/* * (C) Copyright 2010 * Dirk Eibach, Guntermann & Drunck GmbH, eibach@gdsys.de * * SPDX-License-Identifier: GPL-2.0+ */ #include #include #include #include #include #include #include "405ep.h" #include #include "../common/osd.h" #include "../common/mclink.h" #include #include #include #include DECLARE_GLOBAL_DATA_PTR; #define LATCH0_BASE (CONFIG_SYS_LATCH_BASE) #define LATCH1_BASE (CONFIG_SYS_LATCH_BASE + 0x100) #define LATCH2_BASE (CONFIG_SYS_LATCH_BASE + 0x200) #define MAX_MUX_CHANNELS 2 enum { UNITTYPE_MAIN_SERVER = 0, UNITTYPE_MAIN_USER = 1, UNITTYPE_VIDEO_SERVER = 2, UNITTYPE_VIDEO_USER = 3, }; enum { HWVER_100 = 0, HWVER_104 = 1, HWVER_110 = 2, HWVER_120 = 3, HWVER_200 = 4, HWVER_210 = 5, HWVER_220 = 6, HWVER_230 = 7, }; enum { FPGA_HWVER_200 = 0, FPGA_HWVER_210 = 1, }; enum { COMPRESSION_NONE = 0, COMPRESSION_TYPE1_DELTA = 1, COMPRESSION_TYPE1_TYPE2_DELTA = 3, }; enum { AUDIO_NONE = 0, AUDIO_TX = 1, AUDIO_RX = 2, AUDIO_RXTX = 3, }; enum { SYSCLK_147456 = 0, }; enum { RAM_DDR2_32 = 0, RAM_DDR3_32 = 1, }; enum { CARRIER_SPEED_1G = 0, CARRIER_SPEED_2_5G = 1, }; enum { MCFPGA_DONE = 1 << 0, MCFPGA_INIT_N = 1 << 1, MCFPGA_PROGRAM_N = 1 << 2, MCFPGA_UPDATE_ENABLE_N = 1 << 3, MCFPGA_RESET_N = 1 << 4, }; enum { GPIO_MDC = 1 << 14, GPIO_MDIO = 1 << 15, }; unsigned int mclink_fpgacount; struct ihs_fpga *fpga_ptr[] = CONFIG_SYS_FPGA_PTR; static int setup_88e1518(const char *bus, unsigned char addr); int fpga_set_reg(u32 fpga, u16 *reg, off_t regoff, u16 data) { int res; switch (fpga) { case 0: out_le16(reg, data); break; default: res = mclink_send(fpga - 1, regoff, data); if (res < 0) { printf("mclink_send reg %02lx data %04x returned %d\n", regoff, data, res); return res; } break; } return 0; } int fpga_get_reg(u32 fpga, u16 *reg, off_t regoff, u16 *data) { int res; switch (fpga) { case 0: *data = in_le16(reg); break; default: if (fpga > mclink_fpgacount) return -EINVAL; res = mclink_receive(fpga - 1, regoff, data); if (res < 0) { printf("mclink_receive reg %02lx returned %d\n", regoff, res); return res; } } return 0; } /* * Check Board Identity: */ int checkboard(void) { char *s = getenv("serial#"); puts("Board: "); puts("IoCon"); if (s != NULL) { puts(", serial# "); puts(s); } puts("\n"); return 0; } static void print_fpga_info(unsigned int fpga, bool rgmii2_present) { u16 versions; u16 fpga_version; u16 fpga_features; unsigned unit_type; unsigned hardware_version; unsigned feature_compression; unsigned feature_osd; unsigned feature_audio; unsigned feature_sysclock; unsigned feature_ramconfig; unsigned feature_carrier_speed; unsigned feature_carriers; unsigned feature_video_channels; int legacy = get_fpga_state(0) & FPGA_STATE_PLATFORM; FPGA_GET_REG(0, versions, &versions); FPGA_GET_REG(0, fpga_version, &fpga_version); FPGA_GET_REG(0, fpga_features, &fpga_features); unit_type = (versions & 0xf000) >> 12; feature_compression = (fpga_features & 0xe000) >> 13; feature_osd = fpga_features & (1<<11); feature_audio = (fpga_features & 0x0600) >> 9; feature_sysclock = (fpga_features & 0x0180) >> 7; feature_ramconfig = (fpga_features & 0x0060) >> 5; feature_carrier_speed = fpga_features & (1<<4); feature_carriers = (fpga_features & 0x000c) >> 2; feature_video_channels = fpga_features & 0x0003; if (legacy) printf("legacy "); switch (unit_type) { case UNITTYPE_MAIN_USER: printf("Mainchannel"); break; case UNITTYPE_VIDEO_USER: printf("Videochannel"); break; default: printf("UnitType %d(not supported)", unit_type); break; } if (unit_type == UNITTYPE_MAIN_USER) { if (legacy) hardware_version = (in_le16((void *)LATCH2_BASE)>>8) & 0x0f; else hardware_version = (!!pca9698_get_value(0x20, 24) << 0) | (!!pca9698_get_value(0x20, 25) << 1) | (!!pca9698_get_value(0x20, 26) << 2) | (!!pca9698_get_value(0x20, 27) << 3); switch (hardware_version) { case HWVER_100: printf(" HW-Ver 1.00,"); break; case HWVER_104: printf(" HW-Ver 1.04,"); break; case HWVER_110: printf(" HW-Ver 1.10,"); break; case HWVER_120: printf(" HW-Ver 1.20-1.21,"); break; case HWVER_200: printf(" HW-Ver 2.00,"); break; case HWVER_210: printf(" HW-Ver 2.10,"); break; case HWVER_220: printf(" HW-Ver 2.20,"); break; case HWVER_230: printf(" HW-Ver 2.30,"); break; default: printf(" HW-Ver %d(not supported),", hardware_version); break; } if (rgmii2_present) printf(" RGMII2,"); } if (unit_type == UNITTYPE_VIDEO_USER) { hardware_version = versions & 0x000f; switch (hardware_version) { case FPGA_HWVER_200: printf(" HW-Ver 2.00,"); break; case FPGA_HWVER_210: printf(" HW-Ver 2.10,"); break; default: printf(" HW-Ver %d(not supported),", hardware_version); break; } } printf(" FPGA V %d.%02d\n features:", fpga_version / 100, fpga_version % 100); switch (feature_compression) { case COMPRESSION_NONE: printf(" no compression"); break; case COMPRESSION_TYPE1_DELTA: printf(" type1-deltacompression"); break; case COMPRESSION_TYPE1_TYPE2_DELTA: printf(" type1-deltacompression, type2-inlinecompression"); break; default: printf(" compression %d(not supported)", feature_compression); break; } printf(", %sosd", feature_osd ? "" : "no "); switch (feature_audio) { case AUDIO_NONE: printf(", no audio"); break; case AUDIO_TX: printf(", audio tx"); break; case AUDIO_RX: printf(", audio rx"); break; case AUDIO_RXTX: printf(", audio rx+tx"); break; default: printf(", audio %d(not supported)", feature_audio); break; } puts(",\n "); switch (feature_sysclock) { case SYSCLK_147456: printf("clock 147.456 MHz"); break; default: printf("clock %d(not supported)", feature_sysclock); break; } switch (feature_ramconfig) { case RAM_DDR2_32: printf(", RAM 32 bit DDR2"); break; case RAM_DDR3_32: printf(", RAM 32 bit DDR3"); break; default: printf(", RAM %d(not supported)", feature_ramconfig); break; } printf(", %d carrier(s) %s", feature_carriers, feature_carrier_speed ? "2.5Gbit/s" : "1Gbit/s"); printf(", %d video channel(s)\n", feature_video_channels); } int last_stage_init(void) { int slaves; unsigned int k; unsigned int mux_ch; unsigned char mclink_controllers[] = { 0x24, 0x25, 0x26 }; int legacy = get_fpga_state(0) & FPGA_STATE_PLATFORM; u16 fpga_features; int feature_carrier_speed = fpga_features & (1<<4); bool ch0_rgmii2_present = false; FPGA_GET_REG(0, fpga_features, &fpga_features); if (!legacy) { /* Turn on Parade DP501 */ pca9698_direction_output(0x20, 9, 1); ch0_rgmii2_present = !pca9698_get_value(0x20, 30); } /* wait for FPGA done */ for (k = 0; k < ARRAY_SIZE(mclink_controllers); ++k) { unsigned int ctr = 0; if (i2c_probe(mclink_controllers[k])) continue; while (!(pca953x_get_val(mclink_controllers[k]) & MCFPGA_DONE)) { udelay(100000); if (ctr++ > 5) { printf("no done for mclink_controller %d\n", k); break; } } } if (!legacy && (feature_carrier_speed == CARRIER_SPEED_1G)) { miiphy_register(bb_miiphy_buses[0].name, bb_miiphy_read, bb_miiphy_write); for (mux_ch = 0; mux_ch < MAX_MUX_CHANNELS; ++mux_ch) { if ((mux_ch == 1) && !ch0_rgmii2_present) continue; setup_88e1518(bb_miiphy_buses[0].name, mux_ch); } } /* give slave-PLLs and Parade DP501 some time to be up and running */ udelay(500000); mclink_fpgacount = CONFIG_SYS_MCLINK_MAX; slaves = mclink_probe(); mclink_fpgacount = 0; print_fpga_info(0, ch0_rgmii2_present); osd_probe(0); if (slaves <= 0) return 0; mclink_fpgacount = slaves; for (k = 1; k <= slaves; ++k) { FPGA_GET_REG(k, fpga_features, &fpga_features); feature_carrier_speed = fpga_features & (1<<4); print_fpga_info(k, false); osd_probe(k); if (feature_carrier_speed == CARRIER_SPEED_1G) { miiphy_register(bb_miiphy_buses[k].name, bb_miiphy_read, bb_miiphy_write); setup_88e1518(bb_miiphy_buses[k].name, 0); } } return 0; } /* * provide access to fpga gpios (for I2C bitbang) * (these may look all too simple but make iocon.h much more readable) */ void fpga_gpio_set(unsigned int bus, int pin) { FPGA_SET_REG(bus, gpio.set, pin); } void fpga_gpio_clear(unsigned int bus, int pin) { FPGA_SET_REG(bus, gpio.clear, pin); } int fpga_gpio_get(unsigned int bus, int pin) { u16 val; FPGA_GET_REG(bus, gpio.read, &val); return val & pin; } void gd405ep_init(void) { unsigned int k; if (i2c_probe(0x20)) { /* i2c_probe returns 0 on success */ for (k = 0; k < CONFIG_SYS_FPGA_COUNT; ++k) gd->arch.fpga_state[k] |= FPGA_STATE_PLATFORM; } else { pca9698_direction_output(0x20, 4, 1); } } void gd405ep_set_fpga_reset(unsigned state) { int legacy = get_fpga_state(0) & FPGA_STATE_PLATFORM; if (legacy) { if (state) { out_le16((void *)LATCH0_BASE, CONFIG_SYS_LATCH0_RESET); out_le16((void *)LATCH1_BASE, CONFIG_SYS_LATCH1_RESET); } else { out_le16((void *)LATCH0_BASE, CONFIG_SYS_LATCH0_BOOT); out_le16((void *)LATCH1_BASE, CONFIG_SYS_LATCH1_BOOT); } } else { pca9698_set_value(0x20, 4, state ? 0 : 1); } } void gd405ep_setup_hw(void) { /* * set "startup-finished"-gpios */ gpio_write_bit(21, 0); gpio_write_bit(22, 1); } int gd405ep_get_fpga_done(unsigned fpga) { int legacy = get_fpga_state(0) & FPGA_STATE_PLATFORM; if (legacy) return in_le16((void *)LATCH2_BASE) & CONFIG_SYS_FPGA_DONE(fpga); else return pca9698_get_value(0x20, 20); } /* * FPGA MII bitbang implementation */ struct fpga_mii { unsigned fpga; int mdio; } fpga_mii[] = { { 0, 1}, { 1, 1}, { 2, 1}, { 3, 1}, }; static int mii_dummy_init(struct bb_miiphy_bus *bus) { return 0; } static int mii_mdio_active(struct bb_miiphy_bus *bus) { struct fpga_mii *fpga_mii = bus->priv; if (fpga_mii->mdio) FPGA_SET_REG(fpga_mii->fpga, gpio.set, GPIO_MDIO); else FPGA_SET_REG(fpga_mii->fpga, gpio.clear, GPIO_MDIO); return 0; } static int mii_mdio_tristate(struct bb_miiphy_bus *bus) { struct fpga_mii *fpga_mii = bus->priv; FPGA_SET_REG(fpga_mii->fpga, gpio.set, GPIO_MDIO); return 0; } static int mii_set_mdio(struct bb_miiphy_bus *bus, int v) { struct fpga_mii *fpga_mii = bus->priv; if (v) FPGA_SET_REG(fpga_mii->fpga, gpio.set, GPIO_MDIO); else FPGA_SET_REG(fpga_mii->fpga, gpio.clear, GPIO_MDIO); fpga_mii->mdio = v; return 0; } static int mii_get_mdio(struct bb_miiphy_bus *bus, int *v) { u16 gpio; struct fpga_mii *fpga_mii = bus->priv; FPGA_GET_REG(fpga_mii->fpga, gpio.read, &gpio); *v = ((gpio & GPIO_MDIO) != 0); return 0; } static int mii_set_mdc(struct bb_miiphy_bus *bus, int v) { struct fpga_mii *fpga_mii = bus->priv; if (v) FPGA_SET_REG(fpga_mii->fpga, gpio.set, GPIO_MDC); else FPGA_SET_REG(fpga_mii->fpga, gpio.clear, GPIO_MDC); return 0; } static int mii_delay(struct bb_miiphy_bus *bus) { udelay(1); return 0; } struct bb_miiphy_bus bb_miiphy_buses[] = { { .name = "board0", .init = mii_dummy_init, .mdio_active = mii_mdio_active, .mdio_tristate = mii_mdio_tristate, .set_mdio = mii_set_mdio, .get_mdio = mii_get_mdio, .set_mdc = mii_set_mdc, .delay = mii_delay, .priv = &fpga_mii[0], }, { .name = "board1", .init = mii_dummy_init, .mdio_active = mii_mdio_active, .mdio_tristate = mii_mdio_tristate, .set_mdio = mii_set_mdio, .get_mdio = mii_get_mdio, .set_mdc = mii_set_mdc, .delay = mii_delay, .priv = &fpga_mii[1], }, { .name = "board2", .init = mii_dummy_init, .mdio_active = mii_mdio_active, .mdio_tristate = mii_mdio_tristate, .set_mdio = mii_set_mdio, .get_mdio = mii_get_mdio, .set_mdc = mii_set_mdc, .delay = mii_delay, .priv = &fpga_mii[2], }, { .name = "board3", .init = mii_dummy_init, .mdio_active = mii_mdio_active, .mdio_tristate = mii_mdio_tristate, .set_mdio = mii_set_mdio, .get_mdio = mii_get_mdio, .set_mdc = mii_set_mdc, .delay = mii_delay, .priv = &fpga_mii[3], }, }; int bb_miiphy_buses_num = sizeof(bb_miiphy_buses) / sizeof(bb_miiphy_buses[0]); enum { MIICMD_SET, MIICMD_MODIFY, MIICMD_VERIFY_VALUE, MIICMD_WAIT_FOR_VALUE, }; struct mii_setupcmd { u8 token; u8 reg; u16 data; u16 mask; u32 timeout; }; /* * verify we are talking to a 88e1518 */ struct mii_setupcmd verify_88e1518[] = { { MIICMD_SET, 22, 0x0000 }, { MIICMD_VERIFY_VALUE, 2, 0x0141, 0xffff }, { MIICMD_VERIFY_VALUE, 3, 0x0dd0, 0xfff0 }, }; /* * workaround for erratum mentioned in 88E1518 release notes */ struct mii_setupcmd fixup_88e1518[] = { { MIICMD_SET, 22, 0x00ff }, { MIICMD_SET, 17, 0x214b }, { MIICMD_SET, 16, 0x2144 }, { MIICMD_SET, 17, 0x0c28 }, { MIICMD_SET, 16, 0x2146 }, { MIICMD_SET, 17, 0xb233 }, { MIICMD_SET, 16, 0x214d }, { MIICMD_SET, 17, 0xcc0c }, { MIICMD_SET, 16, 0x2159 }, { MIICMD_SET, 22, 0x00fb }, { MIICMD_SET, 7, 0xc00d }, { MIICMD_SET, 22, 0x0000 }, }; /* * default initialization: * - set RGMII receive timing to "receive clock transition when data stable" * - set RGMII transmit timing to "transmit clock internally delayed" * - set RGMII output impedance target to 78,8 Ohm * - run output impedance calibration * - set autonegotiation advertise to 1000FD only */ struct mii_setupcmd default_88e1518[] = { { MIICMD_SET, 22, 0x0002 }, { MIICMD_MODIFY, 21, 0x0030, 0x0030 }, { MIICMD_MODIFY, 25, 0x0000, 0x0003 }, { MIICMD_MODIFY, 24, 0x8000, 0x8000 }, { MIICMD_WAIT_FOR_VALUE, 24, 0x4000, 0x4000, 2000 }, { MIICMD_SET, 22, 0x0000 }, { MIICMD_MODIFY, 4, 0x0000, 0x01e0 }, { MIICMD_MODIFY, 9, 0x0200, 0x0300 }, }; /* * turn off CLK125 for PHY daughterboard */ struct mii_setupcmd ch1fix_88e1518[] = { { MIICMD_SET, 22, 0x0002 }, { MIICMD_MODIFY, 16, 0x0006, 0x0006 }, { MIICMD_SET, 22, 0x0000 }, }; /* * perform copper software reset */ struct mii_setupcmd swreset_88e1518[] = { { MIICMD_SET, 22, 0x0000 }, { MIICMD_MODIFY, 0, 0x8000, 0x8000 }, { MIICMD_WAIT_FOR_VALUE, 0, 0x0000, 0x8000, 2000 }, }; static int process_setupcmd(const char *bus, unsigned char addr, struct mii_setupcmd *setupcmd) { int res; u8 reg = setupcmd->reg; u16 data = setupcmd->data; u16 mask = setupcmd->mask; u32 timeout = setupcmd->timeout; u16 orig_data; unsigned long start; debug("mii %s:%u reg %2u ", bus, addr, reg); switch (setupcmd->token) { case MIICMD_MODIFY: res = miiphy_read(bus, addr, reg, &orig_data); if (res) break; debug("is %04x. (value %04x mask %04x) ", orig_data, data, mask); data = (orig_data & ~mask) | (data & mask); case MIICMD_SET: debug("=> %04x\n", data); res = miiphy_write(bus, addr, reg, data); break; case MIICMD_VERIFY_VALUE: res = miiphy_read(bus, addr, reg, &orig_data); if (res) break; if ((orig_data & mask) != (data & mask)) res = -1; debug("(value %04x mask %04x) == %04x? %s\n", data, mask, orig_data, res ? "FAIL" : "PASS"); break; case MIICMD_WAIT_FOR_VALUE: res = -1; start = get_timer(0); while ((res != 0) && (get_timer(start) < timeout)) { res = miiphy_read(bus, addr, reg, &orig_data); if (res) continue; if ((orig_data & mask) != (data & mask)) res = -1; } debug("(value %04x mask %04x) == %04x? %s after %lu ms\n", data, mask, orig_data, res ? "FAIL" : "PASS", get_timer(start)); break; default: res = -1; break; } return res; } static int process_setup(const char *bus, unsigned char addr, struct mii_setupcmd *setupcmd, unsigned int count) { int res = 0; unsigned int k; for (k = 0; k < count; ++k) { res = process_setupcmd(bus, addr, &setupcmd[k]); if (res) { printf("mii cmd %u on bus %s addr %u failed, aborting setup", setupcmd[k].token, bus, addr); break; } } return res; } static int setup_88e1518(const char *bus, unsigned char addr) { int res; res = process_setup(bus, addr, verify_88e1518, ARRAY_SIZE(verify_88e1518)); if (res) return res; res = process_setup(bus, addr, fixup_88e1518, ARRAY_SIZE(fixup_88e1518)); if (res) return res; res = process_setup(bus, addr, default_88e1518, ARRAY_SIZE(default_88e1518)); if (res) return res; if (addr) { res = process_setup(bus, addr, ch1fix_88e1518, ARRAY_SIZE(ch1fix_88e1518)); if (res) return res; } res = process_setup(bus, addr, swreset_88e1518, ARRAY_SIZE(swreset_88e1518)); if (res) return res; return 0; }