/* * Copyright (C) 2015 Technexion Ltd. * * Author: Richard Hu * * SPDX-License-Identifier: GPL-2.0+ */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef CONFIG_POWER #include #include #include "../../freescale/common/pfuze.h" #endif #ifdef CONFIG_FSL_FASTBOOT #include #ifdef CONFIG_ANDROID_RECOVERY #include #endif #endif /*CONFIG_FSL_FASTBOOT*/ DECLARE_GLOBAL_DATA_PTR; #define UART_PAD_CTRL (PAD_CTL_PKE | PAD_CTL_PUE | \ PAD_CTL_PUS_100K_UP | PAD_CTL_SPEED_MED | \ PAD_CTL_DSE_40ohm | PAD_CTL_SRE_FAST | PAD_CTL_HYS) #define USDHC_PAD_CTRL (PAD_CTL_PKE | PAD_CTL_PUE | \ PAD_CTL_PUS_22K_UP | PAD_CTL_SPEED_LOW | \ PAD_CTL_DSE_80ohm | PAD_CTL_SRE_FAST | PAD_CTL_HYS) #define USDHC_SD_CD_PAD_CTRL (PAD_CTL_PKE | PAD_CTL_PUE | \ PAD_CTL_PUS_100K_DOWN | PAD_CTL_SPEED_LOW | \ PAD_CTL_DSE_80ohm | PAD_CTL_SRE_FAST | PAD_CTL_HYS) #define ENET_PAD_CTRL (PAD_CTL_PUS_100K_UP | PAD_CTL_PUE | \ PAD_CTL_SPEED_HIGH | \ PAD_CTL_DSE_48ohm | PAD_CTL_SRE_FAST) #define MDIO_PAD_CTRL (PAD_CTL_PUS_100K_UP | PAD_CTL_PUE | \ PAD_CTL_DSE_48ohm | PAD_CTL_SRE_FAST | PAD_CTL_ODE) #define ENET_CLK_PAD_CTRL (PAD_CTL_DSE_40ohm | PAD_CTL_SRE_FAST) #define ENET_RX_PAD_CTRL (PAD_CTL_PKE | PAD_CTL_PUE | \ PAD_CTL_SPEED_HIGH | PAD_CTL_SRE_FAST) #define I2C_PAD_CTRL (PAD_CTL_PKE | PAD_CTL_PUE | \ PAD_CTL_PUS_100K_UP | PAD_CTL_SPEED_MED | \ PAD_CTL_DSE_40ohm | PAD_CTL_HYS | \ PAD_CTL_ODE) #define LCD_PAD_CTRL (PAD_CTL_HYS | PAD_CTL_PUS_100K_UP | PAD_CTL_PUE | \ PAD_CTL_PKE | PAD_CTL_SPEED_MED | PAD_CTL_DSE_40ohm) #define GPMI_PAD_CTRL0 (PAD_CTL_PKE | PAD_CTL_PUE | PAD_CTL_PUS_100K_UP) #define GPMI_PAD_CTRL1 (PAD_CTL_DSE_40ohm | PAD_CTL_SPEED_MED | \ PAD_CTL_SRE_FAST) #define GPMI_PAD_CTRL2 (GPMI_PAD_CTRL0 | GPMI_PAD_CTRL1) #define WEIM_NOR_PAD_CTRL (PAD_CTL_PKE | PAD_CTL_PUE | \ PAD_CTL_PUS_100K_UP | PAD_CTL_SPEED_MED | \ PAD_CTL_DSE_40ohm | PAD_CTL_SRE_FAST) #define SPI_PAD_CTRL (PAD_CTL_HYS | \ PAD_CTL_SPEED_MED | \ PAD_CTL_DSE_40ohm | PAD_CTL_SRE_FAST) #define OTG_ID_PAD_CTRL (PAD_CTL_PKE | PAD_CTL_PUE | \ PAD_CTL_PUS_47K_UP | PAD_CTL_SPEED_LOW | \ PAD_CTL_DSE_80ohm | PAD_CTL_SRE_FAST | PAD_CTL_HYS) #define VERSION_DET_DDR_SIZE IMX_GPIO_NR(5, 1) #ifdef CONFIG_SYS_I2C_MXC #define PC MUX_PAD_CTRL(I2C_PAD_CTRL) /* I2C2 for PMIC */ struct i2c_pads_info i2c_pad_info1 = { .scl = { .i2c_mode = MX6_PAD_GPIO1_IO02__I2C1_SCL | PC, .gpio_mode = MX6_PAD_GPIO1_IO02__GPIO1_IO02 | PC, .gp = IMX_GPIO_NR(1, 2), }, .sda = { .i2c_mode = MX6_PAD_GPIO1_IO03__I2C1_SDA | PC, .gpio_mode = MX6_PAD_GPIO1_IO03__GPIO1_IO03 | PC, .gp = IMX_GPIO_NR(1, 3), }, }; #endif int dram_init(void) { gd->ram_size = PHYS_SDRAM_SIZE; return 0; } static iomux_v3_cfg_t const uart6_pads[] = { MX6_PAD_CSI_MCLK__UART6_DCE_TX | MUX_PAD_CTRL(UART_PAD_CTRL), MX6_PAD_CSI_PIXCLK__UART6_DCE_RX | MUX_PAD_CTRL(UART_PAD_CTRL), }; static iomux_v3_cfg_t const usdhc1_pads[] = { MX6_PAD_SD1_CLK__USDHC1_CLK | MUX_PAD_CTRL(USDHC_PAD_CTRL), MX6_PAD_SD1_CMD__USDHC1_CMD | MUX_PAD_CTRL(USDHC_PAD_CTRL), MX6_PAD_SD1_DATA0__USDHC1_DATA0 | MUX_PAD_CTRL(USDHC_PAD_CTRL), MX6_PAD_SD1_DATA1__USDHC1_DATA1 | MUX_PAD_CTRL(USDHC_PAD_CTRL), MX6_PAD_SD1_DATA2__USDHC1_DATA2 | MUX_PAD_CTRL(USDHC_PAD_CTRL), MX6_PAD_SD1_DATA3__USDHC1_DATA3 | MUX_PAD_CTRL(USDHC_PAD_CTRL), #ifndef CONFIG_SYS_USE_NAND MX6_PAD_NAND_READY_B__USDHC1_DATA4 | MUX_PAD_CTRL(USDHC_PAD_CTRL), MX6_PAD_NAND_CE0_B__USDHC1_DATA5 | MUX_PAD_CTRL(USDHC_PAD_CTRL), MX6_PAD_NAND_CE1_B__USDHC1_DATA6 | MUX_PAD_CTRL(USDHC_PAD_CTRL), MX6_PAD_NAND_CLE__USDHC1_DATA7 | MUX_PAD_CTRL(USDHC_PAD_CTRL), #endif /* CD */ MX6_PAD_UART1_RTS_B__GPIO1_IO19 | MUX_PAD_CTRL(NO_PAD_CTRL), }; static iomux_v3_cfg_t const version_detection_pads[] = { /* dram size detection */ MX6_PAD_SNVS_TAMPER1__GPIO5_IO01 | MUX_PAD_CTRL(NO_PAD_CTRL), }; #ifdef CONFIG_SYS_USE_NAND static iomux_v3_cfg_t const nand_pads[] = { MX6_PAD_NAND_DATA00__RAWNAND_DATA00 | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_DATA01__RAWNAND_DATA01 | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_DATA02__RAWNAND_DATA02 | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_DATA03__RAWNAND_DATA03 | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_DATA04__RAWNAND_DATA04 | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_DATA05__RAWNAND_DATA05 | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_DATA06__RAWNAND_DATA06 | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_DATA07__RAWNAND_DATA07 | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_CLE__RAWNAND_CLE | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_ALE__RAWNAND_ALE | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_CE0_B__RAWNAND_CE0_B | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_CE1_B__RAWNAND_CE1_B | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_RE_B__RAWNAND_RE_B | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_WE_B__RAWNAND_WE_B | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_WP_B__RAWNAND_WP_B | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_READY_B__RAWNAND_READY_B | MUX_PAD_CTRL(GPMI_PAD_CTRL2), MX6_PAD_NAND_DQS__RAWNAND_DQS | MUX_PAD_CTRL(GPMI_PAD_CTRL2), }; static void setup_gpmi_nand(void) { struct mxc_ccm_reg *mxc_ccm = (struct mxc_ccm_reg *)CCM_BASE_ADDR; /* config gpmi nand iomux */ imx_iomux_v3_setup_multiple_pads(nand_pads, ARRAY_SIZE(nand_pads)); clrbits_le32(&mxc_ccm->CCGR4, MXC_CCM_CCGR4_RAWNAND_U_BCH_INPUT_APB_MASK | MXC_CCM_CCGR4_RAWNAND_U_GPMI_BCH_INPUT_BCH_MASK | MXC_CCM_CCGR4_RAWNAND_U_GPMI_BCH_INPUT_GPMI_IO_MASK | MXC_CCM_CCGR4_RAWNAND_U_GPMI_INPUT_APB_MASK | MXC_CCM_CCGR4_PL301_MX6QPER1_BCH_MASK); /* * config gpmi and bch clock to 100 MHz * bch/gpmi select PLL2 PFD2 400M * 100M = 400M / 4 */ clrbits_le32(&mxc_ccm->cscmr1, MXC_CCM_CSCMR1_BCH_CLK_SEL | MXC_CCM_CSCMR1_GPMI_CLK_SEL); clrsetbits_le32(&mxc_ccm->cscdr1, MXC_CCM_CSCDR1_BCH_PODF_MASK | MXC_CCM_CSCDR1_GPMI_PODF_MASK, (3 << MXC_CCM_CSCDR1_BCH_PODF_OFFSET) | (3 << MXC_CCM_CSCDR1_GPMI_PODF_OFFSET)); /* enable gpmi and bch clock gating */ setbits_le32(&mxc_ccm->CCGR4, MXC_CCM_CCGR4_RAWNAND_U_BCH_INPUT_APB_MASK | MXC_CCM_CCGR4_RAWNAND_U_GPMI_BCH_INPUT_BCH_MASK | MXC_CCM_CCGR4_RAWNAND_U_GPMI_BCH_INPUT_GPMI_IO_MASK | MXC_CCM_CCGR4_RAWNAND_U_GPMI_INPUT_APB_MASK | MXC_CCM_CCGR4_PL301_MX6QPER1_BCH_MASK); /* enable apbh clock gating */ setbits_le32(&mxc_ccm->CCGR0, MXC_CCM_CCGR0_APBHDMA_MASK); } #endif #ifdef CONFIG_FEC_MXC static iomux_v3_cfg_t const fec_pads[] = { MX6_PAD_ENET1_TX_EN__ENET2_MDC | MUX_PAD_CTRL(MDIO_PAD_CTRL), MX6_PAD_ENET1_TX_DATA1__ENET2_MDIO | MUX_PAD_CTRL(MDIO_PAD_CTRL), MX6_PAD_ENET2_TX_DATA0__ENET2_TDATA00 | MUX_PAD_CTRL(ENET_PAD_CTRL), MX6_PAD_ENET2_TX_DATA1__ENET2_TDATA01 | MUX_PAD_CTRL(ENET_PAD_CTRL), MX6_PAD_ENET2_TX_CLK__ENET2_REF_CLK2 | MUX_PAD_CTRL(ENET_CLK_PAD_CTRL), MX6_PAD_ENET2_TX_EN__ENET2_TX_EN | MUX_PAD_CTRL(ENET_PAD_CTRL), MX6_PAD_ENET2_RX_DATA0__ENET2_RDATA00 | MUX_PAD_CTRL(ENET_PAD_CTRL), MX6_PAD_ENET2_RX_DATA1__ENET2_RDATA01 | MUX_PAD_CTRL(ENET_PAD_CTRL), MX6_PAD_ENET2_RX_EN__ENET2_RX_EN | MUX_PAD_CTRL(ENET_PAD_CTRL), MX6_PAD_ENET2_RX_ER__ENET2_RX_ER | MUX_PAD_CTRL(ENET_PAD_CTRL), MX6_PAD_UART4_TX_DATA__GPIO1_IO28 | MUX_PAD_CTRL(NO_PAD_CTRL), }; #define RMII_PHY_RESET IMX_GPIO_NR(1, 28) static void setup_iomux_fec(int fec_id) { imx_iomux_v3_setup_multiple_pads(fec_pads, ARRAY_SIZE(fec_pads)); } #endif static void setup_iomux_version_detection(void) { SETUP_IOMUX_PADS(version_detection_pads); } static void setup_iomux_uart(void) { imx_iomux_v3_setup_multiple_pads(uart6_pads, ARRAY_SIZE(uart6_pads)); } #ifdef CONFIG_FSL_ESDHC static struct fsl_esdhc_cfg usdhc_cfg[2] = { #ifdef CONFIG_SYS_USE_NAND { USDHC1_BASE_ADDR, 0, 4 }, #else { USDHC1_BASE_ADDR, 0, 8 }, /* 8-bit emmc */ #endif /* CONFIG_SYS_USE_NAND */ }; #define USDHC1_CD_GPIO IMX_GPIO_NR(1, 19) int mmc_get_env_devno(void) { u32 soc_sbmr = readl(SRC_BASE_ADDR + 0x4); int dev_no; u32 bootsel; bootsel = (soc_sbmr & 0x000000FF) >> 6 ; /* If not boot from sd/mmc, use default value */ if (bootsel != 1) return CONFIG_SYS_MMC_ENV_DEV; /* BOOT_CFG2[3] and BOOT_CFG2[4] */ dev_no = (soc_sbmr & 0x00001800) >> 11; return dev_no; } int mmc_map_to_kernel_blk(int dev_no) { return dev_no; } int board_mmc_getcd(struct mmc *mmc) { struct fsl_esdhc_cfg *cfg = (struct fsl_esdhc_cfg *)mmc->priv; int ret = 0; switch (cfg->esdhc_base) { case USDHC1_BASE_ADDR: #ifdef CONFIG_SYS_USE_NAND ret = !gpio_get_value(USDHC1_CD_GPIO); #else ret = 1; #endif break; } return ret; } int board_mmc_init(bd_t *bis) { int i, ret; /* * According to the board_mmc_init() the following map is done: * (U-boot device node) (Physical Port) * mmc0 USDHC1 */ for (i = 0; i < CONFIG_SYS_FSL_USDHC_NUM; i++) { switch (i) { case 0: imx_iomux_v3_setup_multiple_pads( usdhc1_pads, ARRAY_SIZE(usdhc1_pads)); usdhc_cfg[0].sdhc_clk = mxc_get_clock(MXC_ESDHC_CLK); break; default: printf("Warning: you configured more USDHC controllers" "(%d) than supported by the board\n", i + 1); return -EINVAL; } ret = fsl_esdhc_initialize(bis, &usdhc_cfg[i]); if (ret) { printf("Warning: failed to initialize mmc dev %d\n", i); return ret; } } return 0; } int check_mmc_autodetect(void) { char *autodetect_str = getenv("mmcautodetect"); if ((autodetect_str != NULL) && (strcmp(autodetect_str, "yes") == 0)) { return 1; } return 0; } void board_late_mmc_init(void) { char cmd[32]; char mmcblk[32]; u32 dev_no = mmc_get_env_devno(); if (!check_mmc_autodetect()) return; setenv_ulong("mmcdev", dev_no); /* Set mmcblk env */ sprintf(mmcblk, "/dev/mmcblk%dp2 rootwait rw", mmc_map_to_kernel_blk(dev_no)); setenv("mmcroot", mmcblk); sprintf(cmd, "mmc dev %d", dev_no); run_command(cmd, 0); } #endif #ifdef CONFIG_VIDEO_MXS static iomux_v3_cfg_t const lcd_pads[] = { MX6_PAD_LCD_CLK__LCDIF_CLK | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_ENABLE__LCDIF_ENABLE | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_HSYNC__LCDIF_HSYNC | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_VSYNC__LCDIF_VSYNC | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA00__LCDIF_DATA00 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA01__LCDIF_DATA01 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA02__LCDIF_DATA02 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA03__LCDIF_DATA03 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA04__LCDIF_DATA04 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA05__LCDIF_DATA05 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA06__LCDIF_DATA06 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA07__LCDIF_DATA07 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA08__LCDIF_DATA08 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA09__LCDIF_DATA09 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA10__LCDIF_DATA10 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA11__LCDIF_DATA11 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA12__LCDIF_DATA12 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA13__LCDIF_DATA13 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA14__LCDIF_DATA14 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA15__LCDIF_DATA15 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA16__LCDIF_DATA16 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA17__LCDIF_DATA17 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA18__LCDIF_DATA18 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA19__LCDIF_DATA19 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA20__LCDIF_DATA20 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA21__LCDIF_DATA21 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA22__LCDIF_DATA22 | MUX_PAD_CTRL(LCD_PAD_CTRL), MX6_PAD_LCD_DATA23__LCDIF_DATA23 | MUX_PAD_CTRL(LCD_PAD_CTRL), /* LCD_RST */ MX6_PAD_SNVS_TAMPER9__GPIO5_IO09 | MUX_PAD_CTRL(NO_PAD_CTRL), /* * Use GPIO for Brightness adjustment, duty cycle = period. */ MX6_PAD_GPIO1_IO08__GPIO1_IO08 | MUX_PAD_CTRL(NO_PAD_CTRL), }; struct lcd_panel_info_t { unsigned int lcdif_base_addr; int depth; void (*enable)(struct lcd_panel_info_t const *dev); struct fb_videomode mode; }; void do_enable_parallel_lcd(struct lcd_panel_info_t const *dev) { enable_lcdif_clock(dev->lcdif_base_addr); imx_iomux_v3_setup_multiple_pads(lcd_pads, ARRAY_SIZE(lcd_pads)); /* Reset the LCD */ gpio_direction_output(IMX_GPIO_NR(5, 9) , 0); udelay(500); gpio_direction_output(IMX_GPIO_NR(5, 9) , 1); /* Set Brightness to high */ gpio_direction_output(IMX_GPIO_NR(1, 8) , 1); } static struct lcd_panel_info_t const displays[] = {{ .lcdif_base_addr = LCDIF1_BASE_ADDR, .depth = 24, .enable = do_enable_parallel_lcd, .mode = { .name = "TFT43AB", .xres = 480, .yres = 272, .pixclock = 108695, .left_margin = 8, .right_margin = 4, .upper_margin = 2, .lower_margin = 4, .hsync_len = 41, .vsync_len = 10, .sync = 0, .vmode = FB_VMODE_NONINTERLACED } } }; int board_video_skip(void) { int i; int ret; char const *panel = getenv("panel"); if (!panel) { panel = displays[0].mode.name; printf("No panel detected: default to %s\n", panel); i = 0; } else { for (i = 0; i < ARRAY_SIZE(displays); i++) { if (!strcmp(panel, displays[i].mode.name)) break; } } if (i < ARRAY_SIZE(displays)) { ret = mxs_lcd_panel_setup(displays[i].mode, displays[i].depth, displays[i].lcdif_base_addr); if (!ret) { if (displays[i].enable) displays[i].enable(displays+i); printf("Display: %s (%ux%u)\n", displays[i].mode.name, displays[i].mode.xres, displays[i].mode.yres); } else printf("LCD %s cannot be configured: %d\n", displays[i].mode.name, ret); } else { printf("unsupported panel %s\n", panel); return -EINVAL; } return 0; } #endif #ifdef CONFIG_FEC_MXC int board_eth_init(bd_t *bis) { int ret; setup_iomux_fec(CONFIG_FEC_ENET_DEV); gpio_direction_output(RMII_PHY_RESET, 0); udelay(500); gpio_direction_output(RMII_PHY_RESET, 1); ret = fecmxc_initialize_multi(bis, CONFIG_FEC_ENET_DEV, CONFIG_FEC_MXC_PHYADDR, IMX_FEC_BASE); if (ret) printf("FEC%d MXC: %s:failed\n", CONFIG_FEC_ENET_DEV, __func__); return 0; } static int setup_fec(int fec_id) { struct iomuxc_gpr_base_regs *const iomuxc_gpr_regs = (struct iomuxc_gpr_base_regs *) IOMUXC_GPR_BASE_ADDR; int ret; if (0 == fec_id) { /* Use 50M anatop loopback REF_CLK1 for ENET1, clear gpr1[13], set gpr1[17]*/ clrsetbits_le32(&iomuxc_gpr_regs->gpr[1], IOMUX_GPR1_FEC1_MASK, IOMUX_GPR1_FEC1_CLOCK_MUX1_SEL_MASK); } else { /* Use 50M anatop loopback REF_CLK2 for ENET2, clear gpr1[14], set gpr1[18]*/ clrsetbits_le32(&iomuxc_gpr_regs->gpr[1], IOMUX_GPR1_FEC2_MASK, IOMUX_GPR1_FEC2_CLOCK_MUX1_SEL_MASK); } ret = enable_fec_anatop_clock(fec_id, ENET_50MHZ); if (ret) return ret; enable_enet_clk(1); return 0; } int board_phy_config(struct phy_device *phydev) { phy_write(phydev, MDIO_DEVAD_NONE, 0x1f, 0x8190); if (phydev->drv->config) phydev->drv->config(phydev); return 0; } #endif #ifdef CONFIG_USB_EHCI_MX6 #define USB_OTHERREGS_OFFSET 0x800 #define UCTRL_PWR_POL (1 << 9) static iomux_v3_cfg_t const usb_otg_pads[] = { MX6_PAD_GPIO1_IO00__ANATOP_OTG1_ID | MUX_PAD_CTRL(OTG_ID_PAD_CTRL), }; /* At default the 3v3 enables the MIC2026 for VBUS power */ static void setup_usb(void) { imx_iomux_v3_setup_multiple_pads(usb_otg_pads, ARRAY_SIZE(usb_otg_pads)); } int board_usb_phy_mode(int port) { if (port == 1) return USB_INIT_HOST; else return usb_phy_mode(port); } int board_ehci_hcd_init(int port) { u32 *usbnc_usb_ctrl; if (port > 1) return -EINVAL; usbnc_usb_ctrl = (u32 *)(USB_BASE_ADDR + USB_OTHERREGS_OFFSET + port * 4); /* Set Power polarity */ setbits_le32(usbnc_usb_ctrl, UCTRL_PWR_POL); return 0; } #endif int board_early_init_f(void) { setup_iomux_uart(); return 0; } #ifdef CONFIG_POWER #define I2C_PMIC 0 static struct pmic *pfuze; int power_init_board(void) { int ret; unsigned int reg, rev_id; ret = power_pfuze300_init(I2C_PMIC); if (ret) return ret; pfuze = pmic_get("PFUZE300"); ret = pmic_probe(pfuze); if (ret) return ret; pmic_reg_read(pfuze, PFUZE300_DEVICEID, ®); pmic_reg_read(pfuze, PFUZE300_REVID, &rev_id); printf("PMIC: PFUZE300 DEV_ID=0x%x REV_ID=0x%x\n", reg, rev_id); /* disable Low Power Mode during standby mode */ pmic_reg_read(pfuze, PFUZE300_LDOGCTL, ®); reg |= 0x1; pmic_reg_write(pfuze, PFUZE300_LDOGCTL, reg); /* SW1B step ramp up time from 2us to 4us/25mV */ reg = 0x40; pmic_reg_write(pfuze, PFUZE300_SW1BCONF, reg); /* SW1B mode to APS/PFM */ reg = 0xc; pmic_reg_write(pfuze, PFUZE300_SW1BMODE, reg); /* SW1B standby voltage set to 0.975V */ reg = 0xb; pmic_reg_write(pfuze, PFUZE300_SW1BSTBY, reg); return 0; } #ifdef CONFIG_LDO_BYPASS_CHECK void ldo_mode_set(int ldo_bypass) { unsigned int value; u32 vddarm; struct pmic *p = pfuze; if (!p) { printf("No PMIC found!\n"); return; } /* switch to ldo_bypass mode */ if (ldo_bypass) { prep_anatop_bypass(); /* decrease VDDARM to 1.275V */ pmic_reg_read(pfuze, PFUZE300_SW1BVOLT, &value); value &= ~0x1f; value |= PFUZE300_SW1AB_SETP(1275); pmic_reg_write(pfuze, PFUZE300_SW1BVOLT, value); set_anatop_bypass(1); vddarm = PFUZE300_SW1AB_SETP(1175); pmic_reg_read(pfuze, PFUZE300_SW1BVOLT, &value); value &= ~0x1f; value |= vddarm; pmic_reg_write(pfuze, PFUZE300_SW1BVOLT, value); finish_anatop_bypass(); printf("switch to ldo_bypass mode!\n"); } } #endif #endif int board_init(void) { /* Address of boot parameters */ gd->bd->bi_boot_params = PHYS_SDRAM + 0x100; #ifdef CONFIG_SYS_I2C_MXC setup_i2c(0, CONFIG_SYS_I2C_SPEED, 0x7f, &i2c_pad_info1); #endif #ifdef CONFIG_FEC_MXC setup_fec(CONFIG_FEC_ENET_DEV); #endif #ifdef CONFIG_SYS_USE_NAND setup_gpmi_nand(); #endif #ifdef CONFIG_USB_EHCI_MX6 setup_usb(); #endif return 0; } #ifdef CONFIG_CMD_BMODE static const struct boot_mode board_boot_modes[] = { /* 4 bit bus width */ {"sd1", MAKE_CFGVAL(0x42, 0x20, 0x00, 0x00)}, {"sd2", MAKE_CFGVAL(0x40, 0x28, 0x00, 0x00)}, {NULL, 0}, }; #endif int board_late_init(void) { #ifdef CONFIG_CMD_BMODE add_board_boot_modes(board_boot_modes); #endif #ifdef CONFIG_ENV_IS_IN_MMC board_late_mmc_init(); #endif set_wdog_reset((struct wdog_regs *)WDOG1_BASE_ADDR); return 0; } u32 get_board_rev(void) { return get_cpu_rev(); } void version_detection(void) { setup_iomux_version_detection(); gpio_direction_input(VERSION_DET_DDR_SIZE); if (gpio_get_value(VERSION_DET_DDR_SIZE)) printf("DRAM size is 512MB \r\n"); else printf("DRAM size is 256MB \r\n"); } int checkboard(void) { version_detection(); puts("Board: PicoSOM i.mx6UL\n"); return 0; } #ifdef CONFIG_FSL_FASTBOOT void board_fastboot_setup(void) { switch (get_boot_device()) { #if defined(CONFIG_FASTBOOT_STORAGE_MMC) case SD1_BOOT: case MMC1_BOOT: if (!getenv("fastboot_dev")) setenv("fastboot_dev", "mmc0"); if (!getenv("bootcmd")) setenv("bootcmd", "boota mmc0"); break; case SD2_BOOT: case MMC2_BOOT: if (!getenv("fastboot_dev")) setenv("fastboot_dev", "mmc1"); if (!getenv("bootcmd")) setenv("bootcmd", "boota mmc1"); break; #endif /*CONFIG_FASTBOOT_STORAGE_MMC*/ #if defined(CONFIG_FASTBOOT_STORAGE_NAND) case NAND_BOOT: if (!getenv("fastboot_dev")) setenv("fastboot_dev", "nand"); if (!getenv("fbparts")) setenv("fbparts", ANDROID_FASTBOOT_NAND_PARTS); if (!getenv("bootcmd")) setenv("bootcmd", "nand read ${loadaddr} ${boot_nand_offset} " "${boot_nand_size};boota ${loadaddr}"); break; #endif /*CONFIG_FASTBOOT_STORAGE_NAND*/ default: printf("unsupported boot devices\n"); break; } } #ifdef CONFIG_ANDROID_RECOVERY int is_recovery_key_pressing(void) { /* No key defined for this board */ return 0; } void board_recovery_setup(void) { int bootdev = get_boot_device(); switch (bootdev) { #if defined(CONFIG_FASTBOOT_STORAGE_MMC) case SD1_BOOT: case MMC1_BOOT: if (!getenv("bootcmd_android_recovery")) setenv("bootcmd_android_recovery", "boota mmc0 recovery"); break; case SD2_BOOT: case MMC2_BOOT: if (!getenv("bootcmd_android_recovery")) setenv("bootcmd_android_recovery", "boota mmc1 recovery"); break; #endif /*CONFIG_FASTBOOT_STORAGE_MMC*/ #if defined(CONFIG_FASTBOOT_STORAGE_NAND) case NAND_BOOT: if (!getenv("bootcmd_android_recovery")) setenv("bootcmd_android_recovery", "nand read ${loadaddr} ${recovery_nand_offset} " "${recovery_nand_size};boota ${loadaddr}"); break; #endif /*CONFIG_FASTBOOT_STORAGE_NAND*/ default: printf("Unsupported bootup device for recovery: dev: %d\n", bootdev); return; } printf("setup env for recovery..\n"); setenv("bootcmd", "run bootcmd_android_recovery"); } #endif /*CONFIG_ANDROID_RECOVERY*/ #endif /*CONFIG_FSL_FASTBOOT*/