /* * This function optimise the SOTP redundancy * by considering the 00- zero and 01,10,11 - one */ uint32_t sotp_redundancy_reduction(uint32_t sotp_row_data) { uint32_t opt_data; uint32_t opt_loop; uint32_t temp_data; opt_data = 0; for (opt_loop = 0; opt_loop < 16; opt_loop = opt_loop + 1) { temp_data = ((sotp_row_data >> (opt_loop * 2)) & 0x3); if (temp_data != 0x0) opt_data = (opt_data | (1 << opt_loop)); } return opt_data; }