// SPDX-License-Identifier: GPL-2.0+ /* * Traverse Ten64 Family board * Copyright 2017-2018 NXP * Copyright 2019-2021 Traverse Technologies */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../common/ten64-controller.h" #define I2C_RETIMER_ADDR 0x27 DECLARE_GLOBAL_DATA_PTR; static int ten64_read_board_info(struct t64uc_board_info *); static void ten64_set_macaddrs_from_board_info(struct t64uc_board_info *); static void ten64_board_retimer_ds110df410_init(void); enum { TEN64_BOARD_REV_A = 0xFF, TEN64_BOARD_REV_B = 0xFE, TEN64_BOARD_REV_C = 0xFD, TEN64_BOARD_REV_D = 0xFC, TEN64_BOARD_MAX }; #define RESV_MEM_IN_BANK(b) (gd->arch.resv_ram >= base[b] && \ gd->arch.resv_ram < base[b] + size[b]) int board_early_init_f(void) { fsl_lsch3_early_init_f(); return 0; } static u32 ten64_get_board_rev(void) { struct ccsr_gur *dcfg = (void *)CFG_SYS_FSL_GUTS_ADDR; u32 board_rev_in = in_le32(&dcfg->gpporcr1); return board_rev_in; } int checkboard(void) { enum boot_src src = get_boot_src(); char boardmodel[32]; struct t64uc_board_info boardinfo; u32 board_rev = ten64_get_board_rev(); switch (board_rev) { case TEN64_BOARD_REV_A: snprintf(boardmodel, 32, "A (Alpha)"); break; case TEN64_BOARD_REV_B: snprintf(boardmodel, 32, "B (Beta)"); break; case TEN64_BOARD_REV_C: snprintf(boardmodel, 32, "C"); break; case TEN64_BOARD_REV_D: snprintf(boardmodel, 32, "D"); break; default: snprintf(boardmodel, 32, " Revision %X", (0xFF - board_rev)); break; } printf("Board: 1064-0201%s, boot from ", boardmodel); if (src == BOOT_SOURCE_SD_MMC) puts("SD card\n"); else if (src == BOOT_SOURCE_QSPI_NOR) puts("QSPI\n"); else printf("Unknown boot source %d\n", src); puts("Controller: "); if (IS_ENABLED(CONFIG_TEN64_CONTROLLER)) { /* Driver not compatible with alpha/beta board MCU firmware */ if (board_rev <= TEN64_BOARD_REV_C) { if (ten64_read_board_info(&boardinfo)) { puts("ERROR: unable to communicate\n"); } else { printf("firmware %d.%d.%d\n", boardinfo.fwversion_major, boardinfo.fwversion_minor, boardinfo.fwversion_patch); ten64_set_macaddrs_from_board_info(&boardinfo); } } else { puts("not supported on this board revision\n"); } } else { puts("driver not enabled (no MAC addresses or other information will be read)\n"); } return 0; } int board_init(void) { init_final_memctl_regs(); if (IS_ENABLED(CONFIG_FSL_CAAM)) sec_init(); return 0; } int fsl_initdram(void) { gd->ram_size = tfa_get_dram_size(); if (!gd->ram_size) gd->ram_size = fsl_ddr_sdram_size(); return 0; } void detail_board_ddr_info(void) { puts("\nDDR "); print_size(gd->bd->bi_dram[0].size + gd->bd->bi_dram[1].size, ""); print_ddr_info(0); } void board_quiesce_devices(void) { if (IS_ENABLED(CONFIG_FSL_MC_ENET)) fsl_mc_ldpaa_exit(gd->bd); } void fdt_fixup_board_enet(void *fdt) { int offset; offset = fdt_path_offset(fdt, "/fsl-mc"); if (offset < 0) offset = fdt_path_offset(fdt, "/soc/fsl-mc"); if (offset < 0) { printf("%s: ERROR: fsl-mc node not found in device tree (error %d)\n", __func__, offset); return; } if (get_mc_boot_status() == 0 && (is_lazy_dpl_addr_valid() || get_dpl_apply_status() == 0)) fdt_status_okay(fdt, offset); else fdt_status_fail(fdt, offset); } /* Called after SoC board_late_init in fsl-layerscape/soc.c */ int fsl_board_late_init(void) { ten64_board_retimer_ds110df410_init(); return 0; } int ft_board_setup(void *blob, struct bd_info *bd) { int i; u16 mc_memory_bank = 0; u64 *base; u64 *size; u64 mc_memory_base = 0; u64 mc_memory_size = 0; u16 total_memory_banks; debug("%s blob=0x%p\n", __func__, blob); ft_cpu_setup(blob, bd); fdt_fixup_mc_ddr(&mc_memory_base, &mc_memory_size); if (mc_memory_base != 0) mc_memory_bank++; total_memory_banks = CONFIG_NR_DRAM_BANKS + mc_memory_bank; base = calloc(total_memory_banks, sizeof(u64)); size = calloc(total_memory_banks, sizeof(u64)); /* fixup DT for the two GPP DDR banks */ for (i = 0; i < CONFIG_NR_DRAM_BANKS; i++) { base[i] = gd->bd->bi_dram[i].start; size[i] = gd->bd->bi_dram[i].size; /* reduce size if reserved memory is within this bank */ if (IS_ENABLED(CONFIG_RESV_RAM) && RESV_MEM_IN_BANK(i)) size[i] = gd->arch.resv_ram - base[i]; } if (mc_memory_base != 0) { for (i = 0; i <= total_memory_banks; i++) { if (base[i] == 0 && size[i] == 0) { base[i] = mc_memory_base; size[i] = mc_memory_size; break; } } } fdt_fixup_memory_banks(blob, base, size, total_memory_banks); fdt_fsl_mc_fixup_iommu_map_entry(blob); if (IS_ENABLED(CONFIG_FSL_MC_ENET)) fdt_fixup_board_enet(blob); fdt_fixup_icid(blob); return 0; } #define MACADDRBITS(a, b) (u8)(((a) >> (b)) & 0xFF) /** Probe and return a udevice for the Ten64 board microcontroller. * Optionally, return the I2C bus the microcontroller resides on * @i2c_bus_out: return I2C bus device handle in this pointer */ static int ten64_get_micro_udevice(struct udevice **ucdev, struct udevice **i2c_bus_out) { int ret; struct udevice *i2cbus; ret = uclass_get_device_by_seq(UCLASS_I2C, 0, &i2cbus); if (ret) { printf("%s: Could not get I2C UCLASS", __func__); return ret; } if (i2c_bus_out) *i2c_bus_out = i2cbus; ret = dm_i2c_probe(i2cbus, 0x7E, DM_I2C_CHIP_RD_ADDRESS, ucdev); if (ret) { printf("%s: Could not get microcontroller device\n", __func__); return ret; } return ret; } static int ten64_read_board_info(struct t64uc_board_info *boardinfo) { struct udevice *ucdev; int ret; ret = ten64_get_micro_udevice(&ucdev, NULL); if (ret) return ret; ret = misc_call(ucdev, TEN64_CNTRL_GET_BOARD_INFO, NULL, 0, (void *)boardinfo, 0); if (ret) return ret; return 0; } static void ten64_set_macaddrs_from_board_info(struct t64uc_board_info *boardinfo) { char ethaddr[18]; char enetvar[10]; u8 intfidx, this_dpmac_num; u64 macaddr = 0; /* We will copy the MAC address returned from the * uC (48 bits) into the u64 macaddr */ u8 *macaddr_bytes = (u8 *)&macaddr + 2; /** MAC addresses are allocated in order of the physical port numbers, * DPMAC7->10 is "eth0" through "eth3" * DPMAC3->6 is "eth4" through "eth7" * DPMAC2 and 1 are "eth8" and "eth9" respectively */ int allocation_order[10] = {7, 8, 9, 10, 3, 4, 5, 6, 2, 1}; memcpy(macaddr_bytes, boardinfo->mac, 6); /* MAC address bytes from uC are in big endian, * convert to CPU */ macaddr = __be64_to_cpu(macaddr); for (intfidx = 0; intfidx < 10; intfidx++) { snprintf(ethaddr, 18, "%02X:%02X:%02X:%02X:%02X:%02X", MACADDRBITS(macaddr, 40), MACADDRBITS(macaddr, 32), MACADDRBITS(macaddr, 24), MACADDRBITS(macaddr, 16), MACADDRBITS(macaddr, 8), MACADDRBITS(macaddr, 0)); this_dpmac_num = allocation_order[intfidx]; printf("DPMAC%d: %s\n", this_dpmac_num, ethaddr); snprintf(enetvar, 10, (this_dpmac_num != 1) ? "eth%daddr" : "ethaddr", this_dpmac_num - 1); macaddr++; if (!env_get(enetvar)) env_set(enetvar, ethaddr); } } /* The retimer (DS110DF410) is one of the devices without * a RESET line, but a power switch is on the board * allowing it to be reset via uC command */ static int board_cycle_retimer(struct udevice **retim_dev) { int ret; u8 loop; struct udevice *uc_dev; struct udevice *i2cbus; ret = ten64_get_micro_udevice(&uc_dev, &i2cbus); if (ret) return ret; ret = dm_i2c_probe(i2cbus, I2C_RETIMER_ADDR, 0, retim_dev); if (ret == 0) { puts("(retimer on, resetting...) "); ret = misc_call(uc_dev, TEN64_CNTRL_10G_OFF, NULL, 0, NULL, 0); mdelay(1000); } ret = misc_call(uc_dev, TEN64_CNTRL_10G_ON, NULL, 0, NULL, 0); // Wait for retimer to come back for (loop = 0; loop < 5; loop++) { ret = dm_i2c_probe(i2cbus, I2C_RETIMER_ADDR, 0, retim_dev); if (ret == 0) return 0; mdelay(500); } return -ENOSYS; } /* ten64_board_retimer_ds110df410_init() - Configure the 10G retimer * Adopted from the t102xqds board file */ static void ten64_board_retimer_ds110df410_init(void) { u8 reg; int ret; struct udevice *retim_dev; u32 board_rev = ten64_get_board_rev(); puts("Retimer: "); /* Retimer power cycle not implemented on early board * revisions/controller firmwares */ if (IS_ENABLED(CONFIG_TEN64_CONTROLLER) && board_rev >= TEN64_BOARD_REV_C) { ret = board_cycle_retimer(&retim_dev); if (ret) { puts("Retimer power on failed\n"); return; } } /* Access to Control/Shared register */ reg = 0x0; ret = dm_i2c_write(retim_dev, 0xff, ®, 1); if (ret) { printf("Error writing to retimer register (error %d)\n", ret); return; } /* Read device revision and ID */ dm_i2c_read(retim_dev, 1, ®, 1); if (reg == 0xF0) puts("DS110DF410 found\n"); else printf("Unknown retimer 0x%xn\n", reg); /* Enable Broadcast */ reg = 0x0c; dm_i2c_write(retim_dev, 0xff, ®, 1); /* Perform a full reset (state, channel and clock) * for all channels * as the DS110DF410 does not have a RESET line */ dm_i2c_read(retim_dev, 0, ®, 1); reg |= 0x7; dm_i2c_write(retim_dev, 0, ®, 1); /* Set rate/subrate = 0 */ reg = 0x6; dm_i2c_write(retim_dev, 0x2F, ®, 1); /* Set data rate as 10.3125 Gbps */ reg = 0x0; dm_i2c_write(retim_dev, 0x60, ®, 1); reg = 0xb2; dm_i2c_write(retim_dev, 0x61, ®, 1); reg = 0x90; dm_i2c_write(retim_dev, 0x62, ®, 1); reg = 0xb3; dm_i2c_write(retim_dev, 0x63, ®, 1); reg = 0xff; dm_i2c_write(retim_dev, 0x64, ®, 1); /* Invert channel 2 (Lower SFP TX to CPU) due to the SFP being inverted */ reg = 0x05; dm_i2c_write(retim_dev, 0xFF, ®, 1); dm_i2c_read(retim_dev, 0x1F, ®, 1); reg |= 0x80; dm_i2c_write(retim_dev, 0x1F, ®, 1); puts("OK\n"); }