/* * TI DaVinci DM365 EVM board support * * Copyright (C) 2009 Texas Instruments Incorporated * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation version 2. * * This program is distributed "as is" WITHOUT ANY WARRANTY of any * kind, whether express or implied; without even the implied warranty * of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #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 static inline int have_imager(void) { /* REVISIT when it's supported, trigger via Kconfig */ return 0; } static inline int have_tvp7002(void) { /* REVISIT when it's supported, trigger via Kconfig */ return 0; } #define DM365_ASYNC_EMIF_CONTROL_BASE 0x01d10000 #define DM365_ASYNC_EMIF_DATA_CE0_BASE 0x02000000 #define DM365_ASYNC_EMIF_DATA_CE1_BASE 0x04000000 #define DM365_EVM_PHY_MASK (0x2) #define DM365_EVM_MDIO_FREQUENCY (2200000) /* PHY bus frequency */ /* * A MAX-II CPLD is used for various board control functions. */ #define CPLD_OFFSET(a13a8,a2a1) (((a13a8) << 10) + ((a2a1) << 3)) #define CPLD_VERSION CPLD_OFFSET(0,0) /* r/o */ #define CPLD_TEST CPLD_OFFSET(0,1) #define CPLD_LEDS CPLD_OFFSET(0,2) #define CPLD_MUX CPLD_OFFSET(0,3) #define CPLD_SWITCH CPLD_OFFSET(1,0) /* r/o */ #define CPLD_POWER CPLD_OFFSET(1,1) #define CPLD_VIDEO CPLD_OFFSET(1,2) #define CPLD_CARDSTAT CPLD_OFFSET(1,3) /* r/o */ #define CPLD_DILC_OUT CPLD_OFFSET(2,0) #define CPLD_DILC_IN CPLD_OFFSET(2,1) /* r/o */ #define CPLD_IMG_DIR0 CPLD_OFFSET(2,2) #define CPLD_IMG_MUX0 CPLD_OFFSET(2,3) #define CPLD_IMG_MUX1 CPLD_OFFSET(3,0) #define CPLD_IMG_DIR1 CPLD_OFFSET(3,1) #define CPLD_IMG_MUX2 CPLD_OFFSET(3,2) #define CPLD_IMG_MUX3 CPLD_OFFSET(3,3) #define CPLD_IMG_DIR2 CPLD_OFFSET(4,0) #define CPLD_IMG_MUX4 CPLD_OFFSET(4,1) #define CPLD_IMG_MUX5 CPLD_OFFSET(4,2) #define CPLD_RESETS CPLD_OFFSET(4,3) #define CPLD_CCD_DIR1 CPLD_OFFSET(0x3e,0) #define CPLD_CCD_IO1 CPLD_OFFSET(0x3e,1) #define CPLD_CCD_DIR2 CPLD_OFFSET(0x3e,2) #define CPLD_CCD_IO2 CPLD_OFFSET(0x3e,3) #define CPLD_CCD_DIR3 CPLD_OFFSET(0x3f,0) #define CPLD_CCD_IO3 CPLD_OFFSET(0x3f,1) static void __iomem *cpld; /* NOTE: this is geared for the standard config, with a socketed * 2 GByte Micron NAND (MT29F16G08FAA) using 128KB sectors. If you * swap chips with a different block size, partitioning will * need to be changed. This NAND chip MT29F16G08FAA is the default * NAND shipped with the Spectrum Digital DM365 EVM */ #define NAND_BLOCK_SIZE SZ_128K static struct mtd_partition davinci_nand_partitions[] = { { /* UBL (a few copies) plus U-Boot */ .name = "bootloader", .offset = 0, .size = 28 * NAND_BLOCK_SIZE, .mask_flags = MTD_WRITEABLE, /* force read-only */ }, { /* U-Boot environment */ .name = "params", .offset = MTDPART_OFS_APPEND, .size = 2 * NAND_BLOCK_SIZE, .mask_flags = 0, }, { .name = "kernel", .offset = MTDPART_OFS_APPEND, .size = SZ_4M, .mask_flags = 0, }, { .name = "filesystem1", .offset = MTDPART_OFS_APPEND, .size = SZ_512M, .mask_flags = 0, }, { .name = "filesystem2", .offset = MTDPART_OFS_APPEND, .size = MTDPART_SIZ_FULL, .mask_flags = 0, } /* two blocks with bad block table (and mirror) at the end */ }; static struct davinci_nand_pdata davinci_nand_data = { .mask_chipsel = BIT(14), .parts = davinci_nand_partitions, .nr_parts = ARRAY_SIZE(davinci_nand_partitions), .ecc_mode = NAND_ECC_HW, .options = NAND_USE_FLASH_BBT, .ecc_bits = 4, }; static struct resource davinci_nand_resources[] = { { .start = DM365_ASYNC_EMIF_DATA_CE0_BASE, .end = DM365_ASYNC_EMIF_DATA_CE0_BASE + SZ_32M - 1, .flags = IORESOURCE_MEM, }, { .start = DM365_ASYNC_EMIF_CONTROL_BASE, .end = DM365_ASYNC_EMIF_CONTROL_BASE + SZ_4K - 1, .flags = IORESOURCE_MEM, }, }; static struct platform_device davinci_nand_device = { .name = "davinci_nand", .id = 0, .num_resources = ARRAY_SIZE(davinci_nand_resources), .resource = davinci_nand_resources, .dev = { .platform_data = &davinci_nand_data, }, }; static struct at24_platform_data eeprom_info = { .byte_len = (256*1024) / 8, .page_size = 64, .flags = AT24_FLAG_ADDR16, .setup = davinci_get_mac_addr, .context = (void *)0x7f00, }; static struct snd_platform_data dm365_evm_snd_data; static struct i2c_board_info i2c_info[] = { { I2C_BOARD_INFO("24c256", 0x50), .platform_data = &eeprom_info, }, { I2C_BOARD_INFO("tlv320aic3x", 0x18), }, }; static struct davinci_i2c_platform_data i2c_pdata = { .bus_freq = 400 /* kHz */, .bus_delay = 0 /* usec */, }; static int dm365evm_keyscan_enable(struct device *dev) { return davinci_cfg_reg(DM365_KEYSCAN); } static unsigned short dm365evm_keymap[] = { KEY_KP2, KEY_LEFT, KEY_EXIT, KEY_DOWN, KEY_ENTER, KEY_UP, KEY_KP1, KEY_RIGHT, KEY_MENU, KEY_RECORD, KEY_REWIND, KEY_KPMINUS, KEY_STOP, KEY_FASTFORWARD, KEY_KPPLUS, KEY_PLAYPAUSE, 0 }; static struct davinci_ks_platform_data dm365evm_ks_data = { .device_enable = dm365evm_keyscan_enable, .keymap = dm365evm_keymap, .keymapsize = ARRAY_SIZE(dm365evm_keymap), .rep = 1, /* Scan period = strobe + interval */ .strobe = 0x5, .interval = 0x2, .matrix_type = DAVINCI_KEYSCAN_MATRIX_4X4, }; static int cpld_mmc_get_cd(int module) { if (!cpld) return -ENXIO; /* low == card present */ return !(__raw_readb(cpld + CPLD_CARDSTAT) & BIT(module ? 4 : 0)); } static int cpld_mmc_get_ro(int module) { if (!cpld) return -ENXIO; /* high == card's write protect switch active */ return !!(__raw_readb(cpld + CPLD_CARDSTAT) & BIT(module ? 5 : 1)); } static struct davinci_mmc_config dm365evm_mmc_config = { .get_cd = cpld_mmc_get_cd, .get_ro = cpld_mmc_get_ro, .wires = 4, .max_freq = 50000000, .caps = MMC_CAP_MMC_HIGHSPEED | MMC_CAP_SD_HIGHSPEED, .version = MMC_CTLR_VERSION_2, }; static void dm365evm_emac_configure(void) { /* * EMAC pins are multiplexed with GPIO and UART * Further details are available at the DM365 ARM * Subsystem Users Guide(sprufg5.pdf) pages 125 - 127 */ davinci_cfg_reg(DM365_EMAC_TX_EN); davinci_cfg_reg(DM365_EMAC_TX_CLK); davinci_cfg_reg(DM365_EMAC_COL); davinci_cfg_reg(DM365_EMAC_TXD3); davinci_cfg_reg(DM365_EMAC_TXD2); davinci_cfg_reg(DM365_EMAC_TXD1); davinci_cfg_reg(DM365_EMAC_TXD0); davinci_cfg_reg(DM365_EMAC_RXD3); davinci_cfg_reg(DM365_EMAC_RXD2); davinci_cfg_reg(DM365_EMAC_RXD1); davinci_cfg_reg(DM365_EMAC_RXD0); davinci_cfg_reg(DM365_EMAC_RX_CLK); davinci_cfg_reg(DM365_EMAC_RX_DV); davinci_cfg_reg(DM365_EMAC_RX_ER); davinci_cfg_reg(DM365_EMAC_CRS); davinci_cfg_reg(DM365_EMAC_MDIO); davinci_cfg_reg(DM365_EMAC_MDCLK); /* * EMAC interrupts are multiplexed with GPIO interrupts * Details are available at the DM365 ARM * Subsystem Users Guide(sprufg5.pdf) pages 133 - 134 */ davinci_cfg_reg(DM365_INT_EMAC_RXTHRESH); davinci_cfg_reg(DM365_INT_EMAC_RXPULSE); davinci_cfg_reg(DM365_INT_EMAC_TXPULSE); davinci_cfg_reg(DM365_INT_EMAC_MISCPULSE); } static void dm365evm_mmc_configure(void) { /* * MMC/SD pins are multiplexed with GPIO and EMIF * Further details are available at the DM365 ARM * Subsystem Users Guide(sprufg5.pdf) pages 118, 128 - 131 */ davinci_cfg_reg(DM365_SD1_CLK); davinci_cfg_reg(DM365_SD1_CMD); davinci_cfg_reg(DM365_SD1_DATA3); davinci_cfg_reg(DM365_SD1_DATA2); davinci_cfg_reg(DM365_SD1_DATA1); davinci_cfg_reg(DM365_SD1_DATA0); } static struct tvp514x_platform_data tvp5146_pdata = { .clk_polarity = 0, .hs_polarity = 1, .vs_polarity = 1 }; #define TVP514X_STD_ALL (V4L2_STD_NTSC | V4L2_STD_PAL) /* Inputs available at the TVP5146 */ static struct v4l2_input tvp5146_inputs[] = { { .index = 0, .name = "Composite", .type = V4L2_INPUT_TYPE_CAMERA, .std = TVP514X_STD_ALL, }, { .index = 1, .name = "S-Video", .type = V4L2_INPUT_TYPE_CAMERA, .std = TVP514X_STD_ALL, }, }; /* * this is the route info for connecting each input to decoder * ouput that goes to vpfe. There is a one to one correspondence * with tvp5146_inputs */ static struct vpfe_route tvp5146_routes[] = { { .input = INPUT_CVBS_VI2B, .output = OUTPUT_10BIT_422_EMBEDDED_SYNC, }, { .input = INPUT_SVIDEO_VI2C_VI1C, .output = OUTPUT_10BIT_422_EMBEDDED_SYNC, }, }; static struct vpfe_subdev_info vpfe_sub_devs[] = { { .name = "tvp5146", .grp_id = 0, .num_inputs = ARRAY_SIZE(tvp5146_inputs), .inputs = tvp5146_inputs, .routes = tvp5146_routes, .can_route = 1, .ccdc_if_params = { .if_type = VPFE_BT656, .hdpol = VPFE_PINPOL_POSITIVE, .vdpol = VPFE_PINPOL_POSITIVE, }, .board_info = { I2C_BOARD_INFO("tvp5146", 0x5d), .platform_data = &tvp5146_pdata, }, }, }; static struct vpfe_config vpfe_cfg = { .num_subdevs = ARRAY_SIZE(vpfe_sub_devs), .sub_devs = vpfe_sub_devs, .i2c_adapter_id = 1, .card_name = "DM365 EVM", .ccdc = "ISIF", }; static void __init evm_init_i2c(void) { davinci_init_i2c(&i2c_pdata); i2c_register_board_info(1, i2c_info, ARRAY_SIZE(i2c_info)); } static struct platform_device *dm365_evm_nand_devices[] __initdata = { &davinci_nand_device, }; static inline int have_leds(void) { #ifdef CONFIG_LEDS_CLASS return 1; #else return 0; #endif } struct cpld_led { struct led_classdev cdev; u8 mask; }; static const struct { const char *name; const char *trigger; } cpld_leds[] = { { "dm365evm::ds2", }, { "dm365evm::ds3", }, { "dm365evm::ds4", }, { "dm365evm::ds5", }, { "dm365evm::ds6", "nand-disk", }, { "dm365evm::ds7", "mmc1", }, { "dm365evm::ds8", "mmc0", }, { "dm365evm::ds9", "heartbeat", }, }; static void cpld_led_set(struct led_classdev *cdev, enum led_brightness b) { struct cpld_led *led = container_of(cdev, struct cpld_led, cdev); u8 reg = __raw_readb(cpld + CPLD_LEDS); if (b != LED_OFF) reg &= ~led->mask; else reg |= led->mask; __raw_writeb(reg, cpld + CPLD_LEDS); } static enum led_brightness cpld_led_get(struct led_classdev *cdev) { struct cpld_led *led = container_of(cdev, struct cpld_led, cdev); u8 reg = __raw_readb(cpld + CPLD_LEDS); return (reg & led->mask) ? LED_OFF : LED_FULL; } static int __init cpld_leds_init(void) { int i; if (!have_leds() || !cpld) return 0; /* setup LEDs */ __raw_writeb(0xff, cpld + CPLD_LEDS); for (i = 0; i < ARRAY_SIZE(cpld_leds); i++) { struct cpld_led *led; led = kzalloc(sizeof(*led), GFP_KERNEL); if (!led) break; led->cdev.name = cpld_leds[i].name; led->cdev.brightness_set = cpld_led_set; led->cdev.brightness_get = cpld_led_get; led->cdev.default_trigger = cpld_leds[i].trigger; led->mask = BIT(i); if (led_classdev_register(NULL, &led->cdev) < 0) { kfree(led); break; } } return 0; } /* run after subsys_initcall() for LEDs */ fs_initcall(cpld_leds_init); static void __init evm_init_cpld(void) { u8 mux, resets; const char *label; struct clk *aemif_clk; /* Make sure we can configure the CPLD through CS1. Then * leave it on for later access to MMC and LED registers. */ aemif_clk = clk_get(NULL, "aemif"); if (IS_ERR(aemif_clk)) return; clk_enable(aemif_clk); if (request_mem_region(DM365_ASYNC_EMIF_DATA_CE1_BASE, SECTION_SIZE, "cpld") == NULL) goto fail; cpld = ioremap(DM365_ASYNC_EMIF_DATA_CE1_BASE, SECTION_SIZE); if (!cpld) { release_mem_region(DM365_ASYNC_EMIF_DATA_CE1_BASE, SECTION_SIZE); fail: pr_err("ERROR: can't map CPLD\n"); clk_disable(aemif_clk); return; } /* External muxing for some signals */ mux = 0; /* Read SW5 to set up NAND + keypad _or_ OneNAND (sync read). * NOTE: SW4 bus width setting must match! */ if ((__raw_readb(cpld + CPLD_SWITCH) & BIT(5)) == 0) { /* external keypad mux */ mux |= BIT(7); platform_add_devices(dm365_evm_nand_devices, ARRAY_SIZE(dm365_evm_nand_devices)); } else { /* no OneNAND support yet */ } /* Leave external chips in reset when unused. */ resets = BIT(3) | BIT(2) | BIT(1) | BIT(0); /* Static video input config with SN74CBT16214 1-of-3 mux: * - port b1 == tvp7002 (mux lowbits == 1 or 6) * - port b2 == imager (mux lowbits == 2 or 7) * - port b3 == tvp5146 (mux lowbits == 5) * * Runtime switching could work too, with limitations. */ if (have_imager()) { label = "HD imager"; mux |= 1; /* externally mux MMC1/ENET/AIC33 to imager */ mux |= BIT(6) | BIT(5) | BIT(3); } else { struct davinci_soc_info *soc_info = &davinci_soc_info; /* we can use MMC1 ... */ dm365evm_mmc_configure(); davinci_setup_mmc(1, &dm365evm_mmc_config); /* ... and ENET ... */ dm365evm_emac_configure(); soc_info->emac_pdata->phy_mask = DM365_EVM_PHY_MASK; soc_info->emac_pdata->mdio_max_freq = DM365_EVM_MDIO_FREQUENCY; resets &= ~BIT(3); /* ... and AIC33 */ resets &= ~BIT(1); if (have_tvp7002()) { mux |= 2; resets &= ~BIT(2); label = "tvp7002 HD"; } else { /* default to tvp5146 */ mux |= 5; resets &= ~BIT(0); label = "tvp5146 SD"; } } __raw_writeb(mux, cpld + CPLD_MUX); __raw_writeb(resets, cpld + CPLD_RESETS); pr_info("EVM: %s video input\n", label); /* REVISIT export switches: NTSC/PAL (SW5.6), EXTRA1 (SW5.2), etc */ } static struct davinci_uart_config uart_config __initdata = { .enabled_uarts = (1 << 0), }; static void __init dm365_evm_map_io(void) { /* setup input configuration for VPFE input devices */ dm365_set_vpfe_config(&vpfe_cfg); dm365_init(); } static struct spi_eeprom at25640 = { .byte_len = SZ_64K / 8, .name = "at25640", .page_size = 32, .flags = EE_ADDR2, }; static struct spi_board_info dm365_evm_spi_info[] __initconst = { { .modalias = "at25", .platform_data = &at25640, .max_speed_hz = 10 * 1000 * 1000, .bus_num = 0, .chip_select = 0, .mode = SPI_MODE_0, }, }; static __init void dm365_evm_init(void) { evm_init_i2c(); davinci_serial_init(&uart_config); dm365evm_emac_configure(); dm365evm_mmc_configure(); davinci_setup_mmc(0, &dm365evm_mmc_config); /* maybe setup mmc1/etc ... _after_ mmc0 */ evm_init_cpld(); #ifdef CONFIG_SND_DM365_AIC3X_CODEC dm365_init_asp(&dm365_evm_snd_data); #elif defined(CONFIG_SND_DM365_VOICE_CODEC) dm365_init_vc(&dm365_evm_snd_data); #endif dm365_init_rtc(); dm365_init_ks(&dm365evm_ks_data); dm365_init_spi0(BIT(0), dm365_evm_spi_info, ARRAY_SIZE(dm365_evm_spi_info)); } static __init void dm365_evm_irq_init(void) { davinci_irq_init(); } MACHINE_START(DAVINCI_DM365_EVM, "DaVinci DM365 EVM") .phys_io = IO_PHYS, .io_pg_offst = (__IO_ADDRESS(IO_PHYS) >> 18) & 0xfffc, .boot_params = (0x80000100), .map_io = dm365_evm_map_io, .init_irq = dm365_evm_irq_init, .timer = &davinci_timer, .init_machine = dm365_evm_init, MACHINE_END