/* SPDX-License-Identifier: GPL-2.0-only */ /* * This file is basically drivers/spi/cbfs_spi.cb but the boot device is not known at build time */ #include #include #include #include #include #include #include #include #include #include #include #include // There are two different means of accessing the SPI flash. // They are controlled by the fctrl register. // 1. memory mapped access // 2. FIFO based access /* follow is the FSBL boot device defined by ZSBL of sifive * FSBL replaced by bootblock of coreboot * MSEL_SPInx1 -> test if boot from memory-mapped on SPIn * MSEL_SPInx4 -> test if boot from memory-mapped on QPIn * MSEL_SPInSD -> test if boot from sdcard mount on SPIn */ #define MSEL_SPI0x1(m) (((m) == 5) || ((m) == 14)) #define MSEL_SPI0x4(m) (((m) == 6) || ((m) == 10) || ((m) == 15)) #define MSEL_SPI1x1(m) ((m) == 12) #define MSEL_SPI1x4(m) (((m) == 7) || ((m) == 13)) #define MSEL_SPI1SD(m) ((m) == 8) #define MSEL_SPI2x1(m) ((m) == 9) #define MSEL_SPI2SD(m) ((m) == 11) #define MSEL_ACCESS_METHOD_MMAP(m) ((m == 5) || (m == 6) || (m == 7) || (m == 10) || (m == 13)) // probably something for devicetree struct fu740_spi_config fu740_spi_configs[] = { { 0 }, { .freq = 10*1000*1000, }, { 0 }, }; static struct spi_sdcard spi2_sdcard; //TODO initialize SPI2 //static struct spi_flash spi0_flash; //static struct spi_flash spi1_flash; static struct spi_flash spi_flash; static bool spi_flash_init_done; static ssize_t sd_readat(const struct region_device *rdev, void *dest, size_t offset, size_t count) { spi_sdcard_read(&spi2_sdcard, dest, offset, count); return count; } static ssize_t spi_readat(const struct region_device *rd, void *b, size_t offset, size_t size) { if (spi_flash_read(&spi_flash, offset, size, b)) return -1; return size; } static ssize_t spi_writeat(const struct region_device *rd, const void *b, size_t offset, size_t size) { if (spi_flash_write(&spi_flash, offset, size, b)) return -1; return size; } static ssize_t spi_eraseat(const struct region_device *rd, size_t offset, size_t size) { if (spi_flash_erase(&spi_flash, offset, size)) return -1; return size; } static const struct region_device_ops sd_ops = { .mmap = mmap_helper_rdev_mmap, .munmap = mmap_helper_rdev_munmap, .readat = sd_readat, }; static const struct region_device_ops spi_ops = { .mmap = mmap_helper_rdev_mmap, .munmap = mmap_helper_rdev_munmap, .readat = spi_readat, .writeat = spi_writeat, .eraseat = spi_eraseat, }; //TODO using postram cache means that all spi transitions are transferred to actual memory. // Native memory mapping obviously doesnt have that problem. That can however only happen if // memory has been initialized before accessing the boot device. So no CBFS access before boot. //static struct mem_pool mem_cbfs_cache = // MEM_POOL_INIT(_postram_cbfs_cache, REGION_SIZE(postram_cbfs_cache), CONFIG_CBFS_CACHE_ALIGN); //static struct mmap_helper_region_device spi_mdev = // MMAP_HELPER_DEV_INIT(&spi_ops, 0, CONFIG_ROM_SIZE, &mem_cbfs_cache); static struct mmap_helper_region_device spi_mdev = MMAP_HELPER_DEV_INIT(&spi_ops, 0, CONFIG_ROM_SIZE, &cbfs_cache); static struct mmap_helper_region_device sd_mdev = MMAP_HELPER_DEV_INIT(&sd_ops, 0, CONFIG_ROM_SIZE, &cbfs_cache); void boot_device_init(void) { printk(BIOS_DEBUG, "%s 0\n", __func__); if (spi_flash_init_done == true) return; uint32_t m = read32((uint32_t *)FU740_MSEL) & 0xf; printk(BIOS_DEBUG, "%s MSEL %#x\n", __func__, m); // We have not yet found a way to reliably program the // on-board SPI part (sifive neglected to put a diode on vcc ...) // Once we work that out, we can test this code. // It is left here as a hint of what needs to be done. // Pass the information of the flash read operation to the spi controller if (MSEL_SPI0x4(m)) { die("SPI0x4 is not supported yet"); //config.ffmt_config.data_proto = FU740_SPI_PROTO_Q; //config.ffmt_config.cmd_code = 0x6B; // Quad output read //.cmd_code = 0xec, //.pad_cnt = 6, } if (MSEL_SPI1x4(m)) { printk(BIOS_DEBUG, "%s SPI1x4 1\n", __func__); fu740_spi_configs[1].ffmt_config.data_proto = FU740_SPI_PROTO_Q; fu740_spi_configs[1].ffmt_config.cmd_code = 0x6b; // quad if (spi_flash_probe(1, 0, &spi_flash)) { printk(BIOS_EMERG, "SPI1x4 failed to init SPI flash\n"); return; } if (fu740_spi_setup(&spi_flash.spi) == -1) { printk(BIOS_EMERG, "SPI1x4 failed to configure mmap for SPI flash\n"); } printk(BIOS_DEBUG, "%s SPI1x4 2\n", __func__); } else if (MSEL_SPI1x1(m)) { printk(BIOS_DEBUG, "%s 1\n", __func__); fu740_spi_configs[1].ffmt_config.data_proto = FU740_SPI_PROTO_S; fu740_spi_configs[1].ffmt_config.cmd_code = 0x03; // Normal read //TODO SPI1x1 is always using programmed IO (FIFO)? (memory map did not work...) if (spi_flash_probe(1, 0, &spi_flash)) { printk(BIOS_EMERG, "failed to init SPI flash\n"); return; } printk(BIOS_DEBUG, "%s 2\n", __func__); } else if (MSEL_SPI2SD(m)) { spi_sdcard_init(&spi2_sdcard, 2, 0); } else { printk(BIOS_EMERG, "MSEL: %#02x: ", m); die("unsupported configuration of MSEL\n"); } spi_flash_init_done = true; } /* Return the CBFS boot device. */ const struct region_device *boot_device_ro(void) { if (spi_flash_init_done != true) return NULL; uint32_t m = read32((uint32_t *)FU740_MSEL); if (MSEL_SPI2SD(m) || MSEL_SPI1SD(m)) return &sd_mdev.rdev; return &spi_mdev.rdev; } //const struct spi_flash *boot_device_spi_flash(void) //{ // boot_device_init(); // // if (spi_flash_init_done != true) // return NULL; // // return &spi_flash; //}