openwrt/target/linux/ar71xx/files/arch/mips/ath79/mach-rbspi.c
Thibaut VARÈNE 091e915d99 ar71xx: improve MikroTik wAP R support
81d446b045 introduced incomplete
support for this device.

This patch attempts to correct the situation based on OEM source
code.

LED1-3 are GSM mode on OFW (2G/3G/4G) hence unassigned here.

Signed-off-by: Thibaut VARÈNE <hacks@slashdirt.org>
Tested-by: David Ehrmann <ehrmann@gmail.com>
2018-07-30 10:35:11 +02:00

1247 lines
33 KiB
C

/*
* MikroTik SPI-NOR RouterBOARDs support
*
* - MikroTik RouterBOARD mAP 2nD
* - MikroTik RouterBOARD mAP L-2nD
* - MikroTik RouterBOARD 911-2Hn (911 Lite2)
* - MikroTik RouterBOARD 911-5Hn (911 Lite5)
* - MikroTik RouterBOARD 931-2nD (hAP mini)
* - 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
* - MikroTik RouterBOARD wAP2nD
* - MikroTik RouterBOARD wAP G-5HacT2HnDwAP (wAP AC)
* - MikroTik RouterBOARD wAP R-2nD
*
* 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) 2017-2018 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_PWROFF 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_WIFI_LED_1 1
#define RB962_WIFI_LED_2 2
#define RB962_GPIO_POE_STATUS 2
#define RB962_GPIO_POE_POWER 3
#define RB962_GPIO_LED_USER 12
#define RB962_GPIO_USB_PWROFF 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_PWROFF 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",
.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_WIFI_LED_1 1
#define RBWAPGSC_WIFI_LED_2 8
#define RBWAPGSC_WIFI_LED_3 9
#define RBWAPGSC_GPIO_LED_POWER 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:power",
.gpio = RBWAPGSC_GPIO_LED_POWER,
.active_low = 1,
.default_state = LEDS_GPIO_DEFSTATE_ON,
},
};
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
},
};
/* 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, active low */
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,
.active_low = 1,
.open_drain = 1,
}, {
.name = "rb:green:user",
.gpio = RB911L_GPIO_LED_USER,
.active_low = 1,
.open_drain = 1,
},
};
/* RB 931-2nD gpios */
#define RB931_GPIO_BTN_RESET 0
#define RB931_GPIO_BTN_MODE 9
#define RB931_GPIO_LED_USER 1
static struct gpio_keys_button rb931_gpio_keys[] __initdata = {
{
.desc = "Reset button",
.type = EV_KEY,
.code = KEY_RESTART,
.debounce_interval = RBSPI_KEYS_DEBOUNCE_INTERVAL,
.gpio = RB931_GPIO_BTN_RESET,
.active_low = 1,
}, {
.desc = "Mode button",
.type = EV_KEY,
.code = BTN_0,
.debounce_interval = RBSPI_KEYS_DEBOUNCE_INTERVAL,
.gpio = RB931_GPIO_BTN_MODE,
.active_low = 1,
}
};
static struct gpio_led rb931_leds[] __initdata = {
{
.name = "rb:green:user",
.gpio = RB931_GPIO_LED_USER,
.active_low = 1,
},
};
/* RB wAP R-2nD (wAP R) gpios*/
#define RBWAPR_GPIO_LED_USER 14
#define RBWAPR_GPIO_LED1 12
#define RBWAPR_GPIO_LED2 13
#define RBWAPR_GPIO_LED3 3
#define RBWAPR_GPIO_PCIE_PWROFF 15
#define RBWAPR_GPIO_CONTROL 10
#define RBWAPR_GPIO_BTN_RESET 16
static struct gpio_led rbwapr_leds[] __initdata = {
{
.name = "rb:green:user",
.gpio = RBWAPR_GPIO_LED_USER,
.active_low = 0,
},{
.name = "rb:green:led1",
.gpio = RBWAPR_GPIO_LED1,
.active_low = 1,
},{
.name = "rb:green:led2",
.gpio = RBWAPR_GPIO_LED2,
.active_low = 1,
},{
.name = "rb:green:led3",
.gpio = RBWAPR_GPIO_LED3,
.active_low = 0,
},
};
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_PWROFF, GPIOF_ACTIVE_LOW |
GPIOF_OUT_INIT_HIGH | GPIOF_EXPORT_DIR_FIXED,
"USB power off");
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_PWROFF, GPIOF_ACTIVE_LOW |
GPIOF_OUT_INIT_HIGH | GPIOF_EXPORT_DIR_FIXED,
"USB power off");
/* 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);
}
/*
* 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);
/* 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);
}
/*
* 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)
{
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,
GPIOF_OUT_INIT_LOW | GPIOF_EXPORT_DIR_FIXED,
"POE power");
if (flags & RBSPI_HAS_USB)
gpio_request_one(RBMAP_GPIO_USB_PWROFF,
GPIOF_OUT_INIT_HIGH | GPIOF_ACTIVE_LOW |
GPIOF_EXPORT_DIR_FIXED,
"USB power off");
ath79_register_leds_gpio(-1, ARRAY_SIZE(rbmap_leds), rbmap_leds);
/* 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);
}
/*
* 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);
}
/*
* Init the hAP mini hardware (QCA953x).
* The 931-2nD (hAP mini) has 3 ethernet ports, with port 2-3
* being assigned to LAN on the casing, and port 1 being assigned
* to "internet" (WAN) on the casing. Port 1 is connected to PHY2.
* Since WAN is neither PHY0 nor PHY4, we cannot use GMAC0 with this device.
*/
static void __init rb931_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 + 3 */
rbspi_network_setup(flags, 0, 3, 0);
ath79_register_leds_gpio(-1, ARRAY_SIZE(rb931_leds), rb931_leds);
/* hAP mini has two buttons */
ath79_register_gpio_keys_polled(-1, RBSPI_KEYS_POLL_INTERVAL,
ARRAY_SIZE(rb931_gpio_keys),
rb931_gpio_keys);
}
/*
* Init the wAP R hardware.
* The wAP R-2nD has a single ethernet port and a mini PCIe slot.
* The OEM source shows it has usb (used over PCIe for LTE devices),
* and the 'control' GPIO is assumed to be an output pin not tied to an LED.
*/
static void __init rbwapr_setup(void)
{
u32 flags = RBSPI_HAS_WLAN0 | RBSPI_HAS_USB | RBSPI_HAS_PCI;
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(rbwapr_leds), rbwapr_leds);
gpio_request_one(RBWAPR_GPIO_PCIE_PWROFF, GPIOF_OUT_INIT_HIGH |
GPIOF_ACTIVE_LOW | GPIOF_EXPORT_DIR_FIXED,
"PCIE power off");
gpio_request_one(RBWAPR_GPIO_CONTROL, GPIOF_OUT_INIT_LOW |
GPIOF_ACTIVE_LOW | GPIOF_EXPORT_DIR_FIXED,
"control");
rbspi_register_reset_button(RBWAPR_GPIO_BTN_RESET);
}
MIPS_MACHINE_NONAME(ATH79_MACH_RB_MAPL, "map-hb", rbmapl_setup);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_941, "H951L", rbhapl_setup);
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_WAPR, "wap-lte", rbwapr_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);
MIPS_MACHINE_NONAME(ATH79_MACH_RB_931, "931", rb931_setup);