/* * arch/arm/mach-orion5x/ts78xx-setup.c * * Maintainer: Alexander Clouter * * This file is licensed under the terms of the GNU General Public * License version 2. This program is licensed "as is" without any * warranty of any kind, whether express or implied. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "common.h" #include "mpp.h" #include "ts78xx-fpga.h" /***************************************************************************** * TS-78xx Info ****************************************************************************/ /* * FPGA - lives where the PCI bus would be at ORION5X_PCI_MEM_PHYS_BASE */ #define TS78XX_FPGA_REGS_PHYS_BASE 0xe8000000 #define TS78XX_FPGA_REGS_VIRT_BASE 0xff900000 #define TS78XX_FPGA_REGS_SIZE SZ_1M static struct ts78xx_fpga_data ts78xx_fpga = { .id = 0, .state = 1, /* .supports = ... - populated by ts78xx_fpga_supports() */ }; /***************************************************************************** * I/O Address Mapping ****************************************************************************/ static struct map_desc ts78xx_io_desc[] __initdata = { { .virtual = TS78XX_FPGA_REGS_VIRT_BASE, .pfn = __phys_to_pfn(TS78XX_FPGA_REGS_PHYS_BASE), .length = TS78XX_FPGA_REGS_SIZE, .type = MT_DEVICE, }, }; void __init ts78xx_map_io(void) { orion5x_map_io(); iotable_init(ts78xx_io_desc, ARRAY_SIZE(ts78xx_io_desc)); } /***************************************************************************** * Ethernet ****************************************************************************/ static struct mv643xx_eth_platform_data ts78xx_eth_data = { .phy_addr = MV643XX_ETH_PHY_ADDR(0), }; /***************************************************************************** * SATA ****************************************************************************/ static struct mv_sata_platform_data ts78xx_sata_data = { .n_ports = 2, }; /***************************************************************************** * RTC M48T86 - nicked^Wborrowed from arch/arm/mach-ep93xx/ts72xx.c ****************************************************************************/ #define TS_RTC_CTRL (TS78XX_FPGA_REGS_VIRT_BASE | 0x808) #define TS_RTC_DATA (TS78XX_FPGA_REGS_VIRT_BASE | 0x80c) static unsigned char ts78xx_ts_rtc_readbyte(unsigned long addr) { writeb(addr, TS_RTC_CTRL); return readb(TS_RTC_DATA); } static void ts78xx_ts_rtc_writebyte(unsigned char value, unsigned long addr) { writeb(addr, TS_RTC_CTRL); writeb(value, TS_RTC_DATA); } static struct m48t86_ops ts78xx_ts_rtc_ops = { .readbyte = ts78xx_ts_rtc_readbyte, .writebyte = ts78xx_ts_rtc_writebyte, }; static struct platform_device ts78xx_ts_rtc_device = { .name = "rtc-m48t86", .id = -1, .dev = { .platform_data = &ts78xx_ts_rtc_ops, }, .num_resources = 0, }; /* * TS uses some of the user storage space on the RTC chip so see if it is * present; as it's an optional feature at purchase time and not all boards * will have it present * * I've used the method TS use in their rtc7800.c example for the detection * * TODO: track down a guinea pig without an RTC to see if we can work out a * better RTC detection routine */ static int ts78xx_ts_rtc_load(void) { int rc; unsigned char tmp_rtc0, tmp_rtc1; tmp_rtc0 = ts78xx_ts_rtc_readbyte(126); tmp_rtc1 = ts78xx_ts_rtc_readbyte(127); ts78xx_ts_rtc_writebyte(0x00, 126); ts78xx_ts_rtc_writebyte(0x55, 127); if (ts78xx_ts_rtc_readbyte(127) == 0x55) { ts78xx_ts_rtc_writebyte(0xaa, 127); if (ts78xx_ts_rtc_readbyte(127) == 0xaa && ts78xx_ts_rtc_readbyte(126) == 0x00) { ts78xx_ts_rtc_writebyte(tmp_rtc0, 126); ts78xx_ts_rtc_writebyte(tmp_rtc1, 127); if (ts78xx_fpga.supports.ts_rtc.init == 0) { rc = platform_device_register(&ts78xx_ts_rtc_device); if (!rc) ts78xx_fpga.supports.ts_rtc.init = 1; } else rc = platform_device_add(&ts78xx_ts_rtc_device); return rc; } } return -ENODEV; }; static void ts78xx_ts_rtc_unload(void) { platform_device_del(&ts78xx_ts_rtc_device); } /***************************************************************************** * NAND Flash ****************************************************************************/ #define TS_NAND_CTRL (TS78XX_FPGA_REGS_VIRT_BASE | 0x800) /* VIRT */ #define TS_NAND_DATA (TS78XX_FPGA_REGS_PHYS_BASE | 0x804) /* PHYS */ /* * hardware specific access to control-lines * * ctrl: * NAND_NCE: bit 0 -> bit 2 * NAND_CLE: bit 1 -> bit 1 * NAND_ALE: bit 2 -> bit 0 */ static void ts78xx_ts_nand_cmd_ctrl(struct mtd_info *mtd, int cmd, unsigned int ctrl) { struct nand_chip *this = mtd->priv; if (ctrl & NAND_CTRL_CHANGE) { unsigned char bits; bits = (ctrl & NAND_NCE) << 2; bits |= ctrl & NAND_CLE; bits |= (ctrl & NAND_ALE) >> 2; writeb((readb(TS_NAND_CTRL) & ~0x7) | bits, TS_NAND_CTRL); } if (cmd != NAND_CMD_NONE) writeb(cmd, this->IO_ADDR_W); } static int ts78xx_ts_nand_dev_ready(struct mtd_info *mtd) { return readb(TS_NAND_CTRL) & 0x20; } static void ts78xx_ts_nand_write_buf(struct mtd_info *mtd, const uint8_t *buf, int len) { struct nand_chip *chip = mtd->priv; void __iomem *io_base = chip->IO_ADDR_W; unsigned long off = ((unsigned long)buf & 3); int sz; if (off) { sz = min(4 - off, len); writesb(io_base, buf, sz); buf += sz; len -= sz; } sz = len >> 2; if (sz) { u32 *buf32 = (u32 *)buf; writesl(io_base, buf32, sz); buf += sz << 2; len -= sz << 2; } if (len) writesb(io_base, buf, len); } static void ts78xx_ts_nand_read_buf(struct mtd_info *mtd, uint8_t *buf, int len) { struct nand_chip *chip = mtd->priv; void __iomem *io_base = chip->IO_ADDR_R; unsigned long off = ((unsigned long)buf & 3); int sz; if (off) { sz = min(4 - off, len); readsb(io_base, buf, sz); buf += sz; len -= sz; } sz = len >> 2; if (sz) { u32 *buf32 = (u32 *)buf; readsl(io_base, buf32, sz); buf += sz << 2; len -= sz << 2; } if (len) readsb(io_base, buf, len); } const char *ts_nand_part_probes[] = { "cmdlinepart", NULL }; static struct mtd_partition ts78xx_ts_nand_parts[] = { { .name = "mbr", .offset = 0, .size = SZ_128K, .mask_flags = MTD_WRITEABLE, }, { .name = "kernel", .offset = MTDPART_OFS_APPEND, .size = SZ_4M, }, { .name = "initrd", .offset = MTDPART_OFS_APPEND, .size = SZ_4M, }, { .name = "rootfs", .offset = MTDPART_OFS_APPEND, .size = MTDPART_SIZ_FULL, } }; static struct platform_nand_data ts78xx_ts_nand_data = { .chip = { .nr_chips = 1, .part_probe_types = ts_nand_part_probes, .partitions = ts78xx_ts_nand_parts, .nr_partitions = ARRAY_SIZE(ts78xx_ts_nand_parts), .chip_delay = 15, .options = NAND_USE_FLASH_BBT, }, .ctrl = { /* * The HW ECC offloading functions, used to give about a 9% * performance increase for 'dd if=/dev/mtdblockX' and 5% for * nanddump. This all however was changed by git commit * e6cf5df1838c28bb060ac45b5585e48e71bbc740 so now there is * no performance advantage to be had so we no longer bother */ .cmd_ctrl = ts78xx_ts_nand_cmd_ctrl, .dev_ready = ts78xx_ts_nand_dev_ready, .write_buf = ts78xx_ts_nand_write_buf, .read_buf = ts78xx_ts_nand_read_buf, }, }; static struct resource ts78xx_ts_nand_resources = { .start = TS_NAND_DATA, .end = TS_NAND_DATA + 4, .flags = IORESOURCE_MEM, }; static struct platform_device ts78xx_ts_nand_device = { .name = "gen_nand", .id = -1, .dev = { .platform_data = &ts78xx_ts_nand_data, }, .resource = &ts78xx_ts_nand_resources, .num_resources = 1, }; static int ts78xx_ts_nand_load(void) { int rc; if (ts78xx_fpga.supports.ts_nand.init == 0) { rc = platform_device_register(&ts78xx_ts_nand_device); if (!rc) ts78xx_fpga.supports.ts_nand.init = 1; } else rc = platform_device_add(&ts78xx_ts_nand_device); return rc; }; static void ts78xx_ts_nand_unload(void) { platform_device_del(&ts78xx_ts_nand_device); } /***************************************************************************** * HW RNG ****************************************************************************/ #define TS_RNG_DATA (TS78XX_FPGA_REGS_PHYS_BASE | 0x044) static struct resource ts78xx_ts_rng_resource = { .flags = IORESOURCE_MEM, .start = TS_RNG_DATA, .end = TS_RNG_DATA + 4 - 1, }; static struct timeriomem_rng_data ts78xx_ts_rng_data = { .period = 1000000, /* one second */ }; static struct platform_device ts78xx_ts_rng_device = { .name = "timeriomem_rng", .id = -1, .dev = { .platform_data = &ts78xx_ts_rng_data, }, .resource = &ts78xx_ts_rng_resource, .num_resources = 1, }; static int ts78xx_ts_rng_load(void) { int rc; if (ts78xx_fpga.supports.ts_rng.init == 0) { rc = platform_device_register(&ts78xx_ts_rng_device); if (!rc) ts78xx_fpga.supports.ts_rng.init = 1; } else rc = platform_device_add(&ts78xx_ts_rng_device); return rc; }; static void ts78xx_ts_rng_unload(void) { platform_device_del(&ts78xx_ts_rng_device); } /***************************************************************************** * FPGA 'hotplug' support code ****************************************************************************/ static void ts78xx_fpga_devices_zero_init(void) { ts78xx_fpga.supports.ts_rtc.init = 0; ts78xx_fpga.supports.ts_nand.init = 0; ts78xx_fpga.supports.ts_rng.init = 0; } static void ts78xx_fpga_supports(void) { /* TODO: put this 'table' into ts78xx-fpga.h */ switch (ts78xx_fpga.id) { case TS7800_REV_1: case TS7800_REV_2: case TS7800_REV_3: case TS7800_REV_4: case TS7800_REV_5: case TS7800_REV_6: case TS7800_REV_7: case TS7800_REV_8: case TS7800_REV_9: ts78xx_fpga.supports.ts_rtc.present = 1; ts78xx_fpga.supports.ts_nand.present = 1; ts78xx_fpga.supports.ts_rng.present = 1; break; default: ts78xx_fpga.supports.ts_rtc.present = 0; ts78xx_fpga.supports.ts_nand.present = 0; ts78xx_fpga.supports.ts_rng.present = 0; } } static int ts78xx_fpga_load_devices(void) { int tmp, ret = 0; if (ts78xx_fpga.supports.ts_rtc.present == 1) { tmp = ts78xx_ts_rtc_load(); if (tmp) { printk(KERN_INFO "TS-78xx: RTC not registered\n"); ts78xx_fpga.supports.ts_rtc.present = 0; } ret |= tmp; } if (ts78xx_fpga.supports.ts_nand.present == 1) { tmp = ts78xx_ts_nand_load(); if (tmp) { printk(KERN_INFO "TS-78xx: NAND not registered\n"); ts78xx_fpga.supports.ts_nand.present = 0; } ret |= tmp; } if (ts78xx_fpga.supports.ts_rng.present == 1) { tmp = ts78xx_ts_rng_load(); if (tmp) { printk(KERN_INFO "TS-78xx: RNG not registered\n"); ts78xx_fpga.supports.ts_rng.present = 0; } ret |= tmp; } return ret; } static int ts78xx_fpga_unload_devices(void) { int ret = 0; if (ts78xx_fpga.supports.ts_rtc.present == 1) ts78xx_ts_rtc_unload(); if (ts78xx_fpga.supports.ts_nand.present == 1) ts78xx_ts_nand_unload(); if (ts78xx_fpga.supports.ts_rng.present == 1) ts78xx_ts_rng_unload(); return ret; } static int ts78xx_fpga_load(void) { ts78xx_fpga.id = readl(TS78XX_FPGA_REGS_VIRT_BASE); printk(KERN_INFO "TS-78xx FPGA: magic=0x%.6x, rev=0x%.2x\n", (ts78xx_fpga.id >> 8) & 0xffffff, ts78xx_fpga.id & 0xff); ts78xx_fpga_supports(); if (ts78xx_fpga_load_devices()) { ts78xx_fpga.state = -1; return -EBUSY; } return 0; }; static int ts78xx_fpga_unload(void) { unsigned int fpga_id; fpga_id = readl(TS78XX_FPGA_REGS_VIRT_BASE); /* * There does not seem to be a feasible way to block access to the GPIO * pins from userspace (/dev/mem). This if clause should hopefully warn * those foolish enough not to follow 'policy' :) * * UrJTAG SVN since r1381 can be used to reprogram the FPGA */ if (ts78xx_fpga.id != fpga_id) { printk(KERN_ERR "TS-78xx FPGA: magic/rev mismatch\n" "TS-78xx FPGA: was 0x%.6x/%.2x but now 0x%.6x/%.2x\n", (ts78xx_fpga.id >> 8) & 0xffffff, ts78xx_fpga.id & 0xff, (fpga_id >> 8) & 0xffffff, fpga_id & 0xff); ts78xx_fpga.state = -1; return -EBUSY; } if (ts78xx_fpga_unload_devices()) { ts78xx_fpga.state = -1; return -EBUSY; } return 0; }; static ssize_t ts78xx_fpga_show(struct kobject *kobj, struct kobj_attribute *attr, char *buf) { if (ts78xx_fpga.state < 0) return sprintf(buf, "borked\n"); return sprintf(buf, "%s\n", (ts78xx_fpga.state) ? "online" : "offline"); } static ssize_t ts78xx_fpga_store(struct kobject *kobj, struct kobj_attribute *attr, const char *buf, size_t n) { int value, ret; if (ts78xx_fpga.state < 0) { printk(KERN_ERR "TS-78xx FPGA: borked, you must powercycle asap\n"); return -EBUSY; } if (strncmp(buf, "online", sizeof("online") - 1) == 0) value = 1; else if (strncmp(buf, "offline", sizeof("offline") - 1) == 0) value = 0; else { printk(KERN_ERR "ts78xx_fpga_store: Invalid value\n"); return -EINVAL; } if (ts78xx_fpga.state == value) return n; ret = (ts78xx_fpga.state == 0) ? ts78xx_fpga_load() : ts78xx_fpga_unload(); if (!(ret < 0)) ts78xx_fpga.state = value; return n; } static struct kobj_attribute ts78xx_fpga_attr = __ATTR(ts78xx_fpga, 0644, ts78xx_fpga_show, ts78xx_fpga_store); /***************************************************************************** * General Setup ****************************************************************************/ static struct orion5x_mpp_mode ts78xx_mpp_modes[] __initdata = { { 0, MPP_UNUSED }, { 1, MPP_GPIO }, /* JTAG Clock */ { 2, MPP_GPIO }, /* JTAG Data In */ { 3, MPP_GPIO }, /* Lat ECP2 256 FPGA - PB2B */ { 4, MPP_GPIO }, /* JTAG Data Out */ { 5, MPP_GPIO }, /* JTAG TMS */ { 6, MPP_GPIO }, /* Lat ECP2 256 FPGA - PB31A_CLK4+ */ { 7, MPP_GPIO }, /* Lat ECP2 256 FPGA - PB22B */ { 8, MPP_UNUSED }, { 9, MPP_UNUSED }, { 10, MPP_UNUSED }, { 11, MPP_UNUSED }, { 12, MPP_UNUSED }, { 13, MPP_UNUSED }, { 14, MPP_UNUSED }, { 15, MPP_UNUSED }, { 16, MPP_UART }, { 17, MPP_UART }, { 18, MPP_UART }, { 19, MPP_UART }, /* * MPP[20] PCI Clock Out 1 * MPP[21] PCI Clock Out 0 * MPP[22] Unused * MPP[23] Unused * MPP[24] Unused * MPP[25] Unused */ { -1 }, }; static void __init ts78xx_init(void) { int ret; /* * Setup basic Orion functions. Need to be called early. */ orion5x_init(); orion5x_mpp_conf(ts78xx_mpp_modes); /* * Configure peripherals. */ orion5x_ehci0_init(); orion5x_ehci1_init(); orion5x_eth_init(&ts78xx_eth_data); orion5x_sata_init(&ts78xx_sata_data); orion5x_uart0_init(); orion5x_uart1_init(); orion5x_xor_init(); /* FPGA init */ ts78xx_fpga_devices_zero_init(); ret = ts78xx_fpga_load(); ret = sysfs_create_file(power_kobj, &ts78xx_fpga_attr.attr); if (ret) printk(KERN_ERR "sysfs_create_file failed: %d\n", ret); } MACHINE_START(TS78XX, "Technologic Systems TS-78xx SBC") /* Maintainer: Alexander Clouter */ .boot_params = 0x00000100, .init_machine = ts78xx_init, .map_io = ts78xx_map_io, .init_early = orion5x_init_early, .init_irq = orion5x_init_irq, .timer = &orion5x_timer, MACHINE_END