openwrt/target/linux/ar71xx/files/arch/mips/ath79/mach-rbspi.c

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/*
* MikroTik SPI-NOR RouterBOARDs support
*
ar71xx: complete support for RB mAP 2nD This patch adds support for the MikroTik RouterBOARD mAP 2nD https://mikrotik.com/product/RBmAP2nD Specifications: - SoC: Qualcomm QCA9531 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: builtin QCA9531, 2x2:2 - Ethernet: 2x100M (802.3af/at POE in and passive POE out on ETH2) - USB: microUSB type AB port This patch adds missing code to fully support mAP. Machfile already contained configuration for mAP 2nD, but device specific configuration like LEDs etc., was missing. Note: The POE LED works but doesn't turn on when POE passthrough is enabled, despite being configured with GPIO trigger. Installation 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-11-14 11:15:03 +00:00
* - MikroTik RouterBOARD mAP 2nD
* - MikroTik RouterBOARD mAP L-2nD
ar71xx: add support for the MikroTik RB911-2Hn/5Hn boards The patch adds support for the MikroTik RB911-2Hn (911 Lite2) and the RB911-5Hn (911 Lite5) boards: https://mikrotik.com/product/RB911-2Hn https://mikrotik.com/product/RB911-5Hn The two boards are using the same hardware design, the only difference between the two is the supported wireless band. Specifications: * SoC: Atheros AR9344 (600MHz) * RAM: 64MiB * Storage: 16 MiB SPI NOR flash * Ethernet: 1x100M (Passive PoE in) * Wireless: AR9344 built-in wireless MAC, single chain 802.11b/g/n (911-2Hn) or 802.11a/g/n (911-5Hn) Notes: * Older versions of these boards might be equipped with a NAND flash chip instead of the SPI NOR device. Those boards are not supported (yet). * The MikroTik RB911-5HnD (911 Lite5 Dual) board also uses the same hardware. Support for that can be added later with little effort probably. Installation: 1. Setup a DHCP/BOOTP Server with the following parameters: * DHCP-Option 66 (TFTP server name): pointing to a local TFTP server within the same subnet of the DHCP range * DHCP-Option 67 (Bootfile-Name): matching the initramfs filename of the to be booted image. The usable intramfs files are: - openwrt-ar71xx-mikrotik-vmlinux-initramfs.elf - openwrt-ar71xx-mikrotik-vmlinux-initramfs-lzma.elf - openwrt-ar71xx-mikrotik-rb-nor-flash-16M-initramfs-kernel.bin 2. Press the reset button on the board and keep that pressed. 3. Connect the board to your local network via its ethernet port. 4. Release the button after the LEDs on the board are turned off. Now the board should load and start the initramfs image from the TFTP server. 5. Upload the sysupgrade image to the board with scp: $ scp openwrt-ar71xx-mikrotik-rb-nor-flash-16M-squashfs-sysupgrade.bin root@192.168.1.1:/tmp/fw.bin 5. Log in to the running system listening on 192.168.1.1 via ssh as root (without password): $ ssh root@192.168.1.1 7. Flash the uploaded firmware file from the ssh session via the sysupgrade command: root@OpenWrt:~# sysupgrade /tmp/fw.bin Signed-off-by: Gabor Juhos <juhosg@freemail.hu>
2018-01-18 12:50:32 +00:00
* - MikroTik RouterBOARD 911-2Hn (911 Lite2)
* - MikroTik RouterBOARD 911-5Hn (911 Lite5)
* - MikroTik RouterBOARD 941L-2nD
* - MikroTik RouterBOARD 951Ui-2nD
* - MikroTik RouterBOARD 952Ui-5ac2nD
* - MikroTik RouterBOARD 962UiGS-5HacT2HnT
* - MikroTik RouterBOARD 750UP r2
* - MikroTik RouterBOARD 750P-PBr2
* - MikroTik RouterBOARD 750 r2
* - MikroTik RouterBOARD LHG 5nD
ar71xx: complete support for RB wAP 2nD This patch adds support for the MikroTik RouterBOARD wAP https://mikrotik.com/product/RBwAP2nD Specifications: - SoC: Qualcomm QCA9533 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: built-in QCA9533, 2x2:2 - Ethernet: 1x100M (802.3af/at POE in) This patch adds missing code to fully support wAP. Machfile already contained configuration for wAP 2nD but device specific configuration like LEDs etc. was missing. Installation: 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-10-28 10:30:39 +00:00
* - MikroTik RouterBOARD wAP2nD
* - MikroTik RouterBOARD wAP G-5HacT2HnDwAP (wAP AC)
*
* Preliminary support for the following hardware
* - MikroTik RouterBOARD cAP2nD
* Furthermore, the cAP lite (cAPL2nD) appears to feature the exact same
* hardware as the mAP L-2nD. It is unknown if they share the same board
* identifier.
*
* Copyright (C) 2017 Thibaut VARENE <varenet@parisc-linux.org>
* Copyright (C) 2016 David Hutchison <dhutchison@bluemesh.net>
* Copyright (C) 2017 Ryan Mounce <ryan@mounce.com.au>
*
* 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 <linux/pci.h>
#include <linux/platform_device.h>
#include <linux/phy.h>
#include <linux/routerboot.h>
#include <linux/gpio.h>
#include <linux/spi/spi.h>
#include <linux/spi/74x164.h>
#include <linux/mtd/mtd.h>
#include <linux/mtd/partitions.h>
#include <linux/ar8216_platform.h>
#include <linux/platform_data/phy-at803x.h>
#include <linux/platform_data/mdio-gpio.h>
#include <asm/prom.h>
#include <asm/mach-ath79/ar71xx_regs.h>
#include <asm/mach-ath79/ath79.h>
#include "common.h"
#include "dev-eth.h"
#include "dev-spi.h"
#include "dev-gpio-buttons.h"
#include "dev-leds-gpio.h"
#include "dev-m25p80.h"
#include "dev-usb.h"
#include "dev-wmac.h"
#include "machtypes.h"
#include "pci.h"
#include "routerboot.h"
#define RBSPI_KEYS_POLL_INTERVAL 20 /* msecs */
#define RBSPI_KEYS_DEBOUNCE_INTERVAL (3 * RBSPI_KEYS_POLL_INTERVAL)
#define RBSPI_HAS_USB BIT(0)
#define RBSPI_HAS_WLAN0 BIT(1)
#define RBSPI_HAS_WLAN1 BIT(2)
#define RBSPI_HAS_WAN4 BIT(3) /* has WAN port on PHY4 */
#define RBSPI_HAS_SSR BIT(4) /* has an SSR on SPI bus 0 */
#define RBSPI_HAS_POE BIT(5)
#define RBSPI_HAS_MDIO1 BIT(6)
#define RBSPI_HAS_PCI BIT(7)
#define RB_ROUTERBOOT_OFFSET 0x0000
#define RB_BIOS_SIZE 0x1000
#define RB_SOFT_CFG_SIZE 0x1000
/* Flash partitions indexes */
enum {
RBSPI_PART_RBOOT,
RBSPI_PART_HCONF,
RBSPI_PART_BIOS,
RBSPI_PART_RBOOT2,
RBSPI_PART_SCONF,
RBSPI_PART_FIRMW,
RBSPI_PARTS
};
static struct mtd_partition rbspi_spi_partitions[RBSPI_PARTS];
/*
* Setup the SPI flash partition table based on initial parsing.
* The kernel can be at any aligned position and have any size.
*/
static void __init rbspi_init_partitions(const struct rb_info *info)
{
struct mtd_partition *parts = rbspi_spi_partitions;
memset(parts, 0x0, sizeof(*parts));
parts[RBSPI_PART_RBOOT].name = "routerboot";
parts[RBSPI_PART_RBOOT].offset = RB_ROUTERBOOT_OFFSET;
parts[RBSPI_PART_RBOOT].size = info->hard_cfg_offs;
parts[RBSPI_PART_RBOOT].mask_flags = MTD_WRITEABLE;
parts[RBSPI_PART_HCONF].name = "hard_config";
parts[RBSPI_PART_HCONF].offset = info->hard_cfg_offs;
parts[RBSPI_PART_HCONF].size = info->hard_cfg_size;
parts[RBSPI_PART_HCONF].mask_flags = MTD_WRITEABLE;
parts[RBSPI_PART_BIOS].name = "bios";
parts[RBSPI_PART_BIOS].offset = info->hard_cfg_offs
+ info->hard_cfg_size;
parts[RBSPI_PART_BIOS].size = RB_BIOS_SIZE;
parts[RBSPI_PART_BIOS].mask_flags = MTD_WRITEABLE;
parts[RBSPI_PART_RBOOT2].name = "routerboot2";
parts[RBSPI_PART_RBOOT2].offset = parts[RBSPI_PART_BIOS].offset
+ RB_BIOS_SIZE;
parts[RBSPI_PART_RBOOT2].size = info->soft_cfg_offs
- parts[RBSPI_PART_RBOOT2].offset;
parts[RBSPI_PART_RBOOT2].mask_flags = MTD_WRITEABLE;
parts[RBSPI_PART_SCONF].name = "soft_config";
parts[RBSPI_PART_SCONF].offset = info->soft_cfg_offs;
parts[RBSPI_PART_SCONF].size = RB_SOFT_CFG_SIZE;
parts[RBSPI_PART_FIRMW].name = "firmware";
parts[RBSPI_PART_FIRMW].offset = parts[RBSPI_PART_SCONF].offset
+ parts[RBSPI_PART_SCONF].size;
parts[RBSPI_PART_FIRMW].size = MTDPART_SIZ_FULL;
}
static struct flash_platform_data rbspi_spi_flash_data = {
.parts = rbspi_spi_partitions,
.nr_parts = ARRAY_SIZE(rbspi_spi_partitions),
};
/*
* Several boards only have a single reset button, use a common
* structure for that.
*/
static struct gpio_keys_button rbspi_gpio_keys_reset[] __initdata = {
{
.desc = "Reset button",
.type = EV_KEY,
.code = KEY_RESTART,
.debounce_interval = RBSPI_KEYS_DEBOUNCE_INTERVAL,
.gpio = -ENOENT, /* filled dynamically */
.active_low = 1,
},
};
/* RB mAP L-2nD gpios */
#define RBMAPL_GPIO_LED_POWER 17
#define RBMAPL_GPIO_LED_USER 14
#define RBMAPL_GPIO_LED_ETH 4
#define RBMAPL_GPIO_LED_WLAN 11
#define RBMAPL_GPIO_BTN_RESET 16
static struct gpio_led rbmapl_leds[] __initdata = {
{
.name = "rb:green:power",
.gpio = RBMAPL_GPIO_LED_POWER,
.active_low = 0,
.default_state = LEDS_GPIO_DEFSTATE_ON,
}, {
.name = "rb:green:user",
.gpio = RBMAPL_GPIO_LED_USER,
.active_low = 0,
}, {
.name = "rb:green:eth",
.gpio = RBMAPL_GPIO_LED_ETH,
.active_low = 0,
}, {
.name = "rb:green:wlan",
.gpio = RBMAPL_GPIO_LED_WLAN,
.active_low = 0,
},
};
/* RB 941L-2nD gpios */
#define RBHAPL_GPIO_LED_USER 14
#define RBHAPL_GPIO_BTN_RESET 16
static struct gpio_led rbhapl_leds[] __initdata = {
{
.name = "rb:green:user",
.gpio = RBHAPL_GPIO_LED_USER,
.active_low = 1,
},
};
/* common RB SSRs */
#define RBSPI_SSR_GPIO_BASE 40
#define RBSPI_SSR_GPIO(bit) (RBSPI_SSR_GPIO_BASE + (bit))
/* RB 951Ui-2nD gpios */
#define RB952_SSR_BIT_LED_LAN1 0
#define RB952_SSR_BIT_LED_LAN2 1
#define RB952_SSR_BIT_LED_LAN3 2
#define RB952_SSR_BIT_LED_LAN4 3
#define RB952_SSR_BIT_LED_LAN5 4
#define RB952_SSR_BIT_USB_POWER 5
#define RB952_SSR_BIT_LED_WLAN 6
#define RB952_GPIO_SSR_CS 11
#define RB952_GPIO_LED_USER 4
#define RB952_GPIO_POE_POWER 14
#define RB952_GPIO_POE_STATUS 12
#define RB952_GPIO_BTN_RESET 16
#define RB952_GPIO_USB_POWER RBSPI_SSR_GPIO(RB952_SSR_BIT_USB_POWER)
#define RB952_GPIO_LED_LAN1 RBSPI_SSR_GPIO(RB952_SSR_BIT_LED_LAN1)
#define RB952_GPIO_LED_LAN2 RBSPI_SSR_GPIO(RB952_SSR_BIT_LED_LAN2)
#define RB952_GPIO_LED_LAN3 RBSPI_SSR_GPIO(RB952_SSR_BIT_LED_LAN3)
#define RB952_GPIO_LED_LAN4 RBSPI_SSR_GPIO(RB952_SSR_BIT_LED_LAN4)
#define RB952_GPIO_LED_LAN5 RBSPI_SSR_GPIO(RB952_SSR_BIT_LED_LAN5)
#define RB952_GPIO_LED_WLAN RBSPI_SSR_GPIO(RB952_SSR_BIT_LED_WLAN)
static struct gpio_led rb952_leds[] __initdata = {
{
.name = "rb:green:user",
.gpio = RB952_GPIO_LED_USER,
.active_low = 0,
}, {
.name = "rb:blue:wlan",
.gpio = RB952_GPIO_LED_WLAN,
.active_low = 1,
}, {
.name = "rb:green:port1",
.gpio = RB952_GPIO_LED_LAN1,
.active_low = 1,
}, {
.name = "rb:green:port2",
.gpio = RB952_GPIO_LED_LAN2,
.active_low = 1,
}, {
.name = "rb:green:port3",
.gpio = RB952_GPIO_LED_LAN3,
.active_low = 1,
}, {
.name = "rb:green:port4",
.gpio = RB952_GPIO_LED_LAN4,
.active_low = 1,
}, {
.name = "rb:green:port5",
.gpio = RB952_GPIO_LED_LAN5,
.active_low = 1,
},
};
/* RB 962UiGS-5HacT2HnT gpios */
#define RB962_GPIO_POE_STATUS 2
#define RB962_GPIO_POE_POWER 3
#define RB962_GPIO_LED_USER 12
#define RB962_GPIO_USB_POWER 13
#define RB962_GPIO_BTN_RESET 20
static struct gpio_led rb962_leds_gpio[] __initdata = {
{
.name = "rb:green:user",
.gpio = RB962_GPIO_LED_USER,
.active_low = 1,
},
};
static const struct ar8327_led_info rb962_leds_ar8327[] = {
AR8327_LED_INFO(PHY0_0, HW, "rb:green:port1"),
AR8327_LED_INFO(PHY1_0, HW, "rb:green:port2"),
AR8327_LED_INFO(PHY2_0, HW, "rb:green:port3"),
AR8327_LED_INFO(PHY3_0, HW, "rb:green:port4"),
AR8327_LED_INFO(PHY4_0, HW, "rb:green:port5"),
};
static struct ar8327_pad_cfg rb962_ar8327_pad0_cfg = {
.mode = AR8327_PAD_MAC_RGMII,
.txclk_delay_en = true,
.rxclk_delay_en = true,
.txclk_delay_sel = AR8327_CLK_DELAY_SEL1,
.rxclk_delay_sel = AR8327_CLK_DELAY_SEL2,
.mac06_exchange_dis = true,
};
static struct ar8327_pad_cfg rb962_ar8327_pad6_cfg = {
/* Use SGMII interface for GMAC6 of the AR8337 switch */
.mode = AR8327_PAD_MAC_SGMII,
.rxclk_delay_en = true,
.rxclk_delay_sel = AR8327_CLK_DELAY_SEL0,
};
static struct ar8327_led_cfg rb962_ar8327_led_cfg = {
.led_ctrl0 = 0xc737c737,
.led_ctrl1 = 0x00000000,
.led_ctrl2 = 0x00000000,
.led_ctrl3 = 0x0030c300,
.open_drain = false,
};
static struct ar8327_platform_data rb962_ar8327_data = {
.pad0_cfg = &rb962_ar8327_pad0_cfg,
.pad6_cfg = &rb962_ar8327_pad6_cfg,
.port0_cfg = {
.force_link = 1,
.speed = AR8327_PORT_SPEED_1000,
.duplex = 1,
.txpause = 1,
.rxpause = 1,
},
.port6_cfg = {
.force_link = 1,
.speed = AR8327_PORT_SPEED_1000,
.duplex = 1,
.txpause = 1,
.rxpause = 1,
},
.led_cfg = &rb962_ar8327_led_cfg,
.num_leds = ARRAY_SIZE(rb962_leds_ar8327),
.leds = rb962_leds_ar8327,
};
static struct mdio_board_info rb962_mdio0_info[] = {
{
.bus_id = "ag71xx-mdio.0",
.phy_addr = 0,
.platform_data = &rb962_ar8327_data,
},
};
/* RB wAP-2nD gpios */
#define RBWAP_GPIO_LED_USER 14
#define RBWAP_GPIO_LED_WLAN 11
#define RBWAP_GPIO_BTN_RESET 16
static struct gpio_led rbwap_leds[] __initdata = {
{
.name = "rb:green:user",
.gpio = RBWAP_GPIO_LED_USER,
.active_low = 1,
}, {
.name = "rb:green:wlan",
.gpio = RBWAP_GPIO_LED_WLAN,
.active_low = 1,
},
};
/* RB cAP-2nD gpios */
#define RBCAP_GPIO_LED_1 14
#define RBCAP_GPIO_LED_2 12
#define RBCAP_GPIO_LED_3 11
#define RBCAP_GPIO_LED_4 4
#define RBCAP_GPIO_LED_ALL 13
static struct gpio_led rbcap_leds[] __initdata = {
{
.name = "rb:green:rssi1",
.gpio = RBCAP_GPIO_LED_1,
.active_low = 1,
}, {
.name = "rb:green:rssi2",
.gpio = RBCAP_GPIO_LED_2,
.active_low = 1,
}, {
.name = "rb:green:rssi3",
.gpio = RBCAP_GPIO_LED_3,
.active_low = 1,
}, {
.name = "rb:green:rssi4",
.gpio = RBCAP_GPIO_LED_4,
.active_low = 1,
},
};
/* RB mAP-2nD gpios */
#define RBMAP_SSR_BIT_LED_LAN1 0
#define RBMAP_SSR_BIT_LED_LAN2 1
#define RBMAP_SSR_BIT_LED_POEO 2
#define RBMAP_SSR_BIT_LED_USER 3
#define RBMAP_SSR_BIT_LED_WLAN 4
#define RBMAP_SSR_BIT_USB_POWER 5
#define RBMAP_SSR_BIT_LED_APCAP 6
#define RBMAP_GPIO_BTN_RESET 16
#define RBMAP_GPIO_SSR_CS 11
#define RBMAP_GPIO_LED_POWER 4
#define RBMAP_GPIO_POE_POWER 14
#define RBMAP_GPIO_POE_STATUS 12
#define RBMAP_GPIO_USB_POWER RBSPI_SSR_GPIO(RBMAP_SSR_BIT_USB_POWER)
#define RBMAP_GPIO_LED_LAN1 RBSPI_SSR_GPIO(RBMAP_SSR_BIT_LED_LAN1)
#define RBMAP_GPIO_LED_LAN2 RBSPI_SSR_GPIO(RBMAP_SSR_BIT_LED_LAN2)
#define RBMAP_GPIO_LED_POEO RBSPI_SSR_GPIO(RBMAP_SSR_BIT_LED_POEO)
#define RBMAP_GPIO_LED_USER RBSPI_SSR_GPIO(RBMAP_SSR_BIT_LED_USER)
#define RBMAP_GPIO_LED_WLAN RBSPI_SSR_GPIO(RBMAP_SSR_BIT_LED_WLAN)
#define RBMAP_GPIO_LED_APCAP RBSPI_SSR_GPIO(RBMAP_SSR_BIT_LED_APCAP)
static struct gpio_led rbmap_leds[] __initdata = {
{
.name = "rb:green:power",
.gpio = RBMAP_GPIO_LED_POWER,
.active_low = 1,
.default_state = LEDS_GPIO_DEFSTATE_ON,
}, {
.name = "rb:green:eth1",
.gpio = RBMAP_GPIO_LED_LAN1,
.active_low = 1,
}, {
.name = "rb:green:eth2",
ar71xx: complete support for RB mAP 2nD This patch adds support for the MikroTik RouterBOARD mAP 2nD https://mikrotik.com/product/RBmAP2nD Specifications: - SoC: Qualcomm QCA9531 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: builtin QCA9531, 2x2:2 - Ethernet: 2x100M (802.3af/at POE in and passive POE out on ETH2) - USB: microUSB type AB port This patch adds missing code to fully support mAP. Machfile already contained configuration for mAP 2nD, but device specific configuration like LEDs etc., was missing. Note: The POE LED works but doesn't turn on when POE passthrough is enabled, despite being configured with GPIO trigger. Installation 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-11-14 11:15:03 +00:00
.gpio = RBMAP_GPIO_LED_LAN2,
.active_low = 1,
}, {
.name = "rb:red:poe_out",
.gpio = RBMAP_GPIO_LED_POEO,
.active_low = 1,
}, {
.name = "rb:green:user",
.gpio = RBMAP_GPIO_LED_USER,
.active_low = 1,
}, {
.name = "rb:green:wlan",
.gpio = RBMAP_GPIO_LED_WLAN,
.active_low = 1,
}, {
.name = "rb:green:ap_cap",
.gpio = RBMAP_GPIO_LED_APCAP,
.active_low = 1,
},
};
/* RB LHG 5nD gpios */
#define RBLHG_GPIO_LED_0 13
#define RBLHG_GPIO_LED_1 12
#define RBLHG_GPIO_LED_2 4
#define RBLHG_GPIO_LED_3 21
#define RBLHG_GPIO_LED_4 18
#define RBLHG_GPIO_LED_ETH 14
#define RBLHG_GPIO_LED_POWER 11
#define RBLHG_GPIO_LED_USER 20
#define RBLHG_GPIO_BTN_RESET 15
static struct gpio_led rblhg_leds[] __initdata = {
{
.name = "rb:green:rssi0",
.gpio = RBLHG_GPIO_LED_0,
.active_low = 1,
}, {
.name = "rb:green:rssi1",
.gpio = RBLHG_GPIO_LED_1,
.active_low = 1,
}, {
.name = "rb:green:rssi2",
.gpio = RBLHG_GPIO_LED_2,
.active_low = 1,
}, {
.name = "rb:green:rssi3",
.gpio = RBLHG_GPIO_LED_3,
.active_low = 1,
}, {
.name = "rb:green:rssi4",
.gpio = RBLHG_GPIO_LED_4,
.active_low = 1,
}, {
.name = "rb:green:eth",
.gpio = RBLHG_GPIO_LED_ETH,
.active_low = 1,
}, {
.name = "rb:green:user",
.gpio = RBLHG_GPIO_LED_USER,
.active_low = 1,
}, {
.name = "rb:blue:power",
.gpio = RBLHG_GPIO_LED_POWER,
.active_low = 0,
.default_state = LEDS_GPIO_DEFSTATE_ON,
},
};
/* RB w APG-5HacT2HnD (wAP AC) gpios*/
#define RBWAPGSC_LED1 1
#define RBWAPGSC_LED2 8
#define RBWAPGSC_LED3 9
#define RBWAPGSC_POWERLED 16
#define RBWAPGSC_GPIO_BTN_RESET 1
#define RBWAPGSC_GPIO_MDIO_MDC 12
#define RBWAPGSC_GPIO_MDIO_DATA 11
#define RBWAPGSC_MDIO_PHYADDR 0
static struct gpio_led rbwapgsc_leds[] __initdata = {
{
.name = "rb:green:led1",
.gpio = RBWAPGSC_LED1,
.active_low = 1,
},{
.name = "rb:blue:power",
.gpio = RBWAPGSC_POWERLED,
.active_low = 1,
},
};
static struct mdio_gpio_platform_data rbwapgsc_mdio_data = {
.mdc = RBWAPGSC_GPIO_MDIO_MDC,
.mdio = RBWAPGSC_GPIO_MDIO_DATA,
.phy_mask = ~BIT(RBWAPGSC_MDIO_PHYADDR),
};
static struct platform_device rbwapgsc_phy_device = {
.name = "mdio-gpio",
.id = 1,
.dev = {
.platform_data = &rbwapgsc_mdio_data
},
};
ar71xx: add support for the MikroTik RB911-2Hn/5Hn boards The patch adds support for the MikroTik RB911-2Hn (911 Lite2) and the RB911-5Hn (911 Lite5) boards: https://mikrotik.com/product/RB911-2Hn https://mikrotik.com/product/RB911-5Hn The two boards are using the same hardware design, the only difference between the two is the supported wireless band. Specifications: * SoC: Atheros AR9344 (600MHz) * RAM: 64MiB * Storage: 16 MiB SPI NOR flash * Ethernet: 1x100M (Passive PoE in) * Wireless: AR9344 built-in wireless MAC, single chain 802.11b/g/n (911-2Hn) or 802.11a/g/n (911-5Hn) Notes: * Older versions of these boards might be equipped with a NAND flash chip instead of the SPI NOR device. Those boards are not supported (yet). * The MikroTik RB911-5HnD (911 Lite5 Dual) board also uses the same hardware. Support for that can be added later with little effort probably. Installation: 1. Setup a DHCP/BOOTP Server with the following parameters: * DHCP-Option 66 (TFTP server name): pointing to a local TFTP server within the same subnet of the DHCP range * DHCP-Option 67 (Bootfile-Name): matching the initramfs filename of the to be booted image. The usable intramfs files are: - openwrt-ar71xx-mikrotik-vmlinux-initramfs.elf - openwrt-ar71xx-mikrotik-vmlinux-initramfs-lzma.elf - openwrt-ar71xx-mikrotik-rb-nor-flash-16M-initramfs-kernel.bin 2. Press the reset button on the board and keep that pressed. 3. Connect the board to your local network via its ethernet port. 4. Release the button after the LEDs on the board are turned off. Now the board should load and start the initramfs image from the TFTP server. 5. Upload the sysupgrade image to the board with scp: $ scp openwrt-ar71xx-mikrotik-rb-nor-flash-16M-squashfs-sysupgrade.bin root@192.168.1.1:/tmp/fw.bin 5. Log in to the running system listening on 192.168.1.1 via ssh as root (without password): $ ssh root@192.168.1.1 7. Flash the uploaded firmware file from the ssh session via the sysupgrade command: root@OpenWrt:~# sysupgrade /tmp/fw.bin Signed-off-by: Gabor Juhos <juhosg@freemail.hu>
2018-01-18 12:50:32 +00:00
/* RB911L GPIOs */
#define RB911L_GPIO_BTN_RESET 15
#define RB911L_GPIO_LED_1 13
#define RB911L_GPIO_LED_2 12
#define RB911L_GPIO_LED_3 4
#define RB911L_GPIO_LED_4 21
#define RB911L_GPIO_LED_5 18
#define RB911L_GPIO_LED_ETH 20
#define RB911L_GPIO_LED_POWER 11
#define RB911L_GPIO_LED_USER 3
#define RB911L_GPIO_PIN_HOLE 14 /* for reference */
static struct gpio_led rb911l_leds[] __initdata = {
{
.name = "rb:green:eth",
.gpio = RB911L_GPIO_LED_ETH,
.active_low = 1,
}, {
.name = "rb:green:led1",
.gpio = RB911L_GPIO_LED_1,
.active_low = 1,
}, {
.name = "rb:green:led2",
.gpio = RB911L_GPIO_LED_2,
.active_low = 1,
}, {
.name = "rb:green:led3",
.gpio = RB911L_GPIO_LED_3,
.active_low = 1,
}, {
.name = "rb:green:led4",
.gpio = RB911L_GPIO_LED_4,
.active_low = 1,
}, {
.name = "rb:green:led5",
.gpio = RB911L_GPIO_LED_5,
.active_low = 1,
}, {
.name = "rb:green:power",
.gpio = RB911L_GPIO_LED_POWER,
.default_state = LEDS_GPIO_DEFSTATE_ON,
.open_drain = 1,
}, {
.name = "rb:green:user",
.gpio = RB911L_GPIO_LED_USER,
.active_low = 1,
.open_drain = 1,
},
};
static struct gen_74x164_chip_platform_data rbspi_ssr_data = {
.base = RBSPI_SSR_GPIO_BASE,
.num_registers = 1,
};
/* the spi-ath79 driver can only natively handle CS0. Other CS are bit-banged */
static int rbspi_spi_cs_gpios[] = {
-ENOENT, /* CS0 is always -ENOENT: natively handled */
-ENOENT, /* CS1 can be updated by the code as necessary */
};
static struct ath79_spi_platform_data rbspi_ath79_spi_data = {
.bus_num = 0,
.cs_gpios = rbspi_spi_cs_gpios,
};
/*
* Global spi_board_info: devices that don't have an SSR only have the SPI NOR
* flash on bus0 CS0, while devices that have an SSR add it on the same bus CS1
*/
static struct spi_board_info rbspi_spi_info[] = {
{
.bus_num = 0,
.chip_select = 0,
.max_speed_hz = 25000000,
.modalias = "m25p80",
.platform_data = &rbspi_spi_flash_data,
}, {
.bus_num = 0,
.chip_select = 1,
.max_speed_hz = 25000000,
.modalias = "74x164",
.platform_data = &rbspi_ssr_data,
}
};
void __init rbspi_wlan_init(u16 id, int wmac_offset)
{
char *art_buf;
u8 wlan_mac[ETH_ALEN];
art_buf = rb_get_ext_wlan_data(id);
if (!art_buf)
return;
ath79_init_mac(wlan_mac, ath79_mac_base, wmac_offset);
ath79_register_wmac(art_buf + 0x1000, wlan_mac);
kfree(art_buf);
}
#define RBSPI_MACH_BUFLEN 64
/*
* Common platform init routine for all SPI NOR devices.
*/
static __init const struct rb_info *rbspi_platform_setup(void)
{
const struct rb_info *info;
char buf[RBSPI_MACH_BUFLEN] = "MikroTik ";
char *str;
int len = RBSPI_MACH_BUFLEN - strlen(buf) - 1;
info = rb_init_info((void *)(KSEG1ADDR(AR71XX_SPI_BASE)), 0x20000);
if (!info)
return NULL;
if (info->board_name) {
str = "RouterBOARD ";
if (strncmp(info->board_name, str, strlen(str))) {
strncat(buf, str, len);
len -= strlen(str);
}
strncat(buf, info->board_name, len);
}
else
strncat(buf, "UNKNOWN", len);
mips_set_machine_name(buf);
/* fix partitions based on flash parsing */
rbspi_init_partitions(info);
return info;
}
/*
* Common peripherals init routine for all SPI NOR devices.
* Sets SPI and USB.
*/
static void __init rbspi_peripherals_setup(u32 flags)
{
unsigned spi_n;
if (flags & RBSPI_HAS_SSR)
spi_n = ARRAY_SIZE(rbspi_spi_info);
else
spi_n = 1; /* only one device on bus0 */
rbspi_ath79_spi_data.num_chipselect = spi_n;
rbspi_ath79_spi_data.cs_gpios = rbspi_spi_cs_gpios;
ath79_register_spi(&rbspi_ath79_spi_data, rbspi_spi_info, spi_n);
if (flags & RBSPI_HAS_USB)
ath79_register_usb();
if (flags & RBSPI_HAS_PCI)
ath79_register_pci();
}
/*
* Common network init routine for all SPI NOR devices.
* Sets LAN/WAN/WLAN.
*/
static void __init rbspi_network_setup(u32 flags, int gmac1_offset,
int wmac0_offset, int wmac1_offset)
{
/* for QCA953x that will init mdio1_device/data */
ath79_register_mdio(0, 0x0);
if (flags & RBSPI_HAS_MDIO1)
ath79_register_mdio(1, 0x0);
if (flags & RBSPI_HAS_WAN4) {
ath79_setup_ar934x_eth_cfg(0);
/* set switch to oper mode 1, PHY4 connected to CPU */
ath79_switch_data.phy4_mii_en = 1;
ath79_switch_data.phy_poll_mask |= BIT(4);
/* init GMAC0 connected to PHY4 at 100M */
ath79_eth0_data.phy_if_mode = PHY_INTERFACE_MODE_MII;
ath79_eth0_data.phy_mask = BIT(4);
ath79_init_mac(ath79_eth0_data.mac_addr, ath79_mac_base, 0);
ath79_register_eth(0);
} else {
/* set the SoC to SW_ONLY_MODE, which connects all PHYs
* to the internal switch.
* We hijack ath79_setup_ar934x_eth_cfg() to set the switch in
* the QCA953x, this works because this configuration bit is
* the same as the AR934x. There's no equivalent function for
* QCA953x for now. */
ath79_setup_ar934x_eth_cfg(AR934X_ETH_CFG_SW_ONLY_MODE);
}
/* init GMAC1 */
ath79_init_mac(ath79_eth1_data.mac_addr, ath79_mac_base, gmac1_offset);
ath79_eth1_data.phy_if_mode = PHY_INTERFACE_MODE_GMII;
ath79_register_eth(1);
if (flags & RBSPI_HAS_WLAN0)
rbspi_wlan_init(0, wmac0_offset);
if (flags & RBSPI_HAS_WLAN1)
rbspi_wlan_init(1, wmac1_offset);
}
static __init void rbspi_register_reset_button(int gpio)
{
rbspi_gpio_keys_reset[0].gpio = gpio;
ath79_register_gpio_keys_polled(-1, RBSPI_KEYS_POLL_INTERVAL,
ARRAY_SIZE(rbspi_gpio_keys_reset),
rbspi_gpio_keys_reset);
}
/*
* Init the mAP lite hardware (QCA953x).
* The mAP L-2nD (mAP lite) has a single ethernet port, connected to PHY0.
* Trying to use GMAC0 in direct mode was unsucessful, so we're
* using SW_ONLY_MODE, which connects PHY0 to MAC1 on the internal
* switch, which is connected to GMAC1 on the SoC. GMAC0 is unused.
*/
static void __init rbmapl_setup(void)
{
u32 flags = RBSPI_HAS_WLAN0;
if (!rbspi_platform_setup())
return;
rbspi_peripherals_setup(flags);
/* GMAC1 is HW MAC, WLAN0 MAC is HW MAC + 1 */
rbspi_network_setup(flags, 0, 1, 0);
ath79_register_leds_gpio(-1, ARRAY_SIZE(rbmapl_leds), rbmapl_leds);
/* mAP lite has a single reset button as gpio 16 */
rbspi_register_reset_button(RBMAPL_GPIO_BTN_RESET);
/* clear internal multiplexing */
ath79_gpio_output_select(RBMAPL_GPIO_LED_ETH, AR934X_GPIO_OUT_GPIO);
ath79_gpio_output_select(RBMAPL_GPIO_LED_POWER, AR934X_GPIO_OUT_GPIO);
}
/*
* Init the hAP lite hardware (QCA953x).
* The 941-2nD (hAP lite) has 4 ethernet ports, with port 2-4
* being assigned to LAN on the casing, and port 1 being assigned
* to "internet" (WAN) on the casing. Port 1 is connected to PHY3.
* Since WAN is neither PHY0 nor PHY4, we cannot use GMAC0 with this device.
*/
static void __init rbhapl_setup(void)
{
u32 flags = RBSPI_HAS_WLAN0;
if (!rbspi_platform_setup())
return;
rbspi_peripherals_setup(flags);
/* GMAC1 is HW MAC, WLAN0 MAC is HW MAC + 4 */
rbspi_network_setup(flags, 0, 4, 0);
ath79_register_leds_gpio(-1, ARRAY_SIZE(rbhapl_leds), rbhapl_leds);
/* hAP lite has a single reset button as gpio 16 */
rbspi_register_reset_button(RBHAPL_GPIO_BTN_RESET);
}
/*
* The hAP, hAP ac lite, hEX lite and hEX PoE lite share the same platform
*/
static void __init rbspi_952_750r2_setup(u32 flags)
{
if (flags & RBSPI_HAS_SSR)
rbspi_spi_cs_gpios[1] = RB952_GPIO_SSR_CS;
rbspi_peripherals_setup(flags);
/*
* GMAC1 is HW MAC + 1, WLAN0 MAC IS HW MAC + 5 (hAP),
* WLAN1 MAC IS HW MAC + 6 (hAP ac lite)
*/
rbspi_network_setup(flags, 1, 5, 6);
if (flags & RBSPI_HAS_USB)
gpio_request_one(RB952_GPIO_USB_POWER,
GPIOF_OUT_INIT_HIGH | GPIOF_EXPORT_DIR_FIXED,
"USB power");
if (flags & RBSPI_HAS_POE)
gpio_request_one(RB952_GPIO_POE_POWER,
GPIOF_OUT_INIT_HIGH | GPIOF_EXPORT_DIR_FIXED,
"POE power");
ath79_register_leds_gpio(-1, ARRAY_SIZE(rb952_leds), rb952_leds);
/* These devices have a single reset button as gpio 16 */
rbspi_register_reset_button(RB952_GPIO_BTN_RESET);
}
/*
* Init the hAP (ac lite) hardware (QCA953x).
* The 951Ui-2nD (hAP) has 5 ethernet ports, with ports 2-5 being assigned
* to LAN on the casing, and port 1 being assigned to "internet" (WAN).
* Port 1 is connected to PHY4 (the ports are labelled in reverse physical
* number), so the SoC can be set to connect GMAC0 to PHY4 and GMAC1 to the
* internal switch for the LAN ports.
* The device also has USB, PoE output and an SSR used for LED multiplexing.
* The 952Ui-5ac2nD (hAP ac lite) is nearly identical to the hAP, it adds a
* QCA9887 5GHz radio via PCI and moves 2.4GHz from WLAN0 to WLAN1.
*/
static void __init rb952_setup(void)
{
u32 flags = RBSPI_HAS_WAN4 | RBSPI_HAS_USB |
RBSPI_HAS_SSR | RBSPI_HAS_POE;
if (!rbspi_platform_setup())
return;
/* differentiate the hAP from the hAP ac lite */
if (strstr(mips_get_machine_name(), "952Ui-5ac2nD"))
flags |= RBSPI_HAS_WLAN1 | RBSPI_HAS_PCI;
else
flags |= RBSPI_HAS_WLAN0;
rbspi_952_750r2_setup(flags);
}
/*
* Init the hEX (PoE) lite hardware (QCA953x).
* The 750UP r2 (hEX PoE lite) is nearly identical to the hAP, only without
* WLAN. The 750 r2 (hEX lite) is nearly identical to the 750UP r2, only
* without USB and POE. The 750P Pbr2 (Powerbox) is nearly identical to hEX PoE
* lite, only without USB. It shares the same bootloader board identifier.
*/
static void __init rb750upr2_setup(void)
{
u32 flags = RBSPI_HAS_WAN4 | RBSPI_HAS_SSR;
if (!rbspi_platform_setup())
return;
/* differentiate the hEX lite from the hEX PoE lite */
if (strstr(mips_get_machine_name(), "750UP r2"))
flags |= RBSPI_HAS_USB | RBSPI_HAS_POE;
/* differentiate the Powerbox from the hEX lite */
else if (strstr(mips_get_machine_name(), "750P r2"))
flags |= RBSPI_HAS_POE;
rbspi_952_750r2_setup(flags);
}
/*
* Init the hAP ac / 962UiGS-5HacT2HnT hardware (QCA9558).
* The hAP ac has 5 ethernet ports provided by an AR8337 switch. Port 1 is
* assigned to WAN, ports 2-5 are assigned to LAN. Port 0 is connected to the
* SoC, ports 1-5 of the switch are connected to physical ports 1-5 in order.
* The SFP cage is not assigned by default on RouterOS. Extra work is required
* to support this interface as it is directly connected to the SoC (eth1).
* Wireless is provided by a 2.4GHz radio on the SoC (WLAN1) and a 5GHz radio
* attached via PCI (QCA9880). Red and green WLAN LEDs are populated however
* they are not attached to GPIOs, extra work is required to support these.
* PoE and USB output power control is supported.
*/
static void __init rb962_setup(void)
{
u32 flags = RBSPI_HAS_USB | RBSPI_HAS_POE | RBSPI_HAS_PCI;
if (!rbspi_platform_setup())
return;
rbspi_peripherals_setup(flags);
/* Do not call rbspi_network_setup as we have a discrete switch chip */
ath79_eth0_pll_data.pll_1000 = 0xae000000;
ath79_eth0_pll_data.pll_100 = 0xa0000101;
ath79_eth0_pll_data.pll_10 = 0xa0001313;
ath79_register_mdio(0, 0x0);
mdiobus_register_board_info(rb962_mdio0_info,
ARRAY_SIZE(rb962_mdio0_info));
ath79_setup_qca955x_eth_cfg(QCA955X_ETH_CFG_RGMII_EN);
ath79_init_mac(ath79_eth0_data.mac_addr, ath79_mac_base, 0);
ath79_eth0_data.phy_if_mode = PHY_INTERFACE_MODE_RGMII;
ath79_eth0_data.phy_mask = BIT(0);
ath79_eth0_data.mii_bus_dev = &ath79_mdio0_device.dev;
ath79_register_eth(0);
/* WLAN1 MAC is HW MAC + 7 */
rbspi_wlan_init(1, 7);
if (flags & RBSPI_HAS_USB)
gpio_request_one(RB962_GPIO_USB_POWER,
GPIOF_OUT_INIT_HIGH | GPIOF_EXPORT_DIR_FIXED,
"USB power");
/* PoE output GPIO is inverted, set GPIOF_ACTIVE_LOW for consistency */
if (flags & RBSPI_HAS_POE)
gpio_request_one(RB962_GPIO_POE_POWER,
GPIOF_OUT_INIT_HIGH | GPIOF_ACTIVE_LOW |
GPIOF_EXPORT_DIR_FIXED,
"POE power");
ath79_register_leds_gpio(-1, ARRAY_SIZE(rb962_leds_gpio),
rb962_leds_gpio);
/* This device has a single reset button as gpio 20 */
rbspi_register_reset_button(RB962_GPIO_BTN_RESET);
}
/*
* Init the LHG hardware (AR9344).
* The LHG 5nD has a single ethernet port connected to PHY0.
* Wireless is provided via 5GHz WLAN1.
*/
static void __init rblhg_setup(void)
{
u32 flags = RBSPI_HAS_WLAN1 | RBSPI_HAS_MDIO1;
if (!rbspi_platform_setup())
return;
rbspi_peripherals_setup(flags);
/* GMAC1 is HW MAC, WLAN1 MAC is HW MAC + 1 */
rbspi_network_setup(flags, 0, 0, 1);
ath79_register_leds_gpio(-1, ARRAY_SIZE(rblhg_leds), rblhg_leds);
rbspi_register_reset_button(RBLHG_GPIO_BTN_RESET);
}
/*
ar71xx: complete support for RB wAP 2nD This patch adds support for the MikroTik RouterBOARD wAP https://mikrotik.com/product/RBwAP2nD Specifications: - SoC: Qualcomm QCA9533 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: built-in QCA9533, 2x2:2 - Ethernet: 1x100M (802.3af/at POE in) This patch adds missing code to fully support wAP. Machfile already contained configuration for wAP 2nD but device specific configuration like LEDs etc. was missing. Installation: 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-10-28 10:30:39 +00:00
* Init the wAP hardware.
* The wAP 2nD has a single ethernet port.
*/
static void __init rbwap_setup(void)
{
u32 flags = RBSPI_HAS_WLAN0;
if (!rbspi_platform_setup())
return;
rbspi_peripherals_setup(flags);
/* GMAC1 is HW MAC, WLAN0 MAC is HW MAC + 1 */
rbspi_network_setup(flags, 0, 1, 0);
ath79_register_leds_gpio(-1, ARRAY_SIZE(rbwap_leds), rbwap_leds);
ar71xx: complete support for RB wAP 2nD This patch adds support for the MikroTik RouterBOARD wAP https://mikrotik.com/product/RBwAP2nD Specifications: - SoC: Qualcomm QCA9533 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: built-in QCA9533, 2x2:2 - Ethernet: 1x100M (802.3af/at POE in) This patch adds missing code to fully support wAP. Machfile already contained configuration for wAP 2nD but device specific configuration like LEDs etc. was missing. Installation: 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-10-28 10:30:39 +00:00
/* wAP has a single reset button as GPIO 16 */
rbspi_register_reset_button(RBWAP_GPIO_BTN_RESET);
}
/*
* Init the cAP hardware (EXPERIMENTAL).
* The cAP 2nD has a single ethernet port, and a global LED switch.
*/
static void __init rbcap_setup(void)
{
u32 flags = RBSPI_HAS_WLAN0;
if (!rbspi_platform_setup())
return;
rbspi_peripherals_setup(flags);
/* GMAC1 is HW MAC, WLAN0 MAC is HW MAC + 1 */
rbspi_network_setup(flags, 0, 1, 0);
gpio_request_one(RBCAP_GPIO_LED_ALL,
GPIOF_OUT_INIT_HIGH | GPIOF_EXPORT_DIR_FIXED,
"LEDs enable");
ath79_register_leds_gpio(-1, ARRAY_SIZE(rbcap_leds), rbcap_leds);
}
/*
ar71xx: complete support for RB mAP 2nD This patch adds support for the MikroTik RouterBOARD mAP 2nD https://mikrotik.com/product/RBmAP2nD Specifications: - SoC: Qualcomm QCA9531 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: builtin QCA9531, 2x2:2 - Ethernet: 2x100M (802.3af/at POE in and passive POE out on ETH2) - USB: microUSB type AB port This patch adds missing code to fully support mAP. Machfile already contained configuration for mAP 2nD, but device specific configuration like LEDs etc., was missing. Note: The POE LED works but doesn't turn on when POE passthrough is enabled, despite being configured with GPIO trigger. Installation 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-11-14 11:15:03 +00:00
* Init the mAP hardware.
* The mAP 2nD has two ethernet ports, PoE output, SSR for LED
* multiplexing and USB port.
*/
static void __init rbmap_setup(void)
{
ar71xx: complete support for RB mAP 2nD This patch adds support for the MikroTik RouterBOARD mAP 2nD https://mikrotik.com/product/RBmAP2nD Specifications: - SoC: Qualcomm QCA9531 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: builtin QCA9531, 2x2:2 - Ethernet: 2x100M (802.3af/at POE in and passive POE out on ETH2) - USB: microUSB type AB port This patch adds missing code to fully support mAP. Machfile already contained configuration for mAP 2nD, but device specific configuration like LEDs etc., was missing. Note: The POE LED works but doesn't turn on when POE passthrough is enabled, despite being configured with GPIO trigger. Installation 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-11-14 11:15:03 +00:00
u32 flags = RBSPI_HAS_USB | RBSPI_HAS_WLAN0 |
RBSPI_HAS_SSR | RBSPI_HAS_POE;
if (!rbspi_platform_setup())
return;
rbspi_spi_cs_gpios[1] = RBMAP_GPIO_SSR_CS;
rbspi_peripherals_setup(flags);
/* GMAC1 is HW MAC, WLAN0 MAC is HW MAC + 2 */
rbspi_network_setup(flags, 0, 2, 0);
if (flags & RBSPI_HAS_POE)
gpio_request_one(RBMAP_GPIO_POE_POWER,
ar71xx: complete support for RB mAP 2nD This patch adds support for the MikroTik RouterBOARD mAP 2nD https://mikrotik.com/product/RBmAP2nD Specifications: - SoC: Qualcomm QCA9531 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: builtin QCA9531, 2x2:2 - Ethernet: 2x100M (802.3af/at POE in and passive POE out on ETH2) - USB: microUSB type AB port This patch adds missing code to fully support mAP. Machfile already contained configuration for mAP 2nD, but device specific configuration like LEDs etc., was missing. Note: The POE LED works but doesn't turn on when POE passthrough is enabled, despite being configured with GPIO trigger. Installation 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-11-14 11:15:03 +00:00
GPIOF_OUT_INIT_LOW | GPIOF_EXPORT_DIR_FIXED,
"POE power");
ar71xx: complete support for RB mAP 2nD This patch adds support for the MikroTik RouterBOARD mAP 2nD https://mikrotik.com/product/RBmAP2nD Specifications: - SoC: Qualcomm QCA9531 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: builtin QCA9531, 2x2:2 - Ethernet: 2x100M (802.3af/at POE in and passive POE out on ETH2) - USB: microUSB type AB port This patch adds missing code to fully support mAP. Machfile already contained configuration for mAP 2nD, but device specific configuration like LEDs etc., was missing. Note: The POE LED works but doesn't turn on when POE passthrough is enabled, despite being configured with GPIO trigger. Installation 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-11-14 11:15:03 +00:00
/* USB power GPIO is inverted, set GPIOF_ACTIVE_LOW for consistency */
if (flags & RBSPI_HAS_USB)
gpio_request_one(RBMAP_GPIO_USB_POWER,
GPIOF_OUT_INIT_HIGH | GPIOF_ACTIVE_LOW |
GPIOF_EXPORT_DIR_FIXED,
"USB power");
ath79_register_leds_gpio(-1, ARRAY_SIZE(rbmap_leds), rbmap_leds);
ar71xx: complete support for RB mAP 2nD This patch adds support for the MikroTik RouterBOARD mAP 2nD https://mikrotik.com/product/RBmAP2nD Specifications: - SoC: Qualcomm QCA9531 (650 MHz) - RAM: 64 MB - Storage: 16 MB NOR SPI flash - Wireless: builtin QCA9531, 2x2:2 - Ethernet: 2x100M (802.3af/at POE in and passive POE out on ETH2) - USB: microUSB type AB port This patch adds missing code to fully support mAP. Machfile already contained configuration for mAP 2nD, but device specific configuration like LEDs etc., was missing. Note: The POE LED works but doesn't turn on when POE passthrough is enabled, despite being configured with GPIO trigger. Installation 1. Login to the Mikrotik WebUI to backup your licence keys 2. Setup a DHCP/BOOTP server with: - DHCP-Option 66 (TFTP server name) pointing to a local TFTP server within the same subnet of the DHCP range - DHCP-Option 67 (Bootfile-Name) matching the initramfs filename of the to be booted image 3. Connect the port labeled internet to your local network 4. Keep the reset button pushed down and power on the board The board should load and start the initramfs image from the TFTP server. Login as root/without password to the started LEDE via SSH listing on IPv4 address 192.168.1.1. Use sysupgrade to install LEDE. Revert to RouterOS Use the "rbcfg" package on in LEDE: - rbcfg set boot_protocol bootp - rbcfg set boot_device ethnand - rbcfg apply Open Netinstall and reboot routerboard. Now Netinstall sees RouterBOARD and you can install RouterOS. If NetInstall gets stuck on Sending offer just wait for it to timeout and then close and open Netinstall again. Click on install again. In order for RouterOS to function properly, you need to restore license for the device. You can do that by including license in NetInstall. Signed-off-by: Robert Marko <robimarko@gmail.com>
2017-11-14 11:15:03 +00:00
/* mAP 2nD has a single reset button as gpio 16 */
rbspi_register_reset_button(RBMAP_GPIO_BTN_RESET);
}
/*
* Init the wAPGSC (RB wAPG-5HacT2HnD // wAP AC) hardware.
* The wAPGSC has one Ethernet port via AR8033 with PoE input, dual radio (SoC
* 2.4 GHz and external QCA9880) and a ZT2046Q temperature and voltage sensor
* (currently not supported).
*/
static void __init rbwapgsc_setup(void)
{
u32 flags = RBSPI_HAS_PCI;
if (!rbspi_platform_setup())
return;
rbspi_peripherals_setup(flags);
platform_device_register(&rbwapgsc_phy_device);
ath79_init_mac(ath79_eth1_data.mac_addr, ath79_mac_base, 0);
ath79_eth1_data.mii_bus_dev = &rbwapgsc_phy_device.dev;
ath79_eth1_data.phy_if_mode = PHY_INTERFACE_MODE_SGMII;
ath79_eth1_data.phy_mask = BIT(RBWAPGSC_MDIO_PHYADDR);
ath79_eth1_pll_data.pll_1000 = 0x03000101;
ath79_eth1_pll_data.pll_100 = 0x80000101;
ath79_eth1_pll_data.pll_10 = 0x80001313;
ath79_eth1_data.speed = SPEED_1000;
ath79_eth1_data.duplex = DUPLEX_FULL;
ath79_register_eth(1);
rbspi_wlan_init(1, 2);
rbspi_register_reset_button(RBWAPGSC_GPIO_BTN_RESET);
ath79_gpio_function_enable(QCA955X_GPIO_FUNC_JTAG_DISABLE|
QCA955X_GPIO_REG_OUT_FUNC4|
QCA955X_GPIO_REG_OUT_FUNC3);
ath79_register_leds_gpio(-1, ARRAY_SIZE(rbwapgsc_leds),
rbwapgsc_leds);
}
ar71xx: add support for the MikroTik RB911-2Hn/5Hn boards The patch adds support for the MikroTik RB911-2Hn (911 Lite2) and the RB911-5Hn (911 Lite5) boards: https://mikrotik.com/product/RB911-2Hn https://mikrotik.com/product/RB911-5Hn The two boards are using the same hardware design, the only difference between the two is the supported wireless band. Specifications: * SoC: Atheros AR9344 (600MHz) * RAM: 64MiB * Storage: 16 MiB SPI NOR flash * Ethernet: 1x100M (Passive PoE in) * Wireless: AR9344 built-in wireless MAC, single chain 802.11b/g/n (911-2Hn) or 802.11a/g/n (911-5Hn) Notes: * Older versions of these boards might be equipped with a NAND flash chip instead of the SPI NOR device. Those boards are not supported (yet). * The MikroTik RB911-5HnD (911 Lite5 Dual) board also uses the same hardware. Support for that can be added later with little effort probably. Installation: 1. Setup a DHCP/BOOTP Server with the following parameters: * DHCP-Option 66 (TFTP server name): pointing to a local TFTP server within the same subnet of the DHCP range * DHCP-Option 67 (Bootfile-Name): matching the initramfs filename of the to be booted image. The usable intramfs files are: - openwrt-ar71xx-mikrotik-vmlinux-initramfs.elf - openwrt-ar71xx-mikrotik-vmlinux-initramfs-lzma.elf - openwrt-ar71xx-mikrotik-rb-nor-flash-16M-initramfs-kernel.bin 2. Press the reset button on the board and keep that pressed. 3. Connect the board to your local network via its ethernet port. 4. Release the button after the LEDs on the board are turned off. Now the board should load and start the initramfs image from the TFTP server. 5. Upload the sysupgrade image to the board with scp: $ scp openwrt-ar71xx-mikrotik-rb-nor-flash-16M-squashfs-sysupgrade.bin root@192.168.1.1:/tmp/fw.bin 5. Log in to the running system listening on 192.168.1.1 via ssh as root (without password): $ ssh root@192.168.1.1 7. Flash the uploaded firmware file from the ssh session via the sysupgrade command: root@OpenWrt:~# sysupgrade /tmp/fw.bin Signed-off-by: Gabor Juhos <juhosg@freemail.hu>
2018-01-18 12:50:32 +00:00
/*
* Setup the 911L hardware (AR9344).
*/
static void __init rb911l_setup(void)
{
const struct rb_info *info;
info = rbspi_platform_setup();
if (!info)
return;
if (!rb_has_hw_option(info, RB_HW_OPT_NO_NAND)) {
/*
* Old hardware revisions might be equipped with a NAND flash
* chip instead of the 16MiB SPI NOR device. Those boards are
* not supported at the moment, so throw a warning and skip
* the peripheral setup to avoid messing up the data in the
* flash chip.
*/
WARN(1, "The NAND flash on this board is not supported.\n");
} else {
rbspi_peripherals_setup(0);
}
ath79_register_mdio(1, 0x0);
ath79_init_mac(ath79_eth1_data.mac_addr, ath79_mac_base, 0);
ath79_eth1_data.phy_if_mode = PHY_INTERFACE_MODE_GMII;
ath79_eth1_data.speed = SPEED_1000;
ath79_eth1_data.duplex = DUPLEX_FULL;
ath79_register_eth(1);
rbspi_wlan_init(0, 1);
rbspi_register_reset_button(RB911L_GPIO_BTN_RESET);
/* Make the eth LED controllable by software. */
ath79_gpio_output_select(RB911L_GPIO_LED_ETH, AR934X_GPIO_OUT_GPIO);
ath79_register_leds_gpio(-1, ARRAY_SIZE(rb911l_leds), rb911l_leds);
}
MIPS_MACHINE_NONAME(ATH79_MACH_RB_MAPL, "map-hb", rbmapl_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_941, "H951L", rbhapl_setup);
ar71xx: add support for the MikroTik RB911-2Hn/5Hn boards The patch adds support for the MikroTik RB911-2Hn (911 Lite2) and the RB911-5Hn (911 Lite5) boards: https://mikrotik.com/product/RB911-2Hn https://mikrotik.com/product/RB911-5Hn The two boards are using the same hardware design, the only difference between the two is the supported wireless band. Specifications: * SoC: Atheros AR9344 (600MHz) * RAM: 64MiB * Storage: 16 MiB SPI NOR flash * Ethernet: 1x100M (Passive PoE in) * Wireless: AR9344 built-in wireless MAC, single chain 802.11b/g/n (911-2Hn) or 802.11a/g/n (911-5Hn) Notes: * Older versions of these boards might be equipped with a NAND flash chip instead of the SPI NOR device. Those boards are not supported (yet). * The MikroTik RB911-5HnD (911 Lite5 Dual) board also uses the same hardware. Support for that can be added later with little effort probably. Installation: 1. Setup a DHCP/BOOTP Server with the following parameters: * DHCP-Option 66 (TFTP server name): pointing to a local TFTP server within the same subnet of the DHCP range * DHCP-Option 67 (Bootfile-Name): matching the initramfs filename of the to be booted image. The usable intramfs files are: - openwrt-ar71xx-mikrotik-vmlinux-initramfs.elf - openwrt-ar71xx-mikrotik-vmlinux-initramfs-lzma.elf - openwrt-ar71xx-mikrotik-rb-nor-flash-16M-initramfs-kernel.bin 2. Press the reset button on the board and keep that pressed. 3. Connect the board to your local network via its ethernet port. 4. Release the button after the LEDs on the board are turned off. Now the board should load and start the initramfs image from the TFTP server. 5. Upload the sysupgrade image to the board with scp: $ scp openwrt-ar71xx-mikrotik-rb-nor-flash-16M-squashfs-sysupgrade.bin root@192.168.1.1:/tmp/fw.bin 5. Log in to the running system listening on 192.168.1.1 via ssh as root (without password): $ ssh root@192.168.1.1 7. Flash the uploaded firmware file from the ssh session via the sysupgrade command: root@OpenWrt:~# sysupgrade /tmp/fw.bin Signed-off-by: Gabor Juhos <juhosg@freemail.hu>
2018-01-18 12:50:32 +00:00
MIPS_MACHINE_NONAME(ATH79_MACH_RB_911L, "911L", rb911l_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_952, "952-hb", rb952_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_962, "962", rb962_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_750UPR2, "750-hb", rb750upr2_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_LHG5, "lhg", rblhg_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_WAP, "wap-hb", rbwap_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_CAP, "cap-hb", rbcap_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_MAP, "map2-hb", rbmap_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_WAPAC, "wapg-sc", rbwapgsc_setup);