/* * linux/arch/arm/mach-pxa/viper.c * * Support for the Arcom VIPER SBC. * * Author: Ian Campbell * Created: Feb 03, 2003 * Copyright: Arcom Control Systems * * Maintained by Marc Zyngier * * * Based on lubbock.c: * Author: Nicolas Pitre * Created: Jun 15, 2001 * Copyright: MontaVista Software Inc. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. */ #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 #include #include #include #include #include #include #include #include #include "generic.h" #include "devices.h" static unsigned int icr; static void viper_icr_set_bit(unsigned int bit) { icr |= bit; VIPER_ICR = icr; } static void viper_icr_clear_bit(unsigned int bit) { icr &= ~bit; VIPER_ICR = icr; } /* This function is used from the pcmcia module to reset the CF */ static void viper_cf_reset(int state) { if (state) viper_icr_set_bit(VIPER_ICR_CF_RST); else viper_icr_clear_bit(VIPER_ICR_CF_RST); } static struct arcom_pcmcia_pdata viper_pcmcia_info = { .cd_gpio = VIPER_CF_CD_GPIO, .rdy_gpio = VIPER_CF_RDY_GPIO, .pwr_gpio = VIPER_CF_POWER_GPIO, .reset = viper_cf_reset, }; static struct platform_device viper_pcmcia_device = { .name = "viper-pcmcia", .id = -1, .dev = { .platform_data = &viper_pcmcia_info, }, }; /* * The CPLD version register was not present on VIPER boards prior to * v2i1. On v1 boards where the version register is not present we * will just read back the previous value from the databus. * * Therefore we do two reads. The first time we write 0 to the * (read-only) register before reading and the second time we write * 0xff first. If the two reads do not match or they read back as 0xff * or 0x00 then we have version 1 hardware. */ static u8 viper_hw_version(void) { u8 v1, v2; unsigned long flags; local_irq_save(flags); VIPER_VERSION = 0; v1 = VIPER_VERSION; VIPER_VERSION = 0xff; v2 = VIPER_VERSION; v1 = (v1 != v2 || v1 == 0xff) ? 0 : v1; local_irq_restore(flags); return v1; } /* CPU sysdev */ static int viper_cpu_suspend(struct sys_device *sysdev, pm_message_t state) { viper_icr_set_bit(VIPER_ICR_R_DIS); return 0; } static int viper_cpu_resume(struct sys_device *sysdev) { viper_icr_clear_bit(VIPER_ICR_R_DIS); return 0; } static struct sysdev_driver viper_cpu_sysdev_driver = { .suspend = viper_cpu_suspend, .resume = viper_cpu_resume, }; static unsigned int current_voltage_divisor; /* * If force is not true then step from existing to new divisor. If * force is true then jump straight to the new divisor. Stepping is * used because if the jump in voltage is too large, the VCC can dip * too low and the regulator cuts out. * * force can be used to initialize the divisor to a know state by * setting the value for the current clock speed, since we are already * running at that speed we know the voltage should be pretty close so * the jump won't be too large */ static void viper_set_core_cpu_voltage(unsigned long khz, int force) { int i = 0; unsigned int divisor = 0; const char *v; if (khz < 200000) { v = "1.0"; divisor = 0xfff; } else if (khz < 300000) { v = "1.1"; divisor = 0xde5; } else { v = "1.3"; divisor = 0x325; } pr_debug("viper: setting CPU core voltage to %sV at %d.%03dMHz\n", v, (int)khz / 1000, (int)khz % 1000); #define STEP 0x100 do { int step; if (force) step = divisor; else if (current_voltage_divisor < divisor - STEP) step = current_voltage_divisor + STEP; else if (current_voltage_divisor > divisor + STEP) step = current_voltage_divisor - STEP; else step = divisor; force = 0; gpio_set_value(VIPER_PSU_CLK_GPIO, 0); gpio_set_value(VIPER_PSU_nCS_LD_GPIO, 0); for (i = 1 << 11 ; i > 0 ; i >>= 1) { udelay(1); gpio_set_value(VIPER_PSU_DATA_GPIO, step & i); udelay(1); gpio_set_value(VIPER_PSU_CLK_GPIO, 1); udelay(1); gpio_set_value(VIPER_PSU_CLK_GPIO, 0); } udelay(1); gpio_set_value(VIPER_PSU_nCS_LD_GPIO, 1); udelay(1); gpio_set_value(VIPER_PSU_nCS_LD_GPIO, 0); current_voltage_divisor = step; } while (current_voltage_divisor != divisor); } /* Interrupt handling */ static unsigned long viper_irq_enabled_mask; static const int viper_isa_irqs[] = { 3, 4, 5, 6, 7, 10, 11, 12, 9, 14, 15 }; static const int viper_isa_irq_map[] = { 0, /* ISA irq #0, invalid */ 0, /* ISA irq #1, invalid */ 0, /* ISA irq #2, invalid */ 1 << 0, /* ISA irq #3 */ 1 << 1, /* ISA irq #4 */ 1 << 2, /* ISA irq #5 */ 1 << 3, /* ISA irq #6 */ 1 << 4, /* ISA irq #7 */ 0, /* ISA irq #8, invalid */ 1 << 8, /* ISA irq #9 */ 1 << 5, /* ISA irq #10 */ 1 << 6, /* ISA irq #11 */ 1 << 7, /* ISA irq #12 */ 0, /* ISA irq #13, invalid */ 1 << 9, /* ISA irq #14 */ 1 << 10, /* ISA irq #15 */ }; static inline int viper_irq_to_bitmask(unsigned int irq) { return viper_isa_irq_map[irq - PXA_ISA_IRQ(0)]; } static inline int viper_bit_to_irq(int bit) { return viper_isa_irqs[bit] + PXA_ISA_IRQ(0); } static void viper_ack_irq(unsigned int irq) { int viper_irq = viper_irq_to_bitmask(irq); if (viper_irq & 0xff) VIPER_LO_IRQ_STATUS = viper_irq; else VIPER_HI_IRQ_STATUS = (viper_irq >> 8); } static void viper_mask_irq(unsigned int irq) { viper_irq_enabled_mask &= ~(viper_irq_to_bitmask(irq)); } static void viper_unmask_irq(unsigned int irq) { viper_irq_enabled_mask |= viper_irq_to_bitmask(irq); } static inline unsigned long viper_irq_pending(void) { return (VIPER_HI_IRQ_STATUS << 8 | VIPER_LO_IRQ_STATUS) & viper_irq_enabled_mask; } static void viper_irq_handler(unsigned int irq, struct irq_desc *desc) { unsigned long pending; pending = viper_irq_pending(); do { /* we're in a chained irq handler, * so ack the interrupt by hand */ desc->chip->ack(irq); if (likely(pending)) { irq = viper_bit_to_irq(__ffs(pending)); generic_handle_irq(irq); } pending = viper_irq_pending(); } while (pending); } static struct irq_chip viper_irq_chip = { .name = "ISA", .ack = viper_ack_irq, .mask = viper_mask_irq, .unmask = viper_unmask_irq }; static void __init viper_init_irq(void) { int level; int isa_irq; pxa25x_init_irq(); /* setup ISA IRQs */ for (level = 0; level < ARRAY_SIZE(viper_isa_irqs); level++) { isa_irq = viper_bit_to_irq(level); set_irq_chip(isa_irq, &viper_irq_chip); set_irq_handler(isa_irq, handle_edge_irq); set_irq_flags(isa_irq, IRQF_VALID | IRQF_PROBE); } set_irq_chained_handler(gpio_to_irq(VIPER_CPLD_GPIO), viper_irq_handler); set_irq_type(gpio_to_irq(VIPER_CPLD_GPIO), IRQ_TYPE_EDGE_BOTH); } /* Flat Panel */ static struct pxafb_mode_info fb_mode_info[] = { { .pixclock = 157500, .xres = 320, .yres = 240, .bpp = 16, .hsync_len = 63, .left_margin = 7, .right_margin = 13, .vsync_len = 20, .upper_margin = 0, .lower_margin = 0, .sync = 0, }, }; static struct pxafb_mach_info fb_info = { .modes = fb_mode_info, .num_modes = 1, .lcd_conn = LCD_COLOR_TFT_16BPP | LCD_PCLK_EDGE_FALL, }; static int viper_backlight_init(struct device *dev) { int ret; /* GPIO9 and 10 control FB backlight. Initialise to off */ ret = gpio_request(VIPER_BCKLIGHT_EN_GPIO, "Backlight"); if (ret) goto err_request_bckl; ret = gpio_request(VIPER_LCD_EN_GPIO, "LCD"); if (ret) goto err_request_lcd; ret = gpio_direction_output(VIPER_BCKLIGHT_EN_GPIO, 0); if (ret) goto err_dir; ret = gpio_direction_output(VIPER_LCD_EN_GPIO, 0); if (ret) goto err_dir; return 0; err_dir: gpio_free(VIPER_LCD_EN_GPIO); err_request_lcd: gpio_free(VIPER_BCKLIGHT_EN_GPIO); err_request_bckl: dev_err(dev, "Failed to setup LCD GPIOs\n"); return ret; } static int viper_backlight_notify(struct device *dev, int brightness) { gpio_set_value(VIPER_LCD_EN_GPIO, !!brightness); gpio_set_value(VIPER_BCKLIGHT_EN_GPIO, !!brightness); return brightness; } static void viper_backlight_exit(struct device *dev) { gpio_free(VIPER_LCD_EN_GPIO); gpio_free(VIPER_BCKLIGHT_EN_GPIO); } static struct platform_pwm_backlight_data viper_backlight_data = { .pwm_id = 0, .max_brightness = 100, .dft_brightness = 100, .pwm_period_ns = 1000000, .init = viper_backlight_init, .notify = viper_backlight_notify, .exit = viper_backlight_exit, }; static struct platform_device viper_backlight_device = { .name = "pwm-backlight", .dev = { .parent = &pxa25x_device_pwm0.dev, .platform_data = &viper_backlight_data, }, }; /* Ethernet */ static struct resource smc91x_resources[] = { [0] = { .name = "smc91x-regs", .start = VIPER_ETH_PHYS + 0x300, .end = VIPER_ETH_PHYS + 0x30f, .flags = IORESOURCE_MEM, }, [1] = { .start = gpio_to_irq(VIPER_ETH_GPIO), .end = gpio_to_irq(VIPER_ETH_GPIO), .flags = IORESOURCE_IRQ | IORESOURCE_IRQ_HIGHEDGE, }, [2] = { .name = "smc91x-data32", .start = VIPER_ETH_DATA_PHYS, .end = VIPER_ETH_DATA_PHYS + 3, .flags = IORESOURCE_MEM, }, }; static struct smc91x_platdata viper_smc91x_info = { .flags = SMC91X_USE_16BIT | SMC91X_NOWAIT, .leda = RPC_LED_100_10, .ledb = RPC_LED_TX_RX, }; static struct platform_device smc91x_device = { .name = "smc91x", .id = -1, .num_resources = ARRAY_SIZE(smc91x_resources), .resource = smc91x_resources, .dev = { .platform_data = &viper_smc91x_info, }, }; /* i2c */ static struct i2c_gpio_platform_data i2c_bus_data = { .sda_pin = VIPER_RTC_I2C_SDA_GPIO, .scl_pin = VIPER_RTC_I2C_SCL_GPIO, .udelay = 10, .timeout = HZ, }; static struct platform_device i2c_bus_device = { .name = "i2c-gpio", .id = 1, /* pxa2xx-i2c is bus 0, so start at 1 */ .dev = { .platform_data = &i2c_bus_data, } }; static struct i2c_board_info __initdata viper_i2c_devices[] = { { I2C_BOARD_INFO("ds1338", 0x68), }, }; /* * Serial configuration: * You can either have the standard PXA ports driven by the PXA driver, * or all the ports (PXA + 16850) driven by the 8250 driver. * Choose your poison. */ static struct resource viper_serial_resources[] = { #ifndef CONFIG_SERIAL_PXA { .start = 0x40100000, .end = 0x4010001f, .flags = IORESOURCE_MEM, }, { .start = 0x40200000, .end = 0x4020001f, .flags = IORESOURCE_MEM, }, { .start = 0x40700000, .end = 0x4070001f, .flags = IORESOURCE_MEM, }, { .start = VIPER_UARTA_PHYS, .end = VIPER_UARTA_PHYS + 0xf, .flags = IORESOURCE_MEM, }, { .start = VIPER_UARTB_PHYS, .end = VIPER_UARTB_PHYS + 0xf, .flags = IORESOURCE_MEM, }, #else { 0, }, #endif }; static struct plat_serial8250_port serial_platform_data[] = { #ifndef CONFIG_SERIAL_PXA /* Internal UARTs */ { .membase = (void *)&FFUART, .mapbase = __PREG(FFUART), .irq = IRQ_FFUART, .uartclk = 921600 * 16, .regshift = 2, .flags = UPF_BOOT_AUTOCONF | UPF_SKIP_TEST, .iotype = UPIO_MEM, }, { .membase = (void *)&BTUART, .mapbase = __PREG(BTUART), .irq = IRQ_BTUART, .uartclk = 921600 * 16, .regshift = 2, .flags = UPF_BOOT_AUTOCONF | UPF_SKIP_TEST, .iotype = UPIO_MEM, }, { .membase = (void *)&STUART, .mapbase = __PREG(STUART), .irq = IRQ_STUART, .uartclk = 921600 * 16, .regshift = 2, .flags = UPF_BOOT_AUTOCONF | UPF_SKIP_TEST, .iotype = UPIO_MEM, }, /* External UARTs */ { .mapbase = VIPER_UARTA_PHYS, .irq = gpio_to_irq(VIPER_UARTA_GPIO), .irqflags = IRQF_TRIGGER_RISING, .uartclk = 1843200, .regshift = 1, .iotype = UPIO_MEM, .flags = UPF_BOOT_AUTOCONF | UPF_IOREMAP | UPF_SKIP_TEST, }, { .mapbase = VIPER_UARTB_PHYS, .irq = gpio_to_irq(VIPER_UARTB_GPIO), .irqflags = IRQF_TRIGGER_RISING, .uartclk = 1843200, .regshift = 1, .iotype = UPIO_MEM, .flags = UPF_BOOT_AUTOCONF | UPF_IOREMAP | UPF_SKIP_TEST, }, #endif { }, }; static struct platform_device serial_device = { .name = "serial8250", .id = 0, .dev = { .platform_data = serial_platform_data, }, .num_resources = ARRAY_SIZE(viper_serial_resources), .resource = viper_serial_resources, }; /* USB */ static void isp116x_delay(struct device *dev, int delay) { ndelay(delay); } static struct resource isp116x_resources[] = { [0] = { /* DATA */ .start = VIPER_USB_PHYS + 0, .end = VIPER_USB_PHYS + 1, .flags = IORESOURCE_MEM, }, [1] = { /* ADDR */ .start = VIPER_USB_PHYS + 2, .end = VIPER_USB_PHYS + 3, .flags = IORESOURCE_MEM, }, [2] = { .start = gpio_to_irq(VIPER_USB_GPIO), .end = gpio_to_irq(VIPER_USB_GPIO), .flags = IORESOURCE_IRQ | IORESOURCE_IRQ_HIGHEDGE, }, }; /* (DataBusWidth16|AnalogOCEnable|DREQOutputPolarity|DownstreamPort15KRSel ) */ static struct isp116x_platform_data isp116x_platform_data = { /* Enable internal resistors on downstream ports */ .sel15Kres = 1, /* On-chip overcurrent protection */ .oc_enable = 1, /* INT output polarity */ .int_act_high = 1, /* INT edge or level triggered */ .int_edge_triggered = 0, /* WAKEUP pin connected - NOT SUPPORTED */ /* .remote_wakeup_connected = 0, */ /* Wakeup by devices on usb bus enabled */ .remote_wakeup_enable = 0, .delay = isp116x_delay, }; static struct platform_device isp116x_device = { .name = "isp116x-hcd", .id = -1, .num_resources = ARRAY_SIZE(isp116x_resources), .resource = isp116x_resources, .dev = { .platform_data = &isp116x_platform_data, }, }; /* MTD */ static struct resource mtd_resources[] = { [0] = { /* RedBoot config + filesystem flash */ .start = VIPER_FLASH_PHYS, .end = VIPER_FLASH_PHYS + SZ_32M - 1, .flags = IORESOURCE_MEM, }, [1] = { /* Boot flash */ .start = VIPER_BOOT_PHYS, .end = VIPER_BOOT_PHYS + SZ_1M - 1, .flags = IORESOURCE_MEM, }, [2] = { /* * SRAM size is actually 256KB, 8bits, with a sparse mapping * (each byte is on a 16bit boundary). */ .start = _VIPER_SRAM_BASE, .end = _VIPER_SRAM_BASE + SZ_512K - 1, .flags = IORESOURCE_MEM, }, }; static struct mtd_partition viper_boot_flash_partition = { .name = "RedBoot", .size = SZ_1M, .offset = 0, .mask_flags = MTD_WRITEABLE, /* force R/O */ }; static struct physmap_flash_data viper_flash_data[] = { [0] = { .width = 2, .parts = NULL, .nr_parts = 0, }, [1] = { .width = 2, .parts = &viper_boot_flash_partition, .nr_parts = 1, }, }; static struct platform_device viper_mtd_devices[] = { [0] = { .name = "physmap-flash", .id = 0, .dev = { .platform_data = &viper_flash_data[0], }, .resource = &mtd_resources[0], .num_resources = 1, }, [1] = { .name = "physmap-flash", .id = 1, .dev = { .platform_data = &viper_flash_data[1], }, .resource = &mtd_resources[1], .num_resources = 1, }, }; static struct platform_device *viper_devs[] __initdata = { &smc91x_device, &i2c_bus_device, &serial_device, &isp116x_device, &viper_mtd_devices[0], &viper_mtd_devices[1], &viper_backlight_device, &viper_pcmcia_device, }; static mfp_cfg_t viper_pin_config[] __initdata = { /* Chip selects */ GPIO15_nCS_1, GPIO78_nCS_2, GPIO79_nCS_3, GPIO80_nCS_4, GPIO33_nCS_5, /* AC97 */ GPIO28_AC97_BITCLK, GPIO29_AC97_SDATA_IN_0, GPIO30_AC97_SDATA_OUT, GPIO31_AC97_SYNC, /* FP Backlight */ GPIO9_GPIO, /* VIPER_BCKLIGHT_EN_GPIO */ GPIO10_GPIO, /* VIPER_LCD_EN_GPIO */ GPIO16_PWM0_OUT, /* Ethernet PHY Ready */ GPIO18_RDY, /* Serial shutdown */ GPIO12_GPIO | MFP_LPM_DRIVE_HIGH, /* VIPER_UART_SHDN_GPIO */ /* Compact-Flash / PC104 */ GPIO48_nPOE, GPIO49_nPWE, GPIO50_nPIOR, GPIO51_nPIOW, GPIO52_nPCE_1, GPIO53_nPCE_2, GPIO54_nPSKTSEL, GPIO55_nPREG, GPIO56_nPWAIT, GPIO57_nIOIS16, GPIO8_GPIO, /* VIPER_CF_RDY_GPIO */ GPIO32_GPIO, /* VIPER_CF_CD_GPIO */ GPIO82_GPIO, /* VIPER_CF_POWER_GPIO */ /* Integrated UPS control */ GPIO20_GPIO, /* VIPER_UPS_GPIO */ /* Vcc regulator control */ GPIO6_GPIO, /* VIPER_PSU_DATA_GPIO */ GPIO11_GPIO, /* VIPER_PSU_CLK_GPIO */ GPIO19_GPIO, /* VIPER_PSU_nCS_LD_GPIO */ /* i2c busses */ GPIO26_GPIO, /* VIPER_TPM_I2C_SDA_GPIO */ GPIO27_GPIO, /* VIPER_TPM_I2C_SCL_GPIO */ GPIO83_GPIO, /* VIPER_RTC_I2C_SDA_GPIO */ GPIO84_GPIO, /* VIPER_RTC_I2C_SCL_GPIO */ /* PC/104 Interrupt */ GPIO1_GPIO | WAKEUP_ON_EDGE_RISE, /* VIPER_CPLD_GPIO */ }; static unsigned long viper_tpm; static int __init viper_tpm_setup(char *str) { strict_strtoul(str, 10, &viper_tpm); return 1; } __setup("tpm=", viper_tpm_setup); static void __init viper_tpm_init(void) { struct platform_device *tpm_device; struct i2c_gpio_platform_data i2c_tpm_data = { .sda_pin = VIPER_TPM_I2C_SDA_GPIO, .scl_pin = VIPER_TPM_I2C_SCL_GPIO, .udelay = 10, .timeout = HZ, }; char *errstr; /* Allocate TPM i2c bus if requested */ if (!viper_tpm) return; tpm_device = platform_device_alloc("i2c-gpio", 2); if (tpm_device) { if (!platform_device_add_data(tpm_device, &i2c_tpm_data, sizeof(i2c_tpm_data))) { if (platform_device_add(tpm_device)) { errstr = "register TPM i2c bus"; goto error_free_tpm; } } else { errstr = "allocate TPM i2c bus data"; goto error_free_tpm; } } else { errstr = "allocate TPM i2c device"; goto error_tpm; } return; error_free_tpm: kfree(tpm_device); error_tpm: pr_err("viper: Couldn't %s, giving up\n", errstr); } static void __init viper_init_vcore_gpios(void) { if (gpio_request(VIPER_PSU_DATA_GPIO, "PSU data")) goto err_request_data; if (gpio_request(VIPER_PSU_CLK_GPIO, "PSU clock")) goto err_request_clk; if (gpio_request(VIPER_PSU_nCS_LD_GPIO, "PSU cs")) goto err_request_cs; if (gpio_direction_output(VIPER_PSU_DATA_GPIO, 0) || gpio_direction_output(VIPER_PSU_CLK_GPIO, 0) || gpio_direction_output(VIPER_PSU_nCS_LD_GPIO, 0)) goto err_dir; /* c/should assume redboot set the correct level ??? */ viper_set_core_cpu_voltage(get_clk_frequency_khz(0), 1); return; err_dir: gpio_free(VIPER_PSU_nCS_LD_GPIO); err_request_cs: gpio_free(VIPER_PSU_CLK_GPIO); err_request_clk: gpio_free(VIPER_PSU_DATA_GPIO); err_request_data: pr_err("viper: Failed to setup vcore control GPIOs\n"); } static void __init viper_init_serial_gpio(void) { if (gpio_request(VIPER_UART_SHDN_GPIO, "UARTs shutdown")) goto err_request; if (gpio_direction_output(VIPER_UART_SHDN_GPIO, 0)) goto err_dir; return; err_dir: gpio_free(VIPER_UART_SHDN_GPIO); err_request: pr_err("viper: Failed to setup UART shutdown GPIO\n"); } #ifdef CONFIG_CPU_FREQ static int viper_cpufreq_notifier(struct notifier_block *nb, unsigned long val, void *data) { struct cpufreq_freqs *freq = data; /* TODO: Adjust timings??? */ switch (val) { case CPUFREQ_PRECHANGE: if (freq->old < freq->new) { /* we are getting faster so raise the voltage * before we change freq */ viper_set_core_cpu_voltage(freq->new, 0); } break; case CPUFREQ_POSTCHANGE: if (freq->old > freq->new) { /* we are slowing down so drop the power * after we change freq */ viper_set_core_cpu_voltage(freq->new, 0); } break; case CPUFREQ_RESUMECHANGE: viper_set_core_cpu_voltage(freq->new, 0); break; default: /* ignore */ break; } return 0; } static struct notifier_block viper_cpufreq_notifier_block = { .notifier_call = viper_cpufreq_notifier }; static void __init viper_init_cpufreq(void) { if (cpufreq_register_notifier(&viper_cpufreq_notifier_block, CPUFREQ_TRANSITION_NOTIFIER)) pr_err("viper: Failed to setup cpufreq notifier\n"); } #else static inline void viper_init_cpufreq(void) {} #endif static void viper_power_off(void) { pr_notice("Shutting off UPS\n"); gpio_set_value(VIPER_UPS_GPIO, 1); /* Spin to death... */ while (1); } static void __init viper_init(void) { u8 version; pm_power_off = viper_power_off; pxa2xx_mfp_config(ARRAY_AND_SIZE(viper_pin_config)); pxa_set_ffuart_info(NULL); pxa_set_btuart_info(NULL); pxa_set_stuart_info(NULL); /* Wake-up serial console */ viper_init_serial_gpio(); set_pxa_fb_info(&fb_info); /* v1 hardware cannot use the datacs line */ version = viper_hw_version(); if (version == 0) smc91x_device.num_resources--; pxa_set_i2c_info(NULL); platform_add_devices(viper_devs, ARRAY_SIZE(viper_devs)); viper_init_vcore_gpios(); viper_init_cpufreq(); sysdev_driver_register(&cpu_sysdev_class, &viper_cpu_sysdev_driver); if (version) { pr_info("viper: hardware v%di%d detected. " "CPLD revision %d.\n", VIPER_BOARD_VERSION(version), VIPER_BOARD_ISSUE(version), VIPER_CPLD_REVISION(version)); system_rev = (VIPER_BOARD_VERSION(version) << 8) | (VIPER_BOARD_ISSUE(version) << 4) | VIPER_CPLD_REVISION(version); } else { pr_info("viper: No version register.\n"); } i2c_register_board_info(1, ARRAY_AND_SIZE(viper_i2c_devices)); viper_tpm_init(); pxa_set_ac97_info(NULL); } static struct map_desc viper_io_desc[] __initdata = { { .virtual = VIPER_CPLD_BASE, .pfn = __phys_to_pfn(VIPER_CPLD_PHYS), .length = 0x00300000, .type = MT_DEVICE, }, { .virtual = VIPER_PC104IO_BASE, .pfn = __phys_to_pfn(0x30000000), .length = 0x00800000, .type = MT_DEVICE, }, }; static void __init viper_map_io(void) { pxa_map_io(); iotable_init(viper_io_desc, ARRAY_SIZE(viper_io_desc)); PCFR |= PCFR_OPDE; } MACHINE_START(VIPER, "Arcom/Eurotech VIPER SBC") /* Maintainer: Marc Zyngier */ .boot_params = 0xa0000100, .map_io = viper_map_io, .init_irq = viper_init_irq, .timer = &pxa_timer, .init_machine = viper_init, MACHINE_END